A physical map of the human pseudoautosomal region.

A physical map of the human pseudoautosomal region has been constructed using pulsed field gel electrophoresis and the infrequently cutting restriction enzymes BssHIII, EagI, SstII, NotI, MluI and NruI. This map extends 2.3 Mbp from the telomere to sex-chromosome-specific DNA, includes at least seven CpG islands and locates four genetically mapped loci. Five of the CpG islands are organized into two clusters. One cluster is adjacent to the telomere, the other extends into sex-chromosome-specific DNA. There is congruence between the genetic and physical maps which implies that the frequency of recombination is approximately uniform throughout the DNA.     

A human genomic sequence highly homologous to the 3'-untranslated region of rat uricase mRNA

A human genomic sequence was isolated from a library using a rat uricase cDNA probe. Sequence analysis has shown that it is highly homologous to the 3'-untranslated region of rat uricase mRNA. Total loss of uricase activity in human is, therefore, not due to total loss of the gene. Discovery of high degree of conservation of the non-coding region of the gene would be of great interest as we attempt to learn the process of gene evolution.     

Inter-species sequence diversity in the replication initiation region of Paramecium mitochondrial DNA

Mitochondrial DNA from Paramecium aurelia is a linear molecule. Replication is initiated at a unique cross-linked molecular terminus. During replication dimer length molecules, consisting of two head-to-head monomers, are generated. We have cloned the head-to-head dimer initiation region from five different species and several stocks (or races) within species and determined its DNA sequence. For all species, this dimer initiation region consists of a central non-palindromic sequence containing almost exclusively A and T, arranged in an array of direct tandem repeats. In an intra-species comparison, the sequences of the repeat units are relatively homogeneous; inter-species comparisons, however, show diversity except for a conserved "Goldberg-Hogness box", T-A-T-A-A-A-T-A. The size of a repeat unit and the number of repeats within a molecule can vary over a wide range, even in an intra-species comparison. Because of these wide inter-species variations observed, it is likely that the function of this region imposes few constraints on the sequence other than its high A + T content and possibly a Goldberg-Hogness box. The array of direct tandem repeats may have arisen from unequal recombination or crossover within this region. Adjacent to the non-palindromic region is a transcribed sequence which is highly conserved for all species and presumably represents a gene coding region.     

Assessment of genomic imprinting of PPP1R9A, NAP1L5 and PEG3 in pigs

Imprinted genes play significant roles in the regulation of fetal growth and development, function of the placenta, and maternal nurturing behaviour in mammals. At present, few imprinted genes have been reported in pigs compared to human and mouse. In order to increase understanding of imprinted genes in swine, a polymorphism-based approach was used to assess the imprinting status of three porcine genes in 12 tissue types, obtained from F1 pigs of reciprocal crosses between Rongchang and Landrace pure breeds. In contrast to human and mouse homologues, porcine PPP1R9A was not imprinted, and was found to be expressed in all tissues examined. The expression of porcine NAP1L5 was detected in pituitary, liver, spleen, lung, kidney, stomach, small intestine, skeletal muscle, fat, ovary, and uterus, but undetectable in heart. Furthermore, porcine NAP1L5 was paternally expressed in the tissues where it's expression was observed. For PEG3, pigs expressed the paternal allele in skeletal muscle, liver, spleen, kidney, and uterus, but biallele in heart, lung, fat, stomach, small intestine, and ovary. Our data indicate that tissue distribution of the three gene differs among mammals, and the imprinting of NAP1L5 and PEG3 is well conserved.     

DNA sequence comparative analysis of the 3pter-p26 region of human genome

Most proterminal regions of human chromosomes are GC-rich and gene-rich. Chromosome 3p is an exception. Its proterminal region is GC-poor, and likely to lose heterozy-gosity, thus causing a number of fatal diseases. Except one gap left in the telomeric position, the proterminal region of human chromosome 3p has been completely sequenced. The detailed sequence analysis showed: (i) the GC content of this region was 38.5%, being the lowest among all the human proterminal regions; (ii) this region contained 20 known genes and 22 predicted genes, with an average gene size of 97.5 kb. The previously mapped gene Cntn3 was not found in this region, but instead located in the 74 Mb position of human chromosome 3p; (iii) the interspersed repeats of this region were more active than the average level of the whole human genome, especially (TA)n, the content of which was twice the genome average; (iv) this region had a conserved synteny extending from 104.1 Mb to 112.4 Mb on the mouse chromosome 6, which was 8% larger in size, not in accordance with the whole genome comparison, probably because the 3pter-p26 region was more likely to lose neocleitides and its mouse synteny had more active interspersed repeats.     

