Binding of proteolytically processed phospholipase D from Streptomyces chromofuscus to phosphatidylcholine membranes facilitates vesicle aggregation and fusion

Lysine propionylation modulates the transcriptional activity of phosphate regulator PhoP in Saccharopolyspora erythraea

Phosphate concentration extensively modulates the central physiological processes mediated by the two-component system PhoR-PhoP in actinobacteria. The system serves a role beyond phosphate metabolism, mediating crucial functions in nitrogen and carbon metabolism, and secondary metabolism in response to the nutritional states. Here, we found that the phosphate-sensing regulator PhoP was propionylated, and thus lost its DNA-binding activity in vivo and in vitro in Saccharopolyspora erythraea. Two key conserved lysine residues 198 and 203 (K198 and K203) in winged HTH motif at the C-terminal domain of PhoP are propionylated by protein acyltransferase AcuA (encoding by sace_5148). Single amino acid mutation of these two lysine residues resulted in severely impaired binding of PhoP to PHO box. The addition of propionate (to supply precursors for erythromycin biosynthesis) increases the intracellular propionylation level of PhoP, resulting in the loss of response to phosphate availability. Furthermore, simultaneous mutation of K198 and K203 of PhoP to arginine, mimicking the non-propionylated form, promotes the expression of the PhoP regulon under the condition of propionate addition. Together, these findings present a common regulatory mechanism of genes' expression mediated by posttranslational regulation of OmpR family transcriptional regulator PhoP and provide new insights into the multifaceted regulation of metabolism in response to nutritional signals.

Transcriptomic studies of phosphate control of primary and secondary metabolism in Streptomyces coelicolor

Phosphate controls the biosynthesis of many classes of secondary metabolites that belong to different biosynthetic groups, indicating that phosphate control is a general mechanism governing secondary metabolism. We refer in this article to the molecular mechanisms of regulation, mediated by the two-component system PhoR-PhoP, of the primary metabolism and the biosynthesis of antibiotics. The two-component PhoR-PhoP system is conserved in all Streptomyces and related actinobacteria sequenced so far, and involves a third component PhoU that modulates the signal transduction cascade. The PhoP DNA-binding sequence is well characterized in Streptomyces coelicolor. It comprises at least two direct repeat units of 11 nt, the first seven of which are highly conserved. Other less conserved direct repeats located adjacent to the core ones can also be bound by PhoP through cooperative protein-protein interactions. The phoR-phoP operon is self-activated and requires phosphorylated PhoP to mediate the full response. About 50 up-regulated PhoP-dependent genes have been identified by comparative transcriptomic studies between the parental S. coelicolor M145 and the ΔphoP mutant strains. The PhoP regulation of several of these genes has been studied in detail using EMSA and DNase I footprinting studies as well as in vivo expression studies with reporter genes and RT-PCR transcriptomic analyses.

Intracellular phospholipase A1gamma (iPLA1gamma) is a novel factor involved in coat protein complex I- and Rab6-independent retrograde transport between the endoplasmic reticulum and the Golgi complex

The mammalian intracellular phospholipase A(1) (iPLA(1)) family consists of three members, iPLA(1)alpha/PA-PLA(1), iPLA(1)beta/p125, and iPLA(1)gamma/KIAA0725p. Although iPLA(1)beta has been implicated in organization of the ER-Golgi compartments, little is known about the physiological role of its closest paralog, iPLA(1)gamma. Here we show that iPLA(1)gamma mediates a specific retrograde membrane transport pathway between the endoplasmic reticulum (ER) and the Golgi complex. iPLA(1)gamma appeared to be localized to the cytosol, the cis-Golgi, and the ER-Golgi intermediate compartment (ERGIC). Time-lapse microscopy revealed that a population of GFP-iPLA(1)gamma was associated with transport carriers moving out from the Golgi complex. Knockdown of iPLA(1)gamma expression by RNAi did not affect the anterograde transport of VSVGts045 but dramatically delayed two types of Golgi-to-ER retrograde membrane transport; that is, transfer of the Golgi membrane into the ER in the presence of brefeldin A and delivery of cholera toxin B subunit from the Golgi complex to the ER. Notably, knockdown of iPLA(1)gamma did not impair COPI- and Rab6-dependent retrograde transports represented by ERGIC-53 recycling and ER delivery of Shiga toxin, respectively. Thus, iPLA(1)gamma is a novel membrane transport factor that contributes to a specific Golgi-to-ER retrograde pathway distinct from presently characterized COPI- and Rab6-dependent pathways.

