Christina Schultheis

Transposable elements as drivers of genomic and biological diversity in vertebrates

Comparative genomics has revealed that major vertebrate lineages contain quantitatively and qualitatively different populations of retrotransposable elements and DNA transposons, with important differences also frequently observed between species of the same lineage. This is essentially due to (i) the differential evolution of ancestral families of transposable elements, with evolutionary scenarios ranging from complete extinction to massive invasion; (ii) the lineage-specific introduction of transposable elements by infection and horizontal transfer, as exemplified by endogenous retroviruses; and (iii) the lineage-specific emergence of new transposable elements, as particularly observed for non-coding retroelements called short interspersed elements (SINEs). During vertebrate evolution, transposable elements have repeatedly contributed regulatory and coding sequences to the host, leading to the emergence of new lineage-specific gene regulations and functions. In all vertebrate lineages, there is evidence of transposable element-mediated genomic rearrangements such as insertions, deletions, inversions and duplications potentially associated with or subsequent to speciation events. Taken together, these observations indicate that transposable elements are major drivers of genomic and biological diversity in vertebrates, with possible important roles in speciation and major evolutionary transitions.

Tissue-specific expression of dmrt genes in embryos and adults of the platyfish Xiphophorus maculatus.

The vertebrate dmrt gene family encodes transcription factors with a characteristic DNA-binding motif called the DM domain. The best studied member is dmrt1, which is involved in sexual development in fish and tetrapods. The cloning of dmrt5 from the platyfish Xiphophorus maculatus and the expression pattern of dmrt1, dmrt2a, dmrt4, and dmrt5 in adults and embryos are reported. Consistent with a role in sexual development, platyfish dmrt1 is expressed exclusively in adult testis. Interestingly, dmrt1 expression was detected in both spermatogonia and Sertoli cells. This contrasts with the situation in other fish, where dmrt1 is not expressed in both types of cells, and is reminiscent of the expression observed in other vertebrates. Certain expression patterns in platyfish embryos were similar to those found in other vertebrates, suggesting conserved functions of dmrt genes in vertebrate development. This was the case for dmrt2a/terra and dmrt4, presenting expression patterns compatible with roles in somitogenesis and olfactory system development, respectively. However, differences in expression during embryogenesis and in adult tissues were observed not only between fish and tetrapods, but also between fish species, illustrating the possible functional divergence of this gene family in fish and other vertebrates.

Helitron Transposons on the Sex Chromosomes of the Platyfish Xiphophorus maculatus and Their Evolution in Animal Genomes.

The sex-determining region of the sex chromosomes of the platyfish Xiphophorus maculatus contains several copies of a recently described class of DNA transposons called Helitrons, which probably transpose through a mechanism involving rolling circle replication. The unique open reading frame of platyfish elements encodes a 2816 amino-acid protein with helicase and replication initiator (Rep) domains, which are hallmarks of Helitrons. Like previously described elements from zebrafish but unlike sequences from plants, insects and nematodes, platyfish Helitrons also encode a C-terminal apurinic-apyrimidinic-like endonuclease probably captured from a non-long-terminal- repeat retrotransposon. A cysteine protease domain related to the Drosophila ovarian tumor (OTU) protein was identified in the N-terminal part of the platyfish sequence. Putative endonuclease and protease have been acquired sequentially at least 600 million years ago and maintained functional in elements from sea urchin, lancelet and teleost fish, implying an important role for these domains in the transposition mechanism. Apparently intact Helitron elements are transcribed in Xiphophorus, and insertion polymorphism was observed between related fishes in different poeciliids. These observations suggest that Helitron transposons are still active in the genome of platyfish and related species, where they might play a role in the evolution of sex chromosomes and other genomic regions.

