Investigation of the RH locus in gorillas and chimpanzees

The human Rh blood-group system is encoded by two homologous genes,RhD andRhCE. TheRH genes in gorillas and chimpanzees were investigated to delineate the phylogeny of the humanRH genes. Southern blot analysis with an exon 7-specific probe suggested that gorillas have more than twoRH 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 humanD gene, whereas the nucleotide sequences of this exon in chimpanzees were more similar to the humanCE gene. The intron between exon 4 and exon 5 is polymorphic and can be used to distinguish the humanD gene from theCE gene. Nucleotide sequencing revealed that the basis for the intron polymorphism is anAlu element inCE which is not present in theD gene. Examination of gorilla and chimpanzee genomic DNA for this intron polymorphism demonstrated that theD intron was present in all the chimpanzees and in all but one gorilla. TheCE intron was found in three of six gorillas, but in none of the seven chimpanzees. Sequence data suggested that theAlu element might have previously been present in the chimpanzeeRH genes but was eliminated by excision or recombination. Conservation of theRhD gene was also apparent from the complete identity between the 3′-noncoding region of the human D cDNA and a gorilla genomic clone, including anAlu element which is present in both species. The data suggest that at least twoRH genes were present in a common ancestor of humans, chimpanzees, and gorillas, and that additionalRH gene duplication has taken place in gorillas and chimpanzees. TheRhCE gene appears to have diverged more thanRhD among primates. In addition, theRhD gene deletion associated with the Rh-negative phenotype in humans seems to have occurred after speciation. Correspondence to: C.M. Westhoff     

Rh gene evolution in primates: study of intron sequences

By amplification and sequencing of RH gene intron 4 of various primates we demonstrate that an Alu-Sx-like element has been inserted in the RH gene of the common ancestor of humans, apes, Old World monkeys, and New World monkeys. The study of mouse and lemur intron 4 sequences allowed us to precisely define the insertion point of the Alu-Sx element in intron 4 of the RH gene ancestor common to Anthropoidea. Like humans, chimpanzees and gorillas possess two types of RH intron 4, characterized by the presence (human RHCE and ape RHCE-like genes) or absence (human RHD and ape RHD-like genes) of the Alu-Sx element. This led us to conclude that in the RH common ancestor of humans, chimpanzees, and gorillas, a duplication of the common ancestor gene gave rise to two genes, one differing from the other by a 654-bp deletion encompassing an Alu-Sx element. Moreover, most of chimpanzees and some gorillas posses two types of RHD-like intron 4. The introns 4 of type 1 have a length similar to that of human RHD intron 4, whereas introns 4 of type 2 display an insertion of 12 bp. The latest insertion was not found in the human genome (72 individuals tested). The study of RH intron 3 length polymorphism confirmed that, like humans, chimpanzees and gorillas possess two types of intron 3, with the RHD-type intron 3 being 289 bases shorter than the RHCE intron 3. By amplification and sequencing of regions encompassing introns 3 and 4, we demonstrated that chimpanzee and gorilla RH-like genes displayed associations of introns 3 and 4 distinct to those found in man. Altogether, the results demonstrate that, as in humans, chimpanzee and gorilla RH genes experienced intergenic exchanges.     

The human CD38 gene: polymorphism, CpG island, and linkage to the CD157 (BST-1) gene

 CD38 is a leukocyte activation antigen and ectoenzyme [NAD(P)⁺ glycohydrolase; EC 3.2.2.6] involved in numerous immune functions. The human CD38 gene is complex [eight exons, >80 kilobases (kb) long] located on Chromosome 4p15, and part of the eukaryotic NAD⁺ glycohydrolase/ADP-ribosyl cyclase gene family. Because of the increasing relevance of the CD38 molecule in the host immune response to infectious, tumoral, and metabolic diseases, we investigated the genetic variability and linkage of the human CD38 locus. We report that (1) the restriction endonuclease Pvu II identifies a bi-allelic polymorphism here defined as formed by the alleles CD38 ^* A (12 kb) and CD38 ^* B (9/2.5 kb); (2) their frequency in the healthy Italian Caucasian population is 14% and 86%, respectively; (3) the polymorphic Pvu II site is located at the 5′ end of the first intron of the CD38 gene; (4) in conjunction with the polymorphic site, we identified a 900 base pair CpG island associated with the CD38 gene, with two potential Sp1 binding sites; (5) the CpG island may play a role in the regulation of CD38 expression and is hypomethylated in various cell lines; (6) by pulsed-field gel electrophoresis we show that CD38 and its paralogue, the bone-marrow stromal cell antigen BST-1 (CD157), map to the same 800 kb Avi II fragment, indicating that the two human ecto-NADase genes are closely linked. Received: 16 December 1998 / Revised: 26 January 1999     

