Study on thermostability of phospholipase D from Streptomyces sp

Phospholipids (PLs) know-how: exploring and exploiting phospholipase D for its industrial dissemination

Owing to their numerous nutritional and bioactive functions, phospholipids (PLs), which are major components of biological membranes in all living organisms, have been widely applied as nutraceuticals, food supplements, and cosmetic ingredients. To date, PLs are extracted solely from soybean or egg yolk, despite the diverse market demands and high cost, owing to a tedious and inefficient manufacturing process. A microbial-based manufacturing process, specifically phospholipase D (PLD)-based biocatalysis and biotransformation process for PLs, has the potential to address several challenges associated with the soybean- or egg yolk-based supply chain. However, poor enzyme properties and inefficient microbial expression systems for PLD limit their wide industrial dissemination. Therefore, sourcing new enzyme variants with improved properties and developing advanced PLD expression systems are important. In the present review, we systematically summarize recent achievements and trends in the discovery, their structural properties, catalytic mechanisms, expression strategies for enhancing PLD production, and its multiple applications in the context of PLs. This review is expected to assist researchers to understand current advances in this field and provide insights for further molecular engineering efforts toward PLD-mediated bioprocessing.

Acyl Chain Specificity of Marine Streptomyces klenkii PhosPholipase D and Its Application in Enzymatic Preparation of Phosphatidylserine

Mining of phospholipase D (PLD) with altered acyl group recognition except its head group specificity is also useful in terms of specific acyl size phospholipid production and as diagnostic reagents for quantifying specific phospholipid species. Microbial PLDs from Actinomycetes, especially Streptomyces, best fit this process requirements. In the present studies, a new PLD from marine Streptomyces klenkii (SkPLD) was purified and biochemically characterized. The optimal reaction temperature and pH of SkPLD were determined to be 60 °C and 8.0, respectively. Kinetic analysis showed that SkPLD had the relatively high catalytic efficiency toward phosphatidylcholines (PCs) with medium acyl chain length, especially 12:0/12:0-PC (67.13 S-1 mM-1), but lower catalytic efficiency toward PCs with long acyl chain (>16 fatty acids). Molecular docking results indicated that the different catalytic efficiency was related to the increased steric hindrance of long acyl-chains in the substrate-binding pockets and differences in hydrogen-bond interactions between the acyl chains and substrate-binding pockets. The enzyme displayed suitable transphosphatidylation activity and the reaction process showed 26.18% yield with L-serine and soybean PC as substrates. Present study not only enriched the PLD enzyme library but also provide guidance for the further mining of PLDs with special phospholipids recognition properties.

Efficient secretion expression of phospholipase D in Bacillus subtilis and its application in synthesis of phosphatidylserine by enzyme immobilization

Transphosphatidylation catalyzed by phospholipase D has gained increasing attention for producing phosphatidylserine (PS), which can be used in functional food and medicine. In this study, we investigated the effects of six signal peptides on the secretion of PLD (PLD_sa) from Streptomyces antibioticus TCCC 21059 in the food-grade GRAS bacterium Bacillus subtilis. It indicated that the optimal signal peptide DacB with an Ala-X-Ala sequence motif at the C-terminus showed the highest secretory expression ability, resulting in increased production of 2.84 U/mL PLD_sa. Then PLD_sa was immobilized on the epoxy-based carriers, and one of these carriers allowed PLD_sa loading of up to 2.7 mg/g. The immobilized PLD_sa was more stable over a wide range of pH value (4.5-7.5) and temperature (16 °C-60 °C) than free PLD_sa. Subsequently, the synthesis of PS from soybean phosphatidylcholine (PC) was carried out in purely aqueous solution using immobilized PLD_sa, leading to a high yield of 65%. The immobilized PLD_sa catalyst maintained a relative PS production of 60% after 5 recycles. Notably, the use of toxic solvent was completely eliminated in the whole process, which would be more profitable for the application of PS.

