Browsing by Subject "Leydig cells"

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    Effects of thyroid hormones on Leydig cells in the postnatal testis
    (Murcia : F. Hernández, 2004) Mendis-Handagama, S.M.L.C.; Ariyaratne,H.B.S.
    Thyroid hormones (TH) stimulate oxidative metabolism in many tissues in the body, but testis is not one of them. Therefore, in this sense, testis is not considered as a target organ for TH. However, recent findings clearly show that TH have significant functions on the testis in general, and Leydig cells in particular; this begins from the onset of their differentiation through aging. Some of these functions include triggering the Leydig stem cells to differentiate, producing increased numbers of Leydig cells during differentiation by causing proliferation of Leydig stem cells and progenitors, stimulation of the Leydig cell steroidogenic function and cellular maintenance. The mechanism of action of TH on Leydig cell differentiation is still not clear and needs to be determined in future studies. However, some information on the mechanisms of TH action on Leydig cell steroidogenesis is available. TH acutely stimulate testosterone production by the Leydig cells in vitro via stimulating the production of steroidogenic acute regulatory protein (StAR) and StAR mRNA in Leydig cells; StAR is associated with intracellular trafficking of cholesterol into the mitochondria during steroid hormone synthesis. However, the presence and/or the types of TH receptors in Leydig cells and other cell types of the Leydig cell lineage is still to be resolved. Additionally, it has been shown that thyrotropin-releasing hormone (TRH), TRH receptor and TRH mRNA in the testis in many mammalian species are seen exclusively in Leydig cells. Although the significance of the latter observations are yet to be determined, these findings prompt whether hypothalamo-pituitary-thyroid axis and hypothalamopituitary- testis axis are short-looped through Leydig cells.
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    GNRH induces activation of Leydig-like cells in Pleurodeles waltlii. A morphometric study
    (Murcia : F. Hernández, 1987) Moya, L.; Guerrero, F.; Navas, P.; García-Herdugo, G.
    The ultrastructure of the interstitial cells of the glandular tissue of Pleurodeles waltlii was studied in testis of animals obtained in early breeding season (January) under gonadotropic releasing hormone (GNRH) treatments and controls. These cells (parenchimal or Ledyig-like cells) displayed the structural characteristics of steroid-producing cells. GNRH administration for 24 hours induced a significant decrease of both medial volume and volume density of lipid droplets. On the other hand, cell volume, nucleus. mitochondria, mitochondrial cristae and tubules of smooth endoplasmic reticulum were increased. The surface density of mitochondrial cristae was also increased
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    Luteinizing hormone on Leydig cell structure and function
    (Murcia : F. Hernández, 1997) Mendis-Handagama, S.M.L.C.
    The effects of luteinizing hormone (LH) and human chorionic gonadotrophic hormone (hCG) on Leydig cell structure and function are reviewed in this paper under two main headings; responses to LH and hCG stimulation and responses to LH deprivation. With acute LH stimulation, up to 2 hours following the LH injection, there was no change in the volume of a Leydig cell. However, Leydig cell peroxisomal volume and intraperoxisomal SCP2 content showed a rapid and transient change. These changes can be considered to be specific because: i) no other Leydig cell organelle including smooth endoplasmic reticulum (SER) showed such a change, and ii) only the intraperoxisomal SCP but not catalase (a marker enryme for peroxisome~ showed such a change within 30 minutes of LH stimulation. As these changes occurred prior to the peak testosterone levels following this treatment, it is suggested that SCP2 and peroxisomes may have an association with testosterone biosynthesis prior to cholesterol transport into mitochondria. With LH or hCG stimulation for longer periods, i.e. one day or more, the same morphological changes are produced in Leydig cells irrespective of the age of the species, dosage of LH or hCG, and with single or multiple doses. These changes include, Leydig cell hypertrophy andlor hyperplasia, increase in the cellular organelle content (mostly SER and mitochondria) and depletion of lipid droplets. In addition, a recent study showed that Leydig cell peroxisomal volume, SCP2 content, the amount of intraperoxisomal SCP2 and testosterone secretory capacity were also significantly increased in response to chronic LH treatment. The effects of LH deprivation by whatever means (e.g. hypophysectomy, with testosterone and 17B-estradiol Silastic implants, LH antisera) on Leydig cell structure and function is generally described as opposite to those observed following LH or hCG stimulation. These include Leydig cell hypotrophy and hypoplasia, reductions in the cytoplasmic organelle content in general and specific reductions in SER and peroxisomal volumes, reductions in total catalase and Ofíprint requests to: Dr. S.M.L. Chamindrani Mendis-Handagama, Department of Animal Science, College of Veterinary Medicine, The Universiiy of Tennessee, Knoxville, Tennessee 37996, USA. SCP2 in Leydig cells together with reductions in the intraperoxisomal SCP2 content in Leydig cells and their testosterone secretory capacity.
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    Ovarian Leydig cells (OLC): A histomorphological and immunohistochemical study
    (Universidad de Murcia. Departamento de Biología Celular e Histología, 2017) Carrasco Juan, J.L.; Álvarez Argüelles Cabrera, H.; Martín Corriente, M.C.; González Gómez, M.; Valladares Parrilla, F.; Gutiérrez García, R.; Díaz Flores, L.
