Query 013573
Match_columns 440
No_of_seqs 349 out of 1198
Neff 4.3
Searched_HMMs 46136
Date Fri Mar 29 05:13:23 2013
Command hhsearch -i /work/01045/syshi/csienesis_hhblits_a3m/013573.a3m -d /work/01045/syshi/HHdatabase/Cdd.hhm -o /work/01045/syshi/hhsearch_cdd/013573hhsearch_cdd -cpu 12 -v 0
No Hit Prob E-value P-value Score SS Cols Query HMM Template HMM
1 PF03106 WRKY: WRKY DNA -bindi 100.0 4.5E-31 9.9E-36 206.7 0.8 59 255-313 1-59 (60)
2 smart00774 WRKY DNA binding do 100.0 5.7E-30 1.2E-34 200.1 3.9 58 255-312 1-59 (59)
3 PF03106 WRKY: WRKY DNA -bindi 100.0 8.7E-30 1.9E-34 199.5 2.9 59 93-151 1-60 (60)
4 smart00774 WRKY DNA binding do 99.9 1.1E-28 2.3E-33 193.0 4.4 57 93-149 1-59 (59)
5 PF04500 FLYWCH: FLYWCH zinc f 91.0 0.13 2.9E-06 38.5 1.7 49 92-149 11-62 (62)
6 PF03101 FAR1: FAR1 DNA-bindin 88.0 0.49 1.1E-05 38.6 3.0 29 123-151 61-89 (91)
7 PF04500 FLYWCH: FLYWCH zinc f 86.4 0.13 2.8E-06 38.5 -1.2 49 254-312 11-62 (62)
8 PF03101 FAR1: FAR1 DNA-bindin 71.6 2.6 5.6E-05 34.3 1.8 30 284-314 60-89 (91)
9 PF03859 CG-1: CG-1 domain; I 34.5 14 0.00031 33.4 0.2 10 92-101 50-59 (118)
10 PLN03097 FHY3 Protein FAR-RED 32.5 50 0.0011 38.6 4.1 35 119-153 156-190 (846)
11 PF03615 GCM: GCM motif protei 28.1 54 0.0012 30.5 2.8 23 132-154 111-133 (143)
12 PLN03097 FHY3 Protein FAR-RED 20.9 77 0.0017 37.1 2.9 35 281-316 156-190 (846)
No 1
>PF03106 WRKY: WRKY DNA -binding domain; InterPro: IPR003657 The WRKY domain is a 60 amino acid region that is defined by the conserved amino acid sequence WRKYGQK at its N-terminal end, together with a novel zinc-finger- like motif. The WRKY domain is found in one or two copies in a superfamily of plant transcription factors involved in the regulation of various physiological programs that are unique to plants, including pathogen defence, senescence, trichome development and the biosynthesis of secondary metabolites. The WRKY domain binds specifically to the DNA sequence motif (T)(T)TGAC(C/T), which is known as the W box. The invariant TGAC core of the W box is essential for function and WRKY binding []. Some proteins known to contain a WRKY domain include Arabidopsis thaliana ZAP1 (Zinc-dependent Activator Protein-1) and AtWRKY44/TTG2, a protein involved in trichome development and anthocyanin pigmentation; and wild oat ABF1-2, two proteins involved in the gibberelic acid-induced expression of the alpha-Amy2 gene. Structural studies indicate that this domain is a four-stranded beta-sheet with a zinc binding pocket, forming a novel zinc and DNA binding structure []. The WRKYGQK residues correspond to the most N-terminal beta-strand, which enables extensive hydrophobic interactions, contributing to the structural stability of the beta-sheet.; GO: 0003700 sequence-specific DNA binding transcription factor activity, 0043565 sequence-specific DNA binding, 0006355 regulation of transcription, DNA-dependent; PDB: 2AYD_A 1WJ2_A 2LEX_A.
