Alpha-agglutinin expression in Saccharomyces cerevisiae

A polyclonal antiserum raised against purified alpha-agglutinin was made specific for alpha-agglutinin after adsorption with a cells. The adsorbed antiserum identified alpha-agglutinin peptides on Western blots and bound to cell surface alpha-agglutinin, inhibiting the binding of alpha cells to a cells. Using the antibody, we have determined that 1) the surface distribution of alpha-agglutinin on alpha cells is polar, 2) about 5 x 10(4) molecules/cell are constitutively expressed on strain X2180-1B (alpha) cells, and 3) treatment of alpha cells with the sex pheromone a-factor causes an increase in cell surface alpha-agglutinin, consistent with the a-factor induced increase in cell agglutinability.     

Identification of glycoprotein components of alpha-agglutinin, a cell adhesion protein from Saccharomyces cerevisiae.

Several glycoproteins which inhibit the agglutinability of Saccharomyces cerevisiae mating type a cells were partially purified from extracts of mating type alpha cells. These proteins, called alpha-agglutinin, were labeled with 125I-Bolton-Hunter reagent. The labeled alpha-agglutinin showed specific binding to a cells. Such specific binding approached saturation with respect to agglutinin or cells and was inhibited in the presence of excess unlabeled alpha-agglutinin. Nonspecific binding was similar in a and alpha cells, was neither saturable nor competable, and was three- to fourfold less than the specific binding to a cells at maximum tested agglutinin concentrations. The major a-specific binding species had a low electrophoretic mobility in sodium dodecyl sulfate-polyacrylamide gels and had an apparent molecular weight of 155,000 by rate zonal centrifugation. Endo-N-acetylglucosaminidase H digestion of the purified glycoprotein complex converted the low-mobility material to four major and several minor bands which were resolved by polyacrylamide gel electrophoresis. All but two minor peptides bound specifically to a cells. Analyses of agglutinin from mnn mutants confirmed the deglycosylation results in suggesting that the N-linked carbohydrate portion of alpha-agglutinin was not necessary for activity.     

Sexual agglutination in budding yeasts: structure, function, and regulation of adhesion glycoproteins.

The sexual agglutinins of the budding yeasts are cell adhesion proteins that promote aggregation of cells during mating. In each yeast species, complementary agglutinins are expressed by cells of opposite mating type that interact to mediate aggregation. Saccharomyces cerevisiae alpha-agglutinin and its analogs from other yeasts are single-subunit glycoproteins that contain N-linked and O-linked oligosaccharides. The N-glycosidase-sensitive carbohydrate is not necessary for activity. The proposed binding domain of alpha-agglutinin has features characteristic of the immunoglobulin fold structures of cell adhesion proteins of higher eukaryotes. The C-terminal region of alpha-agglutinin plays a role in anchoring the glycoprotein to the cell surface. The S. cerevisiae alpha-agglutinin and its analogs from other species contain multiple subunits; one or more binding subunits, which interact with the opposite agglutinin, are disulfide bonded to a core subunit, which mediates cell wall anchorage. The core subunits are composed of 80 to 95% O-linked carbohydrate. The binding subunits have less carbohydrate, and both carbohydrate and peptide play roles in binding. The alpha-agglutinin and alpha-agglutinin genes from S. cerevisiae have been cloned and shown to be regulated by the mating-type locus, MAT, and by pheromone induction. The agglutinins are necessary for mating under conditions that do not promote cell-cell contact. The role of the agglutinins therefore is to promote close interactions between cells of opposite mating type and possibly to facilitate the response to phermone, thus increasing the efficiency of mating. We speculate that they mediate enhanced response to sex pheromones by providing a synapse at the point of cell-cell contact, at which both pheromone secretion and cell fusion occur.     

