Cellular composition of the sheep corpus luteum in the mid- and late luteal phases of the oestrous cycle

Corpora lutea (CL) from naturally cycling Corriedale ewes were obtained in the mid- and late luteal phases of the oestrous cycle (Days 9 and 13; 5 ewes per group). The cellular composition of these CL was compared by ultrastructural morphometry to determine whether there were changes in numbers of large and small luteal cells consistent with differentiation of some small luteal cells to large luteal cells during the last part of the luteal phase. No differences between Days 9 and 13 were detected in luteal volume, plasma progesterone concentration, or volume density of any component of the luteal tissue. Large luteal cell numbers (mean +/- s.e.m.) were lower per unit volume of luteal tissue on Day 13 than on Day 9 (14.1 +/- 0.5 vs 18.4 +/- 1.3 X 10(3)/mm3, P less than 0.05). Mean volume of the individual large luteal cells was greater on Day 13 than on Day 9 (19.65 +/- 0.72 vs' 15.60 +/- 1.34 micrograms 3 X 10(3), P less than 0.05). However, there were no significant differences in numbers or volumes of small luteal cells between Days 9 and 13, and total numbers of large luteal cells per CL were not different between these two days. These results provide no support for the hypothesis that small luteal cells differentiate into large luteal cells during the oestrous cycle of the sheep.     

Morphometric analysis of cell types in the ovine corpus luteum throughout the estrous cycle

The cellular composition of ovine corpora lutea obtained during the early (Day 4), mid (Days 8 and 12), and late (Day 16) stages of the estrous cycle was determined by morphometric analysis. Individual corpora lutea were collected via midventral laparotomy from a total of 19 ewes. A center slice from each corpus luteum was processed for electron microscopy and subsequent morphometric analysis of the numbers and sizes of steroidogenic and nonsteroidogenic cells. Luteal weight progressively increased throughout the estrous cycle (p less than 0.05). Corpora lutea collected on Day 16 were assigned to one of two subgroups on the basis of gross appearance and weight: nonregressed (NR, 542 +/- 25 mg) or regressed (R, 260 +/- 2 mg). There were no significant changes in the proportion of the corpus luteum occupied by small luteal cells (19 +/- 2%) or large luteal cells (36 +/- 1%) throughout the estrous cycle. The total number of steroidogenic cells per corpus luteum increased from 21.8 +/- 3.7 (X 10(6)) on Day 4 to 61.7 +/- 5.4 (X 10(6)) on Day 8 (p less than 0.05) and remained elevated thereafter. The number of small luteal cells was 10.0 +/- 2.7 (X 10(6)), 39.7 +/- 1.4 (X 10(6)), 46.1 +/- 5.8 (X 10(6)), 49.0 +/- 13.7 (X 10(6)), and 29.9 +/- 8.6 (X 10(6)) on Days 4, 8, 12, 16 (NR), and 16 (R), respectively (p less than 0.05, Day 4 vs. Days 8, 12, 16 NR). In contrast, the number of large luteal cells was 11.8 +/- 1.5 (X 10(6)) on Day 4 and did not vary significantly during the remainder of the estrous cycle. The numbers of nonsteroidogenic cell types increased (p less than 0.05) from Day 4 to Day 16 (NR) but were decreased in regressed corpora lutea (Day 16 R). Regression was characterized by a 50% decrease (p less than 0.05) in the total number of cells per corpus luteum from 243 +/- 57 ( X 10(6)) on Day 16 (NR) to 125 +/- 14 ( X 10(6)) on Day 16 (R) (p less than 0.05). Small luteal cells remained constant in volume throughout the entire estrous cycle (2520 +/- 270 microns 3), whereas large luteal cells increased in size from 5300 +/- 800 microns 3 on Day 4 to 16,900 +/- 3300 microns 3 on Day 16 (NR) (p less than 0.05). In summary, small luteal cells increased in number but not size throughout the estrous cycle, whereas large luteal cells increased in size but not number.     

Quantitative light microscopic analysis of corpus luteum growth during pseudopregnancy in the rabbit

We employed stereological methods at the light-microscope level to examine the mechanism by which corpora lutea (CL) grow during the course of pseudopregnancy in the rabbit. Corpus luteum volume per ovary, the absolute volume of luteal cells per CL, individual luteal cell volume, the number of luteal and endothelial cells per CL, and capillary surface area per CL were examined in rabbits at Days 1, 4, 7, 11, and 18 of pseudopregnancy. Total CL volume increased from 3.7 +/- 0.1 microliter to 30.3 +/- 0.5 microliter over Days 1 to 11 and thereafter decreased to 15.2 +/- 1.1 microliter by Day 18. Stereological analyses showed that the increases in CL volume from Day 1 to Day 11 were due primarily to increases in the volume of individual luteal cells (from 2.6 +/- 0.2 pl on Day 1 to 23.5 +/- 1.7 pl on Day 11, 1 pl = (10 mu)3; r = 0.96), and that the decrease in CL volume after Day 11 resulted largely from a decrease in luteal cell volume (to 12.8 +/- 1.5 pl). In contrast, no change was seen in the number of luteal cells per CL (range 9.1 x 10(5)-12.5 x 10(5)). These data show that CL growth and subsequent regression during pseudopregnancy result primarily from changes in the volume of individual luteal cells, and not from changes in the number of luteal cells. These data support the hypothesis that modulation of progesterone production during pseudopregnancy is due to changes in individual luteal cell volume and not to changes in cell number.     

