Ying-Jie Lu

Transcriptional regulation of fatty acid biosynthesis in Streptococcus pneumoniae

The transcriptional regulation of membrane fatty acid composition in the human pathogen Streptococcus pneumoniae is distinct from the systems utilized in the model organisms Escherichia coli and Bacillus subtilis. The genes encoding the components of type II fatty acid biosynthesis cluster at a single location within the S. pneumoniae genome, and the second gene in this cluster (SPR0376) encodes a transcription factor (FabT) that belongs to the MarR superfamily. Derivatives of S. pneumoniae strain D39 were constructed that lacked functional FabT. This strain had significantly elevated levels of saturated fatty acids and longer chain lengths than the control strain, was unable to grow at pH 5.5 and had increased sensitivity to detergent. Eliminating FabT function increased the expression levels of all of fab genes with the notable exception of fabM. FabT was purified and bound to the DNA palindrome located within the promoter regions of the fabT and fabK genes within the cluster. The analysis of cells with increased expression of individual genes leads to a model where the physical properties of the S. pneumoniae membrane is controlled primarily by the activity of FabK, the enoyl reductase, which diverts intermediates to saturated fatty acid formation, in contrast to E. coli where FabB, an elongation condensing enzyme, pulls the pathway in the direction of unsaturated acid synthesis.

Coupling of Fatty Acid and Phospholipid Synthesis in Bacillus subtilis

plsX (acyl-acyl carrier protein [ACP]:phosphate acyltransferase), plsY (yneS) (acyl-phosphate:glycerol-phosphate acyltransferase), and plsC (yhdO) (acyl-ACP:1-acylglycerol-phosphate acyltransferase) function in phosphatidic acid formation, the precursor to membrane phospholipids. The physiological functions of these genes was inferred from their in vitro biochemical activities, and this study investigated their roles in gram-positive phospholipid metabolism through the analysis of conditional knockout strains in the Bacillus subtilis model system. The depletion of PlsX led to the cessation of both fatty acid synthesis and phospholipid synthesis. The inactivation of PlsY also blocked phospholipid synthesis, but fatty acid formation continued due to the appearance of acylphosphate intermediates and fatty acids arising from their hydrolysis. Phospholipid synthesis ceased following PlsC depletion, but fatty acid synthesis continued at a high rate, leading to the accumulation of fatty acids arising from the dephosphorylation of 1-acylglycerol-3-P followed by the deacylation of monoacylglycerol. Analysis of glycerol 3-P acylation in B. subtilis membranes showed that PlsY was an acylphosphate-specific acyltransferase, whereas PlsC used only acyl-ACP as an acyl donor. PlsX was found in the soluble fraction of disrupted cells but was associated with the cell membrane in intact organisms. These data establish that PlsX is a key enzyme that coordinates the production of fatty acids and membrane phospholipids in B. subtilis.

The reductase steps of the type II fatty acid synthase as antimicrobial targets.

The increasing of multidrug resistance of clinically important pathogens calls for the development of novel antibiotics with unexploited cellular targets. FA biosynthesis in bacteria is catalyzed by a group of highly conserved proteins known as the type II FA synthase (FAS II) system. Bacteria FAS II organization is distinct from its mammalian counterpart; thus the FAS II pathway offers several unique steps for selective inhibition by antibacterial agents. Some known antibiotics that target the FAS II system include triclosan, isoniazid, and thiolactomycin. Recent years have seen remarkable progress in the understanding of the genetics, biochemistry, and regulation of the FAS II system with the availability of the complete geome, sequence for many bacteria. Crystal structures of the FAS II pathway enzymes have been determined for not only the Escherichia coli model system but also other gram-netative and gram-positive pathogens. The protein structures have greatly facilitated structure-based design of novel inhibitors and the improvement of existing antibacterial agents. This review discusses new developments in the discovery of inhibitors that specifically target the two reductase steps of the FAS II system, β-ketoacyl-acyl carrier potein (ACP) reductase and enoyl-ACP reductase.