Probab=99.96 E-value=4.5e-31 Score=206.74 Aligned_cols=59 Identities=66% Similarity=1.367 Sum_probs=52.6
Q ss_pred CCcCchhhhccCcccCCCCCCCcccccCCCCCCcccchhhccCCCCeEEEEEeccCCCC
Q 013573 255 LDDGYRWRKYGQKVVRGNPNPRSYYKCTNAGCPVRKHVERASHDPKAVITTYEGKHNHD 313 (440)
Q Consensus 255 ~~DGy~WRKYGQK~ikgn~~pRsYYrCt~~gC~akK~Ver~~~D~~~~~~tY~G~HnH~ 313 (440)
++|||+|||||||.|+|+++||+||||+..+|+|+|+|||+.+|+.+|+|||+|+|||+
T Consensus 1 ~~Dgy~WRKYGqK~i~g~~~pRsYYrCt~~~C~akK~Vqr~~~d~~~~~vtY~G~H~h~ 59 (60)
T PF03106_consen 1 LDDGYRWRKYGQKNIKGSPYPRSYYRCTHPGCPAKKQVQRSADDPNIVIVTYEGEHNHP 59 (60)
T ss_dssp --SSS-EEEEEEEEETTTTCEEEEEEEECTTEEEEEEEEEETTCCCEEEEEEES--SS-
T ss_pred CCCCCchhhccCcccCCCceeeEeeeccccChhheeeEEEecCCCCEEEEEEeeeeCCC
Confidence 58999999999999999999999999999999999999999999999999999999996
No 2
>smart00774 WRKY DNA binding domain. The WRKY domain is a DNA binding domain found in one or two copies in a superfamily of plant transcription factors. These transcription factors are involved in the regulation of various physiological programs that are unique to plants, including pathogen defense, senescence and trichome development. The domain is a 60 amino acid region that is defined by the conserved amino acid sequence WRKYGQK at its N-terminal end, together with a novel zinc-finger-like motif. It binds specifically to the DNA sequence motif (T)(T)TGAC(C/T), which is known as the W box. The invariant TGAC core is essential for function and WRKY binding.
Probab=99.96 E-value=5.7e-30 Score=200.11 Aligned_cols=58 Identities=64% Similarity=1.321 Sum_probs=56.5
Q ss_pred CCcCchhhhccCcccCCCCCCCcccccCC-CCCCcccchhhccCCCCeEEEEEeccCCC
Q 013573 255 LDDGYRWRKYGQKVVRGNPNPRSYYKCTN-AGCPVRKHVERASHDPKAVITTYEGKHNH 312 (440)
Q Consensus 255 ~~DGy~WRKYGQK~ikgn~~pRsYYrCt~-~gC~akK~Ver~~~D~~~~~~tY~G~HnH 312 (440)
++|||+|||||||.|+|+++||+|||||. +||+|+|+|||+.+|+.+++|||+|+|||
T Consensus 1 ~~DGy~WRKYGQK~ikgs~~pRsYYrCt~~~~C~a~K~Vq~~~~d~~~~~vtY~g~H~h 59 (59)
T smart00774 1 LDDGYQWRKYGQKVIKGSPFPRSYYRCTYSQGCPAKKQVQRSDDDPSVVEVTYEGEHTH 59 (59)
T ss_pred CCCcccccccCcEecCCCcCcceEEeccccCCCCCcccEEEECCCCCEEEEEEeeEeCC
Confidence 48999999999999999999999999998 99999999999999999999999999998
No 3
>PF03106 WRKY: WRKY DNA -binding domain; InterPro: IPR003657 The WRKY domain is a 60 amino acid region that is defined by the conserved amino acid sequence WRKYGQK at its N-terminal end, together with a novel zinc-finger- like motif. The WRKY domain is found in one or two copies in a superfamily of plant transcription factors involved in the regulation of various physiological programs that are unique to plants, including pathogen defence, senescence, trichome development and the biosynthesis of secondary metabolites. The WRKY domain binds specifically to the DNA sequence motif (T)(T)TGAC(C/T), which is known as the W box. The invariant TGAC core of the W box is essential for function and WRKY binding []. Some proteins known to contain a WRKY domain include Arabidopsis thaliana ZAP1 (Zinc-dependent Activator Protein-1) and AtWRKY44/TTG2, a protein involved in trichome development and anthocyanin pigmentation; and wild oat ABF1-2, two proteins involved in the gibberelic acid-induced expression of the alpha-Amy2 gene. Structural studies indicate that this domain is a four-stranded beta-sheet with a zinc binding pocket, forming a novel zinc and DNA binding structure []. The WRKYGQK residues correspond to the most N-terminal beta-strand, which enables extensive hydrophobic interactions, contributing to the structural stability of the beta-sheet.; GO: 0003700 sequence-specific DNA binding transcription factor activity, 0043565 sequence-specific DNA binding, 0006355 regulation of transcription, DNA-dependent; PDB: 2AYD_A 1WJ2_A 2LEX_A.
