Mammalian ZFY genes are located on the Y chromosome, and code putative transcription factors with 12–13 zinc fingers preceded by a large acidic (activating) domain. In mice, there are two genes, Zfy1 and Zfy2, which are expressed mainly in the testis. Their transcription increases in germ cells as they enter meiosis, both are silenced by meiotic sex chromosome inactivation (MSCI) during pachytene, and Zfy2 is strongly reactivated later in spermatids. Recently, we have shown that mouse Zfy2, but not Zfy1, is involved in triggering the apoptotic elimination of specific types of sex chromosomally aberrant spermatocytes. In humans, there is a single widely transcribed ZFY gene, and there is no evidence for a specific role in the testis. Here, we characterize ZFY transcription during spermatogenesis in mice and humans. In mice, we define a variety of Zfy transcripts, among which is a Zfy2 transcript that predominates in spermatids, and a Zfy1 transcript, lacking an exon encoding approximately half of the acidic domain, which predominates prior to MSCI. In humans, we have identified a major testis-specific ZFY transcript that encodes a protein with the same short acidic domain. This represents the first evidence that ZFY has a conserved function during human spermatogenesis. We further show that, in contrast to the full acidic domain, the short domain does not activate transcription in yeast, and we hypothesize that this explains the functional difference observed between Zfy1 and Zfy2 during mouse meiosis.
Although the HSFY deletion is restricted to our infertile group, it has been transmitted naturally over many generations, indicating that HSFY genes make only a slight contribution to male fertility. Importantly, our study formally excludes HSFY genes as the AZFb factor required for progression through meiosis.
AZFc deletions of the Y chromosome are the major known genetic cause of spermatogenetic failure. Meiotic studies have shown a prevalence of synaptonemal complex fragmentation and an excess of early-stage sperm cells, suggesting that the maturation block could involve apoptosis. We present a prospective and observational study of apoptotic markers in the sperm of four AZFc-deleted patients and two non-obstructive azoospermic controls without an AZFc deletion. Polycaspases assays and terminal deoxynucleotidyl transferase dUDP nick-end labelling (TUNEL) assays were combined to evaluate the incidence of apoptosis in pre-meiotic, meiotic and post-meiotic germs cells identified, respectively, using anti-melanoma-associated antigen A4 (MAGE-A4), anti-synaptonemal complex protein 3 (SCP3) and anti-sperm acrosome membrane-associated protein 1 (SPACA1) antibodies. We detected apoptosis at all stages of AZFc-deletion spermatogenesis. Using the caspase assay, the incidence of positive cells was found to be heterogeneous for pre-meiotic (from 4.8 to 84.5%) and meiotic stages (from 7.9 to 57.6%), while for post-meiotic cells, the mean incidence was 6% in AZFc-deleted patients compared with 26.5% in controls (P < 0.05). Using the TUNEL assay, the mean percentage with DNA fragmentation for meiotic cells was 54.0% in AZFc-deleted patients compared with 20.3% in controls (P < 0.05), while the percentage of TUNEL-positive post-meiotic cells ranged from 5.3 to 44.7%. Spermatocyte loss in AZFc-deleted patients occurs via the apoptotic pathway. In post-meiotic cells, the lower incidence of apoptosis in testis from three of the four AZFc-deleted patients, compared with controls, is consistent with AZFc deletions having little negative impact on sperm quality.
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