Functional topology of a surface loop shielding the catalytic center in lipoprotein lipase.

Lipoprotein lipase (LPL), hepatic lipase, and pancreatic lipase show high sequence homology to one another. The crystal structure of pancreatic lipase suggests that it contains a trypsin-like Asp-His-Ser catalytic triad at the active center, which is shielded by a disulfide bridge-bounded surface loop that must be repositioned before the substrate can gain access to the catalytic residues. By sequence alignment, the homologous catalytic triad in LPL corresponds to Asp156-His241-Ser132, absolutely conserved residues, and the homologous surface loop to residues 217-238, a poorly conserved region. To verify these assignments, we expressed in vitro wild-type LPL and mutant LPLs having single amino acid mutations involving residue Asp156 (to His, Ser, Asn, Ala, Glu, or Gly), His241 (to Asn, Ala, Arg, Gln, or Trp), or Ser132 (to Gly, Ala, Thu, or Asp) individually. All 15 mutant LPLs were totally devoid of enzyme activity, while wild-type LPL and other mutant LPLs containing substitutions in other positions were fully active. We further replaced the 22-residue LPL loop which shields the catalytic center either partially (replacing 6 of 22 residues) or completely with the corresponding hepatic lipase loop. The partial loop-replacement chimeric LPL was found to be fully active, and the complete loop-replacement mutant had approximately 60% activity, although the primary sequence of the hepatic lipase loop is quite different. In contrast, replacement with the pancreatic lipase loop completely inactivated the enzyme. Our results are consistent with Asp156-His241-Ser132 being the catalytic triad in lipoprotein lipase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sequence of horse pancreatic lipase as determined by protein and cDNA sequencing. Implications for p-nitrophenyl acetate hydrolysis by pancreatic lipases.

The complete sequence of the horse pancreatic lipase was elucidated by combining polypeptide chain and cDNA sequencing. Among the structural features of horse lipase, it is worth mentioning that Lys373 is not conserved. This residue, which is present in human, porcine and canine lipases, has been assumed to be involved in p-nitrophenyl acetate hydrolysis by pancreatic lipases. Kinetic investigation of the p-nitrophenyl acetate hydrolysis by the various pancreatic lipases and by the C-terminal domain (336-449) of human lipase reveals that this hydrolysis is the result of the superimposition of independent events; a specific linear hydrolysis occurring at the active site of lipase, a fast acylation depending on the presence of Lys373 and a non-specific hydrolysis most likely occurring in the C-terminal domain of the enzyme. This finding definitely proves that pancreatic lipase bears only one active site and raises the question of a covalent catalysis by pancreatic lipases. Moreover, based on sequence comparison with the above-mentioned pancreatic lipases, three residues located in the C-terminal domain, Lys349, Lys398 and Lys419, are proposed as possible candidates for lipase/colipase binding.     

Structure and evolution of the lipase superfamily.

The lipase superfamily includes three vertebrate and three invertebrate (dipteran) proteins that show significant amino acid sequence similarity to one another. The vertebrate proteins are lipoprotein lipase (LPL), hepatic lipase (HL), and pancreatic lipase (PL). The dipteran proteins are Drosophila yolk proteins 1, 2, and 3. We review the relationships among these proteins that have been established according to gene structural relatedness and introduce our findings on the phylogenetic relationships, distance relationships, and evolutionary history of the lipase gene superfamily. Drosophila yolk proteins contain a 104 amino acid residue segment that is conserved with respect to the lipases. We have used the yolk proteins as an outgroup to root a phylogeny of the lipase family. Our phylogenetic reconstruction suggests that ancestral PL diverged earlier than HL and LPL, which share a more recent root. Human and bovine LPL are shown to be more closely related to murine LPL than to guinea pig LPL. A comparison of the distance (a measure of the number of substitutions between sequences) between mammalian and avian LPL reveals that guinea pig LPL has the largest distance from the other mammals. Human, rodent, and rabbit HL show marked divergence from one another, although they have similar relative rates of amino acid substitution when compared to human LPL as an outgroup. Human and porcine PL are not as divergent as human and rat HL, suggesting that PL is more conserved than HL. However, canine PL demonstrates an unusually rapid rate of substitution with respect to the other pancreatic lipases. The lipases share several structurally conserved features. One highly conserved sequence (Gly-Xaa-Ser-Xaa-Gly) contains the active site serine. This feature, which agrees with that found in serine esterases and proteases, is found within the entire spectrum of lipases, including the evolutionarily unrelated prokaryotic lipases. We review the location and possible activity of putative lipid binding domains. We have constructed a conservation index (CI) to display conserved structural features within the lipase gene family, a CI of 1.0 signifying perfect conservation. We have found a correlation between a high CI and the position of conserved functional structures. The putative lipid-binding domains of LPL and HL, the disulfide-bridging cysteine residues, catalytic residues, and N-linked glycosylation sites of LPL, HL, and PL all lie within regions having a CI of 0.8 or higher. A number of amino acid substitutions have been identified in familial hyperchylomicronemia which result in loss of LPL function.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structural and functional roles of highly conserved serines in human lipoprotein lipase. Evidence that serine 132 is essential for enzyme catalysis

