Single‐nucleotide polymorphism c.474G>A in the SEPT12 gene is a predisposing factor in male infertility

SEPT12 is a testis‐specific gene involved in the terminal differentiation of male germ cells. SEPT12 protein is required for sperm head‐tail formation and acts as a fundamental constituent of sperm tail annulus. In this study, we screened genetic variations in exons 5, 6, 7 of the SEPT12 and assessed the annulus status in teratozoospermic, globozoospermic, and patients with immotile short tail sperm. DNA sequencing was performed for 90 teratozoospermic and 30 normozoospermic individuals. Immunocytochemistry, transmission electron microscopy and western blotting were conducted to evaluate annulus status and the expression level of SEPT12 in patients with a distinct exonic variation (c.474G>A), respectively. Five polymorphisms identified within the desired regions of the SEPT12, among them c.474G>A had the potential to induce aberrant splicing results in the expression of a truncated protein. The annulus was detected in most of the spermatozoa from teratozoospermic and normozoospermic men with c.474G>A. In contrast, in the patient with short tail sperm defect carrying c.474G>A, 99% of spermatozoa were devoid of the annulus. Based on our findings there would be no association between exons 5, 6, 7 polymorphisms of the SEPT12 gene and the occurrence of mentioned disease but c.474G>A would be a predisposing factor in male infertility.     

Initiation of sperm motility depending on a change in external osmotic pressure in the noncopulatory marine cottid fish Gymnocanthus herzensteini

 The initiation of sperm motility in a noncopulatory marine cottid fish, Gymnocanthus herzensteini, was examined. The spermatozoa, which were immotile in seminal plasma, initiated motility at osmolalities of more than 500 mOsm kg⁻¹ in NaCl solution and 400 mOsm kg⁻¹ in KCl and mannitol solutions, indicating that the initiation of sperm motility depends on changes in external osmolality, in contrast with that of the sperm of other marine cottid fish, which are motile in seminal plasma. This study revealed that there are plural manner of initiation of sperm motility in marine cottid fish, which are oviparous but include both copulatory and noncopulatory modes. Received: May 24, 2001 / Revised: December 19, 2001 / Accepted: January 8, 2002     

A novel protein,sperm head and tail associated protein (SHTAP), interacts with cysteine‐rich secretory protein 2 (CRISP2) during spermatogenesis in the mouse

Background information. CRISP2 (cysteine‐rich secretory protein 2) is a sperm acrosome and tail protein with the ability to regulate Ca²⁺ flow through ryanodine receptors. Based on these properties, CRISP2 has a potential role in fertilization through the regulation of ion signalling in the acrosome reaction and sperm motility. The purpose of the present study was to determine the expression, subcellular localization and the role in spermatogenesis of a novel CRISP2‐binding partner, which we have designated SHTAP (sperm head and tail associated protein). Results. Using yeast two‐hybrid screens of an adult testis expression library, we identified SHTAP as a novel mouse CRISP2‐binding partner. Sequence analysis of all Shtap cDNA clones revealed that the mouse Shtap gene is embedded within a gene encoding the unrelated protein NSUN4 (NOL1/NOP2/Sun domain family member 4). Five orthologues of the Shtap gene have been annotated in public databases. SHTAP and its orthologues showed no significant sequence similarity to any known protein or functional motifs, including NSUN4. Using an SHTAP antiserum, multiple SHTAP isoforms (～20–87 kDa) were detected in the testis, sperm, and various somatic tissues. Interestingly, only the ～26 kDa isoform of SHTAP was able to interact with CRISP2. Furthermore, yeast two‐hybrid assays showed that both the CAP (CRISP/antigen 5/pathogenesis related‐1) and CRISP domains of CRISP2 were required for maximal binding to SHTAP. SHTAP protein was localized to the peri‐acrosomal region of round spermatids, and the head and tail of the elongated spermatids and sperm tail where it co‐localized with CRISP2. During sperm capacitation, SHTAP and the SHTAP—CRISP2 complex appeared to be redistributed within the head. Conclusions. The present study is the first report of the identification, annotation and expression analysis of the mouse Shtap gene. The redistribution observed during sperm capacitation raises the possibility that SHTAP and the SHTAP—CRISP2 complex play a role in the attainment of sperm functional competence.     