DNA sequence comparative analysis of the 3pter-p26 region of human genome

Most proterminal regions of human chromosomes are GC-rich and gene-rich. Chromosome 3p is an exception. Its proterminal region is GC-poor, and likely to lose heterozygosity, thus causing a number of fatal diseases. Except one gap left in the telomeric position, the proterminal region of human chromosome 3p has been completely sequenced. The detailed sequence analysis showed: (i) the GC content of this region was 38.5%, being the lowest among all the human proterminal regions; (ii) this region contained 20 known genes and 22 predicted genes, with an average gene size of 97.5 kb. The previously mapped gene Cntn3 was not found in this region, but instead located in the 74 Mb position of human chromosome 3p; (iii) the interspersed repeats of this region were more active than the average level of the whole human genome, especially (TA)n, the content of which was twice the genome average; (iv) this region had a conserved synteny extending from 104.1 Mb to 112.4 Mb on the mouse chromosome 6, which was 8% larger in size, not in accordance with the whole genome comparison, probably because the 3pter-p26 region was more likely to lose neocleitides and its mouse synteny had more active interspersed repeats.     

A gradient of silent substitution rate in the human pseudoautosomal region

It has been demonstrated that recombination in the human p-arm pseudoautosomal region (p-PAR) is at least twenty times more frequent than the genomic average of approximately 1 cM/Mb, which may affect substitution patterns and rates in this region. Here I report the analysis of substitution patterns and rates in 10 human, chimpanzee, gorilla, and orangutan genes across the p-PAR. Between species silent divergence in the p-PAR forms a gradient, increasing toward the telomere. The correlation of silent divergence with distance from the p-PAR boundary is highly significant (rho = 0.911, P < 0.001). After exclusion of the CpG dinucleotides this correlation is still significant (rho = 0.89, P < 0.01), thus the substitution rate gradient cannot be explained solely by the differences in the extent of methylation across the p-PAR. Frequent recombination in the PAR may result in a relatively strong effect of biased gene conversion (BGC), which, because of the increased probability of fixation of the G or C nucleotides at (A or T)/(G or C) segregating sites, may affect substitution rates. BGC, however, does not seem to be the factor creating the substitution rate gradient in the p-PAR, because the only gradient is still detactable if only A<-->T and G<-->C substitutions are taken into account (rho = 0.82, P < 0.01). I hypothesize that the substitution rate gradient in the p-PAR is due to the mutagenic effect of recombination, which is very frequent in the distal human p-PAR and might be lower near the p-PAR boundary.     

Arrangement and localization of the human GM-CSF receptor alpha chain gene CSF2RA within the X-Y pseudoautosomal region.

The gene encoding one subunit of the receptor for the hemopoietic growth factor, GM-CSF, has been previously localized to the short arm of the human sex chromosomes. By pulsed-field gel electrophoresis, the precise localization of this gene, CSF2RA, within the pseudoautosomal region has been determined. The gene is located 1180 to 1300 kb from the telomere, in close proximity to the CpG island B5. The CSF2RA gene spans at least 45 kb, and a representation of most of the gene on three overlapping cosmid clones has been obtained. The exon(s) encoding the first 35 bp of cDNA sequence lies outside these cosmids. The CSF2RA gene is characterized by abundant hypervariable sequences, and a number of informative restriction fragment length polymorphisms have been defined.     

The intergenic spacer region of the ribosomal RNA gene of Penicillium marneffei shows almost no DNA sequence diversity

The fungus Penicillium marneffei causes fatal systemic infections and is endemic in many parts of South-East Asia, especially Thailand. The intergenic spacer (IGS) region, the most variable region of rRNA genes, was found to be highly conserved among 58 P. marneffei strains. IGS analysis might not be suitable for molecular epidemiological analysis of P. marneffei infections.     

