Masaru Himeno

Localization of mouse vasa homolog protein in chromatoid body and related nuage structures of mammalian spermatogenic cells during spermatogenesis.

The localization of vasa homolog protein in the spermatogenic cells of mice, rats, and guinea pigs was studied by immunofluorescence and electron microscopies with the antibody against mouse vasa homolog (MVH) protein. By immunofluorescence microscopy, four types of granular staining patterns were identified: (1) fine particles observed in diplotene and meiotic cells, (2) small granules associated with a mitochondrial marker and appearing in pachytene spermatocytes after stage V, (3) strands lacking the mitochondrial marker in late spermatocytes, and (4) large irregularly shaped granules in round spermatids. Immunoelectron microscopy defined the ultrastructural profiles of these MVH protein-positive granules: the first type consisted of small dense particles, the second had intermitochondrial cement (IMC), the third type, consisting of strands, had loose aggregates of either material dissociated from IMC or 70–90-nm particles, and the fourth had typical chromatoid bodies (CBs). The results suggest that MVH proteins function in these components of nuage. MVH protein-positive structures other than CBs disappeared during meiosis and CB appeared first in early spermatids. The results suggest that the formation of nuage is discontinued between spermatocytes and spermatids. The formation of nuage in spermatocytes and of CB in spermatids is discussed.

Inulavosin, a melanogenesis inhibitor, leads to mistargeting of tyrosinase to lysosomes and accelerates its degradation.

The melanosome is a highly specialized organelle where melanin is synthesized. Tyrosinase and tyrosinase-related protein-1 (Tyrp1) are major melanosomal membrane proteins and key enzymes for melanin synthesis in melanocytes. Inulavosin, a melanogenesis inhibitor isolated from Inula nervosa (Compositae), reduced the melanin content without affecting either the enzymatic activities or the transcription of tyrosinase or Tyrp1 in B16 melanoma cells. To our knowledge, this inhibitor is previously unreported. Electron-microscopic analyses revealed that inulavosin impaired late-stage development of melanosomes (stages III and IV), in which melanin is heavily deposited. However, it did not alter the early stages of melanosomes (stages I and II), when filamentous structure is observed. Immunofluorescence analyses showed that tyrosinase, but not Tyrp1, was specifically eliminated from melanosomes in cells treated with inulavosin. Unexpectedly, inulavosin specifically accelerated the degradation of tyrosinase but not other melanosomal/lysosomal membrane proteins (Tyrp1, Pmel17, and LGP85). The degradation of tyrosinase induced by inulavosin associated with lysosomes but not the proteasome. Interestingly, lysosomal protease inhibitors restored the melanogenesis but not the targeting of tyrosinase to melanosomes in the cells treated with inulavosin. Instead, colocalization of tyrosinase with lysosome-associated membrane protein-1 at late endosomes/multivesicular bodies and lysosomes was accentuated. Taken together, inulavosin inhibits melanogenesis as a result of mistargeting of tyrosinase to lysosomes.

Restoration of Dioxin-Induced Damage to Fetal Steroidogenesis and Gonadotropin Formation by Maternal Co-Treatment with α-Lipoic Acid

2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD), an endocrine disruptor, causes reproductive and developmental toxic effects in pups following maternal exposure in a number of animal models. Our previous studies have demonstrated that TCDD imprints sexual immaturity by suppressing the expression of fetal pituitary gonadotropins, the regulators of gonadal steroidogenesis. In the present study, we discovered that all TCDD-produced damage to fetal production of pituitary gonadotropins as well as testicular steroidogenesis can be repaired by co-treating pregnant rats with α-lipoic acid (LA), an obligate co-factor for intermediary metabolism including energy production. While LA also acts as an anti-oxidant, other anti-oxidants; i.e., ascorbic acid, butylated hydroxyanisole and edaravone, failed to exhibit any beneficial effects. Neither wasting syndrome nor CYP1A1 induction in the fetal brain caused through the activation of aryl hydrocarbon receptor (AhR) could be attenuated by LA. These lines of evidence suggest that oxidative stress makes only a minor contribution to the TCDD-induced disorder of fetal steroidogenesis, and LA has a restorative effect by targeting on mechanism(s) other than AhR activation. Following a metabolomic analysis, it was found that TCDD caused a more marked change in the hypothalamus, a pituitary regulator, than in the pituitary itself. Although the components of the tricarboxylic acid cycle and the ATP content of the fetal hypothalamus were significantly changed by TCDD, all these changes were again rectified by exogenous LA. We also provided evidence that the fetal hypothalamic content of endogenous LA is significantly reduced following maternal exposure to TCDD. Thus, the data obtained strongly suggest that TCDD reduces the expression of fetal pituitary gonadotropins to imprint sexual immaturity or disturb development by suppressing the level of LA, one of the key players serving energy production.

