RPS-BLAST 2.2.26 [Sep-21-2011]
Database: CDD.v3.10
44,354 sequences; 10,937,602 total letters
Searching..................................................done
Query= psy3998
(102 letters)
>gnl|CDD|212675 cd10233, HSPA1-2_6-8-like_NBD, Nucleotide-binding domain of
HSPA1-A, -B, -L, HSPA-2, -6, -7, -8, and similar
proteins. This subfamily includes human HSPA1A (70-kDa
heat shock protein 1A, also known as HSP72; HSPA1;
HSP70I; HSPA1B; HSP70-1; HSP70-1A), HSPA1B (70-kDa heat
shock protein 1B, also known as HSPA1A; HSP70-2;
HSP70-1B), and HSPA1L (70-kDa heat shock protein 1-like,
also known as HSP70T; hum70t; HSP70-1L; HSP70-HOM). The
genes for these three HSPA1 proteins map in close
proximity on the major histocompatibility complex (MHC)
class III region on chromosome 6, 6p21.3. This subfamily
also includes human HSPA8 (heat shock 70kDa protein 8,
also known as LAP1; HSC54; HSC70; HSC71; HSP71; HSP73;
NIP71; HSPA10; the HSPA8 gene maps to 11q24.1), human
HSPA2 (70-kDa heat shock protein 2, also known as
HSP70-2; HSP70-3, the HSPA2 gene maps to 14q24.1), human
HSPA6 (also known as heat shock 70kDa protein 6
(HSP70B') gi 94717614, the HSPA6 gene maps to 1q23.3),
human HSPA7 (heat shock 70kDa protein 7 , also known as
HSP70B; the HSPA7 gene maps to 1q23.3) and Saccharmoyces
cerevisiae Stress-Seventy subfamily B/Ssb1p. This
subfamily belongs to the heat shock protein 70 (HSP70)
family of chaperones that assist in protein folding and
assembly and can direct incompetent "client" proteins
towards degradation. Typically, HSP70s have a
nucleotide-binding domain (NBD) and a substrate-binding
domain (SBD). The nucleotide sits in a deep cleft formed
between the two lobes of the NBD. The two subdomains of
each lobe change conformation between ATP-bound,
ADP-bound, and nucleotide-free states. ATP binding opens
up the substrate-binding site; substrate-binding
increases the rate of ATP hydrolysis. HSP70 chaperone
activity is regulated by various co-chaperones: J-domain
proteins and nucleotide exchange factors (NEFs).
Associations of polymorphisms within the MHC-III HSP70
gene locus with longevity, systemic lupus erythematosus,
Meniere's disease, noise-induced hearing loss,
high-altitude pulmonary edema, and coronary heart
disease, have been found. HSPA2 is involved in cancer
cell survival, is required for maturation of male
gametophytes, and is linked to male infertility. The
induction of HSPA6 is a biomarker of cellular stress.
HSPA8 participates in the folding and trafficking of
client proteins to different subcellular compartments,
and in the signal transduction and apoptosis process; it
has been shown to protect cardiomyocytes against
oxidative stress partly through an interaction with
alpha-enolase. S. cerevisiae Ssb1p, is part of the
ribosome-associated complex (RAC), it acts as a
chaperone for nascent polypeptides, and is important for
translation fidelity; Ssb1p is also a [PSI+]
prion-curing factor.
Length = 376
Score = 211 bits (538), Expect = 3e-69
Identities = 81/102 (79%), Positives = 86/102 (84%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEIS 60
MNP NTVFDAKRLIGRKF D +Q D+KHWPF VV+ GGKP I VEYKGE K F PEEIS
Sbjct: 56 MNPTNTVFDAKRLIGRKFSDPVVQSDMKHWPFKVVNGGGKPPIIVEYKGETKTFYPEEIS 115
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
SMVLTKM+EIAE YLG V+ AVITVPAYFNDSQRQATKDAG
Sbjct: 116 SMVLTKMKEIAEAYLGKTVTNAVITVPAYFNDSQRQATKDAG 157
>gnl|CDD|212681 cd10241, HSPA5-like_NBD, Nucleotide-binding domain of human HSPA5
and similar proteins. This subfamily includes human
HSPA5 (also known as 70-kDa heat shock protein 5,
glucose-regulated protein 78/GRP78, and immunoglobulin
heavy chain-binding protein/BIP, MIF2; the gene encoding
HSPA5 maps to 9q33.3.), Sacchaormyces cerevisiae Kar2p
(also known as Grp78p), and related proteins. This
subfamily belongs to the heat shock protein 70 (HSP70)
family of chaperones that assist in protein folding and
assembly and can direct incompetent "client" proteins
towards degradation. HSPA5 and Kar2p are chaperones of
the endoplasmic reticulum (ER). Typically, HSP70s have a
nucleotide-binding domain (NBD) and a substrate-binding
domain (SBD). The nucleotide sits in a deep cleft formed
between the two lobes of the NBD. The two subdomains of
each lobe change conformation between ATP-bound,
ADP-bound, and nucleotide-free states. ATP binding opens
up the substrate-binding site; substrate-binding
increases the rate of ATP hydrolysis. HSP70 chaperone
activity is regulated by various co-chaperones: J-domain
proteins and nucleotide exchange factors (NEFs).
Multiple ER DNAJ domain proteins have been identified
and may exist in distinct complexes with HSPA5 in
various locations in the ER, for example DNAJC3-p58IPK
in the lumen. HSPA5-NEFs include SIL1 and an atypical
HSP70 family protein HYOU1/ORP150. The ATPase activity
of Kar2p is stimulated by the NEFs: Sil1p and Lhs1p.
Length = 374
Score = 179 bits (456), Expect = 5e-57
Identities = 71/102 (69%), Positives = 87/102 (85%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEIS 60
NP+NT+FD KRLIGRKF+D+++Q+DIK P+ VV+ GKP I+V+ KGE K F+PEEIS
Sbjct: 58 SNPENTIFDVKRLIGRKFDDKEVQKDIKLLPYKVVNKDGKPYIEVDVKGEKKTFSPEEIS 117
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+MVLTKM+EIAE YLG KV AV+TVPAYFND+QRQATKDAG
Sbjct: 118 AMVLTKMKEIAEAYLGKKVKHAVVTVPAYFNDAQRQATKDAG 159
>gnl|CDD|240227 PTZ00009, PTZ00009, heat shock 70 kDa protein; Provisional.
Length = 653
Score = 184 bits (470), Expect = 7e-57
Identities = 74/103 (71%), Positives = 85/103 (82%), Gaps = 1/103 (0%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDG-GKPKIQVEYKGEIKKFAPEEI 59
NP+NTVFDAKRLIGRKF+D +Q D+KHWPF V + G KP I+V Y+GE K F PEEI
Sbjct: 61 RNPENTVFDAKRLIGRKFDDSVVQSDMKHWPFKVTTGGDDKPMIEVTYQGEKKTFHPEEI 120
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
SSMVL KM+EIAE YLG +V +AV+TVPAYFNDSQRQATKDAG
Sbjct: 121 SSMVLQKMKEIAEAYLGKQVKDAVVTVPAYFNDSQRQATKDAG 163
>gnl|CDD|215656 pfam00012, HSP70, Hsp70 protein. Hsp70 chaperones help to fold
many proteins. Hsp70 assisted folding involves repeated
cycles of substrate binding and release. Hsp70 activity
is ATP dependent. Hsp70 proteins are made up of two
regions: the amino terminus is the ATPase domain and the
carboxyl terminus is the substrate binding region.
Length = 598
Score = 170 bits (434), Expect = 6e-52
Identities = 65/103 (63%), Positives = 76/103 (73%), Gaps = 3/103 (2%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVV-SDGGKPKIQVEYKGEIKKFAPEEI 59
NPKNTVF KRLIGRKF D +Q DIKH P+ VV G ++V Y GE F PE+I
Sbjct: 56 TNPKNTVFSVKRLIGRKFSDPVVQRDIKHVPYKVVKLPNGDAGVEVRYLGE--TFTPEQI 113
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
S+MVL K++E AE YLG V++AVITVPAYFND+QRQATKDAG
Sbjct: 114 SAMVLQKLKETAEAYLGEPVTDAVITVPAYFNDAQRQATKDAG 156
>gnl|CDD|234715 PRK00290, dnaK, molecular chaperone DnaK; Provisional.
