Génétique de l’infertilité chez l’homme, nouvelles approches

15% of couples worldwide present with reproduction difficulties related to infertility. To date, very few genetic causes have been associated with male or female infertility. The identification of single-gene mutations causing male infertility is not a field of intense research at the present time, although they are probably responsible for a large number of so-called idiopathic cases of infertility. Murine models were created several years ago by gene knock-out by genetic recombination: more than 200 genes have been shown to be responsible for isolated syndromic infertility. This is the case for genes controlling meiosis. The course of meiosis and the genes associated with this process have been largely characterized in yeasts. Mammalian homologues were recently cloned and knocked out in mice, demonstrating their essential roles during meiosis and gametogenesis. The gonadal phenotype of these mutant animals is similar to that of certain patients with unexplained infertility. The search for possible mutations in meiosis genes, genes that have been highly preserved during evolution, is currently underway. These murine models are very useful to study and dissect the various steps of normal and pathological gametogenesis in mammals. This progress should lead, in the near future, to more precise diagnosis and therefore informed genetic counselling in these infertile couples.     

Towards an understanding of the genetics of human male infertility: lessons from flies

It has been argued that about 4–5% of male adults suffer from infertility due to a genetic causation. From studies in the fruitfly Drosophila, there is evidence that up to 1500 recessive genes contribute to male fertility in that species. Here we suggest that the control of human male fertility is of at least comparable genetic complexity. However, because of small family size, conventional positional cloning methods for identifying human genes will have little impact on the dissection of male infertility. A critical selection of well-defined infertility phenotypes in model organisms, combined with identification of the genes involved and their orthologues in man, might reveal the genes that contribute to human male infertility.     

Anomalies génétiques et infertilité masculine

Fifteen percent of couples are infertile and in about 50% of cases the cause is of male origin. The aetiology is still unknown in more than 90% of cases and there may be genetic or environmental causes. Three approaches are used to detect genetic causes for male infertility: 1) cytogenetics, resulting in particular from progress made in molecular cytogenetics and the direct analysis of gametes by in situ molecular hybridation techniques. When a chromosome anomaly, the most common cause of infertility, including deletion of the Y chromosome, is discovered, it is not easy to distinguish between gene anomalies resulting from change and mechanical anomalies that are an integral part of meiosis; 2) the analysis of candidate genes, which often uses data obtained from animal, usually murine, models. This approach, frequently described in the literature, tends to be lengthy, expensive and rarely results in the discovery of an abnormal gene, as is the case, for example, with meiotic genes; 3) Mendel’s approach is clearly the preferred choice, studying as it does cases of inherited infertility, which is much more widespread than we might think.     

21个野生,培育及地方猪种免疫及生化遗传标记基因位点的遗传分化研究

分析了亚,欧,美,非２１个野生,培育及地方猪种４个免疫遗传标记基因位点（Ｅ,Ｆ,Ｇ,Ｌ系统）和３人生化遗传标记基因位点（Ｃｐ,Ａｍ和Ｔｆ）的遗传多态性,认为Ｅ＾ａｅｇ,Ｆ＾ａ,Ｔｆ＾ｃ基因在亚洲猪种与欧美猪种间存在显著差异,是亚洲猪种３个重要的遗传标记基因,根据Ｆ＾ａ基因频率在亚,欧,美,非猪种的变化规律分析了其基因流向特点,证明欧美猪的育种过程中利用了中国地方猪种的血缘,计算了所测猪种间的Ｎｅｉ     

The molecular genetics of male infertility

Spermatogenesis is an elaborate process involving both cell division and differentiation, and cell-cell interactions. Defects in any of these processes can result in infertility, and in some cases these can be genetic in cause. Mapping experiments have defined at least three regions of the human Y chromosome that are required for normal spermatogenesis. Two of these contain the genes encoding the RNA binding proteins RBM and DAZ, suggesting that the control of RNA metabolism is likely to be an important control point for human spermatogenesis. A similar analysis in mice has shown that at least two regions of the mouse Y chromosome are essential for spermatogenesis. Both genetic and reverse genetic approaches have been used to identify mouse autosomal genes required for spermatogenesis. These studies have shown that genes in a number of different pathways are essential for normal spermatogenesis, and also provide putative models of human infertility.     

