DNMT3L promotes quiescence in postnatal spermatogonial progenitor cells.

The ability of adult stem cells to reside in a quiescent state is crucial for preventing premature exhaustion of the stem cell pool. However, the intrinsic epigenetic factors that regulate spermatogonial stem cell quiescence are largely unknown. Here, we investigate in mice how DNA methyltransferase 3-like (DNMT3L), an epigenetic regulator important for interpreting chromatin context and facilitating de novo DNA methylation, sustains the long-term male germ cell pool. We demonstrated that stem cell-enriched THY1(+) spermatogonial stem/progenitor cells (SPCs) constituted a DNMT3L-expressing population in postnatal testes. DNMT3L influenced the stability of promyelocytic leukemia zinc finger (PLZF), potentially by downregulating Cdk2/CDK2 expression, which sequestered CDK2-mediated PLZF degradation. Reduced PLZF in Dnmt3l KO THY1(+) cells released its antagonist, Sal-like protein 4A (SALL4A), which is associated with overactivated ERK and AKT signaling cascades. Furthermore, DNMT3L was required to suppress the cell proliferation-promoting factor SALL4B in THY1(+) SPCs and to prevent premature stem cell exhaustion. Our results indicate that DNMT3L is required to delicately balance the cycling and quiescence of SPCs. These findings reveal a novel role for DNMT3L in modulating postnatal SPC cell fate decisions.

DAZAP1 regulates the splicing of Crem, Crisp2 and Pot1a transcripts.

Deleted in Azoospermia Associated Protein 1 (DAZAP1) is a ubiquitous heterogeneous nuclear ribonucleoprotein (hnRNP) that is expressed abundantly in the testis. DAZAP1 deficiency in mice results in growth retardation and spermatogenic arrest. Previous reports on DAZAP1's binding to several naturally occurring splicing mutations support a role for DAZAP1 in RNA splicing. To elucidate the biological function(s) of DAZAP1 and to search for its natural RNA substrates, we used microarrays to compare the expression profiles and exon usages of wild-type and Dazap1 mutant testes and identified three genes (Crem, Crisp2 and Pot1a) with aberrant RNA splicing in the mutant testes. We further demonstrated that DAZAP1, but not DAZAP1 mutant proteins, promoted the inclusion of Crem exon 4, Crisp2 exon 9 and Pot1a exon 4 in splicing reporter transcripts in cultured cells. Additional studies on the binding of DAZAP1 to the exons and their flanking intronic sequences and the effects of minigene deletions on exon inclusion identified regulatory regions in Crem intron 3, Crisp2 intron 9 and Pot1a intron 4 where DAZAP1 bound and regulated splicing. Aberrant splicing of the Pot1a gene, which encodes an essential protein that protects telomere integrity, may partially account for the growth retardation phenotype of DAZAP1-deficient mice.

Transcription-dependent nuclear localization of DAZAP1 requires an N-terminal signal.

Deleted in Azoospermia Associated Protein 1 (DAZAP1) is a ubiquitous hnRNP protein required for normal development and spermatogenesis. It resides predominantly in the nucleus and moves between the nucleus and the cytoplasm via a ZNS shuttling signal at its C-terminus. DAZAP1 accumulates in the cytoplasm when RNA polymerase II activity is inhibited by actinomycin D. Here we report the mapping of a 42-amino acid segment (N42) at the N-terminus of DAZAP1 that is both necessary and sufficient for its transcription-dependent nuclear localization. In addition, using a yeast two-hybrid system, we have identified SLIRP as a N42-binding protein which may regulate DAZAP1 subcellular localization.

DAZAP1, an hnRNP protein, is required for normal growth and spermatogenesis in mice.

