伊藤 千鶴

<title>Abstract</title> The acrosome reaction is a multi-step event essential for physiological fertilization. During the acrosome reaction, gamete fusion-related factor IZUMO1 translocates from the anterior acrosome to the equatorial segment and assembles the gamete fusion machinery. The morphological changes in the acrosome reaction process have been well studied, but little is known about the molecular mechanisms of acrosome reorganization essential for physiological gamete membrane fusion. To elucidate the molecular mechanisms of IZUMO1 translocation, the steps of the acrosome reaction during that process must be clarified. In this study, we established a method to detect the early steps of the acrosome reaction and subdivided the process into seven populations through the use of two epitope-defined antibodies, anti-IZUMO1 and anti-SPACA1, a fertilization-inhibiting antibody. We found that part of the SPACA1 C-terminus in the periacrosomal space was cleaved and had begun to disappear when the vesiculation of the anterior acrosome occurred. The IZUMO1 epitope externalized from the acrosomal lumen before acrosomal vesiculation and phosphorylation of IZUMO1 occurred during the translocation to the equatorial segment. IZUMO1 circumvented the area of the equatorial segment where the SPACA1C-terminus was still localized. We therefore propose an IZUMO1 translocation model and involvement of SPACA1.

<title>Abstract</title> Spermatogenesis is a reproductive system process that produces sperm. Ubiquitin specific peptidase 26 (USP26) is an X chromosome-linked deubiquitinase that is specifically expressed in the testes. It has long been controversial whether <italic>USP26</italic> variants are associated with human male infertility. Thus, in the present study, we introduced a mutation into the <italic>Usp26</italic> gene in mice and found that <italic>Usp26</italic> mutant males backcrossed to a DBA/2 background, but not a C57BL/6 background, were sterile or subfertile and had atrophic testes. These findings indicate that the effects of the <italic>Usp26</italic> mutation on male reproductive capacity were influenced by genetic background. Sperm in the cauda epididymis of <italic>Usp26</italic> mutant mice backcrossed to a DBA/2 background were decreased in number and showed a malformed head morphology compared to those of wild-type mice. Additionally, histological examinations of the testes revealed that the number of round and elongated spermatids were dramatically reduced in <italic>Usp26</italic> mutant mice. The mutant mice exhibited unsynapsed chromosomes in pachynema and defective chiasma formation in diplonema, which presumably resulted in apoptosis of metaphase spermatocytes and subsequent decrease of spermatids. Taken together, these results indicate that the deficiencies in fertility and spermatogenesis caused by mutation of <italic>Usp26</italic> were dependent on genetic background.

Outer dense fibre 2 (Odf2 or ODF2) is a cytoskeletal protein required for flagella (tail)-beating and stability to transport sperm cells from testes to the eggs. There are infertile males, including human patients, who have a high percentage of decapitated and decaudated spermatozoa (DDS), whose semen contains abnormal spermatozoa with tailless heads and headless tails due to head-neck separation. DDS is untreatable in reproductive medicine. We report for the first time a new type of Odf2-DDS in heterozygous mutant Odf2+/- mice. Odf2+/- males were infertile due to haploinsufficiency caused by heterozygous deletion of the Odf2 gene, encoding the Odf2 proteins. Odf2 haploinsufficiency induced sperm neck-midpiece separation, a new type of head-tail separation, leading to the generation of headneck sperm cells or headnecks composed of heads with necks and neckless tails composed of only the main parts of tails. The headnecks were immotile but alive and capable of producing offspring by intracytoplasmic headneck sperm injection (ICSI). The neckless tails were motile and could induce capacitation but had no significant forward motility. Further studies are necessary to show that ICSI in humans, using headneck sperm cells, is viable and could be an alternative for infertile patients suffering from Odf2-DDS.

Lysyl hydroxylase 2 (LH2) is an endoplasmic reticulum (ER)-resident enzyme that catalyzes the hydroxylation of lysine residues in the telopeptides of fibrillar collagens. This is a critical modification to determine the fate of collagen cross-linking pathway that contributes to the stability of collagen fibrils. Studies have demonstrated that the aberrant LH2 function causes various diseases including osteogenesis imperfecta, fibrosis, and cancer metastasis. However, surprisingly, a LH2-deficient animal model has not been reported. In the current study, to better understand the function of LH2, we generated LH2 gene knockout mice by CRISPR/Cas9 technology. LH2 deficiency was confirmed by genotyping polymerase chain reaction (PCR), reverse transcriptase-PCR, and immunohistochemical analyses. Homozygous LH2 knockout (LH2-/-) embryos failed to develop normally and died at early embryonic stage E10.5 with abnormal common ventricle in a heart, i.e., an insufficient wall, a thin ventricular wall, and loosely packed cells. In the LH2-/- mice, the ER stress-responsive genes, ATF4 and CHOP were significantly up-regulated leading to increased levels of Bax and cleaved caspase-3. These data indicate that LH2 plays an essential role in cardiac development through an ER stress-mediated apoptosis pathway.

