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= psy17079
(99 letters)
Database: pdbaa
62,578 sequences; 14,973,337 total letters
Searching..................................................done
>pdb|3IYG|H Chain H, Ca Model Of Bovine TricCCT DERIVED FROM A 4.0 ANGSTROM
Cryo-Em Map
Length = 515
Score = 90.5 bits (223), Expect = 2e-19, Method: Compositional matrix adjust.
Identities = 39/55 (70%), Positives = 47/55 (85%)
Query: 2 QSNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKNPK 56
Q WYGVDI EDI+DN E+ VWEPA+V+ NA+TAASEAACL++SVDETIKNP+
Sbjct: 461 QGGMWYGVDINTEDIADNFEAFVWEPAMVRINALTAASEAACLIVSVDETIKNPR 515
>pdb|3P9D|G Chain G, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9D|O Chain O, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|GG Chain g, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|OO Chain o, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|4D8Q|G Chain G, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8Q|O Chain O, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|GG Chain g, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|OO Chain o, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
Length = 550
Score = 63.5 bits (153), Expect = 3e-11, Method: Compositional matrix adjust.
Identities = 29/49 (59%), Positives = 35/49 (71%)
Query: 6 WYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKN 54
WYGV E+I DN VWEPA+VK NA+ +A+EA L+LSVDETI N
Sbjct: 478 WYGVVFETENIGDNFAKFVWEPALVKINALNSATEATNLILSVDETITN 526
>pdb|3KO1|A Chain A, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|B Chain B, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|C Chain C, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|D Chain D, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|E Chain E, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|F Chain F, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|G Chain G, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|H Chain H, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
pdb|3KO1|I Chain I, Cystal Structure Of Thermosome From Acidianus
Tengchongensis Strain S5
Length = 553
Score = 50.8 bits (120), Expect = 2e-07, Method: Compositional matrix adjust.
Identities = 24/51 (47%), Positives = 34/51 (66%)
Query: 2 QSNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
++N WYG+D+ D + V EPA+VK NAI AA+EAA LVL +D+ +
Sbjct: 480 ENNKWYGIDLYAGQPVDMWQKGVIEPALVKMNAIKAATEAATLVLRIDDVV 530
>pdb|3P9D|C Chain C, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9D|K Chain K, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|CC Chain c, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|KK Chain k, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|4D8Q|C Chain C, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8Q|K Chain K, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|CC Chain c, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|KK Chain k, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
Length = 590
Score = 45.1 bits (105), Expect = 1e-05, Method: Compositional matrix adjust.
Identities = 19/51 (37%), Positives = 31/51 (60%)
Query: 2 QSNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
Q N G+D K I D + +WEP ++K+ ++ A E+ACL+L VD+ +
Sbjct: 533 QGNFTTGIDGDKGKIVDMVSYGIWEPEVIKQQSVKTAIESACLLLRVDDIV 583
>pdb|3IYG|A Chain A, Ca Model Of Bovine TricCCT DERIVED FROM A 4.0 ANGSTROM
Cryo-Em Map
Length = 529
Score = 43.9 bits (102), Expect = 3e-05, Method: Compositional matrix adjust.
Identities = 19/48 (39%), Positives = 30/48 (62%)
Query: 6 WYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIK 53
W G+D+ DN ++ V+EP IVK ++ A+EAA +L +D+ IK
Sbjct: 479 WIGLDLVNGKPRDNKQAGVFEPTIVKVKSLKFATEAAITILRIDDLIK 526
>pdb|1Q3R|A Chain A, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form Of Single Mutant)
pdb|1Q3R|B Chain B, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form Of Single Mutant)
pdb|1Q3R|C Chain C, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form Of Single Mutant)
pdb|1Q3R|D Chain D, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form Of Single Mutant)
Length = 548
Score = 42.7 bits (99), Expect = 5e-05, Method: Compositional matrix adjust.
