Bacterial lipases.

Many different bacterial species produce lipases which hydrolyze esters of glycerol with preferably long-chain fatty acids. They act at the interface generated by a hydrophobic lipid substrate in a hydrophilic aqueous medium. A characteristic property of lipases is called interfacial activation, meaning a sharp increase in lipase activity observed when the substrate starts to form an emulsion, thereby presenting to the enzyme an interfacial area. As a consequence, the kinetics of a lipase reaction do not follow the classical Michaelis-Menten model. With only a few exceptions, bacterial lipases are able to completely hydrolyze a triacylglycerol substrate although a certain preference for primary ester bonds has been observed. Numerous lipase assay methods are available using coloured or fluorescent substrates which allow spectroscopic and fluorimetric detection of lipase activity. Another important assay is based on titration of fatty acids released from the substrate. Newly developed methods allow to exactly determine lipase activity via controlled surface pressure or by means of a computer-controlled oil drop tensiometer. The synthesis and secretion of lipases by bacteria is influenced by a variety of environmental factors like ions, carbon sources, or presence of non-metabolizable polysaccharides. The secretion pathway is known for Pseudomonas lipases with P. aeruginosa lipase using a two-step mechanism and P. fluorescens lipase using a one-step mechanism. Additionally, some Pseudomonas lipases need specific chaperone-like proteins assisting their correct folding in the periplasm. These lipase-specific foldases (Lif-proteins) which show a high degree of amino acid sequence homology among different Pseudomonas species are coded for by genes located immediately downstream the lipase structural genes. A comparison of different bacterial lipases on the basis of primary structure revealed only very limited sequence homology. However, determination of the three-dimensional structure of the P. glumae lipase indicated that at least some of the bacterial lipases will presumably reveal a conserved folding pattern called the alpha/beta-hydrolase fold, which has been described for other microbial and human lipases. The catalytic site of lipases is buried inside the protein and contains a serine-protease-like catalytic triad consisting of the amino acids serine, histidine, and aspartate (or glutamate). The Ser-residue is located in a strictly conserved beta-epsilon Ser-alpha motif. The active site is covered by a lid-like alpha-helical structure which moves away upon contact of the lipase with its substrate, thereby exposing hydrophobic residues at the protein's surface mediating the contact between protein and substrate.(ABSTRACT TRUNCATED AT 400 WORDS)

The structure-function relationship of the lipases from Pseudomonas aeruginosa and Bacillus subtilis.

Within the BRIDGE T-project on lipases we investigate the structure-function relationships of the lipases from Bacillus subtilis and Pseudomonas aeruginosa. Construction of an overproducing Bacillus strain allowed the purification of > 100 mg lipase from 30 l culture supernatant. After testing a large variety of crystallization conditions, the Bacillus lipase gave crystals of reasonable quality in PEG-4000 (38-45%), Na2SO4 and octyl-beta-glucoside at 22 degrees C, pH 9.0. A 2.5 A dataset has been obtained which is complete from 15 to 2.5 A resolution. P.aeruginosa wild-type strain PAC1R was fermented using conditions of maximum lipase production. More than 90% of the lipase was cell bound and could be solubilized by treatment of the cells with Triton X-100. This permitted the purification of approximately 50 mg lipase. So far, no crystals of sufficient quality were obtained. Comparison of the model we built for the Pseudomonas lipase, on the basis of sequences and structures of various hydrolases which were found to possess a common folding pattern (alpha/beta hydrolase fold), with the X-ray structure of the P.glumae lipase revealed that it is possible to correctly build the structure of the core of a protein even in the absence of obvious sequence homology with a protein of known 3-D structure.

Crystal structure of the high-alkaline serine protease PB92 from Bacillus alcalophilus.

The crystal structure of a serine protease from the alkalophilic strain Bacillus alcalophilus PB92 has been determined by X-ray diffraction at 1.75 A resolution. The structure has been solved by molecular replacement using the atomic model of subtilisin Carlsberg. The model of the PB92 protease has been refined to an R-factor of 14.0% and contains 1882 protein atoms, two calcium ions and 188 water molecules. The overall folding of the polypeptide chain closely resembles that of the subtilisins. Furthermore, almost all of the secondary structure elements found in subtilisin Carlsberg are also present in the PB92 protease. The major differences between the two structures are located around the deletion regions (residues 37 and 158-161 in subtilisin Carlsberg) and in two loops which are known to be the most variable parts of subtilisin structures. Flexibility of one of these loops (residues 126-130 in the PB92 protease) is believed to account for the induced-fit mechanism of substrate binding.