The posttranslational modification of histones is crucial in spermatogenesis, as in other tissues; however, during spermiogenesis, histones are replaced with protamines, which are critical for the tight packaging of the DNA in sperm cells. Protamines are also posttranslationally modified by phosphorylation and dephosphorylation, which prompted our investigation of the underlying mechanisms and biological consequences of their regulation. On the basis of a screen that implicated the heat shock protein Hspa4l in spermatogenesis, we generated mice deficient in Hspa4l (<italic>Hspa4l</italic>-null mice), which showed male infertility and the malformation of sperm heads. These phenotypes are similar to those of <italic>Ppp1cc</italic>-deficient mice, and we found that the amount of a testis- and sperm-specific isoform of the Ppp1cc phosphatase (Ppp1cc2) in the chromatin-binding fraction was substantially less in <italic>Hspa4l</italic>-null spermatozoa than that in those of wild-type mice. We further showed that Ppp1cc2 was a substrate of the chaperones Hsc70 and Hsp70 and that Hspa4l enhanced the release of Ppp1cc2 from these complexes, enabling the freed Ppp1cc2 to localize to chromatin. Pull-down and in vitro phosphatase assays suggested the dephosphorylation of protamine 2 at serine 56 (Prm2 Ser⁵⁶) by Ppp1cc2. To confirm the biological importance of Prm2 Ser⁵⁶ dephosphorylation, we mutated Ser⁵⁶ to alanine in Prm2 (Prm2 S56A). Introduction of this mutation to <italic>Hspa4l</italic>-null mice (<italic>Hspa4l</italic>^−/−; <italic>Prm2</italic>^S56A/S56A) restored the malformation of sperm heads and the infertility of <italic>Hspa4l</italic>^−/− mice. The dephosphorylation signal to eliminate phosphate was crucial, and these results unveiled the mechanism and biological relevance of the dephosphorylation of Prm2 for sperm maturation in vivo.

A number of sperm proteins are involved in the processes from gamete adhesion to fusion, but the underlying mechanism is still unclear. Here, we established a mouse mutant, the EQUATORIN-knockout (EQTN-KO,<italic> Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic>) mouse model and found that the EQTN-KO males have reduced fertility and sperm–egg adhesion, while the EQTN-KO females are fertile. <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic> sperm were normal in morphology and motility. <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic> <italic>-</italic>Tg (<italic>Acr-Egfp</italic>) sperm, which were produced as the acrosome reporter by crossing <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic> with <italic>Eqtn</italic> <italic> ^+/+ </italic>-Tg(<italic>Acr-Egfp</italic>) mice, traveled to the oviduct ampulla and penetrated the egg zona pellucida of WT females. However, <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic> males mated with WT females showed significant reduction in both fertility and the number of sperm attached to the zona-free oocyte. Sperm IZUMO1 and egg CD9 behaved normally in <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic> sperm when they were fertilized with WT egg. Another acrosomal protein, SPESP1, behaved aberrantly in <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic> sperm during the acrosome reaction. The fertility impairment of EQTN/SPESP1-double KO males lacking <italic>Eqtn</italic> and <italic>Spesp1</italic> (<italic>Eqtn</italic>/<italic>Spesp1</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic>) was more severe compared with that of <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic> males. <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic>-Tg (<italic>Eqtn</italic>) males, which were generated to rescue <italic>Eqtn</italic> <italic> ⁻ </italic> <italic> ^/ </italic> <italic> ⁻ </italic>males, restored the reduced fertility.

