Query 043560
Match_columns 66
No_of_seqs 115 out of 975
Neff 7.1
Searched_HMMs 46136
Date Fri Mar 29 06:13:31 2013
Command hhsearch -i /work/01045/syshi/csienesis_hhblits_a3m/043560.a3m -d /work/01045/syshi/HHdatabase/Cdd.hhm -o /work/01045/syshi/hhsearch_cdd/043560hhsearch_cdd -cpu 12 -v 0
No Hit Prob E-value P-value Score SS Cols Query HMM Template HMM
1 KOG0406 Glutathione S-transfer 99.1 1.7E-10 3.7E-15 76.3 5.7 55 10-65 123-180 (231)
2 PF13410 GST_C_2: Glutathione 99.0 1.6E-09 3.4E-14 58.1 5.9 48 12-60 2-50 (69)
3 cd03185 GST_C_Tau GST_C family 98.8 2.9E-08 6.2E-13 58.0 6.4 50 11-61 30-80 (126)
4 cd00299 GST_C_family Glutathio 98.8 2.8E-08 6E-13 55.0 5.9 51 11-62 31-82 (100)
5 cd03193 GST_C_Metaxin GST_C fa 98.8 2.9E-08 6.3E-13 55.4 5.9 56 2-58 1-61 (88)
6 cd03186 GST_C_SspA GST_N famil 98.8 2.6E-08 5.7E-13 57.0 5.7 47 11-58 30-77 (107)
7 PF00043 GST_C: Glutathione S- 98.7 3.8E-08 8.3E-13 55.0 5.3 48 13-61 25-73 (95)
8 cd03184 GST_C_Omega GST_C fami 98.7 3E-08 6.5E-13 58.6 4.1 50 11-61 27-79 (124)
9 cd03201 GST_C_DHAR GST_C famil 98.7 6.5E-08 1.4E-12 57.7 5.4 49 10-59 24-74 (121)
10 cd03179 GST_C_1 GST_C family, 98.7 7.4E-08 1.6E-12 54.5 5.2 46 12-58 39-85 (105)
11 cd03188 GST_C_Beta GST_C famil 98.6 1.1E-07 2.4E-12 54.4 5.7 45 14-59 41-86 (114)
12 cd03190 GST_C_ECM4_like GST_C 98.6 1.3E-07 2.8E-12 57.4 6.0 47 10-57 31-78 (142)
13 cd03189 GST_C_GTT1_like GST_C 98.6 1.1E-07 2.4E-12 55.1 5.4 44 15-59 53-97 (119)
14 cd03202 GST_C_etherase_LigE GS 98.6 9E-08 1.9E-12 57.0 5.0 46 13-59 55-101 (124)
15 cd03187 GST_C_Phi GST_C family 98.6 1.6E-07 3.5E-12 54.1 5.9 46 12-58 41-87 (118)
16 cd03196 GST_C_5 GST_C family, 98.6 1.3E-07 2.8E-12 55.6 5.1 47 12-59 37-84 (115)
17 cd03207 GST_C_8 GST_C family, 98.6 1.2E-07 2.6E-12 53.9 4.8 47 12-59 26-73 (103)
18 TIGR00862 O-ClC intracellular 98.6 2.4E-07 5.1E-12 61.2 6.4 54 11-65 118-191 (236)
19 cd03206 GST_C_7 GST_C family, 98.5 2.9E-07 6.2E-12 52.3 5.3 46 12-58 29-75 (100)
20 cd03182 GST_C_GTT2_like GST_C 98.5 3.8E-07 8.3E-12 52.6 5.8 46 13-59 46-92 (117)
21 cd03180 GST_C_2 GST_C family, 98.5 4.7E-07 1E-11 51.4 5.8 43 14-57 41-85 (110)
22 cd03177 GST_C_Delta_Epsilon GS 98.5 3.4E-07 7.3E-12 53.4 5.3 46 13-59 35-81 (118)
23 cd03209 GST_C_Mu GST_C family, 98.5 4.6E-07 9.9E-12 53.3 5.8 47 13-60 32-79 (121)
24 cd03178 GST_C_Ure2p_like GST_C 98.4 2.6E-07 5.6E-12 53.0 3.6 46 12-58 36-82 (113)
25 cd03192 GST_C_Sigma_like GST_C 98.4 6.7E-07 1.5E-11 50.8 5.0 48 12-60 35-85 (104)
26 cd03181 GST_C_EFB1gamma GST_C 98.4 1.2E-06 2.5E-11 51.0 6.1 46 12-58 36-82 (123)
27 cd03183 GST_C_Theta GST_C fami 98.4 1.7E-06 3.7E-11 50.7 5.9 47 11-58 40-88 (126)
28 cd03210 GST_C_Pi GST_C family, 98.3 2.4E-06 5.3E-11 50.6 5.8 47 12-59 31-81 (126)
29 cd03191 GST_C_Zeta GST_C famil 98.3 2.5E-06 5.5E-11 49.7 5.7 42 17-59 45-89 (121)
30 cd03204 GST_C_GDAP1 GST_C fami 98.3 2.4E-06 5.3E-11 50.8 5.2 47 12-59 25-82 (111)
31 cd03198 GST_C_CLIC GST_C famil 98.3 3E-06 6.4E-11 52.0 5.5 48 11-59 24-88 (134)
32 PRK09481 sspA stringent starva 98.3 2.9E-06 6.4E-11 54.0 5.6 46 12-58 123-169 (211)
33 cd03212 GST_C_Metaxin1_3 GST_C 98.2 3.7E-06 8.1E-11 51.2 5.4 44 13-57 61-105 (137)
34 PRK10542 glutathionine S-trans 98.2 4.2E-06 9E-11 52.3 5.7 43 15-58 123-166 (201)
35 PRK10387 glutaredoxin 2; Provi 98.2 1.5E-06 3.2E-11 54.7 3.6 43 15-59 141-184 (210)
36 PLN02473 glutathione S-transfe 98.2 4E-06 8.6E-11 53.1 5.6 43 15-58 134-177 (214)
37 cd03211 GST_C_Metaxin2 GST_C f 98.2 4.6E-06 9.9E-11 50.1 5.1 44 13-57 54-98 (126)
38 PLN02395 glutathione S-transfe 98.1 6.7E-06 1.4E-10 52.0 5.5 43 14-57 132-175 (215)
39 COG0625 Gst Glutathione S-tran 98.1 8.9E-06 1.9E-10 51.5 5.4 48 12-60 127-175 (211)
40 cd03200 GST_C_JTV1 GST_C famil 98.1 6.4E-06 1.4E-10 47.3 4.2 38 19-57 38-76 (96)
41 PRK13972 GSH-dependent disulfi 98.1 1.1E-05 2.5E-10 51.2 5.5 43 14-57 130-174 (215)
42 cd03203 GST_C_Lambda GST_C fam 98.1 1.1E-05 2.4E-10 47.6 4.9 40 19-59 33-75 (120)
43 PRK11752 putative S-transferas 98.0 1.2E-05 2.7E-10 53.2 5.3 42 15-57 177-219 (264)
44 TIGR02182 GRXB Glutaredoxin, G 98.0 4.1E-06 9E-11 53.5 2.9 44 15-59 140-183 (209)
45 cd03205 GST_C_6 GST_C family, 98.0 2E-05 4.4E-10 44.6 5.5 44 12-59 33-77 (98)
46 cd03195 GST_C_4 GST_C family, 98.0 1.1E-05 2.4E-10 47.2 4.4 47 13-60 39-86 (114)
47 cd03208 GST_C_Alpha GST_C fami 98.0 2.2E-05 4.7E-10 47.5 5.7 39 20-59 43-84 (137)
48 PLN02378 glutathione S-transfe 98.0 1.7E-05 3.7E-10 50.7 5.1 43 15-58 117-162 (213)
49 TIGR01262 maiA maleylacetoacet 97.9 3.2E-05 6.9E-10 48.6 5.5 42 17-59 130-174 (210)
50 PF14497 GST_C_3: Glutathione 97.9 1.7E-05 3.6E-10 45.1 3.6 42 12-54 31-75 (99)
51 PTZ00057 glutathione s-transfe 97.9 3.8E-05 8.2E-10 48.7 5.1 42 16-58 123-167 (205)
52 PRK10357 putative glutathione 97.8 7.1E-05 1.5E-09 46.9 5.8 43 15-59 124-167 (202)
53 PLN02817 glutathione dehydroge 97.7 7.4E-05 1.6E-09 50.0 5.0 41 18-59 173-215 (265)
54 cd03194 GST_C_3 GST_C family, 97.6 0.00029 6.2E-09 41.3 5.8 45 14-59 39-86 (114)
55 PRK15113 glutathione S-transfe 97.6 0.00025 5.5E-09 45.1 5.4 44 14-58 135-179 (214)
56 cd03197 GST_C_mPGES2 GST_C fam 97.1 0.0027 5.9E-08 39.8 5.8 40 18-58 81-122 (149)
57 KOG4420 Uncharacterized conser 96.8 0.0044 9.6E-08 42.5 5.4 47 12-59 201-252 (325)
58 PLN02907 glutamate-tRNA ligase 96.6 0.003 6.6E-08 47.7 4.2 34 20-54 94-128 (722)
59 KOG0867 Glutathione S-transfer 96.5 0.0074 1.6E-07 39.3 5.0 45 12-57 129-174 (226)
60 COG0435 ECM4 Predicted glutath 96.4 0.0021 4.5E-08 44.3 1.7 47 10-57 199-246 (324)
61 KOG3029 Glutathione S-transfer 94.4 0.05 1.1E-06 37.9 3.1 42 19-61 291-334 (370)
62 KOG3027 Mitochondrial outer me 94.0 0.16 3.6E-06 34.0 4.8 44 10-54 171-215 (257)
63 KOG4244 Failed axon connection 93.3 0.062 1.3E-06 36.8 2.0 39 15-54 202-241 (281)
64 PF14834 GST_C_4: Glutathione 92.6 0.44 9.5E-06 28.9 4.8 43 15-58 42-85 (117)
65 KOG1422 Intracellular Cl- chan 92.3 0.16 3.5E-06 33.7 2.9 43 17-60 124-170 (221)
66 KOG2903 Predicted glutathione 91.4 0.22 4.7E-06 34.4 2.8 44 10-54 197-243 (319)
67 KOG1695 Glutathione S-transfer 91.1 0.42 9.1E-06 31.3 3.8 37 18-55 125-164 (206)
68 KOG3028 Translocase of outer m 90.4 1 2.2E-05 31.4 5.4 42 14-56 161-203 (313)
69 KOG0868 Glutathione S-transfer 89.3 0.39 8.4E-06 31.6 2.5 37 18-55 134-173 (217)
70 PF04399 Glutaredoxin2_C: Glut 86.4 3 6.5E-05 25.5 5.1 44 15-59 58-101 (132)
71 cd03199 GST_C_GRX2 GST_C famil 84.4 2.1 4.5E-05 26.2 3.7 46 16-62 60-105 (128)
72 PF11801 Tom37_C: Tom37 C-term 81.5 4.7 0.0001 25.4 4.6 33 21-54 113-150 (168)
73 PF09236 AHSP: Alpha-haemoglob 62.5 4.9 0.00011 23.2 1.2 19 10-28 55-73 (89)
74 PF04726 Microvir_J: Microviru 43.0 8.8 0.00019 16.8 0.1 7 1-7 13-19 (24)
75 COG1656 Uncharacterized conser 42.2 22 0.00048 22.7 1.9 16 45-60 10-25 (165)
76 PF08020 DUF1706: Protein of u 36.8 1.1E+02 0.0024 19.3 4.7 27 35-62 34-62 (166)
77 PHA00008 J DNA packaging prote 33.9 9.4 0.0002 17.1 -0.5 7 1-7 14-20 (26)
78 cd08200 catalase_peroxidase_2 31.1 90 0.0019 21.8 3.6 24 39-65 93-117 (297)
79 PF08256 Antimicrobial20: Aure 22.7 54 0.0012 12.4 0.8 6 44-49 1-6 (13)
No 1
>KOG0406 consensus Glutathione S-transferase [Posttranslational modification, protein turnover, chaperones]
Probab=99.11 E-value=1.7e-10 Score=76.28 Aligned_cols=55 Identities=40% Similarity=0.710 Sum_probs=48.7
Q ss_pred ChHHHHHHHHHHHHHHHHHHhcccC-CCceeccC-chHHHHHHHHHH-HHHHHHHHHhc
Q 043560 10 SVQDQESTMKEILEMLKTVEEHGLG-EKKFFHGD-IGLVDIAFASIV-YWLQIIEDVAR 65 (66)
Q Consensus 10 ~~ee~~~a~~~~~~~l~~l~e~~l~-~~~ff~G~-~g~~Di~~~~~~-~w~~~~e~~~g 65 (66)
.+++++++.+++.+.|+.| |+.|. +++||+|+ +||+||+++|++ +|+.+.+++.|
T Consensus 123 ~~e~~~~~~~e~~e~l~~l-E~el~k~k~~fgG~~~G~vDi~~~p~~~~~~~~~~~~~~ 180 (231)
T KOG0406|consen 123 GGEEQEAAKEELREALKVL-EEELGKGKDFFGGETIGFVDIAIGPSFERWLAVLEKFGG 180 (231)
T ss_pred CchHHHHHHHHHHHHHHHH-HHHHhcCCCCCCCCCcCHhhhhHHhhHHHHHHHHHHhcC
Confidence 4689999999999999999 88887 78999999 999999999655 89888887754
No 2
>PF13410 GST_C_2: Glutathione S-transferase, C-terminal domain; PDB: 4DEJ_H 3IC8_A 2JL4_A 2V6K_B 3CBU_B 1JLW_B 3F6D_B 3G7I_A 3F63_A 3G7J_B ....
