Jaclyn M. Watson

Genes on the short arm of the human X chromosome are not shared with the marsupial X

Eight genes located on the short arm of the human X chromosome (MAOA, SYN1, OAT, OTC, CYBB, DMD, ZFX, POLA) have been mapped in several marsupial species by cell hybrid analysis and/or in situ hybridization using probes derived from human cDNA. Seven appear to be autosomal in all marsupial species examined. The eighth, CYBB, detected a site on the X, as well as major autosomal sites. Although these genes are not conserved on the X chromosome in marsupials, at least some of them are arranged together in autosomal clusters. The autosomal location of human Xp genes in marsupials could mean that this region either was lost from a large ancestral X chromosome in the marsupial lineage or was acquired by a small ancestral X (and perhaps Y) in the eutherian lineage. Either explanation demands that the region was not subject to X chromosome inactivation in a common ancestor 120-150 MyrBP.

Autosomal localization of the amelogenin gene in monotremes and marsupials: implications for mammalian sex chromosome evolution.

We have determined by Southern blot analysis that DNA sequences homologous to the AMG gene probe are present in the genomes of both marsupial and monotreme mammals, although adult monotremes lack teeth. In situ hybridization and Southern analysis of cell hybrids demonstrate that AMG homologues are located on autosomes. In the Tammar Wallaby, AMG homologues are located on chromosomes 5q and 1q and in the Platypus, on chromosomes 1 and 2. The autosomal location of the AMG homologues provides additional support for the hypothesis that an autosomal region equivalent to the human Xp was translocated to the X chromosome in the Eutheria after the divergence of the marsupials 150 million years ago. The region containing the AMG gene is therefore likely to have been added 80-150 million years ago to a pseudoautosomal region shared by the ancestral eutherian X and Y chromosome; the X and Y alleles must have begun diverging after this date.

The X chromosome of marsupials shares a highly conserved region with eutherians

Ten genes, located on the long arm of the human X chromosome, were mapped in several marsupial species by somatic cell analysis and in situ hybridization. All were located on the X chromosome in each species. We conclude that the long arm of the human X chromosome represents a highly conserved region that formed part of the X chromosome in a therian ancestor 120-150 million years ago, before the mammalian infraclasses diverged.

The evolution of human chromosome 21: evidence from in situ hybridization in marsupials and a monotreme.

We have mapped five human chromosome 21 (HSA 21) markers in marsupials and a monotreme, two major groups of mammals that diverged from eutherians 130-150 and 150-170 million years before present (MYrBP), respectively. We have found that these genes map to two distinct autosomal sites, one containing SOD1/CBR/BCEI and the other containing ETS2/INFAR, in the marsupials Macropus eugenii and Sminthopsis macroura (which belong to orders that diverged 40-80 MYrBP), as well as in the monotreme Ornithorhynchus anatinus (the platypus). Since marsupials and monotremes diverged independently from eutherians, these data suggest that HSA 21 genes were originally located in two separate autosomal blocks. In another Sminthopsis species, SOD1 is linked to TRF (a marker on HSA 3q), suggesting that the ancestral SOD1/CBR/BCEI region also included HSA 3 markers. We suggest that these blocks became fused early in the eutherian evolution to form a HSA 3/21 chromosome, which has remained intact in artiodactyls, but has been independently disrupted in both the primate and rodent lineages.

Gene mapping studies confirm the homology between the platypus X and echidna X1 chromosomes and identify a conserved ancestral monotreme X chromosome

The identification of the sex chromosomes in the three extant species of Prototherian mammals (the monotremes) is complicated by their involvement in a multivalent translocation chain at the first division of male meiosis. The platypus X chromosome, identified by the presence of two copies in females and one in males, has been found to possess a suite of genes that have been mapped to the X chromosomes of all eutherian and metatherian mammals. We have extended gene mapping studies to a member of the only other extant monotreme family, the echidna, which has a G-band equivalent X1 chromosome, as well as a smaller X2. We find that the five human X-linked genes (G6PD, GDX, F9, AR and MCF2) map to the echidna X1 chromosome in locations equivalent to those on the platypus X. These results confirm that the echidna X1 is the original X chromosome in this species, and identify a conserved ancestral monotreme X chromosome.

Cloning and characterization of the platypus mitochondrial genome

The vertebrate mitochondrial genome is highly conserved in size and gene content. Among the chordates there appears to be one basic gene arrangement, but rearrangements in the mitochondrial gene order of the avian lineages have indicated that the mitochondrial genome may be more variable than once thought. Different gene orders in marsupials and eutherian mammals leave the ancestral mammalian order in some doubt. We have investigated the mitochondrial gene order in the platypus (Ornithorhynchus anatinus), a representative of the third major group of mammals, to determine which mitochondrial gene arrangement is ancestral in mammals. We have found that the platypus mtDNA conforms to the basic chordate gene arrangement, common to fish, amphibians, and eutherian mammals, indicating that this arrangement was the original mammalian arrangement, and that the unusual rearrangements observed in the avians and marsupials are probably lineage-specific.

Mapping human X-linked genes in the phalangerid marsupial Trichosurus vulpecula.

We mapped 15 human X-chromosome markers in the common brush-tailed possum, Trichosurus vulpecula (Kerr), which represents the Australian marsupial family Phalangeridae. In situ hybridization was used to localize highly conserved human X-linked genes to chromosomes of T. vulpecula diploid lines. Ten genes located on the long arm of the human X (human Xq genes) all mapped to the possum X chromosome. However, all five genes located on the short arm of the human X (human Xp genes) mapped to autosomes. These findings confirm our previous work, which showed that the X chromosome in macropodid and dasyurid marsupials bears all the human Xq genes but none of the human Xp genes studied. This suggests that the marsupial X is highly conserved, but its gene content reflects that of only part of the eutherian X, a result consistent with our hypothesis that an autosomal region was added to the X early in eutherian divergence.

Genome Instability in interspecific cell hybrids II. Aminopterin resistance and gene amplification in lines arising from fusions of cells from divergent mammalian species

In order to investigate instances of genetic instability in divergent cell hybrids, we studied several RAT-resistant colonies recovered from fusions between HPRT or TK-deficient rodent cells and marsupial or monotreme cells. Most of these colonies proved to lack HPRT or TK activity and to have survived by acquiring resistance to aminopterin; such aminopterin-resistant lines were never recovered from parent cells subjected to HAT selection. Two of the aminopterin-resistant hybrids over-produced DHFR, and possessed either double minutes or an abnormally banded region, the cytological manifestations of gene amplification. Selection in higher aminopterin concentrations yielded a highly resistant line with 100X wild-type DHFR activity and a large homogeneously staining region. We suggest that interspecific cell hybrids are predisposed to gene amplification and may also show many other types of genetic and chromosomal instability, possibly thein vitro equivalent of the “genomic shock” phenomena described for interstrain or interspecies hybrids of plants or animals.

Genomic instability in mammalian cell hybrids. IV. Is mutation frequency elevated in hybrid cells

In this study, we set out to determine whether the mutation frequency in cell hybrids is increased over the frequencies in the two parental lines, and whether this increase is related to the evolutionary divergence of the cell parents. Two test loci were chosen: forward mutation at the HPRT locus and mutation to resistance to the drug emetine. We conclude that while some cell combinations do seem to produce hybrids with higher mutation frequencies, this is not consistently so, and, indeed, mutation rates in hybrids may be higher, lower or very similar to rates in the parental lines. Further, evolutionary divergence between the parental lines does not appear to correlate to mutation frequency in the hybrids.