DAZAP1 (Deleted in Azoospermia Associated Protein 1) is a ubiquitous hnRNP protein that is expressed most abundantly in the testis. Its ability to shuttle between the nucleus and the cytoplasm and its exclusion from the transcriptionally inactive XY body in pachytene spermatocytes implicate it in mRNA transcription and transport. We generated Dazap1 mutant alleles to study the role of DAZAP1 in mouse development. Most mice homozygous for the null allele as well as a hypomorphic Fn allele died soon after birth. The few Dazap1(Fn/Fn) mice that survived could nonetheless live for more than a year. They appeared and behaved normally but were much smaller in size compared to their wild-type and heterozygous littermates. Both male and female Dazap1(Fn/Fn) mice were sterile. Males had small testes, and the seminiferous tubules were atrophic with increased numbers of apoptotic cells. The tubules contained many germ cells, including pachytene spermatocytes with visible XY-bodies and diplotene spermatocytes, but no post-meiotic cells. FACS analyses confirmed the absence of haploid germ cells, indicating spermatogenesis arrested right before the meiotic division. Female Dazap1(Fn/Fn) mice had small ovaries that contained normal-appearing follicles, yet their pregnancy produced no progeny due to failure in embryonic development. The phenotypes of Dazap1 mutant mice indicate that DAZAP1 is not only essential for spermatogenesis, but also required for the normal growth and development of mice.

The expression level of septin12 is critical for spermiogenesis.

Septins belong to a family of polymerizing GTP-binding proteins that are required for many cellular functions, such as membrane compartmentalization, vesicular trafficking, mitosis, and cytoskeletal remodeling. One family member, septin12, is expressed specifically in the testis. In this study, we found septin12 expressed in multiple subcellular compartments during terminal differentiation of mouse germ cells. In humans, the testicular tissues of men with either hypospermatogenesis or maturation arrest had lower levels of SEPTIN12 transcripts than normal men. In addition, increased numbers of spermatozoa with abnormal head, neck, and tail morphologies lacked SEPT12 immunostaining signals, as compared with normal spermatozoa. To elucidate the role of septin12, we generated 129 embryonic stem cells containing a septin12 mutant allele with a deletion in the exons that encode the N-terminal GTP-binding domain. Most chimeras derived from the targeted embryonic stem cells were infertile, and the few fertile chimeras only produced offspring with a C57BL/6 background. Semen analysis of the infertile chimeras showed a decreased sperm count, decreased sperm motility, and spermatozoa with defects involving all subcellular compartments. The testicular phenotypes included maturation arrest of germ cells at the spermatid stage, sloughing of round spermatids, and increased apoptosis of germ cells. Electron microscopic examination of spermatozoa showed misshapen nuclei, disorganized mitochondria, and broken acrosomes. Our data indicate that Septin12 expression levels are critical for mammalian spermiogenesis.

Evolution of the DAZ gene and the AZFc region on primate Y chromosomes.

BACKGROUND: The Azoospermia Factor c (AZFc) region of the human Y chromosome is a unique product of segmental duplication. It consists almost entirely of very long amplicons, represented by different colors, and is frequently deleted in subfertile men. Most of the AZFc amplicons have high sequence similarity with autosomal segments, indicating recent duplication and transposition to the Y chromosome. The Deleted in Azoospermia (DAZ) gene within the red-amplicon arose from an ancestral autosomal DAZ-like (DAZL) gene. It varies significantly between different men regarding to its copy number and the numbers of RNA recognition motif and DAZ repeat it encodes. We used Southern analyses to study the evolution of DAZ and AZFc amplicons on the Y chromosomes of primates. RESULTS: The Old World monkey rhesus macaque has only one DAZ gene. In contrast, the great apes have multiple copies of DAZ, ranging from 2 copies in bonobos and gorillas to at least 6 copies in orangutans, and these DAZ genes have polymorphic structures similar to those of their human counterparts. Sequences homologous to the various AZFc amplicons are present on the Y chromosomes of some but not all primates, indicating that they arrived on the Y chromosome at different times during primate evolution. CONCLUSION: The duplication and transposition of AZFc amplicons to the human Y chromosome occurred in three waves, i.e., after the branching of the New World monkey, the gorilla, and the chimpanzee/bonobo lineages, respectively. The red-amplicon, one of the first to arrive on the Y chromosome, amplified by inverted duplication followed by direct duplication after the separation of the Old World monkey and the great ape lineages. Subsequent duplication/deletion in the various lineages gave rise to a spectrum of DAZ gene structure and copy number found in today's great apes.

Restricted expression of the human DAZ protein in premeiotic germ cells.