Enhancing the thermostability of phospholipase D from Streptomyces halstedii by directed evolution and elucidating the mechanism of a key amino acid residue using molecular dynamics simulation

To enhance the thermostability of phospholipase D (PLD), error-prone polymerase chain reaction method was used to create mutants of PLD (PLD_sh) from Streptomyces halstedii. One desirable mutant (S163F) with Ser to Phe substitution at position 163 was screened with high-throughput assay. S163F exhibited a 10 °C higher optimum temperature than wild-type (WT). Although WT exhibited almost no activity after incubating at 50 °C for 40 min, S163F still displayed 27% of its highest activity after incubating at 50 °C for 60 min. Furthermore, the half-life of S163F at 50 °C was 3.04-fold higher than that of WT. The analysis of molecular dynamics simulation suggested that the Ser163Phe mutation led to the formation of salt bridge between Lys300 and Glu314 and a stronger hydrophobic interaction of Phe163 with Pro341, Leu342, and Trp460, resulting in an increased structural rigidity and overall enhanced stability at high temperature. This study provides novel insights on PLD tolerance to high temperature by investigating the structure-activity relationship. In addition, it provides strong theoretical foundation and preliminary information on the engineering of PLD with improved characteristics to meet industrial demand.

Deletion the C-terminal peptides of Vibrio harveyi phospholipase D significantly improved its enzymatic properties

A novel phospholipase D that originate from marine Vibrio harveyi (VhPLD) was recombinant expressed and biochemically characterized. Moreover, effects of C-terminal peptides on catalytic and interfacial binding properties of VhPLD were investigated by constructing two truncated mutants (VhPLD-Δ(472-483) and VhPLD-Δ(437-483)). Optimal reaction temperature and pH value for wild-type VhPLD (VhPLD-WT) was 45 °C and pH 8.0. However, optimal reaction temperature of VhPLD-Δ(437-483) increased to 50 °C. Meanwhile, catalytic efficiency (k_cat/K_M) of VhPLD-Δ(472-483) and VhPLD-Δ(437-483) to the 1,2-Dioctanoyl-sn-glycero-3-phosphatidyl-p-nitrophenol (PpNP) was 12.9 and 14.2 times higher than that of VhPLD-WT. However, when compare the catalytic efficiency between VhPLD-Δ(472-483) and VhPLD-Δ(437-483), no significant change can be found between the two mutants. These results strongly indicated that the C-terminal 12 amino acids (472-483) have important role on the activity of VhPLD. Effects of C-terminal peptides on the interfacial binding properties of VhPLD to different phospholipid monolayers were also investigated by using monolayer film technology. Results of the maximum insertion pressure (MIP) indicated that deletion the C-terminal segment of VhPLD improved its interfacial binding properties to different phospholipid monolayers.

High-yield phosphatidylserine production via yeast surface display of phospholipase D from Streptomyces chromofuscus on Pichia pastoris

The gene encoding phospholipase D (PLD) from Streptomyces chromofuscus was displayed on the cell surface of Pichia pastoris GS115/pKFS-pldh using a Flo1p anchor attachment signal sequence (FS anchor). The displayed PLD (dPLD) showed maximum enzymatic activity at pH 6.0 and 55 °C and was stable within a broad range of temperatures (20-65 °C) and pHs (pH 4.0-11.0). In addition, the thermostability, acid stability and organic solvent tolerance of the dPLD were significantly enhanced compared with the secreted PLD (sPLD) from S. chromofuscus. Use of dPLD for conversion of phosphatidylcholine (PC) and l-serine to phosphatidylserine (PS) showed that 67.5% of PC was converted into PS at the optimum conditions. Moreover, the conversion rate of PS remained above 50% after 7 repeated batch cycles. Thus, P. pastoris GS115/pKFS-pldh shows the potential for viable industrial production of PS.

Recent progress on phospholipases: different sources, assay methods, industrial potential and pathogenicity

Significant studies on phospholipases optimization, characterization, physiological role and industrial potential have been conducted worldwide. Some of them have been directed for biotechnological advances such as gene discovery and functional enhancement by protein engineering. Others reported phospholipases as virulence factor and major cause of pathophysiological effects. A general overview on phospholipase is needed for the identification of new reliable and efficient phospholipase, which would be potentially used in number of industrial and medical applications. Phospholipases catalyse the hydrolysis of one or more ester and phosphodiester bonds of glycerophospholipids. They vary in site of action on phospholipid which can be used industrially for modification/production of new phospholipids. Catalytically active phospholipase mainly use phosphatidylcholine as major substrate, but they can also show specificity with other phospholipids. Several accurate phospholipase assay methods are known, but a rapid and reliable method for high-throughput screening is still a challenge for efficient supply of superior phospholipases and their practical applications. Major application of phospholipase is in industries like oil refinery, health food manufacturing, dairy, cosmetics etc. All types of phospholipases can be involved as virulence factor. They can also be used as diagnostic markers for microbial infection. The importance of phospholipase in virulence is proven and inhibitors of the enzyme can be used as candidate for preventing the associated disease.

