3-Hydroxy-3-methylglutaryl coenzyme A reductase in the sea urchin embryo is developmentally regulated

The activity of 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA) reductase, an enzyme which plays a regulatory role in the synthesis of cholesterol, dolichol, and coenzyme Q, has been measured in the developing embryo of the sea urchin. Enzyme activity increased at least 200-fold during development from the unfertilized egg to the pluteus stage embryo. Mixing experiments suggested that the low level of enzyme activity found at early stages was not due to the presence of inhibitor(s) in the egg or zygote. The enzyme in the sea urchin embryo exhibited properties different from that found in mammals: only a fraction of the activity could be solubilized from microsomes, and mild trypsinization inactivated the enzyme without releasing any of it from the microsomes in soluble form. To further study the sea urchin HMG-CoA reductase, a genomic clone was identified by hybridization to a cDNA encoding hamster HMG-CoA reductase. Sequence analysis of this clone revealed a coding region that shares a high degree of homology with the carboxyl-terminal domain of hamster HMG-CoA reductase. Analysis of sea urchin embryo HMG-CoA reductase mRNA levels using a restriction fragment derived from the genomic clone revealed a 5.5-kilobase poly(A)+ mRNA that increased 15-fold during development from the egg to the gastrula stage and then decreased 1.5-fold at the pluteus stage. Since the relative increase in HMG-CoA reductase mRNA was less than the increase in enzyme activity (15-fold versus 200-fold) factors in addition to the level of mRNA may control the activity of this enzyme during embryogenesis.     

Role of mevalonate in regulation of cholesterol synthesis and 3-hydroxy-3-methylglutaryl coenzyme A reductase in cultured cells and their cytoplasts

H4-II-E-C3 hepatoma cells in culture respond to lipid-depleted media and to mevinolin with increased sterol synthesis from [14C]acetate and rise of 3-hydroxy-3-methylglutaryl coenzyme A reductase levels. Mevalonate at 4 mM concentration represses sterol synthesis and the reductase, and completely abolishes the effects of mevinolin. Mevalonate has little or no effect on sterol synthesis or reductase in enucleated hepatoma cells (cytoplasts) or on reductase in cytoplasts of cultured Chinese hamster ovary (CHO) cells. The sterol-synthesizing system of hepatoma cell cytoplasts and the reductase in the cytoplasts of CHO cells were completely stable for at least 4 hr. While reductase levels and sterol synthesis from acetate followed parallel courses, the effects on sterol synthesis--both increases and decreases--exceeded those on reductase. In vitro translation of hepatoma cell poly(A)+RNAs under various culture conditions gave an immunoprecipitable polypeptide with a mass of 97,000 daltons. The poly(A)+RNA from cells exposed for 24 hr to lipid-depleted media plus mevinolin (1 microgram/ml) contained 2.8 to 3.6 times more reductase-specific mRNA than that of cells kept in full-growth medium, or cells exposed to lipid-depleted media plus mevinolin plus mevalonate. Northern blot hybridization of H4 cell poly(A)+RNAs with [32P]cDNA to the reductase of CHO cells gave two 32P-labeled bands of 4.6 and 4.2 K-bases of relative intensities 1.0, 0.61-1.1, 2.56, and 1.79 from cells kept, respectively, in full-growth medium, lipid-depleted medium plus mevinolin plus mevalonate, lipid-depleted medium plus mevinolin, and lipid-depleted medium. These values approximate the reductase levels of these cells. We conclude that mevalonate suppresses cholesterol biosynthesis in part by being a source of a product that decreases the level of reductase-specific mRNA.     

Alteration of sea urchin embryo cell surface properties by mycostatin, a sterol binding antibiotic

Sea urchin embryos incubated in sea water containing mycostatin (MST), a polyene antibiotic, dissociate into single cells. Reaggregation of dissociated sea urchin embryo cells, and uptake of labeled precursors by these cells are also greatly inhibited although O₂ consumption is only slightly affected by this compound. It is known that mycostatin binds primarily to membrane sterols and affects only cells containing membrane sterols. Sea urchin cell membranes contain sterols. The effects of mycostatin on cell adhesion, reaggregation, and permeability seen in this study may be a result of an interaction with cell membrane sterols or sterol-associated molecules.     