BACKGROUND: The role of the Y chromosome-encoded Deleted in Azoospermia (DAZ) gene family in spermatogenesis remains unclear. The ability of men without the DAZ gene to produce sperm, as well as the lack of selective pressure on DAZ exon sequences during evolution, casts doubts on its functional significance. Most men have four DAZ genes encoding protein isoforms that differ significantly in size. However, published western blots showed only a single "DAZ" band, raising the possibility that not all four DAZ genes are expressed. METHODS: RT-PCR, western blotting and immunostaining were used to study the expression of the four DAZ genes and the autosomal DAZL gene in human testes and in tissue culture cells. RESULTS: RNA transcripts of all four DAZ genes were found in the testis, but at much lower levels than that of the DAZL transcripts. Expression in cultured somatic cells showed that DAZ transcripts encoding multiple DAZ repeats were translated inefficiently. No DAZ proteins could be unambiguously identified on western blots when the testicular samples from three patients without the DAZ genes were used as negative controls. Nonetheless, low levels of DAZ were detected in the cytoplasm of spermatogonia by immunostaining. CONCLUSIONS: The expression of DAZ proteins in adult human testes is restricted to the spermatogonia and suggests a premeiotic role.

Partial duplication at AZFc on the Y chromosome is a risk factor for impaired spermatogenesis in Han Chinese in Taiwan.

The Azoospermia Factor c (AZFc) region on the Y chromosome long arm is one of the least stable regions in the human genome. It consists almost entirely of very long repeats and is prone to rearrangement. Numerous structures at AZFc have been identified, and some of them have been reported to be associated with male infertility. We screened 580 Han Chinese in Taiwan for AZFc deletion and duplication using three PCR assays, and characterized the DAZ genes in selected subjects with additional Southern analyses. About 9.5% of our subjects have AZFc partial deletion, 2.8% have partial deletion followed by duplication, and 1.7% have partial duplication. The overall rearrangement frequencies vary significantly between different Y chromosome haplogroups (Yhgs), ranging from 2.9% in O3e to 100% in N and Q. All individuals in Yhg-N lack the sY1191 marker, but one out of three of them actually have four DAZ genes, indicating further duplication after the b2/b3 deletion. Our additional screening of 142 oligospermic men and 107 fertile controls found no significant difference in the frequencies of the gr/gr and the b2/b3 deletion. However, the frequency of AZFc partial duplication in the infertile group (7.0%) was significantly higher than that in the fertile control group (0.9%) and the general Taiwanese population (1.7%). Our results indicate that AZFc partial deletion and partial duplication are common polymorphisms in Han Chinese, and that the AZFc partial duplication, but not the AZFc partial deletion, is a risk factor for male infertility in the Taiwanese population.

Key apoptotic pathways for heat-induced programmed germ cell death in the testis.

Short-term exposure (43 C for 15 min) of the rat testis to mild heat results within 6 h in stage- and cell-specific activation of germ cell apoptosis. Initiation of apoptosis was preceded by a redistribution of Bax from a cytoplasmic to paranuclear localization in heat-susceptible germ cells. Here we show that the relocation of Bax is accompanied by cytosolic translocation of cytochrome c and is associated with activation of the initiator caspase 9 and the executioner caspases 3, 6, and 7 and cleavage of poly(ADP) ribose polymerase. Furthermore, early in apoptosis, a significant amount of Bax also accumulates in endoplasmic reticulum, as assessed by Western blot analyses of fractionated testicular lysates. In additional studies using the FasL-defective gld mice, we have shown that heat-induced germ cell apoptosis is not blocked, thus providing evidence that the Fas signaling system may be dispensable for heat-induced germ cell apoptosis in the testis. Taken together, these results demonstrate that the mitochondria- and possibly also endoplasmic reticulum-dependent pathways are the key apoptotic pathways for heat-induced germ cell death in the testis.

Deciphering the pathways of germ cell apoptosis in the testis.