微卫星标记对高原蕨麻猪的遗传多样性研究

目的探讨蕨麻猪的亲缘关系,遗传多样性,是否受外来血缘的影响。方法用9个微卫星DNA标记对5群猪进行等位基因频率、遗传距离、系统发生树构建和主成分等分析。结果微卫星标记在125个个体中,共检测出148个等位基因,蕨麻猪最少(55个)。蕨麻猪与兰州猪的遗传距离DA和标准遗传距离DS最大,分别为0.6781和1.3312,DA、DS分别用UPGMA和NJ构建了四种系统发生树,都是蕨麻猪聚为一类,其余4种猪聚为一类。主成分1(PC1)为62.174%,看作是蕨麻猪的代表,与其他4群猪差异较大。结论蕨麻猪与兰州、武威、临洮和青海四群猪相比,遗传距离大,主成分差异大,亲缘关系较远,蕨麻猪比较纯,没有受到这4群猪血缘的影响。     

Candidate genes underlying heritable differences in reproductive seasonality between wild and domestic rabbits

Reproductive seasonality is a trait that often differs between domestic animals and their wild ancestors, with domestic animals showing prolonged or even continuous breeding seasons. However, the genetic basis underlying this trait is still poorly understood for most species, and because environmental factors and resource availability are known to play an important role in determining breeding seasons, it is also not clear in most cases to what extent this phenotypic shift is determined by the more lenient captive conditions or by genetic factors. Here, using animals resulting from an initial cross between wild and domestic rabbits followed by two consecutive backcrosses (BC1 and BC2) to wild rabbits, we evaluated the yearly distribution of births for the different generations. Similar to domestic rabbits, F1 animals could be bred all year round but BC1 and BC2 animals showed a progressive and significant reduction in the span of the breeding season, providing experimental evidence that reduced seasonal breeding in domestic rabbits has a clear genetic component and is not a simple by‐product of rearing conditions. We then took advantage of a recently published genome‐wide scan of selection in the domesticated lineage and searched for candidate genes potentially associated with this phenotypic shift. Candidate genes located within regions targeted by selection include well‐known examples of genes controlling clock functions (CRY1 and NR3C1) and reproduction (PRLR).     

Molecular cloning and expression of a new gene, GON-SJTU1 in the rat testis

Background  

Spermatogenesis is a complex process involving cell development, differentiation and apoptosis. This process is governed by a series of genes whose expressions are highly regulated. Male infertility can be attributed to multiple genetic defects or alterations that are related to spermatogenesis. The discovery, cloning and further functional study of genes related to spermatogenesis is of great importance to the elucidation of the molecular mechanism of spermatogenesis. It is also physiologically and pathologically significant to the therapy of male infertility.     

Porcine genomics delivers new tools and results: this little piggy did more than just go to market

The past decade has yielded new tools for pig geneticists and breeders thanks to the considerable developments resulting from efforts to map the pig genome. The pig genetic linkage map now has nearly 5000 loci including several hundred genes, microsatellites and amplified fragment length polymorphisms (AFLP) markers. Using tools that include somatic cell hybrid panels and radiation hybrid panels, the physical genetic map is also growing rapidly and has over 4000 genes and markers. Scientists using both exotic and commercial breeds for quantitative trait loci (QTL) scans and candidate gene analyses have identified a number of important chromosomal regions and individual genes associated with growth rate, leanness, feed intake, meat quality, litter size and disease resistance. Using marker-assisted selection (MAS) the commercial pig industry is actively incorporating these gene markers and traditional performance information to improve traits of economic importance in pig production. Researchers now have novel tools including pig gene arrays and advanced bioinformatics that are being exploited to find new candidate genes and to advance the understanding of gene function in the pig. Sequencing of the pig genome has been initiated and further sequencing is now being considered. Advances in pig genomics and directions for future research and the implications to both the pig industry and human health are reviewed.     

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.     

