Regulation of Paramecium primaurelia glycosylphosphatidyl-inositol biosynthesis via dolichol phosphate mannose synthesis.

A set of glycosylinositol-phosphoceramides, belonging to a family of glycosylphosphatidyl-inositols (GPIs) synthesized in a cell-free system prepared from the free-living protozoan Paramecium primaurelia has been described. The final GPI precursor was identified and structurally characterized as: ethanolamine-phosphate-6Man alpha 1-2Man alpha 1-6(mannosylphosphate) Man alpha 1-4glucosamine-inositol-phospho-ceramide. During our investigations on the biosynthesis of the acid-labile modification, the additional mannosyl phosphate substitution, we observed that the use of the nucleotide triphosphate analogue GTP gamma S (guanosine 5-O-(thiotriphosphate)) blocks the biosynthesis of the mannosylated GPI glycolipids. We show that GTP gamma S inhibits the synthesis of dolichol-phosphate-mannose, which is the donor of the mannose residues for GPI biosynthesis. Therefore, we investigated the role of GTP binding regulatory 'G' proteins using cholera and pertussis toxins and an intracellular second messenger cAMP analogue, 8-bromo-cAMP. All the data obtained suggest the involvement of classical heterotrimeric G proteins in the regulation of GPI-anchor biosynthesis through dolichol-phosphate-mannose synthesis via the activation of adenylyl cyclase and protein phosphorylation. Furthermore, our data suggest that GTP gamma S interferes with synthesis of dolichol monophosphate, indicating that the dolichol kinase is regulated by the heterotrimeric G proteins.

Paramecium GPI proteins: variability of expression and localization.

In Paramecium primaurelia, the two major classes of cell surface proteins, the surface antigen (SAg) and the surface GPI proteins (SGPs), are linked to the plasma membrane through a glycosylphosphatidylinositol (GPI) anchor. In the present study, we have characterized the expression of the SGPs in several geographical strains of P. primaurelia and P. tetraurelia at different temperatures, 23 degrees C and 32 degrees C. The identification of the expressed SGPs was performed on purified cilia, by establishing the SGP SDS-PAGE profiles under four different conditions: with or without their anchoring lipid, cleaved with a Bacillus thuringiensis phosphatidylinositol-specific phospholipase C (PI-PLC), and either in a reduced or in an unreduced state. This screening revealed the existence of specific sets of ciliary SGPs, as a function of temperature and the geographical origin of the strains. The SGPs the most abundant at 23 degrees C and 32 degrees C displayed a rapid turnover. We also looked for the presence of PI-PLC releasable proteins in purified cortices. In addition to the SAg and SGPs, the cortical fraction was shown to contain other PI-PLC releasable proteins, not found in the ciliary fraction, thus localized exclusively in the interciliary region.

Transient N-acetylgalactosaminylation of mannosyl phosphate side chain in Paramecium primaurelia glycosylphosphatidylinositols.

The surface antigens of the free-living protozoan Paramecium primaurelia belong to the family of glycosylphosphatidylinositol (GPtdIns)-anchored proteins. Using a cell-free system prepared from P. primaurelia, we have described the structure and biosynthetic pathway for GPtdIns glycolipids. The core glycans of the polar glycolipids are modified by a mannosyl phosphate side chain. The data suggest that the mannosyl phosphate side chain is added onto the core glycan in two steps. The first step involves the phosphorylation of the GPtdIns trimannosyl conserved core glycan via an ATP-dependent kinase, prior to the addition of the mannose linked to the phosphate group. We show that dolichol phosphate mannose is the donor of all mannose residues including the mannose linked to phosphate. Furthermore, we were able to identify in vitro a hydrophilic intermediate containing an additional N-acetylgalactosamine linked to the mannosyl phosphate side chain. The addition of this purified hydrophilic radiolabelled intermediate into the cell-free system leads to a loss of the GalNAc residue and its conversion to the penultimate intermediate having only mannosyl phosphate as a side chain. Together the data indicate that the GalNAc-containing intermediate is a transitional intermediate. We suggest that the GalNAc-containing intermediate is essential for biosynthesis and maturation of GPtdIns precursors. It is hypothesized that this oligosaccharide processing in the course of GPtdIns biosynthesis is required for the translocation of GPtdIns from the cytoplasmic side of the endoplasmic reticulum to the luminal side.

The Lipid Moiety of the GPI-Anchor of the Major Plasma Membrane Proteins in Paramecium primaurelia is a Ceramide: Variation of the Amide-Linked Fatty Acid Composition as a Function of Growth Temperature.