    Testicular Leydig cells (LC) regulate the proper development of male individuals, both during fetal life (fetal LC) and puberty (adult LC). In the ovaries of adult women, there are cells that are very similar to Leydig cells, the ovarian hilus cells (OHC), which also produce testosterone. The origin of these cells, in both sexes, remains unknown and is still a matter of debate. We have studied the location, characteristics and relationships of the OHC in 90 patients. The indications for oophorectomy were: metrorrhagia (n=9), prolapse (n=8), endometrial hyperplasia (n=14), cancer (endometrial, myometrial, or cervical) (n=35), uterine leiomyomata (n=14), and various ovarian tumors (cysts and benign tumors, borderline and malignant) (n=10). In addition to the hilus, occasionally the nodules, nests and clusters of OHC were located in the mesovarium, the mesosalpinx, and in the medullar and cortical regions of the ovaries. The morphological (including crystalloids of Reinke) and immunohistochemical (positivity for calretinin and alpha-inhibin) findings were similar to those described for testicular LC. Therefore, OHC can be considered ovarian Leydig cells (OLC). LC are usually found in small numbers in the ovaries, but if one looks for them intentionally, one always finds them. Close relationships were observed between the OLC with nerves and vessels. Moreover, an intraneural location of the OLC was demonstrated in all cases, and these intraneural cells showed similar characteristics to extraneural OLC, suggesting that they derive from endoneural cells which are present in the vegetative nerves of the ovaries.
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    Sertoli cell expression of galectin-l and -3 and accessible binding sites in normal human testis and Sertoli cell only-syndrome
    (Murcia : F. Hernández, 1999) Wollina, U.; Schreiber, G.; Görnig, M.; Feldrappe, S.; Burchert, M.; Gabius, H.J.
    Galectins are vertebrate lectins interacting with B-galactosides and derivates thereof such as blood group A, B and H determinants. The expression of galectin-l and -3 and galectin-specific binding sites by human Sertoli cells was analyzed in normal human testis and Sertoli cell only-syndrome (SCOS). Staining intensity was scored semiquantitatively on a 4-grade scale. Sertoli cells in normal testes displayed a moderate cytoplasmic and weak nuclear staining for galectin-lspecific binding sites. Galectin-3-specific binding sites were expressed in Sertoli cells less intensely than accessible ligands for galectin-l (mean score 2.25 for galectin-l and 1.50 for galectin-3). Germ cells were only weakly reactive. Tubular walls were negative for both classes of galectin-specific binding sites. In SCOS, galectin-l binding was moderate to strong and more pronounced than galectin-3 binding by Sertoli cells (mean scores 4.00 and 2.25). Tubular walls were negative for galectin-staining. The ratio for galectin-1-1 galectin-3-specific binding (staining score ratio) was 1.50 form normal testis and 1.78 for SCOS disclosing a relative increase of galectin-3 binding sites in the latter. Staining with galectin-l- and -3-specific antisera showed a strong cytoplasmic galectin-l immunoreactivity in Sertoli cells of normal and SCOS testis (score 4.00 for both). Anti-galectin-3 did not stain Sertoli cells or germ cells in normal testis. Only Leydig cells were labeled (score 3.00). In SCOS a weak to moderate nuclear staining of Sertoli cells was noted (score 2.00). Galectin-3 expression and galectin-l-specific binding sites were found to be increased in Sertoli cells of SCOS. This modulation of reactivity can have implications for Sertoli cell interactions with galectinreactive extracellular matrix components like laminin and for anti-apoptotic effects.
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    Thyroid hormone and anti-Mullerian hormone (AMH) on Leydig cell differentiation: studies using C57BL/6 mice and AMH over expressing mice
    (F. Hernandez y JuanF. Madrid. Universidad de Murcia. Departamento de Biología Celular e Histología., 2012) Ariyaratne, H.B.S.; Mendis-Handagama, S.M.L.C.
    Although the thyroid hormone has stimulatory effects and anti-Mullerian hormone (AMH) has inhibitory effects on prepubertal Leydig cell (LC) differentiation, it is important to find out whether the stimulatory effect of thyroid hormone could overcome the inhibitory effect of AMH on postnatal LC differentiation. Therefore, the objective of the present study was to use the anti-Mullerian hormone overexpressing mouse (AMH++) model to understand the simultaneous effects of AMH and thyroid hormone on postnatal LC differentiation, proliferation, maturation and function and to test whether the inhibitory effect of AMH could be overcome by the stimulatory effect of the thyroid hormone. Four age groups (7, 21, 40, 90 days) of control (C57BL/6; C) and AMH++ were used. Mice received either saline or triiodothyronine (T3) SC injections daily from birth to 21days. The four experimental groups were C, C+T3, AMH++ and AMH+T3. Body and testis weights of both C+T3 and AMH+T3 mice were significantly reduced at days 21, 40 and 90, compared to their age-matched saline-treated mice (C and AMH++). BrdU studies revealed the absence of LC proliferation in AMH++ mice at day7, however, same-aged mice of C+T3 and AMH+T3 mice showed increased LC proliferation; the rate was highest in C+T3 at day21. C+T3 mice of day 21 had more LC than C mice as well as AMH+T3 and AMH++ mice. At days 40 and 90, LC number/testis in C+T3 was lower than C, however, AMH+T3 had higher LC numbers than AMH++ mice. Cellular apoptosis was not seen as the cause of reduced LC numbers. Serum testosterone was not different among groups at day 21, but significantly higher levels were seen in AMH+T3 compared to AMH++ mice at days 40 and 90. Similar pattern was seen for luteinizing hormone (LH)-stimulated testicular testosterone and androstenedione production in vitro. Findings suggest that T3-treatment for the first postnatal 21 days was able to partially counteract the inhibitory effect of AMH on prepubertal LC differentiation. Whether continuation of the T3-treatment beyond 21 days would have resulted in complete removal of this inhibition, is a question that needs to be addressed.