Pheromone induction of agglutination in Saccharomyces cerevisiae a cells.

a-Agglutinin, the cell surface sexual agglutinin of yeast a cells, was assayed by its ability to bind its complementary agglutinin, alpha-agglutinin. The specific binding of 125I-alpha-agglutinin to a cells treated with the sex pheromone alpha-factor was 2 to 2.5 times that of binding to a cells not treated with alpha-factor. Competition with unlabeled alpha-agglutinin revealed that the increased binding was due to increased cell surface expression of a-agglutinin, with no apparent change in the binding constant. The increase in site number was similar to the increase in cellular agglutinability. Increased expression of a-agglutinin followed the same kinetics as the increase in cellular agglutinability, with a 10-min lag followed by a 15- to 20-min response time. Induction kinetics were similar in cells in phases G1 and G2 of the cell cycle. Maximal expression levels were similar in cells treated with excess pheromone and in cells exposed to pheromone after destruction of constitutively expressed a-agglutinin.     

Cell surface anchorage and ligand-binding domains of the Saccharomyces cerevisiae cell adhesion protein alpha-agglutinin, a member of the immunoglobulin superfamily.

alpha-Agglutinin is a cell adhesion glycoprotein expressed on the cell wall of Saccharomyces cerevisiae alpha cells. Binding of alpha-agglutinin to its ligand a-agglutinin, expressed by a cells, mediates cell-cell contact during mating. Analysis of truncations of the 650-amino-acid alpha-agglutinin structural gene AG alpha 1 delineated functional domains of alpha-agglutinin. Removal of the C-terminal hydrophobic sequence allowed efficient secretion of the protein and loss of cell surface attachment. This cell surface anchorage domain was necessary for linkage to a glycosyl phosphatidylinositol anchor. A construct expressing the N-terminal 350 amino acid residues retained full a-agglutinin-binding activity, localizing the binding domain to the N-terminal portion of alpha-agglutinin. A 278-residue N-terminal peptide was inactive; therefore, the binding domain includes residues between 278 and 350. The segment of alpha-agglutinin between amino acid residues 217 and 308 showed significant structural and sequence similarity to a consensus sequence for immunoglobulin superfamily variable-type domains. The similarity of the alpha-agglutinin-binding domain to mammalian cell adhesion proteins suggests that this structure is a highly conserved feature of adhesion proteins in diverse eukaryotes.     

Interaction of alpha-agglutinin and a-agglutinin, Saccharomyces cerevisiae sexual cell adhesion molecules

alpha-Agglutinin and a-agglutinin are complementary cell adhesion glycoproteins active during mating in the yeast Saccharomyces cerevisiae. They bind with high affinity and high specificity: cells of opposite mating types are irreversibly bound by a few pairs of agglutinins. Equilibrium and surface plasmon resonance kinetic analyses showed that the purified binding region of alpha-agglutinin interacted similarly with purified a-agglutinin and with a-agglutinin expressed on cell surfaces. At 20 degrees C, the K(D) for the interaction was 2 x 10(-9) to 5 x 10(-9) M. This high affinity was a result of a very low dissociation rate ( approximately 2.6 x 10(-4) s(-1)) coupled with a low association rate (= 5 x 10(4) M(-1) s(-1)). Circular-dichroism spectroscopy showed that binding of the proteins was accompanied by measurable changes in secondary structure. Furthermore, when binding was assessed at 10 degrees C, the association kinetics were sigmoidal, with a very low initial rate. An induced-fit model of binding with substantial apposition of hydrophobic surfaces on the two ligands can explain the observed affinity, kinetics, and specificity and the conformational effects of the binding reaction.     

Metal ion binding to alpha-lactalbumin species

A strong cation (calcium) binding site has been demonstrated to exist in several alpha-lactalbumin species; bovine, goat, human, and guinea pig. A metal ion induced conformational change occurs, resulting in a unique (10-14-nm) blue shift and relative quenching of Trp fluorescence for all species. Calcium ion binding to the alpha-lactalbumins yielded dissociation constants (Kdiss consistently in the 10(-10)--10(-12) M range, while Mn(II) binding was in the 20-30 microM range. Independent determinations of these cation binding equilibria were made by ESR measurements of free unliganded Mn(II) in titrations with the bovine species. One strong site (Kdiss = 30.5 microM) was found, which correlated directly with the fluorescence-associated cation binding, plus three weaker sites (Kdiss = 1.1, 5.0, and 5.0 mM, respectively). Several lanthanides as well as Mg(II) were found to displace Mn(II) from the strong site on bovine alpha-lactalbumin (as monitored by ESR) and to cause the identical fluorescence changes as found for Ca(II) and Mn(II) above. The importance of measuring these equilibria by both fluorescence and ESR was borne out by demonstrating the potential errors in estimating dissociation equilibria by the fluorescence method alone. Also, the errors in estimating Kdiss for samples containing partially metal bound apo-alpha-lactalbumin are described as well as rapid, sensitive methods for estimating the extent of metal-free protein and correctly accounting for residual bound metal in equilibrium calculations.     

