Low level expression of hormone-sensitive lipase in arterial macrophage-derived foam cells: potential explanation for low rates of cholesteryl ester hydrolysis.

Conversion of arterial macrophages into foam cells is a key process involved in both the initiation and progression of atherosclerotic lesions. Foam cell formation involves the progressive accumulation and storage of lipoprotein-derived cholesteryl esters. The resulting imbalance in cholesterol metabolism in arterial foam cells may be due in part to an inadequately low level of cytoplasmic neutral cholesteryl ester hydrolase (NCEH) activity. In this study, we have demonstrated that hormone-sensitive lipase (HSL) mRNA is expressed at very low levels in macrophage-derived foam cells, using the unique approach of extracting mRNA from macrophage-derived foam cells purified from human and rabbit atherosclerotic plaques coupled with reverse transcriptase polymerase chain reaction (RT-PCR). We also demonstrate that macrophage-derived foam cells isolated from rabbit atherosclerotic lesions exhibit a resistance to high density lipoprotein (HDL)-mediated cholesterol efflux along with reduced levels of NCEH activity compared to lipid-loaded mouse peritoneal macrophages. Thus, low level expression of HSL may partially account for the reduced NCEH activity observed in arterial foam cells isolated from atherosclerosis-susceptible species.

Domain identification of hormone-sensitive lipase by circular dichroism and fluorescence spectroscopy, limited proteolysis, and mass spectrometry.

Structure-function relationship analyses of hormone-sensitive lipase (HSL) have suggested that this metabolically important enzyme consists of several functional and at least two structural domains (Osterlund, T., Danielsson, B., Degerman, E., Contreras, J. A., Edgren, G., Davis, R. C., Schotz, M. C., and Holm, C. (1996) Biochem. J. 319, 411-420; Contreras, J. A., Karlsson, M., Osterlund, T., Laurell, H., Svensson, A., and Holm, C. (1996) J. Biol. Chem. 271, 31426-31430). To analyze the structural domain composition of HSL in more detail, we applied biophysical methods. Denaturation of HSL was followed by circular dichroism measurements and fluorescence spectroscopy, revealing that the unfolding of HSL is a two-step event. Using limited proteolysis in combination with mass spectrometry, several proteolytic fragments of HSL were identified, including one corresponding exactly to the proposed N-terminal domain. Major cleavage sites were found in the predicted hinge region between the two domains and in the regulatory module of the C-terminal, catalytic domain. Analyses of a hinge region cleavage mutant and calculations of the hydropathic pattern of HSL further suggest that the hinge region and regulatory module are exposed parts of HSL. Together, these data support our previous hypothesis that HSL consists of two major structural domains, encoded by exons 1-4 and 5-9, respectively, of which the latter contains an exposed regulatory module outside the catalytic alpha/beta-hydrolase fold core.

Paradoxical effect on atherosclerosis of hormone-sensitive lipase overexpression in macrophages.

Foam cells formed from receptor-mediated uptake of lipoprotein cholesterol by macrophages in the arterial intima are critical in the initiation, progression, and stability of atherosclerotic lesions. Macrophages accumulate cholesterol when conditions favor esterification by acyl-CoA:cholesterol acyltransferase (ACAT) over cholesteryl-ester hydrolysis by a neutral cholesteryl-ester hydrolase, such as hormone-sensitive lipase (HSL), and subsequent cholesterol efflux mediated by extracellular acceptors. We recently made stable transfectants of a murine macrophage cell line, RAW 264.7, that overexpressed a rat HSL cDNA and had a 5-fold higher rate of cholesteryl-ester hydrolysis than control cells. The current study examined the effect of macrophage-specific HSL overexpression on susceptibility to diet-induced atherosclerosis in mice. A transgenic line overexpressing the rat HSL cDNA regulated with a macrophage-specific scavenger receptor promoter-enhancer was established by breeding with C57BL/6J mice. Transgenic peritoneal macrophages exhibited macrophage-specific 7-fold overexpression of HSL cholesterol esterase activity. Total plasma cholesterol levels in transgenic mice fed a chow diet were modestly elevated 16% compared to control littermates. After 14 weeks on a high-fat, high-cholesterol diet, total cholesterol increased 3-fold, with no difference between transgenics and controls. However, HSL overexpression resulted in thicker aortic fatty lesions that were 2.5-times larger in transgenic mice. HSL expression in the aortic lesions was shown by immunocytochemistry. Atherosclerosis was more advanced in transgenic mice exhibiting raised lesions involving the aortic wall, along with lipid accumulation in coronary arteries occurring only in transgenics. Thus, increasing cholesteryl-ester hydrolysis, without concomitantly decreasing ACAT activity or increasing cholesterol efflux, is not sufficient to protect against atherosclerosis. hormone-sensitive lipase overexpression in macrophages.

