A genetic screen for mutations affecting temperature sensing in Bacillus subtilis.

Two component systems, composed of a receptor histidine kinase and a cytoplasmic response regulator, regulate pivotal cellular processes in microorganisms. Here we describe a new screening procedure for the identification of amino acids that are crucial for the functioning of DesK, a prototypic thermosensor histidine kinase from Bacillus subtilis. This experimental strategy involves random mutagenesis of the membrane sensor domain of the DesK coding sequence, followed by the use of a detection procedure based on changes in the colony morphogenesis that take place during the sporulation programme of B. subtilis. This method permitted us the recovery of mutants defective in DesK temperature sensing. This screening approach could be applied to all histidine kinases of B. subtilis and also to kinases of other bacteria that are functionally expressed in this organism. Moreover, this reporter assay could be expanded to develop reporter assays for a variety of transcriptionally regulated systems.

Bacillus subtilis RapA phosphatase domain interaction with its substrate, phosphorylated Spo0F, and its inhibitor, the PhrA peptide.

Rap proteins in Bacillus subtilis regulate the phosphorylation level or the DNA-binding activity of response regulators such as Spo0F, involved in sporulation initiation, or ComA, regulating competence development. Rap proteins can be inhibited by specific peptides generated by the export-import processing pathway of the Phr proteins. Rap proteins have a modular organization comprising an amino-terminal alpha-helical domain connected to a domain formed by six tetratricopeptide repeats (TPR). In this study, the molecular basis for the specificity of the RapA phosphatase for its substrate, phosphorylated Spo0F (Spo0F∼P), and its inhibitor pentapeptide, PhrA, was analyzed in part by generating chimeric proteins with RapC, which targets the DNA-binding domain of ComA, rather than Spo0F∼P, and is inhibited by the PhrC pentapeptide. In vivo analysis of sporulation efficiency or competence-induced gene expression, as well as in vitro biochemical assays, allowed the identification of the amino-terminal 60 amino acids as sufficient to determine Rap specificity for its substrate and the central TPR3 to TPR5 (TPR3-5) repeats as providing binding specificity toward the Phr peptide inhibitor. The results allowed the prediction and testing of key residues in RapA that are essential for PhrA binding and specificity, thus demonstrating how the widespread structural fold of the TPR is highly versatile, using a common interaction mechanism for a variety of functions in eukaryotic and prokaryotic organisms.

Functional role for a conserved aspartate in the Spo0E signature motif involved in the dephosphorylation of the Bacillus subtilis sporulation regulator Spo0A.

Sporulation is a complex developmental system characterizing Gram-positive bacteria of the genus Bacillus and Clostridium. In Bacillus subtilis the phosphorelay signal transduction system regulates the initiation of sporulation by integrating a myriad of positive and negative signals through the action of histidine sensor kinases and aspartyl phosphate phosphatases. The Spo0E family of phosphatases dephosphorylates the Spo0A response regulator and transcription factor of the phosphorelay. In this study we analyzed the role of the Spo0E signature motif in protein activity. This family is characterized by a conserved signature motif centered around the sequence "SQELD." Alanine scanning mutagenesis was carried out on the T(35)IXXSQ ELDCLI(46) residues of B. subtilis Spo0E and in vivo and in vitro activities were analyzed. The ability of the mutant proteins to interact with Spo0A approximately P was assayed by fluorescence resonance energy transfer spectroscopy. The results suggested that aspartate 43 has a critical role in Spo0E catalytic activity, whereas the other residues have a role in protein conformation and/or interaction with Spo0A. Residues Thr(35) and Cys(44) did not seem to have any critical functional or structural role. We propose that Asp(43) of Spo0E may function in a manner similar to the one proposed for the catalytic mechanisms of nucleotidase members of the haloacid dehalogenase family. These proteins use an aspartyl nucleophile as their common catalytic strategy and the active site of haloacid dehalogenase proteins shares a common geometry and identity of conserved amino acids with the active site of response regulators ( Ridder, I. S., and Dijkstra, B. W. (1999) Biochem. J. 339, 223-226 ).

Membrane topology of the acyl-lipid desaturase from Bacillus subtilis.

The Bacillus subtilis acyl-lipid desaturase (Delta5-Des) is an iron-dependent integral membrane protein, able to selectively introduce double bonds into long chain fatty acids. Structural information on membrane-bound desaturases is still limited, and the present topological information is restricted to hydropathy plots or sequence comparison with the evolutionary related alkane hydroxylase. The topology of Delta5-Des was determined experimentally in Escherichia coli using a set of nine different fusions of N-terminal fragments of Delta5-Des with the reporter alkaline phosphatase (Delta5-Des-PhoA). The alkaline phosphatase activities of cells expressing the Delta5-Des-PhoA fusions, combined with site-directed mutagenesis of His residues identified in most desaturases, suggest that a tripartite motif of His essential for catalysis is located on the cytoplasmic phase of the membrane. These data, together with surface Lys biotinylation experiments, support a model for Delta5-Des as a polytopic membrane protein with six transmembrane- and one membrane-associated domain, which likely represents a substrate-binding motif. This study provides the first experimental evidence for the topology of a plasma membrane fatty acid desaturase. On the basis of our results and the presently available hydrophobicity profile of many acyl-lipid desaturases, we propose that these enzymes contain a new transmembrane domain that might play a critical role in the desaturation of fatty acids esterified in glycerolipids.