Transport characteristics of mammalian Rh and Rh glycoproteins expressed in heterologous systems.

The development and use of heterologous expression systems is critical for deciphering the function of mammalian Rh and Rh-glycoproteins. The studies here use Xenopus oocytes, well known for their ability to readily traffic and express difficult membrane proteins, and S. cerevisiae wild-type strains and mutants that are defective in ammonium transport. Data obtained in both of these expression systems revealed that mammalian Rh-glycoprotein-mediated transport (RhAG, RhBG, and RhCG) is an electroneutral process that is driven by the NH4+ concentration and the transmembrane H+ gradient, effectively exchanging NH4+ for H+ in a process that results in transport of net NH3. Homology modeling and functional studies suggest that the more recently evolved erythrocyte blood group proteins, RhCE and RhD, may not function directly in ammonia transport and may be evolving a new function in the RBC membrane. The relationship of Rh and Rh-glycoproteins to the Amt/Mep ammonium transporters is substantiated with functional transport data and structural modeling.

16Cys encoded by the RHce gene is associated with altered expression of the e antigen and is frequent in the R0 haplotype.

Serological observations have suggested that numerous D, many e (especially in Blacks), several E, and rare c variants exist within the Rh blood group system. The molecular basis for expression of many of these variants has been elucidated. This study describes five unrelated Caucasians whose red blood cells reacted with polyclonal anti-e but did not react with some monoclonal anti-e, which suggested that they carried a variant e antigen. Molecular investigation revealed the presence of a 48G-->C change (encoding cysteine instead of tryptophan at amino acid 16) in their RHce gene. No other differences were found, which suggests that amino acid residues located in the first transmembrane region can affect expression of the e antigen, whose critical residues are on the predicted fourth external loop of the protein. This polymorphism has not previously been observed because polyclonal anti-e does not distinguish this variant from wild type. This position is polymorphic in RHce alleles and the presence of the 48C nucleotide is often found in the R0 (Dce) haplotype.

Evidence supporting the requirement for two proline residues for expression of c.

BACKGROUND: In humans, c antigen expression is associated with a proline residue at amino acid position 103 in the second extracellular loop of the CE protein. Comparison of nonhuman primate Rh proteins suggested that c reactivity might actually involve two proline residues. It has been shown that the RBCs of New World capuchin monkeys (Cebus apella) react with anti-c. To further define the amino acid residues involved in c expression, Rh cDNA from the capuchin was analyzed. STUDY DESIGN AND METHODS: Rh transcripts were amplified by reverse transcription PCR from RNA isolated from the reticulocytes of a capuchin monkey and were cloned and sequenced. RESULTS: Rh transcripts from the capuchin monkey, whose RBCs react with anti-c, were found to encode adjacent proline residues at 102 and 103. CONCLUSION: Sequencing of Rh transcripts from the capuchin monkey supports the hypothesis that the expression of c requires two adjacent proline residues. Proline causes bends or loops in proteins, which, in this case, might form a unique, stable structure resistant to perturbations induced by changes in upstream or downstream residues. This would explain the scarcity in humans of c variants as compared to the other major Rh antigen variants, and the preservation of c reactivity despite 24-percent divergence between the human and capuchin Rh proteins.

Unusual amino acid usage in the variable regions of mercury-binding antibodies.

Monoclonal antibodies (mAb) specific for mercuric ions were isolated from BALB/c mice injected with a mercury-containing, hapten-carrier complex. The antibodies reacted by enzyme-linked immunosorbent assay with bovine serum albumin-glutathione-mercuric chloride (BSA-GSH-HgCl) but not with BSA-GSH without mercury. Nucleotide sequences from polymerase chain reaction products encoding six of the antibody heavy-chain variable regions and seven light-chain variable regions revealed that all the antibodies contained an unpaired cysteine residue in one hypervariable region, which is unusual for murine antibodies. Mutagenesis of the cysteine to either tyrosine or serine in one of the Hg-binding antibodies, mAb 4A10, eliminated mercury binding. However, of two influenza-specific antibodies that contain cysteine residues at the same position as mAb 4A10, one reacted with mercury, although not so strongly as 4A10, whereas the other did not react at all. These results suggested that, in addition to an unpaired cysteine, there are other structural features, not yet identified, that are important for creating an appropriate environment for mercury binding. The antibodies described here could be useful for investigating mechanisms of metal-protein interactions and for characterizing antibody responses to structurally simple haptens.