Cloning,Nucleotide Sequence,and Disruption of Streptococcus mutans Glutathione Reductase Gene (gor)

We cloned and sequenced the glutathione reductase gene (gor) of an oxygen-tolerant Streptococcus mutans, and constructed a gor-disruption mutant by homologous recombination. The gor gene consisted of 1,350 bp, coding for a protein of 450 amino acid residues. The deduced amino acid sequence of the S. mutans gor gene product showed extensive similarity with those of glutathione reductases from prokaryotes and eukaryotes. Although the mutant could grow aerobically, it showed no growth in the presence of 2 mM diamide, a thiol-specific oxidant. In contrast, growth of the wild-type strain was not significantly inhibited by 2 mM diamide, and glutathione reductase activity was increased 2.2-fold under these conditions. In addition, the level of glutathione reductase activity in the wild-type strain was increased 3.6-fold upon exposure to air, and the elevated level of the enzyme was retained throughout the aerobic growth. Thus, glutathione reductase may be important in protection of S. mutans against oxidative stress.     

Evolution of RH genes in hominoids: characterization of a gorilla RHCE-like gene

The human RH locus is responsible for the expression of the Rh blood group antigens. It consists of two closely linked genes, RHD and RHCE, that exhibit 92% similarity between coding regions. These observations suggest that they are derived from a relatively recent duplication event. Previously a study of nonhuman primate RH-like genes demonstrated that ancestral RH gene duplication occurred in the common ancestor of man, chimpanzees and gorillas. By amplification of intron 3 and intron 4 of gorilla RH-like genes, we have now shown that, like man, gorillas possess two types of RH intron 3 (RHCE intron 3 being 289 bp longer than the RHD intron 3) and two types of intron 4 (RHCE intron 4 being 654 bp longer than the RHD intron 4). Here we report the characterization of a cDNA encoded by a gorilla RH-like gene which possesses introns 3 and 4 of the RHCE type. A comparison of this gorilla RHCE-like coding sequence with previously characterized human and ape cDNA sequences suggests that RH genes experienced complex recombination events after duplication in the common ancestor of humans, chimpanzees and gorillas.     

Localization of pyrophosphatase in membranes of cauliflower inflorescence cells

Using a polyclonal antiserum specific for the tonoplastic H⁺-pyrophosphatase (tPPase), significant amounts of antigenic polypeptides of the correct molecular mass were detected in Western blots of plasma membrane isolated from cauliflower (Brassica oleracea L.) inflorescence by phase-partitioning and subsequent sucrose density centrifugation. Potassium iodide-stripped plasma membranes continued to give a strong positive signal, indicating that the PPase antigen detected was not a result of contamination through soluble PPase released during homogenisation. The same preparation contained negligible vacuolar (v)H⁺-ATPase activity and the A subunit of the vATPase could not be detected by immunoblotting. Plasma membrane fractions exhibited a proton-pumping activity with ATP as substrate, but such an activity was not measurable with pyrophosphate, although the hydrolysis of this substrate was recorded. By contrast, pyrophosphate supported proton pumping in tonoplast-containing fractions. Immunogold electron microscopy confirmed the presence of PPase at the plasma membrane as well as at the tonoplast, trans Golgi network, and multivesicular bodies. The density of immunogold label was higher at the plasma membrane than at the tonoplast, except for membrane fragments occurring in the lumen of the vacuoles which stained very conspicuously. Received: 29 June 1998 / Accepted: 9 November 1998     

Association of cattle growth hormone gene polymorphism with milk productivity

Polymorphisms in two growth hormone (GH) gene regions, intron 3 (MspI-polymorphism) and exon 4 (AluI polymorphism), and their association with milk productivity in Black Pied, Bestuzhevskaya, and Simmental cattle breeds have been studied. It was shown that allele GH ^V at the AluI polymorphic site and allele GH ^D at the MSPI polymorphic site of the GH gene, particularly in homozygous state, were more favorable in terms of agricultural importance than the GH ^L and GH ^C alleles.     