Protein engineering of the high-alkaline serine protease PB92 from Bacillus alcalophilus: functional and structural consequences of mutation at the S4 substrate binding pocket.

Serine endoproteases such as trypsins and subtilisins are known to have an extended substrate binding region that interacts with residues P6 to P3' of a substrate. In order to investigate the structural and functional effects of replacing residues at the S4 substrate binding pocket, the serine protease from the alkalophilic Bacillus strain PB92, which shows homology with the subtilisins, was mutated at positions 102 and 126-128. Substitution of Val102 by Trp results in a 12-fold increase in activity towards succinyl-L-Ala-L-Ala-L-Pro-L-Phe-p-nitroanilide (sAAPFpNA). An X-ray structure analysis of the V102W mutant shows that the Trp side chain occupies a hydrophobic pocket at the surface of the molecule leaving a narrow crevice for the P4 residue of a substrate. Better binding of sAAPFpNA by the mutant compared with the wild type protein as indicated by the kinetic data might be due to the hydrophobic interaction of Ala P4 of the substrate with the introduced Trp102 side chain. The observed difference in binding of sAAPFpNA by protease PB92 and thermitase, both of which possess a Trp at position 102, is probably related to the amino acid substitutions at positions 105 and 126 (in the protease PB92 numbering). Kinetic data for the variants obtained by random mutation of residues Ser126, Pro127 and Ser128 reveal that the activity towards sAAPFpNA increases when a hydrophobic residue is introduced at position 126.(ABSTRACT TRUNCATED AT 250 WORDS)

The phosphoglycerate kinases from Trypanosoma brucei. A comparison of the glycosomal and the cytosolic isoenzymes and their sensitivity towards suramin.

Trypanosoma brucei has two phosphoglycerate kinase (PGK) isoenzymes, one is particle-bound and localized in glycosomes while the other is present in the cytosol. The cytosolic isoenzyme (cPGK) was 900-fold purified from cultured procyclic trypanosomes by hydrophobic interaction chromatography on phenyl-Sepharose followed by affinity chromatography on 2',3'-ATP-Sepharose and had a specific activity of 275 units/mg protein. cPGK was compared with the purified glycosomal isoenzyme (gPGK) from bloodstream-form trypanosomes as well as with the commercially available PGKs from yeast, rabbit muscle and Spirulina platensis, a blue-green alga. Like all other PGKs, cPGK was a monomeric protein with a molecular mass of approximately 45 kDa similar to that of the PGKs from other organisms but 2 kDa smaller than that of gPGK. Despite this difference in length and a great difference in isoelectric point, the two trypanosome isoenzymes strongly resembled each other in several respects. The kinetic parameters did not differ significantly from each other or from the PGKs of other organisms. Both trypanosome enzymes resembled the enzyme from S. platensis in that they had an almost absolute requirement for ATP, contrary to the enzymes from yeast and rabbit muscle, which were capable of utilizing GTP and ITP also. This difference in substrate specificity may be related to the amino acid substitutions, Trp 308----His and Ala 306----Glu in the adenine-binding site, which are only found in the two Trypanosoma isoenzymes. Kinetic analysis showed that these substitutions do not prevent binding of the ATP analogues, but probably prevent phosphoryl-group transfer. Both isoenzymes displayed an activity optimum at pH 6.0-9.0 similar to that for the enzyme of yeast. Both gPGK and cPGK were inhibited by the trypanocidal drug Suramin. This inhibition could be described as competitive both with ATP and 3-phosphoglycerate with two inhibitor molecules binding to one molecule of enzyme. The gPGK, however, was much more sensitive (Ki app. = 8.0 microM) to Suramin than either the cPGK (Ki app. = 20 microM) or the enzymes from rabbit muscle (Ki app. = 55 microM), yeast (Ki app. = 167 microM) or S. platensis (Ki app. = 250 microM). It is suggested that positive charges on the enzyme's surface may play an important role in the potentiation of the binding of the negatively charged Suramin molecule.

Glyceraldehyde-phosphate dehydrogenase from Trypanosoma brucei. Comparison of the glycosomal and cytosolic isoenzymes.

