Gonadotropin-regulated testicular helicase (DDX25), an essential regulator of spermatogenesis, prevents testicular germ cell apoptosis

The Search for Cancer Biomarkers: Assessing the Distribution of INDEL Markers in Different Genetic Ancestries

Cancer is a multifactorial group of diseases, being highly incident and one of the leading causes of death worldwide. In Brazil, there is a great variation in cancer incidence and impact among the different geographic regions, partly due to the genetic heterogeneity of the population in this country, composed mainly by European (EUR), Native American (NAM), African (AFR), and Asian (ASN) ancestries. Among different populations, genetic markers commonly present diverse allelic frequencies, but in admixed populations, such as the Brazilian population, data is still limited, which is an issue that might influence cancer incidence. Therefore, we analyzed the allelic and genotypic distribution of 12 INDEL polymorphisms of interest in populations from the five Brazilian geographic regions and in populations representing EUR, NAM, AFR, and ASN, as well as tissue expression in silico. Genotypes were obtained by multiplex PCR and the statistical analyses were done using R, while data of tissue expression for each marker was extracted from GTEx portal. We highlight that all analyzed markers presented statistical differences in at least one of the population comparisons, and that we found 39 tissues to be differentially expressed depending on the genotype. Here, we point out the differences in genotype distribution and gene expression of potential biomarkers for risk of cancer development and we reinforce the importance of this type of study in populations with different genetic backgrounds.

Chromatoid Bodies in the Regulation of Spermatogenesis: Novel Role of GRTH

Post-transcriptional and translational control of specialized genes play a critical role in the progression of spermatogenesis. During the early stages, mRNAs are actively transcribed and stored, temporarily bound to RNA binding proteins in chromatoid bodies (CBs). CBs are membrane-less dynamic organelles which serve as storehouses and processing centers of mRNAs awaiting translation during later stages of spermatogenesis. These CBs can also regulate the stability of mRNAs to secure the correct timing of protein expression at different stages of sperm formation. Gonadotropin-regulated testicular RNA helicase (GRTH/DDX25) is an essential regulator of spermatogenesis. GRTH transports mRNAs from the nucleus to the cytoplasm and phospho-GRTH transports mRNAs from the cytoplasm to the CBs. During spermiogenesis, there is precise control of mRNAs transported by GRTH from and to the CBs, directing the timing of translation of critical proteins which are involved in spermatid elongation and acrosomal development, resulting in functional sperm formation. This chapter presents our current knowledge on the role of GRTH, phospho-GRTH and CBs in the control of spermiogenesis. In addition, it covers the components of CBs compared to those of stress granules and P-bodies.

Formation of spermatogonia and fertile oocytes in golden hamsters requires piRNAs

PIWI-interacting RNAs (piRNAs) support the germline by suppressing retrotransposons. Studies of the pathway in mice have strongly shaped the view that mammalian piRNAs are essential for male but not for female fertility. Here, we report that the role of the piRNA pathway substantially differs in golden hamsters (Mesocricetus auratus), the piRNA pathway setup of which more closely resembles that of other mammals, including humans. The loss of the Mov10l1 RNA helicase—an essential piRNA biogenesis factor—leads to striking phenotypes in both sexes. In contrast to mice, female Mov10l1^–/– hamsters are sterile because their oocytes do not sustain zygotic development. Furthermore, Mov10l1^–/– male hamsters have impaired establishment of spermatogonia accompanied by transcriptome dysregulation and an expression surge of a young retrotransposon subfamily. Our results show that the mammalian piRNA pathway has essential roles in both sexes and its adaptive nature allows it to manage emerging genomic threats and acquire new critical roles in the germline.

A set of three papers reports that the piRNA pathway is essential for mammalian female fertility based on genetic perturbation experiments performed in golden hamsters.