Characterization of the mouse Rh blood group gene.

The Rh blood group system is of clinical importance in blood transfusion and as the cause of hemolytic disease of the newborn. Other than their role as carriers of Rh antigens, very little is known about the function of the Rh polypeptides. As a first step to generate an animal model system in which to study the structure and function of Rh, and to extend the phylogenetic analysis of RH genes, the Rh homologue from Mus musculus was characterized. Comparison of RH from humans and mice revealed 71 and 58% sequence identity at the nucleotide and amino acid levels, respectively. Mouse Rh mRNA encodes a protein which is 1 amino acid longer (418 aa) than that of human (417 aa). Rh protein was detected in mouse erythrocyte membranes and was comparable in size to human Rh. Mouse erythrocytes do not show serologic reactivity with human Rh antibodies, probably because the greatest divergence between the mouse and the human genes was seen in the predicted extracellular loops, while the transmembrane regions were more conserved. The mouse RH locus consists of only one gene, which is important for future genetic manipulation and which also indicates that the RH gene duplication seen in humans has occurred since the mammalian radiation.

DNA-binding antibodies from viable motheaten mutant mice: implications for B cell tolerance.

C57BL/6 me(v)/me(v) (viable motheaten) mice have defective hemopoietic cell protein-tyrosine phosphatase (HCP, SHP-1) and are a model in which to study the role of this phosphatase in immune regulation and hemopoietic development. Immune defects in these mice include hypergammaglobulinemia, production of multiple autoantibodies, and glomerular nephritis. The presence of self-reactive Abs in these mice is an enigma, since it has been demonstrated that they have increased negative selection against self-reactive transgenic Abs. It was of interest to examine autoantibodies from these mice to identify reactivity or structural features that might account for their persistence and expansion in the repertoire. Abs to DNA were selected for investigation, since they have been characterized extensively from normal and autoimmune strains of mice. Viable motheaten mice had high titers of IgM, anti-dsDNA Abs, and all 12 anti-DNA hybridomas generated were also IgM. They had high avidity for dsDNA, also bound to ssDNA, but were not polyreactive. They used V(H) and V(L) gene families found in anti-DNA Abs from other strains, which reinforces evidence that there is preferential use of a restricted number of germline elements in anti-DNA Abs. The results indicate that Hcph-mutant mice do not delete DNA-reactive B cells, nor are they able to maintain these B cells in a state of anergy. Evidence for positive selection and clonal expansion after V-D-J rearrangement was also seen, in that several Abs expressed the same heavy chain in combination with different light chains, which is also a hallmark of the autoimmune anti-DNA response.

Use of a single VH family and long CDR3s in the variable region of cattle Ig heavy chains.

