Ishaiahu Shechter

Structure and Function of HDL Mimetics

HDL mimetics have been constructed from a number of peptides and proteins with varying structures, all of which bind lipids found in HDL. HDL mimetics containing a peptide or protein have been constructed with as few as 4 and as many as 243 amino acid residues. Some HDL mimetics have been constructed with lipid but without a peptide or protein component. Some HDL mimetics promote cholesterol efflux, some have been shown to have a remarkable ability to bind oxidized lipids compared to human apolipoprotein A-I (apoA-I). Many of these peptides have been shown to have antiinflammatory properties. Based on studies in a number of animal models and in early human clinical trials, HDL mimetics appear to have promise as diagnostic and therapeutic agents.

The PULSE Initiative Scientific Priorities and Strategic Planning for Resuscitation Research and Life Saving Therapies

The Post-resuscitative and initial Utility in Life Saving Efforts (PULSE) Conference represented an initiative by leaders of the international scientific community who sought opportunities for major improvements in clinical outcomes after cardiopulmonary resuscitation and after resuscitation from serious traumatic injury.1 The experts focused on scientific research that would yield major advances in lifesaving care, including measurable increases in survival and functional recovery. However, unless research support is prioritized to address resuscitation, it is highly unlikely that these opportunities would soon be realized. We lose more than 1000 lives each day in the United States from sudden, unexpected death, a fatality rate comparable to the crash of two 747 aircraft without survivors.2–5⇓⇓⇓ Cardiovascular disease is the leading cause of death among individuals aged greater than 65 years, the second leading cause of death among individuals aged 45 to 65 years, and the 5th leading cause of death among individuals aged 1 to 9 years.4,5⇓ Traumatic injuries in the United States were responsible for 147 891 deaths and 2.6 million hospitalizations, costing over

Function-Structure Studies and Identification of Three Enzyme Domains Involved in the Catalytic Activity in Rat Hepatic Squalene Synthase

335 000 per death and resulting in 37 million emergency department visits in 1995.6,7⇓ Trauma is the leading cause of death among children and all individuals to age 34 years, the leading cause of loss of productive life-years of any disease, with societal costs (estimated by the National Safety Council) of

Structure and regulation of mammalian squalene synthase.

469 billion dollars annually, and the third leading cause of death among individuals aged 35 to 54 years. The Conferees anticipated that the availability of new intervention strategies with more effective diagnostic methodologies in the early post-injury time interval would not only save lives but also reduce morbidity.1 Accordingly, the PULSE participants cited current restraints and/or barriers to the delivery of more effective resuscitation interventions and reaffirmed that …

Hepatic farnesyl diphosphate synthase expression is suppressed by polyunsaturated fatty acids

Rat hepatic squalene synthase (RSS, EC 2.5.1.21) contains three conserved sections, A, B, and C, that were proposed to be involved in catalysis (McKenzie, T. L., Jiang, G., Straubhaar, J. R., Conrad, D., and Shechter, I. (1992) J. Biol. Chem. 267, 21368–21374). Here we use the high expression vector pTrxRSS and site-directed mutagenesis to determine the specific residues in these sections that are essential for the two reactions catalyzed by RSS. Section C mutants F288Y, F288L, F286Y, F286W, F286L, Q293N, and Q283E accumulate presqualene diphosphate (PSPP) fromtrans-farnesyl diphosphate (FPP) with reduced production of squalene. F288L, which retains approximately 50% first step activity, displays only residual activity (0.2%) in the production of squalene from either FPP or PSPP. Substitution of either Phe288 or Phe286 with charged residues completely abolishes the enzyme activity. Thus, F288W, F288D, F288R, F286D, and F286R cannot produce squalene from either FPP or PSPP. All single residue mutants in Section A, except Tyr171, retain most of the RSS activity, with no detectable accumulation of PSPP in an assay mixture complete with NADPH. Y171F, Y171S, and Y171W are all inactive. Section B, which binds the diphosphate moieties of the allylic diphosphate subtrates, contains four negatively charged residues: Glu222, Glu226, Asp219, and Asp223. The two Glu residues can be replaced with neutral or with positively charged residues without signficantly affecting enzyme activity. However, replacement of either Asp residues with Asn eliminates all but a residual level of activity, and substitution with Glu abolishes all activity. These results indicate that 1) Section C, in particular Phe288, may be involved in the second step of catalysis, 2) Tyr171 of Section A is essential for catalysis, most likely for the first reaction, 3) the two Asp residues in Section B are essential for the activity and most likely bind the substrate via magnesium salt bridges. Based on these results, a mechanism for the first reaction is proposed.

