E3XT25 (E3XT25_ECOLX) Escherichia coli 2362-75

30S ribosomal protein S7 UniProtKBInterProInteractive Modelling

156 aa; Sequence (Fasta) 238 identical sequences

Sequence Features

 1-149Ribosomal protein S7 domain
IPR023798PF00177

Sequence Alignments

Experimental structures

DescriptionOligo-stateLigandsStructureRangeDownloadAssess
'Crystal Structure of Release Factor RF3 Trapped in the GTP State on a Rotated Conformation of th... Heteromer
C3TPN2; C3SQX2; C3SR62; C3SR27; C3SFQ7; C3SR12; C3SRY2; C3SQT7; C3SR57; C3SQR7; C3SR52; C3SR07; C3SSQ7; C3SYP2; C3SQY7; C3SFP7; C3SQW2; P0A7U7; C3STZ7; P0A7I4; C3SSG7; C3SME2; C3SQY2; C3SR32; C3TE02; C3SME7; C3SLL2; C3T7Q2; C3SR47; C3SQV7; C3SQU2; C3SQU7; C3SR02; C3SR17; C3SIB7; C3SIC7; C3SIB2; C3SRX7; C3SQZ2; C3SR37; C3SQX7; C3SR72; C3SR22; C3SYQ7; C3T7Q7; C3SSG2; C3SQW7; C3SQV2; C3SQZ7; C3T3H7;
493×MG;GNP;4v852-152
70S ribosome-EF-Tu H84A complex with GTP and near-cognate tRNA (Complex C2) Heteromer
B7MCT2; B7MCT5; B7MCT4; B7MCS3; B7MCS0; B7MLK8; B7MIW9; B7MBZ2; B7MCS5; A8A5A6; B7MCS8; B7MCR0; B7MCR9; B7MIU4; B7MAS6; B7MBV5; B7MCT0; P0ADZ2; B7L4J5; B7LAK9; B7MBV4; B7MFJ8; B7MCS7; B7MCR7; B7MJ76; B7MFJ7; B7MGC4; B7MAS7; A8A5A4; B7MIX1; B7MI68; B7MBF0; B7MCS9; B7MCR2; P0A7W3; B7NGD4; B7MCS1; B7MBZ1; B7MCT6; B7MCR3; B7MCV7; P0A7T1; B7MCS2; B7MB86; B7MIU7; B7MCS6; B7MLK7; B7MCT1; B7MAE3; A8A4M2; A7ZUJ2;
GTP; 1480×MG;FME;K;PHE;5wf02-152
70S ribosome-EF-Tu H84A complex with GTP and near-cognate tRNA (Complex C4) Heteromer
B7MCT2; B7MCT5; B7MCT4; B7MCS3; B7MCS0; B7MLK8; B7MIW9; B7MBZ2; B7MCS5; A8A5A6; B7MCS8; B7MCR0; B7MCR9; B7MIU4; B7MAS6; B7MBV5; B7MCT0; P0ADZ2; B7L4J5; B7LAK9; B7MBV4; B7MFJ8; B7MCS7; B7MCR7; B7MJ76; B7MFJ7; B7MGC4; B7MAS7; A8A5A4; B7MIX1; B7MI68; B7MBF0; B7MCS9; B7MCR2; P0A7W3; B7NGD4; B7MCS1; B7MBZ1; B7MCT6; B7MCR3; B7MCV7; P0A7T1; B7MCS2; B7MB86; B7MIU7; B7MCS6; B7MLK7; B7MCT1; B7MAE3; A8A4M2; A7ZUJ2;
GTP; 1471×MG;FME;K;PHE;5wfs2-152
Structure of 30S ribosomal subunit and RNA polymerase complex in non-rotated state Heteromer
P0A7Z6; B7MIX3; P0A8T8; B7MFL0; B7MBF0; B7MCS9; B7MCR2; P0A7W3; B7NGD4; B7MCS1; B7MBZ1; B7MCT6; B7MCR3; B7MCV7; P0A7T1; B7MCS2; B7MB86; B7MIU7; B7MCS6; B7MLK7; B7MCT1; B7MAE3; A8A4M2;
6awb2-152
E.coli RF1 bound to E.coli 70S ribosome in response to UAU sense A-site codon Heteromer
B7MIX0; B7MCT2; B7MCT5; B7MCT4; B7MCS3; B7MCS0; B7MLK8; B7MIX1; B7MIW9; B7MBZ2; B7MCS5; P02413; B7MCS8; B7N179; B7MCR9; B7MIU4; B7MAS6; B7MBV5; B7MCT0; B7MCT3; P60624; P68919; B7MBV4; B7MFJ8; B7MCS7; B7MCR7; B7MI68; B7MJ76; B7MFJ7; B7MGC4; B7MAS7; P0A7Q6; B7MKB3; B7MBF0; B7MCS9; B7MCR2; P0A7W1; P02358; B7MCS1; B7MBZ1; B7MCT6; B7MCR3; B7MCV7; P0A7S9; B7MCS2; B7MB86; B7MIU7; B7MCS6; B7MLK7; B7MCT1; B7MAE3; P68679;
