Genome-wide screening of severe male factor infertile patients using BAC-array comparative genomic hybridization (CGH)

Male factor infertility is present in up to 50% of infertile couples, making it increasingly important in their treatment. Although most research into the genetics of male infertility has focused on the Y chromosome, male factor infertility may result from other genetic factors. We utilized the whole genome array comparative genomic hybridization (CGH) to identify novel genetic candidate associated with severely impaired spermatogenesis. We enrolled 37 patients with severe male factor infertility, defined as severe nonobstructive type oligozoospermia (≤5×10(6)/ml) or azoospermia, and 10 controls. Routine cytogenetic analyses, Yq microdeletion PCR test and whole genome bacterial artificial chromosome (BAC)-array CGH were performed. Array CGH results showed no specific gains or losses related to impaired spermatogenesis other than Yq microdeletions, and there were no novel candidate genetic abnormalities in the patients with severe male infertility. However, Yq microdeletions were detected in 10 patients. Three showed a deletion in the AZFb-c region and the other 7 had deletions in the AZFc region. Although we could not identify novel genetic regions specifically associated with male infertility, whole genome array CGH analysis with higher resolution including larger numbers of patients may be able to give an opportunity for identifying new genetic markers for male infertility.     

精子DNA甲基化异常与男性不育

DNA甲基化／去甲基化是表观遗传学最重要的内容并可以控制基因的表达和印迹,越来越多的研究显示DNA甲基化异常与不育男性精子发生异常、特定肿瘤的发生、神经系统疾病、Rett综合征等有关。文章通过总结近来的相关研究资料来阐述精子发生过程中的DNA甲基化状态的改变,探讨精子DNA的甲基化异常与男性不育之间的联系,旨在为男性不育的治疗提供新的临床思路。     

Physical mapping of porcine seasonality genes

Seasonal infertility in sows is a problem in the pig industry characterized by delayed onset of puberty in summer and decreased farrowing rate resulting from silent oestrus and aborted pregnancy. Summer infertility is thought to be influenced by heat, sunburn and stress. However, the strongest contributory factor is photoperiod. The difference in seasonality between wild boar and commercial pig breeds suggests that there may be a genetic component to this trait. The maps and associated molecular tools emerging from the pig genome project have created opportunities to examine the genetic component of seasonal infertility. We are identifying and mapping genes that are likely to be involved in biological clock mechanisms and the melatonin pathways as candidate seasonality genes.     

Genetics of male infertility: the new players

Approximately 10-15% of couples experience infertility and male factors contribute to half of these cases. It was usually thought that infertility cannot be transmitted, but accumulating evidence indicates that many cases are indeed caused by genetic defects, some inherited. The use of single nucleotide polymorphisms (SNP) arrays allowing to genotype the totality of the genome recently led to identify several genes which, when mutated, generate specific infertility phenotypes. With the tremendous progresses in high throughput sequencing techniques, we can expect many more new genes involved in fertility to be identified in the next years. For the patients concerned, these findings mean the possibility of an accurate diagnosis and improved prognosis. Furthermore, these data will lead to a better understanding of the molecular mechanisms underlying spermatogenesis and thus should contribute to identify and offer new therapeutic strategies for the treatment of infertility.     

Single nucleotide polymorphisms in genes that are common targets of luteotropin and luteolysin in primate corpus luteum: Computational exploration

Luteal insufficiency affects fertility and hence study of mechanisms that regulate corpus luteum (CL) function is of prime importance to overcome infertility problems. Exploration of human genome sequence has helped to study the frequency of single nucleotide polymorphisms (SNPs). Clinical benefits of screening SNPs in infertility are being recognized well in recent times. Examining SNPs in genes associated with maintenance and regression of CL may help to understand unexplained luteal insufficiency and related infertility. Publicly available microarray gene expression databases reveal the global gene expression patterns in primate CL during the different functional state. We intend to explore computationally the deleterious SNPs of human genes reported to be common targets of luteolysin and luteotropin in primate CL. Different computational algorithms were used to dissect out the functional significance of SNPs in the luteinizing hormone sensitive genes. The results raise the possibility that screening for SNPs might be integrated to evaluate luteal insufficiency associated with human female infertility for future studies.     

Origins of chromosomal rearrangement hotspots in the human genome: evidence from the <Emphasis Type="Italic">AZFa</Emphasis>deletion hotspots

Background  

The origins of the recombination hotspots that are a common feature of both allelic and non-allelic homologous recombination in the human genome are poorly understood. We have investigated, by comparative sequencing, the evolution of two hotspots of non-allelic homologous recombination on the Y chromosome that lie within paralogous sequences known to sponsor deletions resulting in male infertility.     