Autophagy plays an important role in cell survival, sequestering, and degrading a wide variety of substrates. Although an increase of autophagosomes in liver has been reported in sepsis patients as well as in septic mice, the influence of autophagy on liver injury, the interaction between autophagy, and other types of cell death in sepsis remain unclear. The aim of this study was to elucidate the contribution of liver autophagy to the pathophysiology of sepsis. We performed a cecal ligation and puncture on liver-specific autophagy-deficient (Alb-Cre/Atg5) mice (6-8-week-old male). When compared with controls (C57BL/6), we found a significant accumulation of p62 in the liver and demonstrated a greater number of cleaved caspase-3 immunoreactive hepatocytes in these knockout (KO) mice. Additionally, we confirmed a significant increase in autophagic vacuoles in the control mice relative to KO mice; in contrast, cell shrinkage and nuclear fragmentation (morphological characteristics of apoptosis) were preferentially seen in the KO mice by transmission electron microscopy. Severe mitochondrial damage was also prominent in KO mice, relative to controls, associated with an increase of reactive oxygen species in hepatocytes. Serum aspartate transaminase levels (P = 0.005) and serum interleukin-6 levels (P = 0.020) were significantly increased in the KO mice compared with controls. Deficiency of autophagy in liver significantly decreased survival in the murine sepsis model (P = 0.025). In conclusion, blocking liver autophagy accelerates time to mortality in the murine sepsis model, suggesting that liver autophagy plays a protective role for organ failure through degradation of damaged mitochondria, as well as prevention of apoptosis.

Objective: While type 1 programmed cell death (apoptosis) of T cells leads to immunosuppression in sepsis, a crosstalk between apoptosis and autophagy (type 2 programmed cell death) has not been shown. The aim of this study is to elucidate the details of the interaction between autophagy and immunosuppression. Design: Laboratory investigation in the murine sepsis model. Setting: University laboratory. Subjects: Six- to 8-week-old male mice. Interventions: We investigated the kinetics of autophagy in T cells from spleen in a cecal ligation and puncture model with green fluorescent protein-microtubule-associated protein light chain 3 transgenic mice. We analyzed apoptosis, mitochondrial homeostasis and cytokine production in T cells, and survival rate after cecal ligation and puncture using T cell-specific autophagy-deficient mice. Measurements and Main Results: We observed an increase of autophagosomes, which was assessed by flow cytometry. However, an autophagy process in CD4 + T cells during sepsis was insufficient including the accumulation of p62. On the other hand, a blockade of autophagy accelerated T cell apoptosis compared with the control mice, augmenting the gene expression of Bcl-2-like 11 and programmed cell death 1. Furthermore, mitochondrial accumulation in T cells occurred via a blockade of autophagy during sepsis. In addition, interleukin-10 production in CD4 + T cells from the cecal ligation and puncture-operated knockout mice was markedly increased. Consequently, deficiency of autophagy in T cells significantly decreased the survival rate in the murine sepsis model. Conclusions: We demonstrated that blocking autophagy accelerated apoptosis and increased mortality in concordance with the insufficient autophagy process in CD4 + T cells in the murine sepsis model, suggesting that T cell autophagy plays a protective role against apoptosis and immunosuppression in sepsis.

Spermatids must precisely integrate specific molecules into structurally supported domains that develop during spermatogenesis. Once established, the architecture of the acrosome contributes to the acrosome reaction, which occurs prior to gamete interaction in mammals. The present study aims to clarify the morphology associated with the integration of the mouse fertilization-related acrosomal protein equatorin (mEQT) into the developing acrosome. EQT mRNA was first detected by in situ hybridization in round spermatids but disappeared in early elongating spermatids. The molecular size of mEQT was approximately 65 kDa in the testis. Developmentally, EQT protein was first detected on the nascent acrosomal membrane in round spermatids at approximately step 3, was actively integrated into the acrosomal membranes of round spermatids in the following step and then participated in acrosome remodeling in elongating spermatids. This process was clearly visualized by high-resolution fluorescence microscopy and super-resolution stimulated emission depletion nanoscopy by using newly generated C-terminally green-fluorescent-protein-tagged mEQT transgenic mice. Immunogold electron microscopy revealed that mEQT was anchored to the acrosomal membrane, with the epitope region observed as lying 5-70 nm away from the membrane and was associated with the electron-dense acrosomal matrix. This new information about the process of mEQT integration into the acrosome during spermatogenesis should provide a better understanding of the mechanisms underlying not only acrosome biogenesis but also fertilization and male infertility.