Length = 627
Score = 141 bits (359), Expect = 5e-41
Identities = 59/103 (57%), Positives = 77/103 (74%), Gaps = 7/103 (6%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVS-DGGKPKIQVEYKGEIKKFAPEEI 59
NP+NT+F KRL+GR+ E+ +Q+DIK P+ +V D G VE G KK+ P+EI
Sbjct: 60 TNPENTIFSIKRLMGRRDEE--VQKDIKLVPYKIVKADNGDAW--VEIDG--KKYTPQEI 113
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
S+M+L K+++ AE YLG KV+EAVITVPAYFND+QRQATKDAG
Sbjct: 114 SAMILQKLKKDAEDYLGEKVTEAVITVPAYFNDAQRQATKDAG 156
>gnl|CDD|212683 cd11733, HSPA9-like_NBD, Nucleotide-binding domain of human HSPA9,
Escherichia coli DnaK, and similar proteins. This
subgroup includes human mitochondrial HSPA9 (also known
as 70-kDa heat shock protein 9, CSA; MOT; MOT2; GRP75;
PBP74; GRP-75; HSPA9B; MTHSP75; the gene encoding HSPA9
maps to 5q31.1), Escherichia coli DnaK, and
Saccharomyces cerevisiae Stress-Seventy subfamily
C/Ssc1p (also called mtHSP70, Endonuclease SceI 75 kDa
subunit). It belongs to the heat shock protein 70
(HSP70) family of chaperones that assist in protein
folding and assembly, and can direct incompetent
"client" proteins towards degradation. Typically, HSP70s
have a nucleotide-binding domain (NBD) and a
substrate-binding domain (SBD). The nucleotide sits in a
deep cleft formed between the two lobes of the NBD. The
two subdomains of each lobe change conformation between
ATP-bound, ADP-bound, and nucleotide-free states. ATP
binding opens up the substrate-binding site;
substrate-binding increases the rate of ATP hydrolysis.
Hsp70 chaperone activity is regulated by various
co-chaperones: J-domain proteins and nucleotide exchange
factors (NEFs); for Escherichia coli DnaK, these are the
DnaJ and GrpE, respectively. HSPA9 is involved in
multiple processses including mitochondrial import,
antigen processing, control of cellular proliferation
and differentiation, and regulation of glucose
responses. During glucose deprivation-induced cellular
stress, HSPA9 plays an important role in the suppression
of apoptosis by inhibiting a conformational change in
Bax that allow the release of cytochrome c. DnaK
modulates the heat shock response in Escherichia coli.
It protects E. coli from protein carbonylation, an
irreversible oxidative modification that increases
during organism aging and bacterial growth arrest. Under
severe thermal stress, it functions as part of a
bi-chaperone system: the DnaK system and the
ring-forming AAA+ chaperone ClpB (Hsp104) system, to
promote cell survival. DnaK has also been shown to
cooperate with GroEL and the ribosome-associated
Escherichia coli Trigger Factor in the proper folding of
cytosolic proteins. S. cerevisiae Ssc1p is the major
HSP70 chaperone of the mitochondrial matrix, promoting
translocation of proteins from the cytosol, across the
inner membrane, to the matrix, and their subsequent
folding. Ssc1p interacts with Tim44, a peripheral inner
membrane protein associated with the TIM23 protein
translocase. It is also a subunit of the endoSceI
site-specific endoDNase and is required for full
endoSceI activity. Ssc1p plays roles in the import of
Yfh1p, a nucleus-encoded mitochondrial protein involved
in iron homeostasis (and a homolog of human frataxin,
implicated in the neurodegenerative disease,
Friedreich's ataxia). Ssc1 also participates in
translational regulation of cytochrome c oxidase (COX)
biogenesis by interacting with Mss51 and
Mss51-containing complexes.
Length = 377
Score = 135 bits (341), Expect = 7e-40
Identities = 59/103 (57%), Positives = 76/103 (73%), Gaps = 7/103 (6%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVV--SDGGKPKIQVEYKGEIKKFAPEEI 59
NP+NT++ KRLIGR+F+D ++Q+DIK+ P+ +V S+G VE G KK++P +I
Sbjct: 61 NPENTLYATKRLIGRRFDDPEVQKDIKNVPYKIVKASNG---DAWVEAHG--KKYSPSQI 115
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+ VL KM+E AE YLG V AVITVPAYFNDSQRQATKDAG
Sbjct: 116 GAFVLMKMKETAEAYLGKPVKNAVITVPAYFNDSQRQATKDAG 158
>gnl|CDD|212670 cd10228, HSPA4_like_NDB, Nucleotide-binding domain of 105/110 kDa
heat shock proteins including HSPA4 and similar
proteins. This subgroup includes the human proteins,
HSPA4 (also known as 70-kDa heat shock protein 4, APG-2,
HS24/P52, hsp70 RY, and HSPH2; the human HSPA4 gene maps
to 5q31.1), HSPA4L (also known as 70-kDa heat shock
protein 4-like, APG-1, HSPH3, and OSP94; the human
HSPA4L gene maps to 4q28), and HSPH1 (also known as heat
shock 105kDa/110kDa protein 1, HSP105; HSP105A; HSP105B;
NY-CO-25; the human HSPH1 gene maps to 13q12.3),
Saccharomyces cerevisiae Sse1p and Sse2p, and a sea
urchin sperm receptor. It belongs to the 105/110 kDa
heat shock protein (HSP105/110) subfamily of the
HSP70-like family, and includes proteins believed to
function generally as co-chaperones of HSP70 chaperones,
acting as nucleotide exchange factors (NEFs), to remove
ADP from their HSP70 chaperone partners during the ATP
hydrolysis cycle. HSP70 chaperones assist in protein
folding and assembly, and can direct incompetent
"client" proteins towards degradation. Like HSP70
chaperones, HSP105/110s have an N-terminal
nucleotide-binding domain (NBD) and a C-terminal
substrate-binding domain (SBD). For HSP70 chaperones,
the nucleotide sits in a deep cleft formed between the
two lobes of the NBD. The two subdomains of each lobe
change conformation between ATP-bound, ADP-bound, and
nucleotide-free states. ATP binding opens up the
substrate-binding site; substrate-binding increases the
rate of ATP hydrolysis. Hsp70 chaperone activity is also
regulated by J-domain proteins.
Length = 381
Score = 133 bits (338), Expect = 2e-39
Identities = 54/102 (52%), Positives = 75/102 (73%), Gaps = 1/102 (0%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPF-TVVSDGGKPKIQVEYKGEIKKFAPEEI 59
N KNTV + KRLIGRKF+D ++Q+++K PF V GK I+V Y GE K F+PE++
Sbjct: 57 SNFKNTVRNFKRLIGRKFDDPEVQKELKFLPFKVVELPDGKVGIKVNYLGEEKVFSPEQV 116
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDA 101
+M+LTK++EIAE L GKV++ VI+VP+YF D+QR+A DA
Sbjct: 117 LAMLLTKLKEIAEKALKGKVTDCVISVPSYFTDAQRRALLDA 158
>gnl|CDD|212676 cd10234, HSPA9-Ssq1-like_NBD, Nucleotide-binding domain of human
HSPA9 and similar proteins. This subfamily includes
human mitochondrial HSPA9 (also known as 70-kDa heat
shock protein 9, CSA; MOT; MOT2; GRP75; PBP74; GRP-75;
HSPA9B; MTHSP75; the gene encoding HSPA9 maps to
5q31.1), Escherichia coli DnaK, Saccharomyces cerevisiae
Stress-seventy subfamily Q protein 1/Ssq1p (also called
Ssc2p, Ssh1p, mtHSP70 homolog), and S. cerevisiae
Stress-Seventy subfamily C/Ssc1p (also called mtHSP70,
Endonuclease SceI 75 kDa subunit). It belongs to the
heat shock protein 70 (HSP70) family of chaperones that
assist in protein folding and assembly, and can direct
incompetent "client" proteins towards degradation.