A growing body of evidence demonstrates that germ cell death both spontaneous (during normal spermatogenesis) and that induced by suppression of hormonal support or increased scrotal temperature occurs via apoptosis. The mechanisms by which these proapoptotic stimuli activate germ cell apoptosis are not well understood. In order to provide some insight, here we report the key molecular components of the effector pathways leading to caspase activation and increased germ cells apoptosis triggered by mildly increased scrotal temperature. Short-term exposure (43 degrees C for 15 min) of the testis to mild heat results, within 6h, in stage- and cell-specific activation of germ cell apoptosis in rats. Initiation of apoptosis was preceded by a redistribution of Bax from a cytoplasmic to paranuclear localization in heat-susceptible germ cells. Such relocation of Bax is further accompanied by sequestration of mitochondria and endoplasmic reticulum (ER) into paranuclear areas, cytosolic translocation of cytochrome c and is associated with activation of the initiator caspase 9 and the executioner caspases 3, 6, and 7, and cleavage of PARP. Furthermore, Bax is co-localized with ER in the susceptible germ cells as assessed by combined two-photon and confocal microscopy and Western blot analyses of fractionated testicular lysates. In additional studies, using gld and lpr(cg) mice, which harbor loss-of-function mutations in Fas-ligand (FasL) and Fas, respectively, we demonstrated that heat-induced germ cell apoptosis is not blocked, thus providing further evidence that the Fas signaling system is dispensable for heat-induced germ cell apoptosis in the testis. Taken together, these results demonstrate that the mitochondria- and possibly also ER-dependent pathways are the key apoptotic pathways for heat induced germ cell death in the testis.

Deleted in azoospermia associated protein 1 shuttles between nucleus and cytoplasm during normal germ cell maturation.

DAZAP1 (Deleted in Azoospermia Associated Protein 1) was originally identified through its interaction with a putative male azoospermia factor, DAZ (Deleted in Azoospermia). It contains 2 RNA-binding domains (RBDs) and a proline-rich C-terminal portion and is expressed most abundantly in testes. We used RNA in situ hybridization and immunocytochemistry to study the expression of Dazap1 in mouse testes. Dazap1 messenger RNA (mRNA) was present predominantly in immature germ cells, between the intermediate spermatogonia and preleptotene spermatocyte stages. The DAZAP1 protein was more abundant in germ cells of later stages of development and showed a dynamic subcellular distribution. High expression of DAZAP1 was first detected in midpachytene spermatocytes in stage VII tubules. In these cells, DAZAP1 was present in both the cytoplasm and the nuclei and was clearly excluded from the sex vesicles. In round spermatids, DAZAP1 was localized mainly in the nuclei, whereas in elongated spermatids, it redistributed to the cytoplasm. The subcellular distribution of DAZAP1 suggests that it shuttles between the nucleus and the cytoplasm and may play a role in mRNA transport and/or localization.

Two Y chromosomes with duplication of the distal long arm including the entire AZFc region.

Chromosome anomalies/rearrangements of the Y chromosome seldom threaten life and are quite common. The 4.5 Mb AZFc region on Yq11.2 is one of the most polymorphic regions in the human genome. AZFc partial deletion is almost inevitably associated with impaired fertility while the functional significance of AZFc partial duplications remains controversial. In this report, a large Y chromosome with one centromere and two heterochromatic blocks was identified incidentally in two men. The first case was ascertained through surveillance for recurrent miscarriage. The second case was ascertained through amniocytes of a fetus and his father. FISH and array-based comparative genomic hybridization showed duplications of the entire AZFc region as well as Yq euchromatic region. The duplications in Case 1 and Case 2 spanned 4.8 Mb and 6.2 Mb, respectively, of the Yq euchromatic region. These two cases suggest that complete AZFc duplication could be completely benign. It awaits further investigation whether this is a bona fide chromosomal polymorphism.

Differential translation of Dazap1 transcripts during spermatogenesis.

Deleted in AZoospermia Associated Protein 1 (DAZAP1) is a ubiquitous hnRNP protein that has been implicated in RNA transcription, splicing, and translation. It is highly expressed in testes, predominantly in late stage spermatocytes and post-meiotic spermatids. Dazap1 deficiency in mice results in growth retardation and spermatogenic arrest. The gene produces two major transcripts of 2.4 and 1.8 kb, designated Dazap1-L and Dazap1-S, respectively. Results of our previous RNA in situ hybridization and immunostaining suggested translational regulation of the Dazap1 transcripts during spermatogenesis. The main objectives of the study were to determine the origin of the two Dazap1 transcripts and to investigate whether they were similarly translated. Our Northern and 3' RACE analyses showed that the two transcripts were generated through alternative polyadenylation. In mouse testes, the levels of both transcripts were low at postnatal day 12 (P12), increased significantly at P18, and reached maximum at P27. Sucrose gradient analyses showed that at P12 both transcripts were actively translated. Afterward, an increasing portion of Dazap1-S became associated with the translationally inactive mRNPs, and the translational repression was accompanied by an increase in the length of its poly(A) tail. A much smaller portion of Dazap1-L was also sequestered to mRNPs as testes matured, but there was no changes in its poly(A) tail length. Using RNA pull-down followed by mass spectrometry, we identified DAZL, a germ-cell specific translation regulator, as one of the proteins that bound to the 3'UTR region specific for Dazap1-L. We further showed that DAZL preferentially bound to Dazap1-L in testis lysates and stimulated the translation of a reporter gene carrying Dazap1-L 3'UTR. In summary, our study shows that the translation of the two Dazap1 transcripts is differentially regulated. It also provides a new example of translational repression associated with poly(A) tail elongation during spermatogenesis.

