Troy Beeler

Hydroxylation of Saccharomyces cerevisiae Ceramides Requires Sur2p and Scs7p

The Saccharomyces cerevisiae SCS7 andSUR2 genes are members of a gene family that encodes enzymes that desaturate or hydroxylate lipids. Sur2p is required for the hydroxylation of C-4 of the sphingoid moiety of ceramide, and Scs7p is required for the hydroxylation of the very long chain fatty acid. Neither SCS7 nor SUR2 are essential for growth, and lack of the Scs7p- or Sur2p-dependent hydroxylation does not prevent the synthesis of mannosyldiinositolphosphorylceramide, the mature sphingolipid found in yeast. Deletion of either gene suppresses the Ca2+-sensitive phenotype ofcsg2Δ mutants, which arises from overaccumulation of inositolphosphorylceramide due to a defect in sphingolipid mannosylation. Characterization of scs7 andsur2 mutants is expected to provide insight into the function of ceramide hydroxylation.

The Saccharomyces cerevisiae TSC10/YBR265w gene encoding 3-ketosphinganine reductase is identified in a screen for temperature-sensitive suppressors of the Ca2+-sensitive csg2Delta mutant.

Saccharomyces cerevisiae csg2Δmutants accumulate the sphingolipid inositolphosphorylceramide, which renders the cells Ca2+-sensitive. Temperature-sensitive mutations that suppress the Ca2+ sensitivity ofcsg2Δ mutants were isolated and characterized to identify genes that encode sphingolipid synthesis enzymes. Thesetemperature-sensitive csg2Δ suppressors (tsc) fall into 15 complementation groups. TheTSC10/YBR265w gene was found to encode 3-ketosphinganine reductase, the enzyme that catalyzes the second step in the synthesis of phytosphingosine, the long chain base found in yeast sphingolipids. 3-Ketosphinganine reductase (Tsc10p) is essential for growth in the absence of exogenous dihydrosphingosine or phytosphingosine. Tsc10p is a member of the short chain dehydrogenase/reductase protein family. The tsc10 mutants accumulate 3-ketosphinganine and microsomal membranes isolated fromtsc10 mutants have low 3-ketosphinganine reductase activity. His6-tagged Tsc10p was expressed inEscherichia coli and isolated by nickel-nitrilotriacetic acid column chromatography. The recombinant protein catalyzes the NADPH-dependent reduction of 3-ketosphinganine. These data indicate that Tsc10p is necessary and sufficient for catalyzing the NADPH-dependent reduction of 3-ketosphinganine to dihydrosphingosine.

SUR1 (CSG1 / BCL21), a gene necessary for growth of Saccharomyces cerevisiae in the presence of high Ca2+ concentrations at 37° C, is required for mannosylation of inositolphosphorylceramide

Saccharomyces cerevisiae cells require two genes, CSG1/SUR1 and CSG2, for growth in 50 mM Ca2+, but not 50 mM Sr2+. CSG2 was previously shown to be required for the mannosylation of inositol-phosphorylceramide (IPC) to form mannosylinositolphosphorylceramide (MIPC). Here we demonstrate that SUR1/CSG1 is both genetically and biochemically related to CSG2. Like CSG2, SUR1/CSG1 is required for IPC mannosylation. A 93–amino acid stretch of Csg1p shows 29% identity with the α-1, 6-mannosyltransferase encoded by OCH1. The SUR1/CSG1 gene is a dose-dependent suppressor of the Ca2+-sensitive phenotype of the csg2 mutant, but overexpression of CSG2 does not suppress the Ca2+ sensitivity of the csg1 mutant. The csg1 and csg2 mutants display normal growth in YPD, indicating that mannosylation of sphingolipids is not essential. Increased osmolarity of the growth medium increases the Ca2+ tolerance of csg1 and csg2 mutant cells, suggesting that altered cell wall synthesis causes Ca2+-induced death. Hydroxylation of IPC-C to form IPC-D requires CCC2, a gene encoding an intracellular Cu2+ transporter. Increased expression of CCC2 or increased Cu2+ concentration in the growth medium enhances the Ca2+ tolerance of csg1 mutants, suggesting that accumulation of IPC-C renders csg1 cells Ca2+ sensitive.

