Porcine pancreatic lipase. Completion of the primary structure

Molecular cloning and characterization of rabbit pancreatic triglyceride lipase

Pancreatic lipase (triacylglycerol acylhydrolase, EC 3.1.1.3) has been cloned from a gt11 cDNA library made from poly A+ RNA of adult rabbit pancreas. Pancreatic lipase (PL) assists the absorption of dietary triglycerides by hydrolyzing them at 1 and 3 positions to free fatty acids and 2-monoacylglycerol in the presence of bile acids and colipase in the intestinal lumen. Since rabbits are classifically used for the study of the diet induced changes in the lipid metabolism, as a prelude to studying the diet and age dependent changes in the expression of this enzyme, a full length PL cDNA clone was obtained from its pancreas. The coding region of rabbit pancreatic lipase cDNA consists of 1407 base pairs contained in an open reading frame encoding 469 amino acids including the 16 that constitute the signal peptide. Northern blot analysis revealed a band around 1.5 kb. When rabbit enzyme is compared to other species, an over all homology of 70-80% was observed at the nucleotide level. High homology in the amino acid sequence and composition is also apparent between rabbit and other species like dog (65%), pig (76%) and rat (63%). Highest homology is found to be around active-site serine. The regions of homology with other species may help to define sites of interaction of lipase with co-lipase.

Kinetics and mechanisms of reactions catalysed by immobilized lipases

This review focuses on the kinetics and mechanisms of reactions catalysed by immobilized lipases. The effects of pH, temperature, and various substances on the catalytic properties of immobilized lipases and on the processes by which they are deactivated are reviewed and discussed.

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.

Isoform purification of gastric lipases. Towards crystallization

Several isoforms of rabbit and human gastric lipases have been purified. These isoforms have the same apparent molecular weight (Mr approximately 50,000), but very different isoelectric points. Some of these isoforms were purified: pI 7.2 and 6.5 in the case of rabbit gastric lipase; and pI 7.4 and 7.2 in that of human gastric lipase. All the purified isoforms were found to have the same specific lipase activity (around 1200 units per mg of protein, measured on tributyrin as substrate). The isoforms of dog gastric lipase are more closely related, and could not be separated. Partial enzymatic deglycosylation of human gastric lipase reduced the apparent molecular weight from Mr approximately 50,000 to Mr approximately 43,000 and induced a change in the isoelectrofocusing pattern and the emergence of a new isoform (pI 7.3). It is concluded that the charge heterogeneity of gastric lipases is at least partly due to the glycan moiety of the molecule, which amounts to approximately 14% of the total molecular weight. Several crystallization trials on purified native preparations of rabbit and human gastric lipases were unsuccessful, whereas crystals were obtained from native dog gastric lipase and all the purified isoforms of rabbit and human gastric lipases, some of which were crystallographically characterized.

Direct involvement of the C-terminal extremity of pancreatic lipase (403-449) in colipase binding

After a selective cleavage of a lipase/colipase cross-linked complex, the colipase has been shown to be bound to a 5 kDa lipase fragment identified as the C-terminal extremity of the chain extending from residue 403 to the C-terminus (Cys 449). The colipase binding site on lipase is therefore localized in a restricted contact area. Moreover, from sequence comparison of lipase from various species, an acidic residue, Glu 440, is likely to be involved in ion pairing with colipase.

Identification of the active-site serine in human pancreatic lipase by chemical modification with tetrahydrolipstatin

A chemical modification approach was used in this study to identify the active site serine residue of human pancreatic lipase. Purified human pancreatic lipase was covalently modified by incubation with [3H], [14C] tetrahydrolipstatin (THL), a potent inhibitor of pancreatic lipase. The radiolabeled lipase was digested with thermolysin, and the peptides were separated by HPLC. A single THL-peptide-adduct was obtained which was identical to that obtained earlier from porcine pancreatic lipase. This pentapeptide with the sequence VIGHS is covalently bound to a THL molecule via the side chain hydroxyl group of the serine unit corresponding to Ser-152 of the lipase. The selective cleavage of the THL-serine bond by mild acid treatment resulted in the formation of the delta-lactone Ro 40-4441 in high yield and clearly proves that THL is attached via an ester bond and with retention of stereochemistry at all chiral centers to the side chain hydroxyl group of Ser-152 of the lipase. The results obtained for human pancreatic lipase corroborate the inhibition mechanism of THL found on the porcine enzyme, and are in full agreement with the identification of the Ser-152 ... His-263 ... Asp-176 catalytic triad in the X-ray structure of human pancreatic lipase.