Characterization of a thermostable alkaline protease produced by marine Streptomyces fungicidicus MML1614

Totally 191 different marine actinomycetes were isolated from 256 different marine samples collected from the Bay of Bengal and its associated Pulicat lake and Pichavaram mangrove, India. Among them, 157 produced caseinase, 113 produced gelatinase and 108 produced both the protease enzymes. An isolate coded as MML1614 was selected for further study as it exhibited high proteolytic activity. The MML1614 was identified as Streptomyces fungicidicus based on polyphasic taxonomical approach including 16S rRNA sequence analysis. The culture conditions were standardized for the growth and protease production in S. fungicidicus MML1614. The protease was isolated from a 6-day-old culture filtrate of S. fungicidicus MML1614 and partially purified up to 4.5-fold. The protease was optimally active at pH 9 and 40 degrees C and it was stable up to pH 11 and 60 degrees C. PMSF and NaCl inhibited the enzyme activity up to 22 and 11%, respectively. The partially purified protease removed the blood stain more effectively when combined with different detergents than the detergents alone.

Phospholipase D mechanism using Streptomyces PLD

Phospholipase D (PLD) plays various roles in important biological processes and physiological functions, including cell signaling. Streptomyces PLDs show significant sequence similarity and belong to the PLD superfamily containing two catalytic HKD motifs. These PLDs have conserved catalytic regions and are among the smallest PLD enzymes. Therefore, Streptomyces PLDs are thought to be suitable models for studying the reaction mechanism among PLDs from other sources. Furthermore, Streptomyces PLDs present advantages related to their broad substrate specificity and ease of enzyme preparation. Moreover, the tertiary structure of PLD has been elucidated only for PLD from Streptomyces sp. PMF. This article presents a review of recently reported studies of the mechanism of the catalytic reaction, substrate recognition, substrate specificity and stability of Streptomyces PLD using various protein engineering methods and surface plasmon resonance analysis.

A novel low molecular weight phospholipase D from Streptomyces sp. CS684

With the aim of isolating economically viable enzymes from a microbial source, a novel phospholipase D (PLD) was purified from Streptomyces sp. CS684 (PLD(684)). PLD(684) had molecular weight of 29 kDa, which makes it the second smallest PLD reported so far. The enzyme activity was optimum at pH 6 and 45 degrees C, and enhanced by various detergents. It was stable from pH 7 to 9 and at or below 45 degrees C when assayed after 40 h and 2h, respectively. The K(m) and V(max) values for phosphatidylcholine were 1.16 mM and 1453.74 micromol min(-1)mg(-1), respectively. It catalyzed the transphosphatidylation of glycerol, but not that of l-serine, myo-inositol or ethanolamine. Low molecular weight PLD(684) with transphosphatidylation activity may be utilized in the industrial production of rare and commercially important phospholipids.

C-terminal loop of Streptomyces phospholipase D has multiple functional roles

We have recently shown that two flexible loops of Streptomyces phospholipase D (PLD) affect the catalytic reaction of the enzyme by a comparative study of chimeric PLDs. Gly188 and Asp191 of PLD from Streptomyces septatus TH-2 (TH-2PLD) were identified as the key amino acid residues involved in the recognition of phospholipids. In the present study, we further investigated the relationship between a C-terminal loop of TH-2PLD and PLD activities to elucidate the reaction mechanism and the recognition of the substrate. By analyzing chimeras and mutants in terms of hydrolytic and transphosphatidylation activities, Ala426 and Lys438 of TH-2PLD were identified as the residues associated with the activities. We found that Gly188 and Asp191 recognized substrate forms, whereas residues Ala426 and Lys438 enhanced transphosphatidylation and hydrolysis activities regardless of the substrate form. By substituting Ala426 and Lys438 with Phe and His, respectively, the mutant showed not only higher activities but also higher thermostability and tolerance against organic solvents. Furthermore, the mutant also improved the selectivity of the transphosphatidylation activity. The residues Ala426 and Lys438 were located in the C-terminal flexible loop of Streptomyces PLD separate from the highly conserved catalytic HxKxxxxD motifs. We demonstrated that this C-terminal loop, which formed the entrance of the active well, has multiple functional roles in Streptomyces PLD.