We have analyzed transcripts encoding the variable regions of Ig heavy chains from adult and fetal bovine splenocytes and bovine x mouse heterohybridomas. The 13 adult, seven fetal and two heterohybridomas transcripts as well as the six genes that were sequenced had > 83% identity to each other in the VH-encoded regions (FRs 1-3 and CDRs 1 and 2). By this criterion, all the bovine sequences were assigned to one family, which corresponds to the bovine homolog of the murine Q52 family. Southern blot analysis of genomic DNA demonstrated that homologs of other murine VH families such as 7183, S107 and 36-60 were present in the genome, but transcripts from these families were not detected in rapid amplification of cDNA ends (RACE)-PCR amplified products or in individual clones. The sequences of the adult transcripts using the mu isotype showed extensive somatic mutation indicating that the process of somatic hypermutation begins earlier in development of the bovine B cell. The length of CDR3 from V(D)J rearrangements averaged 21 amino acids, which is larger than other mammalian CDR3s. Analysis of CDR3s from 23 fetal transcripts revealed a preference for a reading frame in the putative D genes which is rich in glycine and tyrosine, and is also extensively mutated in adults. The bovine immune system appears to utilize Ig VH genes of a single family, but generates antibody diversity by extensive somatic mutation and long CDR3s which are subsequently hypermutated.

Role of non-anchor residues of Db-restricted peptides in class I binding and TCR triggering.

To understand better, the role of non-anchor residues of class I restricted T cell epitopes in class I binding and TCR stimulation, a panel of peptides was synthesized in which each of the non-anchor positions of the Db-restricted influenza peptide, ASNENMETM, was changed to each of the 20 natural amino acids (AAs). The relative affinity of all the peptides for Db was determined and their ability to stimulate anti-ASNENMETM cytotoxic T cell hybridomas was also assessed. The results illustrated that for Db binding, the AAs with the most solvent exposure had the smallest effect on binding. Changes at other positions affected binding to different degrees. Results for the recognition by the T cell hybridomas indicated that a peptide-MHC complex represents a multitude of epitopes, as each hybridoma recognized a different subset of peptides. Most changes in the highly solvent-exposed residues negatively affected recognition by all hybridomas while changes in other positions affected each hybridoma differently, independent of the direction of the side chain of the AA at that position. Furthermore, the use of saturating concentrations of low and high binding peptides showed that, as long as the class I-peptide complex is formed, the T-cell receptor does not differentiate between high and low binding peptides. This indicates that, although the stability of the class I-peptide complex is highly dependent on peptide affinity, the class I MHC conformation induced by low affinity peptides does not necessarily differ significantly from that induced by high affinity peptides. The results of peptide-class I recognition by one ASNENMETM-specific hybridoma was used to construct a peptide that differed from ASNENMETM at four of the nine residues, yet stimulated the hybridoma to a level comparable to ASNENMETM. In addition, peptides bearing the canonical Db-binding motif but unable to bind to the class I molecule with high affinity could be made to bind Db, by changing unfavorable AAs to favourable ones at appropriate positions. The extended motif determined was used to identify more accurately the peptides derived from Coxsakie b3 virus that would bind Db. It was also shown that some of the canonical characteristics of the peptide motif could be obviated and still obtain high affinity binding, provided optimal AAs, were present at secondary anchor positions.

Metal binding properties of a monoclonal antibody directed toward metal-chelate complexes.

A monoclonal antibody that recognizes cadmium-EDTA complexes has been produced by the injection of BALB/c mice with a metal-chelate complex covalently coupled to a carrier protein. The ability of purified antibody to recognize 16 different metal-EDTA complexes was assessed by measuring equilibrium binding constants using a KinExATM immunoassay instrument. The antibody bound to cadmium- and mercury-EDTA complexes with equilibrium dissociation constants of 21 and 26 nM, respectively. All other metal-EDTA complexes tested, including those of Mn(II), In(III), Ni(II), Zn(II), Co(II), Cu(II), Ag(I), Fe(III), Pb(II), Au(III), Tb(III), Ga(III), Mg(II), and Al(III) bound with affinities from 20- to 40,000-fold less than that determined for the cadmium-EDTA complex. With the exception of mercury and magnesium, the binding of divalent metal-chelate complexes was well-correlated with the size of the metal ion. The amino acid sequences of the heavy and light chain variable regions were deduced from polymerase chain reaction-amplified regions of the corresponding genes and subsequently used to construct molecular models of the antigen binding region. The key residue for cadmium binding in the model for 2A81G5 appeared to be histidine 96 in the heavy chain.