Primary structure of rat pancreatic lipase mRNA

The sequence of rat pancreatic lipase mRNA was determined. The data have been assigned the following accession number, X61925, in the EMBL data library. The total length of the messenger is 1531 nucleotides, plus a poly(A) stretch of about 60 nucleotides. A 72-nucleotides 5'-noncoding region is followed by a 1419-nucleotides open reading frame which encodes a protein of 473 amino acids, including the 17 amino acid signal peptide. The mature enzyme (456 residues) has 6 additional C-terminal amino acids, as compared with the amino acid sequence of pig (direct amino acid sequence), dog, man and rat isoenzyme from Genbank, M58369 (all deduced from the nucleotide sequence). A higher degree of homology exists between the amino acid sequence of rat mature enzyme with those of dog (88%), pig (75%) and man (75%) than with that of rat isolipase (74%).

[The characterization of microbial lipases. 2. The determination of lipase specificity]

Types of lipase specificity are as follows: Positional specificity; fatty acid specificity; stereospecificity; substrate specificity (different rates of lipolysis of different glyceride classes. The acylglycerol used for determination of lipase specificity must be so structured, that specificities are not confused and unambiguous results are obtained. Different substrates and methods for detection of specificity are reviewed and advantages and disadvantages are discussed. Positional specificity can be determined with synthetic dialkylacylglycerols and 2,3-dioleoyl butanediol. Stereospecificity can be detected with enantiomeric dialkylacylglycerols or diacylalkylglycerols.

Interactions of lipases with lipid monolayers. Facts and questions

Among the proteins, lipolytic enzymes provide a valuable model for studying protein-lipid interactions. Lipases having a catalytic action which is strictly dependent upon the presence of a lipid interface were used in the present study in order to gain better insight into protein-lipid interactions. Most of the data presented here were obtained using the monolayer technique, by recording (either independently or simultaneously) the lipolytic activity, the amount of protein adsorbed to the lipid monolayer, and the surface pressure variations following protein adsorption. Several non-enzymatic proteins were used as controls in order to determine how lipase behaviour differs from that of other proteins. At all initial surface pressures tested, with zwitterionic monolayers, a good correlation was observed between the amount of lipase bound to the monolayer and the surface pressure increase, in agreement with previous studies. Conversely, with neutral lipid monolayers the amount of lipase bound to the monolayer was not found to be surface pressure dependent. This latter behaviour observed with lipases on neutral films is not specific to lipases, since it was also observed with bovine serum albumin and beta-lactoglobulin A. Lipase activity in the presence of various proteins was investigated with monomolecular films of glycerol didecanoate, either at constant surface area or at constant surface pressure. Depending upon the nature of the lipase and the protein, inhibition of lipase activity was either observed or not. Inhibition was correlated with a decrease in lipase surface concentration. The ability of the various proteins to inhibit lipolysis is: (i) a function of their excess versus lipase in the bulk phase, and: (ii) correlated with their penetration capacity (i.e., the initial rate of surface pressure increase of a glycerol didecanoate monolayer having an initial surface pressure of 20 dyn/cm, after the injection-of the protein). Since lipase inhibition was observed with low surface densities of inhibitory proteins, a long-range effect is probably involved in the mechanism of interfacial lipase inhibition. The nature of the ionic charge added to the monolayer by the protein is not critical for determining lipase adsorption or desorption. It is hypothesized that the lack of lipase adsorption to, or desorption from, the lipid monolayer results from a change in the organization of the hydrocarbon moiety of the lipid.