Probab=99.95 E-value=8.7e-30 Score=199.52 Aligned_cols=59 Identities=61% Similarity=1.230 Sum_probs=50.8
Q ss_pred CCCCccccccCccCCCCCCCCCCcccccCCCcceeeeEEecc-CCceEEEEecCCCCCCC
Q 013573 93 SDDGYNWRKYGQKHVKGSEFPRSYYKCTHPNCEVKKLFERSH-DGQITEIIYKGTHDHPK 151 (440)
Q Consensus 93 ~~DGy~WRKYGQK~ikgs~~pRsYYrCt~~~C~akK~ver~~-dg~~~~i~Y~G~H~H~~ 151 (440)
.+|||+|||||||.|+|+++||+||||++.+|+|+|+|||+. |+.++.|+|+|+|||++
T Consensus 1 ~~Dgy~WRKYGqK~i~g~~~pRsYYrCt~~~C~akK~Vqr~~~d~~~~~vtY~G~H~h~k 60 (60)
T PF03106_consen 1 LDDGYRWRKYGQKNIKGSPYPRSYYRCTHPGCPAKKQVQRSADDPNIVIVTYEGEHNHPK 60 (60)
T ss_dssp --SSS-EEEEEEEEETTTTCEEEEEEEECTTEEEEEEEEEETTCCCEEEEEEES--SS--
T ss_pred CCCCCchhhccCcccCCCceeeEeeeccccChhheeeEEEecCCCCEEEEEEeeeeCCCC
Confidence 489999999999999999999999999999999999999986 88999999999999985
No 4
>smart00774 WRKY DNA binding domain. The WRKY domain is a DNA binding domain found in one or two copies in a superfamily of plant transcription factors. These transcription factors are involved in the regulation of various physiological programs that are unique to plants, including pathogen defense, senescence and trichome development. The domain is a 60 amino acid region that is defined by the conserved amino acid sequence WRKYGQK at its N-terminal end, together with a novel zinc-finger-like motif. It binds specifically to the DNA sequence motif (T)(T)TGAC(C/T), which is known as the W box. The invariant TGAC core is essential for function and WRKY binding.
