Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

Molecular chaperone DnaJ; Participates actively in the response to hyperosmotic and heat shock by preventing the aggregation of stress-denatured proteins and by disaggregating proteins, also in an autonomous, DnaK-independent fashion. Unfolded proteins bind initially to DnaJ; upon interaction with the DnaJ-bound protein, DnaK hydrolyzes its bound ATP, resulting in the formation of a stable complex. GrpE releases ADP from DnaK; ATP binding to DnaK triggers the release of the substrate protein, thus completing the reaction cycle. Several rounds of ATP-dependent interactions between DnaJ, [...]

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

Molecular chaperone DnaK; Acts as a chaperone; Belongs to the heat shock protein 70 family.

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

Chaperonin GroL; Prevents misfolding and promotes the refolding and proper assembly of unfolded polypeptides generated under stress conditions.

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S2; Derived by automated computational analysis using gene prediction method: Protein Homology; Belongs to the universal ribosomal protein uS2 family.

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S5; Located at the back of the 30S subunit body where it stabilizes the conformation of the head with respect to the body. Belongs to the universal ribosomal protein uS5 family.

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S7; One of the primary rRNA binding proteins, it binds directly to 16S rRNA where it nucleates assembly of the head domain of the 30S subunit. Is located at the subunit interface close to the decoding center, probably blocks exit of the E-site tRNA; Belongs to the universal ribosomal protein uS7 family.

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S12; Interacts with and stabilizes bases of the 16S rRNA that are involved in tRNA selection in the A site and with the mRNA backbone. Located at the interface of the 30S and 50S subunits, it traverses the body of the 30S subunit contacting proteins on the other side and probably holding the rRNA structure together. The combined cluster of proteins S8, S12 and S17 appears to hold together the shoulder and platform of the 30S subunit.

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S17; One of the primary rRNA binding proteins, it binds specifically to the 5'-end of 16S ribosomal RNA.

ATP-dependent chaperone ClpB; Derived by automated computational analysis using gene prediction method: Protein Homology; Belongs to the ClpA/ClpB family.

Molecular chaperone DnaJ; Participates actively in the response to hyperosmotic and heat shock by preventing the aggregation of stress-denatured proteins and by disaggregating proteins, also in an autonomous, DnaK-independent fashion. Unfolded proteins bind initially to DnaJ; upon interaction with the DnaJ-bound protein, DnaK hydrolyzes its bound ATP, resulting in the formation of a stable complex. GrpE releases ADP from DnaK; ATP binding to DnaK triggers the release of the substrate protein, thus completing the reaction cycle. Several rounds of ATP-dependent interactions between DnaJ, [...]

ATP-dependent chaperone ClpB; Derived by automated computational analysis using gene prediction method: Protein Homology; Belongs to the ClpA/ClpB family.

Molecular chaperone DnaK; Acts as a chaperone; Belongs to the heat shock protein 70 family.

ATP-dependent chaperone ClpB; Derived by automated computational analysis using gene prediction method: Protein Homology; Belongs to the ClpA/ClpB family.

Chaperonin GroL; Prevents misfolding and promotes the refolding and proper assembly of unfolded polypeptides generated under stress conditions.

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

Molecular chaperone DnaJ; Participates actively in the response to hyperosmotic and heat shock by preventing the aggregation of stress-denatured proteins and by disaggregating proteins, also in an autonomous, DnaK-independent fashion. Unfolded proteins bind initially to DnaJ; upon interaction with the DnaJ-bound protein, DnaK hydrolyzes its bound ATP, resulting in the formation of a stable complex. GrpE releases ADP from DnaK; ATP binding to DnaK triggers the release of the substrate protein, thus completing the reaction cycle. Several rounds of ATP-dependent interactions between DnaJ, [...]

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

Molecular chaperone DnaK; Acts as a chaperone; Belongs to the heat shock protein 70 family.

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

Chaperonin GroL; Prevents misfolding and promotes the refolding and proper assembly of unfolded polypeptides generated under stress conditions.

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S2; Derived by automated computational analysis using gene prediction method: Protein Homology; Belongs to the universal ribosomal protein uS2 family.

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S5; Located at the back of the 30S subunit body where it stabilizes the conformation of the head with respect to the body. Belongs to the universal ribosomal protein uS5 family.

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S7; One of the primary rRNA binding proteins, it binds directly to 16S rRNA where it nucleates assembly of the head domain of the 30S subunit. Is located at the subunit interface close to the decoding center, probably blocks exit of the E-site tRNA; Belongs to the universal ribosomal protein uS7 family.

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S12; Interacts with and stabilizes bases of the 16S rRNA that are involved in tRNA selection in the A site and with the mRNA backbone. Located at the interface of the 30S and 50S subunits, it traverses the body of the 30S subunit contacting proteins on the other side and probably holding the rRNA structure together. The combined cluster of proteins S8, S12 and S17 appears to hold together the shoulder and platform of the 30S subunit.

Hypothetical protein; Derived by automated computational analysis using gene prediction method: Protein Homology.

30S ribosomal protein S17; One of the primary rRNA binding proteins, it binds specifically to the 5'-end of 16S ribosomal RNA.

Molecular chaperone DnaJ; Participates actively in the response to hyperosmotic and heat shock by preventing the aggregation of stress-denatured proteins and by disaggregating proteins, also in an autonomous, DnaK-independent fashion. Unfolded proteins bind initially to DnaJ; upon interaction with the DnaJ-bound protein, DnaK hydrolyzes its bound ATP, resulting in the formation of a stable complex. GrpE releases ADP from DnaK; ATP binding to DnaK triggers the release of the substrate protein, thus completing the reaction cycle. Several rounds of ATP-dependent interactions between DnaJ, [...]

Hypothetical protein; Too many ambiguous residues; Derived by automated computational analysis using gene prediction method: Protein Homology.