Identification of a ligand-binding site in an immunoglobulin fold domain of the Saccharomyces cerevisiae adhesion protein alpha-agglutinin.

The Saccharomyces cerevisiae adhesion protein alpha-agglutinin (Ag alpha 1p) is expressed by alpha cells and binds to the complementary a-agglutinin expressed by a cells. The N-terminal half of alpha-agglutinin is sufficient for ligand binding and has been proposed to contain an immunoglobulin (Ig) fold domain. Based on a structural homology model for this domain and a previously identified critical residue (His292), we made Ag alpha 1p mutations in three discontinuous patches of the domain that are predicted to be in close proximity to His292 in the model. Residues in each of the three patches were identified that are important for activity and therefore define a putative ligand binding site, whereas mutations in distant loops had no effect on activity. This putative binding site is on a different surface of the Ig fold than the defined binding sites of immunoglobulins and other members of the Ig superfamily. Comparison of protein interaction sites by structural and mutational analysis has indicated that the area of surface contact is larger than the functional binding site identified by mutagenesis. The putative alpha-agglutinin binding site is therefore likely to identify residues that contribute to the functional binding site within a larger area that contacts a-agglutinin.     

Glycosyl phosphatidylinositol-dependent cross-linking of alpha- agglutinin and beta 1,6-glucan in the Saccharomyces cerevisiae cell wall

The cell adhesion protein alpha-agglutinin is bound to the outer surface of the Saccharomyces cerevisiae cell wall and mediates cell- cell contact in mating. alpha-Agglutinin is modified by addition of a glycosyl phosphatidylinositol (GPI) anchor as it traverses the secretory pathway. The presence of a GPI anchor is essential for cross- linking into the wall, but the fatty acid and inositol components of the anchor are lost before cell wall association (Lu, C.-F., J. Kurjan, and P. N. Lipke, 1994. A pathway for cell wall anchorage of Saccharomyces cerevisiae alpha-agglutinin. Mol. Cell. Biol. 14:4825- 4833). Cell wall association of alpha-agglutinin was accompanied by an increase in size and a gain in reactivity to antibodies directed against beta 1,6-glucan. Several kre mutants, which have defects in synthesis of cell wall beta 1,6-glucan, had reduced molecular size of cell wall alpha-agglutinin. These findings demonstrate that the cell wall form of alpha-agglutinin is covalently associated with beta 1,6- glucan. The alpha-agglutinin biosynthetic precursors did not react with antibody to beta 1,6-glucan, and the sizes of these forms were unaffected in kre mutants. A COOH-terminal truncated form of alpha- agglutinin, which is not GPI anchored and is secreted into the medium, did not react with the anti-beta 1,6-glucan. We propose that extracellular cross-linkage to beta 1,6-glucan mediates covalent association of alpha-agglutinin with the cell wall in a manner that is dependent on prior addition of a GPI anchor to alpha-agglutinin.     

Mating type-specific cell-cell recognition of Saccharomyces cerevisiae: cell wall attachment and active sites of a- and alpha-agglutinin.

