Expressed Peromyscus maniculatus (Pema) MHC class I genes: evolutionary implications and the identification of a gene encoding a Qa1-like antigen

To gain insight into the evolution of rodent major histocompatibility complex (MHC) class I genes and identify important (conserved) nonclassical class I (class Ib) gene products and residues in these proteins, sixPeromyscus maniculatus MHC (Pema) class I cDNA clones were isolated and sequenced. FivePema class I cDNAs appeared most similar to mouse and rat classical class I (class Ia) genes. One exhibited highest similarity to anH2 class Ib gene,H2-T23 (encoding the Qa1 antigen). Phylogenetic trees constructed withPema, RT1, andH2 class I sequences suggested that the lineages of some rodent class Ib genes (e.g.,T23 andT24) originated prior toMus andPeromyscus speciation [>50 million years (My) ago]. Sequences of four Qa1-like proteins from three species permitted the identification of ten Qa1-specific amino acids. On the basis of molecular modeling, three residues showed the potential to interact with T-cell receptors and three residues (all corresponding to polymorphic positions among H2 class Ia proteins) were predicted to influence antigen binding. The recognition of mouse Qa1 proteins by a subset of T-cells in influenced by a locus,Qdm, which encodes the H2-D leader peptide. One of thePema class I cDNA clones classified asH2-K, D/L-like (class Ia) is predicted to encode an identical peptide, implying that an antigen binding protein (Qa1) and the antigen to which it binds (the product ofQdm) has been conserved for over 50 My. The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers U12822 (Pm13), U12885 (Pm41), U12886 (Pm52), U12887 (Pm62), U16846 (Pm11), and U16847 (Pm53)     

Frequent segmental sequence exchanges and rapid gene duplication characterize the<Emphasis Type="Italic"> MHC</Emphasis> class I genes in lemurs

Major histocompatibility complex (MHC) class I genes have complicated and profound evolutionary histories. To reconstruct and better understand their histories, partial class I genes (exon 2–intron 2–exon 3) were sequenced in a sampling of prosimians (Strepsirhini, Primates). In total, we detected 117 different sequences from 36 Malagasy prosimians (lemurs) and 1 non-Malagasy prosimian (galago) representing 4 families, 7 genera, and 13 species. Unlike the MHC class II genes (MHC-DRB), MHC class I genes show a generally genus-specific mode of evolution in lemurs. Additionally, no prosimian class I loci were found to be orthologous to HLA genes, even at highly conserved loci (such as HLA-E, HLA-F). Phylogenetic analysis indicates that nucleotide diversity among loci was very small and the persistence time of the polymorphisms was short, suggesting that the origin of the lemur MHC class I genes detected in this study was relatively recent. The evolutionary mode of these genes is similar to that of classic HLA genes, HLA-A, HLA-B, and HLA-C, in terms of their recent origin and rarity of pseudogenes, and differs from them with respect to the degree of gene duplications. From the viewpoint of MHC genes evolution, some interlocus sequence exchanges were apparently observed in the lemur lineage upon phylogenetic and amino acid motif analyses. This is also in contrast to the evolutionary mode of HLA genes, where intralocus exchanges have certainly occurred but few interlocus exchanges have taken place. Consequently, the gene conversion model for explaining the generation of the MHC diversity among different loci can be thought to play more important roles in the evolution of lemur MHC class I genes than in that of HLA genes.Electronic Supplementary Material Supplementary material is available in the online version of this article at     

Linkage of a new member of the lectin supergene family to chicken Mhc genes

With the use of tissue-specific cDNA probes, several genes, which do not correspond to the class I (B-F), class II (B-L), or class IV (B-G) genes, were detected within the cosmid clusters containing the chicken major histocompatibility genes. We isolated cDNA clones with a probe corresponding to one of them, the 17.5 gene, located between two class I genes. The 17.5.3 cDNA, isolated from a chicken spleen cDNA library, encodes a 257-residue-long protein. This sequence shows significant similarity with several members of the C-type animal lectin superfamily and is probably a type II transmembrane protein. Analysis of several cDNA clones, together with Southern blot experiments, strongly suggest that this gene belongs to a multigene family, with at least some of its members being polymorphic. Several arguments lend support to the possibility that, together with the linked Mhc genes, the 17.5 gene is part of the recently described Rfp-Y system.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M88072.     