The structure of human lipoprotein lipase was recently deduced from its cDNA sequence. It contains 8 serine residues (residues 45, 132, 143, 172, 193, 244, 251, and 363) that are absolutely conserved in both lipoprotein lipase and hepatic lipase across all species studied. The high homology between lipoprotein lipase, hepatic lipase, and pancreatic lipase suggests that the catalytic functions of these enzymes share a common mechanism and that one of the 8 conserved serines in human lipoprotein lipase must play a catalytic role as does serine 152 in the case of pancreatic lipase (Winkler, F. K., D'Arcy, A., and Hunziker, W. Nature 343, 771-774). We expressed wild-type and site-specific mutants of human lipoprotein lipase in COS cells in vitro. We produced two to four substitution mutants involving each of the 8 serines and assayed a total of 22 mutants for both enzyme activity and the amount of immunoreactive enzyme mass produced. Immunoreactive lipase was detected in all cases. With the exception of Ser132, for each of the 8 serine mutants we studied, at least one of several mutants at each position showed detectable enzyme activity. All three substitution mutants at Ser132, Ser----Thr, Ser----Ala, and Ser----Asp, were totally inactive. Ser132 occurs in the consensus sequence Gly-Xaa-Ser-Xaa-Gly present in all serine proteinases and in human pancreatic lipase. The x-ray crystallography structure of human pancreatic lipase suggests that the analogous serine residue in human pancreatic lipase, Ser152, is the nucleophilic residue essential for catalysis. Our biochemical data strongly support the conclusion that Ser132 in human lipoprotein lipase is the crucial residue required for enzyme catalysis. The observed specific activities of the variants involving the other seven highly conserved serines in human lipoprotein lipase are consistent with the interpretation that this enzyme has a three-dimensional structure very similar to that of human pancreatic lipase.     

Human hepatic lipase. Cloned cDNA sequence, restriction fragment length polymorphisms, chromosomal localization, and evolutionary relationships with lipoprotein lipase and pancreatic lipase

Human hepatic lipase is an important enzyme in high density lipoprotein (HDL) metabolism, being implicated in the conversion of HDL2 to HDL3. Three human hepatic lipase cDNA clones were identified in two lambda gt11 libraries from human liver. The cDNA-derived amino acid sequence predicts a protein of 476 amino acid residues, preceded by a 23-residue signal peptide. Four potential N-glycosylation sites are identified, two of which are conserved in rat hepatic lipase. On alignment with human, mouse, and bovine lipoprotein lipase, the same two sites were also conserved in lipoprotein lipase in all three species. Stringent conservation of the cysteine residues was also evident. Comparative analysis of amino acid sequences shows that hepatic lipase evolves at a rapid rate, 2.07 x 10(-9) substitutions/site/year, about four times that in lipoprotein lipase and half that in pancreatic lipase. Further, hepatic lipase and pancreatic lipase appear to be evolutionarily closer to each other than either of them is to lipoprotein lipase. Southern blot analysis revealed high frequency restriction fragment length polymorphisms of the hepatic lipase gene for the enzymes HindIII and MspI. these polymorphisms will be useful for haplotype and linkage analysis of the hepatic lipase gene. Using cloned human hepatic lipase cDNA as a hybridization probe, we performed Southern blot analysis of a panel of 13 human-rodent somatic cell hybrids. Concordance analysis of the various hybrid clones indicates that the hepatic lipase gene is located on the long arm of human chromosome 15. Analysis of hybrids containing different translocations of chromosome 15 localized the gene to the region 15q15----q22.     

