BLASTP 2.2.26 [Sep-21-2011]
Reference: Altschul, Stephen F., Thomas L. Madden, Alejandro A. Schaffer,
Jinghui Zhang, Zheng Zhang, Webb Miller, and David J. Lipman (1997),
"Gapped BLAST and PSI-BLAST: a new generation of protein database search
programs", Nucleic Acids Res. 25:3389-3402.
Reference for compositional score matrix adjustment: Altschul, Stephen F.,
John C. Wootton, E. Michael Gertz, Richa Agarwala, Aleksandr Morgulis,
Alejandro A. Schaffer, and Yi-Kuo Yu (2005) "Protein database searches
using compositionally adjusted substitution matrices", FEBS J. 272:5101-5109.
Query= 028542
(207 letters)
Database: pdbaa
62,578 sequences; 14,973,337 total letters
Searching..................................................done
>pdb|3GLA|A Chain A, Crystal Structure Of The Hspa From Xanthomonas Axonopodis
pdb|3GLA|B Chain B, Crystal Structure Of The Hspa From Xanthomonas Axonopodis
Length = 100
Score = 35.8 bits (81), Expect = 0.017, Method: Compositional matrix adjust.
Identities = 27/90 (30%), Positives = 39/90 (43%), Gaps = 9/90 (10%)
Query: 111 DAKETDDALNLSIDMPGLGKEDVRVSLEQNTLVIRXXXXXXXXXXXS-----VRRYTS-- 163
D KE + L D+PG+ + V +++ L IR RRY S
Sbjct: 8 DIKEEVNHFVLYADLPGIDPSQIEVQMDKGILSIRGERKSESSTETERFSRIERRYGSFH 67
Query: 164 -RIDLPEKLYRTDQIKAEMKNGVLKVTVPK 192
R LP+ D I A +NGVL++ +PK
Sbjct: 68 RRFALPDSA-DADGITAAGRNGVLEIRIPK 96
>pdb|3GT6|A Chain A, Crystal Structure Of The Hspa From Xanthomonas Axonopodis
pdb|3GT6|B Chain B, Crystal Structure Of The Hspa From Xanthomonas Axonopodis
pdb|3GUF|A Chain A, Crystal Structure Of The Hspa From Xanthomonas Axonopodis
pdb|3GUF|B Chain B, Crystal Structure Of The Hspa From Xanthomonas Axonopodis
Length = 103
Score = 35.8 bits (81), Expect = 0.019, Method: Compositional matrix adjust.
Identities = 27/90 (30%), Positives = 39/90 (43%), Gaps = 9/90 (10%)
Query: 111 DAKETDDALNLSIDMPGLGKEDVRVSLEQNTLVIRXXXXXXXXXXXS-----VRRYTS-- 163
D KE + L D+PG+ + V +++ L IR RRY S
Sbjct: 11 DIKEEVNHFVLYADLPGIDPSQIEVQMDKGILSIRGERKSESSTETERFSRIERRYGSFH 70
Query: 164 -RIDLPEKLYRTDQIKAEMKNGVLKVTVPK 192
R LP+ D I A +NGVL++ +PK
Sbjct: 71 RRFALPDSA-DADGITAAGRNGVLEIRIPK 99
>pdb|4ELD|A Chain A, Crystal Structure Of An Activated Variant Of Small Heat
Shock Protein Hsp16.5
pdb|4ELD|B Chain B, Crystal Structure Of An Activated Variant Of Small Heat
Shock Protein Hsp16.5
Length = 161
Score = 35.0 bits (79), Expect = 0.033, Method: Compositional matrix adjust.
