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 long and the short of it: RNA-directed chromatin asymmetry in mammalian X-chromosome inactivation

Mammalian X-chromosome inactivation is controlled by a multilayered silencing pathway involving both short and long non-coding RNAs, which differentially recruit the epigenetic machinery to establish chromatin asymmetries. In response to developmentally regulated small RNAs, dicer, a key effector of RNA interference, locally silences Xist on the active X-chromosome and establishes the heterochromatin conformation along the silent X-chromosome. The 1.6 kb RepA RNA initiates silencing by targeting the PRC2 polycomb complex to the inactive X-chromosome. In addition, the nuclear microenvironment is implicated in the initiation and maintenance of X-chromosome asymmetries. Here we review new findings involving these various RNA species in terms of understanding Xist gene regulation and the establishment of X-chromosome inactivation.     

Gene mapping in marsupials and monotremes

Somatic cell genetic mapping of marsupial and monotreme species will greatly extend the power of comparative gene mapping to detect ancient mammalian gene arrangements. The use of eutherian-marsupial cell hybrids for such mapping is complicated by the frequent retention of deleted and rearranged marsupial chromosomes. We used staining techniques, involving the fluorochromes Hoechst 33258 and chromomycin A₃, to facilitate rapid and unequivocal identification of marsupial chromosomes and chromosome segments and to make chromosome assignment and regional localization of marsupial genes possible. Chromosome segregation in rodent-macropod hybrids was consistent with preferential loss of the marsupial complement. The extent of loss was very variable. Some hybrids retained 30% of the marsupial complement; some retained small centric fragments; and some, no cytologically identifiable marsupial material. We examined the chromosomes and gene products of a number of rodent-grey kangaroo Macropus giganteus hybrids, and have assigned the genes Pgk-A (phosphoglycerate kinase-A), Hpt (Hypoxanthine phosphoribosyl transferase), and Gpd (Glucose-6-phosphate dehydrogenase) to the long arm of the kangaroo X chromosome, and provisionally established the gene order Pgk-A -Hpt -Gpd.     

Genetic conflict and evolution of mammalian X-chromosome inactivation

The existence of parentally imprinted gene expression in the somatic tissues of mammals and plants can be explained by a theory of intragenomic genetic conflict, which is a logical extension of classical parent-offspring conflict theory. This theory unites conceptually the phenomena of autosomal imprinting and X-chromosome inactivation. We argue that recent experimental studies of X-chromosome inactivation and andro-genetic development address previously published predictions of the conflict theory, and we discuss possible explanations for the occurrence of random X-inactivation in the somatic tissues of eutherians. © 1995 Wiley-Liss, Inc.     

Diversity in parasitic helminths of Australasian marsupials and monotremes: a molecular perspective

Marsupials and monotremes are a prominent part of the mammalian fauna in Australia, and harbour an extremely diverse and highly distinctive array of helminth parasites. Their study has been relatively neglected, likely because they have no direct, adverse socioeconomic impact. As the body plans of helminths generally are very simple and morphological characterisation likely underestimates true diversity, molecular tools have been employed to assess genetic diversity. Using biochemical and/or molecular methods, recent studies show extensive diversity in helminths of marsupials, with cryptic species being commonly encountered. The purpose of this article is to review current knowledge about the diversity of parasitic helminths of marsupials and monotremes, to raise questions as to whether current molecular data can be used to estimate diversity, what mechanisms lead to such diversity, to critically appraise the molecular tools that have been employed thus far to explore diversity and to discuss the directions which might be taken in the future employing improved techniques.     

X-chromosome inactivation and escape

X-chromosome inactivation, which was discovered by Mary Lyon in 1961 results in random silencing of one X chromosome in female mammals. This review is dedicated to Mary Lyon, who passed away last year. She predicted many of the features of X inactivation, for e.g., the existence of an X inactivation center, the role of L1 elements in spreading of silencing and the existence of genes that escape X inactivation. Starting from her published work here we summarize advances in the field.     