Identities = 19/49 (38%), Positives = 30/49 (61%)
Query: 4 NCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
G+D+ + +D +E + EP VKK AI +ASEAA ++L +D+ I
Sbjct: 474 GLGIGIDVFEGKPADMLEKGIIEPLRVKKQAIKSASEAAIMILRIDDVI 522
>pdb|1Q3S|A Chain A, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
pdb|1Q3S|B Chain B, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
pdb|1Q3S|C Chain C, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
pdb|1Q3S|D Chain D, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
pdb|1Q3S|E Chain E, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
pdb|1Q3S|F Chain F, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
pdb|1Q3S|G Chain G, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
pdb|1Q3S|H Chain H, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Formiii Crystal Complexed With Adp)
Length = 548
Score = 42.7 bits (99), Expect = 5e-05, Method: Compositional matrix adjust.
Identities = 19/49 (38%), Positives = 30/49 (61%)
Query: 4 NCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
G+D+ + +D +E + EP VKK AI +ASEAA ++L +D+ I
Sbjct: 474 GLGIGIDVFEGKPADMLEKGIIEPLRVKKQAIKSASEAAIMILRIDDVI 522
>pdb|1Q2V|A Chain A, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form)
pdb|1Q2V|B Chain B, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form)
pdb|1Q2V|C Chain C, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form)
pdb|1Q2V|D Chain D, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Nucleotide-Free Form)
pdb|1Q3Q|A Chain A, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Two-Point Mutant Complexed With Amp-Pnp)
pdb|1Q3Q|B Chain B, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Two-Point Mutant Complexed With Amp-Pnp)
pdb|1Q3Q|C Chain C, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Two-Point Mutant Complexed With Amp-Pnp)
pdb|1Q3Q|D Chain D, Crystal Structure Of The Chaperonin From Thermococcus
Strain Ks-1 (Two-Point Mutant Complexed With Amp-Pnp)
Length = 548
Score = 42.7 bits (99), Expect = 5e-05, Method: Compositional matrix adjust.
Identities = 19/49 (38%), Positives = 30/49 (61%)
Query: 4 NCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
G+D+ + +D +E + EP VKK AI +ASEAA ++L +D+ I
Sbjct: 474 GLGIGIDVFEGKPADMLEKGIIEPLRVKKQAIKSASEAAIMILRIDDVI 522
>pdb|1A6D|B Chain B, Thermosome From T. Acidophilum
pdb|1A6E|B Chain B, Thermosome-Mg-Adp-Alf3 Complex
Length = 543
Score = 42.4 bits (98), Expect = 6e-05, Method: Compositional matrix adjust.
Identities = 19/51 (37%), Positives = 33/51 (64%)
Query: 2 QSNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
+ N YG+++ +I D +++ V EP V K AI +A+EAA ++L +D+ I
Sbjct: 470 KGNKTYGINVFTGEIEDMVKNGVIEPIRVGKQAIESATEAAIMILRIDDVI 520
>pdb|3P9D|H Chain H, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9D|P Chain P, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|HH Chain h, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|PP Chain p, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|4D8Q|H Chain H, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8Q|P Chain P, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|HH Chain h, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|PP Chain p, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
Length = 568
Score = 36.2 bits (82), Expect = 0.004, Method: Composition-based stats.
Identities = 22/55 (40%), Positives = 31/55 (56%), Gaps = 3/55 (5%)
Query: 6 WYGVDI---TKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKNPKA 57
+ GVDI + E + D E +++ KK AI A+EAA VLS+D+ I KA
Sbjct: 496 YKGVDIDGESDEGVKDIREENIYDMLATKKFAINVATEAATTVLSIDQIIMAKKA 550
>pdb|3P9D|A Chain A, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9D|I Chain I, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|AA Chain a, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|II Chain i, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|4D8Q|A Chain A, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8Q|I Chain I, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|AA Chain a, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|II Chain i, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
Length = 559
Score = 35.0 bits (79), Expect = 0.011, Method: Compositional matrix adjust.
