Production of 25-hydroxycholesterol by testicular macrophages and its effects on Leydig cells

Testicular macrophages secrete 25-hydroxycholesterol, which can be converted to testosterone by neighboring Leydig cells. The purposes of the present studies were to determine the mode of production of this oxysterol and its long-term effects on Leydig cells. Because oxysterols are produced both enzymatically and by auto-oxidation, we first determined if testicular macrophages possess cholesterol 25-hydroxylase mRNA and/or if macrophage-secreted products oxidize cholesterol extracellularly. Rat testicular macrophages had 25-hydroxylase mRNA and converted 14C-cholesterol to 14C-25-hydroxycholesterol; however, radiolabeled cholesterol was not converted to 25-hydroxycholesterol when incubated with medium previously exposed to testicular macrophages. Exposure of Leydig cells to 10 microg/ml of 25-hydroxycholesterol, a dose within the range known to result in high basal production of testosterone when tested from 1 to 6 h, completely abolished LH responsiveness after 2 days of treatment. Because 25-hydroxycholesterol is toxic to many cell types at 1-5 microg/ml, we also studied its influence on Leydig cells during 4 days in culture using a wide range of doses. Leydig cells were highly resistant to the cytotoxic effects of 25-hydroxycholesterol, with no cells dying at 10 microg/ml and only 50% of cells affected at 100 microg/ml after 2 days of treatment. Similar conditions resulted in 100% death of a control lymphocyte cell line. These results demonstrate that 1) testicular macrophages have mRNA for cholesterol 25-hydroxylase and can convert cholesterol into 25-hydroxycholesterol, 2) macrophage-conditioned medium is not capable of auto-oxidation of cholesterol, 3) Leydig cells are highly resistant to the cytotoxic influences of 25-hydroxycholesterol, and 4) long-term treatment with high doses of 25-hydroxycholesterol results in loss of LH responsiveness. These results support the concept that testicular macrophages enzymatically produce 25-hydroxycholesterol that not only is metabolized to testosterone by Leydig cells when present at putative physiological levels but also may exert inhibitory influences on Leydig cells when present for extended periods at very high concentrations that may occur under pathological conditions.     

Development of cytoplasmic digitations between Leydig cells and testicular macrophages of the rat

Summary Testicular macrophages and Leydig cells from adult animals are known to be functionally coupled. For example, secreted products from macrophages stimulate testosterone secretion by Leydig cells. In adult rat testes, structural coupling also exists between these cells. This coupling consists of cytoplasmic projections from Leydig cells located within cytoplasmic invaginations of macrophages. Although macrophages are known to exist in the testis in immature animals, it is not known when these digitations develop. The purpose of the present study was to determine whether the time of their development coincides with known maturational events that occur in Leydig cells, particularly during the peripubertal period. Testes from rats at 20, 30 and 40-days-of-age as well as testes from mature rats weighing more than 500 gm were prepared for ultrastructural analysis. It was found that digitations form between 20 and 30-days-of-age. These structures varied from simple tubular projections to complicated branched structures, suggesting that digitations are more than simple invaginations of microvilli into coated vesicles as previously described. Subplasmalemmal linear densities were also observed within macrophages juxtaposed to Leydig cells. Collagen was commonly observed between macrophages and Leydig cells in animals 20 days old. These studies demonstrate that although macrophages are present in the testis in maximal numbers at 20 days-of-age, they do not form junctions with Leydig cells until day 30. This is just prior to the major increase in secretory activity of rat Leydig cells that occurs during puberty.     

Glycogen content during the postnatal differentiation of the Leydig cell in the mouse testis

Summary The concentration and distribution of glycogen in relation to postnatal differentiation of the mouse Leydig cell are studied by biochemical and ultrastructural methods. Glycogen decreases to less than one third in the first twelve days after birth. This decrease is accompanied by modifications of its distribution in the cytoplasm. In the newborn it is abundant and arranged in clusters of beta particles; in the mature Leydig cell, glycogen is found scattered in extremely low concentration interspersed among elements of the endoplasmic reticulum.The role of glycogen during Leydig cell differentiation can be interpreted as a source of energy and/or as a source of building material in the biogenesis of membranous components.This work was supported by Grant M 63,121 from the Population Council, U.S.A.Fellow Consejo Nacional de Investigaciones Cientificas y Técnicas, Argentina.     