Mouse sperm acquire a new structure on the apical hook during epididymal maturation.

Spermatozoa emerging from the testis undergo a maturation process in the epididymis during which they change morphologically, biochemically and physiologically to gain motility and the ability to fertilize ova. We examined mouse epididymal sperm with immunostaining and transmission electron microscopy (EM) and identified a previously unknown structure on the apical hook. The structure has a coiled configuration around 11 nm in thickness and is present at the tip of each corner of the triangular-rod shaped perforatorium. Surveying sperm isolated from various regions of the epididymis indicated that mouse sperm acquire the hook rim (HR) structure during its passage through the proximal two-thirds of the caput epididymidis. The structure withstands vigorous sonication and harsh chemical treatments and remains intact after the acrosome reaction. Its location and sturdiness suggest a function in protecting the apical hook from mechanical wear during fertilization. Our EM images of epididymal sperm also revealed additional novel structures as well as lateral asymmetry of the sperm head, indicating that mouse sperm head has a structure more complex than previously recognized.

TEX11 modulates germ cell proliferation by competing with estrogen receptor ß for the binding to HPIP.

Klinefelter syndrome (KS), characterized by the presence of more than one X-chromosome in men, is a major genetic cause of male infertility. Germ cell degeneration in KS patients is thought to be the consequences of overexpression of some genes on the X-chromosome. However, the identity of these genes and the underlying mechanisms remain unclear. Testis-expressed 11 (TEX11) is an X-chromosome-encoded germ-cell-specific protein that is expressed most abundantly in spermatogonia and early spermatocytes in the testes. In our search for TEX11-interacting partners using the yeast two-hybrid system, we identified hematopoietic pre-B cell leukemia transcription factor-interacting protein (HPIP), which anchors estrogen receptors (ER) to the cytoskeleton and modulates their functions. We found that mouse spermatogonial stem cells expressed Tex11, Hpip, and Esr2 but not Esr1. In cultured cells, TEX11 competed with ERß for binding to HPIP. Upon treatment with 17ß-estradiol or an ERß agonist diarylpropionitrile, TEX11 promoted the nuclear translocation of ERß and enhanced its transcriptional activities. On the other hand, TEX11 suppressed the nongenomic activities of ERß in the cytoplasm, as indicated by reduced phosphorylation of AKT and ERK signaling molecules. Overexpression of TEX11 in mouse germ-cell-derived GC-1 and GC-2 cells suppressed the cell proliferation and the expression of cFos, Ccnd1, and Ccnb1 that were stimulated by 17ß-estradiol or diarylpropionitrile and elevated the expression level of the proapoptotic Bax gene. The negative effect of TEX11 on cell proliferation suggests that increased expression of TEX11 in the germ cells may partially contribute to the spermatogenic defect observed in KS patients.

Intragenic microdeletion of RUNX2 is a novel mechanism for cleidocranial dysplasia.

Cleidocranial dysplasia (CCD; MIM 119600) is a rare autosomal dominant disorder characterized by facial, dental, and skeletal malformations. To date, rearrangement and mutations involving RUNX2, which encodes a transcription factor required for osteoblast differentiation on 6p21, has been the only known molecular etiology for CCD. However, only 70% patients were found to have point mutations, 13% large/contiguous deletion but the rest of 17% remains unknown. We ascertained a family consisted of eight affected individuals with CCD phenotypes. Direct sequencing analysis revealed no mutations in the RUNX2. Real time quantitative PCR were performed which revealed an exon 2 to exon 6 intragenic deletion in RUNX2. Our patients not only demonstrated a unique gene change as a novel mechanism for CCD, but also highlight the importance of considering "deletion" and "duplication" in suspected familial cases before extensive effort of gene hunting be carried.