The major membrane proteins of Paramecium are anchored in the plasma membrane via a glycosylphosphatidylinositol (GPI). The expression of these GPI-proteins, the surface antigen (SAg) and the surface GPI-proteins (SGPs), is temperature-dependent, different sets are expressed at 23°C and at 32 °C. To characterize the GPI-anchor lipid moieties of these proteins, a new strategy of biosynthetic radiolabeling was developed. Cells of Paramecium primaurelia, grown at 23°C or at 32 °C, were fed with [(14)C]-labeled cyanobacteria. The paramecia metabolized the cyanobacteria lipids and synthesized fatty acids with longer and more unsaturated chains. The SAg and SGPs from [(14)C]-labeled paramecia, were purified and the lipid moieties of their GPI-anchors were cleaved by a Bacillus thuringiensis phosphatidylinositol-specific phospholipase C and identified as ceramides. The GPI-anchor ceramides, from the SAg and SGPs expressed at both temperatures, contained long-chain bases which did not display variations detectable upon thin layer chromatography analysis. In contrast, the amide-linked fatty acid component varied: palmitic acid was identified as the major amidelinked fatty acid in the GPI-protein anchors from paramecia grown at 23°C, while at 32°C a C(14) fatty acid could be the prominent fatty acid. This modulation in the fatty acid composition could playa role in the antigenic variation process.

Glycosyl-phosphatidylinositols in protozoa structure, biosynthesis and intracellular localisation.

We are investigating the structure and biosynthesis of glycosyl-phosphatidylinositols (GPI) in the protozoa Toxoplasma gondii, Plasmodium falciparum, Plasmodium yoelii and Paramecium primaurelia. This comparison of structural and biosynthesis data should lead us to common and individual features of the GPI-biosynthesis and transport in different organisms.

The major ciliary membrane proteins in Paramecium primaurelia are all glycosylphosphatidylinositol-anchored proteins.

Using a strategy based upon specific features of membrane proteins linked to the plasma membrane by a glycosylphosphatidylinositol (GPI) anchor, we have studied in the strain 513 of Paramecium primaurelia the glycosylphosphatidylinositol (GPI) proteins both in their membrane-bound and soluble forms. 35S-Labeling associated with bacterial phosphatidylinositol-specific phospholipase C treatment of purified cilia allowed the identification of soluble GPI proteins (devoid of their lipid moiety), released from cilia. By labeling with 88[33P]phosphoric acid and [3H]ethanolamine, respectively, we identified membrane-bound GPI proteins, when anchored in the cilia membrane via the lipid of their GPI tail. We demonstrated that, in addition to the SAg (surface antigen) which is a high molecular weight protein implicated in the antigenic variation phenomenon, three other ciliary membrane proteins were also GPI-anchored. The membrane-bound and soluble forms of these GPI proteins had apparent molecular weights, in unreduced conditions, of 30,000 and 40 to 50,000, respectively. We named these surface GPI proteins SGPs, SGP1 to SGP3, SGP1 (surface GPI protein 1) and SGP2 (surface GPI protein 2) were the most abundantly expressed. Only SGP2 displayed a rapid turnover. By phosphatidylinositol-specific phospholipase C treatment of the membrane proteins recovered in the detergent phase, following partitioning with Triton X-114, we demonstrated that the SAg and SGPs are the major ciliary membrane proteins of P.primaurelia.

Glycosylinositol-phosphoceramide in the free-living protozoan Paramecium primaurelia: modification of core glycans by mannosyl phosphate.

Glycolipids synthesized in a cell-free system prepared from the free-living protozoan Paramecium primaurelia and labelled with [3H]mannose and [3H]glucosamine using GDP-[3H]mannose and UDP-[3H]N-acetyl glucosamine, respectively, were identified and structurally characterized as glycosylinositol-phosphoceramides (GIP-ceramides). The ceramide-based lipid was also found in the GIP membrane anchor of the G surface antigen of P.primaurelia, strain 156. Using a combination of in vitro labelling with GDP-[3H]mannose and in vivo labelling with 33P, we found that the core glycans of the P.primaurelia GIP-ceramides were substituted with an acid-labile modification identified as mannosyl phosphate. The modification of the glycosylinositol-phospholipid core glycan by mannosyl phosphate has not been described to date in other organisms. The biosynthesis of GIP-ceramide intermediates in P.primaurelia was studied by a pulse-chase analysis. Their structural characterization is reported. We propose the following structure for the putative GIP-ceramide membrane anchor precursor of P.primaurelia surface proteins: ethanolamine phosphate-6Man-alpha 1-2Man-alpha 1-6Man-(mannosyl phosphate)-alpha 1-4glucosamine-inositol-phosphoceramide.

Temperature-dependent expression of ciliary GPI-proteins in Paramecium.