Identities = 16/46 (34%), Positives = 26/46 (56%)
Query: 7 YGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
YG+D+ + I D + + V EP I K ++ +A EA +L +D I
Sbjct: 500 YGLDLIRGKIVDEIHAGVLEPTISKVKSLKSALEACVAILRIDTMI 545
>pdb|3IYG|D Chain D, Ca Model Of Bovine TricCCT DERIVED FROM A 4.0 ANGSTROM
Cryo-Em Map
Length = 518
Score = 33.5 bits (75), Expect = 0.031, Method: Compositional matrix adjust.
Identities = 15/51 (29%), Positives = 29/51 (56%)
Query: 2 QSNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
Q G+++ K IS+ +E V +P +V +A+T A+E +L +D+ +
Sbjct: 465 QGEKTTGINVRKGGISNILEELVVQPLLVSVSALTLATETVRSILKIDDVV 515
>pdb|3IYG|G Chain G, Ca Model Of Bovine TricCCT DERIVED FROM A 4.0 ANGSTROM
Cryo-Em Map
Length = 515
Score = 32.3 bits (72), Expect = 0.070, Method: Compositional matrix adjust.
Identities = 19/56 (33%), Positives = 27/56 (48%), Gaps = 1/56 (1%)
Query: 2 QSNC-WYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKNPK 56
Q NC +GV+ + D E +WEP VK A E A L+L +D+ + K
Sbjct: 460 QENCETWGVNGETGTLVDMKELGIWEPLAVKLQTYKTAVETAVLLLRIDDIVSGHK 515
>pdb|3AQ1|B Chain B, Open State Monomer Of A Group Ii Chaperonin From
Methanococcoides Burtonii
Length = 500
Score = 32.0 bits (71), Expect = 0.082, Method: Compositional matrix adjust.
Identities = 16/51 (31%), Positives = 29/51 (56%)
Query: 2 QSNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
+ N G+++ ++ D E+ V EP +K AI AA EA ++L +D+ +
Sbjct: 423 KGNKNAGLNVYTGEVVDMWENDVIEPLRIKTQAINAAMEATVMILRIDDVV 473
>pdb|3P9D|F Chain F, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9D|N Chain N, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|FF Chain f, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|NN Chain n, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|4D8Q|F Chain F, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8Q|N Chain N, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|FF Chain f, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|NN Chain n, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
Length = 546
Score = 29.6 bits (65), Expect = 0.46, Method: Composition-based stats.
Identities = 16/48 (33%), Positives = 25/48 (52%)
Query: 6 WYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIK 53
+ GVD+ D D +W+ V +NAIT A+ A +L DE ++
Sbjct: 488 YVGVDLNIGDSCDPTIEGIWDSYRVLRNAITGATGIASNLLLCDELLR 535
>pdb|3P9D|B Chain B, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9D|J Chain J, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|BB Chain b, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|JJ Chain j, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|4D8Q|B Chain B, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8Q|J Chain J, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|BB Chain b, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|JJ Chain j, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
Length = 527
Score = 29.3 bits (64), Expect = 0.53, Method: Composition-based stats.
Identities = 15/46 (32%), Positives = 28/46 (60%)
Query: 8 GVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIK 53
G+D+ I+D + + E +K+ +++ASEAA ++L VD I+
Sbjct: 471 GLDLNNGTIADMRQLGIVESYKLKRAVVSSASEAAEVLLRVDNIIR 516
>pdb|3IYF|A Chain A, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|B Chain B, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|C Chain C, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|D Chain D, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|E Chain E, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|F Chain F, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|G Chain G, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|H Chain H, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|I Chain I, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|J Chain J, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|K Chain K, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|L Chain L, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|M Chain M, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|N Chain N, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|O Chain O, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3IYF|P Chain P, Atomic Model Of The Lidless Mm-Cpn In The Open State
pdb|3KFE|A Chain A, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFE|B Chain B, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFE|C Chain C, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFE|D Chain D, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFE|E Chain E, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFE|F Chain F, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFE|G Chain G, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFE|H Chain H, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFK|A Chain A, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFK|B Chain B, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFK|C Chain C, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFK|D Chain D, Crystal Structures Of A Group Ii Chaperonin From
Methanococcus Maripaludis
Length = 521
Score = 29.3 bits (64), Expect = 0.53, Method: Compositional matrix adjust.