Trypanosoma brucei contains two glyceraldehyde-phosphate (GAPDH; EC 1.2.1.12) isoenzymes; one is located in glycosomes and represents 80% of the total activity, whereas the other is present in the cytosol. The purification of the cytosolic GAPDH, which is identical in both bloodstream-form and insect-stage trypanosomes, is described, and the enzyme compared with its glycosomal counterpart. Cytosolic GAPDH is specific for NAD. It is a tetrameric enzyme with subunits of 33.5 kDa, 5 kDa smaller than those of the glycosomal GAPDH. The native enzyme has a pI of 7.9, which is 1.5 pH units less basic than the glycosomal enzyme. Both enzymes display maximal activity at pH 8 but the cytosolic enzyme has a much broader activity profile especially towards lower pH values. Sequence comparison of the first 85 amino acids reveals that the N-terminal parts of both isoenzymes differ by 52%. The N terminus of the cytosolic isoenzyme resembles the corresponding N termini of ten other known GAPDH sequences in that they all lack three amino-acid insertions, which so far only have been found in the glycosomal isoenzyme of T. brucei. This observation explains in part the great difference in subunit size between the two T. brucei isoenzymes and suggests that at least one of these insertions is responsible for import of the glycosomal isoenzyme into the organelle.

Common elements on the surface of glycolytic enzymes from Trypanosoma brucei may serve as topogenic signals for import into glycosomes.

In Trypanosoma brucei, a major pathogenic protozoan parasite of Central Africa, a number of glycolytic enzymes present in the cytosol of other organisms are uniquely segregated in a microbody-like organelle, the glycosome, which they are believed to reach post-translationally after being synthesized by free ribosomes in the cytosol. In a search for possible topogenic signals responsible for import into glycosomes we have compared the amino acid sequences of four glycosomal enzymes: triosephosphate isomerase (TIM), glyceraldehyde-phosphate dehydrogenase (GAPDH), phosphoglycerate kinase (PGK) and aldolase (ALDO), with each other and with their cytosolic counterparts. Each of these enzymes contains a marked excess of positive charges, distributed in two or more clusters along the polypeptide chain. Modelling of the three-dimensional structures of TIM, PGK and GAPDH using the known structural coordinates of homologous enzymes from other organisms indicates that all three may have in common two 'hot spots' about 40 A apart, which themselves include a pair of basic amino acid residues separated by a distance of about 7 A. The sequence of glycosomal ALDO, for which no three-dimensional information is available, is compatible with the presence of the same configuration on the surface of this enzyme. We propose that this feature plays an essential role in the import of enzymes into glycosomes.

Glycolytic enzymes of Trypanosoma brucei. Simultaneous purification, intraglycosomal concentrations and physical properties.

We have developed a method for the simultaneous purification of hexokinase, glucosephosphate isomerase, phosphofructokinase, fructose-1,6-bisphosphate aldolase, triosephosphate isomerase, D-glyceraldehyde-phosphate dehydrogenase, phosphoglycerate kinase, glycerol-3-phosphate dehydrogenase and glycerol kinase from Trypanosoma brucei in yields varying over 8-55%. Crude glycosomes were prepared by differential centrifugation of cell homogenates. Subsequent hydrophobic interaction chromatography on phenyl-Sepharose resulted in six pools containing various mixtures of enzymes. These pools were processed via affinity chromatography (immobilized ATP), hydrophobic interaction chromatography (octyl-Sepharose) and ion-exchange chromatography (CM- and DEAE-cellulose) which resulted in the purification of all nine enzymes. The native enzyme and subunit molecular masses, as determined by gel filtration and gel electrophoresis under denaturing conditions, were compared with those of their homologous counterparts from other organisms. Trypanosomal hexokinase is a hexamer and differs in subunit composition from the mammalian enzymes (monomers) as well as in subunit size (51 kDa versus 96-100 kDa, respectively). Phosphofructokinase only differs in subunit size (51 kDa for T. brucei versus 80-90 kDa for mammals) but had identical subunit composition (tetrameric). The others all have the same subunit composition as their mammalian counterparts. Except for triosephosphate isomerase, all Trypanosoma enzymes have subunits which are 1-5 kDa larger in size. Together these nine enzymes contribute 3.3 +/- 1.6% to the total cellular protein of T. brucei and at least 90% to the total glycosomal protein. A comparison of calculated intraglycosomal concentrations of the enzymes with the glycosomal metabolite concentrations shows that in the case of aldolase, glyceraldehyde-phosphate dehydrogenase and phosphoglycerate kinase, the concentration of active sites is of the same order of magnitude as that of their reactants. A common feature of the glycosomal glycolytic enzymes (with the exception of glucosephosphate isomerase) is that they are highly basic proteins with pI values between 8.8 and 10.2, values which are 1-4 higher than in the case of their mammalian cytosolic counterparts and 3-6 higher than in the case of the various unicellular organisms. It is suggested that both the larger subunit size and the basic character of the T. brucei glycolytic proteins are involved in the routing of the enzymes from their site of biogenesis (the cytosol) towards their site of action (the glycosome).