Probab=99.01 E-value=1.6e-09 Score=58.08 Aligned_cols=48 Identities=27% Similarity=0.479 Sum_probs=41.2
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQII 60 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~~ 60 (66)
+..+++.+++.+.++.+ |+.|.+++|+.|+ ||++||++++++.|+..+
T Consensus 2 ~~~~~~~~~~~~~l~~l-e~~L~~~~fl~G~~~s~aD~~l~~~l~~~~~~ 50 (69)
T PF13410_consen 2 AAVERARAQLEAALDAL-EDHLADGPFLFGDRPSLADIALAPFLWRLRFV 50 (69)
T ss_dssp HHHHHHHHHHHHHHHHH-HHHHTTSSBTTBSS--HHHHHHHHHHHHHHHC
T ss_pred HHHHHHHHHHHHHHHHH-HHHHhhCCCCCCCCCCHHHHHHHHHHHHHHHh
Confidence 45778899999999999 9999999999999 999999999999888754
No 3
>cd03185 GST_C_Tau GST_C family, Class Tau subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. The plant-specific class Tau GST subfamily has undergone extensive gene duplication. The Arabidopsis and Oryza genomes contain 28 and 40 Tau GSTs, respectively. They are primarily responsible for herbicide detoxification together with class Phi GSTs, showing class specificity in substrate preference. Tau enzymes are highly efficient in detoxifying diphenylether and aryloxyphenoxypropi
Probab=98.79 E-value=2.9e-08 Score=58.03 Aligned_cols=50 Identities=46% Similarity=0.755 Sum_probs=43.1
Q ss_pred hHHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHHHH
Q 043560 11 VQDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQIIE 61 (66)
Q Consensus 11 ~ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~~e 61 (66)
++.++...+++.+.++.+ |+.|.++||+.|+ +|++||++++++.|+....
T Consensus 30 ~~~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~t~ADi~l~~~~~~~~~~~ 80 (126)
T cd03185 30 GEEREKAKEEALEALKVL-EEELGGKPFFGGDTIGYVDIALGSFLGWFRAYE 80 (126)
T ss_pred hHHHHHHHHHHHHHHHHH-HHHhcCCCCCCCCCcchHHHHHHHHHHHHHHHH
Confidence 345667788899999999 9999888999999 9999999999998886543
No 4
>cd00299 GST_C_family Glutathione S-transferase (GST) family, C-terminal alpha helical domain; a large, diverse group of cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. In addition, GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. This family, also referred to as soluble GSTs, is the largest family of GSH transferases and is only distantly related to the mitochondrial GSTs (GSTK). Soluble GSTs bear no structural similarity to microsomal GSTs (MAPEG family) and display additional activities unique to their group, such as catalyzing thiolysis, reduction and isomerization of certain compounds. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an activ
Probab=98.79 E-value=2.8e-08 Score=55.04 Aligned_cols=51 Identities=25% Similarity=0.427 Sum_probs=44.3
Q ss_pred hHHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHHHHH
Q 043560 11 VQDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQIIED 62 (66)
Q Consensus 11 ~ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~~e~ 62 (66)
.+.++...+++.+.++.+ ++.|++++|+.|+ +|++||++++++.|+.....
T Consensus 31 ~~~~~~~~~~~~~~~~~l-~~~L~~~~~~~g~~~t~aDi~~~~~l~~~~~~~~ 82 (100)
T cd00299 31 EAALEEAREELAAALAAL-EKLLAGRPYLAGDRFSLADIALAPVLARLDLLGP 82 (100)
T ss_pred HHHHHHHHHHHHHHHHHH-HHHHccCCCCCCCCcCHHHHHHHHHHHHHHHhhh
Confidence 455677788999999999 9999888999999 99999999999988876544
No 5
>cd03193 GST_C_Metaxin GST_C family, Metaxin subfamily; composed of metaxins and related proteins. Metaxin 1 is a component of a preprotein import complex of the mitochondrial outer membrane. It extends to the cytosol and is anchored to the mitochondrial membrane through its C-terminal domain. In mice, metaxin is required for embryonic development. In humans, alterations in the metaxin gene may be associated with Gaucher disease. Metaxin 2 binds to metaxin 1 and may also play a role in protein translocation into the mitochondria. Genome sequencing shows that a third metaxin gene also exists in zebrafish, Xenopus, chicken, and mammals. Sequence analysis suggests that all three metaxins share a common ancestry and that they possess similarity to GSTs. Also included in the subfamily are uncharacterized proteins with similarity to metaxins, including a novel GST from Rhodococcus with toluene o-monooxygenase and glutamylcysteine synthetase activities. Other members are the cadmium-inducible
Probab=98.78 E-value=2.9e-08 Score=55.43 Aligned_cols=56 Identities=21% Similarity=0.261 Sum_probs=45.0
Q ss_pred Cchhhhhc-C---hHHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 2 ATVWKKFC-S---VQDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 2 ~~~~~~~~-~---~ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
||+|..+. + ..-+.+..+++.+.++.+ |+.|++++|+.|+ +|++||++++++.|+.
T Consensus 1 ~~~~~~~~~~~~~~~~~~~~~~~~~~~l~~l-e~~L~~~~yl~Gd~~t~aDi~l~~~l~~~~ 61 (88)
T cd03193 1 ARAYTRWVDEHLYWTLTREIYSLAKKDLKAL-SDLLGDKKFFFGDKPTSLDATVFGHLASIL 61 (88)
T ss_pred ChhHHHhhhhHhHHHHHHHHHHHHHHHHHHH-HHHhCCCCccCCCCCCHHHHHHHHHHHHHH
Confidence 45665555 2 233556788899999999 9999989999999 9999999999887765
No 6
>cd03186 GST_C_SspA GST_N family, Stringent starvation protein A (SspA) subfamily; SspA is a RNA polymerase (RNAP)-associated protein required for the lytic development of phage P1 and for stationary phase-induced acid tolerance of E. coli. It is implicated in survival during nutrient starvation. SspA adopts the GST fold with an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, but it does not bind glutathione (GSH) and lacks GST activity. SspA is highly conserved among gram-negative bacteria. Related proteins found in Neisseria (called RegF), Francisella and Vibrio regulate the expression of virulence factors necessary for pathogenesis.
Probab=98.77 E-value=2.6e-08 Score=57.02 Aligned_cols=47 Identities=28% Similarity=0.457 Sum_probs=40.7
Q ss_pred hHHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 11 VQDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 11 ~ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
++.++...+++.+.+..+ |+.|+++||+.|+ +|++||++++++.++.
T Consensus 30 ~~~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~t~aDi~~~~~~~~~~ 77 (107)
T cd03186 30 KKEAEKARKELRESLLAL-APVFAHKPYFMSEEFSLVDCALAPLLWRLP 77 (107)
T ss_pred HHHHHHHHHHHHHHHHHH-HHHHcCCCcccCCCCcHHHHHHHHHHHHHH
Confidence 455677888999999999 9999889999999 9999999999875544
No 7
>PF00043 GST_C: Glutathione S-transferase, C-terminal domain; InterPro: IPR004046 In eukaryotes, glutathione S-transferases (GSTs) participate in the detoxification of reactive electrophillic compounds by catalysing their conjugation to glutathione. The GST domain is also found in S-crystallins from squid, and proteins with no known GST activity, such as eukaryotic elongation factors 1-gamma and the HSP26 family of stress-related proteins, which include auxin-regulated proteins in plants and stringent starvation proteins in Escherichia coli. The major lens polypeptide of cephalopods is also a GST [, , , ]. Bacterial GSTs of known function often have a specific, growth-supporting role in biodegradative metabolism: epoxide ring opening and tetrachlorohydroquinone reductive dehalogenation are two examples of the reactions catalysed by these bacterial GSTs. Some regulatory proteins, like the stringent starvation proteins, also belong to the GST family [, ]. GST seems to be absent from Archaea in which gamma-glutamylcysteine substitute to glutathione as major thiol. Glutathione S-transferases form homodimers, but in eukaryotes can also form heterodimers of the A1 and A2 or YC1 and YC2 subunits. The homodimeric enzymes display a conserved structural fold. Each monomer is composed of a distinct N-terminal sub-domain, which adopts the thioredoxin fold, and a C-terminal all-helical sub-domain. This entry is the C-terminal domain.; PDB: 3UAP_A 3UAR_A 3QAV_A 3QAW_A 1Y6E_A 1U88_B 4AI6_B 1UA5_A 4AKH_A 3QMZ_S ....
Probab=98.73 E-value=3.8e-08 Score=54.99 Aligned_cols=48 Identities=23% Similarity=0.444 Sum_probs=40.2
Q ss_pred HHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQIIE 61 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~~e 61 (66)
.++...+++.+.|..+ ++.|++++|+.|+ +|+|||++.+++.|+..+.
T Consensus 25 ~~~~~~~~~~~~l~~l-e~~l~~~~~l~G~~~t~ADi~~~~~~~~~~~~~ 73 (95)
T PF00043_consen 25 MVEEARAKVPRYLEVL-EKRLKGGPYLVGDKLTIADIALFPMLDWLERLG 73 (95)
T ss_dssp HHHHHHHHHHHHHHHH-HHHHHTSSSSSBSS-CHHHHHHHHHHHHHHHHT
T ss_pred HHHHHHHHHHHHHHHH-HHHHcCCCeeeccCCchhHHHHHHHHHHHHHhC
Confidence 4566678888999999 9999999999999 9999999999988876553
No 8
>cd03184 GST_C_Omega GST_C family, Class Omega subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. Class Omega GSTs show little or no GSH-conjugating activity towards standard GST substrates. Instead, they catalyze the GSH dependent reduction of protein disulfides, dehydroascorbate and monomethylarsonate, activities which are more characteristic of glutaredoxins. They contain a conserved cysteine equivalent to the first cysteine in the CXXC motif of glutaredoxins, which is a re
Probab=98.68 E-value=3e-08 Score=58.55 Aligned_cols=50 Identities=28% Similarity=0.420 Sum_probs=43.0
Q ss_pred hHHHHHHHHHHHHHHHHHHhcccCC--CceeccC-chHHHHHHHHHHHHHHHHH
Q 043560 11 VQDQESTMKEILEMLKTVEEHGLGE--KKFFHGD-IGLVDIAFASIVYWLQIIE 61 (66)
Q Consensus 11 ~ee~~~a~~~~~~~l~~l~e~~l~~--~~ff~G~-~g~~Di~~~~~~~w~~~~e 61 (66)
+++.++..+++.+.++.+ |+.|.+ +||+.|+ +|++||++++++.|+..+.
T Consensus 27 ~~~~~~~~~~~~~~l~~l-e~~L~~~~~~yl~G~~~t~aDi~~~~~~~~~~~~~ 79 (124)
T cd03184 27 PSDREEKKAELRSALENL-EEELTKRGTPFFGGDSPGMVDYMIWPWFERLEALK 79 (124)
T ss_pred cccchhhHHHHHHHHHHH-HHHHHhcCCCCcCCCCccHHHHHhhHHHHHHHHHH
Confidence 356778889999999999 888874 7999999 9999999999888877654
No 9
>cd03201 GST_C_DHAR GST_C family, Dehydroascorbate Reductase (DHAR) subfamily; composed of plant-specific DHARs, monomeric enzymes catalyzing the reduction of DHA into ascorbic acid (AsA) using glutathione as the reductant. DHAR allows plants to recycle oxidized AsA before it is lost. AsA serves as a cofactor of violaxanthin de-epoxidase in the xanthophyll cycle and as an antioxidant in the detoxification of reactive oxygen species. Because AsA is the major reductant in plants, DHAR serves to regulate their redox state. It has been suggested that a significant portion of DHAR activity is plastidic, acting to reduce the large amounts of ascorbate oxidized during hydrogen peroxide scavenging by ascorbate peroxidase. DHAR contains a conserved cysteine in its active site and in addition to its reductase activity, shows thiol transferase activity similar to glutaredoxins.
Probab=98.67 E-value=6.5e-08 Score=57.70 Aligned_cols=49 Identities=33% Similarity=0.580 Sum_probs=40.1
Q ss_pred ChHHHHHHHHHHHHHHHHHHhcccCC-CceeccC-chHHHHHHHHHHHHHHH
Q 043560 10 SVQDQESTMKEILEMLKTVEEHGLGE-KKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 10 ~~ee~~~a~~~~~~~l~~l~e~~l~~-~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
...+.+++.+++.+.+..| |+.|.+ ++|+.|+ +|++||+++|++.++..
T Consensus 24 ~~~~~~~~~~~l~~~l~~L-e~~L~~~~~fl~Gd~~TlADi~l~~~l~~l~~ 74 (121)
T cd03201 24 SKDSNDGTEQALLDELEAL-EDHLKENGPFINGEKISAVDLSLAPKLYHLEI 74 (121)
T ss_pred CCcHHHHHHHHHHHHHHHH-HHHHhcCCCccCCCCCCHHhHHHHHHHHHHHH
Confidence 3334577788899999999 889974 7999999 99999999997766553
No 10
>cd03179 GST_C_1 GST_C family, unknown subfamily 1; composed of uncharacterized bacterial proteins, with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=98.66 E-value=7.4e-08 Score=54.49 Aligned_cols=46 Identities=22% Similarity=0.243 Sum_probs=40.2
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+..+...+++.+.++.+ |+.|+++||+.|+ +|++||++++++.|+.
T Consensus 39 ~~~~~~~~~~~~~l~~l-e~~L~~~~~l~g~~~slaDi~~~~~~~~~~ 85 (105)
T cd03179 39 EVLAFLRERGHAALAVL-EAHLAGRDFLVGDALTIADIALAAYTHVAD 85 (105)
T ss_pred HHHHHHHHHHHHHHHHH-HHHHccCccccCCCCCHHHHHHHHHHHhcc
Confidence 44567788899999999 9999888999999 9999999999888864
No 11
>cd03188 GST_C_Beta GST_C family, Class Beta subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. Unlike mammalian GSTs which detoxify a broad range of compounds, the bacterial class Beta GSTs exhibit limited GSH conjugating activity with a narrow range of substrates. In addition to GSH conjugation, they also bind antibiotics and reduce the antimicrobial activity of beta-lactam drugs. The structure of the Proteus mirabilis enzyme reveals that the cysteine in the active site for
Probab=98.64 E-value=1.1e-07 Score=54.38 Aligned_cols=45 Identities=13% Similarity=0.305 Sum_probs=38.4
Q ss_pred HHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 14 QESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 14 ~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
.+...+++.+.++.+ |+.|++++|+.|+ +|++||++++.+.|+..