Bismuth uptake in rat testicular macrophages: a follow-up observation suggesting that bismuth alters interactions between testicular macrophages and Leydig cells.

Recent studies suggest that bismuth accumulates in Leydig cells. In addition, a reduced level of serum testosterone and a statistically significant reduction of Leydig cells have been observed. It was therefore hypothesized that Bi has a direct toxic effect on rat Leydig cells. We have now developed a method for double labeling of bismuth and ED-2 (a marker for testicular macrophages). The present data demonstrate that the heavily bismuth-loaded cells in rat testis, originally interpreted as being Leydig cells, are bismuth-loaded macrophages. Consequently, our data suggest a modified hypothesis regarding bismuth-induced interactions between testicular macrophages and Leydig cells.     

Ontogenetic and lung development in Tupaia belangeri during the early postnatal period

The Belanger's tree shrew (Tupaia belangeri) has an unusual reproductive strategy. The animals are born in altricial condition and remain in the nest for the first four weeks of life, nursed only once in 48 h. This is highly demanding for the constitution of the neonates. Despite their immaturity in the external appearance at birth, newborn tree shrews have to deal with the absence of the mother. We asked if the lung structure of the neonates match the high physiological requirements of this “absentee system”. To examine the lung development of nest young tree shrews, histological and ultrastructural investigations were performed. Newborn tree shrews are at the transition stage between the saccular and the alveolar stage of lung development. In addition to small saccules, the lung has alveoli and associated structures already at birth and thus appears more mature compared with typical altricial species. The results of the present study reveal that despite their immaturity in the external appearance newborn tree shrews are relatively mature in terms of lung development. This can be interpreted as a prerequisite for thermoregulatory abilities, necessary in neonate tree shrews to cope with the restricted nature of maternal care.     

Rat testicular endogenous steroids and number of Leydig cells between the fetal period and sexual maturity

Endogenous androgens (androstenedione, testosterone, 5 alpha-dihydrotestosterone and 5 alpha-androstane-3 alpha,17 beta-diol), and some of their C21 precursors (pregnenolone, progesterone and 17-hydroxyprogesterone) were measured in rat testes between Day 18.5 of pregnancy and Day 64 postpartum, and correlated with numerical densities of Leydig cells. The latter parameter showed an early maximum on Day 19.5 of the fetal period, a nadir on Day 15 postpartum, and a gradual increase thereafter. The two dominating androgens, testosterone and 5 alpha-androstane-3 alpha,17 beta-diol, had similar levels until 15 days of age, but the 5 alpha-diol predominated thereafter. The total steroid content per Leydig cell was highest on Day 18.5 of gestation (77 ng/10(6) cells). A decline started already in utero, and reached a nadir of 5 ng/10(6) cells on Day 29. Thereafter, a slight increase occurred with advancing age. It is concluded that: The fetal testis has highest Leydig cell and endogenous steroid concentrations. A nadir in these parameters is seen 2-4 wk postpartum. The Leydig cell concentration increases around puberty on Days 40-60, but only a slight concomitant increase occurs in steroids. A sharp decline in steroid content per Leydig cell occurs during the last fetal days, but the postnatal decline of testicular steroids is due to Leydig cell loss. The new Leydig cell generation after 15 days has a persistently low steroid concentration through puberty.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hyaluronectin is produced by oligodendrocytes and Schwann cells in vitro

A hyaluronectin (HN)-like antigen was found in rat O-2A progenitors and oligodendrocytes, as well as in Schwann cells and in their culture medium. The HN-like antigen secreted in culture supernatants had a higher molecular mass than HN extracted from rat brain at acidic pH. In vitro the secreted HN-like antigen was spontaneously and slowly degraded into species whose Mr was close to that of HN found in acidic brain extract. In brain or nerve neutral pH extracts, both HN-like antigen and HN were present. The high Mr of the secreted antigen, the homology in amino acid sequences between HN and N-terminal domain of PG-M/versican, in addition to a positive hybridization between Schwann cell RNAs and a probe obtained with primers derived from HN sequences also found in versican suggested that HN is closely related to the large proteoglycan PG-M/versican. The presence in Schwann cell extract of a HN mRNA whose Mr was compatible with the size expected for HN showed that HN may be directly secreted by cells and not only the consequence of a proteolytic cleavage. The similarity of HN with PG-M (V3) suggested that HN found in vivo could be the result of an alternative splicing of a single gene. We conclude that HN as other members of the PG-M/versican family is a marker of oligodendrocytes and Schwann cells in culture.     

