Immunogenetic studies of rhesus monkeys

Five alloimmune blood typing reagents have been produced which define five new blood group systems in rhesus monkeys. Each of the five independent blood group loci is comprised of a detectable allele and a null allele. Using these new reagents and those previously described, we can potentially identify close to a million phenotypes in rhesus monkeys.     

Trinitrophenylation of the bilirubin binding site of human serum albumin.

Human serum albumin has been modified with 2,4,6-trinitrobenzenesulphonic acid and picryl chloride in low ratios of reagents/albumin. The derivatives have been investigated by spectrophotometry and by thin layer chromatography of the hydrolysates in order to assess the specificity of the reagents. The same reaction conditions were used to modify albumin previously complexed with bilirubin in the ratio of 1:1. The affinity of bilirubin to the modified albumins was estimated by an improved perozidase method. It is concluded that TNBS and picryl chloride react almost quantity with epsilon-amino groups of lysine on the albumin molecule. The results also suggest that at least on TNBS reactive amino group and at least one picryl chloride reactive amino group are located in or near the high-affinity bilirubin binding site.     

Immunogenetic studies of rhesus monkeys

Five alloimmune rhesus monkey blood typing reagents have been produced which define two new blood group loci inMacaca mulatto. Three of these reagents detect blood group factors at theM locus; the other two detect factors at theN locus. By typing over 1900 pedigreed monkeys we have established that these two loci are independent of each other and of any of our previously defined blood group systems.     

Three new blood groups of rhesus monkeys

Three new blood group systems, called “T,” “U,” and “V,” have been identified in the rhesus monkey (Macaca mulatta). Each system consists of a single antigenic factor (blood group) detected by a monospecific alloimmune reagent that agglutinates erythrocytes. The antisera that detect these blood groups were obtained following a series of alloimmunizations and absorption fractionizations of the resulting antisera to produce operationally monospecific typing reagents. Analyses of family data indicated that each blood group was controlled by an autosomal dominant gene and that each system was independent of previously defined systems. With the addition of these new blood groups, we can identify 16 different blood group systems and well over one hundred million possible phenotypes in this species.     

Caprine blood groups. 2. The C,G, H,I, J,K, L,N, and Q systems

Nine blood group systems of goats were identified using 12 caprine reagents produced by absorption of alloimmune antisera. The caprine C blood group system, possibly homologous to the ovine C blood group system, was characterized by two reagents and shown to be controlled by three alleles,C ¹²,C ²⁵, andC ⁻. A more complex blood group system of goats, designated G, was identified using three reagents and shown to be controlled by six codominant alleles (G ^10.19.20,G ^10.19,G ^10.20,G ¹⁰,G ¹⁹,G ²⁰) and a recessive allele (G ⁻). A further seven one-factor two-allelic systems were identified by seven reagents. The nine genetic systems provided exclusion probabilities of 0.479, 0.492, 0.548, and 0.572 in Australian Angora, Dairy, Cashmere, and Texan Angora goat breeds, respectively. This work was supported by a grant from the Australian Stud Book, Alison Road, Randwick, New South Wales 2031, Australia.     

Unmasking of an essential thiol during function of the membrane bound enzyme II of the phosphoenolpyruvate glucose phosphotransferase system of Escherichia coli.