Structure and chromosomal mapping of a highly polymorphic repetitive DNA sequence from the pseudoautosomal region of the mouse sex chromosomes

The pseudoautosomal region of the Mov15 mouse strain is marked by a Moloney murine leukemia provirus. The sequences flanking the Mov15 provirus were molecularly cloned and shown to consist of a tandemly repeated sequence of 31 nucleotides. Copy number variation of this repeat most likely accounts for the polymorphism in the mouse pseudoautosomal region detected with a probe from the flanking sequences. In situ hybridization to metaphase chromosomes showed heavy labeling of the pairing region of the X and Y chromosomes. The repetitive sequence was also found at the subtelomeric region of three autosomes. A similar level of amplification as the one seen on the sex chromosomes seems to be present on chromosomes 9 and 13. Lower copy number appear to be present on chromosome 4.     

Structure and partial genomic sequence of the human retinoblastoma susceptibility gene

This report describes the genomic organization of the human retinoblastoma susceptibility locus. This gene spans approximately 200 kb of DNA within human chromosome 13, band q14. The previously determined cDNA sequence comprises 27 exons, ranging in size from 31 bp to 1873 bp, and 26 introns, ranging in size from 80 bp to 70,500 bp. We have mapped the positions of the exons and the positions of the recognition sites for six restriction endonucleases. We also present the sequence of 9.2% of the locus (18,335 bp), including approximately 200 bp of intron sequence immediately flanking each exon. This map of a wild-type allele will form the foundation for future studies of mutant, oncogenic alleles at this locus.     

A partial sequence of lipoxygenase gene from genomic DNA of aromatic rice (Oryza sativa L.)

Aromatic (Bas-370, PB-1) and non-aromatic (Pusa-677, Pusa-834) rice were selected for the characterization and for distribution of lipoxygenase (Lox) genes. Polymorphism was observed when genomic DNA of rice varieties was hybridized with a heterologous lipoxygenase probe. A distinct polymorphic fragment (approximately 1.2 kb) was found in Bas-370. Sub-genomic library of Bas-370 was constructed and screened with LoxA probe. The smallest putative clone (pBas-14) of approximately 1.2 kb was sequenced. Complete nucleotide and deduced amino acid sequence showed the clone was 1134 bp long and comprised of 378 amino acid residues. PCR amplification of genomic DNA from four rice varieties with a soybean Lox primer also showed a polymorphic fragment of size approximately 600 bp (amplicon) in aromatic varieties that was sequenced directly. Nucleotide sequence alignment between pBas-14 and amplicon concluded that the amplicon was a part of the insert pBas-14.     

DNA sequence of the coding region of the HLA-B44 gene

An HLA-B44 cDNA clone was identified in a cDNA library constructed from an HLA-B44 homozygous cell line. The DNA sequence was determined and was found to contain the complete coding sequence but for (probably) the three N-terminal codons. Comparisons of the derived amino acid sequence with other HLA-A and -B locus amino acid sequences revealed four HLA-B44-specific substitutions including a new polymorphic site. Regions of strong sequence conservation for HLA-B-locus products were found at the nucleotide and amino acid levels.     

Recombination and nucleotide diversity in the sex chromosomal pseudoautosomal region of the emu, Dromaius novaehollandiae

Pseudoautosomal regions (PARs) shared by avian Z and W sex chromosomes are typically small homologous regions within which recombination still occurs and are hypothesized to share the properties of autosomes. We capitalized on the unusual structure of the sex chromosomes of emus, Dromaius novaehollandiae, which consist almost entirely of PAR shared by both sex chromosomes, to test this hypothesis. We compared recombination, linkage disequilibrium (LD), GC content, and nucleotide diversity between pseudoautosomal and autosomal loci derived from 11 emu bacterial artificial chromosome (BAC) clones that were mapped to chromosomes by fluorescent in situ hybridization. Nucleotide diversity (pi = 4N(e)mu) was not significantly lower in pseudoautosomal loci (14 loci, 1.9 +/- 2.4 x 10(-3)) than autosomal loci (8 loci, 4.2 +/- 6.1 x 10(-3)). By contrast, recombination per site within BAC-end sequences (rho = 4Nc) (pseudoautosomal, 3.9 +/- 6.9 x 10(-2); autosomal, 2.3 +/- 3.7 x 10(-2)) was higher and average LD (D') (pseudoautosomal, 4.2 +/- 0.2 x 10(-1); autosomal, 4.7 +/- 0.5 x 10(-1)) slightly lower in pseudoautosomal sequences. We also report evidence of deviation from a simple neutral model in the PAR and in autosomal loci, possibly caused by departures from demographic equilibrium, such as population growth. This study provides a snapshot of the population genetics of avian sex chromosomes at an early stage of differentiation.