Characterization of the Phosphorylation Site of GRTH/DDX25 and Protein Kinase A Binding Interface Provides Structural Basis for the Design of a Non-Hormonal Male Contraceptive

Gonadotropin Regulated Testicular Helicase (GRTH/DDX25), expressed in the male gonad, is essential for the completion of spermatogenesis. Our early studies revealed a missense mutation (R242H) of GRTH in 5.8% of Japanese patient population with azoospermia. Transfection of the mutant GRTH construct in COS-1 cells leads to loss of the 61 kDa cytoplasmic phospho-species. Mice with knock-in of the human GRTH mutation are sterile and lack sperm with normal androgen and mating behavior. These findings provide an avenue for the development of a non-hormonal male contraceptive. Using site directed mutagenesis and a site-specific phospho-antibody, we have identified T239, structurally adjacent to the patient’s mutant site as the GRTH phospho-site. Molecular modelling provided structural basis for the role of R242 and other critical solvent-exposed residues at the GRTH/PKA interface (E165/K240/D237), on the control of GRTH phosphorylation at T239. Single or double mutations of these residues caused marked reduction or abolition of the phospho-form. These effects can be ascribed to critical disruptions of intramolecular H-bonds at the GRTH/PKA interface, which leads to modest but consequential structural changes that can affect PKA catalytic efficiency. Inhibition of phosphorylation may be achieved by small, drug-like molecules that bind to GRTH and reconfigure the GRTH/PKA interface.

Gonadotropin Regulation Testicular RNA Helicase, Two Decades of Studies on Its Structure Function and Regulation From Its Discovery Opens a Window for Development of a Non-hormonal Oral Male Contraceptive

Gonadotropin Regulated Testicular Helicase (GRTH/DDX25) is member of the DEAD-box family of RNA helicases present in Leydig and germ cells. GRTH is the only family member regulated by hormones, luteinizing hormone, through androgen action. Male mice with knock-out of the GRTH gene are sterile, lack sperm with arrest at round spermatids. GRTH participates on the nuclear export and transport of specific mRNAs, the structural integrity of Chromatoid Bodies of round spermatids, where mRNAs are processed and stored, and in their transit to polyribosomes, where it may regulate translation of relevant genes. GRTH has a central role in the control of germ cell apoptosis and acts as negative regulator of miRNAs which regulate expression of genes involved in the progress of spermatogenesis. In Leydig cells, GRTH gene transcription is regulated by LH via autocrine actions of androgen/androgen receptor and has regulatory effects in steroidogenesis. In germ cells, androgen actions are indirect via receptors in Sertoli cells. Transgenic mice carrying GRTH 5' flanking region-GFP permitted to discern regions in the gene which directs its expression upstream, in germ cells, and downstream in Leydig cells, and the androgen-regulated transcription at interstitial (autocrine), and germ cell (paracrine) compartments. Further evidence for paracrine actions of androgen/androgen receptor is their transcriptional induction of Germ Cell Nuclear Factor as requisite up-regulator of GRTH gene transcription in round spermatids, linking androgen action to two relevant germ cell genes essential for the progress of spermatogenesis. A missense mutation of R to H at amino acid 242 of GRTH found in 5.8% of a patient population with azoospermia causes loss of the cytoplasmic phospho-GRTH species with preservation of the non-phospho form in transfected cells. Mice with knock-in of the human mutation, lack sperm due to arrest at round spermatids. This model permits to discern the function of phospho-GRTH. The GRTH phospho-site resides at a Threonine structurally adjacent to the mutant site found in patients. Molecular modeling of this site elucidated the amino acids that form the GRTH/PKA interphase and provide the basis for drug design for use as male contraceptive.

Phosphorylation of the RNA-binding protein Dazl by MAPKAP kinase 2 regulates spermatogenesis

Developing male germ cells are exquisitely sensitive to stress and rely on RNA-binding proteins for posttranscriptional gene expression. Phosphorylation of the germ cell–specific RNA-binding protein deleted in azoospermia-like (Dazl) by the stress-activated protein kinase MK2 is a negative regulator of spermatogenesis.

Developing male germ cells are exquisitely sensitive to environmental insults such as heat and oxidative stress. An additional characteristic of these cells is their unique dependence on RNA-binding proteins for regulating posttranscriptional gene expression and translational control. Here we provide a mechanistic link unifying these two features. We show that the germ cell–specific RNA-binding protein deleted in azoospermia-like (Dazl) is phosphorylated by MAPKAP kinase 2 (MK2), a stress-induced protein kinase activated downstream of p38 MAPK. We demonstrate that phosphorylation of Dazl by MK2 on an evolutionarily conserved serine residue inhibits its interaction with poly(A)-binding protein, resulting in reduced translation of Dazl-regulated target RNAs. We further show that transgenic expression of wild-type human Dazl but not a phosphomimetic form in the Drosophila male germline can restore fertility to flies deficient in boule, the Drosophila orthologue of human Dazl. These results illuminate a novel role for MK2 in spermatogenesis, expand the repertoire of RNA-binding proteins phosphorylated by this kinase, and suggest that signaling by the p38-MK2 pathway is a negative regulator of spermatogenesis via phosphorylation of Dazl.