Two tandemly linked identical genes code for the glycosomal glyceraldehyde-phosphate dehydrogenase in Trypanosoma brucei.

Trypanosoma brucei contains two isoenzymes for glyceraldehyde-phosphate dehydrogenase (GAPDH); one enzyme resides in a microbody-like organelle, the glycosome, the other one is found in the cytosol. We show here that the glycosomal enzyme is encoded by two tandemly linked genes of identical sequence. These genes code for a protein of 358 amino acids, with a mol. wt of 38.9 kd. This is considerably larger than all other GAPDH proteins studied so far, including the enzyme that is located in the cytosol of the trypanosome. The glycosomal enzyme shows 52-57% homology with known sequences of GAPDH proteins from 10 other organisms, both prokaryotes and eukaryotes. The residues that are involved in NAD+ binding, catalysis and subunit contacts are well conserved between all these GAPDH molecules, including the trypanosomal one. However, the glycosomal protein of T. brucei has some distinct features. Firstly, it contains a number of insertions, 1-8 amino acids long, which are responsible for the high mol. wt of the protein. Secondly, an unusually high number of positively charged amino acids confer a high isoelectric point (pI 9.3) to the protein. Part of the additional basic residues are present in the insertions. We discuss the genomic organization of the genes for the glycosomal GAPDH and the possibility that the particular features of the protein are involved in its transfer from the cytoplasm, where it is synthesized, into the glycosome.

Simultaneous purification of hexokinase, class-I fructose-bisphosphate aldolase, triosephosphate isomerase and phosphoglycerate kinase from Trypanosoma brucei.

A method is presented for the simultaneous purification of hexokinase, fructose-bisphosphate aldolase, triosephosphate isomerase and phosphoglycerate kinase, and the partial purification of glycerol-3-phosphate dehydrogenase (NAD+), 6-phosphofructokinase, glucosephosphate isomerase, and glycerol kinase from Trypanosoma brucei. As a first step, the glycosomes, microbody-like organelles of Trypanosomatidae, containing almost exclusively enzymes involved in glucose and glycerol metabolism [Opperdoes, F. R. and Borst, P. (1977) FEBS Lett. 80, 360-364], were purified eightfold from homogenates with an average yield of 38%. Subsequently, the glycosomal content was subjected to hydrophobic interaction chromatography on phenyl-Sepharose. This step results in pure hexokinase (15% final yield) and almost pure triosephosphate isomerase, while the other glycosomal enzymes elute as mixtures of two or three enzymes. Triosephosphate isomerase was further purified to homogeneity on CM-cellulose (33% final yield), while phosphoglycerate kinase and fructose-bisphosphate aldolase were separated from each other and purified to homogeneity by affinity chromatography using ATP-Sepharose (25% and 30% final yields, respectively). Fructose-bisphosphate aldolase was further characterized as a typical class I enzyme.

Preliminary crystallographic studies of triosephosphate isomerase from the blood parasite Trypanosoma brucei brucei.

Crystals of triosephosphate isomerase (EC 5.3.1.1) from Trypanosoma brucei brucei have been grown. These crystals diffract to at least 2 A, even after 60 hours of exposure to X-rays. The space group is P212121, with cell dimensions a = 112.4 A, b = 97.8 A, c = 48.0 A. There is one dimer per asymmetric unit.

A comparison of the glycosomes (microbodies) isolated from Trypanosoma brucei bloodstream form and cultured procyclic trypomastigotes.

Highly purified glycosomes were isolated from Trypanosoma brucei bloodstream forms and cultured procyclic trypomastigotes. A comparison of the specific activities of glycosomal enzymes revealed that glycosomes from insect stages had decreased levels of hexokinase, phosphoglucose isomerase, phospho-fructokinase, fructose-bisphosphate aldolase, glyceraldehyde-phosphate dehydrogenase and phosphoglycerate kinase, but contained increased levels of adenylate kinase, malate dehydrogenase and phosphoenolpyruvate carboxykinase. Glycosomes from bloodstream forms were almost totally devoid of the latter two activities. Comparison of the two types of glycosomes by sodium dodecylsulphate-polyacrylamide gel electrophoresis revealed that bloodstream form glycosomes contained 3 prominent polypeptides (64, 46 and 40 kDa) which were hardly detectable in insect stage glycosomes, whereas the latter contained 3 insect stage specific bands with molecular weight of 34 000, 61 000 and 77 000 and 4 additional bands with molecular weights between 94 000 and 110 000. Both types of glycosome contained the phospholipids phosphatidylcholine and phosphatidylethanolamine. Insect stage glycosomes contained in addition also phosphatidylinositol and some phosphatidylserine.