Identities = 17/54 (31%), Positives = 29/54 (53%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKNPK 56
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I K
Sbjct: 445 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVIAAEK 498
>pdb|3RUS|A Chain A, Crystal Structure Of Cpn-Rls In Complex With Adp From
Methanococcus Maripaludis
pdb|3RUS|B Chain B, Crystal Structure Of Cpn-Rls In Complex With Adp From
Methanococcus Maripaludis
pdb|3RUS|C Chain C, Crystal Structure Of Cpn-Rls In Complex With Adp From
Methanococcus Maripaludis
pdb|3RUS|D Chain D, Crystal Structure Of Cpn-Rls In Complex With Adp From
Methanococcus Maripaludis
pdb|3RUV|A Chain A, Crystal Structure Of Cpn-Rls In Complex With Atp Analogue
From Methanococcus Maripaludis
pdb|3RUV|B Chain B, Crystal Structure Of Cpn-Rls In Complex With Atp Analogue
From Methanococcus Maripaludis
pdb|3RUV|C Chain C, Crystal Structure Of Cpn-Rls In Complex With Atp Analogue
From Methanococcus Maripaludis
pdb|3RUV|D Chain D, Crystal Structure Of Cpn-Rls In Complex With Atp Analogue
From Methanococcus Maripaludis
pdb|3RUW|A Chain A, Crystal Structure Of Cpn-Rls In Complex With Adp-Alfx From
Methanococcus Maripaludis
pdb|3RUW|B Chain B, Crystal Structure Of Cpn-Rls In Complex With Adp-Alfx From
Methanococcus Maripaludis
pdb|3RUW|C Chain C, Crystal Structure Of Cpn-Rls In Complex With Adp-Alfx From
Methanococcus Maripaludis
pdb|3RUW|D Chain D, Crystal Structure Of Cpn-Rls In Complex With Adp-Alfx From
Methanococcus Maripaludis
Length = 543
Score = 29.3 bits (64), Expect = 0.53, Method: Compositional matrix adjust.
Identities = 17/54 (31%), Positives = 29/54 (53%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKNPK 56
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I K
Sbjct: 467 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVIAAEK 520
>pdb|3LOS|A Chain A, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|B Chain B, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|C Chain C, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|D Chain D, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|E Chain E, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|F Chain F, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|G Chain G, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|H Chain H, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|I Chain I, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|J Chain J, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|K Chain K, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|L Chain L, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|M Chain M, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|N Chain N, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|O Chain O, Atomic Model Of Mm-Cpn In The Closed State
pdb|3LOS|P Chain P, Atomic Model Of Mm-Cpn In The Closed State
pdb|3KFB|A Chain A, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFB|B Chain B, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFB|C Chain C, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFB|D Chain D, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFB|E Chain E, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFB|F Chain F, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFB|G Chain G, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3KFB|H Chain H, Crystal Structure Of A Group Ii Chaperonin From
Methanococcus Maripaludis
pdb|3RUQ|A Chain A, Crystal Structure Of Cpn-Wt In Complex With Adp From
Methanococcus Maripaludis
pdb|3RUQ|B Chain B, Crystal Structure Of Cpn-Wt In Complex With Adp From
Methanococcus Maripaludis
pdb|3RUQ|C Chain C, Crystal Structure Of Cpn-Wt In Complex With Adp From
Methanococcus Maripaludis
pdb|3RUQ|D Chain D, Crystal Structure Of Cpn-Wt In Complex With Adp From
Methanococcus Maripaludis
Length = 543
Score = 29.3 bits (64), Expect = 0.55, Method: Compositional matrix adjust.
