Distribution and transport of cholesterol in Caenorhabditis elegans.

Cholesterol transport is an essential process in all multicellular organisms. In this study we applied two recently developed approaches to investigate the distribution and molecular mechanisms of cholesterol transport in Caenorhabditis elegans. The distribution of cholesterol in living worms was studied by imaging its fluorescent analog, dehydroergosterol, which we applied to the animals by feeding. Dehydroergosterol accumulates primarily in the pharynx, nerve ring, excretory gland cell, and gut of L1-L3 larvae. Later, the bulk of dehydroergosterol accumulates in oocytes and spermatozoa. Males display exceptionally strong labeling of spermatids, which suggests a possible role for cholesterol in sperm development. In a complementary approach, we used a photoactivatable cholesterol analog to identify cholesterol-binding proteins in C. elegans. Three major and several minor proteins were found specifically cross-linked to photocholesterol after UV irradiation. The major proteins were identified as vitellogenins. rme-2 mutants, which lack the vitellogenin receptor, fail to accumulate dehydroergosterol in oocytes and embryos and instead accumulate dehydroergosterol in the body cavity along with vitellogenin. Thus, uptake of cholesterol by C. elegans oocytes occurs via an endocytotic pathway involving yolk proteins. The pathway is a likely evolutionary ancestor of mammalian cholesterol transport.

Mammalian homologues of C. elegans PAR-1 are asymmetrically localized in epithelial cells and may influence their polarity.

The establishment of polarity in the embryo is fundamental for the correct development of an organism [1]. The first cleavage of the Caenorhabditis elegans embryo is asymmetric with certain cytoplasmic components being distributed unequally between the daughter cells [2-4]. Using a genetic screen, Kemphues and co-workers have identified six par genes (partition-defective) [5,6], which are involved in the process of asymmetric division. One of these genes encodes a highly conserved protein, PAR-1, which is a serine/threonine kinase that localizes asymmetrically to the posterior part of the zygote and to those blastocysts that give rise to the germ line [7-9]. We reasoned that the mammalian homologue of PAR-1 (mPAR-1) might be involved in the process of polarization of epithelial cells, which consist of apical and basolateral membrane domains. We found that mPAR-1 was expressed in a wide variety of epithelial tissues and cell lines and was associated with the cellular cortex. In polarized epithelial cells, mPAR-1 was asymmetrically localized to the lateral domain. A fusion protein lacking the kinase domain had the same localization as the full-length protein but its prolonged expression acted in a dominant-negative fashion: lateral adhesion of the transfected cells to neighbouring cells was diminished, resulting in the former cells being 'squeezed out' from the monolayer. Moreover, the polarity of these cells was disturbed resulting in mislocalization of E-cadherin. Thus, in the C. elegans embryo and in epithelial cells, polarity appears to be governed by similar mechanisms.

VIP21-caveolin, a membrane protein constituent of the caveolar coat, oligomerizes in vivo and in vitro.

VIP21-caveolin is a membrane protein, proposed to be a component of the striated coat covering the cytoplasmic surface of caveolae. To investigate the biochemical composition of the caveolar coat, we used our previous observation that VIP21-caveolin is present in large complexes and insoluble in the detergents CHAPS or Triton X-114. The mild treatment of these insoluble structures with sodium dodecyl sulfate leads to the detection of high molecular mass complexes of approximately 200, 400, and 600 kDa. The 400-kDa complex purified to homogeneity from dog lung is shown to consist exclusive of the two isoforms of VIP21-caveolin. Pulse-chase experiments indicate that the oligomers form early after the protein is synthesized in the endoplasmic reticulum (ER). VIP21-caveolin does indeed insert into the ER membrane through the classical translocation machinery. Its hydrophobic domain adopts an unusual loop configuration exposing the N- and C-flanking regions to the cytoplasm. Similar high molecular mass complexes can be produced from the in vitro-synthesized VIP21-caveolin. The complex formation occurs only if VIP21-caveolin isoforms are properly inserted into the membrane; formation is cytosol-dependent and does not involve a vesicle fusion step. We propose that high molecular mass oligomers of VIP21-caveolin represent the basic units forming the caveolar coat. They are formed in the ER and later, between the ER and the plasma membrane, these oligomers could associate into larger detergent-insoluble structures.

Identification of proteins of the 40 S ribosomal subunit involved in interaction with initiation factor eIF-2 in the quaternary initiation complex by means of monospecific antibodies.

Monospecific polyclonal antibodies against seven proteins of the 40 S subunit of rat liver ribosomes were used to identify ribosomal proteins involved in interaction with initiation factor eIF-2 in the quaternary initiation complex [eIF-2 X GMPPCP X [3H]Met-tRNAf X 40 S ribosomal subunit]. Dimeric immune complexes of 40 S subunits mediated by antibodies against ribosomal proteins S3a, S13/16, S19 and S24 were found to be unable to bind the ternary initiation complex [eIF-2 X GMPPCP X [3H]Met-tRNAf]. In contrast, 40 S dimers mediated by antibodies against proteins S2, S3 and S17 were found to bind the ternary complex. Therefore, from the ribosomal proteins tested, only proteins S3a, S13/16, S19 and S24 are concluded to be involved in eIF-2 binding to the 40 S subunit.

Shape and location of eukaryotic initiation factor eIF-2 on the 40S ribosomal subunit of rat liver. Immunoelectron-microscopic and hydrodynamic investigations.