The expression pattern of PARP-1 and PARP-2 in the developing and adult mouse testis

Although the importance of the PARP family members in the adult testis has already been acknowledged, their expression in the developing testis has not been addressed. We performed immunohistochemistry by using PARP-1 and PARP-2 antibodies on the developing mouse testis at embryonic day (E) 15.5, E17.5, postnatal day (PN) 0, PN3, PN9, PN20 and adult. Our results showed that at embryonic and early postnatal days, the expression of PARP-1 was in the nuclei of gonocytes and spermatogonia. PARP-1 was positive in interstitial cells with nuclear localization at all studied ages. At embryonic and early postnatal days, the expression of PARP-2 was in the cytoplasm of gonocytes and spermatogonia. During the progress of spermatogenesis, PARP-2 was localized in the cytoplasm of pre-leptotene spermatocytes on PN9, in the cytoplasm of pachytene spermatocytes on PN15 and in the cytoplasm of round spermatids on PN20. In the adult, PARP-2 staining can still be observed in the cytoplasm of spermatogonia, but to a much lesser degree than in the round and elongating spermatids. For all the studied ages, PARP-2 was positive in Sertoli cells and interstitial cells with cytoplasmic localization. Our results indicate that PARP proteins are present in germ and somatic cells during testis development in mice.

Association of the gonadotrophin-regulated testicular RNA helicase gene polymorphism with human male infertility

Gonadotrophin-regulated testicular RNA helicase (GRTH) plays an important role in RNA functions including nuclear transcription, pre-mRNA splicing and it regulates the translation of specific genes required for the progression of spermatogenesis. In this study, we analysed the association of GRTH gene IVS6+55G/T and c.852C/T polymorphisms with human male infertility. The study showed c.852 T allele was associated with an increased risk of male infertility (OR: 3.16, P = 0.008), whereas IVS6+55G/T allele conferred no risk. In Indian population, this is the first report on association of GRTH gene SNP polymorphism and male infertility and it underscores the significance of GRTH genotypes in modulating the risk of male infertility.

A 5'-flanking region of gonadotropin-regulated testicular RNA helicase (GRTH/DDX25) gene directs its cell-specific androgen-regulated gene expression in testicular germ cells

Gonadotropin-regulated testicular RNA helicase (GRTH/Ddx25) is a posttranscriptional regulator of genes that are essential for spermatid elongation and completion of spermatogenesis. It also prevents Leydig cells (LCs) from gonadotropin overstimulation of androgen production. In transgenic (Tg) mice carrying deletions of the GRTH 5'-flanking regions, we previously demonstrated that the -1085 bp to ATG contains the elements for basal and androgen-induced LC-specific expression. No expression in germ cells (GCs) was found with sequences extended up to -3.6 kb. To define regulatory regions of GRTH required for expression in GC, Tg mice were generated with 5'-flanking sequence 6.4 kb (6.4 Kb-Tg) and/or deletion using green fluorescent protein (GFP) as reporter gene in the present study. GFP was expressed in all lines. Immunohistochemistry analysis showed that 6.4 Kb-Tg directed GFP expression in both GCs and LCs. Deletion of the sequence -205 bp to -3.6 kb (6.4 Kb/del-Tg) directs GFP expression only in meiotic and haploid GCs. This indicated that the distal region -6.4 kb/-3.6 kb is required for GRTH cell-specific expression in GC. Also, it inhibits the expression of GRTH in LC directed by the 205-bp promoter, an effect that is neutralized by the -3.6-kb/-205-bp sequence. Androgen receptor antagonist, flutamide treatment prevents GFP/GRTH expression in Tg lines, demonstrating in vivo direct and indirect effects of endogenous androgen on LCs and GCs, respectively. Our studies have generated and characterized Tg lines that can be used to define requirements for cell-specific expression of the GRTH gene and to further advance our knowledge on the regulation of GRTH by androgen in GCs.