Genetic Polymorphism of Cat (Felis catus) Plasma Orosomucoid

Genetic polymorphism of orosomucoid (ORM) was observed in 22 breeds of cats (Felis catus) using isoelectric focusing (pH 4.0–6.5) of desialylated plasmas followed by immunoblotting with rabbit antiserum to human ORM. From a total of 943 plasma samples examined, 15 phenotypes were identified and family studies demonstrated an inheritance of five codominant alleles, ORM^A, ORM^B, ORM^C, ORM^D, and ORM^E, at a single locus.     

Lineage-Specific Homogenization of the Polyubiquitin Gene Among Human and Great Apes

Ubiquitin is a highly conserved protein, and is encoded by a multigene family among eukaryote species. The polyubiquitin genes, UbB and UbC, comprise tandem multiple ubiquitin coding units without a spacer region or intron. We determined nucleotide sequences for the UbB and UbC of human, chimpanzee, gorilla, and orangutan. The ubiquitin repeat number of UbB was constant (3) in human and great apes, while that of UbC varied: 6 to 11 for human, 10 to 12 for chimpanzee, 8 for gorilla, and 10 for orangutan. The heterogeneity of the repeat number within closely related hominoid species suggests that a lineage-specific unequal crossover and/or gene duplication occurred. A marked homogenization of UbC occurred in gorilla with a low level of synonymous difference (p_s). The homogenization of UbC also occurred in chimpanzee and less strikingly in human. The first and last ubiquitin coding units of UbC were clustered independently between species, and less affected by homogenization during the hominoid evolution. Therefore, the homogenization of ubiquitin coding units is likely due to an unequal crossing-over inside the ubiquitin units. The lineage-specific homogenization of UbC among closely related species suggests that concerted evolution has a key role in the short-term evolution of UbC.     

Identification of new TAP2 alleles in gorilla: evolution of the locus within hominoids

 Transporters associated with antigen processing molecules (TAP1 and TAP2) mediate the transfer of cytosolic peptides into the lumen of the endoplasmic reticulum for association with newly synthesized class I molecules of the major histocompatibility complex. Previous molecular and functional analyses of rat and human TAP2 homologues indicated major differences in gene diversification patterns and selectivity of peptides transported. Therefore, in this study, we analyzed the alleles of the gorilla TAP2 locus to determine whether the pattern of diversification resembled that in either of those two species. Sequence analysis of the TAP2 cDNAs from gorilla Epstein-Barr virus-transformed B-cell lines revealed four alleles with a genetic distance of less than 1%. The nucleotide substitutions distinguishing the alleles are confined to the 3′ half of the coding region and occur individually or within two small clusters of variability. Diversification of the locus appears to have resulted from point substitutions and recombinational events. Evolutionary-rate estimates for the TAP2 gene in gorilla and human closely approximate those observed for other hominoid genes. The amino acid polymorphisms within the gorilla molecules are distinct from those in the human homologues. The absence of ancestral polymorphisms suggests that gorilla and human TAP2 genes have not evolved in a trans-species fashion but rather have diversified since the divergence of the lineages. Received: 3 January 1996 / Revised: 28 March 1996     

Genome-scale identification of resistance gene analogs and the development of their intron length polymorphism markers in maize

As introns are vulnerable to changes such as insertions and deletions when exposed to various evolutionary forces, they constitute a repository for developing genetic markers based on intron length polymorphisms (ILP). This study developed a set of genetic markers that use the potential intron length polymorphism in resistance gene analogs (RGAs) in Zea mays. By searching the genome of Zea mays B73 for the homologs of 73 R genes which have already been identified in plants, we found 861 RGAs, 632 of which have at least one intron that can serve as putative markers targeting the intron length polymorphism in RGAs (RGA-ILP). We developed 1972 candidate markers via electronic PCR (e-PCR) with primer pairs designed in each pair of exonic regions that flank an intron. Furthermore, the performance of RGA-ILP among four maize inbred lines (Huangzao4, B73, Mo17, and Dan340) was evaluated with 69 pairs of randomly selected primers. Of them, 46.4% showed bands that had discriminating length polymorphism, and between any two of the inbred lines the proportion of polymorphism ranged from 23.2 to 31.9%. To make it convenient to use these markers for those interested in molecular breeding of disease-resistant maize, we provide all related information in a web-based database named MaizeRGA, which is available at .     