Identities = 28/90 (31%), Positives = 43/90 (47%), Gaps = 10/90 (11%)
Query: 114 ETDDALNLSIDMPGLGKEDVRVSLEQNTLVIRXXXXXXXXXXXSVRRYTSRIDLPEKLYR 173
E D + + +PG+ KED+ ++ +TL IR S R S I E++YR
Sbjct: 63 EGDQHIKVIAWLPGVNKEDIILNAVGDTLEIR-AKRSPLMITESERIIYSEIPEEEEIYR 121
Query: 174 TDQIKAEMK---------NGVLKVTVPKVK 194
T ++ A +K NGVL V +PK +
Sbjct: 122 TIKLPATVKEENASAKFENGVLSVILPKAE 151
>pdb|1SHS|A Chain A, Small Heat Shock Protein From Methanococcus Jannaschii
pdb|1SHS|B Chain B, Small Heat Shock Protein From Methanococcus Jannaschii
pdb|1SHS|C Chain C, Small Heat Shock Protein From Methanococcus Jannaschii
pdb|1SHS|D Chain D, Small Heat Shock Protein From Methanococcus Jannaschii
pdb|1SHS|E Chain E, Small Heat Shock Protein From Methanococcus Jannaschii
pdb|1SHS|F Chain F, Small Heat Shock Protein From Methanococcus Jannaschii
pdb|1SHS|G Chain G, Small Heat Shock Protein From Methanococcus Jannaschii
pdb|1SHS|H Chain H, Small Heat Shock Protein From Methanococcus Jannaschii
Length = 147
Score = 34.7 bits (78), Expect = 0.034, Method: Compositional matrix adjust.
Identities = 28/90 (31%), Positives = 43/90 (47%), Gaps = 10/90 (11%)
Query: 114 ETDDALNLSIDMPGLGKEDVRVSLEQNTLVIRXXXXXXXXXXXSVRRYTSRIDLPEKLYR 173
E D + + +PG+ KED+ ++ +TL IR S R S I E++YR
Sbjct: 49 EGDQHIKVIAWLPGVNKEDIILNAVGDTLEIR-AKRSPLMITESERIIYSEIPEEEEIYR 107
Query: 174 TDQIKAEMK---------NGVLKVTVPKVK 194
T ++ A +K NGVL V +PK +
Sbjct: 108 TIKLPATVKEENASAKFENGVLSVILPKAE 137
>pdb|1GME|A Chain A, Crystal Structure And Assembly Of An Eukaryotic Small Heat
Shock Protein
pdb|1GME|B Chain B, Crystal Structure And Assembly Of An Eukaryotic Small Heat
Shock Protein
pdb|1GME|C Chain C, Crystal Structure And Assembly Of An Eukaryotic Small Heat
Shock Protein
pdb|1GME|D Chain D, Crystal Structure And Assembly Of An Eukaryotic Small Heat
Shock Protein
Length = 151
Score = 29.3 bits (64), Expect = 1.6, Method: Compositional matrix adjust.
Identities = 27/93 (29%), Positives = 42/93 (45%), Gaps = 10/93 (10%)
Query: 111 DAKETDDALNLSIDMPGLG-KEDVRVSLEQNTLVIRXXXXXXXXXXX--------SVRRY 161
D KET +A D+PG+ +E + N LV+ S ++
Sbjct: 47 DWKETPEAHVFKADLPGVKKEEVKVEVEDGNVLVVSGERTKEKEDKNDKWHRVERSSGKF 106
Query: 162 TSRIDLPEKLYRTDQIKAEMKNGVLKVTVPKVK 194
R L E + +++KA ++NGVL VTVPK +
Sbjct: 107 VRRFRLLEDA-KVEEVKAGLENGVLTVTVPKAE 138
>pdb|2BYU|A Chain A, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|B Chain B, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|C Chain C, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|D Chain D, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|E Chain E, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|F Chain F, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|G Chain G, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|H Chain H, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|I Chain I, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|J Chain J, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|K Chain K, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
pdb|2BYU|L Chain L, Negative Stain Em Reconstruction Of M.Tuberculosis
Acr1(Hsp 16.3) Fitted With Wheat Shsp Dimer
Length = 101
Score = 28.9 bits (63), Expect = 2.3, Method: Compositional matrix adjust.