DNA helicase 3.6.4.12

EC number

 3.6.4.12

Systematic name

 ATP phosphohydrolase (DNA helix unwinding)

Recommended name

 DNA helicase

Synonyms

 3’ to 5’ DNA helicase <28> [35]

 3’-5’ DNA helicase <11> [55]

 3’-5’ PfDH <11> [55]

 5’ to 3’ DNA helicase <26,27> [19,42]

 AvDH1 <47> [37]

 BACH1 helicase <19> [34]

 BLM <3> [28]

 BLM protein <3> [28]

 BRCA1-associated C-terminal helicase <19> [34]

 BcMCM <8> [52]

 CeWRN-1 <43> [9]

 DDX25 <3,48> [36]

 DNA helicase 120 <7> [15]

 DNA helicase A <4> [8]

 DNA helicase E <5> [44]

 DNA helicase II <9> [7]

 DNA helicase III <4> [27]

 DNA helicase RECQL5β <44> [17]

 DNA helicase VI <3> [45]

 Dbp9p <46> (<46> a member of the DEAD box protein family [24]) [24]

 DmRECQ5 <1> [50]

 DnaB helicase <29> [23]

 E1 helicase <17> [58]

 GRTH/DDX25 <3,48> [36]

 HCoV SF1 helicase <23> [3]

 HCoV helicase <23> [3]

 HDH IV <3> [45]

 Hel E <5> [44]

 Hmi1p <40> [60]

 MCM helicase <6,5,38> [43,54]

 MCM protein <6,35> [43]

 MER3 helicase <22> [30]

 MER3 protein <22> [30]

 MPH1 <28> [35]

 NS3 <12,50> (<12,50> ambiguous [38,65,66]) [38,65,66]

 NS3 NTPase/helicase <14> (<14> ambiguous [67]) [67]

 NS3 protein <12> (<12> ambiguous [63]) [63]

 NTPase/helicase <12,16> (<12> ambiguous [61]) [61,64]

 PDH120 <7> [15]

 PIF1 <33> [51]

 PIF1 helicase <33> [51,53]

 PcrA <37> [20]

 PcrA helicase <37,41,49> [20,21,39]

 PcrASpn <41> [21]

 PfDH A <11> [55]

 Pfh1p <27> [42]

 RECQ5 <1> [49,50]

 RECQ5 helicase <1> (<1> small isoform [49]) [49]

 RECQL5b <44> [17]

 REcQ <31> [13]

 RSF1010 RepA <30> [5]

 RecG <45> [6]

 RecQ helicase <32> [56]

 RecQsim <32> [56]

 Rep52 <24> [40]

 Rrm3p <26> [19]

 Sgs1 <36> [29]

 Sgs1 DNA helicase <36> [29]

 TWINKLE <21> [33]

 Tth UvrD <20> [16]

 UvrD <20,42> [16,22]

 UvrD helicase <39> [18]

 WRN <18> [31]

 WRN RecQ helicase <18> [12]

 WRN helicase <18> [12]

 WRN protein <18> [12]

 WRN-1 RecQ helicase <43> [9]

 Werner Syndrome helicase <18> [31]

 Werner syndrome RecQ helicase <18> [12]

 dheI I <1> [46]

 dnaB <29> [23]

 hPif1 <33> [53]

 helicase DnaB <2> [10]

 helicase II <25> [25]

 helicase PcrA <49> [39]

 helicase UvrD <20> [16]

 helicase domain of bacteriophage T7 gene 4 protein <10> [47]

 non structural protein 3 <12> (<12> ambiguous [61,62]) [61,62]

 nonstructural protein 3 <12,14,50,51> (<12,14,50> ambiguous [38,63,65,66,67]; <51> ambigous [4]) [4,38,63,65,66,67]

 protein NS3 <12> (<12> ambiguous [62]) [62]

 scHelI <4> [26]

 urvD <25> [25]

RNA helicase 3.6.4.13

EC number

 3.6.4.13

Systematic name

 ATP phosphohydrolase (RNA helix unwinding)

Recommended name

 RNA helicase

Synonyms

 1a NTPase/helicase <16> [5]