T Consensus 41 ~~~~~~~~~~~l~~l-e~~l~~~~~l~G~~~t~aDi~~~~~~~~~~~ 86 (114)
T cd03188 41 KAAARERLAARLAYL-DAQLAGGPYLLGDRFSVADAYLFVVLRWAPG 86 (114)
T ss_pred HHHHHHHHHHHHHHH-HHHhcCCCeeeCCCcchHHHHHHHHHHHHhh
Confidence 355667889999999 9999888999999 99999999988877653
No 12
>cd03190 GST_C_ECM4_like GST_C family, ECM4-like subfamily; composed of predominantly uncharacterized and taxonomically diverse proteins with similarity to the translation product of the Saccharomyces cerevisiae gene ECM4. ECM4, a gene of unknown function, is involved in cell surface biosynthesis and architecture. S. cerevisiae ECM4 mutants show increased amounts of the cell wall hexose, N-acetylglucosamine. More recently, global gene expression analysis shows that ECM4 is upregulated during genotoxic conditions and together with the expression profiles of 18 other genes could potentially differentiate between genotoxic and cytotoxic insults in yeast.
Probab=98.63 E-value=1.3e-07 Score=57.44 Aligned_cols=47 Identities=19% Similarity=0.430 Sum_probs=41.0
Q ss_pred ChHHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 10 SVQDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 10 ~~ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
+++..+++.+++.+.|+.+ |+.|.+++|+.|+ +|++||++++++.++
T Consensus 31 ~~~~~~~~~~~l~~~l~~L-E~~L~~~~yl~Gd~~TlADi~l~~~l~~~ 78 (142)
T cd03190 31 TQEAYDEAVDELFEALDRL-EELLSDRRYLLGDRLTEADIRLFTTLIRF 78 (142)
T ss_pred CHHHHHHHHHHHHHHHHHH-HHHHccCCeeeCCCccHHHHHHHHHHHHH
Confidence 4566778889999999999 9999888999999 999999999887554
No 13
>cd03189 GST_C_GTT1_like GST_C family, Saccharomyces cerevisiae GTT1-like subfamily; composed of predominantly uncharacterized proteins with similarity to the S. cerevisiae GST protein, GTT1, and the Schizosaccharomyces pombe GST-III. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. GTT1, a homodimer, exhibits GST activity with standard substrates and associates with the endopl
Probab=98.63 E-value=1.1e-07 Score=55.10 Aligned_cols=44 Identities=23% Similarity=0.239 Sum_probs=38.2
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
+....++.+.++.+ |+.|++++|+.|+ +|++||++++.+.|+..
T Consensus 53 ~~~~~~~~~~l~~l-e~~L~~~~~l~Gd~~t~ADi~l~~~~~~~~~ 97 (119)
T cd03189 53 GFINPELKKHLDFL-EDRLAKKGYFVGDKLTAADIMMSFPLEAALA 97 (119)
T ss_pred HHHhHHHHHHHHHH-HHHHccCCCCCCCCCCHHHHHHHHHHHHHHH
Confidence 34556789999999 9999888999999 99999999988888764
No 14
>cd03202 GST_C_etherase_LigE GST_C family, Beta etherase LigE subfamily; composed of proteins similar to Sphingomonas paucimobilis beta etherase, LigE, a GST-like protein that catalyzes the cleavage of the beta-aryl ether linkages present in low-moleculer weight lignins using GSH as the hydrogen donor. This reaction is an essential step in the degradation of lignin, a complex phenolic polymer that is the most abundant aromatic material in the biosphere. The beta etherase activity of LigE is enantioselective and it complements the activity of the other GST family beta etherase, LigF. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains.
Probab=98.62 E-value=9e-08 Score=57.04 Aligned_cols=46 Identities=17% Similarity=0.309 Sum_probs=40.9
Q ss_pred HHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
..++.++++++.++.+ ++.|+++||+.|+ +|++|+++++++.|...
T Consensus 55 ~~~~~~~~~~~~l~~l-~~~L~~~~fl~Gd~~t~AD~~l~~~l~~~~~ 101 (124)
T cd03202 55 GREAALANFRAALEPL-RATLKGQPFLGGAAPNYADYIVFGGFQWARI 101 (124)
T ss_pred chHHHHHHHHHHHHHH-HHHHcCCCccCCCCCchhHHHHHHHHHHHHH
Confidence 3567788999999999 9999889999999 99999999988888765
No 15
>cd03187 GST_C_Phi GST_C family, Class Phi subfamily; composed of plant-specific class Phi GSTs and related fungal and bacterial proteins. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. The class Phi GST subfamily has experience extensive gene duplication. The Arabidopsis and Oryza genomes contain 13 and 16 Tau GSTs, respectively. They are primarily responsible for herbicide detoxification together with class Tau GSTs, showing class specificity in substrate preference. Phi enzymes a
Probab=98.62 E-value=1.6e-07 Score=54.07 Aligned_cols=46 Identities=22% Similarity=0.389 Sum_probs=38.9
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+..+...+.+.+.++.+ |+.|++++|+.|+ +|++||++++++.|+.
T Consensus 41 ~~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~t~aDi~l~~~~~~~~ 87 (118)
T cd03187 41 AVVEENEEKLKKVLDVY-EARLSKSKYLAGDSFTLADLSHLPYLQYLM 87 (118)
T ss_pred HHHHHHHHHHHHHHHHH-HHHcccCcccCCCCccHHHHHHHHHHHHHH
Confidence 34455678899999999 9999888999999 9999999998886654
No 16
>cd03196 GST_C_5 GST_C family, unknown subfamily 5; composed of uncharacterized bacterial proteins with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=98.59 E-value=1.3e-07 Score=55.64 Aligned_cols=47 Identities=23% Similarity=0.312 Sum_probs=41.0
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
++.+...+++.+.++.+ |+.|++++|+.|+ +|++||++++++.|+..
T Consensus 37 ~~~~~~~~~i~~~l~~l-e~~L~~~~yl~Gd~~tlADi~l~~~l~~~~~ 84 (115)
T cd03196 37 ESEEEYRQQAEAFLKDL-EARLQQHSYLLGDKPSLADWAIFPFVRQFAH 84 (115)
T ss_pred ccHHHHHHHHHHHHHHH-HHHHccCCccCCCCccHHHHHHHHHHHHHHH
Confidence 35677888999999999 9999888999999 99999999988777654
No 17
>cd03207 GST_C_8 GST_C family, unknown subfamily 8; composed of uncharacterized bacterial proteins with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=98.59 E-value=1.2e-07 Score=53.91 Aligned_cols=47 Identities=15% Similarity=0.277 Sum_probs=40.9
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
+..+...+++.+.++.+ |+.|++++|+.|+ +|++||++++++.|...
T Consensus 26 ~~~~~~~~~~~~~l~~l-e~~l~~~~~l~g~~~t~aDi~~~~~~~~~~~ 73 (103)
T cd03207 26 PARMAGFGSYDDVLAAL-EQALAKGPYLLGERFTAADVLVGSPLGWGLQ 73 (103)
T ss_pred chhhhhhhhHHHHHHHH-HHHHccCCcccCCccCHHHHHHHHHHHHHHH
Confidence 34566778899999999 9999988999999 99999999998888654
No 18
>TIGR00862 O-ClC intracellular chloride channel protein. These proteins are thought to function in the regulation of the membrane potential and in transepithelial ion absorption and secretion in the kidney.
Probab=98.57 E-value=2.4e-07 Score=61.25 Aligned_cols=54 Identities=20% Similarity=0.407 Sum_probs=43.2
Q ss_pred hHHHHHHHHHHHHHHHHHHhcccC------------------CCceeccC-chHHHHHHHHHHHHHHHH-HHHhc
Q 043560 11 VQDQESTMKEILEMLKTVEEHGLG------------------EKKFFHGD-IGLVDIAFASIVYWLQII-EDVAR 65 (66)
Q Consensus 11 ~ee~~~a~~~~~~~l~~l~e~~l~------------------~~~ff~G~-~g~~Di~~~~~~~w~~~~-e~~~g 65 (66)
++.+++..+++.+.++.| ++.|. +++||.|+ +|++||+++|++.+++++ +++.|
T Consensus 118 ~~~~~~~~~~l~~~l~~L-e~~L~~~~~~~~~~~~~~~~~~~~~~f~~Gd~~tlaD~~l~p~l~~l~~~~~~~~~ 191 (236)
T TIGR00862 118 PEANDNLEKGLLKALKKL-DDYLNSPLPEEIDEDSAEDEKVSRRKFLDGDELTLADCNLLPKLHIVKVVAKKYRN 191 (236)
T ss_pred HHHHHHHHHHHHHHHHHH-HHHHhccccccccccccccccccCCCcccCCccchhhHHHHHHHHHHHHHHHHHhC
Confidence 345566667799999999 88875 57999999 999999999999888875 44433
No 19
>cd03206 GST_C_7 GST_C family, unknown subfamily 7; composed of uncharacterized proteins with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=98.53 E-value=2.9e-07 Score=52.35 Aligned_cols=46 Identities=22% Similarity=0.380 Sum_probs=39.7
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
...++..+++.+.++.+ |+.|+++||+.|+ +|++||.+.+++.|..
T Consensus 29 ~~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~t~aDi~~~~~~~~~~ 75 (100)
T cd03206 29 LDKETAIARAHRLLRLL-EEHLAGRDWLAGDRPTIADVAVYPYVALAP 75 (100)
T ss_pred hHHHHHHHHHHHHHHHH-HHHHccCCccCCCCCCHHHHHHHHHHHHHh
Confidence 35567788999999999 9999888999999 9999999888876643
No 20
>cd03182 GST_C_GTT2_like GST_C family, Saccharomyces cerevisiae GTT2-like subfamily; composed of predominantly uncharacterized proteins with similarity to the S. cerevisiae GST protein, GTT2. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. GTT2, a homodimer, exhibits GST activity with standard substrates. Strains with deleted GTT2 genes are viable but exhibit increased sensiti
Probab=98.53 E-value=3.8e-07 Score=52.61 Aligned_cols=46 Identities=15% Similarity=0.229 Sum_probs=39.7
Q ss_pred HHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
..++...++.+.++.+ |+.|++++|+.|+ +|++||++++++.|+..
T Consensus 46 ~~~~~~~~l~~~l~~l-e~~L~~~~~l~gd~~t~aDi~l~~~~~~~~~ 92 (117)
T cd03182 46 WGERSKARAADFLAYL-DTRLAGSPYVAGDRFTIADITAFVGLDFAKV 92 (117)
T ss_pred HHHHHHHHHHHHHHHH-HHHhcCCCcccCCCCCHHHHHHHHHhHHHHh
Confidence 3466778899999999 9999888999999 99999999998887653
No 21
>cd03180 GST_C_2 GST_C family, unknown subfamily 2; composed of uncharacterized bacterial proteins, with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=98.51 E-value=4.7e-07 Score=51.42 Aligned_cols=43 Identities=16% Similarity=0.468 Sum_probs=36.8
Q ss_pred HHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHH-HHH
Q 043560 14 QESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIV-YWL 57 (66)
Q Consensus 14 ~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~-~w~ 57 (66)
.+...+.+.+.++.+ |+.|++++|+.|+ +|++||.+++++ .|.
T Consensus 41 ~~~~~~~~~~~l~~l-E~~L~~~~~l~g~~~t~aDi~~~~~~~~~~ 85 (110)
T cd03180 41 IAASLAAWAKLMAIL-DAQLAGRPYLAGDRFTLADIPLGCSAYRWF 85 (110)
T ss_pred HHHHHHHHHHHHHHH-HHHhCCCCcccCCCCCHHHHHHHHHHHHHH
Confidence 345678899999999 9999888999999 999999998876 554
No 22
>cd03177 GST_C_Delta_Epsilon GST_C family, Class Delta and Epsilon subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. The class Delta and Epsilon subfamily is made up primarily of insect GSTs, which play major roles in insecticide resistance by facilitating reductive dehydrochlorination of insecticides or conjugating them with GSH to produce water-soluble metabolites th
Probab=98.51 E-value=3.4e-07 Score=53.35 Aligned_cols=46 Identities=22% Similarity=0.364 Sum_probs=40.0
Q ss_pred HHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
..+.+.+++.+.++.+ ++.|++++|+.|+ +|++||.+++++.|+..
T Consensus 35 ~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~s~aDi~l~~~~~~~~~ 81 (118)
T cd03177 35 PPEEKLDKLEEALDFL-ETFLEGSDYVAGDQLTIADLSLVATVSTLEA 81 (118)
T ss_pred CCHHHHHHHHHHHHHH-HHHHccCCeeCCCCcCHHHHHHHHHHHHHHH
Confidence 4556778899999999 9999888999999 99999999999887753
No 23
>cd03209 GST_C_Mu GST_C family, Class Mu subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. The class Mu subfamily is composed of eukaryotic GSTs. In rats, at least six distinct class Mu subunits have been identified, with homologous genes in humans for five of these subunits. Class Mu GSTs can form homodimers and heterodimers, giving a large number of possible isoenzymes that can be formed, all with overlapping activities but different substrate specificities. They are the m
Probab=98.50 E-value=4.6e-07 Score=53.26 Aligned_cols=47 Identities=23% Similarity=0.354 Sum_probs=40.2
Q ss_pred HHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQII 60 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~~ 60 (66)
.++...+.+.+.+..+ |+.|++++|+.|+ +|++|+.+++++.|+...