Digestive lipases: from three-dimensional structure to physiology

Human gastric lipase (HGL) is a lipolytic enzyme that is secreted by the chief cells located in the fundic part of the stomach. HGL plays an important role in lipid digestion, since it promotes the subsequent hydrolytic action of pancreatic lipase in duodenal lumen. Physiological studies have shown that HGL is able of acting not only in the highly acid stomach environment but also in the duodenum in synergy with human pancreatic lipase (HPL). Recombinant HGL (r-HGL) was expressed in the baculovirus/insect cell system in the form of an active protein with a molecular mass of 45 kDa. The specific activities of r-HGL were found to be similar to that of the native enzyme when tested on various triacylglycerol (TG) substrates. The 3-D structure of r-HGL was the first solved within the mammalian acid lipase family. This globular enzyme (379 residues) shows a new feature, different from the other known lipases structures, which consists of a core domain having the alpha/beta hydrolase fold and a cap domain including a putative 'lid' of 30 residues covering the active site of the lipase (closed conformation). HPL is the major lipolytic enzyme involved in the digestion of dietary TG. HPL is a 50 kDa glycoprotein which is directly secreted as an active enzyme. HPL was the first mammalian lipase to be solved structurally, and it revealed the presence of two structural domains: a large N-terminal domain (residues 1-336) and a smaller C-terminal domain (residues 337-449). The large N-terminal domain belongs to the alpha/beta hydrolase fold and contains the active site. A surface loop called the lid domain (C237-C261) covers the active site in the closed conformation of the lipase. The 3-D structure of the lipase-procolipase complex illustrates how the procolipase might anchor the lipase at the interface in the presence of bile salts: procolipase binds to the C-terminal domain of HPL and exposes the hydrophobic tips of its fingers at the opposite site of its lipase-binding domain. These hydrophobic tips help to bring N-terminal domain into close conformation with the interface where the opening of the lid domain probably occurs. As a result of all these conformational changes, the open lid and the extremities of the procolipase form an impressive continuous hydrophobic plateau, extending over more than 50 A. This surface might able to interact strongly with a lipid-water interface. The biochemical, histochemical and clinical studies as well as the 3-D structures obtained will be a great help for a better understanding of the structure-function relationships of digestive lipases.     

Effect of mutations of N- and C-terminal charged residues on the activity of LCAT

On the basis of structural homology calculations, we previously showed that lecithin:cholesterol acyltransferase (LCAT), like lipases, belongs to the alpha/beta hydrolase fold family. As there is higher sequence conservation in the N-terminal region of LCAT, we investigated the contribution of the N- and C-terminal conserved basic residues to the catalytic activity of this enzyme. Most basic, and some acidic residues, conserved among LCAT proteins from different species, were mutated in the N-terminal (residues 1;-210) and C-terminal (residues 211;-416) regions of LCAT. Measurements of LCAT-specific activity on a monomeric substrate, on low density lipoprotein (LDL), and on reconstituted high density lipoprotein (rHDL) showed that mutations of N-terminal conserved basic residues affect LCAT activity more than those in the C-terminal region. This agrees with the highest conservation of the alpha/beta hydrolase fold and structural homology with pancreatic lipase observed for the N-terminal region, and with the location of most of the natural mutants reported for human LCAT. The structural homology between LCAT and pancreatic lipase further suggests that residues R80, R147, and D145 of LCAT might correspond to residues R37, K107, and D105 of pancreatic lipase, which form the salt bridges D105-K107 and D105-R37. Natural and engineered mutations at residues R80, D145, and R147 of LCAT are accompanied by a substantial decrease or loss of activity, suggesting that salt bridges between these residues might contribute to the structural stability of the enzyme.     