Investigation of the RH locus in gorillas and chimpanzees.

The human Rh blood-group system is encoded by two homologous genes, RhD and RhCE. The RH genes in gorillas and chimpanzees were investigated to delineate the phylogeny of the human RH genes. Southern blot analysis with an exon 7-specific probe suggested that gorillas have more than two RH genes, as has recently been reported for chimpanzees. Exon 7 was well conserved between humans, gorillas, and chimpanzees, although the exon 7 nucleotide sequences from gorillas were more similar to the human D gene, whereas the nucleotide sequences of this exon in chimpanzees were more similar to the human CE gene. The intron between exon 4 and exon 5 is polymorphic and can be used to distinguish the human D gene from the CE gene. Nucleotide sequencing revealed that the basis for the intron polymorphism is an Alu element in CE which is not present in the D gene. Examination of gorilla and chimpanzee genomic DNA for this intron polymorphism demonstrated that the D intron was present in all the chimpanzees and in all but one gorilla. The CE intron was found in three of six gorillas, but in none of the seven chimpanzees. Sequence data suggested that the Alu element might have previously been present in the chimpanzee RH genes but was eliminated by excision or recombination. Conservation of the RhD gene was also apparent from the complete identity between the 3'-noncoding region of the human D cDNA and a gorilla genomic clone, including an Alu element which is present in both species. The data suggest that at least two RH genes were present in a common ancestor of humans, chimpanzees, and gorillas, and that additional RH gene duplication has taken place in gorillas and chimpanzees. The RhCE gene appears to have diverged more than RhD among primates. In addition, the RhD gene deletion associated with the Rh-negative phenotype in humans seems to have occurred after speciation.

Db-binding peptides from influenza virus: effect of non-anchor residues on stability and immunodominance.

Relative affinities were determined for the interaction of H-2Db with all the peptides from the A/PR/8/34 strain of influenza virus that contained the Db-binding motif. The results indicated that, even though 23 peptides with the appropriate motif were identified and analysed, binding of only five of them could be detected at peptide concentrations lower than 10(-7) M. Of these five, only one, TGICNQNII, bound with better affinity than the nucleoprotein-derived natural epitope, ASNENMETM. The origin of the higher binding peptide was the influenza neuraminidase, a protein for which little cytosolic processing would be expected since it is a surface glycoprotein. To establish why many of the influenza-derived peptides did not bind, the role of non-anchor residues on Db-peptide interactions was analysed, using a scheme where QDIENEEKI, a non-binding peptide from the influenza virus polymerase 1, was sequentially converted to ASNENMETI, which binds to Db with an affinity similar to that of ASNENMETM. Although all positions examined influenced peptide binding, peptide residue no. 2 (P2) was of particular importance. Therefore, each of the 20 naturally occurring amino acids were inserted at this position to investigate their effects on peptide-MHC interaction. The results indicated that amino acids having side chains with charged or ring structures were deleterious, while non-polar and polar residues were either neutral or facilitated binding to different degrees. Our data also indicated that every residue of the peptide contributes to the stability of the MHC-peptide complex, and the final affinity is dependent on the nature of the amino acids at each position, not just on those at a small number of anchor positions. The results also suggested that increased stability, as indicated by the half-life of the peptide-MHC class I complex, might play an important role in selecting the immunodominant epitope.

A semiquantitative rosetting assay for detection of cell-surface class I major histocompatibility complex molecules.

