A genomic clone of Zfy-1 from a YDOM mouse strain detects post-meiotic gene expression of Zfy in testes

Intron/exon structure confirms that mouse Zfy1 and Zfy2 are members of the ZFY gene family

Zfy1 and Zfy2 are homologous zinc finger genes on the mouse Y Chromosome. To ask whether these genes are properly classified as members of the ZFY family, we have characterized and compared their genomic organization to that of mouse Zfx, human ZFX, and human ZFY. We show that Zfy1 has 11 exons distributed across at least 56 kb, and Zfy2 has a minimum of 9 exons distributed across at least 52 kb. The Zfy2 locus contains regions similar in size and sequence to all 11 exons of Zfy1, plus an additional 5' UTR exon. All splice sites conform to the GT-AG rule. There are two instances of additional AG dinucleotides immediately 5' of 3' splice sites. Zfy1 and Zfy2 are homologous to other ZFY family members within the coding region, but the untranslated regions show no sequence similarity. Within the coding region, there is conservation of exon length and splice sites, with each splice preceding the second nucleotide of a codon. We conclude that Zfy1 and Zfy2 are indeed members of the ZFY family, which has evolved from a single common ancestral gene.

Embryonic growth and the evolution of the mammalian Y chromosome. I. The Y as an attractor for selfish growth factors

The fitness of a mammalian zygote is affected by its probability of implantation and of postimplantation maintenance as well as the level of transplacental and transmammary uptake of resources. As with paternally expressed imprinted genes, in a species in which females are not obligately monogamous, a Y-linked sequence that can positively alter any of the above parameters could spread in a population even if it harms the prospects of other embryos. Such a selfish Y-linked gene could act as a sex ratio distorter. In contrast to autosomal imprinted loci, the patrilineal inheritance of the Y ensures that selfish Y-linked growth-promoting genes need not evolve a means to ensure correct parent-dependent expression rules. Thus, as the conditions for both their initial evolution and spread are relatively relaxed, the mammalian Y chromosome is expected to be an attractor for growth-promoting genes. Data from mice and humans indicate that, as expected and in contrast to the Y of flies, the mammalian Y harbours growth factors, sex ratio factors and multiple foetally expressed genes. The accumulation of Y-linked genes may also be explained in terms of sexual antagonism. Sexual antagonism and the model presented here are not mutually exclusive.

Y353/B: a candidate multiple-copy spermiogenesis gene on the mouse Y chromosome

There is evidence from Y Chromosome (Chr) deletion mapping that there is a gene on the long arm of the mouse Y Chr that is needed for the normal development of the sperm head. Since mice with partial Y long arm deletions show incomplete penetrance of the sperm head defect, whereas mice with no Y long arm show complete penetrance, it has been suggested that the 'spermiogenesis' gene may be present in multiple copies. A Y-specific genomic DNA sequence (Y353/B) has previously been described that is present in multiple copies on the long arm of the mouse Y and identifies testis-specific transcripts. We have suggested that Y353/B could be the proposed multiple copy 'spermiogenesis' gene. In support of this suggestion, we show here that mice with a partial Y long arm deletion associated with a 3.5-fold increase in the frequency of abnormal sperm heads have a marked reduction in genomic Y353/B copies and a corresponding reduction in Y353/B-related transcripts. Thus, the incompletely penetrant phenotype correlates with a reduction in Y353/B-related transcription. Furthermore, by in situ hybridization with a Y353/B riboprobe to testis sections, we show that the Y353/B-related transcripts are confined to the round spermatid stage of spermiogenesis, just prior to the shaping of the sperm head. The transcripts sediment with the fraction of cytoplasmic RNA in adult testis that is loaded on polysomes, suggesting that the transcripts are actively translated.