Identities = 17/54 (31%), Positives = 29/54 (53%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKNPK 56
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I K
Sbjct: 467 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVIAAEK 520
>pdb|3IZH|A Chain A, Mm-Cpn D386a With Atp
pdb|3IZH|B Chain B, Mm-Cpn D386a With Atp
pdb|3IZH|C Chain C, Mm-Cpn D386a With Atp
pdb|3IZH|D Chain D, Mm-Cpn D386a With Atp
pdb|3IZH|E Chain E, Mm-Cpn D386a With Atp
pdb|3IZH|F Chain F, Mm-Cpn D386a With Atp
pdb|3IZH|G Chain G, Mm-Cpn D386a With Atp
pdb|3IZH|H Chain H, Mm-Cpn D386a With Atp
pdb|3IZH|I Chain I, Mm-Cpn D386a With Atp
pdb|3IZH|J Chain J, Mm-Cpn D386a With Atp
pdb|3IZH|K Chain K, Mm-Cpn D386a With Atp
pdb|3IZH|L Chain L, Mm-Cpn D386a With Atp
pdb|3IZH|M Chain M, Mm-Cpn D386a With Atp
pdb|3IZH|N Chain N, Mm-Cpn D386a With Atp
pdb|3IZH|O Chain O, Mm-Cpn D386a With Atp
pdb|3IZH|P Chain P, Mm-Cpn D386a With Atp
pdb|3IZM|A Chain A, Mm-Cpn Wildtype With Atp
pdb|3IZM|B Chain B, Mm-Cpn Wildtype With Atp
pdb|3IZM|C Chain C, Mm-Cpn Wildtype With Atp
pdb|3IZM|D Chain D, Mm-Cpn Wildtype With Atp
pdb|3IZM|E Chain E, Mm-Cpn Wildtype With Atp
pdb|3IZM|F Chain F, Mm-Cpn Wildtype With Atp
pdb|3IZM|G Chain G, Mm-Cpn Wildtype With Atp
pdb|3IZM|H Chain H, Mm-Cpn Wildtype With Atp
pdb|3IZM|I Chain I, Mm-Cpn Wildtype With Atp
pdb|3IZM|J Chain J, Mm-Cpn Wildtype With Atp
pdb|3IZM|K Chain K, Mm-Cpn Wildtype With Atp
pdb|3IZM|L Chain L, Mm-Cpn Wildtype With Atp
pdb|3IZM|M Chain M, Mm-Cpn Wildtype With Atp
pdb|3IZM|N Chain N, Mm-Cpn Wildtype With Atp
pdb|3IZM|O Chain O, Mm-Cpn Wildtype With Atp
pdb|3IZM|P Chain P, Mm-Cpn Wildtype With Atp
Length = 513
Score = 29.3 bits (64), Expect = 0.61, Method: Compositional matrix adjust.
Identities = 16/50 (32%), Positives = 28/50 (56%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I
Sbjct: 461 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVI 510
>pdb|3IZN|A Chain A, Mm-Cpn Deltalid With Atp
pdb|3IZN|B Chain B, Mm-Cpn Deltalid With Atp
pdb|3IZN|C Chain C, Mm-Cpn Deltalid With Atp
pdb|3IZN|D Chain D, Mm-Cpn Deltalid With Atp
pdb|3IZN|E Chain E, Mm-Cpn Deltalid With Atp
pdb|3IZN|F Chain F, Mm-Cpn Deltalid With Atp
pdb|3IZN|G Chain G, Mm-Cpn Deltalid With Atp
pdb|3IZN|H Chain H, Mm-Cpn Deltalid With Atp
pdb|3IZN|I Chain I, Mm-Cpn Deltalid With Atp
pdb|3IZN|J Chain J, Mm-Cpn Deltalid With Atp
pdb|3IZN|K Chain K, Mm-Cpn Deltalid With Atp
pdb|3IZN|L Chain L, Mm-Cpn Deltalid With Atp
pdb|3IZN|M Chain M, Mm-Cpn Deltalid With Atp
pdb|3IZN|N Chain N, Mm-Cpn Deltalid With Atp
pdb|3IZN|O Chain O, Mm-Cpn Deltalid With Atp
pdb|3IZN|P Chain P, Mm-Cpn Deltalid With Atp
pdb|3J03|A Chain A, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|B Chain B, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|C Chain C, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|D Chain D, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|E Chain E, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|F Chain F, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|G Chain G, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|H Chain H, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|I Chain I, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|J Chain J, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|K Chain K, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|L Chain L, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|M Chain M, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|N Chain N, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|O Chain O, Lidless Mm-Cpn In The Closed State With AtpALFX
pdb|3J03|P Chain P, Lidless Mm-Cpn In The Closed State With AtpALFX
Length = 491
Score = 29.3 bits (64), Expect = 0.62, Method: Compositional matrix adjust.