The effects of dynein inhibition on the autophagic pathway in glioma cells

Autophagy has multiple physiological functions, including protein degradation, organelle turnover and the response of cancer cells to chemotherapy. Because autophagy is implicated in a number of diseases, a better understanding of the molecular mechanisms of autophagy is needed for therapeutic purposes, including rational design of drugs. Autophagy is a process that occurs in several steps as follows: formation of phagophores, formation of mature autophagosomes, targeting and trafficking of autophagosomes to lysosomes, formation of autolysosomes by fusion between autophagosomes and lysosomes, and finally, degradation of the autophagic bodies within the lysosomes. It has been suggested that autophagosome formation is driven by molecular motor machineries, and, once formed, autophagosomes need to reach lysosomes, enriched perinuclearly around the microtubule‐organizing centre. While it is recognized that all these steps require the cytoskeletal network, little is known about the mechanisms involved. Here we assessed the role of cytoplasmic dynein in the autophagic process of human glioma cells to determine the part played by dynein in autophagy. We observed that chemical interference with dynein function led to an accumulation of autophagosomes, suggesting impaired autophagosome‐lysosome fusion. In contrast, we found that overexpression of dynamitin, which disrupts the dynein complex, reduced the number of autophagosomes, suggesting the requirement of the dynein‐dynactin interaction in the early membrane trafficking step in autophagosome formation. These results suggest that dynein plays a variety of crucial roles during the autophagic process in glioma cells.

Maternal Exposure to Dioxin Imprints Sexual Immaturity of the Pups through Fixing the Status of the Reduced Expression of Hypothalamic Gonadotropin-Releasing Hormone

Our previous studies have shown that treatment of pregnant rats with 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD; 1 μg/kg) at gestational day (GD) 15 reduces the pituitary synthesis of luteinizing hormone (LH) during the late fetal and early postnatal period, leading to the imprinting of defects in sexual behaviors at adulthood. However, it remains unclear how the attenuation of pituitary LH is linked to sexual immaturity. To address this issue, we performed a DNA microarray analysis to identify the gene(s) responsible for dioxin-induced sexual immaturity on the pituitary and hypothalamus of male pups, born of TCDD-treated dams, at the age of postnatal day (PND) 70. Among the reduced genes, we focused on gonadotropin-releasing hormone (GnRH) in the hypothalamus because of published evidence that it has a role in sexual behaviors. An attenuation by TCDD of GnRH expression emerged at PND4, and no subsequent return to the control level was seen. A change in neither DNA methylation nor histone acetylation accounted for the reduced expression of GnRH. Intracerebroventricular infusion of GnRH to the TCDD-exposed pups after reaching maturity restored the impairment of sexual behaviors. Supplying equine chorionic gonadotropin, an LH-mimicking hormone, to the TCDD-exposed fetuses at GD15 resulted in a recovery from the reduced expression of GnRH, as well as from the defects in sexual behavior. These results strongly suggest that maternal exposure to TCDD fixes the status of the lowered expression of GnRH in the offspring by reducing the LH-assisted steroidogenesis at the perinatal stage, and this mechanism imprints defects in sexual behaviors at adulthood.