The addition of N-ethylmaleimide (MalNEt), or of fluoro dinitrobenzene to a suspension of Escherichia coli during the phosphorylating uptake of methyl-alpha-D-glucopyranoside (Me-Glc), a glucose analog, stops uptake and phosphorylation and causes the loss of previously accumulated sugar and of its phosphate ester. After removal of the reagents, the phosphotransferase system remains irreversibly inactive. Pretreatment of the bacteria with the same reagents under the same conditions of concentration, pH, temperature and for the same length of time causes very little inactivation. Mercuric chloride, a reversible inactivator, prevents the phosphotransferase system from reacting simultaneously with MaINEt or with fluorodinitrobenzene. This protection strongly suggests that all three reagents react with the same site, presumably an -SH group. The change which makes this site available to the reagents depends on the phosphorylative uptake of Me-Glc. Preload of the cells and efflux of Me-Glc do not achieve the same change. The rate of inactivation is directly proportional to the rate of phosphorylative uptake. When the Km of phosphorylative uptake is modified by an uncoupling agent, the substrate concentration allowing half maximal rate of inactivation by MaINEt changes accordingly. The reactive sites of the phosphotransferase system can also be made accessible to the -SH group reagents by fluoride inhibition of phosphoenolpyruvate synthesis. This suggests that the inactivator resistent form is an "energized form" of the enzyme. The unmasking of the reactive site is not due to a change in transmembrane penetration of the reagents since incubation of toluene treated cells with MaINEt in the presence of phosphoenolpyruvate fails to inactivate the phosphotransferase activity, while incubation with MaINEt plus Me-Glc causes fast inactivation.     

What we can learn from the effects of thiol reagents on transport proteins.

Many secondary membrane transport systems contain reactive sulfhydryl groups. In this review the applications of SH reagents for analyzing the role of sulfhydryl groups in membrane transport systems will be discussed. First an overview will be given of the more important reagents, that have been used to study SH-groups in membrane transport systems, and examples will be given of transport proteins in which the role of cysteines have been analyzed. An important application of SH-reagents to label transport proteins using various SH-reagents modified with fluorescent- or spin-label moieties will be discussed. Two general models are shown which have been proposed to explain the role of sulfhydryl groups in some membrane transport systems.     

Blood groups of anthropoid apes and their relationship to human blood groups

Affinity between blood groups of man and those of anthropoid apes is reflected not only in similarities or identities of reactions of the red cells with many specific typing reagents, but also in overall structures of some of the main blood group systems defined in man and in apes.Besides specificities of human-type, such as A-B-O, M-N, Rh-Hr, I-i, etc. known to be present on the red cells of various species of apes, specific reagents were produced by iso- or cross-immunization of chimpanzees that detect red cell specificities characteristic for apes only. Some of those specificities were found to be shared by several ape species and to fall into separate blood group systems that are counterparts of the human blood group systems. Recently obtained serological, as well as population data, indicate that the chimpanzee R-C-E-F blood group system is the counterpart of the human Rh-Hr system. Similarly to the Rh-Hr system, it is built around a main antigen, the R^c antigen, to which secondary specificities are attached by means of multiple allelic genes. The R^c is not only the principal factor of the chimpanzee R-C-E-F group system, but also constitutes a direct link with the human Rh-Hr blood group system, since anti-R^c reagents also detect Rh₀ specificity on the human red cells. Another chimpanzee blood group system, the V-A-B-D system, is counterpart of the M-N-S-s system, and is built around the central antigen V^c. the V^c is not only the principal specificity of the chimpanzee V-A-B-D system, but it also constitutes the direct link with the human M-N-S-s system since anti-V^c reagent gives with chimpanzee red cells reactions parralleling those obtained with anti-N lectin (N^v) while in tests with human red cells it detects specificity identical or closely related to the Mi^a specificity.     

Surface polypeptides of the cultured Chinese hamster ovary cell.

The organization of the plasma membrane of logarithmically growing Chinese hamster ovary (CHO) suspension cells has been probed using surface label techniques in conjunction with subcellular fractionation and sodium dodecyl sulfate gel electrophoresis. Five components of apparent molecular weights 137,000, 121,000, 97,000, 67,000, and 57,000 have been shown to be exposed at the outer surface of the cell. These components fully meet the criteria of being (a) reactive with two or more surface label reagents, (b) enriched in a purified plasma membrane fraction, and (c) sensitive to proteolytic digestion of intact cells. Three other components of molecular weights 200,000, 44,000 and 30,000 are also reactive with certain surface label reagents, but fail to meet other criteria for cell surface components. Two polypeptides of molecular weights 180,000 and 37,000 are substantially enriched in the plasma membrane fraction, but are unreactive with surface label reagents. The organization of the CHO cell membrane and the applicability of surface label techniques to cultured cell systems are discussed.     