Mating type-specific agglutination of Saccharomyces cerevisiae a and alpha cells depends on the heterophilic interaction of two cell surface glycoproteins, the gene products of AG alpha 1 and AGA2. Evidence is presented with immunogold labelling that the alpha-agglutinin is part of the outer fimbrial cell wall coat. The a-agglutinin is bound via two S-S bridges (Cys7 and Cys50) to a cell wall component, most probably the gene product of AGA1. His273 of alpha-agglutinin has previously been shown to be essential for a- and alpha-agglutinin interaction and a model based on two opposing ion-pairs had been proposed. By site-directed mutagenesis this possibility has now been excluded. With the help of various peptides, either chemically synthesized, obtained by proteolysis of intact glycosylated a-agglutinin or prepared from a fusion protein expressed in Escherichia coli, the biologically active region of a-agglutinin was located at the C-terminus of the molecule. A peptide consisting of the C-terminal 10 amino acids (GSPIN-TQYVF) was active in nanomolar concentrations. Saccharide moieties, therefore, are not essential for the mating type-specific cell-cell interaction; glycosylated peptides are, however, four to five times more active than non-glycosylated ones. Comparisons of the recognition sequences of the S. cerevisiae agglutinins with that of the Dictyostelium contact site A glycoprotein (gp80), as well as with those of the various families of cell adhesion molecules of higher eucaryotes, have been made and are discussed.     

Saccharomyces cerevisiae a- and alpha-agglutinin: characterization of their molecular interaction.

An O-glycosylated protein of approximately 18 kDa responsible for mating type specific agglutination has been isolated from Saccharomyces cerevisiae a cells, purified to homogeneity and via peptide sequences the gene was cloned by PCR. An open reading frame codes for a protein of 69 amino acids. A minimum of five serine and five threonine residues of the mature protein are glycosylated. alpha-Agglutinin is a highly N-glycosylated protein of approximately 250 kDa. Both purified agglutinins form a specific 1:1 complex in vitro. Pretreatment of alpha-agglutinin, but not of alpha-agglutinin, with diethylpyrocarbonate (DEPC) prevents formation of the complex; treatment of alpha-agglutinin in the presence of alpha-agglutinin protects the former from DEPC inactivation. By carboxy terminal shortening of the alpha-agglutinin gene and by replacing three of its eight histidyl residues by arginine, the active region of alpha-agglutinin for interaction with alpha-agglutinin has been defined. Neither the N- nor the O-linked saccharides of the two agglutinins seem to be essential for their interaction.     

The interaction of phenyldichloroarsine with erythrocytes

The purpose of the study was to identify binding sites of organic arsenic in the erythrocyte and to explain species differences in binding. Washed erythrocytes were exposed to graded concentrations of [U-14C]phenyldichloroarsine (PDA) in phosphate-buffered saline containing 0.1% glucose and 0.1% bovine serum albumin. At low PDA concentrations, all cells bound the arsenical rapidly (within 10 min) and quantitatively. Human, pig, hamster, guinea pig, and mouse erythrocytes approached saturation at 0.02-0.3 mumol PDA/10(9) cells, depending on the species. Saturation points correlated well with each respective species' erythrocyte glutathione content. In contrast, rat erythrocytes showed no sign of saturation at PDA loads as high as 3.0 mumol/10(9) cells. Hemolysates of PDA-treated erythrocytes were subjected to Sephadex G-75 gel filtration chromatography. 14C from rat hemolysate was distributed between the hemoglobin and small molecular weight (glutathione-containing) fractions. In all other species, the 14C eluted almost exclusively with the glutathione-containing fractions. In equilibrium dialysis experiments, human hemoglobin did not bind PDA, whereas rat hemoglobin bound 2 PDA/mol with Kd approximately 5 microM. In conclusion, glutathione is the principal binding site of phenyldichloroarsine in erythrocytes. In most species, the arsenical does not bind to hemoglobin, even though it has free (titratable) sulfhydryls considerably in excess of the glutathione concentration. In rat erythrocytes, phenlydichloroarsine binds both to glutathione and to hemoglobin. Arsenical binding by rat hemoglobin is presumably due to the unique location of the extra titratable cysteine in that protein.     

