Michael J. O'Neill

Undermethylation associated with retroelement activation and chromosome remodelling in an interspecific mammalian hybrid

Genetic models, predict that genomic rearrangement in hybrids can facilitate reproductive isolation and the formation of new species by preventing gene flow between the parent species and hybrid (sunflowers are an example). The mechanism underlying hybridization-induced chromosome remodelling is as yet unknown, although mobile element activity has been shown to be involved in DNA rearrangement in some dysgenic Drosophila hybrids,. It has been proposed that DNA methylation evolved as a means of repressing the movement of mobile elements (the host defence model,). If such a protective mechanism were to fail, mobile elements could be activated, and could cause major and rapid genome alterations,. Here we demonstrate the occurrence of genome-wide undermethylation, retroviral element amplification and chromosome remodelling in an interspecific mammalian hybrid (Macropus eugenii × Wallabia bicolor). Atypically extended centromeres of Macropus eugenii derived autosomes in the hybrid were composed primarily of an unmethylated, amplified retroviral element not detectable in either parent species. These results, taken with the observation of deficient methylation and de novo chromosome change in other mammalian hybrids, indicate that the failure of DNA methylation and subsequent mobile-element activity in hybrids could facilitate rapid karyotypic evolution.

Allelic expression of IGF2 in marsupials and birds.

Abstract Genomic imprinting, the parent-of-origin- specific expression of genes, has been observed in a variety of eutherian mammals. One gene that has been shown to be imprinted in all eutherians examined is the IGF2 gene. This gene encodes a potent fetal-specific growth factor that is expressed almost exclusively from the paternal chromosome. Several other imprinted genes in the IGF2 pathway are imprinted as well, suggesting that IGF2 is a focal point for the selective pressure leading to imprinted gene expression. This observation is in keeping with a proposal that imprinting arose as the result of a genetic conflict between parents over the allocation of maternal resources to the embryo. One prediction of this model is that imprinting exists in species in which there is at least some contribution of maternal resources to the embryo, and in which polyandry is observed. To test this prediction the allelic expression of the IGF2 gene was examined in two noneutherian species. The IGF2 gene was shown to be expressed in a paternal-specific manner identical to that in eutherians in Monodelphis domestica, a placental South American opossum. In contrast, the IGF2 gene is biallelic in expression in chickens, which are oviparous, and make no postfertilization contribution of maternal resources to the offspring.

Genetic and epigenetic incompatibilities underlie hybrid dysgenesis in Peromyscus.

Crosses between the two North American rodent species Peromyscus polionotus (PO) and Peromyscus maniculatus (BW) yield parent-of-origin effects on both embryonic and placental growth. The two species are approximately the same size, but a female BW crossed with a male PO produces offspring that are smaller than either parent. In the reciprocal cross, the offspring are oversized and typically die before birth. Rare survivors are exclusively female, consistent with Haldanes rule, which states that in instances of hybrid sterility or inviability, the heterogametic sex tends to be more severely affected. To understand these sex- and parent-of-origin-specific patterns of overgrowth, we analysed reciprocal backcrosses. Our studies reveal that hybrid inviability is partially due to a maternally expressed X-linked PO locus and an imprinted paternally expressed autosomal BW locus. In addition, the hybrids display skewing of X-chromosome inactivation in favour of the expression of the BW X chromosome. The most severe overgrowth is accompanied by widespread relaxation of imprinting of mostly paternally expressed genes. Both genetic and epigenetic mechanisms underlie hybrid inviability in Peromyscus and hence have a role in the establishment and maintenance of reproductive isolation barriers in mammals.

ASW: a gene with conserved avian W-linkage and female specific expression in chick embryonic gonad

Abstract Vertebrates exhibit a variety of sex determining mechanisms which fall broadly into two classes: environmental or genetic. In birds and mammals sex is determined by a genetic mechanism. In mammals males are the heterogametic sex (XY) with the Y chromosome acting as a dominant determiner of sex due to the action of the testis-determining factor, SRY. In birds females are the heterogametic sex (ZW); however, it is not known whether the W chromosome carries a dominant ovary-determining gene, or whether Z chromosome dosage determines sex. Using an experimental approach, which assumes only that the sex-determining event in birds is accompanied by sex-specific changes in gene expression, we have identified a novel gene, ASW (Avian Sex-specific W-linked). The putative protein for ASW is related to the HIT (histidine triad) family of proteins. ASW shows female-specific expression in genital ridges and maps to the chicken W chromosome. In addition, we show that, with the exception of ratites, ASW is linked to the W chromosome in each of 17 bird species from nine different families of the class Aves.