Hormone-sensitive lipase overexpression increases cholesteryl ester hydrolysis in macrophage foam cells.

Atherosclerosis is a complex physiopathologic process initiated by the formation of cholesterol-rich lesions in the arterial wall. Macrophages play a crucial role in this process because they accumulate large amounts of cholesterol esters (CEs) to form the foam cells that initiate the formation of the lesion and participate actively in the development of the lesion. Therefore, prevention or reversal of CE accumulation in macrophage foam cells could result in protection from multiple pathological effects. In this report, we show that the CE hydrolysis catalyzed by neutral cholesterol ester hydrolase (nCEH) can be modulated by overexpression of hormone-sensitive lipase (HSL) in macrophage foam cells. For these studies, RAW 264.7 cells, a murine macrophage cell line, were found to be a suitable model of foam cell formation. HSL expression and nCEH activity in these cells and in peritoneal macrophages were comparable. In addition, antibody titration showed that essentially all nCEH activity in murine macrophages was accounted for by HSL. To examine the effect of HSL overexpression on foam cell formation, RAW 264.7 cells were stably transfected with a rat HSL cDNA. The resulting HSL overexpression increased hydrolysis of cellular CEs 2- to 3-fold in lipid-laden cells in the presence of an acyl coenzyme A:cholesterol acyltransferase (ACAT) inhibitor. Furthermore, addition of cAMP produced a 5-fold higher rate of CE hydrolysis in cholesterol-laden, HSL-overexpressing cells than in control cells and resulted in nearly complete hydrolysis of cellular CEs in only 9 hours, compared with <50% hydrolysis in control cells. Thus, HSL overexpression stimulated the net hydrolysis of CEs, leading to faster hydrolysis of lipid deposits in model foam cells. These data suggest that HSL overexpression in macrophages, alone or in combination with ACAT inhibitors, may constitute a useful therapeutic approach for impeding CE accumulation in macrophages in vivo.

A molecular biology-based approach to resolve the subunit orientation of lipoprotein lipase.

The subunit orientation of a dimeric enzyme influences the mechanism of action and function. To determine the subunit arrangement of lipoprotein lipase (LPL), a molecular biology-based approach was initiated. An eight amino acid linker region was engineered between two LPL monomers and expressed in COS-7 cells. The resultant tandem-repeat molecule (LPLTR) was lipolytically active and had kinetic parameters, salt inhibition, cofactor-dependent activity, heparin-binding characteristics, and a functional unit size very similar to the expressed native human enzyme. By these criteria, LPLTR was the functional equivalent of native LPL. Considering the length of the linker peptide (no more than 24 A), monomers in the tethered molecule were restricted to a head-to-tail subunit arrangement. Since LPLTR demonstrated native enzyme-like properties while constrained to this subunit arrangement, these results provide the first compelling evidence that native LPL monomers are arranged in a head-to-tail subunit orientation within the active dimer. Thus, LPL function in physiology, lipolysis, and binding to cell-surface components must now be addressed with this subunit orientation in mind. The utility of the tandem-repeat approach to resolve the subunit arrangement of an obligate dimer has been demonstrated with LPL and could be generalized for use with other oligomeric enzymes.

Lipase engineering: a window into structure-function relationships.

Utilization of genetic engineering techniques to create novel functional lipases has increased knowledge of structure-function relationships in this important class of enzymes. The examples of engineered lipases presented in this chapter addressed the investigation of domain-specific properties, heparin binding, and subunit orientation. Conclusions reached are credible because the designed lipases retained catalytic activity, implying native, or near-native, conformation. This approach has demonstrated vigor by determining the domain location of several important enzyme functions and by providing the first evidence that LPL subunits are arranged in a head-to-tail orientation. In conjunction with physical techniques, such as crystallography and nuclear magnetic resonance spectroscopy, the engineered lipase approach could reveal new insights into the mechanism by which lipolysis is accomplished. The studies described here represent only the first attempts to explore that subject; more sophisticated lipase engineering will be used in future as a window into structure-function relationships.