6dnc2-152
Structure of 30S ribosomal subunit and RNA polymerase complex in rotated state Heteromer
P0A7Z6; B7MIX3; P0A8T8; B7MFL0; B7MBF0; B7MCS9; B7MCR2; P0A7W3; B7NGD4; B7MCS1; B7MBZ1; B7MCT6; B7MCR3; B7MCV7; P0A7T1; B7MCS2; B7MB86; B7MIU7; B7MCS6; B7MLK7; B7MCT1; B7MAE3; A8A4M2;
6awc2-152
Structure of 30S (S1 depleted) ribosomal subunit and RNA polymerase complex Heteromer
P0A7Z6; B7MIX3; P0A8T8; B7MFL0; B7MBF0; B7MCS9; B7MCR2; P0A7W3; B7NGD4; B7MCS1; B7MBZ1; B7MCT6; B7MCR3; B7MCV7; P0A7T1; B7MCS2; B7MB86; B7MIU7; B7MCS6; B7MLK7; B7MCT1; B7MAE3; A8A4M2;
6awd2-152
30S initiation complex Heteromer
A0A069XYI1; A0A080IK26; D7X302; P0A7R9; V6FZ95; A0A1X3KX08; A0A090BZT4; D7XN21; B7MIU7; L3BXG0; F4SQ43; U9ZNW8; T6N332; A0A0K5Z365; A0A376HTV6; L3PZ69; B6I217; S1CG62; D8A1L7; T9TH92;
6o7k2-152
70S initiation complex Heteromer
U9ZNW8; A0A376HTV6; L3PZ69; B6I217; S1CG62; D8A1L7; T9TH92; D7X302; P0A7R9; V6FZ95; A0A1X3KX08; A0A090BZT4; D7XN21; B7MIU7; A0A080IK26; L3BXG0; F4SQ43; T6N332; A0A0K5Z365; A0A069XYI1; D7Z9F6; V0YP03; A0A1X3HYZ2; L2VF14; A0A0G3K9Z8; D7ZET0; A0A1X3JBQ6; A0A037Y8L6; P0ADY7; H4KMQ6; J7R4G2; S1EK76; D7ZEN7; D7Z9G0; A0A0A8UEU4; A0A0G3K7Z5; D7XH79; A0A0E2L017; D6IE98; A0A0E1TA76; D7Z9G3; A0A029IJY9; P60438; A0A069XK10; D6I2Q0; B7MGC4; I2RJ64; E9YV59;
6o9k2-152
RF2 accommodated state bound 70S complex at long incubation time Heteromer
A0A029IK04; P60438; D7Z9F6; V0AXZ0; A0A1X3JB47; D7ZI15; D7ZET0; D7Z9G5; A0A037Y8L6; P0ADY7; A0A2T1LEK9; A0A0F6C9R0; D6IC61; S1EK76; D7ZEN7; D7Z9G0; A0A029IKB7; A0A0G3K7Z5; D7XH79; U9XYH0; V8F9Y0; A0A1X3JBH6; J7R6H0; A0A080FR68; A0A0G3K5Y7; H4LIZ0; B7MGC4; I2RJ64; A0A0E2L017; C3TPN2; A0A376HTV6; L3PZ69; A0A073FR78; A0A376ZL25; D8A1L7; T9TH92; J7RLQ6; P0A7R9; A0A377DM03; A0A1X3JB38; J7R6H7; D7XN21; B7MIU7; A0A080IK26; D7ZI16; A0A0A8UF41; I4T5W9; L3C5D9; A0A2S5ZJX2;
12×MG;ZN;6ouo2-152
RF2 pre-accommodated state bound Release complex 70S at 24ms Heteromer
A0A029IK04; P60438; D7Z9F6; V0AXZ0; A0A1X3JB47; D7ZI15; D7ZET0; D7Z9G5; A0A037Y8L6; P0ADY7; A0A2T1LEK9; A0A0F6C9R0; D6IC61; S1EK76; D7ZEN7; D7Z9G0; A0A029IKB7; A0A0G3K7Z5; D7XH79; U9XYH0; V8F9Y0; A0A1X3JBH6; J7R6H0; A0A0G3K5Y7; H4LIZ0; B7MGC4; I2RJ64; A0A0E2L017; C3TPN2; A0A376HTV6; L3PZ69; A0A073FR78; A0A376ZL25; D8A1L7; T9TH92; J7RLQ6; P0A7R9; K4XKK1; A0A1X3JB38; J7R6H7; D7XN21; B7MIU7; A0A080IK26; D7ZI16; A0A0A8UF41; I4T5W9; L3C5D9; A0A2S5ZJX2;
12×MG;ZN;6ost2-152
RF2 accommodated state bound Release complex 70S at 24 ms Heteromer