The small subunit of ribonucleotide reductase is encoded by one of the most abundant translationally regulated maternal RNAs in clam and sea urchin eggs

In both clam oocytes and sea urchin eggs, fertilization triggers the synthesis of a set of proteins specified by stored maternal mRNAs. One of the most abundant of these (p41) has a molecular weight of 41,000. This paper describes the identification of p41 as the small subunit of ribonucleotide reductase, the enzyme that provides the precursors necessary for DNA synthesis. This identification is based mainly on the amino acid sequence deduced from cDNA clones corresponding to p41, which shows homology with a gene in Herpes Simplex virus that is thought to encode the small subunit of viral ribonucleotide reductase. Comparison with the B2 (small) subunit of Escherichia coli ribonucleotide reductase also shows striking homology in certain conserved regions of the molecule. However, our attention was originally drawn to protein p41 because it was specifically retained by an affinity column bearing the monoclonal antibody YL 1/2, which reacts with alpha-tubulin (Kilmartin, J. V., B. Wright, and C. Milstein, 1982, J. Cell Biol., 93:576-582). The finding that this antibody inhibits the activity of sea urchin embryo ribonucleotide reductase confirmed the identity of p41 as the small subunit. The unexpected binding of the small subunit of ribonucleotide reductase can be accounted for by its carboxy-terminal sequence, which matches the specificity requirements of YL 1/2 as determined by Wehland et al. (Wehland, J., H. C. Schroeder, and K. Weber, 1984, EMBO [Eur. Mol. Biol. Organ.] J., 3:1295-1300). Unlike the small subunit, there is no sign of synthesis of a corresponding large subunit of ribonucleotide reductase after fertilization. Since most enzymes of this type require two subunits for activity, we suspect that the unfertilized oocytes contain a stockpile of large subunits ready for combination with newly made small subunits. Thus, synthesis of the small subunit of ribonucleotide reductase represents a very clear example of the developmental regulation of enzyme activity by control of gene expression at the level of translation.     

Cloning of cDNA encoding the membrane-bound form of bovine beta 1,4-galactosyltransferase

UDPgalactose: N-acetyl-D-glucosamine 4-beta-D-galactosyltransferase (EC 2.4.1.38) (GalT) is a Golgi-membrane-bound enzyme that participates in the biosynthesis of the oligosaccharide structures of glycoproteins and glycolipids. Synthetic DNA oligomers representing segments of the published partial cDNA sequence for bovine GalT were used as molecular probes to isolate from bovine-liver cDNA libraries overlapping cDNA clones that span 1728 nucleotides and potentially code for the entire polypeptide chain of bovine galactosyltransferase. The cDNA sequence for bovine GalT reveals a 1206-base-pair open reading frame that codes for 402 amino acids, including a presumptive N-terminal membrane anchoring domain of 20 hydrophobic amino acids. The colinearity between the cDNA sequence and 29 non-overlapping amino acid residues which were positively identified by N-terminal sequencing of two polypeptides isolated from the soluble form of the enzyme was consistent with the translation frame and confirmed the authenticity of the cDNA clones. The finding of an N-terminal hydrophobic segment which serves as the membrane anchor and signal sequence suggests that the C-terminal region of the GalT polypeptide is oriented within the lumen of the Golgi membranes. This conclusion is in agreement with previous biochemical studies which indicated that the 51-kDa and 42-kDa soluble forms of the enzyme which encompass the C-terminal 324 and 297 amino acid residues of the entire GalT polypeptide, respectively, include the catalytic site.     

Hmg-coA reductase gene family in cotton (Gossypium hirsutum L.): unique structural features and differential expression of hmg2 potentially associated with synthesis of specific isoprenoids in developing embryos.