Nucleotide Sequencing Analysis of the 146-Kilobase Segment around theIkBLandMICAGenes at the Centromeric End of the HLA Class I Region

To elucidate the complete gene structure and to identify new genes involved in the development ofHLAclass I antigen-associated diseases in the class I region of the human major histocompatibility complex on chromosome 6, a YAC clone (745D12) covering the 146-kb segment around theIkBLandMICAloci was isolated from a YAC library constructed from the B-cell line, BOLETH. A physical map of this region was constructed by isolation of overlapping cosmid clones derived from 745D12. Of these, five contiguous cosmids were chosen for DNA sequencing by the shotgun strategy to give a single contig of 146,601 bp from 2.8 kb telomeric of theIkBLgene to exon 6 ofMICA.This region was confirmed to contain five known genes,IkBL, BAT1, MICB, P5-1,andHLA-X(class I fragment), from centromere to telomere, and their exon–intron organizations were determined. The3.8-1homologue gene (3.8-1-hom) showing 99.7% identity with the3.8-1cDNA clone, which was originally isolated using the 3.8-kbEcoRI fragment between theHLA-54/Hand theHLA-Ggenes, was detected betweenMICAandMICBand was suggested to represent the cognate3.8-1genomic sequence from which the cDNA clone was derived. No evidence for the presence of expressed new genes could be obtained in this region by homology and EST searches or coding and exon prediction analyses. One TA microsatellite repeat spanning 2545 bases with as many as 913 repetitions was found on the centromeric side of theMICAgene and was indicated to be a potential hot spot for genetic recombination. The two segments of approximately 35 kb upstream of theMICAandMICBgenes showed high sequence homology (about 85%) to each other, suggesting that segmental genome duplication including theMICAandMICBgenes must have occurred during the evolution of the humanMHC.     

Class II genes of miniature swine

Genomic clones corresponding to class II genes of theSLA ^c haplotype of miniature swine have been isolated and characterized. These genes have been grouped into seven non-overlapping clusters on the basis of restriction mapping. Ordering of exons within each cluster was accomplished by hybridization of Southern blots of restriction fragments with exon-specific probes. The two clusters (clusters 2 and 3) encoding theDRB andDQB genes were identified on the basis of hybridization with locus-specific 3 untranslated cDNA probes. Cluster 4 contained exons of bothDOB andDQB genes, the basis for which remains to be determined. The remaining four clusters (1, 5, 6, 7) were identified as containingDP, DR, andDO coding sequences, respectively, on the basis of sequence analysis. The porcine class II region appears very similar to that of man in number and nature of the class II genes identified and in the intron/exon organization of corresponding genes.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the association number M29944. Address correspondence and offprint requests to: C. LeGuern.     

Mapping and nucleotide sequence of a newHLA class II light chain gene,DQB3

A genomic clone specifying a new HLA class II antigen β chain,DQB3, was isolated from a human genomic phage library using aDQB1 cDNA probe under low stringency conditions. Southern hybridization and nucleotide sequence analyses identified the β2 domain exon (exon 3) with several deleterious mutations and the CP-TM-CY exon [connecting peptide, transmembrane, and cytoplasmic regions, (exon 4)], but the first, second, and fifth exons encoding the 5′ UT-leader, the β1 domain, and the 3′ UT domain of normal β chains, respectively, were entirely missing. The nucleotide sequences of these two exons were distinct from those of other class II β chain genes, but slightly more related to theDQB1 andDQB2 genes than to other class II genes. TheDQB3 sequence mapped betweenDQA2 andDQB1, 15 kb upstream fromDQA2, by analysis of overlapping cosmid clones. This mapping was supported by the fact thatTaq I,Msp I, andBam HIDQB3 polymorphisms were perfectly correlated with theDQA2 polymorphism and not with any polymorphisms in theDR orDQ subregion, suggesting the presence of a hot spot for recombination betweenDQB3 andDQB1. The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M26577.     