Probab=99.95 E-value=1.1e-28 Score=193.02 Aligned_cols=57 Identities=58% Similarity=1.134 Sum_probs=54.8
Q ss_pred CCCCccccccCccCCCCCCCCCCcccccC-CCcceeeeEEecc-CCceEEEEecCCCCC
Q 013573 93 SDDGYNWRKYGQKHVKGSEFPRSYYKCTH-PNCEVKKLFERSH-DGQITEIIYKGTHDH 149 (440)
Q Consensus 93 ~~DGy~WRKYGQK~ikgs~~pRsYYrCt~-~~C~akK~ver~~-dg~~~~i~Y~G~H~H 149 (440)
.+|||+|||||||.|+|+++||+|||||+ ++|+|+|+||++. |+.+++|+|+|+|||
T Consensus 1 ~~DGy~WRKYGQK~ikgs~~pRsYYrCt~~~~C~a~K~Vq~~~~d~~~~~vtY~g~H~h 59 (59)
T smart00774 1 LDDGYQWRKYGQKVIKGSPFPRSYYRCTYSQGCPAKKQVQRSDDDPSVVEVTYEGEHTH 59 (59)
T ss_pred CCCcccccccCcEecCCCcCcceEEeccccCCCCCcccEEEECCCCCEEEEEEeeEeCC
Confidence 47999999999999999999999999999 9999999999985 899999999999998
No 5
>PF04500 FLYWCH: FLYWCH zinc finger domain; InterPro: IPR007588 Zinc finger (Znf) domains are relatively small protein motifs which contain multiple finger-like protrusions that make tandem contacts with their target molecule. Some of these domains bind zinc, but many do not; instead binding other metals such as iron, or no metal at all. For example, some family members form salt bridges to stabilise the finger-like folds. They were first identified as a DNA-binding motif in transcription factor TFIIIA from Xenopus laevis (African clawed frog), however they are now recognised to bind DNA, RNA, protein and/or lipid substrates [, , , , ]. Their binding properties depend on the amino acid sequence of the finger domains and of the linker between fingers, as well as on the higher-order structures and the number of fingers. Znf domains are often found in clusters, where fingers can have different binding specificities. There are many superfamilies of Znf motifs, varying in both sequence and structure. They display considerable versatility in binding modes, even between members of the same class (e.g. some bind DNA, others protein), suggesting that Znf motifs are stable scaffolds that have evolved specialised functions. For example, Znf-containing proteins function in gene transcription, translation, mRNA trafficking, cytoskeleton organisation, epithelial development, cell adhesion, protein folding, chromatin remodelling and zinc sensing, to name but a few []. Zinc-binding motifs are stable structures, and they rarely undergo conformational changes upon binding their target. C2H2-type (classical) zinc fingers (Znf) were the first class to be characterised. They contain a short beta hairpin and an alpha helix (beta/beta/alpha structure), where a single zinc atom is held in place by Cys(2)His(2) (C2H2) residues in a tetrahedral array. C2H2 Znf's can be divided into three groups based on the number and pattern of fingers: triple-C2H2 (binds single ligand), multiple-adjacent-C2H2 (binds multiple ligands), and separated paired-C2H2 []. C2H2 Znf's are the most common DNA-binding motifs found in eukaryotic transcription factors, and have also been identified in prokaryotes []. Transcription factors usually contain several Znf's (each with a conserved beta/beta/alpha structure) capable of making multiple contacts along the DNA, where the C2H2 Znf motifs recognise DNA sequences by binding to the major groove of DNA via a short alpha-helix in the Znf, the Znf spanning 3-4 bases of the DNA []. C2H2 Znf's can also bind to RNA and protein targets []. This entry represents a potential FLYWCH Zn-finger domain found in a number of eukaryotic proteins. FLYWCH is a C2H2-type zinc finger characterised by five conserved hydrophobic residues, containing the conserved sequence motif: F/Y-X(n)-L-X(n)-F/Y-X(n)-WXCX(6-12)CX(17-22)HXH where X indicates any amino acid. This domain was first characterised in Drosophila Modifier of mdg4 proteins, Mod(mgd4), putative chromatin modulators involved in higher order chromatin domains. Mod(mdg4) proteins share a common N-terminal BTB/POZ domain, but differ in their C-terminal region, most containing C-terminal FLYWCH zinc finger motifs []. The FLYWCH domain in Mod(mdg4) proteins has a putative role in protein-protein interactions; for example, Mod(mdg4)-67.2 interacts with DNA-binding protein Su(Hw) via its FLYWCH domain. FLYWCH domains have been described in other proteins as well, including suppressor of killer of prune, Su(Kpn), which contains 4 terminal FLYWCH zinc finger motifs in a tandem array and a C-terminal glutathione SH-transferase (GST) domain []. More information about these proteins can be found at Protein of the Month: Zinc Fingers [].; PDB: 2RPR_A.