As a first step towards understanding the biosynthesis of isoprenoids that accumulate in specialized pigment glands of cotton at the molecular level, two full-length genes (hmg1 and hmg2) were characterized encoding hmg-coA reductase (HMGR; EC 1.1.1.34), the enzyme that catalyzes the formation of a key isoprenoid precursor. Cotton hmgr genes exhibited features typical of other plant genes, however, hmg2 encodes the largest of all plant HMGR enzymes described to date. HMG2 contains several novel features that may represent functional specialization of this particular HMGR isoform. Such features include a unique 42 amino acid sequence located in the region separating the N-terminal domain and C-terminal catalytic domain, as well as an N-terminal hydrophobic domain that is not found in HMG1 or other HMGR enzymes. DNA blot analysis revealed that hmg1 and hmg2 belong to small subfamilies that probably include homeologous loci in allotetraploid cotton (Gossypium hirsutum L.). Ribonuclease protection assays revealed that hmg1 and hmg2 are differentially expressed in a developmentally- and spatially-modulated manner during morphogenesis of specialized terpenoid-containing pigment glands in embryos. Induced expression of hmg2 coincided with a possible commitment to sesquiterpenoid biosynthesis in developing embryos, although other developmental processes also requiring HMGR cannot be excluded.     

Inhibition of a plant sesquiterpene cyclase by mevinolin

The specificity of mevinolin as an inhibitor of sterol and sesquiterpene metabolism in tobacco cell suspension cultures was examined. Exogenous mevinolin inhibited [14C]acetate, but not [3H]mevalonate incorporation into free sterols. In contrast, mevinolin inhibited the incorporation of both [14C]acetate and [3H]mevalonate into capsidiol, an extracellular sesquiterpene. Microsomal 3-hydroxy-3-methylglutaryl Coenzyme A reductase was inhibited greater than 90% by microM mevinolin, while squalene synthetase was insensitive to even 600 microM mevinolin. Sesquiterpene cyclase, the first branch point enzyme specific for sesquiterpene biosynthesis, was inhibited in a dose-dependent manner by mevinolin with a 50% reduction in activity at 100 microM. Kinetic analysis indicated that the mechanism for inhibition was complex with mevinolin acting as both a competitive and noncompetitive inhibitor. The results suggest that the mevinolin inhibition of [3H]mevalonate incorporation into extracellular sesquiterpenes can, in part, be attributed to a secondary, but specific, site of inhibition, the sesquiterpene cyclase.     

Partial deletion of membrane-bound domain of 3-hydroxy-3-methylglutaryl coenzyme A reductase eliminates sterol-enhanced degradation and prevents formation of crystalloid endoplasmic reticulum

3-Hydroxy-3-methylglutaryl coenzyme A (HMG CoA) reductase is anchored to the endoplasmic reticulum (ER) membrane by a hydrophobic NH2-terminal domain that contains seven apparent membrane-spanning regions and a single N-linked carbohydrate chain. The catalytic domain, which includes the COOH-terminal two-thirds of the protein, extends into the cytoplasm. The enzyme is normally degraded with a rapid half-life (2 h), but when cells are depleted of cholesterol, its half-life is prolonged to 11 h. Addition of sterols accelerates degradation by fivefold. To explore the requirements for regulated degradation, we prepared expressible reductase cDNAs from which we either deleted two contiguous membrane-spanning regions (numbers 4 and 5) or abolished the single site for N-linked glycosylation. When expressed in hamster cells after transfection, both enzymes retained catalytic activity. The deletion-bearing enzyme continued to be degraded with a rapid half-life in the presence of sterols, but it no longer was stabilized when sterols were depleted. The glycosylation-minus enzyme was degraded at a normal rate and was stabilized normally by sterol deprivation. When cells were induced to overexpress the deletion-bearing enzyme, they did not incorporate it into neatly arranged crystalloid ER tubules, as occurred with the normal and carbohydrate-minus enzymes. Rather, the deletion-bearing enzyme was incorporated into hypertrophied but disordered sheets of ER membrane. We conclude that the carbohydrate component of HMG CoA reductase is not required for proper subcellular localization or regulated degradation. In contrast, the native structure of the transmembrane component is required to form a normal crystalloid ER and to allow the enzyme to undergo regulated degradation by sterols.     