Structure of human pancreatic lipase

Pancreatic lipase (triacylglycerol acyl hydrolase) fulfills a key function in dietary fat absorption by hydrolysing triglycerides into diglycerides and subsequently into monoglycerides and free fatty acids. We have determined the three-dimensional structure of the human enzyme, a single-chain glycoprotein of 449 amino acids, by X-ray crystallography and established its primary structure by sequencing complementary DNA clones. Enzymatic activity is lost after chemical modification of Ser 152 in the porcine enzyme, indicating that this residue is essential in catalysis, but other data are more consistent with a function in interfacial recognition. Our structural results are evidence that Ser 152 is the nucleophilic residue essential for catalysis. It is located in the larger N-terminal domain at the C-terminal edge of a doubly wound parallel beta-sheet and is part of an Asp-His-Ser triad, which is chemically analogous to, but structurally different from, that in the serine proteases. This putative hydrolytic site is covered by a surface loop and is therefore inaccessible to solvent. Interfacial activation, a characteristic property of lipolytic enzymes acting on water-insoluble substrates at water-lipid interfaces, probably involves a reorientation of this flap, not only in pancreatic lipases but also in the homologous hepatic and lipoprotein lipases.

The active site composition of porcine pancreatic lipase: possible involvement of lysine

A mechanism is proposed wherein an essential lysine in porcine pancreatic lipase is the acylable residue in the catalytic mechanism of the enzyme. This mechanism involves an initial interfacial activation step were acylation first takes place in a rate-limiting step on a serine residue assisted by histidine and a carboxyl-containing residue, aspartic acid or glutamic acid, and then in a fast subsequent step the acyl group is transferred to the essential lysine residue at the catalytic site. Indirect support for the mechanism is presented. When the essential lysine is made inactive by reductive methylation, the lipase is functionally converted to a proteinase, as predicted by the mechanism.

Genomic organization of the region encoding guinea pig lipoprotein lipase; evidence for exon fusion and unconventional splicing

The coding sequence of guinea pig lipoprotein lipase (LPL) is organized into nine exons and spans a region of approximately 14 kb of the guinea pig genome. A non-conforming 5'-splice site is located on the first intron, which exhibits a 12-nucleotide perfect match with the 5'-end of the second exon. A previously described tryptic cleavage site is located on exon V, close to the 3' end of this exon. A similarity to vitellogenin resides on exons IV and V, and a putative active site is found on exon IV. A novel similarity to a fatty-acid-binding protein is noted on exon VI, adjacent to the postulated heparin-binding region. We suggest that free fatty acids (FFA) and heparin to some extent share the same site of interaction on the LPL molecule; and that a high local concentration of FFA can displace LPL from its site of action--the vascular endothelium--by competing for binding to heparan sulfate.

Molecular cloning and expression of cDNA for rat pancreatic cholesterol esterase

A full-length cDNA complementary to the rat pancreatic cholesterol esterase mRNA was isolated by screening a rat pancreatic cDNA expression library in lambda gt11 vector with antibodies against the porcine pancreatic cholesterol esterase. The isolated cholesterol esterase cDNA is 2050 bp in length and contains an open reading frame coding for a protein of 612 amino acids. A 20-amino acid hydrophobic leader sequence is predicted, based on the position of the first ATG initiation codon upstream from the sequenced amino terminus of the isolated cholesterol esterase. The cholesterol esterase cDNA was subcloned into a mammalian expression vector, pSVL, for transfection studies. Expression of the cDNA in COS cells resulted in the production of bile salt-stimulated cholesterol esterase. Comparison of the cholesterol esterase cDNA sequence with other proteins revealed that the pancreatic cholesterol esterase is identical to rat pancreatic lysophospholipase. The primary structure of cholesterol esterase displayed no significant homology with other lipases, although the putative lipid interfacial recognition site of G-X-S-X-G is present in the cholesterol esterase sequence. However, the cholesterol esterase sequence revealed a 63-amino-acid domain which is highly homologous to the active site domain of other serine esterases. These data suggest that cholesterol esterase may be a member of the serine esterase supergene family. Analysis of the cholesterol esterase structure also revealed a repetitive sequence enriched with Pro, Asp, Glu, Ser, and Thr residues at the C-terminal end of the protein. This sequence is reminiscent of the PEST-rich sequences in short-lived proteins, suggesting that cholesterol esterase may have a short half-life in vivo. Northern blot hybridization showed that the bile salt-stimulated cholesterol esterase mRNA is present in liver suggesting that this protein may also be synthesized by liver cells.