T Consensus 32 ~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~T~aDi~l~~~~~~~~~~ 79 (121)
T cd03209 32 LKPDYLAKLPDKLKLF-SDFLGDRPWFAGDKITYVDFLLYEALDQHRIF 79 (121)
T ss_pred HHHHHHHHHHHHHHHH-HHHhCCCCCcCCCCccHHHHHHHHHHHHHHHh
Confidence 3455677788999999 9999888999999 999999999998888753
No 24
>cd03178 GST_C_Ure2p_like GST_C family, Ure2p-like subfamily; composed of the Saccharomyces cerevisiae Ure2p and related GSTs. Ure2p is a regulator for nitrogen catabolism in yeast. It represses the expression of several gene products involved in the use of poor nitrogen sources when rich sources are available. A transmissible conformational change of Ure2p results in a prion called [Ure3], an inactive, self-propagating and infectious amyloid. Ure2p displays a GST fold containing an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain. The N-terminal thioredoxin-fold domain is sufficient to induce the [Ure3] phenotype and is also called the prion domain of Ure2p. In addition to its role in nitrogen regulation, Ure2p confers protection to cells against heavy metal ion and oxidant toxicity, and shows glutathione (GSH) peroxidase activity. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of GSH with a wide range of en
Probab=98.45 E-value=2.6e-07 Score=53.04 Aligned_cols=46 Identities=22% Similarity=0.334 Sum_probs=39.4
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+..++..+++...++.+ |+.|++++|+.|+ +|++||++++++.|..
T Consensus 36 ~~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~t~aDi~l~~~~~~~~ 82 (113)
T cd03178 36 YAIERYTNEAKRLYGVL-DKRLAGRDYLAGDEYSIADIAIFPWVRRLE 82 (113)
T ss_pred HHHHHHHHHHHHHHHHH-HHHHccCCcccCCCCCeeeeeHHHHHHHHH
Confidence 34556778899999999 9999888999999 9999999988887764
No 25
>cd03192 GST_C_Sigma_like GST_C family, Class Sigma_like; composed of GSTs belonging to class Sigma and similar proteins, including GSTs from class Mu, Pi, and Alpha. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. Vertebrate class Sigma GSTs are characterized as GSH-dependent hematopoietic prostaglandin (PG) D synthases and are responsible for the production of PGD2 by catalyzing the isomerization of PGH2. The functions of PGD2 include the maintenance of body temperature, inhibition
Probab=98.43 E-value=6.7e-07 Score=50.79 Aligned_cols=48 Identities=23% Similarity=0.367 Sum_probs=40.0
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCC--CceeccC-chHHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGE--KKFFHGD-IGLVDIAFASIVYWLQII 60 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~--~~ff~G~-~g~~Di~~~~~~~w~~~~ 60 (66)
+.+....+.+...+..+ ++.|.+ ++|+.|+ +|++||++++++.|+...
T Consensus 35 ~~~~~~~~~~~~~l~~l-e~~l~~~~~~~~~G~~~s~aDi~l~~~~~~~~~~ 85 (104)
T cd03192 35 KKKEFLKEAIPKYLKKL-EKILKENGGGYLVGDKLTWADLVVFDVLDYLLYL 85 (104)
T ss_pred HHHHHHHHhhHHHHHHH-HHHHHHcCCCeeeCCCccHHHHHHHHHHHHHHhh
Confidence 34555677788999999 999976 7999999 999999999998887644
No 26
>cd03181 GST_C_EFB1gamma GST_C family, Gamma subunit of Elongation Factor 1B (EFB1gamma) subfamily; EF1Bgamma is part of the eukaryotic translation elongation factor-1 (EF1) complex which plays a central role in the elongation cycle during protein biosynthesis. EF1 consists of two functionally distinct units, EF1A and EF1B. EF1A catalyzes the GTP-dependent binding of aminoacyl-tRNA to the ribosomal A site concomitant with the hydrolysis of GTP. The resulting inactive EF1A:GDP complex is recycled to the active GTP form by the guanine-nucleotide exchange factor EF1B, a complex composed of at least two subunits, alpha and gamma. Metazoan EFB1 contain a third subunit, beta. The EF1B gamma subunit contains a GST fold consisting of an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain. The GST-like domain of EF1Bgamma is believed to mediate the dimerization of the EF1 complex, which in yeast is a dimer of the heterotrimer EF1A:EF1Balpha:EF1Bgamma. In addition to its role
Probab=98.43 E-value=1.2e-06 Score=50.97 Aligned_cols=46 Identities=22% Similarity=0.351 Sum_probs=39.9
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+..+...+.+.+.++.+ ++.|..++|+.|+ +|++||++++++.|..
T Consensus 36 ~~~~~~~~~~~~~l~~l-e~~l~~~~~l~G~~~siaDi~l~~~~~~~~ 82 (123)
T cd03181 36 KSVEAALEELDRVLGVL-EERLLKRTYLVGERLTLADIFVAGALLLGF 82 (123)
T ss_pred HHHHHHHHHHHHHHHHH-HHHHccCceeccCCccHHHHHHHHHHHHHH
Confidence 45667788899999999 9999888999999 9999999998887763
No 27
>cd03183 GST_C_Theta GST_C family, Class Theta subfamily; composed of eukaryotic class Theta GSTs and bacterial dichloromethane (DCM) dehalogenase. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. Mammalian class Theta GSTs show poor GSH conjugating activity towards the standard substrates, CDNB and ethacrynic acid, differentiating them from other mammalian GSTs. GSTT1-1 shows similar cataytic activity as bacterial DCM dehalogenase, catalyzing the GSH-dependent hydrolytic dehalogenatio
Probab=98.37 E-value=1.7e-06 Score=50.69 Aligned_cols=47 Identities=21% Similarity=0.337 Sum_probs=38.0
Q ss_pred hHHHHHHHHHHHHHHHHHHhcc-cCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 11 VQDQESTMKEILEMLKTVEEHG-LGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 11 ~ee~~~a~~~~~~~l~~l~e~~-l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
.+..+...+++.+.++.+ |+. +++++|+.|+ +|++||++++.+.|..
T Consensus 40 ~~~~~~~~~~~~~~l~~l-e~~l~~~~~~l~Gd~~t~ADi~l~~~~~~~~ 88 (126)
T cd03183 40 PEKVKKAEENLEESLDLL-ENYFLKDKPFLAGDEISIADLSAVCEIMQPE 88 (126)
T ss_pred HHHHHHHHHHHHHHHHHH-HHHHhcCCCcccCCCCCHHHHHHHHHHHHHH
Confidence 344566778899999999 876 4557999999 9999999988776664
No 28
>cd03210 GST_C_Pi GST_C family, Class Pi subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. Class Pi GST is a homodimeric eukaryotic protein. The human GSTP1 is mainly found in erythrocytes, kidney, placenta and fetal liver. It is involved in stress responses and in cellular proliferation pathways as an inhibitor of JNK (c-Jun N-terminal kinase). Following oxidative stress, monomeric GSTP1 dissociates from JNK and dimerizes, losing its ability to bind JNK and causing an incre
Probab=98.32 E-value=2.4e-06 Score=50.60 Aligned_cols=47 Identities=26% Similarity=0.401 Sum_probs=39.3
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCC---CceeccC-chHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGE---KKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~---~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
+.++...+++.+.+..+ |+.|.+ ++|+.|+ +|++||.+++++.|+..
T Consensus 31 ~~~~~~~~~~~~~l~~l-e~~L~~~~~~~~l~G~~~T~ADi~l~~~~~~~~~ 81 (126)
T cd03210 31 AGKDDYIKDLPEQLKPF-EKLLSKNNGKGFIVGDKISFADYNLFDLLDIHLV 81 (126)
T ss_pred HHHHHHHHHHHHHHHHH-HHHHHhCCCCCeeeCCCccHHHHHHHHHHHHHHH
Confidence 34566677788999999 988863 5899999 99999999998888764
No 29
>cd03191 GST_C_Zeta GST_C family, Class Zeta subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. Class Zeta GSTs, also known as maleylacetoacetate (MAA) isomerases, catalyze the isomerization of MAA to fumarylacetoacetate, the penultimate step in tyrosine/phenylalanine catabolism, using GSH as a cofactor. They show little GSH-conjugating activity towards traditional GST substrates, but display modest GSH peroxidase activity. They are also implicated in the detoxification of th
Probab=98.31 E-value=2.5e-06 Score=49.66 Aligned_cols=42 Identities=29% Similarity=0.287 Sum_probs=35.1
Q ss_pred HHHHHHHHHHHHHhcccC--CCceeccC-chHHHHHHHHHHHHHHH
Q 043560 17 TMKEILEMLKTVEEHGLG--EKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 17 a~~~~~~~l~~l~e~~l~--~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
..+.+.+.++.+ |+.|. .++|+.|+ +|++||++++++.|...
T Consensus 45 ~~~~~~~~l~~l-e~~L~~~~~~~l~G~~~t~ADi~~~~~~~~~~~ 89 (121)
T cd03191 45 YRHWIARGFAAL-EKLLAQTAGKFCFGDEPTLADICLVPQVYNARR 89 (121)
T ss_pred HHHHHHHHHHHH-HHHHHhcCCCeecCCcCCHHHHHHHHHHHHHHH
Confidence 345688889999 99986 35799999 99999999998887654
No 30
>cd03204 GST_C_GDAP1 GST_C family, Ganglioside-induced differentiation-associated protein 1 (GDAP1) subfamily; GDAP1 was originally identified as a highly expressed gene at the differentiated stage of GD3 synthase-transfected cells. More recently, mutations in GDAP1 have been reported to cause both axonal and demyelinating autosomal-recessive Charcot-Marie-Tooth (CMT) type 4A neuropathy. CMT is characterized by slow and progressive weakness and atrophy of muscles. Sequence analysis of GDAP1 shows similarities and differences with GSTs; it appears to contain both N-terminal thioredoxin-fold and C-terminal alpha helical domains of GSTs, however, it also contains additional C-terminal transmembrane domains unlike GSTs. GDAP1 is mainly expressed in neuronal cells and is localized in the mitochondria through its transmembrane domains. It does not exhibit GST activity using standard substrates.
Probab=98.28 E-value=2.4e-06 Score=50.83 Aligned_cols=47 Identities=23% Similarity=0.393 Sum_probs=39.7
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCC----------ceeccC-chHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEK----------KFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~----------~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
+..++..+++...+..+ |+.|.++ +|+.|+ +|++||++++++.|+..
T Consensus 25 ~~i~~~~~~l~~~l~~L-E~~L~~~~~~~~~~~~~~yL~Gd~~TlADi~l~~~l~~~~~ 82 (111)
T cd03204 25 EYLKKILDELEMVLDQV-EQELQRRKEETEEQKCQLWLCGDTFTLADISLGVTLHRLKF 82 (111)
T ss_pred HHHHHHHHHHHHHHHHH-HHHHHcCCcccccccCCCccCCCCCCHHHHHHHHHHHHHHH
Confidence 44577888999999999 8888643 699999 99999999998888764
No 31
>cd03198 GST_C_CLIC GST_C family, Chloride Intracellular Channel (CLIC) subfamily; composed of CLIC1-5, p64, parchorin, and similar proteins. They are auto-inserting, self-assembling intracellular anion channels involved in a wide variety of functions including regulated secretion, cell division, and apoptosis. They can exist in both water-soluble and membrane-bound states and are found in various vesicles and membranes. Biochemical studies of the C. elegans homolog, EXC-4, show that the membrane localization domain is present in the N-terminal part of the protein. The structure of soluble human CLIC1 reveals that it is monomeric and adopts a fold similar to GSTs, containing an N-terminal domain with a thioredoxin fold and a C-terminal alpha helical domain. Upon oxidation, the N-terminal domain of CLIC1 undergoes a structural change to form a non-covalent dimer stabilized by the formation of an intramolecular disulfide bond between two cysteines that are far apart in the reduced form. T
Probab=98.27 E-value=3e-06 Score=52.02 Aligned_cols=48 Identities=25% Similarity=0.400 Sum_probs=39.9
Q ss_pred hHHHHHHHHHHHHHHHHHHhcccCC----------------CceeccC-chHHHHHHHHHHHHHHH
Q 043560 11 VQDQESTMKEILEMLKTVEEHGLGE----------------KKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 11 ~ee~~~a~~~~~~~l~~l~e~~l~~----------------~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
.+..+...+.+.+.|+.| +..|.+ ++|+.|+ +|++||.++|.+.++..
T Consensus 24 ~~~~e~~~~~l~~~L~~l-d~~L~~~~~~~~~~~~~~~~~~~~fL~Gd~fTlADi~l~p~L~~~~~ 88 (134)
T cd03198 24 PALNENLEKGLLKALKKL-DDYLNSPLPDEIDSAEDEGVSQRKFLDGDELTLADCNLLPKLHIVKV 88 (134)
T ss_pred hhhhHHHHHHHHHHHHHH-HHHHccCccccccccccccccCCCCCCCCCCCHHHHHHHHHHHHHHH
Confidence 344566678899999999 999875 7899999 99999999998876654
No 32
>PRK09481 sspA stringent starvation protein A; Provisional
Probab=98.26 E-value=2.9e-06 Score=53.98 Aligned_cols=46 Identities=26% Similarity=0.496 Sum_probs=38.7
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+..+...+.+.+.+..+ ++.|.+++|+.|+ +|++||++++++.++.
T Consensus 123 ~~~~~~~~~l~~~l~~l-e~~L~~~~~l~G~~~t~AD~~l~~~~~~~~ 169 (211)
T PRK09481 123 SEADAARKQLREELLAI-APVFGEKPYFMSEEFSLVDCYLAPLLWRLP 169 (211)
T ss_pred HHHHHHHHHHHHHHHHH-HHHhccCCcccCCCccHHHHHHHHHHHHHH
Confidence 34556677888899999 9999888999999 9999999998876654
No 33
>cd03212 GST_C_Metaxin1_3 GST_C family, Metaxin subfamily, Metaxin 1-like proteins; composed of metaxins 1 and 3, and similar proteins. Mammalian metaxin (or metaxin 1) is a component of the preprotein import complex of the mitochondrial outer membrane. Metaxin extends to the cytosol and is anchored to the mitochondrial membrane through its C-terminal domain. In mice, metaxin is required for embryonic development. Like the murine gene, the human metaxin gene is located downstream to the glucocerebrosidase (GBA) pseudogene and is convergently transcribed. Inherited deficiency of GBA results in Gaucher disease, which presents many diverse clinical phenotypes. Alterations in the metaxin gene, in addition to GBA mutations, may be associated with Gaucher disease. Genome sequencing shows that a third metaxin gene also exists in zebrafish, Xenopus, chicken, and mammals.