Identities = 27/91 (29%), Positives = 41/91 (45%), Gaps = 10/91 (10%)
Query: 111 DAKETDDALNLSIDMPGLG-KEDVRVSLEQNTLVIRXXXXXXXXXXX--------SVRRY 161
D KET +A D+PG+ +E + N LV+ S ++
Sbjct: 5 DWKETPEAHVFKADLPGVKKEEVKVEVEDGNVLVVSGERTKEKEDKNDKWHRVERSSGKF 64
Query: 162 TSRIDLPEKLYRTDQIKAEMKNGVLKVTVPK 192
R L E + +++KA ++NGVL VTVPK
Sbjct: 65 VRRFRLLED-AKVEEVKAGLENGVLTVTVPK 94
>pdb|2H50|A Chain A, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|B Chain B, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|C Chain C, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|D Chain D, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|E Chain E, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|F Chain F, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|G Chain G, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|H Chain H, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|I Chain I, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|J Chain J, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|K Chain K, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|L Chain L, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|M Chain M, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|N Chain N, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|O Chain O, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|P Chain P, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|Q Chain Q, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|R Chain R, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|S Chain S, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|T Chain T, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|U Chain U, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|V Chain V, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|W Chain W, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H50|X Chain X, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|A Chain A, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|B Chain B, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|C Chain C, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|D Chain D, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|E Chain E, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|F Chain F, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|G Chain G, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|H Chain H, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|I Chain I, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|J Chain J, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|K Chain K, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|L Chain L, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|M Chain M, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|N Chain N, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|O Chain O, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|P Chain P, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|Q Chain Q, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|R Chain R, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|S Chain S, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|T Chain T, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|U Chain U, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|V Chain V, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|W Chain W, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
pdb|2H53|X Chain X, Multiple Distinct Assemblies Reveal Conformational
Flexibility In The Small Heat Shock Protein Hsp26
Length = 93
Score = 28.5 bits (62), Expect = 2.9, Method: Compositional matrix adjust.
Identities = 27/91 (29%), Positives = 41/91 (45%), Gaps = 10/91 (10%)
Query: 111 DAKETDDALNLSIDMPGLG-KEDVRVSLEQNTLVIRXXXXXXXXXXX--------SVRRY 161
D KET +A D+PG+ +E + N LV+ S ++
Sbjct: 4 DWKETPEAHVFKADLPGVKKEEVKVEVEDGNVLVVSGERTKEKEDKNDKWHRVERSSGKF 63
Query: 162 TSRIDLPEKLYRTDQIKAEMKNGVLKVTVPK 192
R L E + +++KA ++NGVL VTVPK
Sbjct: 64 VRRFRLLED-AKVEEVKAGLENGVLTVTVPK 93
Database: pdbaa
Posted date: Mar 3, 2013 10:34 PM
Number of letters in database: 14,973,337
Number of sequences in database: 62,578
Lambda K H
0.318 0.132 0.371
Lambda K H
0.267 0.0410 0.140
Matrix: BLOSUM62
Gap Penalties: Existence: 11, Extension: 1
Number of Hits to DB: 3,829,148
Number of Sequences: 62578
Number of extensions: 106666
Number of successful extensions: 212
Number of sequences better than 100.0: 7
Number of HSP's better than 100.0 without gapping: 3
Number of HSP's successfully gapped in prelim test: 4
Number of HSP's that attempted gapping in prelim test: 204
Number of HSP's gapped (non-prelim): 7
length of query: 207
length of database: 14,973,337
effective HSP length: 94
effective length of query: 113
effective length of database: 9,091,005
effective search space: 1027283565
effective search space used: 1027283565
T: 11
A: 40
X1: 16 ( 7.3 bits)
X2: 38 (14.6 bits)
X3: 64 (24.7 bits)
S1: 41 (21.7 bits)
S2: 49 (23.5 bits)