Nonequivalence of Classical MHC Class I Loci in Ability to Direct Effective Antiviral Immunity

Structural diversity in the peptide binding sites of the redundant classical MHC antigen presenting molecules is strongly selected in humans and mice. Although the encoded antigen presenting molecules overlap in antigen presenting function, differences in polymorphism at the MHC I A, B and C loci in humans and higher primates indicate these loci are not functionally equivalent. The structural basis of these differences is not known. We hypothesize that classical class I loci differ in their ability to direct effective immunity against intracellular pathogens. Using a picornavirus infection model and chimeric H-2 transgenes, we examined locus specific functional determinants distinguishing the ability of class I sister genes to direct effective anti viral immunity. Whereas, parental FVB and transgenic FVB mice expressing the H-2K^b gene are highly susceptible to persisting Theiler''s virus infection within the CNS and subsequent demyelination, mice expressing the D^b transgene clear the virus and are protected from demyelination. Remarkably, animals expressing a chimeric transgene, comprised primarily of K^b but encoding the peptide binding domain of D^b, develop a robust anti viral CTL response yet fail to clear virus and develop significant demyelination. Differences in expression of the chimeric K^bα1α2D^b gene (low) and D^b (high) in the CNS of infected mice mirror expression levels of their endogenous H-2^q counterparts in FVB mice. These findings demonstrate that locus specific elements other than those specifying peptide binding and T cell receptor interaction can determine ability to clear virus infection. This finding provides a basis for understanding locus-specific differences in MHC polymorphism, characterized best in human populations.     

H-2 effects on cell-cell interactions in the response to single non-H-2 alloantigens

Individual mice were tested for their proliferative T-cell response to H-Y- and H-3-incompatible stimulator cells in secondary mixed lymphocyte culture. Responders expressing the H-2 ^bhaplotype were restricted in their response to stimulators presenting H-Y and H-3 in the context of H-2 ^b. Lymphocytes from individual B10 females proliferated in response to H-Y presented with I-A ^band D ^b. The ratio of I-A ^b/D ^b-restricted responses varied between individual responders, indicating significant qualitative variation between genetically identical responders. The majority of the proliferative response in all tested mice was restricted to the entire H-2 ^bhaplotype suggesting complementation of I-A ^b- and D ^b-region genes in presenting the H-Y antigen. Similar observations were made in the response of individual B10.LP mice to the H-3 antigen. H-3-specific, proliferating T cells were restricted to H-3 antigen presented with K ^bA^band D ^bwith significant variation between individuals in their preference for H-3 plus K ^bA^band D ^b. In contrast to the response to H-Y, the proliferative response to H-3 plus H-2 ^bcould be accounted for by the summation of the proliferative responses to H-3. plus K ^bA^band D ^b. These observations demonstrate that the proliferative response to non-H-2 H antigens in the context of I-region determinants is not a sine qua non for the T-cell response to these antigens. Further, the individual qualitative and quantitative variation observed with individual genetically identical mice has strong implications for our knowledge of intrastrain variation in immune responsiveness and the characterization of inbred strains for immune responsiveness.     

Characterization of a TL−variant of a homozygous TL+ mouse lymphoma

A homozygous antigen-loss variant for the TL antigen was isolated by immunoselectionin vitro. The variant expressed <0.01 the parental amount of TL antigen on its surface as measured by quantitative absorption. Neither theK nor theD end H-2^k antigens were detectable on the surface of the variant, although parental amounts of Thy 1.2 and GCSA were expressed. Karyotypic analysis showed that the variant had one less chromosome than the parental line.     