 ATP/dATP-dependent RNA helicase <1,42> [32]

 ATPase <10,12> [1,36]

 ATPase/RNA helicase <1,42> [32]

 ATPase/helicase <10> [36,41]

 BMV 1a protein <16> [5]

 BmL3-helicase <1,42> [32]

 Brr2p <6> [50]

 DBP2 <24> [30]

 DDX17 <33> [12]

 DDX19 <43> [56]

 DDX25 <23,34,35> [12,21]

 DDX3 <25> [8]

 DDX3X <25> (<25> the gene is localized to the X chromosome [12]) [12]

 DDX3Y <29> (<29> the gene is localized to the Y chromosome [12]) [12]

 DDX4 <30> [12]

 DDX5 <32> [12]

 DEAD box RNA helicase <1,2,3> [32,45,52]

 DEAD box helicase <2> [45]

 DEAD-box RNA helicase <4,5,7,38,47,48> [9,14,16,25,53,55]

 DEAD-box protein DED1 <38> [11]

 DEAD-box rRNA helicase <5> [26]

 DEAH-box RNA helicase <24> [30]

 DEAH-box protein 2 <24> [30]

 DED1 <38> [11,14]

 DENV NS3H <10> [41]

 DEXD/H-box RNA helicase <43> [56]

 DEx(H/D)RNA helicase <12> [23]

 DHX9 <44> [58]

 DbpA <5> [10,25,26]

 Dhx9/RNA helicase A <13> [61]

 EhDEAD1 <7> [16]

 EhDEAD1 RNA helicase <7> [16]

 FRH <9> [54]

 FRQ-interacting RNA helicase <9> [54]

 GRTH <3> [57]

 GRTH/DDX25 <3,35> [21,51]

 HCV NS3 helicase <12> [48]

 KOKV helicase <27> [7]

 Mtr4p <31> [22]

 NPH-II <8> [18,28]

 NS3 <10,12,17,20,39,41> (<12,39> ambiguous [27,42,44]) [1,2,4,27,35,36,39, 42,44,46]

 NS3 ATPase/helicase <10> [41]

 NS3 NTPase/helicase <17> (<17> ambiguous [46]) [46]

 NS3 helicase <10,12,17> [15,44,46]

 NS3 protein <10,12,17,18> (<12> ambiguous [39]) [15,39,40,41,62]

 NTPase/helicase <12> (<12> ambiguous [37]) [37,39]

 RHA <6> [31,49]

 RNA helicase <2> [45]

 RNA helicase A <6,44> [31,49,58]

 RNA helicase CrhR <14> [59]

 RNA helicase DDX3 <25> [8]

 RNA helicase Ddx39 <47> [53]

 RNA helicase Hera <4> [9]

 RNA-dependent ATPase <37> [34]

 RNA-dependent NTPase/helicase <12> [1]

 RTPase <10> [36]

 RhlB <5> [43]

 SpolvlgA <48> [55]

 Supv3L1 <46> [64]

 TGBp1 NTPase/helicase domain <22,28> [24]

 Tk-DeaD <15> [47]

 VRH1 <26> [33]

 YxiN <2> [45]

 eIF4A <36> [20]

 eIF4A helicase <36> [20]

 eIF4AIII <37> [34]

 eukaryotic initiation factor eIF 4A <36> [20]

 gonadotropin-regulated testicular RNA helicase <3> [51,57]

 helicase <10> [41]

 helicase B <5> [43]

 helicase/nucleoside triphosphatase <10> [4]

 non structural protein 3 <12> (<12> ambiguous [37,38]) [37,38]

 non-structural 3 <10> [36]

 non-structural protein 3 <17> [46]

 non-structural protein 3 protein <18> [40]

 nonstructural protein 3 <12,17,20,39,40,41> (<12,17,39,40> ambiguous [6,27, 39,42,44,46]) [1,2,6,27,35,39,42,44,46]

 nucleoside 5’-triphosphatase <10> [4]

 nucleoside triphosphatase/RNA helicase and 5’-RNA triphosphatase <20> [2]

 nucleoside triphosphatase/helicase <16> [5]

 p54 RNA helicase <45> [60]

 p68 RNA helicase <3,6> [52,63]

 protein NS3 <12> (<12> ambiguous [38]) [38]