Peroxisomes are subcellular organelles involved in lipid metabolic processes, including those of very-long-chain fatty acids and branched-chain fatty acids, among others. Peroxisome matrix proteins are synthesized in the cytoplasm. Targeting signals (PTS or peroxisomal targeting signal) at the C-terminus (PTS1) or N-terminus (PTS2) of peroxisomal matrix proteins mediate their import into the organelle. In the case of PTS2-containing proteins, the PTS2 signal is cleaved from the protein when transported into peroxisomes. The functional mechanism of PTS2 processing, however, is poorly understood. Previously we identified Tysnd1 (Trypsin domain containing 1) and biochemically characterized it as a peroxisomal cysteine endopeptidase that directly processes PTS2-containing prethiolase Acaa1 and PTS1-containing Acox1, Hsd17b4, and ScpX. The latter three enzymes are crucial components of the very-long-chain fatty acids β-oxidation pathway. To clarify the in vivo functions and physiological role of Tysnd1, we analyzed the phenotype of Tysnd1-/- mice. Male Tysnd1-/- mice are infertile, and the epididymal sperms lack the acrosomal cap. These phenotypic features are most likely the result of changes in the molecular species composition of choline and ethanolamine plasmalogens. Tysnd1-/- mice also developed liver dysfunctions when the phytanic acid precursor phytol was orally administered. Phyh and Agps are known PTS2-containing proteins, but were identified as novel Tysnd1 substrates. Loss of Tysnd1 interferes with the peroxisomal localization of Acaa1, Phyh, and Agps, which might cause the mild Zellweger syndrome spectrum-resembling phenotypes. Our data established that peroxisomal processing protease Tysnd1 is necessary to mediate the physiological functions of PTS2-containing substrates. © 2013 Mizuno et al.

Peroxisomes are subcellular organelles involved in lipid metabolic processes, including those of very-long-chain fatty acids and branched-chain fatty acids, among others. Peroxisome matrix proteins are synthesized in the cytoplasm. Targeting signals (PTS or peroxisomal targeting signal) at the C-terminus (PTS1) or N-terminus (PTS2) of peroxisomal matrix proteins mediate their import into the organelle. In the case of PTS2-containing proteins, the PTS2 signal is cleaved from the protein when transported into peroxisomes. The functional mechanism of PTS2 processing, however, is poorly understood. Previously we identified Tysnd1 (Trypsin domain containing 1) and biochemically characterized it as a peroxisomal cysteine endopeptidase that directly processes PTS2-containing prethiolase Acaa1 and PTS1-containing Acox1, Hsd17b4, and ScpX. The latter three enzymes are crucial components of the very-long-chain fatty acids β-oxidation pathway. To clarify the in vivo functions and physiological role of Tysnd1, we analyzed the phenotype of Tysnd1-/- mice. Male Tysnd1-/- mice are infertile, and the epididymal sperms lack the acrosomal cap. These phenotypic features are most likely the result of changes in the molecular species composition of choline and ethanolamine plasmalogens. Tysnd1-/- mice also developed liver dysfunctions when the phytanic acid precursor phytol was orally administered. Phyh and Agps are known PTS2-containing proteins, but were identified as novel Tysnd1 substrates. Loss of Tysnd1 interferes with the peroxisomal localization of Acaa1, Phyh, and Agps, which might cause the mild Zellweger syndrome spectrum-resembling phenotypes. Our data established that peroxisomal processing protease Tysnd1 is necessary to mediate the physiological functions of PTS2-containing substrates. © 2013 Mizuno et al.

Objective: To describe the delivery of a healthy female infant after intracytoplasmic sperm injection (ICSI) using pentoxifylline-activated sperm from a patient with Kartagener's syndrome. Design: Case report. Setting: Private assisted reproductive technology clinic in Japan. Patient(s): A couple with male factor infertility due to Kartagener's syndrome. Intervention(s): Intracytoplasmic sperm injection using ejaculated sperm activated by pentoxifylline. Main Outcome Measure(s): Semen characteristics, sperm ultrastructure, fertilization, pregnancy, and birth after ICSI. Result(s): The fertilization rate was 7 of 12 (58.3%), and the blastocyst formation rate was 4 of 7 (57.1%); all blastocysts were vitrified. After a single blastcyst transfer, a pregnancy ensued and progressed to term; a healthy female infant was delivered. Conclusion(s): With ejaculated sperm, which was activated by pentoxifylline, successful fertilization was accomplished by ICSI; thus, fertilization, vitrification, pregnancy, and delivery are attainable with sperm obtained from men with Kartagener's syndrome. (Fertil Steril (R) 2011; 95: 2431. e9-e11. (C) 2011 by American Society for Reproductive Medicine.)