The separate estimation of cAMP intracellularly bound to the regulatory subunits of protein kinase I and II in glucagon-stimulated rat hepatocytes

A method is described for the separate determination of cAMP intracellularly bound to the regulatory moieties (RI and RII) of protein kinase I and II. The cAMP endogenously bound to RI or RII in hepatocyte extract was adsorbed to protein A-agarose beads coated with antibodies against RI or RII. The endogenously bound cAMP was eluted from the washed beads with dilute acetic acid before being assayed. By all criteria tested, the present method did not perturb the intracellularly established equilibrium between bound and free cAMP. Stabilization of R X cAMP complexes was achieved by including sulfate in the extraction medium and sulfate/glycerol during the subsequent steps. Hepatocytes were isolated from fed male rats and contained about 0.25 pmol of RI and 0.2 pmol of RII per 10(5) cells. An intracellular titration of the cAMP binding sites of RI and RII was achieved by incubating the cells with various concentrations (1 pM to 10 nM) of glucagon. The fractional saturation of RI and RII was always similar, being 20% in nonstimulated cells. 50% saturation occurred when free cAMP was 0.46 pmol/10(5) cells. A Scatchard plot of the data for the endogenous cAMP binding suggested that cAMP interacted with RI and RII in a slightly positively cooperative manner. About 5% of the intracellularly bound cAMP was sedimentable at 10,000 X g. The apparent affinity of these particulate-associated binding sites was similar to that of soluble RI and RII. Under the conditions used no evidence was obtained for cAMP binding to other proteins than RI and RII.     

Role of secretory component, a secreted glycoprotein, in the specific uptake of IgA dimer by epithelial cells.

The binding of secretory component (SC) to epithelial cells and its role in the specific uptake of immunoglobulin A (IgA) dimer has been studied in rabbit mammary gland and liver. SC, Mr approximately 80,000, secreted by epithelial cells of the mammary gland was found associated with the cell surface of mammary cells in intact tissue. Dispersed mammary cells and plasma membrane-enriched fractions obtained from mammary glands of midpregnant rabbits bound 125I-labeled SC in a saturable time- and temperature-dependent process. The association rate followed a second order reversible reaction (k+1 approximately equal to 2.7 x 10(6) M-1 min-1 at 4 degrees C) and equilibrium was reached in about 4 h at 4 degrees C. The dissociation rate for membranes was first order (k-1 approximately equal to 1.7 x 10(-2) min-1 at 4 degrees C), whereas displacement from cells was incomplete. The apparent affinity constant was similar for membranes and cells (Ka approximately equal to 5 x 10(8) M-1) with one class of binding sites. The number of binding sites varied from one animal to another (260 to 7,000 sites/mammary cell) in relation to endogenous occupancy by SC, which was assessed by immunocytochemistry and complement-mediated cytotoxicity. Rabbit liver and heart membranes did not bind SC, and serum proteins present in rabbit milk failed to interact with mammary cells or membranes. Mammary membranes or cells and liver membranes bound 125I-labeled IgA dimer in a saturable, reversible time- and temperature-dependent process. Association and dissociation rate constants at 4 degrees C (k+1 approximately equal to 5 x 10(6) M-1 min-1 and k-1 approximately equal to 5 x 10(-3) min-1, respectively) and the apparent affinity constant (Ka approximately equal to 10(9) M-1) were similar for liver and mammary membranes; these parameters differed, however, from those reported for free SC-IgA dimer interaction. The binding capacity of membranes for IgA dimer was directly related to the amount of free SC bound to membranes. Interaction of IgA dimer with mammary or liver membranes or cells was abrogated by excess of free SC and was prevented by preincubation of membranes or cells with Fab antibody fragments directed against SC. These data indicate that the first step in the translocation process of polymeric immunoglobulins across epithelia consists of binding of SC to the surface of epithelial cells which in turn acts as a receptor for the specific uptake of IgA dimer.     