The evolution of Mycoplasma genitalium

Mycoplasma genitalium is the smallest microorganism capable of self-replication. With its small genome, M. genitalium is the best representative of a minimal cell. The comparison of genome evolution among the three urogenital mycoplasmas, M. genitalium, M. hominis, and Ureaplasma parvum, not only indicated that they share a core genome of ~250 protein-encoding genes that correspond to their basic cell metabolism, but also showed a striking difference in their energy-generating pathways. M. genitalium is a sexually transmitted organism associated with nongonococcal urethritis in men and several inflammatory reproductive tract syndromes in women, such as cervicitis, pelvic inflammatory disease, and infertility. The treatment of M. genitalium infections has not yet been standardized. Macrolides are recommended, especially single-dose azithromycin; tetracyclines are responsible for a large number of therapeutic failures without any acquired resistance demonstrated. Acquired resistance to macrolides and fluoroquinolones leading to therapeutic failure has been described.     

Inhibitory phosphorylation of separase is essential for genome stability and viability of murine embryonic germ cells

Activity of separase, a cysteine protease that cleaves sister chromatid cohesin at the onset of anaphase, is tightly regulated to ensure faithful chromosome segregation and genome stability. Two mechanisms negatively regulate separase: inhibition by securin and phosphorylation on serine 1121. To gauge the physiological significance of the inhibitory phosphorylation, we created a mouse strain in which Ser1121 was mutated to Ala (S1121A). Here we report that this S1121A point mutation causes infertility in mice. We show that germ cells in the mutants are depleted during development. We further demonstrate that S1121A causes chromosome misalignment during proliferation of the postmigratory primordial germ cells, resulting in mitotic arrest, aneuploidy, and eventual cell death. Our results indicate that inhibitory phosphorylation of separase plays a critical role in the maintenance of sister chromatid cohesion and genome stability in proliferating postmigratory primordial germ cells.     

Expression of a novel HsMCAK mRNA splice variant,tsMCAK gene,in human testis

Identification of specifically expressed genes in the adult or fetal testis is very important for the study of genes related to the development and function of the testis. In this study, a human adult testis cDNA microarray was constructed and hybridized with 33P-labeled human adult and embryo testis cDNA probes, respectively. After differential display analyzing, a number of new genes related to the development of testis and spermatogenesis had been identified. One of these new genes is tsMCAK. tsMCAK was expressed 2.62 folds more in human adult testis than fetal testis. The full length of tsMCAK is 2401 bp and contains a 2013 bp open reading frame, encoding a 671-amino-acid protein. Sequence analysis showed that it has a central kinesin motor domain and is homologous to HsMCAK gene of the somatic cells. Blasting human genome database localized tsMCAK to human chromosome 1P34 and further investigation showed that it is a splice variant of HsMCAK. The tissue distribution of tsMCAK was determined by RT-PCR and it is expressed highly and specifically in the testis. Southern blot studies of its expression in patients with infertility indicated its specific expression in spermatogenic cells and its correlation with male infertility. The above results suggested that tsMCAK is a candidate gene for the testis-specific KRPs and its specific expression in the testis was correlated with spermatogenesis and may be correlated with male infertility.     

Recent knowledge concerning mammalian sperm chromatin organization and its potential weaknesses when facing oxidative challenge

Spermatozoa are the smallest and most cyto-differentiated mammalian cells. From a somatic cell-like appearance at the beginning of spermatogenesis, the male germ cell goes through a highly sophisticated process to reach its final organization entirely devoted to its mission which is to deliver the paternal genome to the oocyte. In order to fit the paternal DNA into the tiny spermatozoa head, complete chromatin remodeling is necessary. This review essentially focuses on present knowledge of this mammalian sperm nucleus compaction program. Particular attention is given to most recent advances that concern the specific organization of mammalian sperm chromatin and its potential weaknesses. Emphasis is placed on sperm DNA oxidative damage that may have dramatic consequences including infertility, abnormal embryonic development and the risk of transmission to descendants of an altered paternal genome.     

Somatic genome variations in health and disease

It is hard to imagine that all the cells of the human organism (about 10(14)) share identical genome. Moreover, the number of mitoses (about 10(16)) required for the organism's development and maturation during ontogeny suggests that at least a proportion of them could be abnormal leading, thereby, to large-scale genomic alterations in somatic cells. Experimental data do demonstrate such genomic variations to exist and to be involved in human development and interindividual genetic variability in health and disease. However, since current genomic technologies are mainly based on methods, which analyze genomes from a large pool of cells, intercellular or somatic genome variations are significantly less appreciated in modern bioscience. Here, a review of somatic genome variations occurring at all levels of genome organization (i.e. DNA sequence, subchromosomal and chromosomal) in health and disease is presented. Looking through the available literature, it was possible to show that the somatic cell genome is extremely variable. Additionally, being mainly associated with chromosome or genome instability (most commonly manifesting as aneuploidy), somatic genome variations are involved in pathogenesis of numerous human diseases. The latter mainly concerns diseases of the brain (i.e. autism, schizophrenia, Alzheimer's disease) and immune system (autoimmune diseases), chromosomal and some monogenic syndromes, cancers, infertility and prenatal mortality. Taking into account data on somatic genome variations and chromosome instability, it becomes possible to show that related processes can underlie non-malignant pathology such as (neuro)degeneration or other local tissue dysfunctions. Together, we suggest that detection and characterization of somatic genome behavior and variations can provide new opportunities for human genome research and genetics.     