A novel nucleocytoplasmic shuttling sequence of DAZAP1, a testis-abundant RNA-binding protein.

Deleted in Azoospermia Associated Protein 1 (DAZAP1) is a ubiquitous RNA-binding protein highly expressed in the human and the mouse testes. It shows a dynamic subcellular localization during spermatogenesis, present predominantly in the nuclei of late-stage spermatocytes and round spermatids and translocated to the cytoplasm during spermatid elongation. To test the hypothesis that DAZAP1 shuttles between the nucleus and the cytoplasm, we studied the nuclear transport of DAZAP1 in somatic cells using immunostaining, heterokaryon formation, and mutagenesis. DAZAP1 is detected exclusively in the nucleus and has the ability to shuttle between the nucleus and the cytoplasm using a highly conserved 25 amino acid segment, designated ZNS, at its C terminus. ZNS shares no sequence homology with other known nuclear localization or export signals. Attachment of ZNS to a red fluorescent protein DsRed2 confers the nucleocytoplasmic shuttling ability to that protein. The nuclear localization of DAZAP1 depends on active transcription. In the presence of an RNA polymerase II inhibitor, DAZAP1 is retained in the cytoplasm. DAZAP1 colocalizes with hnRNP A1 and hnRNP C1 in the nucleus and is a component of the heterogeneous nuclear ribonucleoprotein particles. Our results suggest that DAZAP1 plays a key role in mRNA transport during spermatogenesis.

A two-step protocol for the detection of rearrangements at the AZFc region on the human Y chromosome.

The AZFc region on the human Y chromosome consists mainly of very long direct and inverted repeats and is prone to rearrangement. Although deletion of the entire AZFc is found only in subfertile men, duplications and deletions of portions of AZFc as well as inversions are quite common and represent major polymorphisms of the Y chromosome. Several methods are available to detect these rearrangements, and each has its own advantages and limits. We designed a two-step PCR protocol to study the polymorphic structure of AZFc. The first PCR determines the copy number of the Deleted in Azoospermia (DAZ) genes within AZFc using the autosomal DAZ-Like gene as a dosage control, and the results could be verified by dosage Southern blot analyses. The second PCR simultaneously detects five sequence tagged sites (STSs) that are either present or absent in the various AZFc partial deletions. One of the STSs, sY1291, was found to be polymorphic in size due to varying lengths of a poly-T stretch. A combination of the DAZ dosage PCR and the 5-STS multiplex PCR reaction detects most, if not all, deletions and duplications at AZFc. It offers a simple and reliable way to screen large populations for AZFc rearrangements and study their effects on male fertility.

Polymorphisms associated with the DAZ genes on the human Y chromosome.

The human Y chromosome is unique in that it does not engage in pairing and crossing over during meiosis for most of its length. Y chromosome microdeletions, a frequent finding in infertile men, thus occur through intrachromosomal recombination, either within a single chromatid or between sister chromatids. A recently identified polymorphism associated with increased risk for spermatogenic failure, the gr/gr deletion, removes two of the four Deleted in Azoospermia (DAZ) genes in the AZFc region on the Y-chromosome long arm. We found the likely reciprocal duplication product of gr/gr deletion in 5 (6%) of 82 males using a novel DNA-blot hybridization strategy and confirmed the presence of six DAZ genes in three cases by FISH analysis. Additional polymorphisms identified within the DAZ repeat regions of the DAZ genes indicate that sister chromatid exchange plays a significant role in the genesis of deletions, duplications, and polymorphisms of the Y chromosome.

Putative biological functions of the DAZ family.

The Deleted in Azoospermia (DAZ) gene belongs to a gene family that consists of three members: BOULE, DAZ-Like (DAZL) and DAZ. Members of the DAZ family are expressed exclusively in the germ cells, and their protein products contain a highly conserved RNA-binding motif and a unique DAZ repeat. Null mutations of the DAZ family members affect the fertility of either male or female, or both sexes. DAZ and DAZL are expressed throughout most of the life of germ cells and are required for the development of primordial germ cells and the differentiation and maturation of the germ cells. BOULE is expressed around the time of meiosis and has a more limited function. The DAZ proteins bind to RNAs in vitro and in vivo and are probably involved in the post-transcriptional regulation of mRNA expression. Their downstream RNA targets remain largely unknown, although members of the CDC25 gene family are potential candidates.