Typically, HSP70s have a nucleotide-binding domain (NBD)
and a substrate-binding domain (SBD). The nucleotide
sits in a deep cleft formed between the two lobes of the
NBD. The two subdomains of each lobe change conformation
between ATP-bound, ADP-bound, and nucleotide-free
states. ATP binding opens up the substrate-binding site;
substrate-binding increases the rate of ATP hydrolysis.
Hsp70 chaperone activity is regulated by various
co-chaperones: J-domain proteins and nucleotide exchange
factors (NEFs); for Escherichia coli DnaK, these are the
DnaJ and GrpE, respectively.
Length = 376
Score = 132 bits (333), Expect = 1e-38
Identities = 55/102 (53%), Positives = 76/102 (74%), Gaps = 4/102 (3%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEIS 60
NP+NT+F KR +GRKF++ + + + + VV +GG K++++ G K + P+EIS
Sbjct: 60 TNPENTIFSIKRFMGRKFDEVEEERKVPYKV--VVDEGGNYKVEIDSNG--KDYTPQEIS 115
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+M+L K++E AE YLG KV+EAVITVPAYFNDSQRQATKDAG
Sbjct: 116 AMILQKLKEDAEAYLGEKVTEAVITVPAYFNDSQRQATKDAG 157
>gnl|CDD|233830 TIGR02350, prok_dnaK, chaperone protein DnaK. Members of this
family are the chaperone DnaK, of the DnaK-DnaJ-GrpE
chaperone system. All members of the seed alignment were
taken from completely sequenced bacterial or archaeal
genomes and (except for Mycoplasma sequence) found
clustered with other genes of this systems. This model
excludes DnaK homologs that are not DnaK itself, such as
the heat shock cognate protein HscA (TIGR01991).
However, it is not designed to distinguish among DnaK
paralogs in eukaryotes. Note that a number of dnaK genes
have shadow ORFs in the same reverse (relative to dnaK)
reading frame, a few of which have been assigned
glutamate dehydrogenase activity. The significance of
this observation is unclear; lengths of such shadow ORFs
are highly variable as if the presumptive protein
product is not conserved [Protein fate, Protein folding
and stabilization].
Length = 595
Score = 132 bits (333), Expect = 2e-37
Identities = 54/101 (53%), Positives = 78/101 (77%), Gaps = 6/101 (5%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEISS 61
NP+NT++ KR +GR+F+ ++ E+ K P+ VV DGG +++V+ K ++ P+EIS+
Sbjct: 59 NPENTIYSIKRFMGRRFD--EVTEEAKRVPYKVVGDGGDVRVKVDGK----EYTPQEISA 112
Query: 62 MVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
M+L K+++ AE YLG KV+EAVITVPAYFND+QRQATKDAG
Sbjct: 113 MILQKLKKDAEAYLGEKVTEAVITVPAYFNDAQRQATKDAG 153
>gnl|CDD|212667 cd10170, HSP70_NBD, Nucleotide-binding domain of the HSP70 family.
HSP70 (70-kDa heat shock protein) family chaperones
assist in protein folding and assembly and can direct
incompetent "client" proteins towards degradation.
Typically, HSP70s have a nucleotide-binding domain (NBD)
and a substrate-binding domain (SBD). The nucleotide
sits in a deep cleft formed between the two lobes of the
NBD. The two subdomains of each lobe change conformation
between ATP-bound, ADP-bound, and nucleotide-free
states. ATP binding opens up the substrate-binding site;
substrate-binding increases the rate of ATP hydrolysis.
HSP70 chaperone activity is regulated by various
co-chaperones: J-domain proteins and nucleotide exchange
factors (NEFs). Some HSP70 family members are not
chaperones but instead, function as NEFs to remove ADP
from their HSP70 chaperone partners during the ATP
hydrolysis cycle, some may function as both chaperones
and NEFs.
Length = 369
Score = 127 bits (322), Expect = 4e-37
Identities = 55/102 (53%), Positives = 72/102 (70%), Gaps = 4/102 (3%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEIS 60
NP+NTV D KRLIGRKF+D +Q K + D G P I V + KK++PEE+S
Sbjct: 57 DNPENTVGDFKRLIGRKFDDPLVQSAKKV----IGVDRGAPIIPVPVELGGKKYSPEEVS 112
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+++L K++E AE YLG V+EAVITVPAYFND+QR+ATK+A
Sbjct: 113 ALILKKLKEDAEAYLGEPVTEAVITVPAYFNDAQREATKEAA 154
>gnl|CDD|212684 cd11734, Ssq1_like_NBD, Nucleotide-binding domain of Saccharomyces
cerevisiae Ssq1 and similar proteins. Ssq1p (also
called Stress-seventy subfamily Q protein 1, Ssc2p,
Ssh1p, mtHSP70 homolog) belongs to the heat shock
protein 70 (HSP70) family of chaperones that assist in
protein folding and assembly, and can direct incompetent
"client" proteins towards degradation. Typically, HSP70s
have a nucleotide-binding domain (NBD) and a
substrate-binding domain (SBD). The nucleotide sits in a
deep cleft formed between the two lobes of the NBD. The
two subdomains of each lobe change conformation between
ATP-bound, ADP-bound, and nucleotide-free states. ATP
binding opens up the substrate-binding site;
substrate-binding increases the rate of ATP hydrolysis.
Hsp70 chaperone activity is regulated by various
co-chaperones: J-domain proteins and nucleotide exchange
factors (NEFs). S. cerevisiae Ssq1p is a mitochondrial
chaperone that is involved in iron-sulfur (Fe/S) center
biogenesis. Ssq1p plays a role in the maturation of
Yfh1p, a nucleus-encoded mitochondrial protein involved
in iron homeostasis (and a homolog of human frataxin,
implicated in the neurodegenerative disease,
Friedreich's ataxia).
Length = 373
Score = 116 bits (291), Expect = 1e-32
Identities = 54/103 (52%), Positives = 72/103 (69%), Gaps = 5/103 (4%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVV-SDGGKPKIQVEYKGEIKKFAPEEI 59
++P+NT F KRLIGR+F+D ++Q +K + +V G I G KK++P +I
Sbjct: 59 LHPENTFFATKRLIGRQFKDVEVQRKMKVPYYKIVEGRNGDAWIYT--NG--KKYSPSQI 114
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+S VL K+++ AE YLG +V EAVITVPAYFNDSQRQATKDAG
Sbjct: 115 ASFVLKKLKKTAEAYLGKRVDEAVITVPAYFNDSQRQATKDAG 157
>gnl|CDD|240403 PTZ00400, PTZ00400, DnaK-type molecular chaperone; Provisional.
Length = 663
Score = 118 bits (296), Expect = 2e-32
Identities = 54/101 (53%), Positives = 72/101 (71%), Gaps = 3/101 (2%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEISS 61
NP+NTVF KRLIGR++++ +++ K P+ +V +E +G KK++P +I +
Sbjct: 100 NPENTVFATKRLIGRRYDEDATKKEQKILPYKIVRASNG-DAWIEAQG--KKYSPSQIGA 156
Query: 62 MVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
VL KM+E AE YLG KV +AVITVPAYFNDSQRQATKDAG
Sbjct: 157 FVLEKMKETAESYLGRKVKQAVITVPAYFNDSQRQATKDAG 197
>gnl|CDD|214360 CHL00094, dnaK, heat shock protein 70.
Length = 621
Score = 116 bits (293), Expect = 6e-32
Identities = 55/102 (53%), Positives = 69/102 (67%), Gaps = 3/102 (2%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEIS 60
+NP+NT + KR IGRKF + I E+ K + V +D I++E K F+PEEIS
Sbjct: 60 INPENTFYSVKRFIGRKFSE--ISEEAKQVSYKVKTDS-NGNIKIECPALNKDFSPEEIS 116
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+ VL K+ E A YLG V++AVITVPAYFNDSQRQATKDAG
Sbjct: 117 AQVLRKLVEDASKYLGETVTQAVITVPAYFNDSQRQATKDAG 158
>gnl|CDD|184038 PRK13410, PRK13410, molecular chaperone DnaK; Provisional.