New uses for new haplotypes the human Y chromosome, disease and selection

Recent discoveries of many new genes have made it clear that there is more to the human Y chromosome than a heap of evolutionary debris, hooked up to a sequence that happens to endow its bearer with testes. Coupled with the recent development of new polymorphic markers on the Y, making it the best-characterized haplotypic system in the genome, this gives us new opportunities to assess its role in disease and selection, through association studies with phenotypes such as infertility and cancers. However, the peculiar genetics of this bizarre chromosome means that we should interpret such studies particularly cautiously.     

La spermatide, cette méconnue

The use of microinsemination of round or elongated spermatids into ovocytes, in certain cases of male infertility, requires re-examination of the sequence of morphological and functional changes that occur throughout spermiogenesis. This paper reviews essential findings on morphogenesis of spermatids, genome expression during sperm differentiation and cellular interactions between spermatids themselves and between spermatids and Sertoli cells. Round and elongated spermatids appear to represent two classes of structuraly and functionnaly different cells. One question remains: on what criteria can one claim that a round spermatid functions normally when spermiogenesis is blocked or impaired?     

Transmission, inheritance and replication of mitochondrial DNA in mammals: implications for reproductive processes and infertility

The mitochondrial genome contributes key proteins to the electron-transfer chain, which through oxidative phosphorylation, generates the vast majority of cellular ATP. This maternally inherited genome is transmitted to subsequent generations through the oocyte. Its transmission, inheritance and replication are strictly regulated so that fully mature cells can be appropriately populated with mitochondrial DNA once they mature into adult cells. However, gametes do not always acquire the appropriate numbers of mitochondrial DNA copy; this often renders them inappropriate for successful fertilisation outcome. Furthermore, the number of assisted reproductive technologies that can overcome problems associated with infertility and that can provide enhanced genetic outcomes for the offspring is increasing. However, such techniques could also have a detrimental effect on offspring survival. If we are to introduce these technologies into in vitro fertilisation clinics and animal production, then we first need to validate their use carefully.     

Transposable element contributions to plant gene and genome evolution

Transposable elements were first discovered in plants because they can have tremendous effects on genome structure and gene function. Although only a few or no elements may be active within a genome at any time in any individual, the genomic alterations they cause can have major outcomes for a species. All major element types appear to be present in all plant species, but their quantitative and qualitative contributions are enormously variable even between closely related lineages. In some large-genome plants, mobile DNAs make up the majority of the nuclear genome. They can rearrange genomes and alter individual gene structure and regulation through any of the activities they promote: transposition, insertion, excision, chromosome breakage, and ectopic recombination. Many genes may have been assembled or amplified through the action of transposable elements, and it is likely that most plant genes contain legacies of multiple transposable element insertions into promoters. Because chromosomal rearrangements can lead to speciating infertility in heterozygous progeny, transposable elements may be responsible for the rate at which such incompatibility is generated in separated populations. For these reasons, understanding plant gene and genome evolution is only possible if we comprehend the contributions of transposable elements.     

Ontogenetic variation of the human genome

The human genome demonstrates variable levels of instability during ontogeny. Achieving the highest rate during early prenatal development, it decreases significantly throughout following ontogenetic stages. A failure to decrease or a spontaneous increase of genomic instability can promote infertility, pregnancy losses, chromosomal and genomic diseases, cancer, immunodeficiency, or brain diseases depending on developmental stage at which it occurs. Paradoxically, late ontogeny is associated with increase of genomic instability that is considered a probable mechanism for human aging. The latter is even more appreciable in human diseases associated with pathological or accelerated aging (i.e. Alzheimer's disease and ataxia-telangiectasia). These observations resulted in a hypothesis suggesting that somatic genomic variations throughout ontogeny are determinants of cellular vitality in health and disease including intrauterine development, postnatal life and aging. The most devastative effect of somatic genome variations is observed when it manifests as chromosome instability or aneuploidy, which has been repeatedly noted to produce pathologic conditions and to mediate developmental regulatory and aging processes. However, no commonly accepted concepts on the role of chromosome/genome instability in determination of human health span and life span are available. Here, a review of these ontogenetic variations is given to propose a new "dynamic genome" model for pathological and natural genomic changes throughout life that mimic those of phylogenetic diversity.     

Electroporated transgene-rescued spermatogenesis in infertile mutant mice with a sertoli cell defect

The molecular basis of most human male infertility arising from spermatogenesis disruption is poorly understood because of a lack of useful investigation systems. To study the roles of the supporting Sertoli cells in mammalian spermatogenesis, we improved an electroporation technique for seminiferous tubules in vivo. Because Sertoli cells barely proliferate in mature testis, linear transgenes are not incorporated into the genome and quickly degrade. However, circular expression vector is stably expressed in Sertoli cells for a long period. By electrotransformation of a complete cDNA, we rescued defective spermatogenesis in infertile Sl(17H)/Sl(17H) mutant mice with partial dysfunction of stem cell factor in Sertoli cells. Application of this gene transfer system will facilitate both the understanding of spermatogenesis and the development of new gene therapies for human male infertility.