Probab=98.23 E-value=3.7e-06 Score=51.25 Aligned_cols=44 Identities=25% Similarity=0.341 Sum_probs=37.4
Q ss_pred HHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
..++..+++.+.++.| ++.|++++||.|+ +|++|+.+++++.++
T Consensus 61 ~~~~~~~~a~~~l~~l-~~~L~~~~~~~Gd~~t~~D~~~~~~l~~~ 105 (137)
T cd03212 61 VEAEIYRDAKECLNLL-SQRLGESQFFFGDTPTSLDALVFGYLAPL 105 (137)
T ss_pred hHHHHHHHHHHHHHHH-HHHHCCCCcCCCCCCcHHHHHHHHHHHHH
Confidence 4566778888999999 9999999999999 999999998776433
No 34
>PRK10542 glutathionine S-transferase; Provisional
Probab=98.22 E-value=4.2e-06 Score=52.33 Aligned_cols=43 Identities=12% Similarity=0.387 Sum_probs=37.0
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+...+.+.+.++.+ |+.|++++|+.|+ +|++||++.+++.|..
T Consensus 123 ~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~s~ADi~l~~~~~~~~ 166 (201)
T PRK10542 123 PTVRAQLEKKFQYV-DEALADEQWICGQRFTIADAYLFTVLRWAY 166 (201)
T ss_pred HHHHHHHHHHHHHH-HHHhcCCCeeeCCCCcHHhHHHHHHHHHhh
Confidence 44567788999999 9999888999999 9999999998887764
No 35
>PRK10387 glutaredoxin 2; Provisional
Probab=98.22 E-value=1.5e-06 Score=54.70 Aligned_cols=43 Identities=19% Similarity=0.154 Sum_probs=37.7
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
++..+++++.|+.+ ++.|++ +|+.|+ +|++||++++++.|+..
T Consensus 141 ~~~~~~~~~~l~~l-e~~L~~-~~l~G~~~s~ADi~l~~~l~~~~~ 184 (210)
T PRK10387 141 PGLIKEINADLRAL-DPLIVK-PNAVNGELSTDDIHLFPILRNLTL 184 (210)
T ss_pred HHHHHHHHHHHHHH-HHHhcC-ccccCCCCCHHHHHHHHHHhccee
Confidence 45678899999999 999976 999999 99999999999988754
No 36
>PLN02473 glutathione S-transferase
Probab=98.22 E-value=4e-06 Score=53.07 Aligned_cols=43 Identities=19% Similarity=0.353 Sum_probs=35.9
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+....++...++.+ |+.|++++|+.|+ +|++||++++.+.|..
T Consensus 134 ~~~~~~~~~~l~~l-e~~L~~~~~l~Gd~~t~ADi~~~~~~~~~~ 177 (214)
T PLN02473 134 EELKVKFDKVLDVY-ENRLATNRYLGGDEFTLADLTHMPGMRYIM 177 (214)
T ss_pred HHHHHHHHHHHHHH-HHHhccCCcccCCCCCHHHHHHHHHHHHHH
Confidence 34456778889999 9999888999999 9999999988876653
No 37
>cd03211 GST_C_Metaxin2 GST_C family, Metaxin subfamily, Metaxin 2; a metaxin 1 binding protein identified through a yeast two-hybrid system using metaxin 1 as the bait. Metaxin 2 shares sequence similarity with metaxin 1 but does not contain a C-terminal mitochondrial outer membrane signal-anchor domain. It associates with mitochondrial membranes through its interaction with metaxin 1, which is a component of the mitochondrial preprotein import complex of the outer membrane. The biological function of metaxin 2 is unknown. It is likely that it also plays a role in protein translocation into the mitochondria. However, this has not been experimentally validated. In a recent proteomics study, it has been shown that metaxin 2 is overexpressed in response to lipopolysaccharide-induced liver injury.
Probab=98.19 E-value=4.6e-06 Score=50.07 Aligned_cols=44 Identities=16% Similarity=0.351 Sum_probs=37.6
Q ss_pred HHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
..++..+.+.+.++.| ++.|+++|||.|+ +|.+|+++++++.++
T Consensus 54 ~~ee~~~~~~~~l~aL-s~~Lg~~~~l~Gd~pT~~Da~vf~~la~~ 98 (126)
T cd03211 54 TLDQVIEEVDQCCQAL-SQRLGTQPYFFGDQPTELDALVFGHLFTI 98 (126)
T ss_pred CHHHHHHHHHHHHHHH-HHHHCCCCCCCCCCCcHHHHHHHHHHHHH
Confidence 3466677788899999 9999999999999 999999998887554
No 38
>PLN02395 glutathione S-transferase
Probab=98.15 E-value=6.7e-06 Score=51.98 Aligned_cols=43 Identities=23% Similarity=0.470 Sum_probs=36.2
Q ss_pred HHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 14 QESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 14 ~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
.+...+++.+.++.+ |+.|++++|+.|+ +|++||++++++.|+
T Consensus 132 ~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~s~ADi~l~~~~~~~ 175 (215)
T PLN02395 132 IKESEEKLAKVLDVY-EARLSKSKYLAGDFVSLADLAHLPFTEYL 175 (215)
T ss_pred HHHHHHHHHHHHHHH-HHHhcCCccccCCCcCHHHHHHHHHHHHH
Confidence 345567788899999 9999888999999 999999988877665
No 39
>COG0625 Gst Glutathione S-transferase [Posttranslational modification, protein turnover, chaperones]
Probab=98.10 E-value=8.9e-06 Score=51.51 Aligned_cols=48 Identities=27% Similarity=0.488 Sum_probs=40.8
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQII 60 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~~ 60 (66)
+..+.+.+++.+.++.+ +..|.+++|+.|+ +|++|+.+++.+.|+...
T Consensus 127 ~~~~~~~~~~~~~l~~l-e~~L~~~~~l~G~~~tiAD~~~~~~~~~~~~~ 175 (211)
T COG0625 127 AALEAARAEIRALLALL-EALLADGPYLAGDRFTIADIALAPLLWRLALL 175 (211)
T ss_pred HHHHHHHHHHHHHHHHH-HHHhccCCcccCCCCCHHHHHHHHHHHHhhhc
Confidence 34566778899999999 9999989999999 999999999888875543
No 40
>cd03200 GST_C_JTV1 GST_C family, JTV-1 subfamily; composed of uncharacterized proteins with similarity to the translation product of the human JTV-1 gene. Human JTV-1, a gene of unknown function, initiates within the human PMS2 gene promoter, but is transcribed from the opposite strand. PMS2 encodes a protein involved in DNA mismatch repair and is mutated in a subset of patients with hereditary nonpolyposis colon cancer. It is unknown whether the expression of JTV-1 affects that of PMS2, or vice versa, as a result of their juxtaposition. JTV-1 is up-regulated while PMS2 is down-regulated in tumor cell spheroids that show increased resistance to anticancer cytotoxic drugs compared with tumor cell monolayers indicating that suppressed DNA mismatch repair may be a mechanism for multicellular resistance to alkylating agents.
Probab=98.09 E-value=6.4e-06 Score=47.29 Aligned_cols=38 Identities=21% Similarity=0.334 Sum_probs=32.1
Q ss_pred HHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 19 KEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 19 ~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
++..+.++.+ ++.|.+++|+.|+ +|++||++++.+.|.
T Consensus 38 ~~~~~~l~~l-e~~L~~~~fl~Gd~~tiADi~l~~~l~~~ 76 (96)
T cd03200 38 KEKAAVLRAL-NSALGRSPWLVGSEFTVADIVSWCALLQT 76 (96)
T ss_pred HHHHHHHHHH-HHHHcCCCccCCCCCCHHHHHHHHHHHHc
Confidence 4566788889 8999888999999 999999999877553
No 41
>PRK13972 GSH-dependent disulfide bond oxidoreductase; Provisional
Probab=98.08 E-value=1.1e-05 Score=51.24 Aligned_cols=43 Identities=21% Similarity=0.339 Sum_probs=35.3
Q ss_pred HHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHH-HHH
Q 043560 14 QESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIV-YWL 57 (66)
Q Consensus 14 ~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~-~w~ 57 (66)
.+...+.+.+.+..+ |+.|.+++|+.|+ +|++||++++++ .|.
T Consensus 130 ~~~~~~~~~~~l~~l-e~~L~~~~~l~Gd~~t~ADi~l~~~~~~~~ 174 (215)
T PRK13972 130 IERYQVETQRLYHVL-NKRLENSPWLGGENYSIADIACWPWVNAWT 174 (215)
T ss_pred HHHHHHHHHHHHHHH-HHHhccCccccCCCCCHHHHHHHHHHHHHh
Confidence 344556788899999 9999888999999 999999988765 554
No 42
>cd03203 GST_C_Lambda GST_C family, Class Lambda subfamily; composed of plant-specific class Lambda GSTs. GSTs are cytosolic, usually dimeric, proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. The class Lambda subfamily was recently discovered, together with dehydroascorbate reductases (DHARs), as two outlying groups of the GST superfamily in Arabidopsis thaliana, which contain conserved active site cysteines. Characterization of recombinant A. thaliana proteins show that Lambda class GSTs are monomeric, similar
Probab=98.06 E-value=1.1e-05 Score=47.62 Aligned_cols=40 Identities=35% Similarity=0.588 Sum_probs=32.1
Q ss_pred HHHHHHHHHHHhcccC---CCceeccCchHHHHHHHHHHHHHHH
Q 043560 19 KEILEMLKTVEEHGLG---EKKFFHGDIGLVDIAFASIVYWLQI 59 (66)
Q Consensus 19 ~~~~~~l~~l~e~~l~---~~~ff~G~~g~~Di~~~~~~~w~~~ 59 (66)
+++.+.++.| |+.|+ +++|+.|.+|++||+++|++.++..
T Consensus 33 ~~~~~~l~~L-e~~L~~~~~~~fl~G~~tlADi~l~~~~~~~~~ 75 (120)
T cd03203 33 AEAAAALDYI-ENALSKFDDGPFFLGQFSLVDIAYVPFIERFQI 75 (120)
T ss_pred HHHHHHHHHH-HHHHHhcCCCCCcCCCccHHHHHHHHHHHHHHH
Confidence 3557778888 77775 4799988999999999998877654
No 43
>PRK11752 putative S-transferase; Provisional
Probab=98.04 E-value=1.2e-05 Score=53.22 Aligned_cols=42 Identities=24% Similarity=0.281 Sum_probs=35.0
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
++..+++.+.|+.+ |+.|.+++|+.|+ +|++||++++++.++
T Consensus 177 ~~~~~~~~~~L~~l-e~~L~~~~fl~Gd~~TlADi~l~~~l~~l 219 (264)
T PRK11752 177 NRFTMEAKRQLDVL-DKQLAEHEYIAGDEYTIADIAIWPWYGNL 219 (264)
T ss_pred HHHHHHHHHHHHHH-HHHhccCCCCCCCccCHHHHHHHHHHHHH
Confidence 34456678899999 9999888999999 999999998876554
No 44
>TIGR02182 GRXB Glutaredoxin, GrxB family. This model includes the highly abundant E. coli GrxB (Grx2) glutaredoxin which is notably longer than either GrxA or GrxC. Unlike the other two E. coli glutaredoxins, GrxB appears to be unable to reduce ribonucleotide reductase, and may have more to do with resistance to redox stress.
Probab=98.04 E-value=4.1e-06 Score=53.51 Aligned_cols=44 Identities=16% Similarity=0.228 Sum_probs=36.7
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccCchHHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGDIGLVDIAFASIVYWLQI 59 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~~g~~Di~~~~~~~w~~~ 59 (66)
++..+++++.++.+ ++.|++++|++|++|++||++++++.|+..
T Consensus 140 ~~~~~~~~~~l~~l-e~~L~~~~~l~g~~TiADi~l~~~l~~~~~ 183 (209)
T TIGR02182 140 PGLLEEINADLEEL-DKLIDGPNAVNGELSEDDILVFPLLRNLTL 183 (209)
T ss_pred HHHHHHHHHHHHHH-HHHHhCccccCCCCCHHHHHHHHHhcCeee
Confidence 45678889999999 999999999854499999999988877653
No 45
>cd03205 GST_C_6 GST_C family, unknown subfamily 6; composed of uncharacterized bacterial proteins with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=98.04 E-value=2e-05 Score=44.63 Aligned_cols=44 Identities=27% Similarity=0.320 Sum_probs=37.3
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
+..+...+.+.+.++.+ |+.|++++| + +|++||.+++.+.|...
T Consensus 33 ~~~~~~~~~~~~~l~~l-e~~L~~~~~---d~~TlADi~l~~~l~~~~~ 77 (98)
T cd03205 33 PWLERQRGKIERALDAL-EAELAKLPL---DPLDLADIAVACALGYLDF 77 (98)
T ss_pred HHHHHHHHHHHHHHHHH-HHhhhhCCC---CCCCHHHHHHHHHHHHHHh
Confidence 44566788899999999 999988887 8 99999999998877753
No 46
>cd03195 GST_C_4 GST_C family, unknown subfamily 4; composed of uncharacterized proteins with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=98.03 E-value=1.1e-05 Score=47.23 Aligned_cols=47 Identities=15% Similarity=0.139 Sum_probs=39.6
Q ss_pred HHHHHHHHHHHHHHHHHhcccC-CCceeccCchHHHHHHHHHHHHHHHH
Q 043560 13 DQESTMKEILEMLKTVEEHGLG-EKKFFHGDIGLVDIAFASIVYWLQII 60 (66)
Q Consensus 13 e~~~a~~~~~~~l~~l~e~~l~-~~~ff~G~~g~~Di~~~~~~~w~~~~ 60 (66)
.++...+++.+.+..+ |..|. +++|+.|++|.+|+.+++++.|....