Recognition of phospholipids in Streptomyces phospholipase D

To investigate the contribution of amino acid residues to the enzyme reaction of Streptomyces phospholipase D (PLD), we constructed a chimeric gene library between two highly homologous plds, which indicated different activity in transphosphatidylation, using RIBS (repeat-length independent and broad spectrum) in vivo DNA shuffling. By comparing the activities of chimeras, six candidate residues related to transphosphatidylation activity were shown. Based on the above result, we constructed several mutants to identify the key residues involved in the recognition of phospholipids. By kinetic analysis, we identified that Gly188 and Asp191 of PLD from Streptomyces septatus TH-2, which are not present in the highly conserved catalytic HXKXXXXD (HKD) motifs, are key amino acid residues related to the transphosphatidylation activity. To investigate the role of two residues in the recognition of phospholipids, the effects of these residues on binding to substrates were analyzed by surface plasmon spectroscopy. The result suggests that Gly188 and Asp191 are involved in the recognition of phospholipids in correlation with the N-terminal HKD motif. Furthermore, this study also provides experimental evidence that the N-terminal HKD motif contains the catalytic nucleophile, which attacks the phosphatidyl group of the substrate.

Identification of a key amino acid residue of Streptomyces phospholipase D for thermostability by in vivo DNA shuffling

To isolate thermostability-related amino acid residues of Streptomyces phospholipase D (PLD), we constructed a chimeral genes library between two highly homologous plds, which exhibited different thermostabilities, by an in vivo DNA shuffling method using Escherichia coli that has a mutation of a single-stranded DNA-binding protein gene. To confirm the location of the recombination site, we carried out the restriction mapping of 68 chimeral pld genes. The recombination sites were widely dispersed over the entire pld sequence. Moreover, we examined six chimeral PLDs by comparing their thermostabilities with those of parental PLDs. To identify a thermostability-related amino acid residue, we investigated the thermostability of chimera C that was the most thermolabile among the six chimeras. We identified the thermostability-related factor Gly-188, which is located in the alpha-7 helix of PLD from Streptomyces septatus TH-2 (TH-2PLD). TH-2PLD mutants, in which Gly-188 was substituted with Phe, Val or Trp, exhibited higher thermostabilities than that of the parental PLD. Gly-188 substituted with the Phe mutant, which was the most stable among the mutants, showed an enzyme activity almost the same as that of TH-2PLD as determine by kinetic analysis.

Repeat-length-independent broad-spectrum shuffling, a novel method of generating a random chimera library in vivo

We describe a novel method of random chimeragenesis based on highly frequent deletion formation in the Escherichia coli ssb-3 strain and a deletion-directed chimera selection system that uses the rpsL(+) gene as a reporter. It enables the selection of chimeras without target gene expression and can therefore be applied to cytotoxic targets. When this system was applied to phospholipase D genes from Streptomyces septatus TH-2 and Streptomyces halstedii subsp. scabies K6 (examples of cytotoxic targets), chimeragenesis occurred between short identical sequences at the corresponding position of the parental genes with large variations. Chimeragenesis was >1,000 times more frequent in the ssb-3 background than in the ssb(+) background. We called this system repeat-length-independent broad-spectrum shuffling. It enables the convenient chimeragenesis and functional study of chimeric proteins. In fact, we found two amino acid residues related to the thermostability of phospholipase D (Phe426 and Thr433) by comparing thermostability among the chimeric enzymes obtained.

