The roles of the DAZ family in spermatogenesis: More than just translation?

The DAZ family of genes are important fertility factors in animals, including humans. The family consists of Y-linked DAZ, and autosomal homologs Boule and Dazl. All three genes encode RNA-binding proteins that are nearly exclusively expressed in germ cells. The DAZ family is highly conserved, with ancestral Boule present in sea anemones through humans, Dazl conserved among vertebrates, and DAZ present only in higher primates. Here we review studies on DAZ family genes from multiple organisms, and summarize the common features of each DAZ gene and their roles during spermatogenesis in animals. DAZ family proteins are thought to activate the translation of RNA targets, but recent work has uncovered additional functions. Boule, Dazl, and DAZ likely function through similar mechanisms, and we present known functions of the DAZ family in spermatogenesis, and discuss possible mechanisms in addition to translation activation.

Phylogenomic analyses reveal the evolutionary origin of the inhibin alpha-subunit, a unique TGFbeta superfamily antagonist.

Transforming growth factor-beta (TGFbeta) homologues form a diverse superfamily that arose early in animal evolution and control cellular function through membrane-spanning, conserved serine-threonine kinases (RII and RI receptors). Activin and inhibin are related dimers within the TGFbeta superfamily that share a common beta-subunit. The evolution of the inhibin alpha-subunit created the only antagonist within the TGFbeta superfamily and the only member known to act as an endocrine hormone. This hormone introduced a new level of complexity and control to vertebrate reproductive function. The novel functions of the inhibin alpha-subunit appear to reflect specific insertion-deletion changes within the inhibin beta-subunit that occurred during evolution. Using phylogenomic analysis, we correlated specific insertions with the acquisition of distinct functions that underlie the phenotypic complexity of vertebrate reproductive processes. This phylogenomic approach presents a new way of understanding the structure-function relationships between inhibin, activin, and the larger TGFbeta superfamily.

Characterization of a Dazl-GFP germ cell-specific reporter.

In this study, we characterized the promoter activity of a 1.7 kb sequence in the 5' flanking region of the mouse Deleted in Azoospermia-Like (Dazl) gene. We found the 1.7 kb sequence sufficient to drive robust germ cell-specific expression of green fluorescent protein (GFP) in adult mouse testis and lower levels of expression in adult ovary and in fetal and newborn gonads of both sexes. This expression pattern was confirmed in two independently-derived transgenic mouse lines. In adult testis, Dazl-GFP exhibited a developmentally-regulated, stage-specific expression pattern during spermatogenesis. GFP was highly expressed in spermatocyte stages, with strongest expression in pachytene spermatocytes. Weaker expression was observed in round and elongating spermatids, as well as spermatogonial cells. In the fetal gonad, GFP transcript was detected by e12.5 in both sexes; however, GFP fluorescence was only detected during later embryonic stages. In addition, we produced mouse embryonic stem cell (ESC) lines harboring the Dazl-GFP reporter and used this reporter to isolate putative germ cell populations derived from mouse ESCs following embryoid body differentiation and fluorescence activated cell sorting.

Evolutionary comparison of the reproductive genes, DAZL and BOULE, in primates with and without DAZ.

Genes of the DAZ (Deleted in AZoospermia) gene family, DAZ, DAZL (DAZ-Like), and BOULE, encode closely related RNA-binding proteins that are required for fertility in numerous organisms, yet the genomes of different organisms possess different complements of DAZ family genes. Thus, invertebrates such as flies and worms contain just a single DAZ homolog, boule, while genomes of vertebrates, other than catarrhine primates (Old World monkeys and hominids), possess both Boule and Dazl genes. Finally, catarrhine primates possess BOULE, DAZL, and DAZ genes. Since the DAZ genes arose recently in evolution in the catarrhine lineage, we sought to examine how the sequences and expression of this gene family may have changed after the introduction of a new member, DAZ. Based on previous results, we hypothesized that the introduction of a new member of the DAZ gene family into catarrhines could reduce functional constraint on DAZL. Surprisingly, however, we found that platyrrhine DAZL demonstrated significantly more sequence divergence than catarrhine DAZL (p=0.0006 for nucleotide and p=0.05 for amino acid sequence); however, comparison of K (a)/K (s) ratios suggests that the DAZL and BOULE genes are under similar functional constraints regardless of lineage. Thus, our data are most consistent with the hypothesis that the introduction of DAZ did not affect the evolution of DAZL or BOULE, and that a higher neutral mutation rate in platyrrhines than in catarrhines, along with the greater tolerance of DAZL for variation relative to BOULE, may be the foundation for the observed differences in sequence divergence in this gene family.

Association of meiotic arrest with lack of BOULE protein expression in infertile men.

Spermatogenesis is a complex developmental process of mitotic and meiotic cell divisions that ultimately results in production of haploid spermatozoa. Recent studies in flies demonstrate that the BOULE gene encodes a key factor of meiosis in male germ cells, regulating the expression of twine, a cdc25 phosphatase, which promotes progression through meiosis. In this study, we investigated whether a common mechanism underlies the block of germ cell maturation observed in idiopathic and nonidiopathic azoospermic patients with meiotic arrest. We examined, by immunohistochemistry, BOULE and CDC25A phosphatase protein, the human homolog of twine, expression in 47 men with meiotic arrest, mixed atrophy, or normal spermatogenesis. The presence of genetic alterations within the BOULE gene was investigated by single-stranded conformation polymorphism. BOULE protein expression in men with complete spermatogenesis can be restricted to stages from leptotene up to stages of late spermatocytes, whereas CDC25A expression ranges from leptotene spermatocytes to elongating spermatids. Although spermatocytes were present in all testicular biopsies with meiotic arrest (28 testes), BOULE protein expression was completely lacking. In addition, in nearly all biopsies in which BOULE was absent, CDC25A was concomitantly lacking. However, no mutations or polymorphisms in the BOULE gene were identified, which could explain the lack of BOULE or CDC25A expression. These results indicate that a major group of infertile men with meiotic arrest lack BOULE protein and its putative target, CDC25A expression. The spermatogenic failure seems to arise from factor(s) upstream of BOULE, which are possibly involved in regulating transcription and/or translation of BOULE. Thus, the spermatogenic damage leading to meiotic arrest is independent of the etiology and indicates that BOULE is a possible fundamental mediator of meiotic transition in the human.