Sex Determination Diversity and Sex Chromosome Evolution in Poeciliid Fish

Poeciliids, a family of live-bearing freshwater fish, including among others platyfish, swordtails and guppies, fully illustrate the diversity of genetic sex determination mechanisms observed in teleosts. Besides unisexuality, a variety of sex-determining systems has been described in this group of fish, including male and female heterogamety with or without autosomal influence, as well as more complicated situations such as multichromosomal and polyfactorial sex determination. Due to the presence of different mechanisms in closely related species or even between populations within a same species, poeciliids are a very attractive model to study the evolutionary dynamics of sex determination. For one species, the Southern platyfish Xiphophorus maculatus, positional cloning of the master sex-determining gene has been initiated through the construction and sequencing of bacterial artificial chromosome contigs covering the region differentiating the X from the Y chromosome. Initial analysis revealed a high plasticity of the sex-determining region and the absence of synteny with other fish and vertebrate sex chromosomes, indicating an independent evolutionary origin.

Molecular Analysis of the Sex-Determining Region of the Platyfish Xiphophorus maculatus

Due to the presence of genetically well-defined sex chromosomes, with a relatively restricted sex-determination region containing markers identified at the molecular level, the platyfish Xiphophorus maculatus is one of the best models for the positional cloning of a master sex-determining gene in fish. Both male and female heterogametes and three different types of sex chromosomes have been described in the platyfish, with several loci involved in pigmentation, melanoma formation, and sexual maturity closely linked to the master sex-determining locus. Using the melanoma-inducing oncogene Xmrk, its protooncogenic counterpart egfrb, as well as other X- and Y-linked molecular markers, bacterial artificial chromosome (BAC) contigs have been assembled for the sex-determining region of X. maculatus, which was mapped by fluorescent in situ hybridization to the subtelomeric region of the sex chromosomes. Initial sequence analysis of these contigs revealed several gene candidates and uncovered syntenies with different mammalian and chicken autosomes, supporting an independent origin of sex chromosomes in platyfish and tetrapods. Strikingly, the sex determination region of the platyfish is very instable and frequently undergoes duplications, deletions, and transpositions. This instability might be linked to the high genetic variability affecting sex determination and other sex-linked traits in Xiphophorus.

Gene Amplification and Functional Diversification of Melanocortin 4 Receptor at an Extremely Polymorphic Locus Controlling Sexual Maturation in the Platyfish

In two swordtail species of the genus Xiphophorus, the onset of puberty has been shown to be modulated at the P locus by sequence polymorphism and gene copy-number variation affecting the type 4 melanocortin hormone receptor Mc4r. The system works through the interaction of two allelic types, one encoding wild type and the other dominant-negative receptors. We have analyzed the structure and evolution of the P locus in the platyfish Xiphophorus maculatus, where as many as nine alleles of P determining the onset of sexual maturity in males and females, fecundity in females, and adult size in males are located on both the X and Y chromosomes in a region linked to the master sex-determining locus. In this species, mc4r has been amplified to up to 10 copies on both the X and Y chromosomes through recent large serial duplications. Subsequently, mc4r paralogues have diverged considerably into many different subtypes. Certain copies have acquired new untranslated regions through genomic rearrangements, and transposable element insertions and other mutations have accumulated in promoter regions, possibly explaining observed deviations from the classical mc4r transcriptional pattern. In the mc4r-coding sequence, in-frame insertions and deletions as well as nonsense and missense mutations have generated a high diversity of Mc4r-predicted proteins. Most of these variants are expressed in embryos, adults, and/or tumors. Functional receptor characterization demonstrated major divergence in pharmacological behavior for Mc4r receptors encoded by different copies of platyfish mc4r, with differences in constitutive activity as well as binding and stimulation by hormones. The high degree of allelic and copy-number variation observed between individuals can explain the high level of polymorphism for sexual maturation, fecundity, and body size in the platyfish: multiple combinations of Mc4r variants with different biochemical properties might interact to modulate the melanocortin signaling that regulates the hypothalamus–pituitary–gonadal axis.

