Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It autophosphorylates an histidine in its phosphoacceptor domain and phosphorylates an aspartic acid present in the response regulator receiver domain; Contains a CheB-type methylesterase catalytic domain and a CheR-type methyltransferase domain, both involved in the bacterial chemotaxis system; Contains a PAS/PAC domain; Seems localized in the cytoplasm; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It autophosphorylates an histidine in its phosphoacceptor domain and phosphorylates an aspartic acid present in the response regulator receiver domain; Contains a CheB-type methylesterase catalytic domain and a CheR-type methyltransferase domain, both involved in the bacterial chemotaxis system; Contains a PAS/PAC domain; Seems localized in the cytoplasm; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It autophosphorylates an histidine in its phosphoacceptor domain and phosphorylates an aspartic acid present in the response regulator receiver domain; Contains a CheB-type methylesterase catalytic domain and a CheR-type methyltransferase domain, both involved in the bacterial chemotaxis system; Contains a PAS/PAC domain; Seems localized in the cytoplasm; Family membership.

Putative protein.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It autophosphorylates an histidine in its phosphoacceptor domain and phosphorylates an aspartic acid present in the response regulator receiver domain; Contains a CheB-type methylesterase catalytic domain and a CheR-type methyltransferase domain, both involved in the bacterial chemotaxis system; Contains a PAS/PAC domain; Seems localized in the cytoplasm; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

Putative protein.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

Hypothetical membrane protein; Contains a putative lipoprotein signal peptide cleaved between the residues 17 and 18; Possibly localized in the outer membrane; Hypothetical protein.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

Conserved hypothetical lipoprotein; This Protein likely adopts a beta-propeller fold; Contains a prokaryotic lipoprotein signal peptide cleaved between the residues 21 and 22; Localized in the outer membrane; Conserved hypothetical protein.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It autophosphorylates an histidine in its phosphoacceptor domain and phosphorylates an aspartic acid present in the response regulator receiver domain; Contains a CheB-type methylesterase catalytic domain and a CheR-type methyltransferase domain, both involved in the bacterial chemotaxis system; Contains a PAS/PAC domain; Seems localized in the cytoplasm; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Response regulator proteins are involved in the two-component signal transduction systems to detect and respond to environmental changes. These proteins consist of two domains, an N-terminal response regulator receiver domain that is substrate for a histidine protein kinase sensor, and a variable C-terminal effector domain with DNA- binding activity (here, a LuxR-type HTH domain) that acts as transcriptional regulator; Family membership.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Putative protein.

The sensor histidine kinase belongs to two-component signal transduction systems. It catalyzes the ATP dependent autophosphorylation of a conserved histidine in its phosphoacceptor domain and the signal dependent phosphorylation of a conserved aspartic acid present in the response regulator receiver domain; Signal peptide cleaved between the residues 20 and 21; Contains four N- terminal tetratrico peptide repeats (TPR); Localized in the cytoplasmic membrane; Family membership.

Hypothetical membrane protein; Contains a putative lipoprotein signal peptide cleaved between the residues 17 and 18; Possibly localized in the outer membrane; Hypothetical protein.