Many eukaryotic membrane proteins have now been found to be anchored to the plasma membrane via a glycosylphosphatidylinositol membrane anchor (GPI-anchor). In Paramecium aurelia, a free-living ciliated protozoan, the major membrane protein, the surface antigen (SAg), is a GPI-anchored protein. This surface protein belongs to a multigene family, the expression and antigenic variation of which is controlled by environmental conditions. In order to screen for other Paramecium GPI-anchored proteins to identify those whose expression is also variable and influenced by external factors, we established a protocol permitting the rapid identification of GPI-proteins. The protocol is based upon the property of bacterial PI-PLCs to specifically release GPI-proteins. To overcome the resistance displayed by living paramecia to exogenous PI-PLCs, we used cilia purified from 35S-labeled cells obtained from various geographical strains grown under similar or different conditions. We observed a temperature-dependent variation in the electrophoretic patterns, as revealed by autoradiography of ciliary PI-PLC-releasable proteins from strain 513 of Paramecium primaurelia. In addition to a high molecular mass band corresponding to SAg molecules, three bands varying in apparent molecular mass from 30 to 50 kDa were observed at 23 degrees C. At 32 degrees C only one band of about 45 kDa was observed. Biosynthetic labeling experiments and the detection of the cross-reacting determinant after PI-PLC treatment (results reported elsewhere) provided definitive proof that these ciliary PI-PLC releasable proteins were actually GPI-proteins.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural comparisons between the soluble and the GPI-anchored forms of the Paramecium temperature-specific 156G surface antigen.

Biosynthetic labelling experiments performed on P primaurelia strain 156, expressing the temperature-specific G surface antigen, 156G SAg, demonstrated that the purified 156G SAg contained the components characteristic of a GPI-anchor. [3H]ethanolamine, [3H]myo-inositol, [32P]phosphoric acid and [3H]myristic acid could all be incorporated into the surface antigen. Myristic acid labelling was lost after treatment in vitro with Bacillus thuringiensis phosphatidylinositol-specific phospholipase C (PI-PLC). After complete digestion by pronase, a fragment containing the intact GPI-anchor of 156G surface antigen was isolated. This fragment was shown to be hydrophobic and glycosylated and to possess an epitope found specifically in the GPI component of GPI-anchored proteins. The role of the GPI-tail in anchoring the 156G surface antigen into the membrane was assessed by determining that purified 156G molecules with the GPI-anchor could be incorporated into lipid vesicles and red cell ghosts whereas the 156G molecules lacking the GPI-anchor, as result of treatment with B thuringiensis PI-PLC, could not. It has also been shown that the membrane-bound form and the soluble form, obtained after cleavage of the 156G SAg lipid moiety either by an endogenous PI-PLC or by a bacterial PI-PLC, displayed identical circular dichroic spectra.

Purification of the temperature-specific surface antigen of Paramecium primaurelia with its glycosyl-phosphatidylinositol membrane anchor.

The membrane form of the temperature-specific G surface antigen of Paramecium primaurelia strain 156 has been purified by a novel procedure utilizing solubilization by detergent, ammonium sulfate precipitation, and high-performance liquid chromatography. The surface antigen, which was prepared in a nondenatured state containing a glycosyl-phosphatidylinositol membrane anchor, migrated as a single band upon electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. Following cleavage of the purified surface antigen by a phosphatidylinositol-specific phospholipase C from Bacillus thuringiensis, the soluble form was released with the unmasking of a particular glycosidic immunodeterminant called the cross-reacting determinant. The purification protocol described here will now permit further biochemical and biophysical characterization of the nondenatured membrane form of Paramecium surface antigens.

A new class of Paramecium surface proteins anchored in the plasma membrane by a glycosylinositol phospholipid. Membrane anchor of Paramecium cross-reacting glycoproteins.

Treatment of paramecia with ethanol or Triton X-100 solubilizes a major membrane protein, namely the surface antigen (SAg), and a set of glycopeptides in the range 40-60 kDa, which cross-react with the SAg. We demonstrate that these glycopeptides, called 'cross-reacting glycoproteins' (CRGs), are distinct molecules from the SAg. First, after purification of CRGs from ethanolic extracts of Paramecium primaurelia expressing the 156G SAg, the amino acid composition of a given CRG was found to be different from, and incompatible with, that of the 156G SAg. Secondly, we showed that the CRGs, although not immunologically detectable, are present in fractions containing the myristoylated form of the 156G SAg. The treatment of these fractions by phosphatidylinositol-specific phospholipases C enables us to reveal the CRGs through the unmasking of two distinct epitopes. One is the 'cross-reacting determinant' (CRD), initially described for the variant surface glycoproteins (VSGs) of Trypanosoma; the other determinant, called 'det-2355', is specific to the SAg and to the CRGs. Our results suggest that (1) phosphatidylinositol is covalently linked to the CRGs and (2) the CRD and the det-2355 are localized in the same region of the CRGs. We propose that the CRGs are a new set of surface proteins anchored in the cell membrane of Paramecium via a glycosylinositol phospholipid, in the same way as the SAgs.