Probab=90.97 E-value=0.13 Score=38.47 Aligned_cols=49 Identities=22% Similarity=0.565 Sum_probs=25.0
Q ss_pred CCCCCccccccCccCCCCCCCCCCcccccCC---CcceeeeEEeccCCceEEEEecCCCCC
Q 013573 92 PSDDGYNWRKYGQKHVKGSEFPRSYYKCTHP---NCEVKKLFERSHDGQITEIIYKGTHDH 149 (440)
Q Consensus 92 ~~~DGy~WRKYGQK~ikgs~~pRsYYrCt~~---~C~akK~ver~~dg~~~~i~Y~G~H~H 149 (440)
..-|||.-+++... ..+.|++|+.. +|+|+=.+. ..++ ..+...++|||
T Consensus 11 L~~~Gy~y~~~~~~------~~~~~WrC~~~~~~~C~a~~~~~-~~~~--~~~~~~~~HnH 62 (62)
T PF04500_consen 11 LVYDGYRYYFNKRN------DGKTYWRCSRRRSHGCRARLITD-AGDG--RVVRTNGEHNH 62 (62)
T ss_dssp EEETTEEEEEEEE-------SS-EEEEEGGGTTS----EEEEE---TT--EEEE-S---SS
T ss_pred EEECCeEEECcCCC------CCcEEEEeCCCCCCCCeEEEEEE-CCCC--EEEECCCccCC
Confidence 45788887776555 44689999864 799977666 2233 33445589999
No 6
>PF03101 FAR1: FAR1 DNA-binding domain; InterPro: IPR004330 Phytochrome A is the primary photoreceptor for mediating various far-red light-induced responses in higher plants. It has been found that the proteins governing this response, which include FAR-RED ELONGATED HYPOCOTYL3 (FHY3) and FAR-RED-IMPAIRED RESPONSE1 (FAR1), are a pair of homologous proteins sharing significant sequence homology to mutator-like transposases. These proteins appear to be novel transcription factors, which are essential for activating the expression of FHY1 and FHL (for FHY1-like) and related genes, whose products are required for light-induced phytochrome A nuclear accumulation and subsequent light responses in plants. The FRS (FAR1 Related Sequences) family of proteins share a similar domain structure to mutator-like transposases, including an N-terminal C2H2 zinc finger domain, a central putative core transposase domain, and a C-terminal SWIM motif (named after SWI2/SNF and MuDR transposases). It seems plausible that the FRS family represent transcription factors derived from mutator-like transposases [, ]. This entry represents a domain found in FAR1 and FRS proteins. It contains a WRKY like fold and is therefore most likely a zinc binding DNA-binding domain.
Probab=88.00 E-value=0.49 Score=38.57 Aligned_cols=29 Identities=24% Similarity=0.487 Sum_probs=24.7
Q ss_pred CcceeeeEEeccCCceEEEEecCCCCCCC
Q 013573 123 NCEVKKLFERSHDGQITEIIYKGTHDHPK 151 (440)
Q Consensus 123 ~C~akK~ver~~dg~~~~i~Y~G~H~H~~ 151 (440)
+|+|+=.+.+..+|....+.+..+|||+.