T Consensus 39 ~~~~~~~~~~~~~~~l-e~~l~~~~~~l~G~fSiAD~~l~~~~~~~~~~ 86 (114)
T cd03195 39 LSEAAQAAAEKLIAVA-EALLPPGAANLFGEWCIADTDLALMLNRLVLN 86 (114)
T ss_pred CCHHHHHHHHHHHHHH-HHHHhcCCCcccCCccHHHHHHHHHHHHHHHc
Confidence 4567788889999999 88885 55899989999999999999998654
No 47
>cd03208 GST_C_Alpha GST_C family, Class Alpha subfamily; GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain. The class Alpha subfamily is composed of vertebrate GSTs which can form homodimer and heterodimers. There are at least six types of class Alpha GST subunits in rats, four of which have human counterparts, resulting in many possible isoenzymes with different activities, tissue distribution and substrate specificities. Human GSTA1-1 and GSTA2-2 show high GSH peroxidase activity. GS
Probab=98.02 E-value=2.2e-05 Score=47.55 Aligned_cols=39 Identities=15% Similarity=0.254 Sum_probs=33.2
Q ss_pred HHHHHHHHHHhcccC--CCceeccC-chHHHHHHHHHHHHHHH
Q 043560 20 EILEMLKTVEEHGLG--EKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 20 ~~~~~l~~l~e~~l~--~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
.+...+..| |+.|. +++|+.|+ +|++|+.+++++.|+..
T Consensus 43 ~~~~~l~~l-E~~L~~~~~~~l~G~~~T~ADi~l~~~l~~~~~ 84 (137)
T cd03208 43 AKNRYFPVF-EKVLKSHGQDFLVGNKLSRADIHLLEAILMVEE 84 (137)
T ss_pred HHHHHHHHH-HHHHHhCCCCeeeCCCCCHHHHHHHHHHHHHHH
Confidence 346788999 99887 67899999 99999999988888754
No 48
>PLN02378 glutathione S-transferase DHAR1
Probab=97.99 E-value=1.7e-05 Score=50.73 Aligned_cols=43 Identities=28% Similarity=0.543 Sum_probs=35.8
Q ss_pred HHHHHHHHHHHHHHHhcccC--CCceeccC-chHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLG--EKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~--~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
+...+.+.+.+..+ |+.|. +++|+.|+ +|++||++++.+.|+.
T Consensus 117 ~~~~~~~~~~l~~l-e~~L~~~~~~fl~Gd~~T~ADi~l~~~~~~l~ 162 (213)
T PLN02378 117 DGSEHALLVELEAL-ENHLKSHDGPFIAGERVSAVDLSLAPKLYHLQ 162 (213)
T ss_pred hHHHHHHHHHHHHH-HHHHhcCCCCCcCCCCCchhhHHHHHHHHHHH
Confidence 34556788889999 88886 47999999 9999999999877654
No 49
>TIGR01262 maiA maleylacetoacetate isomerase. Maleylacetoacetate isomerase is an enzyme of tyrosine and phenylalanine catabolism. It requires glutathione and belongs by homology to the zeta family of glutathione S-transferases. The enzyme (EC 5.2.1.2) is described as active also on maleylpyruvate, and the example from a Ralstonia sp. catabolic plasmid is described as a maleylpyruvate isomerase involved in gentisate catabolism.
Probab=97.93 E-value=3.2e-05 Score=48.60 Aligned_cols=42 Identities=24% Similarity=0.213 Sum_probs=35.0
Q ss_pred HHHHHHHHHHHHHhcccCC--CceeccC-chHHHHHHHHHHHHHHH
Q 043560 17 TMKEILEMLKTVEEHGLGE--KKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 17 a~~~~~~~l~~l~e~~l~~--~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
..+.+.+.++.+ |+.|.+ ++|+.|+ +|+|||.+.+++.|...
T Consensus 130 ~~~~~~~~l~~l-e~~L~~~~~~~l~G~~~T~ADi~~~~~l~~~~~ 174 (210)
T TIGR01262 130 YQHWISKGFAAL-EALLQPHAGAFCVGDTPTLADLCLVPQVYNAER 174 (210)
T ss_pred HHHHHHHHHHHH-HHHHhcCCCCEeeCCCCCHHHHHHHHHHHHHHH
Confidence 345688899999 999975 5799999 99999999998877653
No 50
>PF14497 GST_C_3: Glutathione S-transferase, C-terminal domain; PDB: 3AY8_A 2UZ8_B 1V2A_C 2HNL_A 2YV9_B 3H1N_A 3FR6_A 1Q4J_B 1PA3_B 1OKT_B ....
Probab=97.91 E-value=1.7e-05 Score=45.06 Aligned_cols=42 Identities=31% Similarity=0.449 Sum_probs=33.0
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCc--eeccC-chHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKK--FFHGD-IGLVDIAFASIV 54 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~--ff~G~-~g~~Di~~~~~~ 54 (66)
...+...+++.+.+..+ ++.|.+++ |+.|+ ||++|+++.+++
T Consensus 31 ~~~~~~~~~~~~~l~~l-~~~L~~~~~~~l~G~~~T~AD~~v~~~l 75 (99)
T PF14497_consen 31 ASGDFSREELPKALKIL-EKHLAERGGDFLVGDKPTLADIAVFGFL 75 (99)
T ss_dssp CHHHHHHHHHHHHHHHH-HHHHHHTSSSSSSSSS--HHHHHHHHHH
T ss_pred hhHHhhHHHHHHHHHHH-HHHHHcCCCeeecCCCCCHHHHHHHHHH
Confidence 34566778899999999 99997655 99999 999999987755
No 51
>PTZ00057 glutathione s-transferase; Provisional
Probab=97.87 E-value=3.8e-05 Score=48.74 Aligned_cols=42 Identities=19% Similarity=0.213 Sum_probs=34.4
Q ss_pred HHHHHHHHHHHHHHhcccCC--CceeccC-chHHHHHHHHHHHHHH
Q 043560 16 STMKEILEMLKTVEEHGLGE--KKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 16 ~a~~~~~~~l~~l~e~~l~~--~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
...+.+.+.+..+ |+.|.+ ++|+.|+ +|+||+.+++++.|+.
T Consensus 123 ~~~~~~~~~l~~l-e~~L~~~~~~~l~Gd~~T~AD~~l~~~~~~~~ 167 (205)
T PTZ00057 123 FLNEELPKWSGYF-ENILKKNHCNYFVGDNLTYADLAVFNLYDDIE 167 (205)
T ss_pred HHHHHHHHHHHHH-HHHHHhCCCCeeeCCcccHHHHHHHHHHHHHH
Confidence 3456778888999 888864 3899999 9999999998887765
No 52
>PRK10357 putative glutathione S-transferase; Provisional
Probab=97.82 E-value=7.1e-05 Score=46.92 Aligned_cols=43 Identities=26% Similarity=0.291 Sum_probs=36.1
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
+...+++...++.+ |+.|.+++ +.|+ +|++||.+++.+.|...
T Consensus 124 ~~~~~~l~~~l~~l-e~~L~~~~-l~Gd~~t~ADi~l~~~l~~~~~ 167 (202)
T PRK10357 124 LRQREKINRSLDAL-EGYLVDGT-LKTDTVNLATIAIACAVGYLNF 167 (202)
T ss_pred HHHHHHHHHHHHHH-HHhhccCc-ccCCCcCHHHHHHHHHHHHHHh
Confidence 45567788999999 99998777 9999 99999999998877643
No 53
>PLN02817 glutathione dehydrogenase (ascorbate)
Probab=97.73 E-value=7.4e-05 Score=49.96 Aligned_cols=41 Identities=24% Similarity=0.530 Sum_probs=34.1
Q ss_pred HHHHHHHHHHHHhcccCC-CceeccC-chHHHHHHHHHHHHHHH
Q 043560 18 MKEILEMLKTVEEHGLGE-KKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 18 ~~~~~~~l~~l~e~~l~~-~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
.+++.+.+..+ |+.|.+ ++|+.|+ +|+|||++++.+.++..
T Consensus 173 ~~~l~~~l~~L-E~~L~~~g~yl~Gd~~SlADi~l~p~L~~l~~ 215 (265)
T PLN02817 173 EQALLDELTSF-DDYIKENGPFINGEKISAADLSLGPKLYHLEI 215 (265)
T ss_pred HHHHHHHHHHH-HHHHhcCCCeeCCCCCCHHHHHHHHHHHHHHH
Confidence 45678889999 888864 6999999 99999999998866643
No 54
>cd03194 GST_C_3 GST_C family, unknown subfamily 3; composed of uncharacterized proteins with similarity to GSTs. GSTs are cytosolic dimeric proteins involved in cellular detoxification by catalyzing the conjugation of glutathione (GSH) with a wide range of endogenous and xenobiotic alkylating agents, including carcinogens, therapeutic drugs, environmental toxins, and products of oxidative stress. GSTs also show GSH peroxidase activity and are involved in the synthesis of prostaglandins and leukotrienes. The GST fold contains an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain, with an active site located in a cleft between the two domains. GSH binds to the N-terminal domain while the hydrophobic substrate occupies a pocket in the C-terminal domain.
Probab=97.62 E-value=0.00029 Score=41.27 Aligned_cols=45 Identities=22% Similarity=0.344 Sum_probs=31.1
Q ss_pred HHHHHHHHHHHHHHHHhccc---CCCceeccCchHHHHHHHHHHHHHHH
Q 043560 14 QESTMKEILEMLKTVEEHGL---GEKKFFHGDIGLVDIAFASIVYWLQI 59 (66)
Q Consensus 14 ~~~a~~~~~~~l~~l~e~~l---~~~~ff~G~~g~~Di~~~~~~~w~~~ 59 (66)
++...+.+.+.+..+ +..+ .+++|+.|++|++||.+++++.|...
T Consensus 39 ~~~~~~~~~~~~~~l-e~~l~~~~~~~yl~Gd~T~ADi~l~~~~~~~~~ 86 (114)
T cd03194 39 SEAVQADIARIEAIW-AECLARFQGGPFLFGDFSIADAFFAPVVTRFRT 86 (114)
T ss_pred CHHHHHHHHHHHHHH-HHHHHHcCCCCCCCCCCcHHHHHHHHHHHHHHH
Confidence 344445455555555 4444 45789987899999999998888754
No 55
>PRK15113 glutathione S-transferase; Provisional
Probab=97.56 E-value=0.00025 Score=45.15 Aligned_cols=44 Identities=16% Similarity=0.198 Sum_probs=35.7
Q ss_pred HHHHHHHHHHHHHHHHhcccCC-CceeccCchHHHHHHHHHHHHHH
Q 043560 14 QESTMKEILEMLKTVEEHGLGE-KKFFHGDIGLVDIAFASIVYWLQ 58 (66)
Q Consensus 14 ~~~a~~~~~~~l~~l~e~~l~~-~~ff~G~~g~~Di~~~~~~~w~~ 58 (66)
.++..+.+.+.++.+ |+.|.+ ++|+.|++|+|||++++++.|+.
T Consensus 135 ~~~~~~~~~~~l~~l-e~~L~~~~~~l~G~~TlADi~l~~~l~~~~ 179 (214)
T PRK15113 135 SEAGKAAAEKLFAVA-ERLLAPGQPNLFGEWCIADTDLALMLNRLV 179 (214)
T ss_pred cHHHHHHHHHHHHHH-HHHHhcCCCEeeCCccHHHHHHHHHHHHHH
Confidence 355667788999999 888864 47887779999999999887764
No 56
>cd03197 GST_C_mPGES2 GST_C family; microsomal Prostaglandin E synthase Type 2 (mPGES2) subfamily; mPGES2 is a membrane-anchored dimeric protein containing a CXXC motif which catalyzes the isomerization of PGH2 to PGE2. Unlike cytosolic PGE synthase (cPGES) and microsomal PGES Type 1 (mPGES1), mPGES2 does not require glutathione (GSH) for its activity, although its catalytic rate is increased two- to four-fold in the presence of DTT, GSH, or other thiol compounds. PGE2 is widely distributed in various tissues and is implicated in the sleep/wake cycle, relaxation/contraction of smooth muscle, excretion of sodium ions, maintenance of body temperature, and mediation of inflammation. mPGES2 contains an N-terminal hydrophobic domain which is membrane associated and a C-terminal soluble domain with a GST-like structure. The C-terminus contains two structural domains a N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain. The GST active site is located in a cleft between t
Probab=97.06 E-value=0.0027 Score=39.75 Aligned_cols=40 Identities=20% Similarity=0.321 Sum_probs=25.5
Q ss_pred HHHHHHHHHHHHhccc-CCCceeccC-chHHHHHHHHHHHHHH
Q 043560 18 MKEILEMLKTVEEHGL-GEKKFFHGD-IGLVDIAFASIVYWLQ 58 (66)
Q Consensus 18 ~~~~~~~l~~l~e~~l-~~~~ff~G~-~g~~Di~~~~~~~w~~ 58 (66)
.+.+.+.+.-. -+.+ .+++|++|+ +|+|||++.+++..+.