Listeria monocytogenes phosphatidylinositol-specific phospholipase C: Kinetic activation and homing in on different interfaces

The phosphatidylinositol-specific phospholipase C (PI-PLC) from Listeria monocytogenes forms aggregates with anionic lipids leading to low activity. The specific activity of the enzyme can be enhanced by dilution of the protein or by addition of both zwitterionic and neutral amphiphiles (e.g., diheptanoylphosphatidylcholine or Triton X-100) or 0.1-0.2 M inorganic salts. Activation by amphiphiles occurs with both micellar (phosphatidylinositol dispersed in detergents) and monomeric [dibutroylphosphatidylinositol (diC(4)PI)] phosphotransferase substrates and inositol 1,2-(cyclic)-phosphate (cIP), the phosphodiesterase substrate. The presence of zwitterionic and neutral amphiphiles (to which the protein binds weakly) dilutes the surface concentration of the interfacial anionic substrate and thereby reduces the level of enzyme-phospholipid particle aggregation. Zwitterionic amphiphiles also can bind directly to the protein and enhance catalysis since they enhance both diC(4)PI and cIP hydrolysis. In contrast to activation by amphiphiles, the rate enhancement by salt occurs for only the phosphotransferase step of the reaction. Added salt has a synergistic effect with zwitterionic phospholipids, leading to high specific activities for PI cleavage with only moderate dilution of the anionic substrate in the interface. This kinetic activation correlates with weakening of strong PI-PLC hydrophobic interactions with the interface as monitored by a decrease in the maximum monolayer surface pressure for insertion of the protein. Several point mutations of surface hydrophobic residues (W49A, L51A, L235A, and F237W) can dramatically alter the unusual kinetics of this secreted enzyme. The high affinity of PI-PLC for anionic phospholipids along with a strong hydrophobic interaction, which gives rise to the unusual kinetic behavior, is considered in terms of how it might contribute to the role of this phospholipase in L. monocytogenes infectivity.

Phosphate control of phoA, phoC and phoD gene expression in Streptomyces coelicolor reveals significant differences in binding of PhoP to their promoter regions

Three putative alkaline phosphatase genes, phoA, phoC and phoD, were identified in the genome of Streptomyces coelicolor by homology with the amino acid sequence obtained from the PhoA protein of Streptomyces griseus. PhoA and PhoC correspond to broad-spectrum alkaline phosphatases whereas PhoD is similar to a Ca(2+)-dependent phospholipase D of Streptomyces chromofuscus. The phoA and phoD genes were efficiently expressed in R5 medium under phosphate-limited conditions, as shown by studies using the xylE reporter gene, whereas phoC was poorly transcribed under the same conditions. Expression of phoA was clearly PhoP-dependent since it was not transcribed in the S. coelicolor DeltaphoP mutant and was strongly activated under low phosphate concentrations. Similarly, expression of phoD was PhoP-dependent and highly sensitive to phosphate availability. By contrast, expression of phoC was not PhoP-dependent. Electrophoretic mobility shift assays showed that PhoP binds to the phoA and phoD promoters, but not to that of phoC. Footprinting studies with GST-PhoP revealed the presence of a PHO box (two direct 11 nt repeats) in the phoA promoter and two PHO boxes in the promoter of phoD. The transcription start points of the three promoters were identified by primer extension. The transcription start point of phoD coincides with the G of its translation start codon, indicating that this gene is transcribed as a leaderless mRNA. The deduced -10 and -35 regions of phoD (but not those of phoA) overlapped with the PHO boxes in this promoter, suggesting that an excess of PhoP interferes with binding of the RNA polymerase to this promoter. In summary, the three promoters showed clear differences in the modulation of their expression by PhoP.

Spontaneous integration of transmembrane peptides into a bacterial magnetic particle membrane and its application to display of useful proteins

An antimicrobial peptide, temporin L, and its derivative (TL-A2) were employed as anchor peptides and displayed streptavidin on a bacterial magnetic particle (BMP) membrane. The ribotoxin L3 loop (L3) and the arginine-chain peptide (R(12)), which are carrier peptides permeable to eukaryotic cell membranes, were also used. The peptides were labeled with a fluorescent dye, 4-fluoro-7-nitrobenzofurazan (NBD), at the N-terminal region (NBD-peptides) and mixed with BMPs. A specific integration of NBD-temporin L into a BMP membrane was observed. The basic amino acids in temporin L played an important role in the integration into BMPs. Biotin conjugated to the N-terminus of temporin L was integrated into a BMP membrane. The C-terminus of temporin L was incorporated into a BMP membrane, and the N-terminus was located on the BMP membrane surface. The present study shows that temporin L is a stable molecular anchor on BMPs by the binding of soluble protein to the N-terminus.