Interaction of glucosyltransferase from Streptococcus mutans with various glucans

Cell-free glucosyltransferase of Streptococcus mutans strain B13 (serotype d) exclusively synthesized water-insoluble glucan from sucrose. The insoluble glucan possessed strong glucan-associated glucosyltransferase activity even after extensive washing and lyophilization. Furthermore, cell-free glucosyltransferase became bound to heat-treated water-insoluble glucan or to heat-treated S. mutans B13 cells grown in Todd Hewitt broth, and the resulting glucan and cells adhered to a glass surface in the presence of exogenous sucrose. No other water-insoluble glucans bound significant quantities of glucosyltransferase. Glucan synthesis by free or glucan-bound glucosyltransferase was stimulated by low concentrations (1 to 5 mg ml-1) of isomaltose or water-soluble dextrans of various molecular weights, but higher concentrations (10 mg ml-1) inhibited glucan synthesis. The glucan synthesized in the presence of primer dextrans exhibited a reduced ability to adhere to a glass surface. Certain sugars such as maltose and fructose significantly lowered the yield of insoluble glucans. Preincubation of glucosyltransferase with the low molecular weight dextran T10 increased subsequent binding to S. mutans B13 insoluble glucan, whereas preincubation with higher molecular weight dextrans significantly inhibited the glucosyltransferase binding.     

Binding of cobalamin analogs to intrinsic factor-cobalamin receptor and its prevention by R binder

It is now known that nonphysiological cobalamin analogs exist in the gastrointestinal tract, but their metabolic behavior is unclear. In this study, [57Co]cobinamide was used to study its affinity to hog intrinsic factor-cobalamin (IF-Cbl) receptor which has no species specificity against human IF-Cbl receptor, and its relation to human saliva R binder. Cobinamide was prepared from [57Co]cyanocobalamin and separated by paper chromatography. Human IF-Cbl complex was bound to IF-Cbl receptor but free cyanocobalamin was not. Although R binder-cobinamide was not bound to the IF-Cbl receptor, free cobinamide was bound to the IF-Cbl receptor to a significant extent (about one-half of IF-cyanocobalamin binding to the IF-Cbl receptor). We then investigated the binding of cobinamide to R binder and trypsin-treated R binder. Association constant of cobinamide binding to the IF-Cbl receptor was 1.0 X 10(9) M-1 which was much lower than that of cobinamide binding to trypsin-treated R binder and to untreated R binder. Further study indicated that cobinamide binding to the IF-Cbl receptor was blocked by the addition of R binder and also by trypsin-treated R binder. We conclude that one of the roles of R binder is to prevent binding of free cobalamin analogs to the IF-Cbl receptor in the gut.     

Different binding of poly(A)-containing and poly(A)-free fractions of nuclear ribonucleic acid to ribosomes from rat liver.

Total nuclear RNA extracted from nuclei of rat liver cells by phenol/chloroform in the presence of sodium dodecyl sulphate was separated by combined gel filtration on Sepharose 4 B and affinity chromatography on poly(U) Sepharose into fractions differing in their molecular weights and contents of poly(A) sequences. The poly(A)-containing 45-S RNA became labelled most rapidly if rats were administered [3H] orotic acid. This fraction showed a high template activity when added to postmitochondrial supernatants of the Krebs ascites tumour. Fractions of nRNA, free of poly(A) sequences, had no stimulating effect on protein synthesis in this system. The 45-S RNA-containing poly(A) was readily bound to crude polyribosomes from rat liver at 0 degrees C and both ATP and GTP were necessary for this reaction. Sucrose gradient analyses provided evidence that this RNA species is bound predominantly to 80-S ribosomes. No binding was obtained with polyribosomes washed with 0.5 M KCl. The binding ability of washed polyribosomes was restored by the addition of the ribosomal wash fraction or rat liver cytosol. Crude polyribosomes bound significantly lower quantities of nRNA species free of poly(A) when compared with poly(A)-45-S RNA. The label was scattered through the whole ribosomal sedimentation pattern with no predominant peaks and the binding reaction required neither soluble factors nor nucleotide cofactors. The labelling kinetics and high template activity of poly(A)-45-S nRNA indicate that this fraction contains precursors of cytoplasmic mRNA. Requirements for soluble factors and nucleotide cofactors in the binding of this RNA species to 80-S ribosomes suggest that this binding, unlike that of other nRNA species, has a specific mechanism resembling that of mRNA binding during peptide initiation.     

Binding of Semliki Forest virus and its spike glycoproteins to cells.