T Consensus 81 r~~L~~a~~~w-~~~~~~~~~FlaGd~ptIADisvyg~l~s~e 122 (149)
T cd03197 81 REWLYDALNTW-VAALGKDRQFHGGSKPNLADLAVYGVLRSVE 122 (149)
T ss_pred HHHHHHHHHHH-HHHhcCCCCccCCCCCCHHHHHHHHHHHHHH
Confidence 33444444433 2333 346899999 9999999877654433
No 57
>KOG4420 consensus Uncharacterized conserved protein (Ganglioside-induced differentiation associated protein 1, GDAP1) [Function unknown]
Probab=96.77 E-value=0.0044 Score=42.51 Aligned_cols=47 Identities=19% Similarity=0.343 Sum_probs=37.2
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCC----CceeccC-chHHHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGE----KKFFHGD-IGLVDIAFASIVYWLQI 59 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~----~~ff~G~-~g~~Di~~~~~~~w~~~ 59 (66)
..-.+...++...|+-. |.+|.+ .+|+.|+ +|+|||.+++.+..++-
T Consensus 201 s~lkkild~l~~~Ld~V-EteLe~r~~~~~wL~G~efslADVsLg~~LhRL~~ 252 (325)
T KOG4420|consen 201 SYLKKILDELAMVLDQV-ETELEKRKLCELWLCGCEFSLADVSLGATLHRLKF 252 (325)
T ss_pred HHHHHHHHHHHHHHHHH-HHHHhhccccceeeccccchHHHHHHHHHHHHHHH
Confidence 34456667777777777 777765 5899999 99999999999977764
No 58
>PLN02907 glutamate-tRNA ligase
Probab=96.63 E-value=0.003 Score=47.67 Aligned_cols=34 Identities=26% Similarity=0.309 Sum_probs=29.3
Q ss_pred HHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHH
Q 043560 20 EILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIV 54 (66)
Q Consensus 20 ~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~ 54 (66)
++.+.++.| ++.|+.++|+.|+ +|+|||++++.+
T Consensus 94 ~l~~~L~~L-E~~L~~rtYLvGd~lTLADIaL~~~L 128 (722)
T PLN02907 94 EFENACEYV-DGYLASRTFLVGYSLTIADIAIWSGL 128 (722)
T ss_pred HHHHHHHHH-HHHhccCCeecCCCCCHHHHHHHHHH
Confidence 456678899 9999888999999 999999987655
No 59
>KOG0867 consensus Glutathione S-transferase [Posttranslational modification, protein turnover, chaperones]
Probab=96.51 E-value=0.0074 Score=39.32 Aligned_cols=45 Identities=20% Similarity=0.326 Sum_probs=38.3
Q ss_pred HHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 12 QDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 12 ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
...+....+++..+.++ |+.|.+++|+.|+ +|++|+.+++-+..+
T Consensus 129 ~~~~~~~~~~~~~~~~~-e~~l~~~~yl~g~~~tlADl~~~~~~~~~ 174 (226)
T KOG0867|consen 129 TAVKELEAKLRKALDNL-ERFLKTQVYLAGDQLTLADLSLASTLSQF 174 (226)
T ss_pred hhhHHHHHHHHHHHHHH-HHHHccCCcccCCcccHHHHHHhhHHHHH
Confidence 44566678899999999 9999988999999 999999998866554
No 60
>COG0435 ECM4 Predicted glutathione S-transferase [Posttranslational modification, protein turnover, chaperones]
Probab=96.36 E-value=0.0021 Score=44.28 Aligned_cols=47 Identities=23% Similarity=0.461 Sum_probs=41.1
Q ss_pred ChHHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHHH
Q 043560 10 SVQDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYWL 57 (66)
Q Consensus 10 ~~ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w~ 57 (66)
.++.-+++.+++.+.|+.| |+.|+++.|+.|+ ++-|||-+.+-+..|
T Consensus 199 tq~aYeea~~~lF~~Ld~l-E~~L~~~ryl~Gd~lTEAD~RLftTlvRF 246 (324)
T COG0435 199 TQEAYEEAVKKLFEALDKL-EQILSERRYLTGDQLTEADIRLFTTLVRF 246 (324)
T ss_pred hHHHHHHHHHHHHHHHHHH-HHHhhcCeeeccccchHhhhhhhheeEee
Confidence 4677889999999999999 9999999999999 999999988755433
No 61
>KOG3029 consensus Glutathione S-transferase-related protein [General function prediction only]
Probab=94.40 E-value=0.05 Score=37.92 Aligned_cols=42 Identities=12% Similarity=0.245 Sum_probs=27.7
Q ss_pred HHHHHHHHHHHhccc-CCCceeccC-chHHHHHHHHHHHHHHHHH
Q 043560 19 KEILEMLKTVEEHGL-GEKKFFHGD-IGLVDIAFASIVYWLQIIE 61 (66)
Q Consensus 19 ~~~~~~l~~l~e~~l-~~~~ff~G~-~g~~Di~~~~~~~w~~~~e 61 (66)
+++.+..+.. -..+ +++||.||+ ++++|..+..+++-++..+
T Consensus 291 e~lydA~d~W-vaalgknr~flGG~kPnLaDLsvfGvl~sm~gc~ 334 (370)
T KOG3029|consen 291 EHLYDAADQW-VAALGKNRPFLGGKKPNLADLSVFGVLRSMEGCQ 334 (370)
T ss_pred HHHHHHHHHH-HHHhCCCCCccCCCCCchhhhhhhhhhhHhhhhh
Confidence 3344444433 3344 357999999 9999999988776555443
No 62
>KOG3027 consensus Mitochondrial outer membrane protein Metaxin 2, Metaxin 1-binding protein [Cell wall/membrane/envelope biogenesis; Intracellular trafficking, secretion, and vesicular transport]
Probab=93.95 E-value=0.16 Score=33.96 Aligned_cols=44 Identities=14% Similarity=0.292 Sum_probs=35.9
Q ss_pred ChHHHHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHH
Q 043560 10 SVQDQESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIV 54 (66)
Q Consensus 10 ~~ee~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~ 54 (66)
+....++..+++..+.+.| +.+|+.+|||.|+ ++=+|..+...+
T Consensus 171 ~~~~~DqVie~vdkc~~aL-sa~L~~q~yf~g~~P~elDAlvFGHl 215 (257)
T KOG3027|consen 171 DDKTMDQVIEQVDKCCRAL-SAQLGSQPYFTGDQPTELDALVFGHL 215 (257)
T ss_pred ccccHHHHHHHHHHHHHHH-HHHhcCCCccCCCCccHHHHHHHhhh
Confidence 3345677788889999999 9999999999999 999998765443
No 63
>KOG4244 consensus Failed axon connections (fax) protein/glutathione S-transferase-like protein [Signal transduction mechanisms]
Probab=93.27 E-value=0.062 Score=36.76 Aligned_cols=39 Identities=26% Similarity=0.373 Sum_probs=32.3
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIV 54 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~ 54 (66)
++..+-++.-|+.+ ++.|++++|+.|+ ++-+|.++.+.+
T Consensus 202 ~Ei~ell~rDlr~i-~~~Lg~KkflfGdkit~~DatvFgqL 241 (281)
T KOG4244|consen 202 AEIDELLHRDLRAI-SDYLGDKKFLFGDKITPADATVFGQL 241 (281)
T ss_pred HHHHHHHHHHHHHH-HHHhCCCccccCCCCCcceeeehhhh
Confidence 33556677889999 9999999999999 999999987644
No 64
>PF14834 GST_C_4: Glutathione S-transferase, C-terminal domain; PDB: 3BBY_A.
Probab=92.64 E-value=0.44 Score=28.87 Aligned_cols=43 Identities=16% Similarity=0.254 Sum_probs=29.3
Q ss_pred HHHHHHHHHHHHHHHhcccCC-CceeccCchHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGE-KKFFHGDIGLVDIAFASIVYWLQ 58 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~-~~ff~G~~g~~Di~~~~~~~w~~ 58 (66)
+.+.+++...+... +..|.. ++++-|+.|++|.-+++++..+.
T Consensus 42 ~~a~~~a~kL~~~a-~~ll~~g~~~LFGewsIAD~dlA~ml~Rl~ 85 (117)
T PF14834_consen 42 EAAQAAAQKLIAVA-ERLLADGGPNLFGEWSIADADLALMLNRLV 85 (117)
T ss_dssp HHHHHHHHHHHHHH-HHHTTT--SSTTSS--HHHHHHHHHHHHHH
T ss_pred HHHHHHHHHHHHHH-HHHhccCCCCccccchHHHHHHHHHHHHHH
Confidence 34445555666666 666654 68999999999999999987664
No 65
>KOG1422 consensus Intracellular Cl- channel CLIC, contains GST domain [Inorganic ion transport and metabolism]
Probab=92.31 E-value=0.16 Score=33.69 Aligned_cols=43 Identities=23% Similarity=0.441 Sum_probs=33.0
Q ss_pred HHHHHHHHHHHHHhcccCC---CceeccC-chHHHHHHHHHHHHHHHH
Q 043560 17 TMKEILEMLKTVEEHGLGE---KKFFHGD-IGLVDIAFASIVYWLQII 60 (66)
Q Consensus 17 a~~~~~~~l~~l~e~~l~~---~~ff~G~-~g~~Di~~~~~~~w~~~~ 60 (66)
.-+.+...+..| ++.|+. ++|+.|| +|.+|.-+.|=++-+++.
T Consensus 124 ~e~~Ll~~L~~L-d~yL~sp~~~~Fl~Gd~lt~aDcsLlPKL~~i~va 170 (221)
T KOG1422|consen 124 LEKALLKELEKL-DDYLKSPSRRKFLDGDKLTLADCSLLPKLHHIKVA 170 (221)
T ss_pred HHHHHHHHHHHH-HHHhcCccCCccccCCeeeeehhhhchhHHHHHHH
Confidence 345566777888 999974 7999999 999999977766555543
No 66
>KOG2903 consensus Predicted glutathione S-transferase [Posttranslational modification, protein turnover, chaperones]
Probab=91.41 E-value=0.22 Score=34.39 Aligned_cols=44 Identities=25% Similarity=0.450 Sum_probs=36.8
Q ss_pred ChHHHHHHHHHHHHHHHHHHhcccCCC--ceeccC-chHHHHHHHHHH
Q 043560 10 SVQDQESTMKEILEMLKTVEEHGLGEK--KFFHGD-IGLVDIAFASIV 54 (66)
Q Consensus 10 ~~ee~~~a~~~~~~~l~~l~e~~l~~~--~ff~G~-~g~~Di~~~~~~ 54 (66)
.+|.=+++++++.+.|+.+ |+.|+++ +|.-|+ ++-+||-+.+-+
T Consensus 197 ~~e~Ye~~V~~lfe~LDr~-E~vL~~~~~~f~~G~~LTeaDirLy~Ti 243 (319)
T KOG2903|consen 197 KQEAYEEEVNQLFEALDRC-EDVLGKNRKYFLCGDTLTEADIRLYTTI 243 (319)
T ss_pred ccchHHHHHHHHHHHHHHH-HHHHhcccceEeeccccchhheeeeeeE
Confidence 4566788899999999999 9999864 589999 999999876543
No 67
>KOG1695 consensus Glutathione S-transferase [Posttranslational modification, protein turnover, chaperones]
Probab=91.08 E-value=0.42 Score=31.29 Aligned_cols=37 Identities=22% Similarity=0.320 Sum_probs=27.2
Q ss_pred HHHHHHHHHHHHhcccC--CCceeccC-chHHHHHHHHHHH
Q 043560 18 MKEILEMLKTVEEHGLG--EKKFFHGD-IGLVDIAFASIVY 55 (66)
Q Consensus 18 ~~~~~~~l~~l~e~~l~--~~~ff~G~-~g~~Di~~~~~~~ 55 (66)
..+....+..+ ++.|. ++.|+.|+ +|++|+++.-.+.
T Consensus 125 ~Pa~~~~~~~~-~~~L~~~~sgflvGd~lT~aDl~i~e~l~ 164 (206)
T KOG1695|consen 125 LPAKPKYFKIL-EKILKKNKSGFLVGDKLTWADLVIAEHLD 164 (206)
T ss_pred ccchHHHHHHH-HHHHHhCCCCeeecCcccHHHHHHHHHHH
Confidence 33555667777 77776 35799999 9999999765553
No 68
>KOG3028 consensus Translocase of outer mitochondrial membrane complex, subunit TOM37/Metaxin 1 [Intracellular trafficking, secretion, and vesicular transport]
Probab=90.45 E-value=1 Score=31.39 Aligned_cols=42 Identities=29% Similarity=0.396 Sum_probs=35.1
Q ss_pred HHHHHHHHHHHHHHHHhcccCCCceeccC-chHHHHHHHHHHHH
Q 043560 14 QESTMKEILEMLKTVEEHGLGEKKFFHGD-IGLVDIAFASIVYW 56 (66)
Q Consensus 14 ~~~a~~~~~~~l~~l~e~~l~~~~ff~G~-~g~~Di~~~~~~~w 56 (66)
.+...+...+++..| .+.|+++.||-|+ ++-.|.-+.+++..
T Consensus 161 e~~i~~~Aska~~~L-S~~Lgs~kffFgd~psslDa~lfs~la~ 203 (313)
T KOG3028|consen 161 EDQIYKDASKALNLL-STLLGSKKFFFGDKPSSLDALLFSYLAI 203 (313)
T ss_pred HHHHHHHHHHHHHHH-HHHhcCceEeeCCCCchHHHHHHHHHHH
Confidence 455567788889999 9999999999999 99999998877644
No 69
>KOG0868 consensus Glutathione S-transferase [Posttranslational modification, protein turnover, chaperones]
Probab=89.29 E-value=0.39 Score=31.59 Aligned_cols=37 Identities=24% Similarity=0.398 Sum_probs=29.3
Q ss_pred HHHHHHHHHHHHhcccCC--CceeccC-chHHHHHHHHHHH
Q 043560 18 MKEILEMLKTVEEHGLGE--KKFFHGD-IGLVDIAFASIVY 55 (66)
Q Consensus 18 ~~~~~~~l~~l~e~~l~~--~~ff~G~-~g~~Di~~~~~~~ 55 (66)
..-+.+++..| |+.|.. +.|-.|| ++++|+++.|..+
T Consensus 134 q~~ItkGF~AL-EklL~~~aGkycvGDevtiADl~L~pqv~ 173 (217)
T KOG0868|consen 134 QHFITKGFTAL-EKLLKSHAGKYCVGDEVTIADLCLPPQVY 173 (217)
T ss_pred HHHHHHhHHHH-HHHHHHccCCcccCceeehhhhccchhhh
Confidence 34466778888 888853 6799999 9999999998764
No 70
>PF04399 Glutaredoxin2_C: Glutaredoxin 2, C terminal domain; InterPro: IPR007494 Glutaredoxins [, , ], also known as thioltransferases (disulphide reductases, are small proteins of approximately one hundred amino-acid residues which utilise glutathione and NADPH as cofactors. Oxidized glutathione is regenerated by glutathione reductase. Together these components compose the glutathione system []. Glutaredoxin functions as an electron carrier in the glutathione-dependent synthesis of deoxyribonucleotides by the enzyme ribonucleotide reductase. Like thioredoxin, which functions in a similar way, glutaredoxin possesses an active centre disulphide bond []. It exists in either a reduced or an oxidized form where the two cysteine residues are linked in an intramolecular disulphide bond. Glutaredoxin has been sequenced in a variety of species. On the basis of extensive sequence similarity, it has been proposed [] that Vaccinia virus protein O2L is most probably a glutaredoxin. Finally, it must be noted that Bacteriophage T4 thioredoxin seems also to be evolutionary related. In position 5 of the pattern T4 thioredoxin has Val instead of Pro. Unlike other glutaredoxins, glutaredoxin 2 (Grx2) cannot reduce ribonucleotide reductase. Grx2 has significantly higher catalytic activity in the reduction of mixed disulphides with glutathione (GSH) compared with other glutaredoxins. The active site residues (Cys9-Pro10-Tyr11-Cys12, in Escherichia coli Grx2, P39811 from SWISSPROT), which are found at the interface between the N- and C-terminal domains are identical to other glutaredoxins, but there is no other similarity between glutaredoxin 2 and other glutaredoxins. Grx2 is structurally similar to glutathione-S-transferases (GST), but there is no obvious sequence similarity. The inter-domain contacts are mainly hydrophobic, suggesting that the two domains are unlikely to be stable on their own. Both domains are needed for correct folding and activity of Grx2. It is thought that the primary function of Grx2 is to catalyse reversible glutathionylation of proteins with GSH in cellular redox regulation including the response to oxidative stress. The N-terminal domain is IPR004045 from INTERPRO.; PDB: 1G7O_A 3IR4_A.