Lipoprotein lipases from cow, guinea-pig and man. Structural characterization and identification of protease-sensitive internal regions

Lipoprotein lipases from human, bovine or guinea-pig milk were purified, judged for domain relationships by characterization of sites sensitive to proteases, and structurally compared. The subunit of human lipoprotein lipase migrated slightly slower than those of bovine or guinea-pig lipoprotein lipases on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Bovine lipoprotein lipase is known to be a dimer of two non-covalently linked subunits of equal size, and the lipases from all three sources now yielded homogeneous N-terminal amino acid sequences (followed for 15-27 residues). The results indicate that the two subunits are identical. Bovine lipoprotein lipase had two additional N-terminal residues, Asp-Arg, compared to the human and guinea-pig enzymes, and the next two positions revealed residue differences, but further on homologies were extensive between all three enzymes as far as presently traced. Exposure of bovine lipoprotein lipase to trypsin led to production of three fragments (T1, T2a, and T2b), suggesting cleavage at exposed segments delineating domain borders. Time studies gave no evidence for precursor-product relationships between the fragments, and prolonged digestion did not lead to further cleavage. Fragments T2a and T2b had the same N-terminal sequence as intact lipase. Fragment T1 revealed a new sequence, and represents the C-terminal half of the molecule. Plasmin caused a similar cleavage as trypsin, whereas thrombin, factor Xa, and tissue plasminogen activator did not cleave the enzyme. Chymotrypsin cleaved off a relatively small fragment from the C-terminal of the molecule, after which exposure to trypsin still resulted in cleavage at the same sites as in intact lipase. Tryptic cleavage of guinea-pig lipoprotein lipase yielded two fragments. One had a similar size as bovine fragment T2b; the other had a similar size as bovine fragment T1 and an N-terminal sequence homologous with that of T1. Thus, trypsin recognizes the same unique site in guinea-pig lipoprotein lipase as in the bovine enzyme. This confirms the conclusion that this segment is the border between two domains in the subunit. The binding site for heparin was retained after both tryptic and chymotryptic cleavages and was identified as localized in the C-terminal part of the molecule.     

Why is there sequence similarity between insect yolk proteins and vertebrate lipases?

The major proteins stored in the yolk of developing oocytes are thought to provide a nutritional store for utilization during embryogenesis. They seem to fall into two major families of proteins. The first are called vitellogenins and are found in frog, chicken, nematode, fish, and some insects such as the boll weevil. The other group are called yolk proteins and are found in dipteran insects such as fruitfly, housefly, fleshfly, and blue-bottles. Both groups are the major proteins found in the oocyte and are female-specific proteins endocytosed from the serum or hemolymph. The yolk protein group were found to have sequence similarity to the triacylglycerol lipases and lipoprotein lipases of vertebrates, including rat, pig, and human. The yolk proteins do not have lipase activity, but the sequences conserved between yolk proteins and lipases surround the active site where there are interactions with lipids. The likely reason for the presence of this domain in the yolk proteins is to bind a steroid hormone in a storage form conjugated to lipids. This permits the storage of the hormone in an inactive form until the yolk proteins are degraded, when it can be released from its conjugate to induce developmental decisions in embryogenesis. They may also transport lipids into the oocyte for use in embryogenesis. Whilst the vitellogenin family of proteins do not share this homology with the lipases they do have similarity to the human serum protein, apolipoprotein B, which also has a role in binding lipids. These findings are discussed in relation to the evolution and functions of lipases, apolipoproteins, vitellogenins, and yolk proteins. Experiments aimed at isolating genes encoding lipases in insects and at further elucidating the function of the yolk proteins are suggested.     

Human lipoprotein lipase: the loop covering the catalytic site is essential for interaction with lipid substrates.

Lipoprotein lipase (LPL), a key enzyme which initiates the hydrolysis of triglycerides present in chylomicrons and very low density lipoproteins, consists of multiple functional domains which are necessary for normal activity. The catalytic domain of LPL mediates the esterase function of the enzyme but separate lipid binding sites have been proposed to be involved in the interaction of LPL with emulsified lipid substrates at the water-lipid interface. Like pancreatic lipase (PL), LPL contains a surface loop covering the catalytic pocket that may modulate access of the substrate to the active site of the enzyme. Secondary structural analysis of this loop reveals a helix-turn-helix motif with two short amphipathic helices that have hydrophobic moments of 0.64 and 0.68. In order to investigate the role of the loop in the initial interaction of LPL with its substrate, we utilized site-directed mutagenesis to generate eight constructs in which the amphipathic properties of the loop were altered and expressed them in human embryonal kidney-293 cells. Reducing the amphiphilicity without changing the predicted secondary structure of the loop abolished the ability of the lipase to hydrolyze emulsified, long chain fatty acid triglycerides (triolein) but not the water soluble substrate tributyrin. Replacing the loop of LPL with the loop of hepatic lipase, which differs in 15 of 22 amino acids but is also amphiphilic, led to the expression of an enzyme that retained both triolein and tributyrin hydrolyzing activity. Substitution of the LPL loop by a short four amino acid peptide, which may allow more direct access to the active site than the 22 amino acid loop, enhanced hydrolysis of short chain fatty acid triglycerides by more than 2-fold, while the ability to hydrolyze emulsified substrates was abolished. Thus, disruption of the amphipathic structure of the LPL loop selectively decreases the hydrolysis of emulsified lipid substrate without affecting the esterase or catalytic function of the enzyme. These studies establish that the loop with its two amphipathic helices is essential for hydrolysis of long chain fatty acid substrate by LPL providing new insight into the role of the LPL loop in lipid-substrate interactions. We propose that the interaction between the lipoprotein substrates and the amphipathic helices within this loop may in part determine lipase substrate specificity.     