Length = 668
Score = 112 bits (281), Expect = 3e-30
Identities = 49/106 (46%), Positives = 74/106 (69%), Gaps = 11/106 (10%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDG-GKPKI---QVEYKGEIKKFAP 56
+NP+NT ++ KR IGR++++ + + K P+T+ + G +I ++E ++FAP
Sbjct: 60 LNPQNTFYNLKRFIGRRYDE--LDPESKRVPYTIRRNEQGNVRIKCPRLE-----REFAP 112
Query: 57 EEISSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
EE+S+M+L K+ + A YLG V+ AVITVPAYFNDSQRQAT+DAG
Sbjct: 113 EELSAMILRKLADDASRYLGEPVTGAVITVPAYFNDSQRQATRDAG 158
>gnl|CDD|140213 PTZ00186, PTZ00186, heat shock 70 kDa precursor protein;
Provisional.
Length = 657
Score = 110 bits (277), Expect = 6e-30
Identities = 55/102 (53%), Positives = 75/102 (73%), Gaps = 4/102 (3%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVV-SDGGKPKIQVEYKGEIKKFAPEEIS 60
NP++T + KRLIGR+FED+ IQ+DIK+ P+ +V + G +Q G K+++P +I
Sbjct: 85 NPQSTFYAVKRLIGRRFEDEHIQKDIKNVPYKIVRAGNGDAWVQ---DGNGKQYSPSQIG 141
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+ VL KM+E AE +LG KVS AV+T PAYFND+QRQATKDAG
Sbjct: 142 AFVLEKMKETAENFLGHKVSNAVVTCPAYFNDAQRQATKDAG 183
>gnl|CDD|223520 COG0443, DnaK, Molecular chaperone [Posttranslational modification,
protein turnover, chaperones].
Length = 579
Score = 105 bits (264), Expect = 5e-28
Identities = 53/102 (51%), Positives = 63/102 (61%), Gaps = 22/102 (21%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEIS 60
NP+NT+F KR IGR KI VE G KK+ PEEIS
Sbjct: 64 DNPENTIFSIKRKIGRG--------------------SNGLKISVEVDG--KKYTPEEIS 101
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+M+LTK++E AE YLG KV++AVITVPAYFND+QRQATKDA
Sbjct: 102 AMILTKLKEDAEAYLGEKVTDAVITVPAYFNDAQRQATKDAA 143
>gnl|CDD|184039 PRK13411, PRK13411, molecular chaperone DnaK; Provisional.
Length = 653
Score = 105 bits (264), Expect = 5e-28
Identities = 49/101 (48%), Positives = 71/101 (70%), Gaps = 5/101 (4%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEISS 61
N +NTV+ KR IGR+++D +E+ P+T V G + V+ +G + + P+EIS+
Sbjct: 61 NAENTVYSIKRFIGRRWDDT--EEERSRVPYTCVK-GRDDTVNVQIRG--RNYTPQEISA 115
Query: 62 MVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
M+L K+++ AE YLG V++AVITVPAYF D+QRQATKDAG
Sbjct: 116 MILQKLKQDAEAYLGEPVTQAVITVPAYFTDAQRQATKDAG 156
>gnl|CDD|215618 PLN03184, PLN03184, chloroplast Hsp70; Provisional.
Length = 673
Score = 105 bits (263), Expect = 7e-28
Identities = 53/103 (51%), Positives = 67/103 (65%), Gaps = 5/103 (4%)
Query: 1 MNPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSD-GGKPKIQVEYKGEIKKFAPEEI 59
+NP+NT F KR IGRK + + E+ K + VV D G K+ G K+FA EEI
Sbjct: 97 VNPENTFFSVKRFIGRKMSE--VDEESKQVSYRVVRDENGNVKLDCPAIG--KQFAAEEI 152
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
S+ VL K+ + A +L KV++AVITVPAYFNDSQR ATKDAG
Sbjct: 153 SAQVLRKLVDDASKFLNDKVTKAVITVPAYFNDSQRTATKDAG 195
>gnl|CDD|212678 cd10236, HscA_like_NBD, Nucleotide-binding domain of HscA and
similar proteins. Escherichia coli HscA (heat shock
cognate protein A, also called Hsc66), belongs to the
heat shock protein 70 (HSP70) family of chaperones that
assist in protein folding and assembly and can direct
incompetent "client" proteins towards degradation.
Typically, HSP70s have a nucleotide-binding domain (NBD)
and a substrate-binding domain (SBD). The nucleotide
sits in a deep cleft formed between the two lobes of the
NBD. The two subdomains of each lobe change conformation
between ATP-bound, ADP-bound, and nucleotide-free
states. ATP binding opens up the substrate-binding site;
substrate-binding increases the rate of ATP hydrolysis.
HSP70 chaperone activity is regulated by various
co-chaperones: J-domain proteins and nucleotide exchange
factors (NEFs). HscA's partner J-domain protein is HscB;
it does not appear to require a NEF, and has been shown
to be induced by cold-shock. The HscA-HscB
chaperone/co-chaperone pair is involved in [Fe-S]
cluster assembly.
Length = 355
Score = 96.9 bits (242), Expect = 2e-25
Identities = 42/100 (42%), Positives = 59/100 (59%), Gaps = 6/100 (6%)
Query: 3 PKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEISSM 62
PKNT+ KRL+G+ ED I++ + P +GG + P E+S+
Sbjct: 59 PKNTISSVKRLMGKSIED--IKKSFPYLPILEGKNGGIILFHTQ----QGTVTPVEVSAE 112
Query: 63 VLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+L ++E AE LGG++ AVITVPAYF+D+QRQATKDA
Sbjct: 113 ILKALKERAEKSLGGEIKGAVITVPAYFDDAQRQATKDAA 152
>gnl|CDD|212679 cd10237, HSPA13-like_NBD, Nucleotide-binding domain of human HSPA13
and similar proteins. Human HSPA13 (also called 70-kDa
heat shock protein 13, STCH, "stress 70 protein
chaperone, microsome-associated, 60kD", "stress 70
protein chaperone, microsome-associated, 60kDa"; the
gene encoding HSPA13 maps to 21q11.1) belongs to the
heat shock protein 70 (HSP70) family of chaperones that
assist in protein folding and assembly and can direct
incompetent "client" proteins towards degradation.
Typically, HSP70s have a nucleotide-binding domain (NBD)
and a substrate-binding domain (SBD). The nucleotide
sits in a deep cleft formed between the two lobes of the
NBD. The two subdomains of each lobe change conformation
between ATP-bound, ADP-bound, and nucleotide-free
states. ATP binding opens up the substrate-binding site;
substrate-binding increases the rate of ATP hydrolysis.
HSP70 chaperone activity is regulated by various
co-chaperones: J-domain proteins and nucleotide exchange
factors (NEFs). STCH contains an NBD but lacks an SBD.
STCH may function to regulate cell proliferation and
survival, and modulate the TRAIL-mediated cell death
pathway. The HSPA13 gene is a candidate stomach cancer
susceptibility gene; a mutation in the NBD coding region
of HSPA13 has been identified in stomach cancer cells.
The NBD of HSPA13 interacts with the ubiquitin-like
proteins Chap1 and Chap2, implicating HSPA13 in
regulating cell cycle and cell death events. HSPA13 is
induced by the Ca2+ ionophore A23187.
Length = 417
Score = 97.5 bits (243), Expect = 2e-25
Identities = 40/101 (39%), Positives = 60/101 (59%), Gaps = 1/101 (0%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSD-GGKPKIQVEYKGEIKKFAPEEIS 60
NP+NT++DAKR IG+ F ++++ + + F V + E K PEEI
Sbjct: 80 NPQNTIYDAKRFIGKIFTKEELEFESDRYRFKVKINSRNGAFFFSVLTNETKTVTPEEIG 139
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDA 101
S ++ K+R++AE YLG V +AVI+VPA F++ QR AT A
Sbjct: 140 SRLILKLRKMAEKYLGTPVGKAVISVPAEFDEKQRNATVKA 180
>gnl|CDD|235360 PRK05183, hscA, chaperone protein HscA; Provisional.