The histidines reacting with ethoxyformic anhydride in porcine pancreatic lipase: their relationships with enzyme activity

The activities of porcine pancreatic lipase (449 amino acid residues) toward two different substrates, p-nitrophenylacetate and tributyrylglycerol, and their dependence on histidine ethoxyformylation were studied. In parallel, the ethoxyformylation of the lipase fragment constituting the C-terminal sequence of lipase (residues 336 to 449) was also investigated. This fragment was found to have retained the ability of lipase to catalyse p-nitrophenylacetate hydrolysis. The first histidine to react either in lipase or in the lipase fragment was His-354. The activities of the two compounds toward p-nitrophenyl-acetate were lost but that of the enzyme toward tributyrylglycerol was almost entirely retained. When a larger excess of ethoxyformic anhydride was used for the lipase reaction, 2.8 histidine residues were ethoxyformylated and characterised as His-354, His-156 and His-75, which resulted in an 85% inhibition of the tributyrylglycerol hydrolysis by the enzyme. Hydroxylamine treatment reactivated most of the lipase and lipase fragment. This is the first demonstration that the two lipase activities are not associated with the same active site. The loss of activity toward triacylglycerol hydrolysis suggests that His-156 and/or His-75 belong(s) to the active site or that a conformational change resulting from the ethoxyformylation renders the lipase inactive.

Secondary structures of rat lipolytic enzymes: circular dichroism studies and relation to hydrophobic moments

To explore the secondary structures of lingual and pancreatic lipases, circular dichroism measurements were performed. Maximum average ellipticities were used to calculate the percentage of alpha-helices, beta-sheets, and random coils. Lingual lipase had an ellipticity of -20235 +/- 140 deg cm2/dmol (mean +/- SE) at 220 nm suggesting 60% alpha-helix, 20% beta-sheet and 20% random coil structure, but the mean ellipticity for pancreatic lipase was -14093 +/- 82 deg cm2/dmol (mean +/- SE) at 210 nm suggesting a 34.8% alpha-helical, 25% beta-sheet and 40% random coil secondary structure. An alpha-helical stretch of residues with a large hydrophobic moment ("globular" alpha-helix by hydrophobic moment plot) from amino acids 382 through 389 at the COOH-terminal end of lingual lipase was noted. This sequence, absent in pancreatic lipase, may account for the avid binding of lingual lipase to fat emulsion particles.

Structural features of lipoprotein lipase. Lipase family relationships, binding interactions, non-equivalence of lipase cofactors, vitellogenin similarities and functional subdivision of lipoprotein lipase

A structural homology between lipoprotein lipase, pancreatic lipase and hepatic lipase is known and indicates that all three lipases are members of a common protein family. Lipoprotein lipase and pancreatic lipase utilize small protein co-factors, apolipoprotein C-II and co-lipase, respectively, but comparisons reveal no homology between the co-factor molecules. Hence, they do not show the same relationship as their target enzymes. Neither do screenings detect any extensive similarities between lipoprotein lipase, serine hydrolases, or apolipoproteins. Scannings against data bank proteins show that a 105-residue segment of lipoprotein lipases exhibits a 35-40% residue identity with a sub-region of Drosophila vitellogenins. One fifth of the conserved amino acid residues (8 of 40) are glycine, a pattern which is typical of distantly related forms of protein families. This supports a true relationship between large segments of Drosophila vitellogenins and lipases. Physiological and functional aspects of the vitellogenin/lipoprotein lipase similarities are given. The region concerned is entirely within the N-terminal domain of lipoprotein lipase and constitutes the segment where the similarity to hepatic and pancreatic lipases is most pronounced. Within this lipase region a 10-residue putative lipid-binding site exists for which further similarities have been found to the otherwise not closely related lingual/gastric lipases, prokaryotic lipases and lecithin-cholesterol acyltransferase. Another segment in lipoprotein lipase, where the heparin-binding site has been mapped, exhibits a correlation between strength of heparin binding and extent of basic residues among members of the lipase family. It further exhibits weak similarities with the 'Zn-finger' DNA-binding segment of steroid hormone receptors and may indicate convergence in a binding interaction. Thus, a functional subdivision of lipoprotein lipase into different segments can be distinguished.