Scanning electron microscopic investigation of the spermatophore and spermatozoa of the shrimp Farfantepenaeus subtilis (Decapoda: Penaeidae)

Scanning electron microscopy was used to describe the structure of the spermatozoon and spermatophore of Farfantepenaeus subtilis. The spermatophore showed characteristics similar to those of members of the subgenus Farfantepenaeus. This included an extensive glandular epithelium and a lack of a wing. The sperm mass, which was distributed at the periphery of the spermatophore, was surrounded by a large amount of acellular material. The spermatozoon has a spherical main body and a well-defined acrosomal region with a single spike, which was bent in some cells. The immotile sperm cells have an average length of 7.1?±?0.6?μm. Information on sperm location within the spermatophore will assist in the efficient extraction of the sperm mass during dissection.     

SPERM PRODUCTION AND STERILITY IN HYBRIDS BETWEEN TWO SUBSPECIES OF DROSOPHILA PSEUDOOBSCURA

Subspecies of Drosophila pseudoobscura, one occurring in the United States and the other in Bogota, Columbia, exhibit Haldane's Rule in one direction of the cross. Additionally, D. pseudoobscura produces two sperm types: short, sterile sperm and long, fertile, sperm. Here I examine the relationship between the production of short and long sperm and hybrid sterility. Fertile and sterile hybrid males produce a greater proportion of short sperm compared to parental males with sterile hybrids producing mainly short, immotile sperm. Sperm transfer and storage patterns were similar between fertile hybrid and parental strains; and unexpectedly, short, immotile sperm from sterile hybrids were stored. These findings raise the question of whether different genetic mechanisms disrupt both sperm heteromorphic production and sperm motility and whether this indicates that females exert some control over sperm storage.     

Hypo-osmotic swelling can accurately assess the viability of nonmotile sperm

Viable, healthy sperm are preferred for oocyte fertilization with intracytoplasmic sperm injection. Currently, motility is the most widely applied measure of sperm viability. However, with this criterion, viable but immotile sperm are overlooked as candidates for micromanipulation. Supravital stains identify viable sperm but may be toxic to the gamete or embryo. We tested the hypothesis that hypo-osmotic swelling, developed to assess sperm membrane integrity, can accurately determine sperm viability. Thawed sperm from 12 fertile donors were exposed to a hypo-osmotic solution and to two supravital stains. A total of 2,010 sperm were assessed for tail coiling after a 30-min exposure to hypo-osmotic solution. By supravital stains, 31% of thawed sperm were viable; 23% showed tail coiling. Among coiled-tail sperm, 100% were viable by supravital stain. As a measure of viability, tail coiling exhibited a sensitivity of 30%, specificity of 100%, and positive predictive value of 100% compared to supravital stains. With a 60-min hypo-osmotic incubation, the specificity (89%) and positive predictive value (78%) decreased significantly (P < 0.05). Therefore, hypo-osmotic swelling accurately detects viable sperm among a nonmotile population. Assay accuracy, however, is very sensitive to the incubation time in hypo-osmotic solution. Mol. Reprod. Dev. 47:200–203, 1997. © 1997 Wiley-Liss, Inc.     

Sequence,expression, and chromosomal assignment of a human sperm outer dense fiber gene

Outer dense fibers (ODFs) are located on the outside of the axoneme in the midpiece and principal piece of the mammalian sperm tail and may help to maintain the passive elastic structures and elastic recoil of the sperm tail. We have identified and describe here a human gene that is homologous to the Mst(3)CGP gene family of Drosophila melanogaster and encodes an ODF protein of 241 amino acids. The transcribed region has a size of ?lkb and contains two exons of 416 bp and 406 bp, respectively, not including the 3′ untranslated region. The gene is expressed in testis but not in human spleen, kidney, or brain and resembles in this respect the expression of the Drosophila Mst(3)CGP gene family in the male germline. An antiserum raised against a synthetic peptide derived from the N-terminus of the encoded sequence identified a protein of ? 32 kDa in an extract of human sperm flagella. By Southern-blot analyses and in situ hybridization, the ODF gene was localized to band q22 of chromosome 8. The isolation of a human gene encoding a sperm tail protein may provide the ability to identify and investigate, on the molecular level, possible reasons for human male infertility that are dependent on flagellar disturbances. © 1993 Wiley-Liss, Inc.     