Length = 616
Score = 98.3 bits (246), Expect = 2e-25
Identities = 47/101 (46%), Positives = 64/101 (63%), Gaps = 7/101 (6%)
Query: 3 PKNTVFDAKRLIGRKFEDQKIQEDIKHWPFT-VVSDGGKPKIQVEYKGEIKKFAPEEISS 61
PKNT+ KR +GR D IQ+ H P+ V S+ G P I+ +G +P E+S+
Sbjct: 78 PKNTISSVKRFMGRSLAD--IQQRYPHLPYQFVASENGMPLIRTA-QGLK---SPVEVSA 131
Query: 62 MVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+L +R+ AE LGG++ AVITVPAYF+D+QRQATKDA
Sbjct: 132 EILKALRQRAEETLGGELDGAVITVPAYFDDAQRQATKDAA 172
>gnl|CDD|212677 cd10235, HscC_like_NBD, Nucleotide-binding domain of Escherichia
coli HscC and similar proteins. This subfamily
includes Escherichia coli HscC (also called heat shock
cognate protein C, Hsc62, or YbeW) and the the putative
DnaK-like protein Escherichia coli ECs0689. It belongs
to the heat shock protein 70 (Hsp70) family of
chaperones that assist in protein folding and assembly
and can direct incompetent "client" proteins towards
degradation. Typically, Hsp70s have a nucleotide-binding
domain (NBD) and a substrate-binding domain (SBD). The
nucleotide sits in a deep cleft formed between the two
lobes of the NBD. The two subdomains of each lobe change
conformation between ATP-bound, ADP-bound, and
nucleotide-free states. ATP binding opens up the
substrate-binding site; substrate-binding increases the
rate of ATP hydrolysis. Hsp70 chaperone activity is
regulated by various co-chaperones: J-domain proteins
and nucleotide exchange factors (NEFs). Two genes in the
vicinity of the HscC gene code for potential
cochaperones: J-domain containing proteins, DjlB/YbeS
and DjlC/YbeV. HscC and its co-chaperone partners may
play a role in the SOS DNA damage response. HscC does
not appear to require a NEF.
Length = 339
Score = 91.8 bits (229), Expect = 9e-24
Identities = 33/57 (57%), Positives = 44/57 (77%)
Query: 46 EYKGEIKKFAPEEISSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+Y+ ++F EE+SS+VL ++E AE YLG V+EAVI+VPAYFND QR+ATK AG
Sbjct: 74 KYRLGKREFRAEELSSLVLRSLKEDAEAYLGEPVTEAVISVPAYFNDEQRKATKRAG 130
>gnl|CDD|233673 TIGR01991, HscA, Fe-S protein assembly chaperone HscA. The Heat
Shock Cognate proteins HscA and HscB act together as
chaperones. HscA resembles DnaK but belongs in a
separate clade. The apparent function is to aid assembly
of iron-sulfur cluster proteins. Homologs from Buchnera
and Wolbachia are clearly in the same clade but are
highly derived and score lower than some examples of
DnaK [Protein fate, Protein folding and stabilization].
Length = 599
Score = 89.3 bits (222), Expect = 3e-22
Identities = 44/100 (44%), Positives = 60/100 (60%), Gaps = 6/100 (6%)
Query: 3 PKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEISSM 62
PKNT+ KRL+GR ED K + P+ V DG +++ P E+S+
Sbjct: 59 PKNTISSVKRLMGRSIEDIKTFSIL---PYRFV-DGPGEMVRLRTVQGTV--TPVEVSAE 112
Query: 63 VLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
+L K+++ AE LGG + AVITVPAYF+D+QRQATKDA
Sbjct: 113 ILKKLKQRAEESLGGDLVGAVITVPAYFDDAQRQATKDAA 152
>gnl|CDD|212680 cd10238, HSPA14-like_NBD, Nucleotide-binding domain of human HSPA14
and similar proteins. Human HSPA14 (also known as
70-kDa heat shock protein 14, HSP70L1, HSP70-4; the gene
encoding HSPA14 maps to 10p13), is ribosome-associated
and belongs to the heat shock protein 70 (HSP70) family
of chaperones that assist in protein folding and
assembly, and can direct incompetent "client" proteins
towards degradation. Typically, HSP70s have a
nucleotide-binding domain (NBD) and a substrate-binding
domain (SBD). The nucleotide sits in a deep cleft formed
between the two lobes of the NBD. The two subdomains of
each lobe change conformation between ATP-bound,
ADP-bound, and nucleotide-free states. ATP binding opens
up the substrate-binding site; substrate-binding
increases the rate of ATP hydrolysis. HSP70 chaperone
activity is regulated by various co-chaperones: J-domain
proteins and nucleotide exchange factors (NEFs). HSPA14
interacts with the J-protein MPP11 to form the mammalian
ribosome-associated complex (mRAC). HSPA14 participates
in a pathway along with Nijmegen breakage syndrome 1
(NBS1, also known as p85 or nibrin), heat shock
transcription factor 4b (HSF4b), and HSPA4 (belonging to
a different subfamily), that induces tumor migration,
invasion, and transformation. HSPA14 is a potent T
helper cell (Th1) polarizing adjuvant that contributes
to antitumor immune responses.
Length = 375
Score = 88.2 bits (219), Expect = 3e-22
Identities = 31/100 (31%), Positives = 59/100 (59%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEISS 61
N NT+ K+++GR + D Q++ ++ G+PK ++ + + K +P+E++
Sbjct: 58 NAANTIVKNKQILGRSYSDPFKQKEKTESSCKIIEKDGEPKYEIFTEEKTKHVSPKEVAK 117
Query: 62 MVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDA 101
++ KM+EIA+ LG + VITVP YF++ Q+ A ++A
Sbjct: 118 LIFKKMKEIAQSALGSDSKDVVITVPVYFSEKQKLALREA 157
>gnl|CDD|212689 cd11739, HSPH1_NBD, Nucleotide-binding domain of HSPH1. Human
HSPH1 (also known as heat shock 105kDa/110kDa protein 1,
HSP105; HSP105A; HSP105B; NY-CO-25; the human HSPH1 gene
maps to 13q12.3) suppresses the aggregation of denatured
proteins caused by heat shock in vitro, and may
substitute for HSP70 family proteins to suppress the
aggregation of denatured proteins in cells under severe
stress. It reduces the protein aggregation and
cytotoxicity associated with Polyglutamine (PolyQ)
diseases, including Huntington's disease, which are a
group of inherited neurodegenerative disorders sharing
the characteristic feature of having insoluble protein
aggregates in neurons. The expression of HSPH1 is
elevated in various malignant tumors, including
malignant melanoma, and there is a direct correlation
between HSPH1 expression and B-cell non-Hodgkin
lymphomas (B-NHLs) aggressiveness and proliferation.
HSPH1 belongs to the 105/110 kDa heat shock protein
(HSP105/110) subfamily of the HSP70-like family.
HSP105/110s are believed to function generally as
co-chaperones of HSP70 chaperones, acting as nucleotide
exchange factors (NEFs), to remove ADP from their HSP70
chaperone partners during the ATP hydrolysis cycle.
HSP70 chaperones assist in protein folding and assembly,
and can direct incompetent "client" proteins towards
degradation. Like HSP70 chaperones, HSP105/110s have an
N-terminal nucleotide-binding domain (NBD) and a
C-terminal substrate-binding domain (SBD). For HSP70
chaperones, the nucleotide sits in a deep cleft formed
between the two lobes of the NBD. The two subdomains of
each lobe change conformation between ATP-bound,
ADP-bound, and nucleotide-free states. ATP binding opens
up the substrate-binding site; substrate-binding
increases the rate of ATP hydrolysis. Hsp70 chaperone
activity is also regulated by J-domain proteins.