Purpose: Zona pellucida (ZP)-free eggs are often used for studies such as evaluating the interaction of sperm-oolemma. To acquire ZP-free eggs, the most commonly used methods employ acidified Tyrode's solution, enzymatic digestion with a trypsin-like enzyme, or mechanical methods using micropipettes. However, acidified Tyrode's solution and trypsin-like enzymes often damage the oolemma, especially when many eggs are treated at once for mass sample analyses. The mechanical method requires skill, and it is time-consuming to prepare many ZP-free eggs. Therefore, in this study, to establish an easy, reliable method for preparing ZP-free eggs, we examined the ZP digestion method originally reported by Zuccotti et al. (J Reprod Fertil 93:515-520, 1991) that uses collagenase. Methods: Mouse unfertilized eggs were treated with collagenase and acidified Tyrode's solution to compare the ZP-free rates, the effect on the oolemma, and the two-cell development rates of ZP-free eggs by in vitro fertilization. The effects on the oolemma were gauged by observing the polarity of the transmembrane protein localization of enhanced green fluorescence protein tagged CD9 protein (CD9-EGFP) and using differential interference contrast microscopy. Results: Collagenase removed the ZP and the cumulus cells from the cumulus oocyte complex. The collagenase method had no influence on the localization of CD9-EGFP, resulting in a high two-cell development rate. Additionally, the collagenase method could exclude low quality eggs with hardened ZP, since collagenase could not digest the hardened ZP. Conclusions: The one-step collagenase method is an easy preparation method for large numbers of high-quality ZP-free eggs. © 2011 Japan Society for Reproductive Medicine.

Recently we reported that an oocyte activation ability in human and mouse sperm is associated with head flatness or the presence of perinuclear theca (PT) substance, MN13, which is an oocyte activation-related protein localized on the post-acrosomal sheath (PAS). As such, we hypothesize that the appearance of oocyte activation ability is stage-specifically regulated and depends on the formation of the acrosome or PAS/PT in spermatids. We monitored the appearance and movement of MN13 as a PT-specific molecule during spermatogenesis and analysed how the MN13 localization is affected in mouse and human globozoospermic acrosomeless sperm. MN13 was first detected on the surface of acrosomic vesicles, i.e. on the nascent outer acrosomal membrane of step 5-6 round spermatids (Sb1 spermatids in human), and it was then translocated via the outer acrosomal membrane surface to the most distal region of the acrosome in step 7 round spermatids (Sb2 spermatids). As spermatids elongated, MN13 was translocated via the cytoplasmic space between the nuclear envelope and the overlying plasma membrane towards the post-acrosomal region, and it was organized on the top of the nascent PAS that was typically found in step 14 elongated spermatids (Sd1 spermatids). In contrast, MN13 was not found in any GOPC-deficient spermatids, which completely lack the acrosome but have manchettes (microtubule bundles), nor in mouse and human acrosomeless sperm. The MN13 appearance or the MN13-related PAS/PT formation is highly dependant on acrosome formation; the MN13-related oocyte activation factor/ability is stage-specifically acquired in elongating/elongated spermatids.

High-resolution microscopy has been used to investigate the mechanism of the migration of cytoplasmic droplets during epididymal maturation of guinea pig spermatozoa. On testicular spermatozoa, droplets are located at the neck and, after passage through the middle cauda epididymidis, migrate only as far as the center of the midpiece. Initially, the space between the plasma membrane and outer mitochondrial membranes outside the droplet is 30.8 +/- 11.0 nm, whereas on mature spermatozoa, it significantly (P &lt; 0.01) narrows to a more consistent 15.9 +/- 1.3 nm. This is accompanied by the appearance of thin filaments cross-linking the two membranes above and below the droplet. Changes also occur in the arrangement of intramembranous particles (IMPs) in the plasma membrane overlying the midpiece. At the spermatid stage, linear arrays of IMPs are absent but appear on immature spermatozoa, where they are short with an irregular orientation, in the epididymis. On mature spermatozoa, numerous parallel linear arrays are present at the region where the plasma membrane adheres to the mitochondria. The membrane adhesion process can thus be observed two-dimensionally. The initial migration of the droplet from the neck is probably attributable to diffusion, with the formation of cross-linking filaments between the two membranes in the proximal midpiece preventing any backward flow and squeezing the droplet distally until it is arrested at the central midpiece by the filaments formed in the distal midpiece. The filaments might also stabilize the flagellum against hypo-osmotic stress encountered during ejaculation and within the female tract.