Visualizing complexes of phospholipids with Streptomyces phospholipase D by automated docking

The automated docking program AutoDock was used to dock nine phosphatidic acids (PAs), six phosphatidylcholines, five phosphatidylethanolamines, four phosphatidylglycerols, one phosphatidylinositol and two phosphatidylserines, which have two identical saturated fatty acid residues with an even numbers of carbon atoms, onto the active site of Streptomyces sp. PMF phospholipase D (PLD). Two PAs with one double bond on the fatty acid chain linked to the C2 of the glycerol residue were also docked. In general, binding energies become progressively more negative as fatty acid residues become longer. When these residues are of sufficient length, one is coiled against a hydrophobic cliff in a well that also holds the glycerol and phosphate residues and the head group, while the other generally is bound by a hydrophobic surface outside the well. Phosphatidylcholines have the only head group that is firmly bound by the active site, giving a possible structural explanation for the low selectivity of Streptomyces PLD for other phospholipid substrates.

Asymmetric in vitro synthesis of diastereomeric phosphatidylglycerols from phosphatidylcholine and glycerol by bacterial phospholipase D

Using chiral-phase HPLC, we determined the stereochemical configuration of the phosphatidylglycerols (PtdGro) synthesized in vitro from 1,2-diacyl-sn-glycero-3-phosphocholine (PtdCho, R configuration) or 1,2-diacyl-sn-glycero-3-phosphoethanolamine (PtdEtn, R configuration) and glycerol by transphosphatidylation with bacterial phospholipase D (PLD). The results obtained with PLD preparations from three Streptomyces strains (S. septatus TH-2, S. halstedii K5, and S. halstedii subsp. scabies K6) and one Actinomadura species were compared with those obtained using cabbage and peanut PLD. The reaction was carried out at 30 degrees C in a biphasic system consisting of diethyl ether and acetate buffer. The resulting PtdGro were then converted into bis(3,5-dinitrophenylurethane) derivatives, which were separated on an (R)-1-(1-naphthyl)ethylamine polymer. In contrast to the cabbage and peanut PLD, which gave equimolar mixtures of the R,S and R,R diastereomers, as previously established, the bacterial PLD yielded diastereomixtures of 30-40% 1,2-diacyl-sn-glycero-3-phospho-1'-sn-glycerol (R,S configuration) and 60-70% 1,2-diacyl-sn-glycero-3-phospho-3'-sn-glycerol (R,R configuration). The highest disproportionation was found for the Streptomyces K6 species. The present study demonstrates that bacterial PLD-catalyzed transphosphatidylation proceeds to a considerable extent stereoselectively to produce PtdGro from PtdCho or PtdEtn and prochiral glycerol, indicating a preference for the sn-3' position of the glycerol molecule.

Effect of temperature on the stereoselectivity of phospholipase D toward glycerol in the transphosphatidylation of phosphatidylcholine to phosphatidylglycerol

In this study, the effect of temperature on the stereoselectivity of phospholipase D (PLD) toward the two primary hydroxyl groups of glycerol in the transphosphatidylation reaction of phosphatidylcholine to phosphatidylglycerol (PtdGro) was investigated. For this purpose, PLD from bacteria (Streptomyces septatus TH-2, S. halstedii subsp. scabies K6, and Actinomadura sp.) and cabbage were tested. At the reaction temperatures employed (0-60 degrees C), the proportions of the two PtdGro diastereomers, namely, 1,2-dioleoyl-sn-glycero-3-phospho-3'-sn-glycerol (R,R configuration) and 1 ,2-dioleoyl-sn-glycero-3-phospho-1'-sn-glycerol (R,S configuration), which were produced with PLD from Streptomyces TH-2 and Actinomadura sp., changed gradually from 50% R,R and 50% R,S at 50-60 degrees C to 70% R,R and 30% R,S at 0 degrees C. These alterations suggested that the stereoselectivity of the bacterial PLD toward the two primary hydroxyl groups of prochiral glycerol was significantly influenced by reaction temperature. PLD from Streptomyces K6 showed relatively little effect of temperature on stereoselectivity, giving 65-69% R,R in the temperature range of 60-10 degrees C examined. The plots of In ([R,R]/[R,S]) vs. 1/T gave good linear fits for these three bacterial PLD. No temperature effect was observed for cabbage PLD, which gave an almost equimolar mixture of the R,R and R,S diastereomers in the range from 0 to 40 degrees C. The temperature-dependent change in enantiomeric selectivity of the bacterial PLD promises potentially profitable commercial exploitation.