Phospholipase D and its application in biocatalysis

Phospholipase D (PLD) from plants or microorganisms is used as biocatalyst in the transformation of phospholipids and phospholipid analogs in both laboratory and industrial scale. In recent years the elucidation of the primary structure of many PLDs from several sources, as well as the resolution of the first crystal structure of a microbial PLD, have yielded new insights into the structural basis and the catalytic mechanism of this catalyst. This review summarizes some new results of PLD research in the light of application.

Expression and characterization of a heterodimer of Streptomyces chromofuscus phospholipase D

Streptomyces chromofuscus phospholipase D (PLD) is secreted by the bacterium and proteolytically cleaved to a more active form (PLD(37/18)) where the two parts of the molecule are still tightly associated. Based on previous sequencing results of authentic PLD(37/18), we have constructed a vector consisting of separate ORFs for the N-terminal and C-terminal portions of S. chromofuscus PLD and overexpressed active heterodimeric PLD. Neither fragment cloned separately folded properly. The identity of each peptide was confirmed by peptide-mass fingerprinting with MALDI-TOF mass spectrometry. The recombinant complex had a specific activity about six times higher than that of the recombinant intact PLD enzyme and was no longer activated by phosphatidic acid (PA). Phosphotransferase activity, binding affinity to phospholipid vesicles, loss of product activation, pH profile and pH-related Ca(2+) activation and inhibition were comparable to authentic PLD(37/18) purified from S. chromofuscus growth medium. PLD(37) alone could also be isolated; the enzyme was active but not as stable as PLD(37/18). These experimental results strongly support the hypothesis that the C-terminal peptide is necessary for correct folding and insertion of catalytic metal ions. However, they suggest the ligands involved in Fe(3+) coordination must be altered upon cleavage of the protein. Asp389, in the C-terminal fragment, whose replacement impairs Fe(3+) binding to the protein, must be replaced by another ligand, since the N-terminal fragment, once folded, is active. In the process of cloning the two peptides, the complete signal sequence for this protein was also determined. The signal peptide of S. chromofuscus PLD enzyme contained a twin arginine motif suggesting that S. chromofuscus PLD, like Bacillus subtilis phoD, is most likely secreted by the TAT translocation pathway under the transcriptional control of the pho regulon.

Transphosphatidylation activity of Streptomyces chromofuscus phospholipase D in biomimetic membranes

The phospholipase D (PLD) from Streptomyces chromofuscus belongs to the superfamily of PLDs. All the enzymes included in this superfamily are able to catalyze both hydrolysis and transphosphatidylation activities. However, S. chromofuscus PLD is calcium dependent and is often described as an enzyme with weak transphosphatidylation activity. S. chromofuscus PLD-catalyzed hydrolysis of phospholipids in aqueous medium leads to the formation of phosphatidic acid. Previous studies have shown that phosphatidic acid-calcium complexes are activators for the hydrolysis activity of this bacterial PLD. In this work, we investigated the influence of diacylglycerols (naturally occurring alcohols) as candidates for the transphosphatidylation reaction. Our results indicate that the transphosphatidylation reaction may occur using diacylglycerols as a substrate and that the phosphatidylalcohol produced can be directly hydrolyzed by PLD. We also focused on the surface pressure dependency of PLD-catalyzed hydrolysis of phospholipids. These experiments provided new information about PLD activity at a water-lipid interface. Our findings showed that classical phospholipid hydrolysis is influenced by surface pressure. In contrast, phosphatidylalcohol hydrolysis was found to be independent of surface pressure. This latter result was thought to be related to headgroup hydrophobicity. This work also highlights the physiological significance of phosphatidylalcohol production for bacterial infection of eukaryotic cells.

Phosphohydrolase and transphosphatidylation reactions of two Streptomyces phospholipase D enzymes: covalent versus noncovalent catalysis

A kinetic comparison of the hydrolase and transferase activities of two bacterial phospholipase D (PLD) enzymes with little sequence homology provides insights into mechanistic differences and also the more general role of Ca(2+) in modulating PLD reactions. Although the two PLDs exhibit similar substrate specificity (phosphatidylcholine preferred), sensitivity to substrate aggregation or Ca(2+), and pH optima are quite distinct. Streptomyces sp. PMF PLD, a member of the PLD superfamily, generates both hydrolase and transferase products in parallel, consistent with a mechanism that proceeds through a covalent phosphatidylhistidyl intermediate where the rate-limiting step is formation of the covalent intermediate. For Streptomyces chromofuscus PLD, the two reactions exhibit different pH profiles, a result consistent with a mechanism likely to involve direct attack of water or an alcohol on the phosphorus. Ca(2+), not required for monomer or micelle hydrolysis, can activate both PLDs for hydrolysis of PC unilamellar vesicles. In the case of Streptomyces sp. PMF PLD, Ca(2+) relieves product inhibition by interactions with the phosphatidic acid (PA). A similar rate enhancement could occur with other HxKx(4)D-motif PLDs as well. For S. chromofuscus PLD, Ca(2+) is absolutely critical for binding of the enzyme to PC vesicles and for PA activation. That the Ca(2+)-PA activation involves a discreet site on the protein is suggested by the observation that the identity of the C-terminal residue in S. chromofuscus PLD can modulate the extent of product activation.