Crystallization and preliminary X-ray study of horse pancreatic lipase

Horse (Equus caballus) pancreatic lipase (EC 3.1.1.3) has been crystallized using the hanging drop method of vapour diffusion at 20 degrees C. The best crystals were grown from an 8 mg/ml solution in 10 to 20% (w/v) polyethylene glycol 8000, 10 mM-MgCl2, 0.1 M-NaCl, 0.1 M-Mes buffer (pH 5.6). They reach dimensions of 0.8 mm x 0.4 mm x 0.6 mm. X-ray examination of the lipase crystals shows that they are orthorombic with a space group P2(1)2(1)2(1). Their cell dimensions are a = 79.8 A, b = 97.2 A c = 145.3 A. Two molecules per asymmetric unit give a Vm value of 2.82 A3/dalton (56% water content). Lipase crystals strongly diffract to at least 1.8 A resolution. Some molecular properties of horse lipase compared to those of the better-known porcine enzyme are also presented.

Cloning, sequencing and expression of the lipase gene from Pseudomonas fragi IFO-12049 in E. coli

The lipase gene from Pseudomonas fragi IFO-12049 was isolated using the expression library and the primary structure of lipase deduced from the nucleotide sequence was determined. It is composed of 277 amino acid residues and a protein of Mr 29,966, which was close to the value of the lipase expressed in E. coli.

Recent advances in the purification, characterization and structure determination of lipases

Recently, lipases have been purified from mammalian, bacterial, fungal and plant sources by different methodologies. Purified lipases subsequently have been characterized for molecular size, metal binding capabilities, glycoside and phosphorus contents, and substrate specificities. Primary structures of several lipases have been determined either from amino acid or nucleic acid sequences. Lipases sequenced to date share sequence homologies including a significant region, Gly-X-Ser-X-Gly, that is conserved in all. The Ser residue is suspected to be essential for binding to lipid substrates.

Acetylation of Lys-373 in porcine pancreatic lipase after reaction of the enzyme or its C-terminal fragment [corrected] with p-nitrophenyl acetate

The reactions of lipase (449 amino acid residues) and lipase fragment (336-449) with p-nitrophenyl acetate have been studied from 2 different angles. In previous papers it has been shown that lipase and lipase fragment enzymatically hydrolyze p-nitrophenyl acetate. The amino acid residue of the catalytic site that is temporarily acetylated has not yet been characterized in lipase or lipase fragment. Besides this very fast enzymatic hydrolysis, acetylation reactions may take place on nucleophilic amino acid side-chain groups. In the present report, acetylated amino acid residues whose acetyl linkages were not cleaved after pH 7.5-8.5 incubations have been investigated. Several residues were acetylated in very low proportion, whereas lysine 373 was stoichiometrically acetylated in lipase and in lipase fragment. This specific acetylation may have been favored by the presence of a hydrophobic reversible binding site for p-nitrophenyl acetate near Lys-373. This acetylation did not greatly change the specific activity of lipase towards an emulsion of tributyrylglycerol in the presence of colipase, but under certain conditions it had an effect on the enzymatic hydrolysis of p-nitrophenyl acetate by the lipase fragment.

Is vitellogenin an ancestor of apolipoprotein B-100 of human low-density lipoprotein and human lipoprotein lipase?