Length = 383
Score = 86.5 bits (214), Expect = 1e-21
Identities = 37/101 (36%), Positives = 64/101 (63%), Gaps = 1/101 (0%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVS-DGGKPKIQVEYKGEIKKFAPEEIS 60
+ NTV + KR GR F D +Q++ ++ + +V G ++V Y GE F+ E+I+
Sbjct: 58 HANNTVSNFKRFHGRAFNDPFVQKEKENLSYDLVPLKNGGVGVKVMYMGEEHLFSVEQIT 117
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDA 101
+M+LTK++E AE L V++ VI+VP++F D++R++ DA
Sbjct: 118 AMLLTKLKETAENNLKKPVTDCVISVPSFFTDAERRSVLDA 158
>gnl|CDD|212674 cd10232, ScSsz1p_like_NBD, Nucleotide-binding domain of
Saccharmomyces cerevisiae Ssz1pp and similar proteins.
Saccharomyces cerevisiae Ssz1p (also known as
/Pdr13p/YHR064C) belongs to the heat shock protein 70
(HSP70) family of chaperones that assist in protein
folding and assembly and can direct incompetent "client"
proteins towards degradation. Typically, HSP70s have a
nucleotide-binding domain (NBD) and a substrate-binding
domain (SBD). The nucleotide sits in a deep cleft formed
between the two lobes of the NBD. The two subdomains of
each lobe change conformation between ATP-bound,
ADP-bound, and nucleotide-free states. ATP binding opens
up the substrate-binding site; substrate-binding
increases the rate of ATP hydrolysis. HSP70 chaperone
activity is regulated by various co-chaperones: J-domain
proteins and nucleotide exchange factors (NEFs). Some
family members are not chaperones but rather, function
as NEFs for their Hsp70 partners, while other family
members function as both chaperones and NEFs. Ssz1 does
not function as a chaperone; it facilitates the
interaction between the HSP70 Ssb protein and its
partner J-domain protein Zuo1 (also known as zuotin) on
the ribosome. Ssz1 is found in a stable heterodimer
(called RAC, ribosome associated complex) with Zuo1.
Zuo1 can only stimulate the ATPase activity of Ssb, when
it is in complex with Ssz1. Ssz1 binds ATP but neither
nucleotide-binding, hydrolysis, or its SBD, is needed
for its in vivo function.
Length = 386
Score = 75.1 bits (185), Expect = 2e-17
Identities = 30/102 (29%), Positives = 53/102 (51%), Gaps = 2/102 (1%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIK--HWPFTVVSDGGKPKIQVEYKGEIKKFAPEEI 59
N KNT+ + + L+G+ F + + P V+ GG + + E + E+
Sbjct: 58 NAKNTITNFRDLLGKPFSEIDVSAAAAAAPVPVAVIDVGGTVQEKEEPVPKETILTVHEV 117
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDA 101
+ L +++E AE +LG KV+ AV++VP +F+D Q +A A
Sbjct: 118 TVRFLRRLKEAAEDFLGKKVAGAVLSVPTWFSDEQTEALVKA 159
>gnl|CDD|212672 cd10230, HYOU1-like_NBD, Nucleotide-binding domain of human HYOU1
and similar proteins. This subgroup includes human
HYOU1 (also known as human hypoxia up-regulated 1,
GRP170; HSP12A; ORP150; GRP-170; ORP-150; the human
HYOU1 gene maps to11q23.1-q23.3) and Saccharomyces
cerevisiae Lhs1p (also known as Cer1p, SsI1). Mammalian
HYOU1 functions as a nucleotide exchange factor (NEF)
for HSPA5 (alos known as BiP, Grp78 or HspA5) and may
also function as a HSPA5-independent chaperone. S.
cerevisiae Lhs1p, does not have a detectable endogenous
ATPase activity like canonical HSP70s, but functions as
a NEF for Kar2p; it's interaction with Kar2p is
stimulated by nucleotide-binding. In addition, Lhs1p has
a nucleotide-independent holdase activity that prevents
heat-induced aggregation of proteins in vitro. This
subgroup belongs to the 105/110 kDa heat shock protein
(HSP105/110) subfamily of the HSP70-like family.
HSP105/110s are believed to function generally as
co-chaperones of HSP70 chaperones, acting as NEFs, to
remove ADP from their HSP70 chaperone partners during
the ATP hydrolysis cycle. HSP70 chaperones assist in
protein folding and assembly, and can direct incompetent
"client" proteins towards degradation. Like HSP70
chaperones, HSP105/110s have an N-terminal
nucleotide-binding domain (NBD) and a C-terminal
substrate-binding domain (SBD). For HSP70 chaperones,
the nucleotide sits in a deep cleft formed between the
two lobes of the NBD. The two subdomains of each lobe
change conformation between ATP-bound, ADP-bound, and
nucleotide-free states. ATP binding opens up the
substrate-binding site; substrate-binding increases the
rate of ATP hydrolysis. Hsp70 chaperone activity is also
regulated by J-domain proteins.
Length = 388
Score = 70.7 bits (174), Expect = 7e-16
Identities = 26/102 (25%), Positives = 46/102 (45%), Gaps = 3/102 (2%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVSDGGKPK-IQVEYKGEIKKFAPEEIS 60
P+ K L+G+ +D + P + + + + ++ EE+
Sbjct: 57 FPQQVYLHLKDLLGKPADDPSVSLYQSRHPLPYLVVDESRGTVAFKISDGEE-YSVEELV 115
Query: 61 SMVLTKMREIAEVYLGG-KVSEAVITVPAYFNDSQRQATKDA 101
+M+L +++AE + V + VITVP YF +QRQA DA
Sbjct: 116 AMILNYAKKLAEEHAKEAPVKDVVITVPPYFTQAQRQALLDA 157
>gnl|CDD|212688 cd11738, HSPA4L_NBD, Nucleotide-binding domain of HSPA4L. Human
HSPA4L (also known as 70-kDa heat shock protein 4-like,
APG-1, HSPH3, and OSP94; the human HSPA4L gene maps to
4q28) is expressed ubiquitously and predominantly in the
testis. It is required for normal spermatogenesis and
plays a role in osmotolerance. HSPA4L belongs to the
105/110 kDa heat shock protein (HSP105/110) subfamily of
the HSP70-like family. HSP105/110s are believed to
function generally as co-chaperones of HSP70 chaperones,
acting as nucleotide exchange factors (NEFs), to remove
ADP from their HSP70 chaperone partners during the ATP
hydrolysis cycle. HSP70 chaperones assist in protein
folding and assembly, and can direct incompetent
"client" proteins towards degradation. Like HSP70
chaperones, HSP105/110s have an N-terminal
nucleotide-binding domain (NBD) and a C-terminal
substrate-binding domain (SBD). For HSP70 chaperones,
the nucleotide sits in a deep cleft formed between the
two lobes of the NBD. The two subdomains of each lobe
change conformation between ATP-bound, ADP-bound, and
nucleotide-free states. ATP binding opens up the
substrate-binding site; substrate-binding increases the
rate of ATP hydrolysis. Hsp70 chaperone activity is also
regulated by J-domain proteins.
Length = 383
Score = 67.0 bits (163), Expect = 2e-14
Identities = 32/102 (31%), Positives = 60/102 (58%), Gaps = 1/102 (0%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVS-DGGKPKIQVEYKGEIKKFAPEEIS 60
N +NT+ K+L GR F+D +Q + P+ + G ++V Y E + FA E+++
Sbjct: 58 NVRNTIHGFKKLHGRSFDDPIVQTERIRLPYELQKMPNGSVGVKVRYLEEERPFAIEQVT 117
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDAG 102
M+L K++E +E L V++ VI++P++F D++R++ A
Sbjct: 118 GMLLAKLKETSENALKKPVADCVISIPSFFTDAERRSVMAAA 159
>gnl|CDD|212687 cd11737, HSPA4_NBD, Nucleotide-binding domain of HSPA4. Human
HSPA4 (also known as 70-kDa heat shock protein 4, APG-2,
HS24/P52, hsp70 RY, and HSPH2; the human HSPA4 gene maps
to 5q31.1) responds to acidic pH stress, is involved in
the radioadaptive response, is required for normal
spermatogenesis and is overexpressed in hepatocellular
carcinoma. It participates in a pathway along with NBS1
(Nijmegen breakage syndrome 1, also known as p85 or
nibrin), heat shock transcription factor 4b (HDF4b), and
HSPA14 (belonging to a different HSP70 subfamily) that
induces tumor migration, invasion, and transformation.