Chemical modifications of the crystalline quinolinate phosphoribosyltransferase from hog liver.

Amino acid analysis and chemical modification of the crystalline quinolinate phosphoribosyltransferase (EC 2.4.2.19) from hog liver were performed. The enzyme contained 29 residues of half cystine per mol. The enzyme activity was strongly inhibited by sulfhydryl reagents. The number of reactive (exposed) sulfhydryl group was determined to be 10.2 and total sulfhydryl group was to be 25.2 per mol by using 5,5'-dithiobis(2-nitrobenzoic acid). The enzyme activity was also inhibited by lysine residue-, histidine residue-, and arginine residue-modifying reagents. These results and the effect of preincubation with the substrates on chemical modifications suggest that the lysine residue, histidine residue and sulfhydryl group may be closely related to the binding site of quinolinic acid.     

Soluble blood group reactive substances in the hemolymph of Biomphalaria glabrata (Mollusca)

The hemagglutinating activity of Biomphalaria glabrata hemolymph was examined with different erythrocyte samples of several human donors. The agglutinin was not specific for the ABO blood group antigens of man. In further tests, the hemolymph was investigated for soluble inhibitors of anti-human blood group agglutinins. An inhibition was observed with respect to human anti-A and anti-B isoagglutinins as well as to anti-P and anti-H reagents. These results were confirmed in agar-gel double diffusion tests: The hemolymph showed very strong precipitation lines with several anti-A, anti-B, and anti-H lectins of invertebrate and plant origins. Some of the indicated blood group reactive substances were identified as glycoproteins. The role of these sugar-containing macromolecules in the relationship between Schistosoma miracidia and the intermediate host snail Biomphalaria glabrata is discussed.     

The reactions of phenylglyoxal and related reagents with amino acids.

1. The reaction of phenylglyoxal (PGO), glyoxal (GO), and methylglyoxal (MGO) with amino acids were investigated at mild pH values at 25 degrees. These aldehydes reacted most rapidly with arginine and the rate of reaction increased with increasing pH values. Histidine, cystine, glycine, tryptophan, asparagine, glutamine, and lysine reacted with these aldehydes at significant but various rates, depending on the pH and the kind of the reagent used. The reactions with these amino acids seemed to involve both the alpha-amino groups and the side chain groups, and no significant reaction appeared to occur with the side chain alone except with those of arginine, lysine, and cysteine. These reagents were similarly reactive with the guanidinium group of arginine, but PGO appeared to be much less reactive with the epsilone-amino group of lysine than MGO and GO. The other ordinary amino acids were very much less reactive or did not react at all with these reagents, with the exception of cysteine. 2. Di-PGO-L-arginine was prepared from Nalpha-benzyloxycarbonyl-L-arginine, and di-PGO-methylguanidine from methylguanidine, and the stoichiometry of the reaction of two PGO molecules with one guanidino group was confirmed. A glyoxal derivative of L-arginine (GO-arginine) was prepared by reaction of glyoxal with arginine. GO-arginine was fairly unstable, especially at higher pH values. A similar derivative (MGO-arginine) was also found to be formed by reaction of MGO with L-arginine, and was similarly unstable. These derivatives, however, did not regenerate arginine upon acid hydrolysis.     