A0A029IK04; P60438; D7Z9F6; V0AXZ0; A0A1X3JB47; D7ZI15; D7ZET0; D7Z9G5; A0A037Y8L6; P0ADY7; A0A2T1LEK9; A0A0F6C9R0; D6IC61; S1EK76; D7ZEN7; D7Z9G0; A0A029IKB7; A0A0G3K7Z5; D7XH79; U9XYH0; V8F9Y0; A0A1X3JBH6; E3PKY6; A0A080FR68; A0A0G3K5Y7; H4LIZ0; B7MGC4; I2RJ64; A0A0E2L017; C3TPN2; A0A376HTV6; L3PZ69; A0A073FR78; A0A376ZL25; D8A1L7; T9TH92; J7RLQ6; P0A7R9; A0A377DM03; A0A1X3JB38; J7R6H7; D7XN21; B7MIU7; A0A080IK26; D7ZI16; A0A0A8UF41; I4T5W9; L3C5D9; A0A2S5ZJX2;
12×MG;ZN;6ot32-152
Release complex 70S Heteromer
A0A029IK04; P60438; D7Z9F6; V0AXZ0; A0A1X3JB47; D7ZI15; D7ZET0; D7Z9G5; A0A037Y8L6; P0ADY7; A0A2T1LEK9; A0A0F6C9R0; D6IC61; S1EK76; D7ZEN7; D7Z9G0; A0A029IKB7; A0A0G3K7Z5; D7XH79; U9XYH0; V8F9Y0; A0A1X3JBH6; J7R6H0; A0A080FR68; A0A0G3K5Y7; H4LIZ0; B7MGC4; I2RJ64; A0A0E2L017; C3TPN2; A0A376HTV6; L3PZ69; A0A073FR78; A0A376ZL25; D8A1L7; T9TH92; J7RLQ6; P0A7R9; L4V1L2; T6LFY5; J7R6H7; D7XN21; B7MIU7; A0A080IK26; D7ZI16; A0A0A8UF41; I4T5W9; L3C5D9;
436×MG;ZN;6ore2-152
RF1 accommodated 70S complex at 60 ms Heteromer
A0A029IK04; P60438; D7Z9F6; V0AXZ0; A0A1X3JB47; D7ZI15; D7ZET0; D7Z9G5; A0A037Y8L6; P0ADY7; A0A2T1LEK9; A0A0F6C9R0; D6IC61; S1EK76; D7ZEN7; D7Z9G0; A0A029IKB7; A0A0G3K7Z5; D7XH79; U9XYH0; V8F9Y0; A0A1X3JBH6; J7R6H0; A0A080FR68; A0A0G3K5Y7; H4LIZ0; B7MGC4; I2RJ64; A0A0E2L017; C3TPN2; A0A376HTV6; L3PZ69; A0A073FR78; A0A376ZL25; D8A1L7; T9TH92; J7RLQ6; P0A7R9; L4V1L2; A0A1X3JB38; J7R6H7; D7XN21; B7MIU7; A0A080IK26; D7ZI16; A0A0A8UF41; I4T5W9; L3C5D9; A0A377MZQ1;
307×MG;ZN;6osk2-152
RF1 pre-accommodated 70S complex at 24 ms Heteromer
A0A029IK04; P60438; D7Z9F6; V0AXZ0; A0A1X3JB47; D7ZI15; D7ZET0; D7Z9G5; A0A037Y8L6; P0ADY7; A0A2T1LEK9; A0A0F6C9R0; D6IC61; S1EK76; D7ZEN7; D7Z9G0; A0A029IKB7; A0A0G3K7Z5; D7XH79; U9XYH0; V8F9Y0; A0A1X3JBH6; J7R6H0; A0A0G3K5Y7; H4LIZ0; B7MGC4; I2RJ64; A0A0E2L017; C3TPN2; A0A376HTV6; L3PZ69; A0A073FR78; A0A376ZL25; D8A1L7; T9TH92; J7RLQ6; P0A7R9; L4V1L2; A0A1X3JB38; J7R6H7; D7XN21; B7MIU7; A0A080IK26; D7ZI16; A0A0A8UF41; I4T5W9; L3C5D9; A0A376PXP6;
295×MG;ZN;6orl2-152
RF1 accommodated state bound Release complex 70S at long incubation time point Heteromer
A0A029IK04; P60438; D7Z9F6; V0AXZ0; A0A1X3JB47; D7ZI15; D7ZET0; D7Z9G5; A0A037Y8L6; P0ADY7; A0A2T1LEK9; A0A0F6C9R0; D6IC61; S1EK76; D7ZEN7; D7Z9G0; A0A029IKB7; A0A0G3K7Z5; D7XH79; U9XYH0; V8F9Y0; A0A1X3JBH6; J7R6H0; A0A080FR68; A0A0G3K5Y7; H4LIZ0; B7MGC4; I2RJ64; A0A0E2L017; C3TPN2; A0A376HTV6; L3PZ69; A0A080IK54; A0A376ZL25; D8A1L7; T9TH92; J7RLQ6; P0A7R9; L4V1L2; A0A1X3JB38; J7R6H7; D7XN21; B7MIU7; A0A080IK26; D7ZI16; A0A0A8UF41; I4T5W9; L3C5D9; A0A377MZQ1;
436×MG;ZN;6osq2-152