Vitellogenin, an ancient animal protein, is the major yolk protein of eggs, where it is used as a food source during embryogenesis. Here it is shown that vitellogenins, including those from the invertebrates Caenorhabditis elegans and Drosophila melanogaster, contain domains that are homologous with parts of apolipoprotein B-100 (apoB-100) of human low-density lipoprotein and human lipoprotein lipase. As vitellogenins are likely to have been used by invertebrates during embryogenesis well before the circulation of lipids appeared in vertebrates, it is suggested that copies of a precursor gene, serving a function similar to vitellogenin, were modified to code for part of apoB-100 and lipoprotein lipase in vertebrates. In addition to providing a link between invertebrates and vertebrates for proteins involved in lipid transport, these homologies suggest new functions for vitellogenin other than being a yolk food for the developing embryo.

Hormone-sensitive lipase: sequence, expression, and chromosomal localization to 19 cent-q13.3

Hormone-sensitive lipase, a key enzyme in fatty acid mobilization, overall energy homeostasis, and possibly steroidogenesis, is acutely controlled through reversible phosphorylation by catecholamines and insulin. The 757-amino acid sequence predicted from a cloned rat adipocyte complementary DNA showed no homology with any other known lipase or protein. The activity-controlling phosphorylation site was localized to Ser563 in a markedly hydrophilic domain, and a lipid-binding consensus site was tentatively identified. One or several messenger RNA species (3.3, 3.5, or 3.9 kilobases) were expressed in adipose and steroidogenic tissues and heart and skeletal muscle. The human hormone-sensitive lipase gene mapped to chromosome 19 cent-q13.3.

Immobilized colipase affinities for lipases B, A, C and their terminal peptide (336-449): the lipase recognition site lysine residues are located in the C-terminal region

Zonal high-performance affinity chromatography has been used in order to study the interactions between pig isolipases A, B and C and the terminal peptide chain fragment 336-449 of the pig lipase on the one hand, and the homolog colipase bound to the inert LiChrosorb diol support on the other. A mathematical treatment led the to assessment of the dissociation constant of the lipase-colipase complex using isolipases or the terminal peptide as eluted acceptors and colipase as silica-bound ligand (Mahé, N., Léger, C.L., Linard, A. and Alessandri, J.-M. (1987) J. Chromatogr. 395, 511-521). A higher affinity of isolipase B as compared to isolipases A and C towards colipase was observed (KD, respectively, of 0.68, 11 and 12 microM) at pH 6.5. Under the same chromatographic conditions, the terminal peptide chain interacted with the bound colipase (KD 0.70 microM, close to that of isolipase B). The chromatographic behaviors of both native and chemically modified lipase and terminal peptide were very similar. In particular, guanidination of lysine residues of both peptide and isolipase B led to the loss of interactions with colipase. The same result was observed with the peptide preincubated in the presence of increasing amounts of free colipase. Accordingly, it is suggested that, firstly, a preferential association of isolipase B to colipase could take place and, secondly, the colipase recognition site of lipase could be located in the C-terminal region, the conformational structure of the terminal peptide not being affected by the enzymic cleavage and, therefore, being largely independent of the rest of the polypeptide molecule. On the other hand, a lower colipase affinity for isolipases A or C than for isolipase B or the C-terminal peptide could tentatively be attributed to a non-local (distant) disturbing effect of the negatively charged glycan chain, as sialic acid is present in both isoforms A and C. Finally, the present paper confirms and extends earlier studies on lipase-colipase interactions.

Minireview on pancreatic lipase and colipase

By hydrolyzing the dietary triacylglycerols, pancreatic lipase causes catalysis in heterogeneous medium. In vivo, lipase action cannot take place without colipase due to the presence of bile salts. The cofactor enables lipase anchoring to the water-lipid interface. The lipase-colipase system furnishes an excellent example of specific interactions (protein-protein and protein-lipid). The studies of lipase catalytic properties brought to light the importance of certain parameters related to the 'quality of the interface'. The structure-function relationship analyses revealed a certain number of functional amino acid residues in lipase and colipase involved either in the catalytic site of the enzyme or in the recognition sites (lipase-colipase and protein-interface). Comparisons of the sequences of lipases derived from different sources display interesting similarities in certain cases.