Proteome analysis of the fathead minnow (Pimephales promelas) reproductive testes

Proteomics is becoming more widely used as a tool in fish physiology and toxicology and can offer mechanistic insight into organism responses to environmental signals and stressors. Using a LTQ Orbitrap Velos MS/MS, we detected 1075 proteins in the reproductive testis of fathead minnow. Proteins localized to the testis included those with a role in spermatogenesis, DNA repair, gamete meiosis, and proteins that have methylation and phosporylation activity, which are important regulatory mechanisms required for sperm maturation. Enrichment analysis revealed that proteins involved in translation, excision DNA repair, and chromatin remodeling were significantly enriched in the testis (>25% protein coverage of the cellular pathways). Proteins involved in RNA metabolism, spliceosome assembly, metabolism, and DNA unwinding were localized to the testis, and the DEAD (Asp-Glu-Ala-Asp) box RNA-dependent helicase family was well represented in this reproductive tissue. Based upon common detected proteins and functional processes between FHMs and the more ancient sharks, other ray-finned fishes, and mammals, we hypothesize that biological processes involved in the testis (DNA unwinding, RNA processing, spliceosome assembly) have been conserved throughout vertebrate evolution. This study provides the foundation for more in depth proteomics studies investigating the effects of hormones and endocrine disruptors in the teleostean testes.

Sertoli-cell-specific knockout of connexin 43 leads to multiple alterations in testicular gene expression in prepubertal mice

A significant decline in human male reproductive function has been reported for the past 20 years but the molecular mechanisms remain poorly understood. However, recent studies showed that the gap junction protein connexin-43 (CX43; also known as GJA1) might be involved. CX43 is the predominant testicular connexin (CX) in most species, including in humans. Alterations of its expression are associated with different forms of spermatogenic disorders and infertility. Men with impaired spermatogenesis often exhibit a reduction or loss of CX43 expression in germ cells (GCs) and Sertoli cells (SCs). Adult male transgenic mice with a conditional knockout (KO) of the Gja1 gene [referred to here as connexin-43 (Cx43)] in SCs (SCCx43KO) show a comparable testicular phenotype to humans and are infertile. To detect possible signaling pathways and molecular mechanisms leading to the testicular phenotype in adult SCCx43KO mice and to their failure to initiate spermatogenesis, the testicular gene expression of 8-day-old SCCx43KO and wild-type (WT) mice was compared. Microarray analysis revealed that 658 genes were significantly regulated in testes of SCCx43KO mice. Of these genes, 135 were upregulated, whereas 523 genes were downregulated. For selected genes the results of the microarray analysis were confirmed using quantitative real-time PCR and immunostaining. The majority of the downregulated genes are GC-specific and are essential for mitotic and meiotic progression of spermatogenesis, including Stra8, Dazl and members of the DM (dsx and map-3) gene family. Other altered genes can be associated with transcription, metabolism, cell migration and cytoskeleton organization. Our data show that deletion of Cx43 in SCs leads to multiple alterations of gene expression in prepubertal mice and primarily affects GCs. The candidate genes could represent helpful markers for investigators exploring human testicular biopsies from patients showing corresponding spermatogenic deficiencies and for studying the molecular mechanisms of human male sterility.

Role of gonadotropin regulated testicular RNA helicase (GRTH/Ddx25) on polysomal associated mRNAs in mouse testis

Gonadotropin Regulated Testicular RNA Helicase (GRTH/Ddx25) is a testis-specific multifunctional RNA helicase and an essential post-transcriptional regulator of spermatogenesis. GRTH transports relevant mRNAs from nucleus to cytoplasmic sites of meiotic and haploid germ cells and associates with actively translating polyribosomes. It is also a negative regulator of steroidogenesis in Leydig cells. To obtain a genome-wide perspective of GRTH regulated genes, in particularly those associated with polyribosomes, microarray differential gene expression analysis was performed using polysome-bound RNA isolated from testes of wild type (WT) and GRTH KO mice. 792 genes among the entire mouse genome were found to be polysomal GRTH-linked in WT. Among these 186 were down-regulated and 7 up-regulated genes in GRTH null mice. A similar analysis was performed using total RNA extracted from purified germ cell populations to address GRTH action in individual target cells. The down-regulation of known genes concerned with spermatogenesis at polysomal sites in GRTH KO and their association with GRTH in WT coupled with early findings of minor or unchanged total mRNAs and abolition of their protein expression in KO underscore the relevance of GRTH in translation. Ingenuity pathway analysis predicted association of GRTH bound polysome genes with the ubiquitin-proteasome-heat shock protein signaling network pathway and NFκB/TP53/TGFB1 signaling networks were derived from the differentially expressed gene analysis. This study has revealed known and unexplored factors in the genome and regulatory pathways underlying GRTH action in male reproduction.