Structure and function of the Ah receptor: sulfhydryl groups required for binding of 2,3,7,8-tetrachlorodibenzo-p-dioxin to cytosolic receptor from rodent livers

Cytosol from rodent liver was exposed to a variety of sulfhydryl-modifying reagents to determine if the cytosolic Ah receptor contained reactive sulfhydryl groups that were essential for preservation of the receptor's ligand binding function. At a 2 mM concentration in rat liver cytosol, all sulfhydryl-modifying reagents tested (except iodoacetamide) both blocked binding of [3H]2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) to unoccupied receptor and caused release of [3H]TCDD from receptor sites that had been labeled with [3H]TCDD before exposure to the sulfhydryl-modifying reagent. Exposure of cytosol to iodoacetamide before labeling with [3H]TCDD prevented subsequent specific binding of [3H]TCDD, but iodoacetamide was not effective at displacing previously bound [3H]TCDD from the Ah receptor. The mercurial reagents, mersalyl, mercuric chloride, and p-hydroxymercuribenzoate, were more effective at releasing bound [3H]TCDD from previously labeled sites than were alkylating agents (iodoacetamide, N-ethylmaleimide) or the disulfide compound 5,5'-dithiobis(2-nitrobenzoate). Presence of bound [3H]TCDD substantially protected the Ah receptor against loss of ligand binding function when the cytosol was exposed to sulfhydryl-modifying reagents. This may indicate that the critical sulfhydryl groups lie in or near the ligand binding site on the receptor. Subtle differences exist between the Ah receptor and the receptors for steroid hormones in response to a spectrum of sulfhydryl-modifying reagents, but the Ah receptor clearly contains a sulfhydryl group (or groups) essential for maintaining the receptor in a state in which it can bind ligands specifically and with high affinity.     

Phenotypic variations in blood and milk of the Somali camel

132 blood samples and 54 milk samples obtained from Somali camel were analysed for red blood cell antigens with the cattle reagents and for Hb, Ca, X proteins, Tf, Alb, Am, SOD, alpha-La, beta-Lg and casein systems respectively. Positive lytic reactions were obtained with the anti-B, -Q, -Q', -W, -F1 and -J reagents. No biochemical polymorphism was observed except for Hb, X protein and beta-Lg systems.     

Unmasking of an essential thiol during function of the membrane bound enzyme II of the phosphoenolpyruvate glucose phosphotransferase system of Escherichia coli

The addition of N-ethylmaleimide (MalNEt), or of fluoro dinitrobenzene to a suspension of Escherichia coli during the phosphorylating uptake of methyl-α-d-glucopyranoside (Me-Glc), a glucose analog, stops uptake and phosphorylation and causes the loss of previously accumulated sugar and of its phosphate ester. After removal of the reagents, the phosphotransferase system remains irreversibly inactive.Pretreatment of the bacteria with the same reagents under the same conditions of concentration, pH, temperature and for the same length of time causes very little inactivation. Mercuric chloride, a reversible inactivator, prevents the phosphotransferase system from reacting simultaneously with MalNEt or with fluorodinitrobenzene. This protection strongly suggests that all three reagents react with the same site, presumably an -SH group.The change which makes this site available to the reagents depends on the phosphorylative uptake of Me-Glc. Preload of the cells and efflux of Me-Glc do not achieve the same change.The rate of inactivation is directly proportional to the rate of phosphorylative uptake. When the K_m of phosphorylative uptake is modified by an uncoupling agent, the substrate concentration allowing half maximal rate of inactivation by MalNEt changes accordingly.The reactive sites of the phosphotransferase system can also be made accessible to the -SH group reagents by fluoride inhibition of phosphoenolpyruvate synthesis. This suggests that the inactivator resistent form is an “energized form” of the enzyme.The unmasking of the reactive site is not due to a change in transmembrane penetration of the reagents since incubation of toluene treated cells with MalNEt in the presence of phosphoenolpyruvate fails to inactivate the phosphotransferase activity, while incubation with MalNEt plus Me-Glc causes fast inactivation.     