Molecular genetic analysis of theripening-inhibitor andnon-ripening loci of tomato: A first step in genetic map-based cloning of fruit ripening genes

Ripening represents a complex developmental process unique to plants. We are using tomato fruit ripening mutants as tools to understand the regulatory components that control and coordinate the physiological and biochemical changes which collectively confer the ripe phenotype. We have genetically characterized two loci which result in significant inhibition of the ripening process in tomato,ripening-inhibitor (rin), andnon-ripening (nor), as a first step toward isolating genes likely to encode key regulators of this developmental process. A combination of pooled-sample mapping as well as classical restriction fragment length polymorphism (RFLP) analysis has permitted the construction of high-density genetic maps for the regions of chromosomes 5 and 10 spanning therin andnor loci, respectively. To assess the feasibility of initiating a chromosome walk, physical mapping of high molecular weight genomic DNA has been employed to estimate the relationship between physical distance (in kb) and genetic distance (in cM) around the targeted loci. Based on this analysis, the relationship in the region spanning therin locus is estimated to be 200–300 kb/cM, while thenor locus region ratio is approximately 200 kb/1 cM. Using RFLP markers tightly linked torin andnor, chromosome walks have been initiated to both loci in a yeast artificial chromosome (YAC) library of tomato genomic DNA. We have isolated and characterized several YAC clones linked to each of the targeted ripening loci and present genetic evidence that at least one YAC clone contains thenot locus.     

Identification of a YAC clone carrying the Xa-1 allele, a bacterial blight resistance gene in rice

Map-based cloning methods have been applied for isolation of Xa-1, one of the bacterial blight resistance genes in rice.Xa-1 was previously mapped on chromosome 4 using molecular markers. For positional cloning of Xa-1, a high-resolution genetic map was made for theXa-1 region using an F₂ population of 402 plants and additional molecular markers. Three restriction fragment length polymorphism (RFLP) markers, XNpb235, XNpb264 and C600 were found to be linked tightly to Xa-1, with no recombinants, and U08 ₇₅₀ was mapped 1.5 cM from Xa-1. The screening of a yeast artificial chromosome (YAC) library using theseXa-1-linked RFLP markers resulted in the identification of ten contiguous YAC clones. Among these, one YAC clone, designated Y5212, with an insert of 340 kb, hybridized with all three tightly linked markers. This YAC was confirmed to possess the Xa-1 allele by mapping the Xa-1 gene between both end clones of this YAC (Y5212R and Y5212L).     

Organization of the genes encoding chalcone synthase in Pisum sativum

To analyze the regulation of defense-related genes by signal molecules produced by phytopathogens, we isolated genes that encode chalcone synthase (CHS) in Pisum sativum. We have obtained seven independent genomic clones that contain at least seven classes of CHS genes, identified by the hybridization analysis to CHS cDNA and by the restriction mapping analysis. Two of the genomic clones (clone 5 and 6) each contain two CHS genes in a tandem repeat. The nucleotide sequence analysis of CHS genomic clone 5 revealed that PsCHS1 and PsCHS2 were corresponding genes of the CHS cDNA clones, pCC6 and pCC2, respectively, as reported earlier. Both genes are interrupted by a single intron of 88 nucleotides with identical sequences, although exonic sequences and 5-flanking sequences are divergent. Nucleotide sequences of the introns in five other classes of CHS genes showed that three classes had an intron of 87 nt with a striking homology to each other, but that the intron of the other two classes of CHS genes showed heterogeneity both in size and nucleotide sequence. 5-upstream regions of PsCHS1 and PsCHS2 did not show sequence homology except the 31 bp identical sequence that contains the CCTACC motif resembling the box-1 sequence. Both PsCHS1 and PsCHS2 genes are shown to be induced by fungal elicitor by a primer extension analysis and a transient transformation analysis using pea protoplasts prepared from suspension cultured-cells.     

The identification of nuclear and mitochondrial genes by sequencing randomly chosen clones from a marsupial mammary gland cDNA library

To increase the number of genes that can be mapped to the genome of the tammar wallaby (Macropus eugenii), we sequenced 100 randomly chosen clones from a mammary gland cDNA library. Provisional identifications were made of seven nuclear genes and one mitochondrial gene encoding two caseins, -galactosidase, acetyl-coenzyme A synthetase, lipoprotein lipase, inorganic pyrophosphatase, an ATP-dependent RNA helicase, and cytochromec oxidase I. Highly conserved genes, such as that encoding acetyl-coenzyme A synthetase, were easily identified even from cross-kingdom matches. Genes which are highly divergent, however, such as those encoding themature casein peptides, could not be aligned with homologues in the databases. Even in an organ where there is high mRNA species redundancy, the sequence characterization of expressed sequence tags provides a rapid means of gene identification for mapping purposes.     