The membrane-anchor of Paramecium temperature-specific surface antigens is a glycosylinositol phospholipid.

The temperature-specific G surface antigen of Paramecium primaurelia strain 156 was biosynthetically labeled by [3H]myristic acid in its membrane-bound form, but not in its soluble form. It could be cleaved by a phosphatidylinositol-specific phospholipase C from Trypanosoma brucei or from Bacillus cereus which released its soluble form with the unmasking of a particular glycosidic immunodeterminant called the crossreacting determinant. The Paramecium enzyme, capable of converting its membrane-bound form into the soluble one, was inhibited by a sulphydril reagent in the same way as the trypanosomal lipase. From this evidence we propose that the Paramecium temperature-specific surface antigens are anchored in the plasma membrane via a glycophospholipid, and that an endogenous phospholipase C may be involved in the antigenic variation process.

Surface antigens of Paramecium primaurelia. Membrane-bound and soluble forms.

The surface antigens of Paramecium constitute a family of high molecular weight (ca 300 kD) iso-proteins whose alternative expression, adjusted to environmental conditions, involves both intergenic and interallelic exclusion. Since the surface antigen molecules had previously been shown to play a key role in the control of their own expression, it seemed important to compare the structural particularities of different surface antigens: the G and D antigens of P. primaurelia expressed at different temperatures, and which are coded by two unlinked loci. Here we demonstrate that in all cases a given surface antigen presents two biochemically distinct basic forms: a soluble form recovered from ethanolic extraction of whole cells, and a membrane-bound form recovered from ciliary membranes solubilized by detergent. The membrane-bound form differs from the soluble one by its mobility on SDS gels and by an electrophoretic mobility shift in the presence of anionic or cationic detergents. Furthermore, two 40-45 kD polypeptides sharing common determinants with soluble antigens were found exclusively in ethanolic extracts but not in ciliary membranes: the cross-reactivity of these light polypeptides with ethanol-extracted antigens could be demonstrated only after beta-mercaptoethanol treatment. Immunological comparisons between allelic and non-allelic soluble antigens demonstrate that allelic antigens share a great number of surface epitopes, most of which are not accessible in vivo, while non-allelic antigens appear to share essentially sequence-antigenic determinants. The significance of these results is discussed in relation to the mechanism of antigenic variation.

Regulation of surface antigen expression in Paramecium primaurelia. II. Role of the surface antigen itself.

In the wild-type strains, 156 and 168, of Paramecium primaurelia, the alleles G156 and G168 expressed at medium temperature specify two immunologically distinguishable surface antigens 156G and 168G, whose phenotypic expression shows allelic exclusion, the majority of heterozygotes being phenotypically [156G] while a small minority is phenotypically [156G-168G]. At high temperature, the antigens coded by another locus, generally the D locus, are expressed. This system, displaying both intergenic and interallelic exclusion, provides favourable material to analyze the respective roles of the genome, of the antigens expressed and of the environmental conditions, in particular temperature, on the regulation of the expression of surface antigens. This analysis was carried out by studying the variations of the expression of surface antigens as a function of temperature, culture medium and previously expressed antigens in different genetic situations (a) in homozygotes: the wild-type strains 156 and 168, and the isogenized strains "G156 isogenic 168 carrying the G156 allele in a 168 genetic background; (b) in heterozygotes of the two phenotypic classes of heterozygotes, [156G] and [156G-168G]. The results show that (1) the thermal stability of the expression of a given surface antigen and its rate of re-appearance at the cell surface depend on its own specificity; (2) in heterozygotes [156G-168G], the stability of the expression of the antigen 156G is modified and "adjusted" to that of the less stable surface antigen 168G, and (3) the surface antigen itself exerts a positive control on the maintenance of its own expression. An interpretative model of "transmembranous control" is proposed to account for the regulation of the expression of surface antigens in Paramecium.

Regulation of surface antigens expression in Paramecium primaurelia: genetic and physiological factors involved in allelic exclusion.

In paramecium aurelia, allelic exclusion can be considered as a basic feature of the surface antigens system in the same way as intergenic exclusion. Our studies on allelic exclusion in G156/G168 heterozygotes show that (1) allelic exclusion does not depend on discrete regulatory genes dispersed throughout the genome; (2) it does not seem to be influenced by cytoplasmic factors; (3) it occurs regardless of the surface antigen expressed by the parental strains at the time of the cross. These results are discussed in relation to both intergenic and interallelic exclusion for which a common basis is proposed.