A tetraspanin family protein, CD9, has not previously been identified in sperm cells. Here, we characterize sperm CD9 in the mouse, including its unique localization in sperm, appearance during spermatogenesis, and behavior and fate during mouse fertilization. In sperm, CD9 is an inner acrosomal membrane-associated protein, not a plasma membrane-associated protein. Its molecular weight is approximately 24 kDa throughout its processing, from testicular germ cells to acrosome-reacted sperm. A temporal difference was found between mRNA and protein expression; CD9 mRNA was detected in the stages from spermatogonia through round spermatids showing the strongest levels in midpachytene spermatocytes. CD9 protein was detected in the cytoplasm throughout the stages from spermatogonia to spermatocytes. While CD9 was weakly expressed in the spermatids from step 1 through step 14, the signals became clearly positive at the marginal region of the anterior acrosome in elongated spermatids. After the acrosome reaction, the majority of sperm CD9 was retained in the inner acrosomal membrane, but some quantity of CD9 was found on the plasma membrane covering the equatorial segment as detected by immunogold electron microscopy using anti-CD9 antibody. CD9 was maintained on the sperm head after reaching the perivitelline space of CD9-deficient eggs that were recovered after natural mating with wild males. Thus, this study characterizes CD9 in sperm development and fertilization.

It is important to establish a reliable and progressive model of the acrosome reaction. Here, we present a progression model of the acrosome reaction centering around the acrosomal membrane-anchored protein equatorin (MN9), comparing the staining pattern traced by MN9 antibody immunofluorescence with that traced by Arachis hypogaea agglutinin (PNA)-FITC. Prior to the acrosome reaction, equatorin was present in both the anterior acrosome and the equatorial segment. Since sperm on zona pellucida showed various staining patterns, MN9-immunostaining patterns were classified into four stages: initial, early, advanced, and final. As the acrosome reaction progressed from the initial to the early stage, equatorin spread from the peripheral region of the anterior acrosome toward the center of the equatorial segment, gradually over the entire region of the equatorial segment during the advanced stage, and finally uniformly at the equatorial segment at the final stage. In contrast, the PNA-FITC signals spread more quickly from the peripheral region of the acrosome toward the entire equatorial segment, while decreasing in staining intensity, and finally became weak at the final stage. MN9-immunogold electron microscopy showed equatorin on the hybrid vesicles surrounded by amorphous substances at advanced stage of acrosome reaction. Equatorin decreased in molecular mass from 40-60 to 35 kDa, and the signal intensity of 35 kDa equatorin increased as the acrosome reaction progressed. Thus, the established equatorin-based progression model will be useful for analyzing not only the behavior of equatorin but also of other molecules of interest involved in the acrosome reaction. Reproduction (2010) 139 533-544

Equatorin (MN9 antigenic molecule) is a widely distributed acrosomal protein in mammalian sperm. During the acrosome reaction, some amount of equatorin translocates to the plasma membrane, covering the equatorial region. From the results of studies of both in vitro and in vivo fertilization inhibition using the MN9 antibody, equatorin has been suggested to be involved in fusion with the oolemma. In the present study, we cloned equatorin and, using mass spectrometry and carbohydrate staining, found it to be a highly glycosylated protein. Equatorin is a sperm-specific type 1 transmembrane protein, and glycosidase treatment and recombinant protein assays verified that it is an N,O-sialoglycoprotein. in addition, the gamete interaction-related domain recognized by the MN9 antibody is posttranslationally modified. The modified domain was identified near threonine 138, which was most likely to be O-glycosylated when analyzed by amino acid substitution, dephosphorylation, and O-glycosylation inhibitor assays. Immunogold electron microscopy localized the equatorin N-terminus, where the MN9 epitope is present, on the acrosomal membrane facing the acrosomal lumen. These biochemical properties and the localization of equatorin are important for further analysis of the translocation mechanism leading to gamete interaction.