Identities = 16/50 (32%), Positives = 28/50 (56%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I
Sbjct: 439 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVI 488
>pdb|3J02|A Chain A, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|B Chain B, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|C Chain C, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|D Chain D, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|E Chain E, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|F Chain F, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|G Chain G, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|H Chain H, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|I Chain I, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|J Chain J, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|K Chain K, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|L Chain L, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|M Chain M, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|N Chain N, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|O Chain O, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
pdb|3J02|P Chain P, Lidless D386a Mm-Cpn In The Pre-Hydrolysis Atp-Bound State
Length = 491
Score = 29.3 bits (64), Expect = 0.62, Method: Compositional matrix adjust.
Identities = 16/50 (32%), Positives = 28/50 (56%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I
Sbjct: 439 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVI 488
>pdb|3IZI|A Chain A, Mm-Cpn Rls With Atp
pdb|3IZI|B Chain B, Mm-Cpn Rls With Atp
pdb|3IZI|C Chain C, Mm-Cpn Rls With Atp
pdb|3IZI|D Chain D, Mm-Cpn Rls With Atp
pdb|3IZI|E Chain E, Mm-Cpn Rls With Atp
pdb|3IZI|F Chain F, Mm-Cpn Rls With Atp
pdb|3IZI|G Chain G, Mm-Cpn Rls With Atp
pdb|3IZI|H Chain H, Mm-Cpn Rls With Atp
pdb|3IZI|I Chain I, Mm-Cpn Rls With Atp
pdb|3IZI|J Chain J, Mm-Cpn Rls With Atp
pdb|3IZI|K Chain K, Mm-Cpn Rls With Atp
pdb|3IZI|L Chain L, Mm-Cpn Rls With Atp
pdb|3IZI|M Chain M, Mm-Cpn Rls With Atp
pdb|3IZI|N Chain N, Mm-Cpn Rls With Atp
pdb|3IZI|O Chain O, Mm-Cpn Rls With Atp
pdb|3IZI|P Chain P, Mm-Cpn Rls With Atp
pdb|3IZJ|A Chain A, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|B Chain B, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|C Chain C, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|D Chain D, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|E Chain E, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|F Chain F, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|G Chain G, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|H Chain H, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|I Chain I, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|J Chain J, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|K Chain K, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|L Chain L, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|M Chain M, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|N Chain N, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|O Chain O, Mm-Cpn Rls With Atp And Alfx
pdb|3IZJ|P Chain P, Mm-Cpn Rls With Atp And Alfx
Length = 513
Score = 29.3 bits (64), Expect = 0.64, Method: Compositional matrix adjust.
Identities = 16/50 (32%), Positives = 28/50 (56%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I
Sbjct: 461 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVI 510
>pdb|3IZK|A Chain A, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|B Chain B, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|C Chain C, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|D Chain D, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|E Chain E, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|F Chain F, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|G Chain G, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|H Chain H, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|I Chain I, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|J Chain J, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|K Chain K, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|L Chain L, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|M Chain M, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|N Chain N, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|O Chain O, Mm-Cpn Rls Deltalid With Atp
pdb|3IZK|P Chain P, Mm-Cpn Rls Deltalid With Atp
pdb|3IZL|A Chain A, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|B Chain B, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|C Chain C, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|D Chain D, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|E Chain E, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|F Chain F, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|G Chain G, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|H Chain H, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|I Chain I, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|J Chain J, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|K Chain K, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|L Chain L, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|M Chain M, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|N Chain N, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|O Chain O, Mm-Cpn Rls Deltalid With Atp And Alfx
pdb|3IZL|P Chain P, Mm-Cpn Rls Deltalid With Atp And Alfx
Length = 491
Score = 29.3 bits (64), Expect = 0.64, Method: Compositional matrix adjust.