T Consensus 61 gC~a~i~v~~~~~~~w~v~~~~~~HNH~L 89 (91)
T PF03101_consen 61 GCKARINVKRRKDGKWRVTSFVLEHNHPL 89 (91)
T ss_pred CCCEEEEEEEccCCEEEEEECcCCcCCCC
Confidence 59998888777788888888999999985
No 7
>PF04500 FLYWCH: FLYWCH zinc finger domain; InterPro: IPR007588 Zinc finger (Znf) domains are relatively small protein motifs which contain multiple finger-like protrusions that make tandem contacts with their target molecule. Some of these domains bind zinc, but many do not; instead binding other metals such as iron, or no metal at all. For example, some family members form salt bridges to stabilise the finger-like folds. They were first identified as a DNA-binding motif in transcription factor TFIIIA from Xenopus laevis (African clawed frog), however they are now recognised to bind DNA, RNA, protein and/or lipid substrates [, , , , ]. Their binding properties depend on the amino acid sequence of the finger domains and of the linker between fingers, as well as on the higher-order structures and the number of fingers. Znf domains are often found in clusters, where fingers can have different binding specificities. There are many superfamilies of Znf motifs, varying in both sequence and structure. They display considerable versatility in binding modes, even between members of the same class (e.g. some bind DNA, others protein), suggesting that Znf motifs are stable scaffolds that have evolved specialised functions. For example, Znf-containing proteins function in gene transcription, translation, mRNA trafficking, cytoskeleton organisation, epithelial development, cell adhesion, protein folding, chromatin remodelling and zinc sensing, to name but a few []. Zinc-binding motifs are stable structures, and they rarely undergo conformational changes upon binding their target. C2H2-type (classical) zinc fingers (Znf) were the first class to be characterised. They contain a short beta hairpin and an alpha helix (beta/beta/alpha structure), where a single zinc atom is held in place by Cys(2)His(2) (C2H2) residues in a tetrahedral array. C2H2 Znf's can be divided into three groups based on the number and pattern of fingers: triple-C2H2 (binds single ligand), multiple-adjacent-C2H2 (binds multiple ligands), and separated paired-C2H2 []. C2H2 Znf's are the most common DNA-binding motifs found in eukaryotic transcription factors, and have also been identified in prokaryotes []. Transcription factors usually contain several Znf's (each with a conserved beta/beta/alpha structure) capable of making multiple contacts along the DNA, where the C2H2 Znf motifs recognise DNA sequences by binding to the major groove of DNA via a short alpha-helix in the Znf, the Znf spanning 3-4 bases of the DNA []. C2H2 Znf's can also bind to RNA and protein targets []. This entry represents a potential FLYWCH Zn-finger domain found in a number of eukaryotic proteins. FLYWCH is a C2H2-type zinc finger characterised by five conserved hydrophobic residues, containing the conserved sequence motif: F/Y-X(n)-L-X(n)-F/Y-X(n)-WXCX(6-12)CX(17-22)HXH where X indicates any amino acid. This domain was first characterised in Drosophila Modifier of mdg4 proteins, Mod(mgd4), putative chromatin modulators involved in higher order chromatin domains. Mod(mdg4) proteins share a common N-terminal BTB/POZ domain, but differ in their C-terminal region, most containing C-terminal FLYWCH zinc finger motifs []. The FLYWCH domain in Mod(mdg4) proteins has a putative role in protein-protein interactions; for example, Mod(mdg4)-67.2 interacts with DNA-binding protein Su(Hw) via its FLYWCH domain. FLYWCH domains have been described in other proteins as well, including suppressor of killer of prune, Su(Kpn), which contains 4 terminal FLYWCH zinc finger motifs in a tandem array and a C-terminal glutathione SH-transferase (GST) domain []. More information about these proteins can be found at Protein of the Month: Zinc Fingers [].; PDB: 2RPR_A.