Evidence for hormone-sensitive lipase mRNA expression in human monocyte/macrophages.

The role of hormone-sensitive lipase (HSL) in the hydrolysis of adipose tissue triacylglycerol to provide free fatty acids for energy requirements has been well established. However, the role of HSL in other tissues, including macrophages, is not well understood. The demonstration that HSL is capable of hydrolyzing cholesteryl esters at approximately the same rate as triacylglycerol raised the possibility that HSL activity in macrophages may influence the accumulation of cholesteryl esters in foam cells of atherosclerotic lesions. We and others have previously demonstrated that HSL mRNA is expressed in murine peritoneal macrophages and macrophage cell lines; however, it was previously reported that HSL mRNA is absent in human monocyte-derived macrophages, suggesting that a species difference may exist. To clarify this point, we have further examined the issue of HSL mRNA expression in human macrophages. In the current study, we demonstrate that HSL mRNA is detectable in human monocyte-derived macrophages and in the THP-1 human monocyte cell line using reverse transcription coupled to polymerase chain reaction (RT-PCR). Specific amplification of cDNA derived from mRNA was ensured by using primers that span an intron within the human HSL gene, and the identity of PCR products as HSL was confirmed by hybridization to HSL cDNA and by DNA sequencing. Using a semiquantitative PCR assay, we establish that HSL mRNA levels in monocyte/macrophages are approximately 1/40 the levels in human adipose tissue. These results indicate that further studies addressing the role of HSL in macrophage metabolism and its potential role in development of foam cells in human atherosclerotic lesions are warranted.

Domain-structure analysis of recombinant rat hormone-sensitive lipase.

Hormone-sensitive lipase (HSL) plays a key role in lipid metabolism and overall energy homoeostasis, by controlling the release of fatty acids from stored triglycerides in adipose tissue. Lipases and esterases form a protein superfamily with a common structural fold, called the alpha/beta-hydrolase fold, and a catalytic triad of serine, aspartic or glutamic acid and histidine. Previous alignments between HSL and lipase 2 of Moraxella TA144 have been extended to cover a much larger part of the HSL sequence. From these extended alignments, possible sites for the catalytic triad and alpha/beta-hydrolase fold are suggested. Furthermore, it is proposed that HSL contains a structural domain with catalytic capacity and a regulatory module attached, as well as a structural N-terminal domain unique to this enzyme. In order to test the proposed domain structure, rat HSL was overexpressed and purified to homogeneity using a baculovirus/insect-cell expression system. The purification, resulting in > 99% purity, involved detergent solubilization followed by anion-exchange chromatography and hydrophobic-interaction chromatography. The purified recombinant enzyme was identical to rat adipose-tissue HSL with regard to specific activity, substrate specificity and ability to serve as a substrate for cAMP-dependent protein kinase. The recombinant HSL was subjected to denaturation by guanidine hydrochloride and limited proteolysis. These treatments resulted in more extensive loss of activity against phospholipid-stabilized lipid substrates than against water-soluble substrates, suggesting that the hydrolytic activity can be separated from recognition of lipid substrates. These data support the concept that HSL has at least two major domains.

Isolation and characterization of the gene for mouse hormone-sensitive lipase.

Hormone-sensitive lipase (HSL) is the rate-limiting enzyme in hydrolysis of triglycerides in adipose tissue and of cholesteryl esters in steroidogenic tissues and macrophages. The gene encoding mouse HSL has been isolated and characterized from two overlapping lambda clones. The gene spans approximately 10.4 kb and comprises 9 exons interrupted by 8 introns. The deduced amino acid sequence specifies a protein of 759 amino acids with a Mr of 83,297 in the absence of posttranslational modifications. The known functional domains of the HSL protein are encoded by discrete exons, with the putative catalytic site (Ser423) encoded by exon 6, and the basal and regulatory phosphorylation sites (Ser557 and Ser559) encoded by exon 8. In addition, a putative lipid binding domain occurs in exon 9. The mouse protein shows 94% identity with the previously determined rat sequence and 85% identity with the recently determined human sequence. Interestingly, despite the high degree of similarity, the three species diverge significantly for a stretch of 16 amino acid residues upstream of the phosphorylation sites. In addition, an error was discovered in the carboxyl-terminal portion of the previously reported rat sequence, which produced a frame shift and premature termination of the coding sequence. The corrected rat sequence alters the identity of 12 amino acid residues and extends the protein an additional 11 residues. We have also examined the mouse HSL gene and 5' flanking region for nucleotide sequences that may modulate HSL gene transcription. Using primer extension, we identified a major transcription initiation site 593 nucleotides upstream of the protein coding sequence.(ABSTRACT TRUNCATED AT 250 WORDS)

Lipoprotein lipase and hormone-sensitive lipase activity and mRNA in rat adipose tissue during pregnancy.