Purification, morphometric analysis, and characterization of the glycosomes (microbodies) of the protozoan hemoflagellate Trypanosoma brucei.

Trypanosoma brucei glycosomes (microbodies containing nine enzymes involved in glycolysis) have been purified to near homogeneity from bloodstream-form trypomastigotes for the purpose of morphologic and biochemical analysis. Differential centrifugation followed by two isopycnic centrifugations in an isotonic Percoll and in a sucrose gradient, respectively, resulted in 12- to 13-fold purified glycosomes with an overall yield of 31%. These glycosomes appeared to be highly pure and contained less than 1% mitochondrial contamination as judged by morphometric and biochemical analyses. In intact cells, glycosomes displayed a remarkably homogeneous size distribution centered on an average diameter of 0.27 micron with a standard deviation of 0.03 micron. The size distribution of isolated glycosomes differed only slightly from that measured in intact cells. One T. brucei cell contained on average 230 glycosomes, representing 4.3% of the total cell volume. The glycosomes were surrounded by a single membrane and contained as phospholipids only phosphatidyl choline and phosphatidyl ethanolamine in a ratio of 2:1. The purified glycosomal fraction had a very low DNA content of 0.18 microgram/mg protein. No DNA molecules were observed that could not have been derived from contaminating mitochondrial or nuclear debris.

Bacterial phosphoenolpyruvate-dependent phosphotransferase system. Mechanism of the transmembrane sugar translocation and phosphorylation.

The phosphoryl-group transfer from PHPr to glucose or alpha-methylglucose and from glucose 6-phosphate to these same sugars catalyzed by membrane-bound EIIBGlc of the bacterial phosphoenolpyruvate-dependent phosphotransferase system has been studied in vitro. Kinetic measurements revealed that both the phosphorylation reaction and the exchange reaction proceed according to a ping-pong mechanism in which a phosphorylated membrane-bound enzyme II acts as an obligatory intermediate. The occurrence of a phospho-IIBGlc/IIIGlc has been physically demonstrated by the production of a glucose 6-phosphate burst from membranes phosphorylated by phosphoenolpyruvate, HPr, and EI. The observation of similar second-order rate constants for the production of sugar phosphate starting with different phosphoryl-group donors confirms the catalytic relevance of the phosphoenzyme IIBGlc intermediate. The in vitro results, together with data published by other investigators, have led to a model describing sugar phosphorylation and transport in vivo.

Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system: mechanism of phosphoryl-group transfer from phosphoenolpyruvate to HPr.

The mechanism of phosphoryl-group transfer from phosphoenolpyruvate (PEP) to HPr, catalyzed by enzyme I of the Escherichia coli PEP-dependent phosphotransferase system, has been studied in vitro. Steady-state kinetics and isotope exchange measurements revealed that this reaction cannot be described by a classical ping-pong mechanism although phosphoenzyme I acts as an intermediate. The kinetic data indicate that HPr and PHPr occupy binding sites on enzyme I that do not overlap with the binding sites for PEP and pyruvate. As a result, binding interactions between HPr and enzyme I exist regardless of their phosphorylated state. A general mechanism is presented that describes the phosphorylation of HPr. The physiological implications of this mechanism are discussed.

Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system. Evidence that the dimer is the active form of enzyme I.

In vitro kinetic measurements have been performed by using purified HPr, EI, and a membrane fraction of EII from the Escherichia coli phosphoenolypyruvate-dependent sugar transport system. These measurements reveal very large lag times in the formation of methyl alpha-glucoside phosphate which are a function of the EI and the EII concentrations. The lag times decrease with increasing concentrations of EI but they increase with increasing concentrations of EII. When EI, together with Mg2+ and phosphoenolpyruvate, is preincubated at 37 degrees C before starting the kinetic measurements, the lag time can be decreased or eliminated. We have shown that the process responsible for the lag time is the activation of EI by dimerization which is influenced by Mg2+ and phosphoenolpyruvate.