Probab=86.40 E-value=0.13 Score=38.52 Aligned_cols=49 Identities=31% Similarity=0.716 Sum_probs=25.4
Q ss_pred CCCcCchhhhccCcccCCCCCCCcccccCC---CCCCcccchhhccCCCCeEEEEEeccCCC
Q 013573 254 ILDDGYRWRKYGQKVVRGNPNPRSYYKCTN---AGCPVRKHVERASHDPKAVITTYEGKHNH 312 (440)
Q Consensus 254 ~~~DGy~WRKYGQK~ikgn~~pRsYYrCt~---~gC~akK~Ver~~~D~~~~~~tY~G~HnH 312 (440)
++-|||.-++.... ....|++|+. .+|+|+=.+. .++ ..+ +...++|||
T Consensus 11 L~~~Gy~y~~~~~~------~~~~~WrC~~~~~~~C~a~~~~~--~~~-~~~-~~~~~~HnH 62 (62)
T PF04500_consen 11 LVYDGYRYYFNKRN------DGKTYWRCSRRRSHGCRARLITD--AGD-GRV-VRTNGEHNH 62 (62)
T ss_dssp EEETTEEEEEEEE-------SS-EEEEEGGGTTS----EEEEE----T-TEE-EE-S---SS
T ss_pred EEECCeEEECcCCC------CCcEEEEeCCCCCCCCeEEEEEE--CCC-CEE-EECCCccCC
Confidence 56789987765544 4568999984 3899988877 223 233 445599998
No 8
>PF03101 FAR1: FAR1 DNA-binding domain; InterPro: IPR004330 Phytochrome A is the primary photoreceptor for mediating various far-red light-induced responses in higher plants. It has been found that the proteins governing this response, which include FAR-RED ELONGATED HYPOCOTYL3 (FHY3) and FAR-RED-IMPAIRED RESPONSE1 (FAR1), are a pair of homologous proteins sharing significant sequence homology to mutator-like transposases. These proteins appear to be novel transcription factors, which are essential for activating the expression of FHY1 and FHL (for FHY1-like) and related genes, whose products are required for light-induced phytochrome A nuclear accumulation and subsequent light responses in plants. The FRS (FAR1 Related Sequences) family of proteins share a similar domain structure to mutator-like transposases, including an N-terminal C2H2 zinc finger domain, a central putative core transposase domain, and a C-terminal SWIM motif (named after SWI2/SNF and MuDR transposases). It seems plausible that the FRS family represent transcription factors derived from mutator-like transposases [, ]. This entry represents a domain found in FAR1 and FRS proteins. It contains a WRKY like fold and is therefore most likely a zinc binding DNA-binding domain.
Probab=71.57 E-value=2.6 Score=34.31 Aligned_cols=30 Identities=37% Similarity=0.617 Sum_probs=26.4
Q ss_pred CCCCcccchhhccCCCCeEEEEEeccCCCCC
Q 013573 284 AGCPVRKHVERASHDPKAVITTYEGKHNHDV 314 (440)
Q Consensus 284 ~gC~akK~Ver~~~D~~~~~~tY~G~HnH~~ 314 (440)
-||+|+=.|.+.. |..-.|+.+..+|||++
T Consensus 60 tgC~a~i~v~~~~-~~~w~v~~~~~~HNH~L 89 (91)
T PF03101_consen 60 TGCKARINVKRRK-DGKWRVTSFVLEHNHPL 89 (91)
T ss_pred cCCCEEEEEEEcc-CCEEEEEECcCCcCCCC
Confidence 6999998888765 78889999999999986
No 9
>PF03859 CG-1: CG-1 domain; InterPro: IPR005559 CG-1 domains are highly conserved domains of about 130 amino-acid residues containing a predicted bipartite NLS and named after a partial cDNA clone isolated from parsley encoding a sequence-specific DNA-binding protein []. CG-1 domains are associated with CAMTA proteins (for CAlModulin -binding Transcription Activator) that are transcription factors containing a calmodulin-binding domain and ankyrins [].; GO: 0005516 calmodulin binding, 0006355 regulation of transcription, DNA-dependent, 0005634 nucleus
Probab=34.50 E-value=14 Score=33.37 Aligned_cols=10 Identities=60% Similarity=1.049 Sum_probs=8.5
Q ss_pred CCCCCccccc
Q 013573 92 PSDDGYNWRK 101 (440)
Q Consensus 92 ~~~DGy~WRK 101 (440)
--.|||+|||
T Consensus 50 fRkDG~~WrK 59 (118)
T PF03859_consen 50 FRKDGHNWRK 59 (118)
T ss_pred hhcccceeEE
Confidence 3579999998
No 10
>PLN03097 FHY3 Protein FAR-RED ELONGATED HYPOCOTYL 3; Provisional
Probab=32.45 E-value=50 Score=38.65 Aligned_cols=35 Identities=20% Similarity=0.429 Sum_probs=30.1
Q ss_pred ccCCCcceeeeEEeccCCceEEEEecCCCCCCCCC
Q 013573 119 CTHPNCEVKKLFERSHDGQITEIIYKGTHDHPKPQ 153 (440)
Q Consensus 119 Ct~~~C~akK~ver~~dg~~~~i~Y~G~H~H~~p~ 153 (440)
|+--+|+|+=.|.+..+|....+-+..+|||+.-.