We have studied the binding of the Semliki Forest virus and its isolated spike glycoproteins, in the form of water-soluble octameric complexes, to various cells at 5 degrees C. The number of viruses bound per cell increased strongly with increasing free concentrations of virus up to about 0.2 nM. At higher concentrations smaller increases in binding were observed but saturation was not achieved. The number of viruses bound at a given free concentration was widely different for different cells. For some cells the binding of the virus was maximal at pH 6.8 with little decrease at lower pH, for other cells it was maximal around pH 6.0. The spike protein complexes were used at 100 times higher molar concentrations than the virus. The binding increased strongly with increasing free concentrations up to about 50 nM and saturation was obtained at higher concentrations. Up to 1.3 X 10(6) spike protein complexes could be bound per cell but great variation could be seen between different cell types. For all cells maximal binding was found below pH 6.0. Together with earlier observations, our results suggest that the virus can bind to a cell by two different modes. Around neutral pH the virus binds to specific glycoproteins and at low pH unspecifically to the lipids of the plasma membrane. The possible physiological roles of these two types of binding are discussed.     

AG alpha 1 is the structural gene for the Saccharomyces cerevisiae alpha-agglutinin, a cell surface glycoprotein involved in cell-cell interactions during mating.

We have cloned the alpha-agglutinin structural gene, AG alpha 1, by the isolation of alpha-specific agglutination-defective mutants, followed by isolation of a complementing plasmid. Independently isolated alpha-specific agglutination-defective mutations were in a single complementation group, consistent with biochemical results indicating that the alpha-agglutinin is composed of a single polypeptide. Mapping results suggested that the complementation group identified by these mutants is allelic to the ag alpha 1 mutation identified previously. Expression of AG alpha 1 RNA was alpha specific and inducible by a-factor. Sequences similar to the consensus sequences for positive control by MAT alpha 1 and pheromone induction were found upstream of the AG alpha 1 initiation codon. The AG alpha 1 gene could encode a 650-amino-acid protein with a putative signal sequence, 12 possible N-glycosylation sites, and a high proportion of serine and threonine residues, all of which are features expected for the alpha-agglutinin sequence. Disruption of the AG alpha 1 gene resulted in failure to express alpha-agglutinin and loss of cellular agglutinability in alpha cells. An Escherichia coli fusion protein containing 229 amino acids of the AG alpha 1 sequence was recognized by an anti-alpha-agglutinin antibody. In addition, the ability of this antibody to inhibit agglutination was prevented by this fusion protein. These results indicate that AG alpha 1 encodes alpha-agglutinin. Features of the AG alpha 1 gene product suggest that the amino-terminal half of the protein contains the a-agglutinin binding domain and that the carboxy-terminal half contains a cell surface localization domain, possibly including a glycosyl phosphatidylinositol anchor.     

Immunofluorescent localization of the proteins of nuclear ribonucleoprotein complexes

Antibodies were raised in chickens against heterogeneous nuclear RNA (hnRNA)-binding proteins from 30S ribonucleoprotein (RNP) complexes of mouse Taper hepatoma ascites cell nuclei. The antibody preparations were characterized for immunological specificity and purity by double- diffusion gels, binding to specific bands in SDS polyacrylamide gels, and crossed immunoelectrophoresis. Antibodies raised against either whole 30S RNP complexes or purified RNP core proteins had a strong selective affinity for the four 34,000- to 40,000-dalton polypeptides which comprise the major structural proteins of hnRNP. The intracellular distribution of 30S RNP antigens in mouse ascites cells was determined by indirect immunofluorescence microsacopy. In interphase cells immunofluorescent sites were restricted to the nucleus, and nucleoli were free of fluorescence. The chicken anti-mouse- RNP antibodies were also able to react with cells from many different vertebrate species, showing a similar nucleus-restricted localization of the reacting sites. The antibodies also bound chick 30S RNP-proteins and reacted with the nuclei of chick cells. An exception to this was the failure of the antibody to bind to adult chick erythrocytes, suggesting that these major hnRNA binding proteins may be found only in nuclei capable of RNA synthesis.