Probab=86.42 E-value=3 Score=25.53 Aligned_cols=44 Identities=23% Similarity=0.296 Sum_probs=28.3
Q ss_pred HHHHHHHHHHHHHHHhcccCCCceeccCchHHHHHHHHHHHHHHH
Q 043560 15 ESTMKEILEMLKTVEEHGLGEKKFFHGDIGLVDIAFASIVYWLQI 59 (66)
Q Consensus 15 ~~a~~~~~~~l~~l~e~~l~~~~ff~G~~g~~Di~~~~~~~w~~~ 59 (66)
.+..+++...|..+ +..+......+|.+|+-||.+.|+++-+..
T Consensus 58 ~~~i~~l~~~L~~L-e~ll~~~~~~n~~LS~dDi~lFp~LR~Lti 101 (132)
T PF04399_consen 58 PELIAELNADLEEL-EPLLASPNAVNGELSIDDIILFPILRSLTI 101 (132)
T ss_dssp HHHHHHHHHHHHHH-HHH-SCTTBTTSS--HHHHHHHHHHHHHCT
T ss_pred HHHHHHHHHHHHHH-HHHhccccccCCCCCHHHHHHHHHHhhhhh
Confidence 45567788888888 777764333333499999999998875543
No 71
>cd03199 GST_C_GRX2 GST_C family, Glutaredoxin 2 (GRX2) subfamily; composed of bacterial proteins similar to E. coli GRX2, an atypical GRX with a molecular mass of about 24kD (most GRXs range from 9-12kD). GRX2 adopts a GST fold containing an N-terminal thioredoxin-fold domain and a C-terminal alpha helical domain. It contains a redox active CXXC motif located in the N-terminal domain, but is not able to reduce ribonucleotide reductase like other GRXs. However, it catalyzes GSH-dependent protein disulfide reduction of other substrates efficiently. GRX2 is thought to function primarily in catalyzing the reversible glutathionylation of proteins in cellular redox regulation including stress responses.
Probab=84.36 E-value=2.1 Score=26.20 Aligned_cols=46 Identities=13% Similarity=0.234 Sum_probs=30.1
Q ss_pred HHHHHHHHHHHHHHhcccCCCceeccCchHHHHHHHHHHHHHHHHHH
Q 043560 16 STMKEILEMLKTVEEHGLGEKKFFHGDIGLVDIAFASIVYWLQIIED 62 (66)
Q Consensus 16 ~a~~~~~~~l~~l~e~~l~~~~ff~G~~g~~Di~~~~~~~w~~~~e~ 62 (66)
+..+++...|.-+ +..+......+|.+|+=||.+.|+++-+..++.
T Consensus 60 ~~i~~l~~~L~~l-~~ll~~~~~~n~~ls~DDi~lFp~LR~Lt~vkg 105 (128)
T cd03199 60 QYIAALNALLEEL-DPLILSSEAVNGQLSTDDIILFPILRNLTLVKG 105 (128)
T ss_pred HHHHHHHHHHHHH-HHHHcCccccCCcCCHHHHHHHHHHhhhhhhcC
Confidence 3455666666666 666633233333399999999999987766543
No 72
>PF11801 Tom37_C: Tom37 C-terminal domain; InterPro: IPR019564 Tom37 is one of the outer membrane proteins that make up the TOM complex for guiding cytosolic mitochondrial beta-barrel proteins from the cytosol across the outer mitochondrial membrane into the intramembrane space. In conjunction with Tom70, it guides peptides without an mitochondrial targeting sequence (MTS) into Tom40, the protein that forms the passage through the outer membrane []. It has homology with metaxin, also part of the outer mitochondrial membrane beta-barrel protein transport complex []. This entry represents outer mitochondrial membrane transport complex proteins Tom37 and metaxin.; GO: 0006626 protein targeting to mitochondrion, 0005741 mitochondrial outer membrane
Probab=81.52 E-value=4.7 Score=25.39 Aligned_cols=33 Identities=27% Similarity=0.394 Sum_probs=24.7
Q ss_pred HHHHHHHHHhcccCCC---ceecc-C-chHHHHHHHHHH
Q 043560 21 ILEMLKTVEEHGLGEK---KFFHG-D-IGLVDIAFASIV 54 (66)
Q Consensus 21 ~~~~l~~l~e~~l~~~---~ff~G-~-~g~~Di~~~~~~ 54 (66)
..+.+..| ++.|+.. .|+.| + ++-+|+.+...+
T Consensus 113 a~~~l~~L-~~~L~~~~~~~~~f~~~~psslD~L~~ayL 150 (168)
T PF11801_consen 113 AMECLSLL-EELLGEWEEARYFFGDSKPSSLDCLAFAYL 150 (168)
T ss_pred HHHHHHHH-HHHHhhccccccccCCCCCCHHHHHHHHHH
Confidence 66778888 8888755 55555 5 999999987655
No 73
>PF09236 AHSP: Alpha-haemoglobin stabilising protein; InterPro: IPR015317 Alpha-haemoglobin stabilising protein (AHSP) acts a molecular chaperone for free alpha-haemoglobin, preventing the harmful aggregation of alpha-haemoglobin during normal erythroid cell development: it specifically protects free alpha-haemoglobin from precipitation. AHSP adopts a helical secondary structure consisting of an elongated antiparallel three alpha-helix bundle []. ; GO: 0030492 hemoglobin binding, 0006457 protein folding, 0020027 hemoglobin metabolic process, 0030097 hemopoiesis, 0050821 protein stabilization; PDB: 1Y01_A 1XZY_A 3OVU_A 1W0A_A 3IA3_C 1Z8U_A 1W0B_A 1W09_A.
Probab=62.51 E-value=4.9 Score=23.18 Aligned_cols=19 Identities=26% Similarity=0.489 Sum_probs=17.0
Q ss_pred ChHHHHHHHHHHHHHHHHH
Q 043560 10 SVQDQESTMKEILEMLKTV 28 (66)
Q Consensus 10 ~~ee~~~a~~~~~~~l~~l 28 (66)
+.+||+++.+++++.|..+
T Consensus 55 eqqeqdrAlqel~qeL~tl 73 (89)
T PF09236_consen 55 EQQEQDRALQELQQELNTL 73 (89)
T ss_dssp SHHHHHHHHHHHHHHHHHH
T ss_pred ChHHHHHHHHHHHHHHHHH
Confidence 5688999999999999888
No 74
>PF04726 Microvir_J: Microvirus J protein; InterPro: IPR006815 This small protein is involved in DNA packaging, interacting with DNA via its hydrophobic C terminus. In bacteriophage phi-X174, J is present in 60 copies, and forms an S-shaped polypeptide chain without any secondary structure. It is thought to interact with DNA through simple charge interactions [].; GO: 0003677 DNA binding, 0019073 viral DNA genome packaging, 0019028 viral capsid; PDB: 1M06_J 1GFF_3 1RB8_J 2BPA_3.
Probab=42.95 E-value=8.8 Score=16.82 Aligned_cols=7 Identities=43% Similarity=0.999 Sum_probs=1.8
Q ss_pred CCchhhh
Q 043560 1 GATVWKK 7 (66)
Q Consensus 1 ~~~~~~~ 7 (66)
|||+|.+
T Consensus 13 garlwyv 19 (24)
T PF04726_consen 13 GARLWYV 19 (24)
T ss_dssp SS----S
T ss_pred ceEEEEe
Confidence 5777754
No 75
>COG1656 Uncharacterized conserved protein [Function unknown]
Probab=42.17 E-value=22 Score=22.73 Aligned_cols=16 Identities=25% Similarity=0.779 Sum_probs=14.3
Q ss_pred HHHHHHHHHHHHHHHH
Q 043560 45 LVDIAFASIVYWLQII 60 (66)
Q Consensus 45 ~~Di~~~~~~~w~~~~ 60 (66)
++|..+|.+++|++.+
T Consensus 10 ~vD~mLG~LARwLRll 25 (165)
T COG1656 10 VVDAMLGKLARWLRLL 25 (165)
T ss_pred eHHHhHHHHHHHHHHc
Confidence 7899999999999864
No 76
>PF08020 DUF1706: Protein of unknown function (DUF1706) ; InterPro: IPR012550 This family contains many hypothetical proteins from bacteria and yeast.
Probab=36.77 E-value=1.1e+02 Score=19.29 Aligned_cols=27 Identities=19% Similarity=0.331 Sum_probs=17.2
Q ss_pred CCceec-cC-chHHHHHHHHHHHHHHHHHH
Q 043560 35 EKKFFH-GD-IGLVDIAFASIVYWLQIIED 62 (66)
Q Consensus 35 ~~~ff~-G~-~g~~Di~~~~~~~w~~~~e~ 62 (66)
..+|.. |. .+..|++ +..+.|...+-.
T Consensus 34 ~~~~~~~~~d~~~~DvL-ayl~gW~~LlL~ 62 (166)
T PF08020_consen 34 DTPFDFGGRDRNPRDVL-AYLYGWHELLLK 62 (166)
T ss_pred cCccccccccCCHHHHH-HHHHHHHHHHHH
Confidence 456553 44 9999996 446677765543
No 77
>PHA00008 J DNA packaging protein
Probab=33.85 E-value=9.4 Score=17.07 Aligned_cols=7 Identities=43% Similarity=0.999 Sum_probs=3.9
Q ss_pred CCchhhh
Q 043560 1 GATVWKK 7 (66)
Q Consensus 1 ~~~~~~~ 7 (66)
|||+|++
T Consensus 14 GARLWYV 20 (26)
T PHA00008 14 GARLWYV 20 (26)
T ss_pred ceEEEEe
Confidence 5666643
No 78
>cd08200 catalase_peroxidase_2 C-terminal non-catalytic domain of catalase-peroxidases. This is a subgroup of heme-dependent peroxidases of the plant superfamily that share a heme prosthetic group and catalyze a multistep oxidative reaction involving hydrogen peroxide as the electron acceptor. Catalase-peroxidases can exhibit both catalase and broad-spectrum peroxidase activities depending on the steady-state concentration of hydrogen peroxide. These enzymes are found in many archaeal and bacterial organisms where they neutralize potentially lethal hydrogen peroxide molecules generated during photosynthesis or stationary phase. Along with related intracellular fungal and plant peroxidases, catalase-peroxidases belong to plant peroxidase superfamily. Unlike the eukaryotic enzymes, they are typically comprised of two homologous domains that probably arose via a single gene duplication event. The heme binding motif is present only in the N-terminal domain; the function of the C-terminal do
Probab=31.12 E-value=90 Score=21.79 Aligned_cols=24 Identities=21% Similarity=0.335 Sum_probs=16.5
Q ss_pred eccC-chHHHHHHHHHHHHHHHHHHHhc
Q 043560 39 FHGD-IGLVDIAFASIVYWLQIIEDVAR 65 (66)
Q Consensus 39 f~G~-~g~~Di~~~~~~~w~~~~e~~~g 65 (66)
.+|. +|++|.. .+...-.+|+..|
T Consensus 93 ~~~~~vS~ADLi---vLaG~vAiE~agg 117 (297)
T cd08200 93 SGGKKVSLADLI---VLGGCAAVEKAAK 117 (297)
T ss_pred cCCccccHHHHH---HHHhHHHHHHHHh
Confidence 3566 9999987 5556666666544
No 79
>PF08256 Antimicrobial20: Aurein-like antibiotic peptide; InterPro: IPR013157 This family of antibacterial peptides are secreted from the granular dorsal glands of Litoria aurea (Green and golden bell frog), Litoria raniformis (Southern bell frog), Litoria citropa (Australian blue mountains tree frog) and frogs from genus Uperoleia. They are a part of the FSAP peptide family. Amongst the more active of these are aurein 1.2, aurein 2.2 and aurein 3.1; caerin 1.1, maculatin 1.1, uperin 3.6 []; citropin 1.1, citropin 1.2, citropin 1.3 and a minor peptide are wide-spectrum antibacterial peptides [].; GO: 0006952 defense response
Probab=22.68 E-value=54 Score=12.39 Aligned_cols=6 Identities=83% Similarity=1.210 Sum_probs=3.4
Q ss_pred hHHHHH
Q 043560 44 GLVDIA 49 (66)
Q Consensus 44 g~~Di~ 49 (66)
|+.||+
T Consensus 1 Gl~Di~ 6 (13)
T PF08256_consen 1 GLFDIA 6 (13)
T ss_pred CHHHHH
Confidence 456664
Done!