A method for detection of cell-surface antigens, referred to as cell-bead immunoassay (CBIA), has been developed by cross-linking monoclonal antibodies specific for cell-surface antigens to protein G-agarose beads. In this case, the antibodies were specific for different murine class I major histocompatibility complex (MHC) antigens and murine beta 2 microglobulin. The antibody-conjugated beads were incubated with cells expressing the relevant MHC molecule and observed microscopically for rosette formation. The number of cells bound per bead correlated with the amount of class I MHC expressed per cell, as measured by fluorescence activated cell sorting (FACS) analysis. In addition, changes in the amount of surface antigen expressed after induction could be followed by CBIA. The advantages of CBIA over other commonly used techniques, such as FACS and immunofluorescence, are that it requires only a few minutes incubation after beads are prepared, and no further manipulations are needed after the cells and beads are mixed together. Although CBIA is primarily a qualitative technique, it can also be used semiquantitatively by determining the number of cells bound per bead.

Investigation of the human Rh blood group system in nonhuman primates and other species with serologic and Southern blot analysis.

To investigate the evolution of the Rh blood-group system in anthropoid apes, New and Old World monkeys, and nonprimate animals, serologic typing of erythrocytes from these species with antibodies specific for the human Rh blood-group antigens was performed. In addition, genomic DNA from these animals was analyzed on Southern blots with a human Rh-specific cDNA. Consistent with earlier reports, serologic results showed that gorilla and chimpanzee erythrocytes had epitopes recognized by human Rh D and c antisera, and gibbon erythrocytes were recognized by the c antisera. Surprisingly, some Old and New World monkeys also expressed a Rh c epitope on their erythrocytes. No erythrocytes from the nonprimate animals reacted specifically with any of the human Rh antisera. Southern blot analysis with a human Rh-specific cDNA probe detected Rh-related sequences in anthropoid apes, all New and Old World monkeys, and in most nonprimate animals tested. Although some Rh-related restriction fragments were conserved across species lines in primates, the Rh locus was more polymorphic in chimpanzees and gorillas than in humans. In addition, restriction fragments segregating with the presence of the D antigen in humans were present in the primate species that expressed the D antigen.

An investigation into the mechanism ofL-asparaginase resistance in L5178Y murine leukemia cells.

Resistance of leukemia cells toL-asparaginase is presumed to be due to increased expression of asparagine synthetase activity by resistant cells, so they are no longer dependent on an exogenous source ofL-asparagine for growth. The mechanism by which cells acquire the ability for increased enzyme expression, however, has not been clearly defined. Evidence presented here indicates that genomic alterations in the form of translocations, gene amplification, or increased P-glycoprotein expression, do not account for the phenotypic transformation fromL-asparaginase sensitivity toL-asparaginase resistance. Instead, both sensitive and resistant L5178Y cells contain immunoreactive material detected by Western blotting with an antiserum prepared against bovine pancreatic asparagine synthetase. This suggests that the mechanism of resistance might involve modification of asparagine synthetase inL-asparaginase-resistant cells by an as-yet-unidentified mechanism or by inhibition of enzyme activity in theL-asparaginase-sensitive cells.

Severe anaphylactic reactions following transfusions of platelets to a patient with anti-Ch.

The high-frequency Chido (Ch) antigen, found predominantly in plasma, is a determinant of the C4d fragment of the C4 molecule and is acquired by red cells during in vivo complement activation. Antibodies are made by Ch- people who lack C4S. It has often been reported that anti-Ch (and anti-Rg) do not cause hemolytic transfusion reactions. Reported here is a case of a transfusion reaction caused by anti-Ch. The antibody did not cause red cell destruction, but did cause a life-threatening anaphylactic reaction during transfusion of plasma proteins in pooled platelets. The antibody was of the IgG4 subclass and might have caused a short-term, sensitizing anaphylactic response. This case, and one previously reported in which a patient with anti-Rg experienced a severe reaction to fresh-frozen plasma and a plasma derivative, illustrates that these antibodies can cause severe, life-threatening reactions in patients who receive plasma-containing components.

Monoclonal antibodies specific for mercuric ions.