T Consensus 156 ~tRtGC~A~m~Vk~~~~gkW~V~~fv~eHNH~L~p 190 (846)
T PLN03097 156 CAKTDCKASMHVKRRPDGKWVIHSFVKEHNHELLP 190 (846)
T ss_pred ccCCCCceEEEEEEcCCCeEEEEEEecCCCCCCCC
Confidence 77789999999988888887778899999998743
No 11
>PF03615 GCM: GCM motif protein; InterPro: IPR003902 GCM transcription factors are a family of proteins which contain a GCM motif. The GCM motif is a domain that has been identified in proteins belonging to a family of transcriptional regulators involved in fundamental developmental processes which comprise Drosophila melanogaster GCM and its mammalian homologs [, , , ]. IN GCM transcription factors the N-terminal moiety contains a DNA-binding domain of 150 residues. Sequence conservation is highest in this GCM domain. In contrast, the C-terminal moiety contains one or two transactivating regions and is only poorly conserved. The GCM motif has been shown to be a DNA binding domain that recognises preferentially the nonpalindromic octamer 5'-ATGCGGGT-3' [, , ]. The GCM motif contains many conserved basic amino acid residues, seven cysteine residues, and four histidine residues []. The conserved cysteines are involved in shaping the overall conformation of the domain, in the process of DNA binding and in the redox regulation of DNA binding []. The GCM domain as a new class of Zn-containing DNA-binding domain with no similarity to any other DNA-binding domain []. The GCM domain consists of a large and a small domain tethered together by one of the two Zn ions present in the structure. The large and the small domains comprise five- and three-stranded beta-sheets, respectively, with three small helical segments packed against the same side of the two beta-sheets. The GCM domain exercises a novel mode of sequence-specific DNA recognition, where the five-stranded beta-pleated sheet inserts into the major groove of the DNA. Residues protruding from the edge strand of the beta-pleated sheet and the following loop and strand contact the bases and backbone of both DNA strands, providing specificity for its DNA target site. ; GO: 0003677 DNA binding, 0006355 regulation of transcription, DNA-dependent; PDB: 1ODH_A.
Probab=28.11 E-value=54 Score=30.49 Aligned_cols=23 Identities=43% Similarity=0.764 Sum_probs=8.6
Q ss_pred eccCCceEEEEecCCCCCCCCCC
Q 013573 132 RSHDGQITEIIYKGTHDHPKPQL 154 (440)
Q Consensus 132 r~~dg~~~~i~Y~G~H~H~~p~~ 154 (440)
+.++|..+..--+|.|+|+.|..
T Consensus 111 Wr~~~~~IfFQaKG~HDHpRPe~ 133 (143)
T PF03615_consen 111 WRHDGNAIFFQAKGVHDHPRPEA 133 (143)
T ss_dssp EEE-SSBEEEEEE----S-----
T ss_pred EecCCCEEEEEcccccCCCCCCc
Confidence 34556666667799999999975
No 12
>PLN03097 FHY3 Protein FAR-RED ELONGATED HYPOCOTYL 3; Provisional
Probab=20.89 E-value=77 Score=37.14 Aligned_cols=35 Identities=34% Similarity=0.660 Sum_probs=29.6
Q ss_pred cCCCCCCcccchhhccCCCCeEEEEEeccCCCCCCC
Q 013573 281 CTNAGCPVRKHVERASHDPKAVITTYEGKHNHDVPT 316 (440)
Q Consensus 281 Ct~~gC~akK~Ver~~~D~~~~~~tY~G~HnH~~p~ 316 (440)
|+--||+|+=.|.+. .|..-.|+-+..+|||+.-.
T Consensus 156 ~tRtGC~A~m~Vk~~-~~gkW~V~~fv~eHNH~L~p 190 (846)
T PLN03097 156 CAKTDCKASMHVKRR-PDGKWVIHSFVKEHNHELLP 190 (846)
T ss_pred ccCCCCceEEEEEEc-CCCeEEEEEEecCCCCCCCC
Confidence 777899999999874 56778999999999998743
Done!