Biochemical characterization,cloning and molecular modeling of a digestive lipase from red seabream (Pagrus major): Structural explanation of the interaction deficiency with colipase and lipidic interface

Red seabream digestive lipase (RsDL) was purified from fresh pyloric caeca. Pure RsDL has an apparent molecular mass of 50 kDa. The RsDL is more active on short‐chain triacylglycerols (TC₄), and enzymatic activity decreases when medium (TC₈) or long‐chain (olive oil) triacylglycerols were used as substrates. The specific activities of RsDL are very weak as compared to those obtained with classical pancreatic lipases. No colipase was detected in the red seabream pyloric caeca. Furthermore, the RsDL was not activated by a mammal colipase. Similar results were reported for annular seabream lipase. In order to explain structurally the discrepancies between sparidae and mammal lipases, genes encoding mature RsDL and five other lipases from sparidae fish species were cloned and sequenced. Phylogenetic studies indicated the closest homology of sparidae lipases to bird pancreatic ones. Structural models were built for annular seabream and RsDL under their closed and open forms using mammal pancreatic lipases as templates. Several differences were noticed when analyzing the amino acids corresponding to those involved in HPL binding to colipase. This is likely to prevent interaction between the fish lipase and the mammalian colipase and may explain the fact that mammalian colipase is not effective in activating sparidae lipases. In addition, several hydrophobic residues, playing a key role in anchoring pancreatic lipase onto the lipid interface, are replaced by polar residues in fish lipases. This might explain the reason why the latter enzymes display weak activity levels when compared to mammalian pancreatic lipases.     

Chlorophyllase as a serine hydrolase: identification of a putative catalytic triad

Chlorophyllases (Chlases), cloned so far, contain a lipase motif with the active serine residue of the catalytic triad of triglyceride lipases. Inhibitors specific for the catalytic serine residue in serine hydrolases, which include lipases effectively inhibited the activity of the recombinant Chenopodium album Chlase (CaCLH). From this evidence we assumed that the catalytic mechanism of hydrolysis by Chlase might be similar to those of serine hydrolases that have a catalytic triad composed of serine, histidine and aspartic acid in their active site. Thus, we introduced mutations into the putative catalytic residue (Ser162) and conserved amino acid residues (histidine, aspartic acid and cysteine) to generate recombinant CaCLH mutants. The three amino acid residues (Ser162, Asp191 and His262) essential for Chlase activity were identified. These results indicate that Chlase is a serine hydrolase and, by analogy with a plausible catalytic mechanism of serine hydrolases, we proposed a mechanism for hydrolysis catalyzed by Chlase.     

Mutations in the "lid" region affect chain length specificity and thermostability of a Pseudomonas fragi lipase

The cold-adapted Pseudomonas fragi lipase (PFL) displays highest activity on short-chain triglyceride substrates and is rapidly inactivated at moderate temperature. Sequence and structure comparison with homologous lipases endowed with different substrate specificity and stability, pointed to three polar residues in the lid region, that were replaced with the amino acids conserved at equivalent positions in the reference lipases. Substitutions at residues T137 and T138 modified the lipase chain-length preference profile, increasing the relative activity towards C8 substrates. Moreover, mutations conferred to PFL higher temperature stability. On the other hand, replacement of the serine at position 141 by glycine destabilized the protein.     

