Michael C. Schotz

Human genes involved in lipolysis of plasma lipoproteins: Mapping of loci for lipoprotein lipase to 8p22 and hepatic lipase to 15q21

We have used cDNA probes for lipoprotein lipase and hepatic lipase to determine the chromosomal and subchromosomal locations of the human genes for these lipolytic enzymes. Southern blot analysis of genomic DNA from 17 independent mouse-human somatic cell hybrids demonstrated the presence of the gene for human lipoprotein lipase on chromosome 8, whereas the gene for hepatic lipase was on chromosome 15. Regional mapping of the genes by in situ hybridization to human chromosomes indicated that the lipoprotein lipase gene (LPL) resides in the p22 region of chromosome 8, while hepatic lipase gene (HL) resides in the q21 region of chromosome 15. We previously reported, on the basis of nucleotide and amino acid homologies, that these genes are members of a gene family of lipases, and, thus, the present findings indicate that the members of this family are dispersed. The results are also of significance with respect to disorders involving deficiencies of the enzymes. In particular, they suggest that certain rare combined deficiencies of both enzymes do not involve mutations of the structural loci.

Regulation of lipoprotein lipase: Induction by insulin

Lipoprotein lipase activity in intact epididymal adipose tissue of fasted rats increased rapidly after treatment with insulin in vivo. In contrast, lipoprotein lipase activity in adipocytes isolated from the contralateral fat pads remained essentially unchanged. When adipocytes were incubated for 30 min at ambient temperature in vitro, about 2 times more lipoprotein lipase activity was found in the medium of cells from insulin-treated rats than in medium from cells of control animals. Following insulin treatment, extracts of tissue acetone powders separated by gel chromatography showed increases in both enzyme activity fractions obtained (designated lipoprotein lipase a and b). However, no consistent differences were observed between fractions derived from adipocyte acetone powders of insulin-treated and control animals. All the observed effects of insulin on lipoprotein lipase activity were abolished by cycloheximide treatment in vivo. These data indicate that following insulin treatment, increased lipoprotein lipase activity in adipose tissue results from enhanced enzyme secretion by the fat cell and subsequent accumulation in the tissue, thus implicating the adipocyte secretory mechanism as a major site of regulation of lipoprotein lipase activity in adipose tissue.

Cloning of an interleukin-4 inducible gene from cytotoxic T lymphocytes and its identification as a lipase

Interleukin-4 (IL-4) has been demonstrated to be an important lymphokine for the generation of cytotoxic T lymphocytes (CTLs). Here we describe an IL-4 inducible gene specifically expressed in CTLs. By sequence homology, this gene is likely to be the mouse homolog of pancreatic lipase. Oocyte translation of in vitro transcribed mRNA results in the expression of a protein with lipase activity, and Northern analysis of various tissues and a large panel of hematopoietic cell types demonstrates that this gene is expressed only in the pancreas and CTLs. Lysates of CTLs grown in IL-4, but not in IL-2, exhibit lipase activity. Furthermore, Northern analysis of CTLs grown in the presence of IL-4 for as little as 5 days demonstrates a marked induction of lipase mRNA, which correlates with enhanced cytolysis by these cells. These results suggest that this lipase may have an important role in CTL effector function.

A heterozygous mutation (the codon for Ser447----a stop codon) in lipoprotein lipase contributes to a defect in lipid interface recognition in a case with type I hyperlipidemia.

Previously, we reported a case with type I hyperlipidemia due to a lipid interface recognition deficiency in lipoprotein lipase (LPL) (1). The LPL from postheparin plasma of this patient did not hydrolyze TritonX-100-triolein or very low density lipoprotein-triolein but did hydrolyze tributyrin and LysoPC-triolein substrates. Sequence analysis of the probands DNA revealed a heterozygous nucleotide change: a C----G transversion at position of 1595, resulting in changing the codon for Ser447 to a stop codon. Expression studies of this mutant LPLcDNA in Cos-1 cells produced and secreted considerable amounts of LPL mass in the culture media. The mutated LPL hydrolyzed much less TritonX-100-triolein than wild type LPL, whereas hydrolysis of tributyrin and LysoPC--triolein was the same with both the mutant and wild type LPL. These results suggest that this mutation might be responsible for the property of the LPL with a defect in lipid interface recognition in the type I patient we reported.

An enzyme-linked immunoassay for lipoprotein lipase

Polyclonal antibodies against bovine milk lipoprotein lipase (LPL) were used to generate an enzyme-linked immunosorbent assay (ELISA) for rat LPL. The antibodies to LPL were affinity purified on bovine LPL columns and were shown to be specific for LPL by immunoprecipitation and enzyme inhibition. The solid-phase ELISA was sensitive from 1.0 to 20 ng/ml of LPL and paralleled enzyme activity. Denatured rat LPL showed the same LPL mass as undenatured samples, allowing LPL mass to be quantitated effectively in a variety of rat tissue extracts.

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.

Hepatic lipase. Purification and characterization.

Hepatic lipase has been purified to homogeneity from rat liver homogenates. The purified enzyme exhibits a single band on SDS-polyacrylamide gel electrophoresis. The molecular size of the native hepatic lipase is 200 000, while on SDS-polyacrylamide gel electrophoresis the apparent minimum molecular weight of the enzyme is 53 000, suggesting that the active enzyme is composed of four subunits. The relationship between triacylglycerol, monoacylglycerol and phospholipid hydrolyzing activities of the purified rat liver enzyme was studied. All three activities had a pH optimum of 8.5. The maximal reaction rates obtained with triolein, monoolein and dipalmitoylphosphatidylcholine were 55 000, 66 000 and 2600 mumol fatty acid/mg per h with apparent Michaelis constant (Km) values of 0.4, 0.25 and 1.0 mM, respectively. Hydrolysis of triolein and monoolein probably takes place at the same site on the enzyme molecule, since competitive inhibition between these two substrates was observed, and a similar loss of hydrolytic activity occurred in the presence of diisopropylfluorophosphate. Addition of apolipoproteins C-II and C-I had no effect on the hydrolytic activity of the enzyme with the three substrates tested. However, the triacylglycerol hydrolyzing activity was inhibited by the addition of apolipoprotein C-III. Monospecific antiserum to the pure hepatic lipase has been raised in a rabbit.

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.

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.

Antibodies to lipoprotein lipase application to perfused heart

An antibody was prepared against purified rat heart lipoprotein lipase. 1. This antibody showed marked species specificity. It inhibited almost totally the lipoprotein lipase activity from all rat tissues examined (i.e., heart, adipose, postheparin plasma, and mammary gland), while having no effect on the activity of lipoprotein lipase partially purified from rabbit, guinea pig and bovine heart and from bovine milk. The antibody also had no effect on the hepatic lipase activity of rat postheparin plasma. 2. After antibody to rat heart lipoprotein lipase was recirculated for 5 min through isolated rat hearts, little or no lipoprotein lipase activity could be detected in the perfusate during 0-20 s of a subsequent non-recirculating perfusion with buffer containing 1 unit heparin/ml. 3. Following recirculation of antibody to lipoprotein lipase for 10 min and a non-recirculating perfusion with buffer for 2 min, the hearts no longer oxidized any significant amounts of 14C-labelled palmitate chylomicron triacylglycerol fatty acid to 14CO2 during a 15-min perfusion. The data give compelling evidence that the functional fraction of lipoprotein lipase in hearts is at the endothelial cell surface accessible to lipoprotein lipase antibody.