Genetic variation in two conserved local Romanian pig breeds using type 1 DNA markers

Analysis of the genetic variation of an endangered population is an important component for the success of conservation. Animals from two local Romanian pig breeds, the Mangalitsa and Bazna, were analysed for variation at a number of genetic loci using PCR-based DNA tests. Polymorphism was assessed at loci which 1) are known to cause phenotypic variation, 2) are potentially involved in trait differences or 3) are putative candidate genes. The traits considered are disease resistance, growth, coat colour, meat quality and prolificacy. Even though the populations are small and the markers are limited to specific genes, we found significant differences in five of the ten characterised loci. In some cases the observed allele frequencies were interesting in relation to gene function and the phenotype of the breed. These breeds are part of a conservation programme in Romania and marker information may be useful in preserving a representative gene pool in the populations. The use of polymorphisms in type 1 (gene) markers may be a useful complement to analysis based on anonymous markers.     

Assessment of genetic diversity of Korean native pig (Sus scrofa) using AFLP markers

In order to assess the genetic diversity and genetic relationships among the six commercial pig breeds including the Korean native pig, we performed an amplified fragment length polymorphism (AFLP) analysis. Applying the three EcoRI/TagI primer combinations to 54 individual pig samples out of six breeds, a total of 186 AFLP bands were generated, 67 (36%) of which were identified as polymorphic bands. From these polymorphic bands, the three estimates (percentage of polymorphic loci, Neis heterozygosity and Shannon index) of genetic diversity, G(ST) estimates, Neis unbiased genetic distance and two indices of genetic similarity were calculated. From all the calculations of genetic diversity, the lowest genetic diversity was exhibited in the Korean native pig, and the highest in the Chinese Yanbian pig. Given the mean G(ST) value (G(ST) = 0.390) across all pigs examined, levels of apparent breed subdivision were considerable. A UPGMA tree of individuals based on Jaccards similarity index showed that the Korean native pig formed a distinct cluster from the other five pigs. In addition, the tree displayed that all the individuals except for six individuals were grouped into their breeds. Principal component analysis based on the binary data matrix of either presence or absence confirmed the distinctness of the Korean native pig from the other pigs. Our results indicate that the Korean native pig has a low level of genetic diversity and is distinct from the five pig breeds, confirming the results from previous microsatellite data. The findings also suggest that AFLP analysis may be a valuable tool for revealing genetic relationships and genetic diversity among different pig breeds.     

Alterations in synaptonemal complex coding genes and human infertility

About 10% of reproductive-aged couples suffer from infertility. However, the genetic causes of human infertility cases are largely unknown. Meiosis produces haploid gametes for fertilization and errors in meiosis are associated with human infertility in both males and females. Successful meiosis relies on the assembly of the synaptonemal complex (SC) between paired homologous chromosomes during the meiotic prophase. The SC is ultrastructurally and functionally conserved, promoting inter-homologous recombination and crossover formation, thus critical for accurate meiotic chromosome segregation. With whole-genome/exome sequencing and mouse models, a list of mutations in SC coding genes has been linked to human infertility. Here we summarize those findings. We also analyzed SC gene variants present in the general population and presented complex interaction networks associated with SC components. Whether a combination of genetic variations and environmental factors causes human infertility demands further investigations.     

The role of oocyte in the genetic determinations of fertility and infertility

Oocyte specific genes play important role in the foliculogenesis, ovulation, fertilization and early embryogenesis. It is suggested that 17-20% of infertility in both sex has idiopathic aspect. This kind of infertility is mainly associated with genetic background. The study on the role of oocyte specific genes can help in our understanding of the causes of idiopathic infertility.     

Anomalies génétiques de la spermatogenèse

The important role of genetic abnormalities in the causation of human male infertility is increasingly recognized. Considerable progress has been achieved over the past years both in the clinical delineation of genetic forms of male infertility and in the characterization of the responsible genes and their mutations. We review the current state of knowledge on genetic disorders where male infertility is a major and regular feature.     