A thymus factor influences the in vitro testosterone secretion of Leydig cells in the rat

Thymus extracts obtained from 15-day-old rats were fractionated through molecular sieve chromatography, and the fractions assayed in vitro by changes produced in the testosterone secretion of Leydig cells obtained from adult rat testes. Fractions corresponding to 27-28000 mol wt of the thymus extract diminish the testosterone secretion of Leydig cells stimulated with hCG. No changes in the basal testosterone secretion were produced by the presence of the thymus fractions. The inhibitory effect is dose related and persists during 180 min of incubation. Fractions of the same mol wt obtained from liver, heart and spleen do not modify the testosterone secretion of Leydig cells. The inhibitory activity of the thymus factor disappears after heat or trypsin treatment. Further fractioning in preparative flat bed electrofocusing makes manifest that the inhibitory activity is focused at pH 4.7. The data demonstrate the existence in rat thymus of a factor, probably of protein nature, which modifies the in vitro hCG response of a testis cell suspension.     

Hormonal regulation of differentiation of human fetal prostate and Leydig cells in vitro

Trowell type of organ culture was used for correlative study of the human fetal prostate and Leydig cell differentiation at the ultrastructural level. Androgens accelerated the differentiation of human urethral epithelial cells into secretory prostatic cells and the ultrastructure resembled that in vivo. Also Leydig cells retained in organ culture the same ultrastructural features as in vivo and human chorionic gonadotropin (hCG) accelerated their differentiation. It is concluded that this type of culture technic can be used in the study of early differentiation of human genital organ and androgenes and hCG take part of human prostatic and Leydig cell differentiation.     

Requirement of serum components for the preservation of primordial germ cells in testis cords during early stages of testicular differentiation in vitro in the mouse

Mouse gonadal primordia were isolated from embryos on the 11th day of gestation and cultured in vitro. They developed into either testes or ovaries after 7 days of culture in Eagle's minimum essential medium (MEM) supplemented with horse serum, whereas they did not differentiate in MEM alone. We studied how serum components are required for testicular development in vitro. When gonadal primordia were cultured in MEM alone for the first 1-3 days and subsequently in MEM supplemented with serum, testis cords developed while germ cells disappeared or only a few remained in the testis cords. In contrast, when serum was present in the medium during the first day of culture and omitted thereafter, germ cells were retained within testis cords. These results suggested that some serum component(s) is specifically required by germ cells independent of testis cord organization. Of more than 10 serum components tested, low and very low density lipoprotein fractions increased the number of germ cells in testicular explants.     

The matricellular protein SPARC is internalized in Sertoli, Leydig, and germ cells during testis differentiation

The gene encoding the matricellular protein secreted protein, acidic and rich in cysteine (SPARC) was identified in a screen for genes expressed sex-specifically during mouse gonad development, as being strongly upregulated in the male gonad from very early in testis development. We present here a detailed analysis of SPARC gene and protein expression during testis development, from 11.5 to 15.5 days post coitum (dpc). Section in situ hybridization analysis revealed that SPARC mRNA is expressed by the Sertoli cells in the testis cords and the fetal Leydig cells, found within the interstitial space between the testis cords. Immunodetection with anti-SPARC antibody showed that the protein was located inside the testis cords, within the cytoplasm of Sertoli and germ cells. In the interstitium, SPARC was present intracellularly within the Leydig cells. The internalization of SPARC in Sertoli, Leydig, and germ cells suggests that it plays an intracellular regulatory role in these cell types during fetal testis development.     