Phenotypic variations in blood and milk of the Somali camel*

132 blood samples and 54 milk samples obtained from Somali camel were analysed for red blood cell antigens with the cattle reagents and for Hb, Ca, X proteins, Tf, Alb, Am, SOD, α-La, β-Lg and casein systems respectively. Positive lytic reactions were obtained with the anti-B, -Q, -Q, -W, -F₁ and -J reagents. No biochemical polymorphism was observed except for Hb, X protein and β-Lg systems.     

Two-hydronic-reactive states of acetylcholinesterase, mechanistically relevant acid-base catalyst of pKa 6.5 and a modulatory group of pKa 5.5

Variation of experimentally observed pKa values in pH-dependent kinetic studies using acetylcholinesterase (AcChE) is rationalized by proposal of two-hydronic-reactive states, EH and EH2, of the free AcChE molecule. Two kinetically influential ionizations with pKa 6.5 for the general acid-base catalyst, possibly the imidazole group of histidine, and a modulatory group with pKa 5.5 residing at the juxtaposal modulatory site, provided fundamental bases for the observed variation in pK(app) values. Appropriate equations applicable to the proposed kinetic model in conjunction with pKa values (pKI 5.5, pKII 6.5) and relative varied values of the pH-independent rate constants, k'cat/K'm and kcat/Km, of the reactive states were used to generate computer simulation error-free pH-rate profiles. A series of theoretical apparently simple sigmoidal pH-rate profiles with characterizing parameters pK(app) varying between 5.5-6.5 were obtained. Ionization of a modulatory group with pKa 5.5 alone modifies the reaction mechanism of AcChE, and binding of substrates and inhibitors at this site provides modulation of catalysis/binding at the active center. Analysis of the relative magnitudes of pH-independent rate constants for the two reactive states revealed that in terms of the overall catalysis, the EH state shows favorable reactivity towards the cationic reagents with reactivity 1.0, as compared to the EH2 state with reactivities 0.25-0.55. Neutral reagents, in general, make use of the EH2 state more than cationic reagents, with reactivities 1.0 for the EH state and 0.3-1.0 for the EH2 state. Further analysis showed that this discrimination between the two reactive states, by both types of reagents, occurs predominantly through the difference in binding constants K'm and Km. Relative binding of a given cationic reagent to the respective reactive states ranges from K'm = 1.8 X Km to 4.0 X Km, and from K'm = 1.0 X Km to 2.0 X Km for the neutral reagents.     

The time of appearance of blood group antigens in miniature pigs

Erythrocytes of foetuses and piglets of miniature pigs of different age were tested with 50 to 55 blood group reagents of 15 genetic systems. Out of 49 blood factors found to be present in parent animals, 40 were present in 34–46-day-old foetuses. Factor Kb was detected in 66-day-old foetuses, and other factors of the K system (Ka, Kc, Kd and Ke) at 77 days of age. Factor A was demonstrated in one day old piglets, factor 0 not earlier than in piglets aged 13 to 24 days.     

DNA duplexes with reactive dialdehyde groups as novel reagents for cross-linking to restriction- modification enzymes.

To create new, effective reagents for affinity modification of restriction-modification (R-M) enzymes, a regioselective method for reactive dialdehyde group incorporation into oligonucleotides, based on insertion of a 1-beta-D-galactopyranosylthymine residue, has been developed. We synthesized DNA duplex analogs of the substrates of the Eco RII and Mva I R-M enzymes that contained a galactose or periodate-oxidized galactose residue as single substituents either in the center of the Eco RII (Mva I) recognition site or in the flanking nucleotide sequence. The dependence of binding, cleavage and methylation of these substrate analogs on the modified sugar location in the duplex was determined. Cross-linking of the reagents to the enzymes under different conditions was examined. M. Eco RII covalent attachment to periodate-oxidized substrate analogs proceeded in a specific way and to a large extent depended on the location of the reactive dialdehyde group in the substrate. The yield of covalent attachment to a DNA duplex with a dialdehyde group in the flanking sequence with Eco RII or Mva I methylases was 9-20% and did not exceed 4% for R. Eco RII.