The location of initiation factor eIF-2 and of its subunits in quaternary initiation complexes (40S-ribosomal-subunit.eIF-2. GuoPP[CH2]P.Met-tRNAf) was investigated by immunoelectron microscopy. Quaternary complexes were fixed with glutaraldehyde and reacted with affinity-purified polyclonal antibodies against eIF-2 alpha, eIF-2 beta or eIF-2 gamma. The dimeric immune complexes obtained by sucrose gradient centrifugation were investigated electron microscopically after negative staining. Antibody-binding sites were observed on the interface side of the 40S ribosomal subunit in the region between the 'head' and the 'body' (neck region) of the 40S ribosomal subunit. Within this region, eIF-2 alpha points to the rear side, whereas eIF-2 beta and eIF-2 gamma point to the frontal side of the 40S subunit indicating an elongated shape of eIF-2 about 15 nm long. By analytical ultracentrifugation of isolated eIF-2 the sedimentation and diffusion coefficients were determined to be 6.54 S and 4.74 x 10(-7) cm2/s respectively. From these data, a molar mass of 122.4 kg/mol and a dry volume of 147.4 nm3 were calculated. For the shape of eIF-2 a prolate ellipsoid of revolution is assumed with a maximal length of about 15 nm and with an axial ratio of about 1:3.5. This conclusion is further confirmed by a calculated frictional ratio of 1.37 and a Stokes radius of about 4.54 nm.

Structure of initiation factor eIF-3 from rat liver. Hydrodynamic and electron microscopic investigations.

On the basis of hydrodynamic, electron microscopic and biochemical investigations a new model of the structure of initiation factor eIF-3 is proposed. From sedimentation and diffusion coefficients of 16.35 S and 2.13 X 10(-7) cm2/s, respectively, as well as from sedimentation equilibrium measurements, a molecular mass of about 650 kDa was determined for isolated eIF-3. This is in agreement with molecular mass estimations by sodium dodecyl sulphate gel electrophoresis. A partial specific volume of 0.723 cm3/g was determined by means of the amino acid composition and the specific volume increments of the amino acids. From this value and from the molecular mass, a volume of 780 nm3 was calculated for eIF-3. In electron micrographs of isolated eIF-3, images with triangular profiles and side lengths of 14 nm, 16 nm, and 17 nm have been observed. Taking into account the calculated volume and considering the triangular image as one face of the particle, it is suggested that eIF-3 has the shape of a flat triangular prism with a height of about 7 nm and the above-mentioned side-lengths. This model is in agreement with results of electron microscopic investigations of eIF-3 in native small ribosomal subunits [Lutsch, G., Benndorf, R., Westermann, P., Bommer, U.-A. & Bielka, H. (1986) Eur. J. Cell Biol. 40/2, in press]. The high frictional ratio of about 1.7 also supports eIF-3 to be rather of a flat than of a globular shape.

Phosphorylation of ribosomal proteins as a possible control system for protein synthesis. Binding of Met-tRNAf to 40 S ribosomal subunits.

The evidence that protein S6 of rat liver ribosomes is involved in P-site functions and that this protein is the main target of the small subunit for in vivo phosphorylation suggests that S6 phosphorylation may contribute to the regulation of protein synthesis. Therefore, we have studied the activity of small ribosomal subunits with unphosphorylated and phosphorylated protein S6 in Met-tRNAf binding. The results described in this paper show that at least under in vitro conditions S6 phosphorylation does obviously not influence the activity of small ribosomal subunits for eIF-2 dependent binding of initiator-tRNA.

Preparation and properties of a Met-tRNAf binding factor from rat liver and rat hepatoma.

A Met-tRNAf binding factor (IF-2) from the microsomal fraction of rat liver and rat hepatoma ascites cells was partially purified by ammonium sulphate fractionation, DEAE-cellulose and phosphocellulose chromatography. The factor binds [3H]Met-tRNAf only in the presence of either GTP or GMPPCP. Maximal binding takes place at 37 degrees C and in the absence of Mg++. The factor is specific for Met-tRNAf and does not bind Phe-tRNA from rat liver or from E. coli. The ternary complex [Met-tRNAf . IF-2 . GTP1 binds to 40 S ribosomal subunits from rat liver in the absence of mRNA or poly(A, G, U) without GTP hydrolysis. GDP as well as aurintricarboxylic acid inhibit the ternary complex formation. Both factors are rapidly inactivated by N-ethylmaleimide treatment and by preincubation at 45 degrees C. Heat inactivation is partially prevented by GTP and GDP. With regard to the functional properties there are no significant differences between IF-2 from normal liver and hepatoma cells. On the other hand heat denaturation compared to the rat liver factor, which may be due to differences in contaminating proteins.

[Age dependent changes of biosynthesis of proteins (author's transl)]. / Zur Altersabhängigkeit der Proteinbiosynthese

The activity of KC1-washed ribosomes from the liver and the kidney of rats in a poly(U) dependent cell free system with [3H]-phe-tRNA as phenylalanine donor is highly increased by the cytosolic fraction from liver, brain, kidney and testicles. The activity of the cell sap of these tissues decreases significantly with increasing age of the rats from which the cytosolic fractions were prepared. Ribosomes do not undergo age dependent alterations with regard to their activity in poly(U) systems supported by cell sap from rat liver. The results are discussed with regard to age dependent change of the content of cytosolic translation factors.