Control of messenger RNA fate by RNA-binding proteins: an emphasis on mammalian spermatogenesis

Posttranscriptional status of messenger RNAs (mRNA) can be affected by many factors, most of which are RNA-binding proteins (RBP) that either bind mRNA in a nonspecific manner or through specific motifs, usually located in the 3' untranslated regions. RBPs can also be recruited by small noncoding RNAs (sncRNA), which have been shown to be involved in posttranscriptional regulations and transposon repression (eg, microRNAs or P-element-induced wimpy testis-interacting RNA) as components of the sncRNA effector complex. Non-sncRNA-binding RBPs have much more diverse effects on their target mRNAs. Some can cause degradation of their target transcripts and/or repression of translation, whereas others can stabilize and/or activate translation. The splicing and exportation of transcripts from the nucleus to the cytoplasm are often mediated by sequence-specific RBPs. The mechanisms by which RBPs regulate mRNA transcripts involve manipulating the 3' poly(A) tail, targeting the transcript to polysomes or to other ribonuclear protein particles, recruiting regulatory proteins, or competing with other RBPs. Here, we briefly review the known mechanisms of posttranscriptional regulation mediated by RBPs, with an emphasis on how these mechanisms might control spermatogenesis in general.

mRNA helicases: the tacticians of translational control

The translation initiation step in eukaryotes is highly regulated and rate-limiting. During this process, the 40S ribosomal subunit is usually recruited to the 5' terminus of the mRNA. It then migrates towards the initiation codon, where it is joined by the 60S ribosomal subunit to form the 80S initiation complex. Secondary structures in the 5' untranslated region (UTR) can impede binding and movement of the 40S ribosome. The canonical eukaryotic translation initiation factor eIF4A (also known as DDX2), together with its accessory proteins eIF4B and eIF4H, is thought to act as a helicase that unwinds secondary structures in the mRNA 5' UTR. Growing evidence suggests that other helicases are also important for translation initiation and may promote the scanning processivity of the 40S subunit, synergize with eIF4A to 'melt' secondary structures or facilitate translation of a subset of mRNAs.

Transcription and post-transcriptional regulation of spermatogenesis

Spermatogenesis in mammals is achieved by multiple players that pursue a common goal of generating mature spermatozoa. The developmental processes acting on male germ cells that culminate in the production of the functional spermatozoa are regulated at both the transcription and post-transcriptional levels. This review addresses recent progress towards understanding such regulatory mechanisms and identifies future challenges to be addressed in this field. We focus on transcription factors, chromatin-associated factors and RNA-binding proteins necessary for spermatogenesis and/or sperm maturation. Understanding the molecular mechanisms that govern spermatogenesis has enormous implications for new contraceptive approaches and treatments for infertility.

Gonadotropin-regulated testicular RNA helicase (GRTH/DDX25) gene: cell-specific expression and transcriptional regulation by androgen in transgenic mouse testis

Gonadotropin-regulated testicular RNA helicase is a multifunctional enzyme present in both Leydig and germ cells that is essential for the progress of spermatogenesis. GRTH gene expression is transcriptionally upregulated by human chorionic gonadotropin (hCG) via second messenger (cAMP) and androgen in Leydig cells. The regulatory region(s) in the GRTH gene that is/are required for its cell-specific expression in the testis and hCG/androgen dependent expression were investigated in transgenic mice carrying sequential deletions of 5' flanking sequences of the GRTH gene. GFP-reporter gene expression directed by the GRTH 5' flanking sequences extending to -3.6 kb was specifically located in Leydig cells and the 205 bp minimal promoter domain was sufficient for this cell-specific expression. The 1 kb (5' to the ATG codon) transgene-directed expression was markedly increased by in vivo hCG treatment. Administration of the androgen receptor inhibitor Flutamide blocked the basal and hCG stimulated GFP expression in Leydig cells. We conclude that the expression of GRTH in testicular cells is differentially regulated by its 5' flanking sequence and that the 1 kb fragment of GRTH gene contains sequences for androgen regulation of its expression in Leydig cells.