Squalene synthase, a determinant of Raft-associated cholesterol and modulator of cancer cell proliferation.

Mammalian squalene synthase (SQS) catalyzes the first reaction of the branch of the isoprenoid metabolic pathway committed specifically to sterol biosynthesis. SQS produces squalene in an unusual two-step reaction in which two molecules of farnesyl diphosphate are condensed head-to-head. Recent studies have advanced understanding of the reaction mechanism, the functional domains of the enzyme, and transcriptional regulation of the gene. Site-directed mutagenesis has identified conserved Asp, Tyr, and Phe residues that are essential for SQS activity. The Asp residues are hypothesized to be required for substrate binding; the Tyr and Phe residues may stabilize carbocation reaction intermediates. The elucidation of SQS crystal structure will most likely direct future research on the relationship between enzyme structure and function. SQS activity, protein, and mRNA levels are regulated by cholesterol status and by the cytokines TNF-alpha and IL-1beta. Activation of the SQS promoter in response to cholesterol deficit is mediated by sterol regulatory element binding proteins SREBP-1a and SREBP-2. The precise contributions made by individual SREBPs and accessory transcription factors to SQS transcriptional control, and the mechanisms underlying cytokine regulation of SQS are major foci of current research.

IDH1 gene transcription is sterol regulated and activated by SREBP-1a and SREBP-2 in human hepatoma HepG2 cells evidence that IDH1 may regulate lipogenesis in hepatic cells

Dietary vegetable oils and fish oils rich in PUFA (polyunsaturated fatty acids) exert hypocholesterolaemic and hypotriglyceridaemic effects in rodents. The plasma cholesterol-lowering properties of PUFA are due partly to a diminution of cholesterol synthesis and of the activity of the rate-limiting enzyme HMG-CoA reductase (3-hydroxy-3-methylglutaryl-CoA reductase). To better understand the mechanisms involved, we examined how tuna fish oil and individual n-3 and n-6 PUFA affect the expression of hepatic FPP synthase (farnesyl diphosphate synthase), a SREBP (sterol regulatory element-binding protein) target enzyme that is subject to negative-feedback regulation by sterols, in co-ordination with HMG-CoA reductase. Feeding mice on a tuna fish oil diet for 2 weeks decreased serum cholesterol and triacylglycerol levels, by 50% and 60% respectively. Hepatic levels of FPP synthase and HMG-CoA reductase mRNAs were also decreased, by 70% and 40% respectively. Individual n-3 and n-6 PUFA lowered FPP synthase and HMG-CoA reductase mRNA levels in H4IIEC3 rat hepatoma cells to a greater extent than did stearate and oleate, with the largest inhibitory effects occurring with arachidonate, EPA (eicosapentaenoic acid) and DHA (docosahexaenoic acid). We observed a similar inhibitory effect on protein levels of FPP synthase. The suppressive effect of PUFA on the FPP synthase mRNA level was not due to a decrease in mRNA stability, but to transcription inhibition. Moreover, a lower nuclear availability of both SREBP-1 and SREBP-2 mature forms was observed in HepG2 human hepatoblastoma cells treated with arachidonate, EPA or DHA. Taken together, these data suggest that PUFA can down-regulate hepatic cholesterol synthesis through inhibition of HMG-CoA reductase and FPP synthase, at least in part through impairment of the SREBP pathway.

Differential Transcriptional Regulation of the Human Squalene Synthase Gene by Sterol Regulatory Element-binding Proteins (SREBP) 1a and 2 and Involvement of 5′ DNA Sequence Elements in the Regulation