Mapping and cloning recombinant breakpoints demarcating the Hybrid Sterility 6-specific sperm tail assembly defect

Variants of the mouse t complex known as t haplotypes (t) express factors that perturb sperm differentiation, resulting in the non-Mendelian transmission of t from +/t heterozygous males and the sterility of t/t homozygous males. Previous studies of mice carrying heterospecific combinations of the t complex have revealed a 1-cM candidate locus, Hst6, for the distal-most of these factors, Tcd/Tcs2. Males heterozygous for the M. spretus allele of Hst6 and a t haplotype (Hst6 ^s /t) are sterile, expressing an abnormality in sperm flagellar curvature (``curlicue') indistinguishable from one exhibited by sperm from t/t homozygotes. Hst6 <sup>s</sup> /Hst6 <sup>s</sup> males are also sterile; however, sperm produced by these males are completely immotile owing to the absence of assembled flagella. Recent studies have shown that the complete presentation of ``curlicue' derives from expression of at least two factors within the locus, Curlicue a (Ccua) proximally and Curlicue b (Ccub) distally, with a factor affecting sperm-oolemma penetration, Stop1p, mapping between them. In the present report, we have examined expression of the Hst6-specific flagellar assembly phenotype in sperm from mice homozygous for M. spretus–M. m. domesticus recombinant Chr 17 homologs whose breakpoints map within the Hst6 locus. SSLP analysis of these homologs has demonstrated that the flagellar assembly defect maps to less than 0.2 cM between D17Mit61 and D17Mit135, coincident with Ccua. SSR content analysis of 23 BACs mapping to four contigs within the Hst6 locus has resulted in isolation of proximal and distal recombinant breakpoints circumscribing the flagellar assembly phenotype/Ccua factor. In addition, we have provided increased high-resolution mapping of the Stop1p and Ccub factors. These new data enhance our ability to isolate and characterize candidates for Tcd/Tcs2. Received: 12 August 1998 / Accepted: 1 October 1998     

Sperm incorporation,the pronuclear migrations,and their relation to the establishment of the first embryonic axis: Time-lapse video microscopy of the movements during fertilization of the sea urchin Lytechinus variegatus

The movements during fertilization have been investigated with differential interference optics and recorded by time-lapse video microscopy of the clear egg of the sea urchin Lytechinus variegatus. Sperm-egg binding occurs rapidly, and following a time when the sperm gyrates on the egg surface, gamete fusion occurs. A rapid cortical contraction radiates from the fusion site and is succeeded by the elevation of the fertilization coat. Sperm incorporation occurs in two stages: the fertilization cone enlarges around and above the erect and immotile sperm and then the sperm head, midpiece, and tail are displaced along the subsurface region of the egg at an average rate of 3.5 μm/min. The formation of the sperm aster moves the male pronucleus from the subsurface region of the egg toward the egg center at a rate of 4.9 μm/min. When the rays of the radial sperm aster appear to contact the female pronucleus, the female pronucleus migrates at a rate of 14.6 μm/min to the center of the sperm aster. The now adjacent pronuclei are moved to the egg center by the continuing enlargement of the sperm aster at a rate of 2.6 μm/min. Syngamy is usually preceded by the disassembly of the sperm aster. The centripetal migration of the pronuclei appears involved in the establishment of the first embryonic axis; cleavage occurs within 8° of the direction of this centering motion.     

Deploying QTL-seq for rapid delineation of a potential candidate gene underlying major trait-associated QTL in chickpea

A rapid high-resolution genome-wide strategy for molecular mapping of major QTL(s)/gene(s) regulating important agronomic traits is vital for in-depth dissection of complex quantitative traits and genetic enhancement in chickpea. The present study for the first time employed a NGS-based whole-genome QTL-seq strategy to identify one major genomic region harbouring a robust 100-seed weight QTL using an intra-specific 221 chickpea mapping population (desi cv. ICC 7184 × desi cv. ICC 15061). The QTL-seq-derived major SW QTL (CaqSW1.1) was further validated by single-nucleotide polymorphism (SNP) and simple sequence repeat (SSR) marker-based traditional QTL mapping (47.6% R² at higher LOD >19). This reflects the reliability and efficacy of QTL-seq as a strategy for rapid genome-wide scanning and fine mapping of major trait regulatory QTLs in chickpea. The use of QTL-seq and classical QTL mapping in combination narrowed down the 1.37 Mb (comprising 177 genes) major SW QTL (CaqSW1.1) region into a 35 kb genomic interval on desi chickpea chromosome 1 containing six genes. One coding SNP (G/A)-carrying constitutive photomorphogenic9 (COP9) signalosome complex subunit 8 (CSN8) gene of these exhibited seed-specific expression, including pronounced differential up-/down-regulation in low and high seed weight mapping parents and homozygous individuals during seed development. The coding SNP mined in this potential seed weight-governing candidate CSN8 gene was found to be present exclusively in all cultivated species/genotypes, but not in any wild species/genotypes of primary, secondary and tertiary gene pools. This indicates the effect of strong artificial and/or natural selection pressure on target SW locus during chickpea domestication. The proposed QTL-seq-driven integrated genome-wide strategy has potential to delineate major candidate gene(s) harbouring a robust trait regulatory QTL rapidly with optimal use of resources. This will further assist us to extrapolate the molecular mechanism underlying complex quantitative traits at a genome-wide scale leading to fast-paced marker-assisted genetic improvement in diverse crop plants, including chickpea.     