Surfing the wave, cycle, life history, and genes/proteins expressed by testicular germ cells. Part 2: changes in spermatid organelles associated with development of spermatozoa

Spermiogenesis is a long process whereby haploid spermatids derived from the meiotic divisions of spermatocytes undergo metamorphosis into spermatozoa. It is subdivided into distinct steps with 19 being identified in rats, 16 in mouse and 8 in humans. Spermiogenesis extends over 22.7 days in rats and 21.6 days in humans. In this part, we review several key events that take place during the development of spermatids from a structural and functional point of view. During early spermiogenesis, the Golgi apparatus forms the acrosome, a lysosome-like membrane bound organelle involved in fertilization. The endoplasmic reticulum undergoes several topographical and structural modifications including the formation of the radial body and annulate lamellae. The chromatoid body is fully developed and undergoes structural and functional modifications at this time. It is suspected to be involved in RNA storing and processing. The shape of the spermatid head undergoes extensive structural changes that are species-specific, and the nuclear chromatin becomes compacted to accommodate the stream-lined appearance of the sperm head. Microtubules become organized to form a curtain or manchette that associates with spermatids at specific steps of their development. It is involved in maintenance of the sperm head shape and trafficking of proteins in the spermatid cytoplasm. During spermiogenesis, many genes/proteins have been implicated in the diverse dynamic events occurring at this time of development of germ cells and the absence of some of these have been shown to result in subfertility or infertility.

Gonadotropin-regulated testicular RNA helicase (GRTH/DDX25): a multifunctional protein essential for spermatogenesis

Male germ cell maturation is governed by the expression of specific protein(s) in a precise temporal sequence during development. Gonadotropin-regulated testicular RNA helicase (GRTH/DDX25), a member of the Glu-Asp-Ala-Glu (DEAD)-box protein family, is a testis-specific gonadotropin/androgen-regulated RNA helicase that is present in germ cells (meiotic spermatocytes and round spermatids) and Leydig cells. GRTH is essential for completion of spermatogenesis as a posttranscriptional regulator of relevant genes during germ cell development. Male mice lacking GRTH are sterile with spermatogenic arrest due to failure of round spermatids to elongate, where striking structural changes and reduction in size of chromatoid bodies are observed. GRTH also plays a central role in preventing germ cell apoptosis. In addition to its inherent helicase unwinding/adenosine triphosphatase activities, GRTH binds to specific mRNAs as an integral component of ribonuclear protein particles. As a shuttle protein, GRTH transports target mRNAs from nucleus to the cytoplasm for storage in chromatoid bodies of spermatids, where they await translation during spermatogenesis. GRTH is also associated with polyribosomes to regulate target gene translation. The finding of a missense mutation associated with male infertility, where its expression associates with loss of GRTH phosphorylation, supports the relevance of GRTH to human germ cell development. We conclude that the mammalian GRTH/DDX25 is a multifunctional RNA helicase that is an essential regulator of spermatogenesis and is highly relevant for studies of male infertility and contraception.

The DEAD box protein Ddx42p modulates the function of ASPP2, a stimulator of apoptosis

Ddx42p is a recently characterized mammalian DEAD box protein with unknown cellular function. We found that in human cells Ddx42p physically interacts with ASPP2, a major apoptosis inducer known to enhance p53 transactivation of proapoptotic genes. The proteins interact via a domain within the carboxy-terminal part of Ddx42p and a mid-amino-terminal sequence as well as the ankyrin-SH3 region of ASPP2. Overexpression of Ddx42p interferes with apoptosis induction by ASPP2, whereas Ddx42p knockdown reduces the survival rate of cultured human cells. In addition, ASPP2 is found in cytoplasm and nucleus at low Ddx42p level, and predominantly in cytoplasm at high concentration of Ddx42p, respectively. Our results show that Ddx42p is capable of modulating ASPP2 function.