Generation of the HLA-B35, -B5, -B16, and B15 groups of alleles studied by intron 1 and 2 sequence analysis

 HLA-B is the most polymorphic of the major histocompatibility complex classical class I loci. This polymorphism is mainly in exons 2 and 3, which code for the molecule’s α1 and α2 domains and include the antigenic peptide binding site. Recent studies have indicated that not only exons but also the intron 2 region may be involved in the generation of certain HLA-B alleles such as B ^* 3906 and B ^* 1522. To study the degree of intron 2 participation and the mechanisms that generate polymorphism at the HLA-B locus, intron 1 and 2 sequences from the HLA-B35, -B5, -B16 and -B15 groups of alleles were obtained. A group-specific intronic polymorphism was found: namely, B ^* 5301 shows intron 1 and 2 sequences identical to those found in all B35 alleles studied. On the other hand, B ^* 5101 and B ^* 52012 show the same intron 1 and 2 sequences and their intron 1 is the same as that found in the B35 group. This suggests that B5 and B35 groups of alleles may have arisen from a common ancestor. All known B16 alleles show the same introns 1 and 2, with the exception of B ^* 39061 and B ^* 39062, and all B15 alleles also bear the same introns 1 and 2, with the exception of B ^* 1522. Variability at intron 1 is more restricted than at intron 2, and the use of intron 1 for HLA-B allele phylogenetic analysis is better for grouping alleles of a postulated common origin. In conclusion, there is a remarkable conservation of intronic sequences within related HLA-B alleles, which probably reflects a common origin and perhaps a selective force avoiding DNA changes. Intronic sequences are also potentially useful to design DNA typing strategies. Received: 11 March 1997 / Revised: 29 May 1997     

There are two C4 genetic loci and a null allele in the chimpanzee

Genetic polymorphism in C4 in the chimpanzee was studied by agarose gel electrophoresis of desialated plasma and development of patterns by immunofixation with antiserum to human C4 and by a C4-sensitive hemolytic overlay. In general, immunofixation patterns showed multiple partially overlapping bands of which only the most cathodal had strong hemolytic activity. In analogy to human C4, the latter were designated C4B, whereas those detected by immunofixation which had little hemolytic activity were designated C4A. Chimp C4A and C4B reacted with human and mouse (monoclonal) anti-C4B and human anti-Ch1 but neither reacted with monoclonal anti-C4A or human anti-Ch2, Ch3, Rg1, or Rg2. On sodium dodecyl sulfate polyacrylamide gel electrophoresis, the alpha chain of C4B showed a slightly lower apparent relative mass than that of C4A at around M _r 93 000. There were three C4A variants and two C4B variants inherited in families as autosomal codominant traits, as C4A-C4B cosegregating pairs with no detectable crossing-over. These pairs were inherited with chimpanzee leukocyte antigen types C2 and BF variants without detectable crossing-over. Half-null C4 haplotypes with C4B ^*Q0 were observed in family studies. Nine BF, C2, C4A, C4B allelic haplotypic combinations (complotypes) were identified among presumably unrelated chimpanzees.Abbreviations used in this paper: ChLA chimpanzee leukocyte antigen - HLA human leukocyte antigen - EDTA ethylenediaminetetraacetate     

Mode matches in hydrophobic free energy eigenfunctions predict peptide–protein interactions

The dominant statistical hydrophobic free energy inverse frequencies, amino acid wavelengths as hydrophobic modes, of neurotensin (NT), cholescystokinin (CCK), the human dopamine D₂ receptor [(DA)D₂], and the human dopamine transporter (DAT) were determined using orthogonal decomposition of the autocovariance matrices of their amino acid sequences as hydrophobic free energy equivalents in kcal/mol. The leading eigenvalues-associated eigenvectors were convolved with the original series to construct eigenfunctions. Eigenfunctions were further analyzed using discrete trigonometric wavelet and all poles, maximum entropy power spectral transformations. This yielded clean representations of the dominant hydrophobic free energy modes, most of which are otherwise lost in the smoothing of hydropathy plots or contaminated by end effects and multimodality in conventional Fourier transformations. Mode matches were found between NT and (DA)D₂ and between CCK and DAT, but not the converse. These mode matches successfully predicted the nonlinear kinetic interactions of NT-(DA)D₂ in contrast with CCK-(DA)D₂ on ³H-spiperone binding to (DA)D₂, and by CCK-DAT but not NT-DAT on [N-methyl-³H]-WIN 35,428 binding to DAT in (DA)D₂ and DAT cDNA stably transfected cell lines without known NT or CCK receptors. Computation of the dominant modes of hydrophobic free energy eigenfunctions may help predict functionally relevant peptide–membrane protein interactions, even across neurotransmitter families. © 1998 John Wiley & Sons, Inc. Biopoly 46: 89–101, 1998