The primary structure of the iron-sulfur subunit of ubiquinol-cytochrome c reductase from Neurospora, determined by cDNA and gene sequencing

The primary structure of the iron-sulfur subunit of ubiquinol-cytochrome c reductase from Neurospora mitochondria was determined by cDNA and genomic DNA sequencing. A first cDNA was identified from a cDNA bank cloned in Escherichia coli by hybridization selection of mRNA, cell-free protein synthesis and immunoadsorption. Further cDNA and geonomic DNA were identified by colony filter hybridization. The N-terminal sequence of the mature protein was determined by automated Edman degradation. From the sequence a molecular mass of 24749 Da results for the precursor protein and of 21556 Da for the mature protein. The presequence consists of 32 amino acids with four arginines as the only charged residues. The mature protein consists of 199 amino acids. It is characterized by a small N-terminal hydrophilic part of 29 residues, a hydrophobic stretch of 25 residues and a large C-terminal hydrophilic domain of 145 residues. The only four cysteines of the protein, which are assumed to bind the 2 Fe-2S cluster, are located in a moderate hydrophobic region of this large domain. Cysteines 3 and 4 are unusually arranged in that they are separated by only one proline. From sequence data the arrangement of the subunit in the membrane is deduced.     

Characterization of human sterol 27-hydroxylase. A mitochondrial cytochrome P-450 that catalyzes multiple oxidation reaction in bile acid biosynthesis.

The enzyme sterol 27-hydroxylase catalyzes the first step in the oxidation of the side chain of sterol intermediates in the bile acid synthesis pathway. Human sterol 27-hydroxylase cDNAs were isolated from a liver cDNA library by cross-hybridization with a previously cloned rabbit cDNA probe. DNA sequence analysis of hybridization-positive clones predicted a human sterol 27-hydroxylase consisting of a 33-amino-acid mitochondrial signal sequence followed by a mature protein of 498 amino acids. RNA blotting experiments demonstrated sterol 27-hydroxylase mRNAs of approximately 1.8 to 2.2 kilobases in liver and fibroblast cells. The steady state levels of the mRNA did not change when cultured cells were grown in the presence or absence of sterols. Introduction of the sterol 27-hydroxylase cDNA into Simian COS cells resulted in the expression of active enzyme capable of catalyzing multiple oxidation reactions (R-CH3----R-CH2OH----R-COOH) at carbon 27 of sterol intermediates of the bile acid synthesis pathway.     

The toposome, essential for sea urchin cell adhesion and development, is a modified iron-less calcium-binding transferrin

We describe the structure and function of the toposome, a modified calcium-binding, iron-less transferrin, the first member of a new class of cell adhesion proteins. In addition to the amino acid sequence of the precursor, we determined by Edman degradation the N-terminal amino acid sequences of the mature hexameric glycoprotein present in the egg as well as that of its derived proteolytically modified fragments necessary for development beyond the blastula stage. The approximate C-termini of the fragments were determined by a combination of mass spectrometry and migration in reducing gels before and after deglycosylation. This new member of the transferrin family shows special features which explain its evolutionary adaptation to development and adhesive function in sea urchin embryos: (i) a protease-inhibiting WAP domain, (ii) a 280 amino acid cysteine-less insertion in the C-terminal lobe, and (iii) a 240 residue C-terminal extension with a modified cystine knot motif found in multisubunit external cell surface glycoproteins. Proteolytic removal of the N-terminal WAP domain generates the mature toposome present in the oocyte. The modified cystine knot motif stabilizes cell-bound trimers upon Ca-dependent dissociation of hexamer-linked cells. We determined the positions of the developmentally regulated cuts in the cysteine-less insertion, which produce the fragments observed previously. These fragments remain bound to the hexameric 22S particle in vivo and are released only after treatment of the purified toposome with reducing agents. In addition, some soluble smaller fragments with possible signal function are produced. Sequence comparison of five sea urchin species reveals the location of the cell-cell contact site targeted by the species-specific embryo dissociating antibodies. The evolutionary tree of 2-, 1-, and 0-ferric transferrins implies their evolution from a basic cation-activated allosteric design modified to serve multiple functions.     