Genetic polymorphism of the swine major histocompatibility complex (SLA) class I genes, SLA-1, -2 and -3

In order to identify and characterize genetic polymorphism of the swine major histocompatibility complex (Mhc: SLA) class I genes, RT-PCR products of the second and third exons of the three SLA classical class I genes, SLA-1, SLA-2 and SLA-3 were subjected to nucleotide determination. These analyses allowed the identification of four, eight and seven alleles at the SLA-1, SLA-2 and SLA-3 loci, respectively, from three different breeds of miniature swine and one mixed breed. Among them, 12 alleles were novel. Construction of a phylogenetic tree using the nucleotide sequences of those 19 alleles indicated that the SLA-1 and -2 genes are more closely related to each other than to SLA-3. Selective forces operating at single amino acid sites of the SLA class I molecules were analyzed by the Adaptsite Package program. Ten positive selection sites were found at the putative antigen recognition sites (ARSs). Among the 14 positively selected sites observed in the human MHC (HLA) classical class I molecules, eight corresponding positions in the SLA class I molecules were inferred as positively selected. On the other hand, four amino acids at the putative ARSs were identified as negatively selected in the SLA class I molecules. These results suggest that selective forces operating in the SLA class I molecules are almost similar to those of the HLA class I molecules, although several functional sites for antigen and cytotoxic T-lymphocyte recognition by the SLA class I molecules may be different from those of the HLA class I molecules.The DNA sequence data reported in this paper have been submitted to the DDBJ, EMBL and GenBank nucleotide databases and have been assigned the accession numbers, AB105379, AB105380, AB105381, AB105382, AB105383, AB105384, AB105385, AB105386, AB105388, AB105389, AB105390 and AB105391     

Molecular cloning and structural analysis of the cucumber (<Emphasis Type="Italic">Cucumis sativus</Emphasis> L.) phosphoenolpyruvate carboxykinase (<Emphasis Type="Italic">CsPCK</Emphasis>) gene

Genomic sequence of the ATP-dependent phosphoeno/pyruvate carboxykinase (CsPCK) gene has been determined first from cucumber. Several putative clones were isolated in three rounds of genomic library screening with designated cDNA probes. These clones were analyzed via restriction digests, Southern hybridization, and nucleotide sequencing to ascertain the structure of theCsPCK gene. Analysis of a selected positive clone (λcscpk-4A) demonstrated that this gene consists of 13 exons and 12 introns, spanning 9 kb in the cucumber genome. Exon 1 contains only 23 nucleotides of the 5′-noncoding region of cucumberPCK cDNA, whereas Exon 2 comprises 12 nucleotides of the S′-noncoding region with an N-terminal PEPCK coding sequence. All the exon-intron junction sequences agree with the GT/AG consensus, except for the 5 donor site of Intron 7, where GC replaces the GT consensus. As with rice (Oryza sativa), cucumber contains only one copy of theCsPCK gene in its haploid genome. The overall number of exons and the structure of this gene are similar to those for bothArabidopsis Chromosome 4 (Atg4)PCK and the rice PCX genes, which contain 13 and 12 exons, respectively. Two additionalArabidopsis PCK genes can be found in the fifth chromosome (Atg5), which contains 9 exons and 8 introns (with 628 and 670 amino acids, respectively) of the PEPCK peptide. TheCsPCK gene promoter has conserved plant-specific as-acting elements within 2 kb of the 5’ flanking region. Several common cis-acting elements of the isocitrate lyase (icl) and malate synthase(ms) gene promoters, identified in theCsPCK gene, are responsible for the sugar response during plant development, especially at germination. These conserved elements are discussed here.     

Construction and Characterization of aPlasmodium vivaxGenomic Library in Yeast Artificial Chromosomes

Here we describe the construction of a representative YAC library for the human malarial parasitePlasmodium vivax.AsP. vivaxcannot be maintained continuously under laboratory conditions, theP. vivaxDNA necessary for the library construction was isolated from a single human patient presenting himself with vivax malaria to a local hospital in the Brazilian Amazon. Thus, this YAC library is the first of its kind to be generated from patient-derived material. The YAC library consists of 560 clones with an average insert size of 180 kb. Of 9 publishedP. vivaxgenes, 8 were found to be present in the library. In addition, 12P. vivaxtelomeric YAC clones were identified.     