Molecular analysis of the sex chromosomes of the platyfish Xiphophorus maculatus: towards the identification of a new type of master sexual regulator in vertebrates.

In contrast to mammals and birds, fish display an amazing diversity of genetic sex determination systems, with frequent changes during evolution possibly associated with the emergence of new sex chromosomes and sex-determining genes. To better understand the molecular and evolutionary mechanisms driving this diversity, several fish models are studied in parallel. Besides the medaka (Oryzias latipes Temminck and Schlegel, 1846) for which the master sex-determination gene has been identified, one of the most advanced models for studying sex determination is the Southern platyfish (Xiphophorus maculatus, Günther 1966). Xiphophorus maculatus belongs to the Poeciliids, a family of live-bearing freshwater fish, including platyfish, swordtails and guppies that perfectly illustrates the diversity of genetic sex-determination mechanisms observed in teleosts. For X. maculatus, bacterial artificial chromosome contigs covering the sex-determination region of the X and Y sex chromosomes have been constructed. Initial molecular analysis demonstrated that the sex-determination region is very unstable and frequently undergoes duplications, deletions, inversions and other rearrangements. Eleven gene candidates linked to the master sex-determining gene have been identified, some of them corresponding to pseudogenes. All putative genes are present on both the X and the Y chromosomes, suggesting a poor degree of differentiation and a young evolutionary age for platyfish sex chromosomes. When compared with other fish and tetrapod genomes, syntenies were detected only with autosomes. This observation supports an independent origin of sex chromosomes, not only in different vertebrate lineages but also between different fish species.

A novel marker for the platyfish （Xiphophorus maculatus） W chromosome is derived from a Polinton transposon

A consensus sequence, encoding a putative DNA polymerase type B derived from a Polinton transposon, was assembled from the sex determination region of Xiphophorus maculatus. This predicted protein, which is 1,158 aa in length, contains a DNA_pol_B_2 domain and a DTDS motif. The DNA polymerase type B gene has about 10 copies in the haploid X. maculatus genome with one Y-specific copy. Interestingly, it has specific copies on the W chromosome in the X. maculatus Usumacinta strain (sex determination with female heterogamety), which represent new markers for this type of sex chromosome in platyfish. This marker with W- and Y-specific copies suggests relationship between different types of gonosomes and allows comparing male and female heterogameties in the platyfish. Further molecular analysis of the DNA polymerase type B gene in X. maculatus will shed new light on the evolution of sex chromosomes in platyfish.

A New Sex Chromosome Marker, Similar to DNA Polymerase Type B, in the Platyfish Xiphophorus Maculatus

A consensus sequence, encoding a putative DNA polymerase type B, was assembled from the sex determination region of Xiphophorus maculatus. This predicted protein, which is 1158aa in length, contains a DNA_pol_B_2 domain and a DTDS motif. The DNA polymerase type B gene has about 10 copies in the haploid X. maculatus, genome with one Y-specific copy. Interestingly, it has specific copies on the W chromosome in the X maculatus Usumacinta strain (sex determination with female heterogamety), which represent new markers for this type of sex chromosome in platyfish. This marker with W- and Y- specific copies suggests relationship between the different types of gonosomes and allows comparing male and female heterogameties in the platyfish. Further molecular analysis of the DNA polymerase type B gene in X maculatus will shed new light on the evolution of sex chromosomes in platyfish.

Genome fluidity in the fish Xiphophorus

A high level of genetic variability affects pigmentation, melanoma formation, sex determination and sexual maturity in the fish Xiphophorus. Gene loci encoding these traits have been mapped to a subtelomeric region of the sex chromosomes that very frequently undergoes DNA rearrangements including duplications, amplifications, deletions and transpositions. This conspicuous genomic fluidity might generate new sex-linked gene regulations and functions, and be involved in the initiation of gonosome differentiation around the major sex-determining locus in Xiphophorus.