Inhibition of phospholipase A1, lipase and galactolipase activities of pancreatic lipase-related protein 2 by methyl arachidonyl fluorophosphonate (MAFP)

Methyl arachidonyl fluorophosphonate (MAFP) is a known inhibitor of cytosolic phospholipase A2 and some other serine enzymes. MAFP was found here to be an irreversible inhibitor of human pancreatic lipase-related protein 2 (HPLRP2), an enzyme displaying lipase, phospholipase A1 and galactolipase activities. In the presence of MAFP, mass spectrometry analysis of HPLRP2 revealed a mass increase of 351Da, suggesting a covalent binding of MAFP to the active site serine residue. When HPLRP2 was pre-incubated with MAFP before measuring residual activity, a direct inhibition of HPLRP2 occurred, confirming that HPLRP2 has an active site freely accessible to solvent and differs from most lipases in solution. HPLRP2 activities on tributyrin (TC4), phosphatidylcholine (PC) and monogalactosyl dioctanoylglycerol (C8-MGDG) were equally inhibited under these conditions. Bile salts were not required to trigger the inhibition, but they significantly increased the rate of HPLRP2 inhibition, probably because of MAFP micellar solubilization. Since HPLRP2 is active on various substrates that self-organize differently in the presence of water, HPLRP2 inhibition by MAFP was tested in the presence of these substrates after adding MAFP in the course of the lipolysis reaction. In this case, the rates of inhibition of lipase, phospholipase A1 and galactolipase activities were not equivalent (triglycerides>PC>MGDG), suggesting different enzyme/inhibitor partitioning between the aqueous phase and lipid aggregates. The inhibition by MAFP of a well identified phospholipase A1 (HPLRP2), present in pancreatic juice and also in human monocytes, indicates that MAFP cannot be used for discriminating phospholipase A2 from A1 activities at the cellular level.     

Lipase-catalysed hydrolysis of short-chain substrates in solution and in emulsion: a kinetic study.

We have studied the enzymatic hydrolysis of solutions and emulsions of vinyl propionate, vinyl butyrate and tripropionin by lipases of various origin and specificity. Kinetic studies of the hydrolysis of short-chain substrates by microbial triacylglycerol lipases from Rhizopus oryzae, Mucor miehei, Candida rugosa, Candida antarctica A and by (phospho)lipase from guinea-pig pancreas show that these lipolytic enzymes follow the Michaelis-Menten model. Surprisingly, the activity against solutions of tripropionin and vinyl esters ranges from 70% to 90% of that determined against emulsions. In contrast, a non-hyperbolic (sigmoidal) dependence of enzyme activity on ester concentration is found with human pancreatic lipase, triacylglycerol lipase from Humicola lanuginosa (Thermomyces lanuginosa) and partial acylglycerol lipase from Penicillium camembertii and the same substrates. In all cases, no abrupt jump in activity (interfacial activation) is observed at substrate concentration corresponding to the solubility limit of the esters. Maximal lipolytic activity is always obtained in the presence of emulsified ester. Despite progress in the understanding of structure-function of lipases, interpretation of the mode of action of lipases active against solutions of short-chain substrates remains difficult. Actually, it is not known whether these enzymes, which possess a lid structure, are in open or/and closed conformation in the bulk phase and whether the opening of the lid that gives access to the catalytic triad is triggered by interaction of the enzyme molecule with monomeric substrates or/and multimolecular aggregates (micelles) both present in the bulk phase. From the comparison of the behaviour of lipases used in this study which, in some cases, follow the Michaelis-Menten model and, in others, deviate from classical kinetics, it appears that the activity of classical lipases against soluble short-chain vinyl esters and tripropionin depends not only on specific interaction with single substrate molecules at the catalytic site of the enzyme but also on physico-chemical parameters related to the state of association of the substrate dispersed in the aqueous phase. It is assumed that the interaction of lipase with soluble multimolecular aggregates of tripropionin or short-chain vinyl esters or the formation of enzyme-substrate mixed micelles with ester bound to lipase, might represent a crucial step that triggers the structural transition to the open enzyme conformation by displacement of the lid.     

A structural model for the prostate disease marker, human prostate-specific antigen.