To investigate the factors controlling maternal depot fat accumulation during early pregnancy and net decrease during late pregnancy, the activity and mRNA expression of adipose tissue lipoprotein lipase (LPL) and hormone-sensitive lipase (HSL) were related to several other lipid metabolic parameters. Virgin control rats, pregnant rats (at days 12, 15, 19, and 21), and lactating rats (at days 5 and 10 postpartum) were studied. In adipose lumbar tissue of late pregnant rats, LPL activity decreased to about one-third that of the virgin control animals, with < 10% of initial LPL mRNA expressed as determined by Northern blots. HSL activity increased maximally 1.5-fold with a fourfold increase of HSL expression at days 12-15 of pregnancy and decreased to control levels after parturition. The HSL-to-LPL mRNA and activity ratios were enhanced from days 15 and 19 of pregnancy, respectively, and remained so even during lactation, mainly because of the marked lowering of the LPL values. This enhancement coincided with increments in plasma free fatty acids and glycerol levels indicating an increased depot fat breakdown. These results give no indication of an involvement of LPL and HSL gene expression changes in the accumulation of maternal depot during early pregnancy. In contrast, such changes could be responsible for the net breakdown of this fat depot during late gestation. Thus, during this physiological state, long-term (e.g., transcriptional) regulation of LPL and HSL gene expression could be an important mechanism for the control of adipose tissue mass breakdown during late gestation.

Identification of the active site serine of hormone-sensitive lipase by site-directed mutagenesis.

The consensus pentapeptide GXSXG is found in virtually all lipases/esterases and generally contains the active site serine. The primary sequence of hormone-sensitive lipase contains a single copy of this pentapeptide, surrounding Ser-423. We have analyzed the catalytic role of Ser-423 by site-directed mutagenesis and expression of the mutant hormone-sensitive lipase in COS cells. Substitution of Ser-423 by several different amino acids resulted in the complete abolition of both lipase and esterase activity, whereas mutation of other conserved serine residues had no effect on the catalytic activity. These results strongly suggest that Ser-423 is the active site serine of hormone-sensitive lipase.

Hormone-sensitive lipase: structure, function, evolution and overproduction in insect cells using the baculovirus expression system.

Hormone-sensitive lipase (HSL) catalyses the rate-limiting step in the hydrolysis of stored triacylglycerols and is thereby a key enzyme in lipid metabolism and overall energy homeostasis. The gene organization of human HSL indicates that each putative functional region is encoded by a different exon, raising the possibility that HSL is a mosaic protein. The catalytic serine (Ser423), as shown by site-directed mutagenesis, is encoded by exon 6. The phosphorylation site for cAMP-mediated activity control and a second site, which is presumably phosphorylated by 5' AMP-activated kinase, are encoded by exon 8, and a putative lipid-binding region is encoded by the ninth and last exon. Besides the catalytic site serine motif (GXSXG), found in virtually all lipases, a sequence similarity between the region surrounding the catalytic site of HSL and that of five prokaryotic enzymes has been found, but the functional basis of this is not yet understood. To resolve the 3-D structure of HSL, an expression system utilizing recombinant baculovirus and insect cells has been established. The expressed protein, 80 mg/l culture, has been purified to homogeneity and a partial characterization indicates that it has the same properties as HSL purified from rat adipose tissue.

Lipoprotein lipase domain function.