Identities = 16/50 (32%), Positives = 28/50 (56%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
N G+++ + D E+ V EP VK AI +A+E+ ++L +D+ I
Sbjct: 439 GNKCAGLNVFTGAVEDMCENGVVEPLRVKTQAIQSAAESTEMLLRIDDVI 488
>pdb|3P9D|D Chain D, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9D|L Chain L, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|DD Chain d, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|3P9E|LL Chain l, The Crystal Structure Of Yeast Cct Reveals Intrinsic
Asymmetry Of Eukaryotic Cytosolic Chaperonins
pdb|4D8Q|D Chain D, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8Q|L Chain L, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|DD Chain d, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
pdb|4D8R|LL Chain l, Molecular Architecture Of The Eukaryotic Chaperonin
TricCCT DERIVED By A Combination Of Chemical
Crosslinking And Mass-Spectrometry, Xl- Ms
Length = 528
Score = 28.9 bits (63), Expect = 0.75, Method: Compositional matrix adjust.
Identities = 12/43 (27%), Positives = 24/43 (55%)
Query: 8 GVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDE 50
G+ + + ++ E + +P +V +AIT ASE +L +D+
Sbjct: 481 GISVRRSGTTNTYEEHILQPVLVSTSAITLASECVKSILRIDD 523
>pdb|2LFC|A Chain A, Solution Nmr Structure Of Fumarate Reductase Flavoprotein
Subunit From Lactobacillus Plantarum, Northeast
Structural Genomics Consortium Target Lpr145j
Length = 160
Score = 28.5 bits (62), Expect = 1.1, Method: Compositional matrix adjust.
Identities = 15/45 (33%), Positives = 24/45 (53%)
Query: 10 DITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIKN 54
D T E+I E+ P VK + +AA +A +V + +T+KN
Sbjct: 74 DFTPEEIKSFFENKGKRPVFVKGSLESAAEQAGIVVDELVQTVKN 118
>pdb|3IYG|B Chain B, Ca Model Of Bovine TricCCT DERIVED FROM A 4.0 ANGSTROM
Cryo-Em Map
pdb|3KTT|B Chain B, Atomic Model Of Bovine Tric Cct2(Beta) Subunit Derived
From A 4.0 Angstrom Cryo-Em Map
pdb|4A0O|A Chain A, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|B Chain B, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|C Chain C, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|D Chain D, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|E Chain E, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|F Chain F, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|G Chain G, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|H Chain H, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|I Chain I, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|J Chain J, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|K Chain K, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|L Chain L, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|M Chain M, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|N Chain N, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|O Chain O, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0O|P Chain P, Symmetry-Free Cryo-Em Map Of Tric In The Nucleotide-Free
(Apo) State
pdb|4A0V|A Chain A, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|B Chain B, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|C Chain C, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|D Chain D, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|E Chain E, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|F Chain F, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|G Chain G, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|H Chain H, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|I Chain I, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|J Chain J, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|K Chain K, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|L Chain L, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|M Chain M, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|N Chain N, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|O Chain O, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0V|P Chain P, Model Refined Against The Symmetry-Free Cryo-Em Map Of
Tric- Amp-Pnp
pdb|4A0W|A Chain A, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|B Chain B, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|C Chain C, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|D Chain D, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|E Chain E, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|F Chain F, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|G Chain G, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|H Chain H, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|I Chain I, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|J Chain J, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|K Chain K, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|L Chain L, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|M Chain M, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|N Chain N, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|O Chain O, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A0W|P Chain P, Model Built Against Symmetry-Free Cryo-Em Map Of
Tric-Adp-Alfx
pdb|4A13|A Chain A, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|B Chain B, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|C Chain C, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|D Chain D, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|E Chain E, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|F Chain F, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|G Chain G, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|H Chain H, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|I Chain I, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|J Chain J, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|K Chain K, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|L Chain L, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|M Chain M, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|N Chain N, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|O Chain O, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
pdb|4A13|P Chain P, Model Refined Agains Symmetry-Free Cryo-Em Map Of Tric-Adp
Length = 513
Score = 28.5 bits (62), Expect = 1.1, Method: Composition-based stats.