Recent studies indicate that round-headed sperm cannot activate oocytes and lack the postacrosomal sheath (PAS) or perinuclear theca (PT), although normal flat-headed sperm can activate oocytes and do have PAS (PT). In this study, we investigated how oocyte activation ability correlates with sperm head morphology (round and flat) and the presence of PT, by studying MN13, a representative molecule of the PT. We analyzed sperm with flat and round heads from infertile patients with globozoospermia (n = 1) and teratozoospermia (n = 1), and also from GOPC(-/-) mice, an animal model of human globozoospermia. Differential interference contrast image analysis, immunocytochemistry with MN13 antibody, transmission electron microscopy and an oocyte activation assay (assessing pronucleus formation) with ICSI were used. Flat-headed (control) sperm from both a healthy fertile volunteer man and wild-type mice had MN13 and PAS (PT). Flat-headed sperm (&lt; 5% of the population) from GOPC(-/-) mice also had both MN13 and PAS (PT), and they showed high oocyte activation ability. In contrast, round-headed sperm from a globozoospermia patient (100%) and GOPC(-/-) mice (&gt; 95% of the population) had neither MN13, nor PAS (PT), nor oocyte activation ability. Oocyte activation was higher in flat- versus round-headed sperm from GOPC(-/-) mice (P &lt; 0.05). Oocyte activation ability may be related to sperm head flatness and presence of MN13 and PAS (PT) in human and mouse sperm. This information is a first step towards the possibility of selecting good-quality sperm with high oocyte activation ability for ICSI.

Aim: To understand the biological functions of the ectoplasmic specializations between Sertoli cells and maturing spermatids in seminiferous epithelia. Methods: In order to disrupt the function of the ectoplasmic specializations, nectin-2, which is expressed at the specialization, was neutralized with anti-nectin-2 antibody micro-injected into the lumen of the mouse seminiferous tubule. Anti-nectin-3 antibody was also micro-injected into the lumen in order to neutralize nectin-3, which is expressed at the specialization. Results: The actin filaments at the specialization disappeared, and exfoliation of maturing spermatids was observed by electron microscopy. Conclusion: Nectin-2 was neutralized by anti-nectin-2 antibody and nectin-3 was neutralized by anti-nectin-3 antibody, respectively. Inactivated nectin-2 and nectin-3 disrupted the pectin-afadin-actin system, and finally the actin filaments disappeared. As a result, the specialization lost the holding function and detachment of spermatids was observed. One of the functions of the specialization seems to be to hold maturing spermatids until spermiation.

Human sperm has functional domains on the head and tail (flagellum). Since functional molecules are organized into the substructures of these domains, sperm with good appearance are expected to be fertile. Thus, it is of interest to see how sperm fine morphologies relate to fertility. The sperm head is divided into the acrosome and postacrosome regions. The acrosome region is further divided into the anterior acrosome for the acrosome reaction and posterior acrosome (equatorial segment) for gamete membrane fusion. The postacrosome region is involved in egg activation. In addition, the human sperm head has varieties of nuclear vacuoles. High-resolution light microscopy, which has recently been used in IMSI (intracytoplasmic morphologically selected sperm injection), is helpful in identifying vacuoles. However, IMSI is still insufficient for analysis of the contents of vacuoles electron microscopy and evaluation tests for sperm DNA damage are more helpful for profound analysis of the nature of nuclear vacuoles and DNA status, respectively. The neck region carries the paternal centrosome to the oocyte to evoke sperm aster, from which microtubules emanate. Organization failure of the midpiece and principal piece strongly affects motility. This paper discusses the relationship beween the normality/abnormality of sperm substructures and fertility and shows typical phenotypes found in gene knockout animal models. © 2008, JAPANESE SOCIETY OF OVA RESEARCH. All rights reserved.

Deletion of the GOPC gene encoding mouse GOPC (Golgi-associated PDZ- and coiled-coil motif-containing protein) causes infertile round-headed spermatozoa. which have acrosome-less round heads and deformed tails (Yao et at, 2002). This study investigated how GOPC deficient spermatids fail to assemble the peri-nuclear structures in round-headed spermatozoa during spermiogenesis in GOPC knockout mouse testes. In step 1-8 spermatids, Golgi-derived proacrosomal vesicles that are transported to the perinuclear region formed acrosome-like vesicles of various sizes, called pseudoacrosomes. The marginal ring of the acroplaxome, which is generally formed between the descending edge of a developing acrosome and nuclear envelope in a wild spermatid, was poorly formed between the pseudoacrosome and nuclear envelope. In step 9-11 elongating spermatids, a majority of pseudoacrosomes were detached from the nucleus and disappeared from the perinuclear region by spermiation. Concomitantly, several failures occurred on the nucleus, manchette, postacrosomal sheath (perinuclear theca), and posterior ring. Ectoplasmic specializations were poorly formed, and did not always associate with developing spermatids. Consequently, spermatid nuclear elongation to form round-headed spermatozoa developed was impaired. In addition to these sequential failures. the posterior ring deficiency was attributed to the tail deformation destined to occur during epididymal maturation as reported in an accompanying paper (Suzuki-Toyota et al., 2004 in this issue), its eventual phenotype being reminiscent of the round-headed spermatozoa of human infertile globozoospermia.