Monoclonal antibodies (mAbs) that react with soluble mercuric ions have been produced by injection of BALB/c mice with a hapten-carrier complex designed to maximize exposure of the metal to the immune system. Three hybridomas producing antibodies that reacted with bovine serum albumin (BSA)-glutathione-HgCl, but not with BSA-glutathione, were isolated from the spleen of a mouse given multiple injections with glutathione-HgCl conjugated to keyhole limpet hemocyanin. Stable subclones were established from two of these antibodies, designated mAb 4A10 and mAb 1F10. The binding of both antibodies to immobilized BSA-glutathione-HgCl was inhibited by soluble HgCl2, and dissociation constants for mercuric chloride binding were 2.3 and 3.7 nM for mAbs 4A10 and 1F10, respectively. Both antibodies bound mercuric acetate with similar affinities, demonstrating that the antibodies were capable of binding to mercuric ions in the presence of a different counterion than the one used in the immunogen. Reactions were not observed with other metal cations by either antibody. These data demonstrate the successful induction of antibodies that react very specifically with mercuric ions in solution regardless of the presence of a carrier.

Detection of mercuric ions in water by ELISA with a mercury-specific antibody.

An immunoassay that detects mercuric ions in water at concentrations of 0.5 ppb and above is described. The assay utilizes a monoclonal antibody that binds specifically to mercuric ions immobilized in wells of microtiter plates. Within the range of 0.5-10 ppb mercury, the absorbance in the enzyme-linked immunosorbent assay (ELISA) is linear to the log of the mercuric ion concentration. The quantitation of mercury by ELISA correlates closely with results from cold-vapor atomic absorption. Other divalent metal cations do not interfere with the assay, although there is interference in the presence of 1 mM chloride ions. The optimum pH for mercury detection is 7.0, although 2 ppb mercury can be detected over a wide pH range. The assay is as sensitive as cold-vapor atomic absorption for mercury detection and can be performed with only 100 microliters of sample.

Glycosylation of eukaryotic peptide chain initiation factor 2 (eIF-2)-associated 67-kDa polypeptide (p67) and its possible role in the inhibition of eIF-2 kinase-catalyzed phosphorylation of the eIF-2 alpha-subunit.

We have reported previously that a 67-kDa polypeptide (p67) present in reticulocyte lysates protects the alpha-subunit of reticulocyte eukaryotic peptide chain initiation factor 2 (eIF-2) from phosphorylation by an eIF-2 kinase, heme-regulated protein synthesis inhibitor (Datta, B., Chakrabarti, D., Roy, A.L., and Gupta, N. K. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3324-3328). We now present evidence that this p67 contains multiple O-linked N-acetylglucosamine (GlcNAc) residues, and these glycosyl residues may be required for p67 activity to protect the eIF-2 alpha-subunit from eIF-2 kinase phosphorylation. Our results are as follows. 1) p67 binds specifically to wheat germ agglutinin, and such binding is completely inhibited in the presence of 0.2 M GlcNAc. 2) The binding of p67 to wheat germ agglutinin leads to complete loss of p67 activity to protect the eIF-2 alpha-subunit from eIF-2 kinase phosphorylation. 3) p67 accepts 10-12 [3H]galactose molecules from UDP-[3H]galactose in the presence of galactosyltransferase. This radioactivity is resistant to endo-beta-N-acetylglucosamine F (+ peptide:N-glycosidase F) treatment but is completely lost when the 3H-labeled p67 is treated with sodium borohydride in mild alkali (beta-elimination reaction). These results suggest that p67 contains terminal GlcNAc moieties O-linked to the protein. 4) Upon hexosaminidase treatment, p67 reaction product migrated as a lower molecular mass (Mr approximately 65 kDa) protein in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. 5) A monoclonal antibody (D1) against p67 has been isolated. D1 apparently recognizes a specific GlcNAc-containing peptide epitope in p67 and does not react with hexosaminidase-treated p67. These results suggest that p67 activity in the cell may also be regulated post-transcriptionally by glycosylation of p67 protein.