Ancient and continuing Darwinian selection on insulin-like growth factor II in placental fishes

Despite abundant examples of both adaptation at the level of phenotype and Darwinian selection at the level of genes, correlations between these two processes are notoriously difficult to identify. Positive Darwinian selection on genes is most easily discerned in cases of genetic conflict, when antagonistic evolutionary processes such as a Red Queen race drive the rate of nonsynonymous substitution above the neutral mutation rate. Genomic imprinting in mammals is thought to be the product of antagonistic evolution coincident with evolution of the placenta, but imprinted loci lack evidence of positive selection likely because of the ancient origin of viviparity in mammals. To determine whether genetic conflict is a general feature of adaptation to placental reproduction, we performed comparative evolutionary analyses of the insulin-like growth factor II (IGF2) gene in teleost fishes. Our analysis included several members of the order Cyprinodontiformes, in which livebearing and placentation have evolved several times independently. We found that IGF2 is subject to positive Darwinian selection coincident with the evolution of placentation in fishes, with particularly strong selection among lineages that have evolved placentation recently. Positive selection is also detected along ancient lineages of placental livebearing fishes, suggesting that selection on IGF2 function is ongoing in placental species. Our observations provide a rare example of natural selection acting in synchrony at the phenotypic and molecular level. These results also constitute the first direct evidence of parent–offspring conflict driving gene evolution.

Kallmann syndrome gene (KAL-X) is not mutated in schizophrenia

Kallmann syndrome and schizophrenia share several clinical features, including dysfunctional olfactory ability, hypogonadotrophic hypogonadism, an excess of affected males, and psychiatric presentation. Because of this congruence, it has been proposed that up to 70% of male schizophrenics might have mutations affecting the function or expression of the gene mutated in Kallmann syndrome, KAL-X. We identified and studied 9 unrelated males with schizophrenia (as defined by DSM-IIIR criteria) who also have severe anosmia (first percentile of normal range) and low sex drive (seventh percentile of the normal range), and we sequenced the exons and the intron-exon junctions of the KAL-X gene for each. We found no mutations, and conclude that schizophrenia is rarely, if ever, due to a mutation in the coding sequence or splice junctions of KAL-X.

The testis determining gene, Sry

Publisher Summary This chapter focuses on the testis determining gene—sex determining region Y gene ( SRY) . The determination of sex is one of the most fundamental developmental events for any organism. It sets the course for the entire life history of an individual within a population. The restrictions on behavior and physiology associated with sexual reproduction define populations as species. In humans, sexual development and sexual identity have a profound effect on the psychology of an individual and their interactions with the society in which they live. The chapter reviews the past four decades of research into mammalian sex determination, which developed into the search for a testis determining factor (TDF) and ultimately led to the isolation of SRY. It also presents the experimental evidence confirming that SRY is TDF and discusses the recent studies implicating SRY as an important regulator of gene expression, the search for its downstream target genes, and its place in the testis determining pathway.

reply: Genome evolution: Global methylation in eutherian hybrids

The absence of global methylation changes in eutherian interspecific hybrids compared with their parents, observed by Roemer et al., sharply contrasts with our own studies of interspecific hybrids between various species of kangaroo. We observed hybrid-specific undermethylation, retroelement activation and genome remodelling, and suggested that these events occurring together may bring about rapid karyotypic change.

Sex chromosome repeats tip the balance towards speciation

Because sex chromosomes, by definition, carry genes that determine sex, mutations that alter their structural and functional stability can have immediate consequences for the individual by reducing fertility, but also for a species by altering the sex ratio. Moreover, the sex‐specific segregation patterns of heteromorphic sex chromosomes make them havens for selfish genetic elements that not only create suboptimal sex ratios but can also foster sexual antagonism. Compensatory mutations to mitigate antagonism or return sex ratios to a Fisherian optimum can create hybrid incompatibility and establish reproductive barriers leading to species divergence. The destabilizing influence of these selfish elements is often manifest within populations as copy number variants (CNVs) in satellite repeats and transposable elements (TE) or as CNVs involving sex‐determining genes, or genes essential to fertility and sex chromosome dosage compensation. This review catalogs several examples of well‐studied sex chromosome CNVs in Drosophilids and mammals that underlie instances of meiotic drive, hybrid incompatibility and disruptions to sex differentiation and sex chromosome dosage compensation. While it is difficult to pinpoint a direct cause/effect relationship between these sex chromosome CNVs and speciation, it is easy to see how their effects in creating imbalances between the sexes, and the compensatory mutations to restore balance, can lead to lineage splitting and species formation.

Genome evolution: reply: Global methylation in eutherian hybrids

The absence of global methylation changes in eutherian interspecific hybrids compared with their parents, observed by Roemer et al., sharply contrasts with our own studies of interspecific hybrids between various species of kangaroo. We observed hybrid-specific undermethylation, retroelement activation and genome remodelling, and suggested that these events occurring together may bring about rapid karyotypic change.