Human lipoprotein lipase (LPL) monomer consists of two domains, a larger NH2-terminal domain that contains catalytic residues and a smaller COOH-terminal domain that modulates substrate specificity and is a major determinant of heparin binding. Analyses of NH2-terminal domain function were performed after site-directed mutagenesis of the putative active-site serine residue, while COOH-terminal domain function was assessed following reaction with a monoclonal antibody. The native enzyme and mutant LPL in which serine 132 was replaced with alanine, cysteine, or glycine were transiently expressed in COS-7 cells. Mutant proteins were synthesized and secreted at levels comparable to native LPL; however, none of the mutants retained enzymatic activity. The mutant with alanine replacing serine 132 was purified and shown to be inactive with both esterase and lipase substrates; however, binding to a 1,2-didodecanoyl-sn-glycero-3-phosphatidylcholine monolayer was comparable to native LPL. These results are consistent with a catalytic, and not a lipid binding, role for serine 132. To investigate the function of the smaller COOH-terminal domain, LPL lipolytic and esterolytic activities as well as heparin binding properties were determined after reaction with a monoclonal antibody specific for this domain. Lipolytic activity was inhibited by the monoclonal antibody, whereas esterolytic activity was only marginally affected, indicating that the LPL COOH-terminal domain is required for lipolysis, perhaps by promoting interaction with insoluble substrates. Also, the affinity of antibody-reacted LPL for heparin was not significantly different from that of LPL alone, suggesting that (i) the heparin-binding site is physically distinct from the COOH-terminal domain region required for lipolysis and (ii) binding of antibody did not cause dimer dissociation. A model is proposed for the two LPL domains fulfilling different roles in the lipolytic process.

Expression of hormone-sensitive lipase mRNA in macrophages.

Macrophages contain a neutral cholesteryl ester hydrolase that can be activated by cAMP-dependent protein kinase. Immunological studies strongly suggest that hormone-sensitive lipase (HSL) is probably responsible for the cholesteryl ester hydrolase activity in macrophages; however, due to the very low level of expression in macrophages, it has been difficult to determine whether the macrophage cholesteryl ester hydrolase and adipose HSL are, in fact, products of the same gene. We have used the sensitive polymerase chain reaction (PCR) technique to demonstrate expression of HSL mRNA in resident and thioglycollate-elicited mouse peritoneal macrophages, as well as in the P388D1 mouse macrophage cell line. PCR was performed using oligonucleotide primer sequences present on adjacent exons of the mouse HSL gene to allow discrimination between products derived from HSL mRNA or genomic DNA sequences; specificity of the PCR was demonstrated by the absence of a product in liver, which does not express HSL mRNA. Northern blot analysis of poly (A)+ RNA from peritoneal macrophages with a mouse adipose HSL cDNA probe demonstrated a low abundance of mRNA of 3.2 kb, identical in size to HSL mRNA in adipose tissue. These findings, together with the results of previous studies demonstrating similarities between HSL and macrophage neutral cholesteryl ester hydrolase, strongly support the conclusion that both are products of a single gene. The development of a PCR assay for HSL mRNA may allow further study of the regulation of neutral cholesteryl ester hydrolase expression in macrophages and foam cells, and its potential role in atherogenesis.

Chimeras of hepatic lipase and lipoprotein lipase. Domain localization of enzyme-specific properties.

Chimeric molecules between human lipoprotein lipase (LPL) and rat hepatic lipase (HL) were used to identify structural elements responsible for functional differences. Based on the close sequence homology with pancreatic lipase, both LPL and HL are believed to have a two-domain structure composed of an amino-terminal (NH2-terminal) domain containing the catalytic Ser-His-Asp triad and a smaller carboxyl-terminal (COOH-terminal) domain. Experiments with chimeric lipases containing the HL NH2-terminal domain and the LPL COOH-terminal domain (HL/LPL) or the reverse chimera (LPL/HL) showed that the NH2-terminal domain is responsible for the catalytic efficiency (Vmax/Km) of these enzymes. Furthermore, it was demonstrated that the stimulation of LPL activity by apolipoprotein C-II and the inhibition of activity by 1 M NaCl originate in structural features within the NH2-terminal domain. HL and LPL bind to vascular endothelium, presumably by interaction with cell surface heparan sulfate proteoglycans. However, the two enzymes differ significantly in their heparin affinity. Experiments with the chimeric lipases indicated that heparin binding avidity was primarily associated with the COOH-terminal domain. Specifically, both HL and the LPL/HL chimera were eluted from immobilized heparin by 0.75 M NaCl, whereas 1.1 M NaCl was required to elute LPL and the HL/LPL chimera. Finally, HL is more active than LPL in the hydrolysis of phospholipid substrates. However, the ratio of phospholipase to neutral lipase activity in both chimeric lipases was enhanced by the presence of the heterologous COOH-terminal domain, demonstrating that this domain strongly influences substrate specificity. The NH2-terminal domain thus controls the kinetic parameters of these lipases, whereas the COOH-terminal domain modulates substrate specificity and heparin binding.