Estimation of spawning sites in the spotted flagtail, Kuhlia marginata, based on sperm motility

To estimate the spawning site of the spotted flagtail, Kuhlia marginata, sperm motility was examined under conditions of different salinities. The spermatozoa were immotile in 0 and 5 ppt test solutions and in seminal fluid but lived longer in 20–30 ppt. Sperm were most active at 25–35 ppt. Therefore, we considered that spotted flagtail spawn in 20–35 ppt salinity. Because the mean salinity of the Genka estuary is below the optimum required for spawning, the spawning site in Okinawa Island would be seawater. This evidence suggested that the spotted flagtail is a catadromous species. Received: January 26, 2001 / Revised: July 6, 2001 / Accepted: July 24, 2001     

Linkage disequilibrium mapping in the Newfoundland population: a re-evaluation of the refinement of the Bardet–Biedl syndrome 1 critical interval

Genetically isolated populations, such as Newfoundland, have contributed greatly to the identification of disease-causing genes. A linkage disequilibrium (LD) study involving six Newfoundland families predicted a critical interval for Bardet-Biedl syndrome 1 (BBS1) (Young et al. in Am J Hum Genet 65:1680–1687, 1999), but the subsequent identification of BBS1 revealed that it lies outside this region. This suggested that either there is another gene responsible for BBS in these families or the Newfoundland population may not be ideal for LD studies. We screened these six Newfoundland families for mutations in BBS1 and found that affected individuals in five of them were homozygous for the same M390R mutation. There was no evidence for any BBS1 mutation in the affected individual in the sixth family. Therefore, one of the criteria for LD mapping was not met; namely, there should be a single disease-causing allele in the population. Haplotype analysis of unaffected individuals from south-west Newfoundland and English BBS1 patients homozygous for M390R, revealed that a second criterion for LD mapping was violated. The M390R mutation occurred in a common haplotype and both of these chromosomes, the ancestral wild-type and disease-causing haplotypes, were introduced to Newfoundland and spread by a founder effect. Moreover, it was found that disease-associated alleles occurred at relatively high frequencies in normal haplotypes and this probably accounted for the incorrect prediction in the previous LD study. Knowing the amount of genetic variation and its distribution in the Newfoundland population would be useful to maximize its potential for mapping hereditary disorders.     

A novel genetic locus for familial febrile seizures and epilepsy on chromosome 3q26.2–q26.33

Febrile seizures (FS) are common in children, and the incidence is 2–5% before the age of 5 years. A four-generation Chinese family with autosomal dominant febrile seizure and epilepsy was studied by genome-wide linkage analysis. Significant linkage was identified with markers on chromosome 3q26.2–26.33 with a maximum pairwise LOD score of >3.00. Fine mapping defined the new genetic locus within a 10.7-Mb region between markers D3S3656 and D3S1232. A maximum multipoint LOD score of 5.27 was detected at marker D3S1565. A previously reported CLCN2 gene for epilepsy was excluded as the disease-causing gene in the family by mutational analysis of all exons and exon–intron boundaries of CLCN2 and by haplotype analysis. Mutation analysis of KCNMB2 and KCNMB3, which were two potassium-channel genes in this linkage region, did not reveal a disease causing mutation. Our results identified another novel locus on chromosome 3q26.2–26.33, and future studies of the candidate genes at the locus will identify a new gene for combined FS and idiopathic epilepsies. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. X.-H. Dai, W.-W. Chen, and X. Wang contributed equally to this work.     