Proteome of ubiquitin ⁄MVB pathway: possible involvement of iron-induced ubiquitylation of transferrin receptor in lysosomal degradation

Ubiquitylation of membrane proteins triggers their endocytosis at the plasma membrane and subsequent lysosomal degradation through multivesicular bodies (MVBs). A dominant‐negative mutant SKD1/Vps4B caused an accumulation of ubiquitylated membrane proteins in MVBs. We have identified 22 membrane proteins whose trafficking is potentially regulated by ubiquitylation. Nine of them, including transferrin receptor (TfR), are indeed ubiquitylated and/or accumulated in MVBs in the cells expressing mutant Vps4. While the recycling route and iron‐regulated expression of TfR are well characterized, the mechanism by which the degradation of TfR is regulated is largely unknown. We show that an excess of iron enhances both TfR’s ubiquitylation and degradation in lysosomes. Probably, the up‐regulated expression of ferritin, an endogenous iron‐chelating molecule, attenuated the iron‐induced degradation of TfR. Exogenously introduced lysine‐less TfR, compared to the wild‐type one, showed resistance to the iron‐induced ubiquitylation and degradation, when endogenous TfR, which most certainly heterodimerizes with exogenous ones, was depleted with siRNA. These data suggest that the iron‐induced ubiquitylation and degradation of TfR along with MVB pathway physiologically plays an important role in iron homeostasis.

Selenium-binding protein 1: Its physiological function, dependence on aryl hydrocarbon receptors, and role in wasting syndrome by 2,3,7,8-tetrachlorodibenzo-p-dioxin

BACKGROUNDnSelenium-binding protein 1 (Selenbp1) is suggested to play a role in tumor suppression, and may be involved in the toxicity produced by dioxin, an activator of aryl hydrocarbon receptors (AhR). However, the mechanism or likelihood is largely unknown because of the limited information available about the physiological role of Selenbp1.nnnMETHODSnTo address this issue, we generated Selenbp1-null [Selenbp1 (-/-)] mice, and examined the toxic effect of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) in this mouse model.nnnRESULTSnSelenbp1 (-/-) mice exhibited only a few differences from wild-type mice in their apparent phenotypes. However, a DNA microarray experiment showed that many genes including Notch1 and Cdk1, which are known to be enhanced in ovarian carcinoma, are also increased in the ovaries of Selenbp1 (-/-) mice. Based on the different responses to TCDD between C57BL/6J and DBA/2J strains of mice, the expression of Selenbp1 is suggested to be under the control of AhR. However, wasting syndrome by TCDD occurred equally in Selenbp1 (-/-) and (+/+) mice.nnnCONCLUSIONSnThe above pieces of evidence suggest that 1) Selenbp1 suppresses the expression of tumor-promoting genes although a reduction in Selenbp1 alone is not very serious as far as the animals are concerned; and 2) Selenbp1 induction by TCDD is neither a pre-requisite for toxicity nor a protective response for combating TCDD toxicity.nnnGENERAL SIGNIFICANCEnSelenbp1 (-/-) mice exhibit little difference in their apparent phenotype and responsiveness to dioxin compared with the wild-type. This may be due to the compensation of Selenbp1 function by a closely-related protein, Selenbp2.

Association of cathepsin E deficiency with the increased territorial aggressive response of mice

Cathepsin E is an endolysosomal aspartic proteinase predominantly expressed in cells of the immune system, but physiological functions of this protein in the brain remains unclear. In this study, we investigate the behavioral effect of disrupting the gene encoding cathepsin E in mice. We found that the cathepsin E‐deficient (CatE−/−) mice were behaviorally normal when housed communally, but they became more aggressive compared with the wild‐type littermates when housed individually in a single cage. The increased aggressive response of CatE−/− mice was reduced to the level comparable to that seen for CatE+/+ mice by pretreatment with an NK‐1‐specific antagonist. Consistent with this, the neurotransmitter substance P (SP) level in affective brain areas including amygdala, hypothalamus, and periaqueductal gray was significantly increased in CatE−/− mice compared with CatE+/+ mice, indicating that the increased aggressive behavior of CatE−/− mice by isolation housing followed by territorial challenge is mainly because of the enhanced SP/NK‐1 receptor signaling system. Double immunofluorescence microscopy also revealed the co‐localization of SP with synaptophysin but not with microtubule‐associated protein‐2. Our data thus indicate that cathepsin E is associated with the SP/NK‐1 receptor signaling system and thereby regulates the aggressive response of the animals to stressors such as territorial challenge.