Synthesis of monohydroxylated inositolphosphorylceramide (IPC-C) in Saccharomyces cerevisiae requires Scs7p, a protein with both a cytochrome b5-like domain and a hydroxylase/desaturase domain

Saccharomyces cerevisiae mutants lacking Scs7p fail to accumulate the inositolphosphorylceramide (IPC) species, IPC‐C, which is the predominant form found in wild‐type cells. Instead scs7 mutants accumulate an IPC‐B species believed to be unhydroxylated on the amide‐linked C26‐fatty acid. Elimination of the SCS7 gene suppresses the Ca2+‐sensitive phenotype of csg1 and csg2 mutants. The CSG1 and CSG2 genes are required for mannosylation of IPC‐C and accumulation of IPC‐C by the csg mutants renders them Ca2+‐sensitive. The SCS7 gene encodes a protein that contains both a cytochrome b5‐like domain and a domain that resembles the family of cytochrome b5‐dependent enzymes that use iron and oxygen to catalyse desaturation or hydroxylation of fatty acids and sterols. Scs7p is therefore likely to be the enzyme that hydroxylates the C26‐fatty acid of IPC‐C.

Regulation of cellular Mg2+ by Saccharomyces cerevisiae

Regulation of cellular Mg2+ by S. cerevisiae was investigated. The minimal concentration of Mg2+ that results in optimal growth of S. cerevisiae is about 30 microM and a half-maximum growth rate is attained at about 5 microM Mg2+. Since the plasma membrane has an electrical potential greater than 100 mV, passive equilibration of Mg2+ across the plasma membrane would provide sufficient cytosolic Mg2+ (0.1-1 mM). The total cellular Mg2+ of cells grown in synthetic medium containing 1 mM Mg2+ is about 400 nmol/mg protein, most of which is bound to polyphosphate, nucleic acids, and ATP. Total cellular Mg2+ decreases to about 80 nmol/mg protein as the Mg2+ in synthetic growth medium is reduced to 0.02 mM, but remains relatively constant in growth medium containing 1 to 100 mM Mg2+. Cells shifted into Mg(2+)-free medium continue to grow by utilizing the vacuolar Mg2+ stores. Mg(2+)-starved cells replenish vacuolar Mg2+ stores with a halftime of 30 min. following the addition of 1 mM Mg2+ to the growth medium. The data indicate that cytosolic Mg2+ is maintained by the regulation of Mg2+ fluxes across both the vacuolar and plasma membranes.

Distribution of glucose transporters and insulin receptors in the plasma membrane and transverse tubules of skeletal muscle

The distribution of glucose transporters and of insulin receptors on the surface membranes of skeletal muscle was studied, using isolated plasma membranes and transverse tubule preparations. (i) Plasma membranes from rabbit skeletal muscle were prepared according to Seiler and Fleischer (1982, J. Biol. Chem. 257, 13862-13871), and transverse tubules from rabbit skeletal muscle were prepared according to Rosemblatt et al. (1981, J. Biol. Chem. 256, 8140-8148) as modified by Hidalgo et al. (1983, J. Biol. Chem. 258, 13937-13945). The membranes were identified by the abundance of nitrendipine receptors in the transverse tubules, and their relative absence from the plasma membranes. (ii) Plasma membranes and transverse tubules were also isolated from rat skeletal muscle, according to a novel procedure that isolates both fractions from the same common homogenate. (iii) Glucose transporters were detected by D-glucose protectable binding of the specific inhibitor [3H]cytochalasin B, and insulin receptors were detected by saturable binding of 125I-insulin. The concentration of glucose transporters was about threefold (rabbit) or fivefold (rat) higher in the transverse tubule membrane compared to the plasma membrane, whereas the insulin receptor concentration was about the same in both membranes. These results indicate that the glucose transporters on the surface of the muscle are preferentially segregated to the transverse tubules, and this poses interesting consequences on the functional response of glucose transport to insulin in skeletal muscle.

Effect of halothane on Ca2+-induced Ca2+ release from sarcoplasmic reticulum vesicles isolated from rat skeletal muscle

Halothane induces the release of Ca2+ from a subpopulation of sarcoplasmic reticulum vesicles that are derived from the terminal cisternae of rat skeletal muscle. Halothane-induced Ca2+ release appears to be an enhancement of Ca2+-induced Ca2+ release. The low-density sarcoplasmic reticulum vesicles which are believed to be derived from nonjunctional sarcoplasmic reticulum lack the capability of both Ca2+-induced and halothane-induced Ca2+ release. Ca2+ release from terminal cisternae vesicles induced by halothane is inhibited by Ruthenium red and Mg2+, and require ATP (or an ATP analogue), KCl (or similar salt) and extravesicular Ca2+. Ca2+-induced Ca2+ release has similar characteristics.