HSPA4 expression in sperm was increased in men with
oligozoospermia, especially in those with varicocele.
HSPA4 belongs to the 105/110 kDa heat shock protein
(HSP105/110) subfamily of the HSP70-like family.
HSP105/110s are believed to function generally as
co-chaperones of HSP70 chaperones, acting as nucleotide
exchange factors (NEFs), to remove ADP from their HSP70
chaperone partners during the ATP hydrolysis cycle.
HSP70 chaperones assist in protein folding and assembly,
and can direct incompetent "client" proteins towards
degradation. Like HSP70 chaperones, HSP105/110s have an
N-terminal nucleotide-binding domain (NBD) and a
C-terminal substrate-binding domain (SBD). For HSP70
chaperones, the nucleotide sits in a deep cleft formed
between the two lobes of the NBD. The two subdomains of
each lobe change conformation between ATP-bound,
ADP-bound, and nucleotide-free states. ATP binding opens
up the substrate-binding site; substrate-binding
increases the rate of ATP hydrolysis. Hsp70 chaperone
activity is also regulated by J-domain proteins.
Length = 383
Score = 66.2 bits (161), Expect = 3e-14
Identities = 36/101 (35%), Positives = 58/101 (57%), Gaps = 1/101 (0%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKHWPFTVVS-DGGKPKIQVEYKGEIKKFAPEEIS 60
N KNTV KR GR F D +Q + + +V G I+V Y E + F E+++
Sbjct: 58 NAKNTVQGFKRFHGRAFSDPFVQAEKPSLAYDLVQLPTGSTGIKVMYMEEERNFTTEQVT 117
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDA 101
+M+LTK++E AE L V + V++VP ++ D++R++ DA
Sbjct: 118 AMLLTKLKETAESALKKPVVDCVVSVPCFYTDAERRSVMDA 158
>gnl|CDD|212682 cd11732, HSP105-110_like_NBD, Nucleotide-binding domain of 105/110
kDa heat shock proteins including HSPA4, HYOU1, and
similar proteins. This subfamily include the human
proteins, HSPA4 (also known as 70-kDa heat shock protein
4, APG-2, HS24/P52, hsp70 RY, and HSPH2; the human HSPA4
gene maps to 5q31.1), HSPA4L (also known as 70-kDa heat
shock protein 4-like, APG-1, HSPH3, and OSP94; the human
HSPA4L gene maps to 4q28), and HSPH1 (also known as heat
shock 105kDa/110kDa protein 1, HSP105; HSP105A; HSP105B;
NY-CO-25; the human HSPH1 gene maps to 13q12.3), HYOU1
(also known as human hypoxia up-regulated 1, GRP170;
HSP12A; ORP150; GRP-170; ORP-150; the human HYOU1 gene
maps to11q23.1-q23.3), Saccharomyces cerevisiae Sse1p,
Sse2p, and Lhs1p, and a sea urchin sperm receptor. It
belongs to the 105/110 kDa heat shock protein
(HSP105/110) subfamily of the HSP70-like family, and
includes proteins believed to function generally as
co-chaperones of HSP70 chaperones, acting as nucleotide
exchange factors (NEFs), to remove ADP from their HSP70
chaperone partners during the ATP hydrolysis cycle.
HSP70 chaperones assist in protein folding and assembly,
and can direct incompetent "client" proteins towards
degradation. Like HSP70 chaperones, HSP105/110s have an
N-terminal nucleotide-binding domain (NBD) and a
C-terminal substrate-binding domain (SBD). For HSP70
chaperones, the nucleotide sits in a deep cleft formed
between the two lobes of the NBD. The two subdomains of
each lobe change conformation between ATP-bound,
ADP-bound, and nucleotide-free states. ATP binding opens
up the substrate-binding site; substrate-binding
increases the rate of ATP hydrolysis. HSP70 chaperone
activity is also regulated by J-domain proteins.
Length = 377
Score = 63.5 bits (154), Expect = 3e-13
Identities = 27/101 (26%), Positives = 51/101 (50%), Gaps = 1/101 (0%)
Query: 2 NPKNTVFDAKRLIGRKFEDQKIQEDIKH-WPFTVVSDGGKPKIQVEYKGEIKKFAPEEIS 60
N KNTV + KR+IG + +++ KH V D K +V + GE F+ +++
Sbjct: 56 NIKNTVANLKRIIGLDYHHPDFEQESKHFTSKLVELDDKKTGAEVRFAGEKHVFSATQLA 115
Query: 61 SMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQRQATKDA 101
+M + K+++ + +++ I VP ++ + QR DA
Sbjct: 116 AMFIDKVKDTVKQDTKANITDVCIAVPPWYTEEQRYNIADA 156
>gnl|CDD|234955 PRK01433, hscA, chaperone protein HscA; Provisional.
Length = 595
Score = 46.8 bits (111), Expect = 2e-07
Identities = 21/55 (38%), Positives = 32/55 (58%), Gaps = 4/55 (7%)
Query: 52 KKFAPEEISSMVLTKMREIAEVYLGGKVSEAVITVPAYFNDSQR----QATKDAG 102
K+ EI++ + ++ AE L +++AVITVPA+FND+ R A K AG
Sbjct: 114 KQLRIPEIAAEIFIYLKNQAEEQLKTNITKAVITVPAHFNDAARGEVMLAAKIAG 168
>gnl|CDD|212671 cd10229, HSPA12_like_NBD, Nucleotide-binding domain of HSPA12A,
HSPA12B and similar proteins. Human HSPA12A (also known
as 70-kDa heat shock protein-12A) and HSPA12B (also
known as 70-kDa heat shock protein-12B, chromosome 20
open reading frame 60/C20orf60, dJ1009E24.2) belong to
the heat shock protein 70 (HSP70) family of chaperones
that assist in protein folding and assembly, and can
direct incompetent "client" proteins towards
degradation. Typically, HSP70s have a nucleotide-binding
domain (NBD) and a substrate-binding domain (SBD). The
nucleotide sits in a deep cleft formed between the two
lobes of the NBD. The two subdomains of each lobe change
conformation between ATP-bound, ADP-bound, and
nucleotide-free states. ATP binding opens up the
substrate-binding site; substrate-binding increases the
rate of ATP hydrolysis. HSP70 chaperone activity is
regulated by various co-chaperones: J-domain proteins
and nucleotide exchange factors (NEFs). No co-chaperones
have yet been identified for HSPA12A or HSPA12B. The
gene encoding HSPA12A maps to 10q26.12, a cytogenetic
region that might represent a common susceptibility
locus for both schizophrenia and bipolar affective
disorder; reduced expression of HSPA12A has been shown
in the prefrontal cortex of subjects with schizophrenia.
HSPA12A is also a candidate gene for forelimb-girdle
muscular anomaly, an autosomal recessive disorder of
Japanese black cattle. HSPA12A is predominantly
expressed in neuronal cells. It may also play a role in
the atherosclerotic process. The gene encoding HSPA12B
maps to 20p13. HSPA12B is predominantly expressed in
endothelial cells, is required for angiogenesis, and may
interact with known angiogenesis mediators. It may be
important for host defense in microglia-mediated immune
response. HSPA12B expression is up-regulated in
lipopolysaccharide (LPS)-induced inflammatory response
in the spinal cord, and mostly located in active
microglia; this induced expression may be regulated by
activation of MAPK-p38, ERK1/2 and SAPK/JNK signaling
pathways. Overexpression of HSPA12B also protects
against LPS-induced cardiac dysfunction and involves the
preserved activation of the PI3K/Akt signaling pathway.