Human 3-hydroxy-3-methylglutaryl coenzyme A reductase. Conserved domains responsible for catalytic activity and sterol-regulated degradation

A full length cDNA for human 3-hydroxy-3-methylglutaryl coenzyme A reductase, the membrane-bound glycoprotein that regulates cholesterol synthesis, was isolated from a human fetal adrenal cDNA library. The nucleotide sequence of this cDNA shows that the human reductase is 888 amino acids long and shares a high degree of homology with the hamster enzyme. The amino-terminal membrane-bound domain is the most conserved region between the two species (7 substitutions out of 339 amino acids). This region, which is predicted to span the endoplasmic reticulum membrane seven times, mediates accelerated degradation of reductase in the presence of sterols. The carboxyl-terminal catalytic domain is also highly conserved (22 substitutions out of 439 amino acids). However, the linker region between these two domains has diverged (32 substitutions out of 110 amino acids). Conservation of the structure of the membrane-bound domain in HMG-CoA reductase supports the hypothesis that sterol-regulated degradation is an important mechanism for suppression of reductase activity and for regulation of cholesterol metabolism in humans as well as in hamsters.     

Conservation of the WD-repeat, microtubule-binding protein, EMAP, in sea urchins, humans, and the nematode C. elegans

The echinoderm microtubule-associated protein (EMAP) is the most abundant microtubule-binding protein in the first cleavage mitotic apparatus in sea urchin embryos. The first goal of this study was to determine whether there is sufficient EMAP in the egg and embryo to modify microtubule dynamics during the early cleavages divisions and whether EMAP functions at a specific time or place in the embryo. To accomplish this goal, we examined the relative abundance, tissue distribution, and temporal pattern of EMAP expression during embryonic development. The second goal of this study was to identify important functional domains within the EMAP coding sequence. A conserved sequence might reveal a potential microtubule-binding domain. We cloned, sequenced and compared overlapping EMAP cDNAs from two different sea urchin species that diverged approximately 80 million years ago, and compared these with cDNA sequences from a vertebrate and nematode species. From quantitative immunoblots, we determined the EMAP concentration in eggs to be 4 μM. The steady-state levels of EMAP mRNA and protein accumulated during development, and all three germ layers expressed EMAP. During the early stages of development, EMAP and tubulin were both abundant in the ectoderm, mesoderm and endoderm. However, during late gastrulation and the formation of the early pluteus larvae, EMAP was enriched in the mesoderm, while tubulin staining was most abundant in the archenteron. These results indicate that EMAP may have tissue-specific functions in the late stage embryo. To identify conserved functional domains, we compared the predicted amino acid sequence encoded by Strongylocentrotus purpuratus and Lytechinus variegatus EMAP cDNAs, and determined that these two sea urchin EMAPs were 95% conserved and shared an identical domain organization. A parsimonious analysis of these sea urchin protein sequences, as well as human and C. elegans EMAP sequences was used to construct a gene tree. Together these results suggest that EMAP is an important microtubule protein required at all developmental stages of sea urchins, and whose cellular function may be conserved amongst metazoans. Received: 2 March 1999 / Accepted: 28 June 1999     

Preimplantation mouse embryos synthesize membrane sterols

The total cholesterol content of preimplantation mouse embryos increases approximately threefold (to 1 pmole) during the development of a blastocyst from a fertilized egg. From the two-cell stage onwards embryos are capable of converting [³H]mevalonate into the membrane sterols lanosterol and cholesterol. However, activity of the ratelimiting enzyme in sterol synthesis, hydroxymethylglutaryl coenzyme A reductase, was only measurable in late expanded blastocysts. These estimates of cholesterol content and the amounts of ³H-sterol formed suggest that the preimplantation mouse embryo can synthesize membrane sterols from early cleavage stages onwards. Late compaction and early fluid accumulation (approx. 84 hr post-hCG) are associated with a transition from lanosterol to cholesterol synthesis. The possible relationship between this transition and changes in the properties of embryo membranes which occur at this time is discussed. The results, taken together with previous evidence for phospholipid synthesis in early embryos, demonstrate that the preimplantation mouse embryo is capable of synthesizing major membrane lipids and hence has the potential for assembling cell membranes and modulating their lipid-mediated properties.