Identification of a Soluble Diacylglycerol Kinase Required for Lipoteichoic Acid Production in Bacillus subtilis

Diacylglycerol kinases (DagKs) are key enzymes in lipid metabolism that function to reintroduce diacylglycerol formed from the hydrolysis of phospholipids into the biosynthetic pathway. Bacillus subtilis is a prototypical Gram-positive bacterium with a lipoteichoic acid structure containing repeating units of sn-glycerol-1-P groups derived from phosphatidylglycerol head groups. The B. subtilis homolog of the prokaryotic DagK gene family (dgkA; Pfam01219) was not a DagK but rather was an undecaprenol kinase. The three members of the soluble DagK protein family (Pfam00781) in B. subtilis were tested by complementation of an E. coli dgkA mutant, and only the essential yerQ gene possessed DagK activity. This gene was dubbed dgkB, and the soluble protein product was purified, and its DagK activity was verified in vitro. Conditional inactivation of dgkB led to the accumulation of diacylglycerol and the cessation of lipoteichoic acid formation in B. subtilis. This study identifies a soluble protein encoded by the dgkB (yerQ) gene as an essential kinase in the diacylglycerol cycle that drives lipoteichoic acid production.

Topology and active site of PlsY: the bacterial acylphosphate:glycerol-3-phosphate acyltransferase.

The most widely distributed biosynthetic pathway to initiate phosphatidic acid formation in bacterial membrane phospholipid biosynthesis involves the conversion of acyl-acyl carrier protein to acylphosphate by PlsX and the transfer of the acyl group from acylphosphate to glycerol 3-phosphate by an integral membrane protein, PlsY. The membrane topology of Streptococcus pneumoniae PlsY was determined using the substituted cysteine accessibility method. PlsY has five membrane-spanning segments with the amino terminus and two short loops located on the external face of the membrane. Each of the three larger cytoplasmic domains contains a highly conserved sequence motif. Site-directed mutagenesis revealed that each conserved domain was critical for PlsY catalysis. Motif 1 had an essential serine and arginine residue. Motif 2 had the characteristics of a phosphate-binding loop. Mutations of the conserved glycines in motif 2 to alanines resulted in a Km defect for glycerol 3-phosphate binding leading to the conclusion that this motif corresponded to the glycerol 3-phosphate binding site. Motif 3 contained a conserved histidine and asparagine that were important for activity and a glutamate that was critical to the structural integrity of PlsY. PlsY was noncompetitively inhibited by palmitoyl-CoA. These data define the membrane architecture and the critical active site residues in the PlsY family of bacterial acyltransferases.

Domain swapping between Enterococcus faecalis FabN and FabZ proteins localizes the structural determinants for isomerase activity.

Anaerobic unsaturated fatty acid synthesis in bacteria occurs through the introduction of a double bond into the growing acyl chain. In the Escherichia coli model system, FabA catalyzes both the dehydration of β-hydroxydecanoyl-ACP and the isomerization of trans-2-decenoyl-ACP to cis-3-decenoyl-ACP as the essential step. A second dehydratase, FabZ, functions in acyl chain elongation but cannot carry out the isomerization reaction. Enterococcus faecalis has two highly related FabZ homologs. One of these, termed EfFabN, carries out the isomerization reaction in vivo, whereas the other, EfFabZ, does not (Wang, H., and Cronan, J. E. (2004) J. Biol. Chem. 279, 34489–34495). We carried out a series of domain swapping and mutagenesis experiments coupled with in vitro biochemical analyses to define the structural feature(s) that specify the catalytic properties of these two enzymes. Substitution of the β3 and β4 strands of EfFabZ with the corresponding strands from EfFabN was necessary and sufficient to convert EfFabZ into an isomerase. These data are consistent with the hypothesis that the isomerase potential of β-hydroxyacyl-ACP dehydratases is determined by the properties of the β-sheets that dictate the orientation of the central α-helix and thus the shape of the substrate binding tunnel rather than the catalytic machinery at the active site.