Cloning and characterization of the lectin cDNA clones from onion,shallot and leek

Characterization of the lectins from onion (Allium cepa), shallot (A. ascalonicum) and leek (A. porrum) has shown that these lectins differ from previously isolated Alliaceae lectins not only in their molecular structure but also in their ability to inhibit retrovirus infection of target cells.cDNA libraries constructed from poly(A)-rich RNA isolated from young shoots of onion, shallot and leek were screened for lectin cDNA clones using colony hybridization. Sequence analysis of the lectin cDNA clones from these three species revealed a high degree of sequence similarity both at the nucleotide and at the amino acid level.Apparently the onion, shallot and leek lectins are translated from mRNAs of ca. 800 nucleotides. The primary translation products are preproproteins (ca. 19 kDa) which are converted into the mature lectin polypeptides (12.5–13 kDa) after post-translational modifications.Southern blot analysis of genomic DNA has shown that the lectins are most probably encoded by a family of closely related genes which is in good agreement with the sequence heterogeneity found between different lectin cDNA clones of one species.     

Recombinational and Physical Mapping of the Locus for Primary Open-Angle Glaucoma (GLC1A) on Chromosome 1q23–q25

Primary open-angle glaucoma (POAG) is a leading cause of irreversible blindness in industrialized countries. A locus for juvenile-onset POAG,GLC1A,has been mapped to 1q21–q31 in a 9-cM interval. With recombinant haplotypes, we have now reduced theGLC1Ainterval to a maximum of 3 cM, between theD1S452/NGA1/D1S210andNGA5loci. These loci are 2.8 Mb apart on a 4.7-Mb contig that we have completed between theD1S2851andD1S218loci and that includes 96 YAC clones and 48 STSs. The newGLC1Ainterval itself is now covered by 25 YACs, 30 STSs, and 16 restriction enzyme site landmarks. The lack of aNotI site suggests that the region has few CpG islands and a low gene content. This is compatible with its predominant cytogenetic location on the 1q24 G-band. Finally, we have excluded important candidate genes, including genes coding for three ATPases (ATP1B1, ATP2B4, ATP1A2), an ion channel (VDAC4), antithrombine III (AT3), and prostaglandin synthase (PTGS2). Our results provide a basis to identify theGLC1Agene.     

Nucleotide sequencing analysis of the swine 433-kb genomic segment located between the non-classical and classical<Emphasis Type="Italic"> SLA</Emphasis> class I gene clusters

Genome analysis of the swine leukocyte antigen (SLA) region is needed to obtain information on the MHC genomic sequence similarities and differences between the swine and human, given the possible use of swine organs for xenotransplantation. Here, the genomic sequences of a 433-kb segment located between the non-classical and classical SLA class I gene clusters were determined and analyzed for gene organization and contents of repetitive sequences. The genomic organization and diversity of this swine non-class I gene region was compared with the orthologous region of the human leukocyte antigen (HLA) complex. The length of the fully sequenced SLA genomic segment was 433 kb compared with 595 kb in the corresponding HLA class I region. This 162-kb difference in size between the swine and human genomic segments can be explained by indel activity, and the greater variety and density of repetitive sequences within the human MHC. Twenty-one swine genes with strong sequence similarity to the corresponding human genes were identified, with the gene order from the centromere to telomere of HCR - SPR1 - SEEK1 - CDSN - STG - DPCR1 - KIAA1885 - TFIIH - DDR - IER3 - FLOT1 - TUBB - KIAA0170 - NRM - KIAA1949 - DDX16 - FLJ13158 - MRPS18B - FB19 - ABCFI - CAT56. The human SEEK1 and DPCR1 genes are pseudogenes in swine. We conclude that the swine non-class I gene region that we have sequenced is highly conserved and therefore homologous to the corresponding region located between the HLA-C and HLA-E genes in the human.The nucleotide sequence data reported in this paper have been submitted to DDBJ, EMBL and GenBank databases under accession numbers AB113354, AB113355, AB113356, AB113357