Homology of Drosophila yolk proteins and the triacylglycerol lipase family

Drosophila yolk proteins consist of a set of related proteins of 50,000 Mr. They are derived from slightly larger precursors by cleavage of a signal peptide. In this respect, they differ from the yolk proteins of other insects which are proteolytic fragments of precursors of 200,000 Mr or larger, termed vitellogenins and probably homologous to the vitellogenins of other egg-laying species. We report here a comparative amino acid analysis demonstrating that the Drosophila yolk proteins are non-homologous to the vitellogenin group of yolk proteins, but surprisingly are related to the triacylglycerol lipase family.

Rhizomucor miehei triglyceride lipase is synthesized as a precursor

A Rhizomucor miehei cDNA library constructed in Escherichia coli was screened with synthetic oligonucleotides designed from knowledge of a partial amino acid sequence of the secreted triglyceride lipase (triacylglycerol acylhydrolase EC 3.1.1.3) from this fungus. Lipase-specific recombinants were isolated and their insert sequenced. Unlike characterized bacterial and mammalian triglyceride lipases, the fungal enzyme is synthesized as a precursor, including a 70 amino acid residue propeptide between the 24 amino acid residues of the signal peptide and the 269 residues of the mature enzyme. The precursor processing mechanism, which involves cleavage between a methionine and a serine residue, is unknown. By sequence comparison with other lipases, a serine residue involved in substrate binding was identified in the fungal lipase. The sequence around this residue is well-conserved among characterized lipases. Conservation of an intron in an isolated cDNA recombinant and immunoprecipitation of in vitro synthesized R. miehei translation products indicates that the expression of the lipase gene might involve inefficient mRNA splicing.

Purification, characterization and kinetic properties of the rabbit gastric lipase

Rabbit gastric lipase was purified from an acetonic powder of rabbit stomach fundus. 25 mg of pure rabbit gastric lipase (glycerol ester hydrolase, EC 3.1.1.3) was obtained from 30 rabbit stomachs after ammonium sulfate fractionation, Sephadex G-100 gel filtration and cation exchange (mono S column) using a fast protein liquid chromatography (FPLC) system. The pure enzyme obtained was resistant to acidic pH conditions, and had specific activities of 1200, 850 and 280 U/mg, using, respectively, short- (tributyroylglycerol (TC4)), medium- (trioctanoyl- to tridecanoylglycerol (TC8-TC10)) and long-chain (soybean oil) triacylglycerols. The amino-acid composition was determined, and the first 30 N-terminal amino-acid residues were sequenced. Interfacial denaturation and catalytic properties on triacylglycerol emulsions were studied. Rabbit gastric lipase turned out to be structurally and kinetically very similar to human gastric lipase.

Evidence that insect embryogenesis is regulated by ecdysteroids released from yolk proteins

That the yolk proteins (YPs), or vitellins, stored in the oocytes of insects are a nutritional store for subsequent embryogenesis has long been assumed. Exhaustive data base searching programs revealed highly significant sequence similarity between the three YPs of Drosophila melanogaster and part of the triacylglycerol lipase of the domestic pig. Based upon time of degradation of YPs during embryogenesis, existence of maternally stored ecdysteroid conjugates in embryos, location of these conjugates in locust embryos, and the fact that free active ecdysteroid hormones are released at a specific time in embryogenesis to trigger cuticle deposition, we postulate that the similarity reflects a common property of Drosophila YPs--the ability to bind the fatty acid ecdysteroid conjugates. Our finding of conjugated ecdysteroids tightly bound to purified Drosophila YP supports this prediction.

Primary structure of the glycans of porcine pancreatic lipase

The glycan primary structure of the main glycopeptide fraction obtained by pronase and carboxypeptidase A digestions of porcine pancreatic lipase has been investigated by 500-MHz 1H-NMR spectroscopy and methylation analysis. The results demonstrate that the glycopeptide fraction was a mixture containing the following structures: (formula; see text)