Gene cloning and overproduction of an aminopeptidase from Streptomyces septatus TH-2, and comparison with a calcium-activated enzyme from Streptomyces griseus

An aminopeptidase secreted from Streptomyces septatus TH-2 (SSAP) was identified as a heat stable enzyme, and the Ssap gene was cloned and sequenced. The primary structure of SSAP showed 71% identity with that of a Streptomyces griseus aminopeptidase (SGAP), however, it lacked a unique calcium binding site. The recombinant SSAP was overexpressed in the culture supernatant of Escherichia coli harboring pET-KmS2. A comparison of recombinant SSAP and SGAP showed that both enzymes are different in terms of modulation by calcium and substrate specificity. The activity of SSAP was not modulated by calcium, while SGAP is a calcium-activated enzyme. SSAP catalyzed the hydrolysis of L-Lys-pNA efficiently whereas the reaction rate for L-Lys-pNA hydrolysis of SGAP was significantly low. Furthermore, in SGAP, the presence of Ca2+ decreased the reaction rate of L-Lys-pNA hydrolysis. SSAP also had different pKas s of reaction from that of SGAP, although almost all the residues which compose the active site were conserved in both enzymes. This result indicates that SSAP has a different environment of substrate binding and active sites from those of SGAP.

A mutant phospholipase D with enhanced thermostability from Streptomyces sp

To investigate the contribution of amino acid residues to the thermostability of phospholipase D (PLD), a chimeric form of two Streptomyces PLDs (thermolabile K1PLD and thermostable TH-2PLD) was constructed. K/T/KPLD, in which residues 329-441 of K1PLD were recombined with the homologous region of TH-2PLD, showed a thermostability midway between those of K1PLD and TH-2PLD. By comparing the primary structures of Streptomyces PLDs, the seven candidates of thermostability-related amino acid residues of K1PLD were identified. The K1E346DPLD mutant, in which Glu346 of K1PLD was substituted with Asp by site-directed mutagenesis, exhibited enhanced thermostability, which was almost the same as that of TH-2PLD.

Using O-(n-alkyl)-N-(N,N'-dimethylethyl)phosphoramidates to investigate the role of Ca2+ and interfacial binding in a bacterial phospholipase D

O-(n-alkyl)-N-(N,N'-dimethylethyl)phosphoramidates (n=6, 8, and 10; CnPNC) were synthesized and characterized as inhibitors of phospholipase D (PLD) activity toward phosphatidylcholine presented as monomers, micelles, and bilayers. Detailed studies with recombinant Streptomyces chromofuscus PLD, a Ca(2+)-activated enzyme that does not show large changes in catalytic activity toward the same substrate as a monomer or micelle, showed that the longer the inhibitor chain length, the more potent CnPNC is as a competitive inhibitor toward all the substrates. However, the physical state of the inhibitor did affect the maximum inhibition attainable. For a fixed concentration of diC4PC (monomer substrate), CnPNC inhibition reached a maximum around the CMC of the inhibitor; the inhibition was reduced at higher inhibitor concentrations, in part caused by the lower solubility of the aggregated inhibitor. With diC4PC as the substrate and using concentrations of C10PNC that were below its CMC, the Ki for C10PNC was 0.030+/-0.003 mM, approximately 13-fold less than the Km for substrate. Aggregated substrates showed significant inhibition of PLD by CnPNC, although as the substrate chain length increased, inhibition by a given CnPNC was diminished. With POPC vesicles, the apparent Ki for C10PNC was 0.030 of the apparent Km. The availability of these inhibitors allowed us to show that PC analogues can bind to the active site of S. chromofuscus PLD in the absence of Ca2+. Once bound at the active site, the inhibitor does not significantly affect the divalent ion-dependent partitioning of the enzyme to PC surfaces. Of the two other PLD enzymes examined, cabbage PLD, but not Streptomyces sp. PMF, was able to catalyze the cleavage of the P-N bond. Differential susceptibility of PLDs to these phosphoramidates may eventually be useful in studying PLD isozymes in cells.

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.