Length = 404
Score = 28.0 bits (63), Expect = 0.69
Identities = 12/39 (30%), Positives = 24/39 (61%), Gaps = 4/39 (10%)
Query: 67 MREIAEVYLGGKVSEA----VITVPAYFNDSQRQATKDA 101
+ E+ + Y G+ + V+TVPA ++D+ +QA ++A
Sbjct: 124 LEELKKTYGNGEFTALDIEWVLTVPAIWSDAAKQAMREA 162
>gnl|CDD|222557 pfam14124, DUF4291, Domain of unknown function (DUF4291). This
family of proteins is functionally uncharacterized. This
family of proteins is found in bacteria and eukaryotes.
Proteins in this family are typically between 190 and
214 amino acids in length. There are two conserved
sequence motifs: VYQAY and RMTW.
Length = 181
Score = 25.6 bits (57), Expect = 3.9
Identities = 16/49 (32%), Positives = 27/49 (55%), Gaps = 3/49 (6%)
Query: 43 IQVEYKGE-IKKFAPEEISSM--VLTKMREIAEVYLGGKVSEAVITVPA 88
IQ+ GE ++++A E I S+ V +REI ++ G + EA +P
Sbjct: 129 IQIGLSGEAVRRYADEWIVSIEDVTPLVREIRQLLDAGDLEEAKRLLPV 177
>gnl|CDD|212041 cd10333, LeuT-like_sbd, Aquifex aeolicus LeuT and related proteins;
solute binding domain. LeuT is a bacterial amino acid
transporter with specificity for the hydrophobic amino
acids glycine, alanine, methionine, and leucine. This
subgroup belongs to the solute carrier 6 (SLC6)
transporter family; LeuT has been used as a structural
template for understanding fundamental aspects of SLC6
function. It has an arrangement of 12 transmembrane
helices (TMs), which appears to be a common motif for
eukaryotic and some prokaryotic and archaeal SLC6s: an
inverted topology repeat: TMs1-5 and TMs6-10, and
TMs11-12.
Length = 500
Score = 25.7 bits (57), Expect = 4.4
Identities = 13/31 (41%), Positives = 16/31 (51%), Gaps = 5/31 (16%)
Query: 60 SSMVLTKMREIAEVYLGGKVSEAVITVPAYF 90
SS+ + E AEV LGG I +PA F
Sbjct: 260 SSLTAASLNEFAEVILGG-----SIVIPAAF 285
>gnl|CDD|236954 PRK11678, PRK11678, putative chaperone; Provisional.
Length = 450
Score = 25.6 bits (57), Expect = 5.1
Identities = 12/46 (26%), Positives = 24/46 (52%), Gaps = 5/46 (10%)
Query: 57 EEISSMVLTKMREIAEVYLGGKVSEAVITVPAYFN-----DSQRQA 97
E++ ++ +++ AE L +++AVI P F ++ RQA
Sbjct: 127 EDLVCAMMLHIKQQAEAQLQAAITQAVIGRPVNFQGLGGEEANRQA 172
>gnl|CDD|214373 CHL00139, rpl18, ribosomal protein L18; Validated.
Length = 109
Score = 25.0 bits (55), Expect = 5.7
Identities = 17/48 (35%), Positives = 24/48 (50%), Gaps = 10/48 (20%)
Query: 9 DAKRLIGRKFEDQKIQEDIKHWPFTVVSD-GGKPKIQVEYKGEIKKFA 55
DA +L+G+K + +++ I VV D GGK Y G IK A
Sbjct: 61 DASKLVGQKLAKKSLKKGITK----VVFDRGGKL-----YHGRIKALA 99
>gnl|CDD|215400 PLN02751, PLN02751, glutamyl-tRNA(Gln) amidotransferase.
Length = 544
Score = 25.6 bits (56), Expect = 5.7
Identities = 21/60 (35%), Positives = 30/60 (50%), Gaps = 6/60 (10%)
Query: 22 KIQEDIKHWPFTVVSDGGKPKIQVEYKGEIKKFAPEEISSMVLTKMREIA---EVYLGGK 78
KI ++I +++ GG K VE KG ++ P EI +MV + E E Y GGK
Sbjct: 453 KIGKEIL---PELLAKGGTVKGLVEEKGLVQISDPAEIEAMVDKVLEENPKQLEQYRGGK 509
>gnl|CDD|191163 pfam05018, DUF667, Protein of unknown function (DUF667). This
family of proteins are highly conserved in eukaryotes.
Some proteins in the family are annotated as
transcription factors. However, there is currently no
support for this in the literature.
Length = 190
Score = 25.1 bits (55), Expect = 7.6
Identities = 20/57 (35%), Positives = 27/57 (47%), Gaps = 13/57 (22%)
Query: 36 SDGGKP----KIQVEYKGEIKKFAPEEISSMVLTKMREIAEVYLGGKVSEAVITVPA 88
S G KP + + G IK+ E+I S+VL EI +G VS + IT P
Sbjct: 16 SVGSKPLQIWDMHTK-NGHIKRVTDEDIKSLVL----EI----MGTNVSTSYITCPE 63
>gnl|CDD|234257 TIGR03559, F420_Rv3520c, probable F420-dependent oxidoreductase,
Rv3520c family. Members of this protein family are
predicted to be oxidoreductases dependent on coenzyme
F420. The family includes a single member in
Mycobacterium tuberculosis (Rv3520c/MT3621) but four in
Mycobacterium smegmatis. Prediction that this family is
F420-dependent is based primarily on Partial
Phylogenetic Profiling vs. F420 biosynthesis [Unknown
function, Enzymes of unknown specificity].
Length = 325
Score = 25.0 bits (55), Expect = 9.7
Identities = 8/21 (38%), Positives = 11/21 (52%)
Query: 68 REIAEVYLGGKVSEAVITVPA 88
I ++YL G+ EA VP
Sbjct: 272 ARIQDLYLAGRKDEAAAAVPD 292
>gnl|CDD|239778 cd04245, AAK_AKiii-YclM-BS, AAK_AKiii-YclM-BS: Amino Acid Kinase
Superfamily (AAK), AKiii-YclM-BS; this CD includes the
N-terminal catalytic aspartokinase (AK) domain of the
lysine plus threonine-sensitive aspartokinase isoenzyme
AKIII, a monofunctional class enzyme found in Bacilli
(Bacillus subtilis YclM) and Clostridia species.
Aspartokinase is the first enzyme in the aspartate
metabolic pathway and catalyzes the conversion of
aspartate and ATP to aspartylphosphate and ADP. In
Bacillus subtilis (BS), YclM is reported to be a single
polypeptide of 50 kD. The Bacillus subtilis 168 AKIII is
induced by lysine and repressed by threonine, and it is
synergistically inhibited by lysine and threonine.
Length = 288
Score = 24.9 bits (55), Expect = 9.9
Identities = 15/36 (41%), Positives = 20/36 (55%), Gaps = 6/36 (16%)
Query: 56 PEEISSMVLTKMREIAEVYLGGKV--SEAVITVPAY 89
P+ IS M +MRE++ Y G V EA+I PA
Sbjct: 235 PKPISEMTYREMRELS--YAGFSVFHDEALI--PAI 266
Database: CDD.v3.10
Posted date: Mar 20, 2013 7:55 AM
Number of letters in database: 10,937,602
Number of sequences in database: 44,354
Lambda K H
0.314 0.133 0.375
Gapped
Lambda K H
0.267 0.0781 0.140
Matrix: BLOSUM62
Gap Penalties: Existence: 11, Extension: 1
Number of Sequences: 44354
Number of Hits to DB: 5,196,835
Number of extensions: 441954
Number of successful extensions: 369
Number of sequences better than 10.0: 1
Number of HSP's gapped: 339
Number of HSP's successfully gapped: 60
Length of query: 102
Length of database: 10,937,602
Length adjustment: 68
Effective length of query: 34
Effective length of database: 7,921,530
Effective search space: 269332020
Effective search space used: 269332020
Neighboring words threshold: 11
Window for multiple hits: 40
X1: 16 ( 7.3 bits)
X2: 38 (14.6 bits)
X3: 64 (24.7 bits)
S1: 42 (22.0 bits)
S2: 53 (24.1 bits)