Identities = 16/46 (34%), Positives = 26/46 (56%)
Query: 8 GVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETIK 53
G+D+ + I D + E VK+ + +A+EAA ++L VD IK
Sbjct: 464 GLDMKEGTIGDMSVLGITESFQVKRQVLLSAAEAAEVILRVDNIIK 509
>pdb|3UIU|A Chain A, Crystal Structure Of Apo-Pkr Kinase Domain
pdb|3UIU|B Chain B, Crystal Structure Of Apo-Pkr Kinase Domain
Length = 306
Score = 26.9 bits (58), Expect = 3.1, Method: Composition-based stats.
Identities = 13/47 (27%), Positives = 24/47 (51%), Gaps = 3/47 (6%)
Query: 3 SNCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVD 49
+ CW G D E D++ES ++P K ++ S+ CL + ++
Sbjct: 71 NGCWDGFDYDPETSDDSLESSDYDPENSKN---SSRSKTKCLFIQME 114
>pdb|1WE3|A Chain A, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|B Chain B, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|C Chain C, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|D Chain D, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|E Chain E, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|F Chain F, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|G Chain G, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|H Chain H, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|I Chain I, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|J Chain J, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|K Chain K, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|L Chain L, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|M Chain M, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WE3|N Chain N, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|AA Chain a, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|BB Chain b, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|CC Chain c, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|DD Chain d, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|EE Chain e, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|FF Chain f, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|GG Chain g, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|HH Chain h, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|II Chain i, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|JJ Chain j, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|KK Chain k, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|LL Chain l, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|MM Chain m, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
pdb|1WF4|NN Chain n, Crystal Structure Of The Chaperonin Complex
Cpn60CPN10(ADP)7 FROM THERMUS THERMOPHILUS
Length = 543
Score = 25.8 bits (55), Expect = 6.9, Method: Composition-based stats.
Identities = 12/49 (24%), Positives = 26/49 (53%)
Query: 4 NCWYGVDITKEDISDNMESCVWEPAIVKKNAITAASEAACLVLSVDETI 52
N YG + + D +E+ + +PA V ++A+ A+ L+L+ + +
Sbjct: 474 NPRYGFNAATGEFVDMVEAGIVDPAKVTRSALQNAASIGALILTTEAVV 522
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
0.313 0.127 0.392
Lambda K H
0.267 0.0410 0.140
Matrix: BLOSUM62
Gap Penalties: Existence: 11, Extension: 1
Number of Hits to DB: 2,166,373
Number of Sequences: 62578
Number of extensions: 47782
Number of successful extensions: 88
Number of sequences better than 100.0: 30
Number of HSP's better than 100.0 without gapping: 30
Number of HSP's successfully gapped in prelim test: 0
Number of HSP's that attempted gapping in prelim test: 58
Number of HSP's gapped (non-prelim): 30
length of query: 99
length of database: 14,973,337
effective HSP length: 65
effective length of query: 34
effective length of database: 10,905,767
effective search space: 370796078
effective search space used: 370796078
T: 11
A: 40
X1: 16 ( 7.2 bits)
X2: 38 (14.6 bits)
X3: 64 (24.7 bits)
S1: 42 (21.9 bits)
S2: 45 (21.9 bits)