Testes weight, body weight and mating systems in marsupials and monotremes

Relationships between testes weight, body weight and mating systems were examined in 40 marsupial species and in the extant monotremes. Relationships between relative testes weight and mating systems in marsupials resemble those previously described for primates. Thus relative testes weights are greatest in those marsupials where females mate with multiple males during the fertile period, i.e. polyandrous species (e.g. Antechinus ftavipes, Isoodon obesulus, Perameles nasuta, Potorous tridactylus, Macropus eugenii and M. agilis) and smallest in monandrous forms (e.g. Petauroides volans and Petaurus breviceps ) where females usually mate with a single male. These findings are consistent with effects of sperm competition upon the evolution of relative testes sizes in marsupials. Where field studies on marsupial mating systems are lacking, we make predictions based upon examination of their relative testes weights. Tarsipes rostratus, Acrobates pygmaeus, Macropus rufogriseus and Sarcophilus harrisii are predicted to engage in multiple matings and sperm competition. Conversely, Lasiorhinus latifrons, Cercatetus concinnus and Pseudoantechinus macdonnellensis are predicted to be monandrous in their mating behaviour. The monotremes ( Ornithorhynchus anatinus, Tachyglossus aculeatus and Zaglossus bruijnii ) are characterized by possession of very large testes; monotremes are shown to have significantly greater relative testes weights than marsupials, primates or avian species. This taxonomic difference is unlikely to be related lo the occurrence of oviparity or to the abdominal position of the testes in the Monotremata. Their mating systems are not known in detail, but some evidence for multiple matings (and hence for sperm competition) exists for Tachyglossus aculeatus so that their large testes may be adaptive in this context.     

Gene mapping in marsupials and monotremes. II. Assignments to the X chromosome of dasyurid marsupials

Somatic cell hybrids have been obtained between HPRT Chinese hamster cells and cells from several dasyurid marsupial species. These hybrids show the extensive loss of marsupial chromosomes characteristic of the majority of marsupial-eutherian somatic cell hybrids. Although all of the hybrids expressed the selected marsupial marker, HPRT, the only other markers observed were PGK, GLA, and G6PD, consistent with the conservation of X-linked genes extending to this major group of marsupials. Counterselection confirmed the synteny of PGK and GLA with HPRT, whereas G6PD showed decreased concordance.     

Embryonic growth rates of marsupials with a note on monotremes

Earlier workers suggest that marsupial embryonic growth rates are slower than those of many eutherians and that there is little correlation between marsupial gestation lengths and their weight at birth. Previously, this latter observation has been explained as being due to the considerable variability in duration of the initial slow phase of marsupial embryonic growth. The latter phase of pregnancy has always been regarded as rapid and highly uniform in all marsupials. However, this review shows that there can be considerable variation in growth rate during this 'fast' phase and also that marsupials have similar rates of embryonic growth to most eutherians. Development within the monotreme egg may proceed at a similar rate to intra-uterine growth in therian mammals.     

X-chromosome inactivation in development and cancer

X-chromosome inactivation represents an epigenetics paradigm and a powerful model system of facultative heterochromatin formation triggered by a non-coding RNA, Xist, during development. Once established, the inactive state of the Xi is highly stable in somatic cells, thanks to a combination of chromatin associated proteins, DNA methylation and nuclear organization. However, sporadic reactivation of X-linked genes has been reported during ageing and in transformed cells and disappearance of the Barr body is frequently observed in cancer cells. In this review we summarise current knowledge on the epigenetic changes that accompany X inactivation and discuss the extent to which the inactive X chromosome may be epigenetically or genetically perturbed in breast cancer.     

X-chromosome inactivation: counting, choice and initiation

In many sexually dimorphic species, a mechanism is required to ensure equivalent levels of gene expression from the sex chromosomes. In mammals, such dosage compensation is achieved by X-chromosome inactivation, a process that presents a unique medley of biological puzzles: how to silence one but not the other X chromosome in the same nucleus; how to count the number of X's and keep only one active; how to choose which X chromosome is inactivated; and how to establish this silent state rapidly and efficiently during early development. The key to most of these puzzles lies in a unique locus, the X-inactivation centre and a remarkable RNA--Xist--that it encodes.     

Gracefully ageing at 50, X-chromosome inactivation becomes a paradigm for RNA and chromatin control

The discovery of X-chromosome inactivation (XCI) celebrated its golden anniversary this year. Originally offered as an explanation for the establishment of genetic equality between males and females, 50 years on, XCI presents more than a curious gender-based phenomenon that causes silencing of sex chromosomes. How have the mysteries of XCI unfolded? And what general lessons can be extracted? Several of the cell biological mechanisms that are used to establish the inactive X chromosome, including regulatory networks of non-coding RNAs and unusual nuclear dynamics, are now suspected to hold true for processes occurring on a genome-wide scale.