Changes in lectin binding patterns of Leydig cells during fetal and postnatal development in mice

Summary Changes in the lectin binding of mouse Leydig cells during fetal and postnatal development were examined by light- and electron-microscopy using eight different biotinylated lectins (ConA, WGA, RCA-I, UEA-I, GS-I, PNA, SBA and GS-II). At the light-microscopic level, ConA, WGA, RCA-I, UEA-I and GS-I showed the same binding pattern in which all five lectins bound to the plasma membrane and cytoplasm of Leydig cells from the 13th day post coitum (p.c.) to the 8th postnatal week. PNA, SBA and GS-II reactions were positive in the plasma membrane and cytoplasm of Leydig cells from the 13th day p.c. to 15th day post partum (p.p.) but disappeared completely by day 20. At the electron-microscopic level, gold particles representing the GS-I or GS-II binding sites were distributed primarily along the cell surface membrane, including that of microvilli, as well as in the cytoplasm. These results indicate that certain glycoconjugates bearingD-galactose,N-acetyl-D-galactosamine, andN-acetyl-D-glucosamine residues are expressed on the cell surface and in the cytoplasm of Leydig cells during the period from the 13th day p.c. to around the 20th day p.p. The results suggest that these glycoconjugates might play some role in modulating hormone-receptor interaction in the Leydig cells before the 20th day. Furthermore, these results may indicate that sugar residues expressed on the cell surface and in the cytoplasm of Leydig cells are different from those in the fetal-neonatal and adult phases.     

Development of ATPase-positive,immature Langerhans cells in the fetal mouse epidermis and their maturation during the early postnatal period

Summary The development and maturation of Langerhans cells during the differentiation of skin was studied in mice from fetal day 13 to adult using 3 indices: (1) ATPase activity; (2) ultrastructure; and (3) quantitative evaluation of the cell population.ATPase-positive Langerhans cells appeared in the epidermis at first at fetal day 16, and they increased in number in the differentiating epidermis during the late fetal period. The earliest appearance of Birbeck granules was at postnatal day 4. Cored tubules were also formed in the Langerhans cells in the dermis at around the same age. The cells containing Birbeck granules or cored tubules are considered to be mature Langerhans cells. In the Langerhans-cell lineage, those cells in the epidermis at stages earlier than postnatal day 4 and not yet containing specific organelles are considered to be immature Langerhans cells. These immature Langerhans cells can be identified ultrastructurally in the epidermis at fetal day 16, coinciding with the appearance of ATPase-positive cells. The increase in the number of immature Langerhans cells during the perinatal period was shown by quantitative analysis of nuclear density and relative Langerhans-cell area on the electron micrographs.It is concluded that ATPase is a marker of the Langerhans-cell lineage from the early development stages, while Birbeck granules and cored tubules are markers that identify mature Langerhans cells in electron micrographs.     

The fate of fetal Leydig cells during the development of the fetal and postnatal rat testis

The ultrastructure and developmental fate of the fetal generation of Leydig cells of the rat testis was studied from the 17th day of fetal life up to 100 days after birth. The number of fetal Leydig cells per testis was determined by light microscopic morphometric analysis of semithin plastic sections. In fetal testes (days 17-22 postconception), Leydig cells exhibited a characteristic ultrastructure, containing smooth endoplasmic reticulum, many lipid inclusions and glycogen. Testes of 17-day-old fetuses contained about 25 x 10(3) fetal Leydig cells, rapidly increasing to 90 x 10(3) per testis in 21-day-old fetuses. After birth, fetal Leydig cells per testis remained relatively constant up to 2 weeks (80-90 x 10(3) per testis) and were identified by light and electron microscopy which showed their numerous lipid inclusions, their tendency for clustering and their association with interstitial tissue fibroblasts which partly encapsulated the fetal Leydig cells. From 21-100 days after birth, fetal Leydig cell numbers were quite variable with a mean of 45-60 x 10(3) per testis. These results are the first to show that the fetal generation of Leydig cells persist in the adult testis and do not undergo early postnatal degeneration or dedifferentiation into other interstitial cells. The simultaneous occurrence of the fetal Leydig cells and the adult population of Leydig cells indicates that these cells are distinct cell generations which are developmentally unrelated.