Evolutionary conservation of physical and functional interactions between phospholipase D and actin

Phospholipase D (PLD) enzymes from bacteria to mammals exhibit a highly conserved core structure and catalytic mechanism, but whether protein-protein interactions exhibit similar commonality is unknown. Our objective was to determine whether the physical and functional interactions of mammalian PLDs with actin are evolutionarily conserved among bacterial and plant PLDs. Highly purified bacterial and plant PLDs cosedimented with mammalian skeletal muscle alpha-actin, indicating direct interaction with F-actin. The binding of bacterial PLD to G-actin exhibited two affinity states, with dissociation constants of 1.13 pM and 0.58 microM. The effects of actin on the activities of bacterial and plant PLDs were polymerization dependent; monomeric G-actin inhibited PLD activity, whereas polymerized F-actin augmented PLD activity. Actin modulation of bacterial and plant PLDs demonstrated kinetic characteristics, efficacies, and potencies similar to those of human PLD1. Thus, physical and functional interactions between PLD and actin in PLD family members from bacteria to mammals are highly conserved throughout evolution.

Cloning, overexpression, and characterization of a bacterial Ca2+-dependent phospholipase D

Phospholipase D (PLD), an important enzyme involved in signal transduction in mammals, is also secreted by many microorganisms. A highly conserved HKD motif has been identified in most PLD homologs in the PLD superfamily. However, the Ca(2+)-dependent PLD from Streptomyces chromofuscus exhibits little homology to other PLDs. We have cloned (using DNA isolated from the ATCC type strain), overexpressed in Escherichia coli (two expression systems, pET-23a(+) and pTYB11), and purified the S. chromofuscus PLD. Based on attempts at sequence alignment with other known Ca(2+)-independent PLD enzymes from Streptomyces species, we mutated five histidine residues (His72, His171, His187, His200, His226) that could be part of variants of an HKD motif. Only H187A and H200A showed dramatically reduced activity. However, mutation of these histidine residues to alanine also significantly altered the secondary structure of PLD. Asparagine replacements at these positions yielded enzymes with structure and activity similar to the recombinant wild-type PLD. The extent of phosphatidic acid (PA) activation of PC hydrolysis by the recombinant PLD enzymes differed in magnitude from PLD purified from S. chromofuscus culture medium (a 2-fold activation rather than 4-5-fold). One of the His mutants, H226A, showed a 12-fold enhancement by PA, suggesting this residue is involved in the kinetic activation. Another notable difference of this bacterial PLD from others is that it has a single cysteine (Cys123); other Streptomyces Ca(2+)-independent PLDs have eight Cys involved in intramolecular disulfide bonds. Both C123A and C123S, with secondary structure and stability similar to recombinant wild-type PLD, exhibited specific activity reduced by 10(-5) and 10(-4). The Cys mutants still bound Ca(2+), so that it is likely that this residue is part of the active site of the Ca(2+)-dependent PLD. This would suggest that S. chromofuscus PLD is a member of a new class of PLD enzymes.

Role of calcium and membrane organization on phospholipase D localization and activity. Competition between a soluble and insoluble substrate

The phospholipase D (PLD) from Streptomyces chromofuscus is a soluble enzyme known to be activated by the phosphatidic acid-calcium complexes. PLD-catalyzed hydrolysis of phospholipids in aqueous medium leads to the formation of phosphatidic acid (PA). Previous studies concluded on an allosteric activation of PLD by the PA-calcium complexes. In this work, the role of PA and calcium was investigated in terms of membrane structure and dynamics. The role of calcium in PLD partitioning between the soluble phase and the water-lipid interface was tested. The monomolecular film technique was used to measure both membrane dynamics and PLD activity. These experiments provided information on PLD activity at a water-lipid interface. Moreover, the ability of PA to enhance PLD activity toward phosphatidylcholine was correlated to the physical properties of PA itself, affecting the rheology of the membrane. The effect of calcium was investigated on PLD binding to lipids and on the catalytic process by competition experiments between a soluble and a vesicular substrate. These experiments confirmed the absolute PLD requirement for calcium and pointed out the importance of calcium for PLD catalytic process and for the enzyme location at the water-lipid interface.