Prostate-specific antigen (PSA) provides an excellent serum marker for prostate cancer, the most frequent form of cancer in American males. PSA is a 237-residue protease based on sequence homology to kallikrein-like enzymes. To predict the 3-dimensional structure of PSA, homology modeling studies were performed based on sequence and structural alignments with tonin, pancreatic kallikrein, chymotrypsin, and trypsin. The structurally conserved regions of the 4 reference X-ray proteins provided the core structure of PSA, whereas the loop structures were modeled on the loops of tonin and kallikrein. The unique "kallikrein loop" insert, between Ser 95b and Pro 95k of kallikrein, was constructed using molecular mechanics, dynamics, and electrostatics calculations. In the resulting PSA structure, the catalytic triad, involving residues His 57, Asp 102, and Ser 195, and hydrophobic and electrostatic interactions typical of serine proteases were extremely well conserved. Similarly, the 5-disulfide bonds of kallikrein were also conserved in PSA. These results, together with the fact that no major steric clashes arose during the modeling process, provide strong evidence for the validity of the PSA model. Calculation of the electrostatic potential contours of kallikrein and PSA was carried out using the finite difference Poisson-Boltzmann method. The calculations revealed matching areas of negative potential near the catalytic triad, but differences in the positive potential surrounding the active site. The PSA glycosylation site, Asn 61, is fully accessible to the solvent and is enclosed in a positive region of the isopotential map. The bottom of the substrate specificity pocket, residue S1, is a serine (Ser 189) as in chymotrypsin, rather than aspartate (Asp 189) as in tonin, kallikrein, and trypsin. This fact, plus other features of the S1 binding-pocket region, suggest that PSA would prefer substrates with hydrophobic residues at the P1 position. The location of a potential zinc ion binding site involving the side chain of histidines 91, 101, and 233 is also suggested. This PSA model should facilitate the understanding and prediction of structural and functional properties of this important cancer marker.     

Hepatic lipase: a member of a family of structurally related lipases

Partial amino acid sequence of rat hepatic lipase was obtained by gas-phase microsequence analysis of proteolytic fragments. Sequence comparison to bovine lipoprotein lipase and porcine pancreatic lipase reveals a highly conserved region existing among these three physiologically distinct lipolytic enzymes. In a stretch of 36 amino acid residues previously reported for pancreatic lipase (De Caro, J., Boudouard, M., Bonicel, J., Guidoni, A., Desnuelle, P. and Rovery, M. (1981) Biochim. Biophys. Acta 671, 129-138), nineteen residues are identical for all three enzymes, whereas 27 of 36 are identical in rat hepatic lipase and bovine lipoprotein lipase. The fact that this primary structural conservation extends to three different animal species emphasizes the conclusion that these lipolytic enzymes comprise a protein family originating from a common ancestral gene.     

Comparative study on digestive lipase activities on the self emulsifying excipient Labrasol, medium chain glycerides and PEG esters

Labrasol is a lipid-based self-emulsifying excipient used in the preparation of lipophilic drugs intended for oral delivery. It is mainly composed of PEG esters and glycerides with medium acyl chains, which are potential substrates for digestive lipases. The hydrolysis of Labrasol by porcine pancreatic extracts, human pancreatic juice and several purified digestive lipases was investigated in the present study. Classical human pancreatic lipase (HPL) and porcine pancreatic lipase, which are the main lipases involved in the digestion of dietary triglycerides, showed very low levels of activity on the entire Labrasol excipient as well as on separated fractions of glycerides and PEG esters. On the other hand, gastric lipase, pancreatic lipase-related protein 2 (PLRP2) and carboxyl ester hydrolase (CEH) showed high specific activities on Labrasol. These lipases were found to hydrolyze the main components of Labrasol (PEG esters and monoglycerides) used as individual substrates, whereas these esters were found to be poor substrates for HPL. The lipolytic activity of pancreatic extracts and human pancreatic juice on Labrasol(R) is therefore mainly due to the combined action of CEH and PLRP2. These two pancreatic enzymes, together with gastric lipase, are probably the main enzymes involved in the in vivo lipolysis of Labrasol taken orally.     

Mutagenic exploration of the active site of lactate dehydrogenase from Plasmodium falciparum

Several site-directed mutations of residues around the active site of the lactate dehydrogenase from Plasmodium falciparum are described. These include changes to three highly, but not completely, conserved residues in the pocket of the active site and also three changes (including deletions) to the active site loop. Changes to residues in the active-site pocket resulted in little or no over-production of protein and no enzymic activity. Likewise, a five residue deletion from the active site loop gave no over-produced protein, while a two residue deletion and changes of residue type in this loop were tolerated. The results are discussed in the light of this protein being a suitable target for novel anti-malarials.