A mouse homologue of Drosophila germ cell-less, mouse germ cell-less-1 (mgcl-1),is highly expressed in the testis. Previous report revealed that the fertility of the mgcl-1(-/-) male mice is reduced significantly as a result of various morphological abnormalities in the sperm (Kimura et al., 2003). To elucidate the function of mgcl-l in spermatogenesis, the expression of mGCL-1 in the wild-type testis was examined. Immunohistochemical studies demonstrated that mGCL-1 first appeared in the nuclei of the pachytene spermatocytes at stage VI of the seminiferous epithelium, and existed in those of spermatids until step 8 during spermatogenesis. mGCL-1 was not detectable after step 9 spermatids. The testicular cells and epididymal sperm were further analyzed morphologically using mgcl-1(-/-) mice. In the testis, deformed nuclei first occurred in the pachytene spermatocytes at stage VI, which is consistent with the time of the first appearance of the mGCL-1 protein in the wild-type testis. Abnormal nuclei and acrosomes were found in spermatids after step 5, and nuclei of the spermatids and epididymal sperm were frequently invaginated. In addition, variously deformed sperm such as bent-neck, multi-headed or multi-nucleated sperm were observed in the mgcl-1(-/-) cauda epididymidis. However, several key structures such as the acroplaxome marginal ring (Kierszenbaum er al., 2003). postacrosonial sheath, and posterior ring apparently formed. In addition. MN7 and MN13. essential suhstances, for fertilization that are located in sperm heads. were detectable in the mgcl-1 null sperm. These observations provide important insights into the mechanisms regulating the nuclear architecture and causes of human infertility.

Male mice deleting the gene encoding GOPC (Golgi -associated PDZ- and coiled-coil motif-containing protein) are infertile, showing globozoospermia with a coiled tail (Yao et al., 2002). We confirmed how and where tail anomalies were produced in spermatids and epididymal spermatozoa by light and electron microscopy. During spermiogenesis, tail formation occurred normally, but a defect was found at the posterior ring. Thereafter, remarkable sperm tail deformations were induced during epididymal passage. In the proximal caput epidiymidis, the tails remained normal and straight, but most of them coiled around the nucleus in the cauda epididymidis. Coiling is presumed to occur with the migration of the cytoplasmic droplet by the absence of the posterior ring. The connecting piece of the coiled tail was often dislocated or separated from the implantation fossa. Many, mitochondria were separated from the outer dense fibers (ODFs) and formed a stratified mitochondrial sheath. Due to this, the distal part of the midpiece became bared of the mitochondrial sheath. The bared ODFs were often bent and disorganized. Tail deformities are attributed to weak or incomplete adhesion between the following structures: 1) plasma membrane and nuclear envelope at the posterior ring, 2) connecting piece and implantation fossa, and 3) mitochondria and ODFs. These defects result in a coiled tail. tail dislocation from the implantation fossa. and the stratified nutochondrial sheath accompanying bared ODFs in the midpiece, respectively. Thus the posterior ring is significant in preventing coiled tail formation. The GOPC-deficient spermatozoa provide a valuable model not only for head but also for tail anomalies.

Either a 20 or 200 mug/kg body weight/injection of bisphenol A (BPA) was subcutaneously administered to adult mice and rats for 6 days, and the effects on the testes were investigated by electron and light microscopy. Abnormalities were observed in the spermatids: acrosomal vesicles, acrosomal caps, acrosonies and nuclei of the spermatids were severely, deformed. The ectoplasmic specialization between the Sertoli cell and spermatids were also affected: incomplete specialization, redundant ectopic specialization and aplasia were observed. Rats and mice responded similarly to BPA. There were no dose dependencies between the 20- and 200 mug/kg body weight/injection groups. The ectoplasmic specialization between adjoining Sertoli cells, or blood-testis barrier, was not affected. Since similar adverse effects were observed when adult mice were treated with beta-estradiol 3-benzoate, the effects of BPA reported here seem to reflect the estrogenic effects on the testes. Animals kept for an additional two months after cessation of the administration were shown to be fertile and the testes showed normal histology, indicating that the adverse effects were transitory.