Detection of Y chromosome microdeletions and mitochondrial DNA mutations in male infertility patients

Infertility affects about 10-15% of all couples attempting pregnancy with infertility attributed to the male partner in approximately half of the cases. Proposed causes of male infertility include sperm motility disturbances, Y chromosome microdeletions, chromosomal abnormalities, single gene mutations, and sperm mitochondrial DNA (mtDNA) rearrangements. To investigate the etiology of decreased sperm fertility and motility of sperm and to develop an appropriate therapeutic strategy, the molecular basis of these defects must be elucidated. In this study, we aimed to reveal the relationships between the genetic factors including sperm mtDNA mutations, Y chromosome microdeletions, and sperm parameters that can be regarded as candidate factors for male infertility. Thirty men with a history of infertility and 30 fertile men were recruited to the study. Y chromosome microdeletions were analyzed by multiplex PCR. Mitochondrial genes ATPase6, Cytb, and ND1, were amplified by PCR and then analyzed by direct sequencing. No Y chromosome microdeletions were detected in either group. However, a total of 38 different nucleotide substitutions were identified in the examined mitochondrial genes in both groups, all of which are statistically non-significant. Fifteen substitutions caused an amino acid change and 12 were considered novel mutations. As a conclusion, mtDNA mutations and Y chromosome microdeletions in male infertility should be examined in larger numbers in order to clarify the effect of genetic factors.     

Routine diagnostic testing of Y chromosome deletions in male infertile and subfertile

Male factor infertility elucidated about half the couple of infertility and in around 50% of cases, its etiology remains unknown. The aim of this study was to investigate a predisposing genetic background for Yq deletions and male infertility and effectiveness of molecular genetic approaches have uncovered several etiopathogenetic factors, such as microdeletions of Yq chromosome. The Y chromosome microdeletions removing the azoospermia factor (AZF) regions, which are most common molecular genetic causes of oligospermia or azoospermia. However, with the analysis of Yq deletions, we are able to obtain a better understanding of the clinical significance of genetic anomaly and to the identifying of fertility candidate genes in the AZF regions. Molecular genetic approaches, becomes a routine diagnostic test, that provides an etiology for spermatogenic disturbances, and prognosis for testicular sperm retrieval according to the type of deletion.     

From a sow's ear to a silk purse: real progress in porcine genomics

An incredible amount of progress has occurred in the past decade since the pig genome map began to develop. The porcine genetic linkage map now has nearly 5,000 loci including several hundred genes, microsatellites and amplified fragment length polymorphism (AFLP) markers being added to the map. Thanks to somatic cell hybrid panels and then radiation hybrid panels the physical genetic map is also growing rapidly and now has over 4,000 genes and markers. Many quantitative trait loci (QTL) scans have been completed and together with candidate gene analyses have identified important chromosomal regions and individual genes associated with traits of economic interests. Using marker assisted selection (MAS) the commercial pig industry is actively using this information and traditional performance information to improve pig production. Large scale pig arrays are just now beginning to be used and co-expression of thousands of genes is now advancing our understanding of gene function. The pig's role in xenotransplantation and biomedical research makes the study of its genome important for the study of human disease. Sequencing of the pig genome appears on the near horizon. This commentary will discuss recent advances in pig genomics, directions for future research and the implications to both the pig industry and human health.     

Gene flow and simulation of transgene dispersal from hybrid poplar plantations

Gene flow is a primary determinant of potential ecological impacts of transgenic trees. However, gene flow is a complex process that must be assessed in the context of realistic genetic, management, and environmental conditions. We measured gene flow from hybrid poplar plantations using morphological and genetic markers, and developed a spatially explicit landscape model to simulate pollination, dispersal, establishment, and mortality in the context of historical and projected disturbance and land-use regimes. Most pollination and seed establishment occurred within 450 m of the source, with a very long tail. Modeled transgene flow was highly context-dependent, strongly influenced by the competitive effects of transgenes, transgenic fertility, plantation rotation length, disturbance regime, and spatial and temporal variation in selection. The use of linked infertility genes even if imperfect, substantially reduced transgene flow in a wide range of modeled scenarios. The significance of seed and vegetative dispersal was highly dependent on plantation size. Our empirical and modeling studies suggest that transgene spread can be spatially extensive. However, the amount of spread is highly dependent on ecological and management context, and can be greatly limited or prevented by management or mitigation genes such as those that cause sexual infertility.