Mapping of bovine FcγR (FCGR) genes by sperm typing allows extended use of human map information

Polymorphic sites within the bovine FcγRI (FCGR1), FcγRII (FCGR2), and FcγRIII (FCGR3) genes were used for proximal mapping of these genes to bovine Chromosome (Chr) 3 (BTA3) with paternal half-sib families from Norwegian Cattle. A fine-structure genetic map of the region was obtained by the analysis of 288 sperm cells from three bulls that were heterozygous for the loci included in the study. No recombinants were observed between FCGR2 and FCGR3 (242 sperm cells). Considering FCGR2 and FCGR3 as a single locus, a three-point linkage analysis for [FCGR2/FCGR3], FCGR1, and INRA003 was carried out. The best-supported order of the loci was found to be INRA003–FCGR1–[FCGR2/FCGR3]. Map distances in a two-point linkage analysis were 10.3 cM between [FCGR2/FCGR3] and FCGR1, and 25.5 cM between FCGR1 and INRA003, respectively. This linkage mapping of the bovine FCGR gene family resembles the human situation where all FCGR genes are located at Chr 1 (HSA1), at position q21-q24. Moreover, the results locate the evolutionary breakpoint between HSA1q and BTA3 within the human 1q24 region. Received: 27 January 1997 / Accepted: 1 April 1997     

The Mouse Spam1 maps to proximal Chromosome 6 and is a candidate for the sperm dysfunction in Rb(6.16)24Lub and Rb(6.15)lAld heterozygotes

We have determined the chromosomal localization of the murine gene encoding the 68-kDa sperm adhesion molecule 1, Spam1 or Ph-20. Using two independent approaches, fluorescence in situ hybridization (FISH) and interspecific backcross analysis, we show that Spam1 maps to proximal mouse Chromosome (Chr) 6. This map position is within the conserved linkage group corresponding to human Chr 7q, where the human homolog, SPAM 1, has been shown to map previously. Genetic mapping shows the gene to be very closely linked to Met, one of the most proximal loci on MMU 6. It thus places the gene near the centromere and the junction of the Rb(6.16)24Lub and Rb(6.15)1Ald translocations. The essential role of the Spam1 sperm antigen in mouse sperm-egg interactions and its gene location provide strong support for its candidacy as the gene involved in the dysfunction of mouse sperm bearing the Rb(6.16)24Lub or Rb(6.15)1Ald translocation. Received: 16 July 1996 / Accepted: 23 September 1996     

Matching population diversity of rhizobial nodA and legume NFR5 genes in plant–microbe symbiosis

We hypothesized that population diversities of partners in nitrogen‐fixing rhizobium–legume symbiosis can be matched for “interplaying” genes. We tested this hypothesis using data on nucleotide polymorphism of symbiotic genes encoding two components of the plant–bacteria signaling system: (a) the rhizobial nodA acyltransferase involved in the fatty acid tail decoration of the Nod factor (signaling molecule); (b) the plant NFR5 receptor required for Nod factor binding. We collected three wild‐growing legume species together with soil samples adjacent to the roots from one large 25‐year fallow: Vicia sativa, Lathyrus pratensis, and Trifolium hybridum nodulated by one of the two Rhizobium leguminosarum biovars (viciae and trifolii). For each plant species, we prepared three pools for DNA extraction and further sequencing: the plant pool (30 plant indiv.), the nodule pool (90 nodules), and the soil pool (30 samples). We observed the following statistically significant conclusions: (a) a monotonic relationship between the diversity in the plant NFR5 gene pools and the nodule rhizobial nodA gene pools; (b) higher topological similarity of the NFR5 gene tree with the nodA gene tree of the nodule pool, than with the nodA gene tree of the soil pool. Both nonsynonymous diversity and Tajima's D were increased in the nodule pools compared with the soil pools, consistent with relaxation of negative selection and/or admixture of balancing selection. We propose that the observed genetic concordance between NFR5 gene pools and nodule nodA gene pools arises from the selection of particular genotypes of the nodA gene by the host plant.     

Ultrastructure of the sperm and spermatogenesis and spermiogenesis of Dina lineata (hirudinea,erpobdellidae)

The mature sperm of Dina lineata is of the modified type. The sperm are 48 μm long and 0.3 μm wide. The sperm are filiform and helicoidal cells with a distinct head, a midpiece, and a tail. There are two distinct regions in the head: the acrosome and the posterior acrosome, each with its own characteristic morphology. The midpiece is the mitochondrial region and has a single mitochondrion. Two distinct portions can be observed in the tail: the axonematic region and the terminal piece. In the process of spermatogenesis the early spermatogonia divide to form a poliplast of 512 spermatic cells. In the spermiogenesis the following sequential stages can be distinguished: elongation of the flagellum; reciprocal migration of mitochondria and Golgi complex; condensation of chromatin and formation of the posterior acrosome; spiralization of nuclear and mitochondrial regions; and, finally, formation of the anterior acrosome. The extreme morphological complexity of the Dina spermatozoon is related to the peculiar hypodermal fertilization which characterizes the erpobdellid family. Correlation between sperm morphology and fertilization biology in the Annelida is revised.