Zfy is transcribed in the normal mouse epididymis and in the XXSxr ("sex reversed") testis

The presence of the mutation Sex reversed (Sxr), a copy of a Y-chromosomal segment that gets transferred to an X chromosome, causes the resulting XXSxr mice to develop as apparent males. However, several features of male sexual development are abnormal in these animals. The testes are small and aspermatogenic, and the epididymides lack the initial segment. Testes and epididymides show abnormalities of extracellular matrix. In this study we examined transcription of the conserved Y chromosomal gene Zfy, which has an X-chromosomal homologue (Zfx). Northern blotting showed Zfy to be expressed in the testes of XXSxr animals, except for those that carry the coat-marker gene Tabby (Ta), despite the lack of germ cells in XXSxr mice. Reverse transcription polymerase chain reaction (RT-PCR) studies detected Zfy in mRNA in testes even when Ta was present. RT-PCR also demonstrated Zfy transcription in epididymides of normal males, though not in XXSxr mice. Previous authors reported an absence of Zfy transcription in XXSxr testes; Zfy transcription in normal testes has been ascribed to germ cells. Our observation indicates that this idea requires re-evaluation. The occurrence of Zfy transcription in the normal epididymis is similarly a novel finding that may help explain those aspects of epididymal development that occur in the absence of androgen.

Gene expression, X-inactivation, and methylation during spermatogenesis: the case of Zfa, Zfx, and Zfy in mice

While it has become clear that X-inactivation in the female soma is complete in mouse (in contrast to being "patchy" in man), the degree of X-inactivation in the testes has not been ascertained. We have compared autosomal and X-linked zinc finger homolog expression and X-linked and Y-linked zinc finger homolog methylation in an attempt to elucidate this question. Using RTPCR, we have extended earlier studies of Zfx and Zfa expression in developing testes and find that Zfa expression starts at the time of X-inactivation while Zfx expression is continuous. Cell separation studies did not preclude continued expression of Zfx in adult germ cells. The methylation status of four CCGG residues in the Zfx promoter was studied using PCR bridging this region before and after DNA digestion with the isoschizomers Msp I and Hpa II, the latter being methylation sensitive. Hpa II resistant Zfx promoter DNA was found in all female tissues, but not in male tissues, including the testes. Previous studies have shown that Zfy is expressed at meiosis (like Zfa and unlike Zfx). Despite its expression, the Zfy gene is adjacent to, or contains, highly methylated CCGG sites since hybridization after Msp I digestion detected multiple small fragments that were not released after DNA digestion with Hpa II. Thus, Zfx is not methylated in sperm, while Zfy is, in contrast to their apparent patterns of expression.

An interstitial deletion in mouse Y chromosomal DNA created a transcribed Zfy fusion gene

The small portion of the mouse Y chromosome retained in the Sxra transposition is thought to carry at least five genes including, as demonstrated here, the entirety of the zinc-finger genes Zfy-1 and Zfy-2. Sxrb, a derivative of Sxra, was previously thought to retain Zfy-1 but to be deleted for Zfy-2. Here we show that Sxrb differs from Sxra as the result of unequal crossing-over between Zfy-1 and Zfy-2. This unequal crossing-over created a transcribed Zfy-2/1 fusion gene and an interstitial deletion. Our data and previous results together suggest that this deletion encompassed the 3' portion of Zfy-2, the histocompatibility gene Hya, the spermatogenesis factor Spy, and the 5' portion of Zfy-1. We suggest that not only Zfy but also other neighboring genes such as Spy and Hya may exist in two copies on the Y as the result of a large tandem duplication during rodent evolution.

Developmental appearance of proteins identified by two-dimensional gel electrophoresis in mouse gonadal tissue

Gonadal protein patterns of the mouse were studied during fetal development by two-dimensional gel electrophoresis. Fetal mice at days 8.5, 10.5, 12.5, and 14.5 post-coitum were analyzed for male or female specific proteins. Although no sex specific proteins were found, several proteins were found which were expressed in significantly different amounts in the two sexes at about the time of gonadal differentiation. Hence, quantitative differences, rather than qualitative ones, could be related to the initiation of testis or ovary development.

Post-meiotic gene expression

Evolutionary arguments and well-designed experiments (based on false premises, however) had suggested that post-meiotic gene expression did not occur in animals. The techniques of molecular genetics have now clearly demonstrated such genetic activity in mammalian testes. The current problem is to understand why some classes of genes, such as Zfy and many oncogenes, are expressed in this manner.