Comparison of the rat microsomal Mg-ATPase of various tissues.

The microsomal Mg-ATPase from various rat tissues was compared. After fractionating the microsomal vesicles by sucrose gradient centrifugation, the highest specific activity of the Mg-ATPase was found in the low-density vesicles which contained plasma membrane. A large fraction (25-90%) of the microsomal Ca-independent Mg-ATPase found in each tissue had the following properties: (1) the Km for ATP was 0.2 mM; (2) the rate of ATP hydrolysis by the Mg-ATPase was nonlinear due to an ATP-stimulated inactivation of the enzyme; (3) wheat germ agglutinin, concanavalin A, glutaraldehyde, and antiserum prevented inactivation induced by ATP or AdoPP[NH]P; (4) detergents at relatively low detergent:protein ratios increased the rate of inactivation with little change in the initial rate of ATP hydrolysis; (5) the Mg-ATPase was inactivated by irradiation in the presence of 8-azido ATP. (6) in addition to ATP, the Mg-ATPase was able to hydrolyze CTP, GTP, UTP, ITP, and GTP but was unable to hydrolyze any of the 10 nonnucleotide phosphocompounds which were tested; (7) the bivalent cation requirement of the Mg-ATPase could be provided by Mg2+, Ca2+, Mn2+, Zn2+, or Co2+ but the enzyme was inactive in the presence of Cu2+, Sr2+, Ba2+, or Be2+; (8) the Mg-ATPase activity was not altered by ionophores or inhibitors of the Na,K-ATPase, the Ca,Mg-ATPase or the mitochondrial F1ATPase. These data suggest that a major portion of the microsomal, basal Mg-ATPase activity is due to one unique enzyme found in most if not all tissues.

Activation and inhibition of the sarcoplasmic reticulum Ca2+ channel by the polycationic dyes Hoechst 33342 and Hoechst 33258.

The polycationic dyes, Hoechst 33342 (Bisbenzimide,2′-(4-ethoxyphenyl)-5-(4-methyl-1-piperazinyl) 2,5′-bi 1H benzimidazole) and Hoechst 33258 (Bisbenzimide,2′-(4-hydroxyphenyl) 5-(4-methyl-1-piperazinyl)-2,5′-bi-1H-benzimidazole) alter the activity of the sarcoplasmic reticulum Ca2+ channel. Although they act competitively, Hoechst 33342 decreases, while Hoechst 33258 increases, the rate of channel-mediated Ca2+ efflux from junctional sarcoplasmic reticulum vesicles. Unlike other cationic sarcoplasmic reticulum Ca2+ channel antagonists, Hoechst 33342 blocks the ryanodine-activated Ca2+ channel. Both Hoechst 33342 and Hoechst 33258 inhibit the channel incorporated into the planar lipid bilayer. Since the only structural difference between the two dyes is that the agonist Hoechst 33258 has a hydroxy group where the antagonist Hoechst 33342 has an ethoxy group, it is possible that the more hydrophobic, bulky ethoxy group blocks Ca2+ movement through the channel, whereas the hydroxy group only reduces the rate of Ca2+ movement.The opinions or assertions contained herein are private ones of the author ad are not to beconstrued as official or reflecting the views of the Department of Defense or the Uniformed Services University of the Health Sciences.

Effect of Na3VO4 and membrane potential on the structure of sarcoplasmic reticulum membrane

SummaryTwo-dimensional crystalline arrays of Ca2+-ATPase molecules develop after treatment of sarcoplasmic reticulum vesicles with Na3VO4 in a Ca2+-free medium. The influence of membrane potential upon the rate of crystallization was studied by ion substitution using oxonol VI and 3,3′-diethyl-2,2′-thiadicarbocyanine (Di−S−C2(5)) to monitor inside positive or inside negative membrane, potentials, respectively. Positive transmembrane potential accelerates the rate of crystallization of Ca2+-ATPase, while negative potential disrupts preformed Ca2+-ATPase crystals, suggesting an influence of transmembrane potential upon the conformation of Ca2+-ATPase.