Several cues for cell proliferation, migration, and survival are transmitted through lipid rafts, membrane microdomains enriched in sphingolipids and cholesterol. Cells obtain cholesterol from the circulation but can also synthesize cholesterol de novo through the mevalonate/isoprenoid pathway. This pathway, however, has several branches and also produces non-sterol isoprenoids. Squalene synthase (SQS) is the enzyme that determines the switch toward sterol biosynthesis. Here we demonstrate that in prostate cancer cells SQS expression is enhanced by androgens, channeling intermediates of the mevalonate/isoprenoid pathway toward cholesterol synthesis. Interestingly, the resulting increase in de novo synthesis of cholesterol mainly affects the cholesterol content of lipid rafts, while leaving non-raft cholesterol levels unaffected. Conversely, RNA interference-mediated SQS inhibition results in a decrease of raft-associated cholesterol. These data show that SQS activity and de novo cholesterol synthesis are determinants of membrane microdomain-associated cholesterol in cancer cells. Remarkably, SQS knock down also attenuates proliferation and induces death of prostate cancer cells. Similar effects are observed when cancer cells are treated with the chemical SQS inhibitor zaragozic acid A. Importantly, although the anti-tumor effect of statins has previously been attributed to inhibition of protein isoprenylation, the present study shows that specific inhibition of the cholesterol biosynthesis branch of the mevalonate/isoprenoid pathway also induces cancer cell death. These findings significantly underscore the importance of de novo cholesterol synthesis for cancer cell biology and suggest that SQS is a potential novel target for antineoplastic intervention.

Androgens stimulate coordinated lipogenic gene expression in normal target tissues in vivo

The mRNA level for cytosolic NADP-dependent isocitrate dehydrogenase (IDH1) increases 2.3-fold, and enzyme activity of NADP-isocitrate dehydrogenase (IDH) 63%, in sterol-deprived HepG2 cells. The mRNA levels of the NADP- and NAD-dependent mitochondrial enzymes show limited or lack of regulation under the same conditions. Nucleotide sequences that are required, and sufficient, for the sterol regulation of transcription are located within a 67 bp region of an IDH1-secreted alkaline phosphatase promoter-reporter gene. The IDH1 promoter is fully activated by the expression of SREBP-1a in the cells and, to a lesser degree, by that of SREBP-2. A 5′-end truncation of 23 bp containing a CAAT and a GC-Box results in 6.5% residual activity. The promoter region involved in the activation by the sterol regulatory element binding proteins (SREBPs) is located at nucleotides −44 to −25. Mutagenesis analysis identified within this region the IDH1-SRE sequence element GTGGGCTGAG, which binds the SREBPs. Similar to the promoter activation, electrophoretic mobility shifts of probes containing the IDH1-SRE element exhibit preferential binding to SREBP-1a, as compared with SREBP-2. These results indicate that IDH1 activity is coordinately regulated with the cholesterol and fatty acid biosynthetic pathways and suggest that it is the source for the cytosolic NADPH required by these pathways.

Workshop Executive Summary Report: Post-Resuscitative and Initial Utility in Life Saving Efforts (PULSE) June 29–30, 2000; Lansdowne Resort and Conference Center; Leesburg, Va

Transcription of the human squalene synthase (HSS) gene is regulated by variations in the level of cellular cholesterol. Three regulatory elements in the HSS promoter region are known to be involved in the regulation: 1) a modified sterol regulatory element (SRE) 1 (HSS-SRE-1), 2) an inverted SRE-3 (Inv-SRE-3), 3) an inverted Y box (Inv-Y-Box). We report here the regulatory role of distinct cis-elements in the HSS promoter by using mutants of an HSS-luciferase promoter reporter. The activity of a wild-type promoter reporter transiently transfected into HepG-2 cells is increased by sterol depletion of the cells or by coexpression of mature forms of the SRE-binding proteins (SREBP) 1a and SREBP-2. Differential activation by SREBP-1a and SREBP-2 of the reporter gene mutated at various regions of the promoter is observed. Mutation of either the HSS-SRE-1 or the Inv-SRE-3 sequence diminished the activation by SREBP-1a and by sterol depletion but did not affect the activation by SREBP-2. Simultaneous mutations of both of these sequences almost completely abolished activation of the promoter by SREBP-1a or by sterol depletion, but activation by SREBP-2 was retained at 70%. Mutation of the Inv-Y-Box sequence element decreased the activity of the promoter by 50% or more, and if mutated together with both SREs, the activation was almost completely abolished. Mutation of any single GC box of the two located at −40 to −57 did not affect activity, whereas simultaneous mutation of the two decreased activation by SREBP-2 by 60%, by lipid depletion by 20%, and had no effect on the activation by SREBP-1a. A Y box motif at −159 to −166 and an SRE-like sequence element (SRE-1(8/10)) at position −101 to −108 are also involved in the sterol regulation. These results indicate that the complex sterol-mediated transcriptional regulation of the HSS gene is due to the presence of multiple copies of diverse cis elements in the HSS promoter. The differential activation of the HSS promoter may point to specific role of the SREBPs in cholesterogenesis.