Isolation and characterization of cell subpopulations from the monkey corpus luteum of the menstrual cycle

This study was designed to test the hypothesis that the corpus luteum of primate species consists of cell subpopulations that differ in physical characteristics, function, and regulation by endocrine and paracrine factors. The corpus luteum (n = 25) was removed from rhesus monkeys at the mid-luteal phase of the menstrual cycle (Days 7-8 after the surge of luteinizing hormone, LH) and enzymatically dispersed. Freshly dispersed cells were analyzed and sorted on the basis of their forward and 90 degrees light scatter (FLS and 90LS, respectively) properties using an EPICS C flow cytometer. Freshly dispersed and sorted cells were fixed, stained histochemically for the presence of 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD), and measured to determine their diameters. Freshly dispersed (MIX) and sorted cells from corpora lutea during the early (Days 4-5 after the LH surge; n = 4) and mid-luteal phases of the cycle were incubated in vitro and steroid production was assessed. The size distribution of dispersed cells revealed four peaks that corresponded to small (10-15 microns in diameter) 3 beta-HSD-negative, and small, medium (16-20 microns), and large (greater than 20 microns) 3 beta-HSD-positive cells. Analysis of dispersed cells for FLS and 90LS demonstrated two continua (C alpha and C beta). C alpha contained single cells and cell clusters; 99.7 +/- 0.3% (n = 3) of the cells were less than or equal to 15 microns in diameter and 96.7 +/- 0.3% were 3 beta-HSD-negative. C alpha cells produced low levels of progesterone (0.2 +/- 0.1 ng/ml per 5 x 10(4) cells; n = 3) in vitro under basal conditions. C beta consisted of single cells from 10 microns to 40 microns in diameter and contained the lipid-filled and 3 beta-HSD-positive cells. Two regions (R1 and R3) of C beta were defined and their cells separated. In R1, 96 +/- 2% (n = 3) of the cells had diameters of less than or equal to 15 microns, whereas 82 +/- 4% (n = 3) of those in R3 were greater than or equal to 20 microns. Basal progesterone production by R3 cells from early luteal phase of the cycle was 12 times greater than that by R1 cells (n = 3 per group).(ABSTRACT TRUNCATED AT 400 WORDS)     

Morphometric estimation of the numbers of granulosa cells in preovulatory follicles of the ewe

Several lines of evidence suggest that follicular granulosa cells give rise to the large luteal cells of the corpus luteum in the sheep. To further investigate this suggestion, numbers of granulosa cells in preovulatory follicles were estimated by morphometric methods for comparison with a previous estimate of numbers of large luteal cells (9.6 +/- 0.9 x 10(6)). Preovulatory follicles from five Corriedale ewes were obtained after synchronization of the oestrous cycle with the prostaglandin analogue cloprostenol. Morphometry was undertaken using light microscopy of plastic-embedded tissue sectioned at 1 micron. Mitotic index in the membrana granulosa was 0.05 +/- s.e.m. 0.05%. Mean follicular diameter was 6.25 +/- 0.25 mm and there were 7.68 +/- 0.53 x 10(6) granulosa cells per follicle. These results demonstrate a similarity between the number of granulosa cells per follicle and the number of large luteal cells per corpus luteum and thus support the hypothesis that large luteal cells are derived from granulosa cells.     

Progesterone production by monkey luteal cell subpopulations at different stages of the menstrual cycle: changes in agonist responsiveness.

Small (less than or equal to 15 microns diameter) and large (greater than 20 microns diam.) luteal cells of the rhesus monkey have been separated by flow cytometry based on light scatter properties. To determine whether the steroidogenic ability and agonist responsiveness of luteal cell subpopulations vary during the life span of the corpus luteum, small and large cells were obtained at early (Days 3-5), mid (Days 7-8), mid-late (Days 11-12), and late (Days 14-15) luteal phase of the cycle. Cells (n = 4 exp./group) were incubated in Ham's F-10 medium + 0.1% BSA for 3 h at 37 degrees C with or without hCG (100 ng/ml), prostaglandin E2 (PGE2; 14 microM), dibutyryl-cAMP (db-cAMP; 5 mM), or pregnenolone (1 microM). Basal progesterone (P) production by large cells was up to 30-fold that by small cells depending on the stage of the cycle. HCG stimulated (p less than 0.05) P secretion by both small (1.8 +/- 0.2-fold) and large (3.7 +/- 0.7-fold) cells in the early luteal phase. HCG responsiveness declined during the luteal lifespan; P production by small cells was not significantly enhanced by hCG by mid luteal phase, whereas that by large cells was stimulated 1.7 +/- 0.2-fold (p less than 0.05) even at late luteal phase. Cell responses to db-cAMP were similar to those for hCG.(ABSTRACT TRUNCATED AT 250 WORDS)     

Weight, composition, mitosis, cell death and content of progesterone and DNA in the corpus luteum of pregnancy in the ewe

Changes in luteal weight from about Day 20 to near term, and in quantitative histology as assessed by ultrastructural morphometry and light microscopic counts of mitosis and cell death on Days 30, 60, 100 and 142, were studied in 168 pregnant ewes. Luteal weight (mean +/- s.d.) remained constant at 0.56 +/- 0.11 g until Day 120, and fell thereafter to reach 0.31 +/- 0.11 g after Day 140 (P less than 0.01). Up to Day 100, quantitative aspects of the composition of the luteal tissue showed no significant change, and values for volume density, cytoplasmic:nuclear ratio, cell number/mm3 and cell volume were comparable to values previously obtained for corpora lutea (CL) of the cycle. By Day 142 structural evidence of luteal regression was present, but regressive changes were much more marked in some CL than others. Mitosis was seen in a few cells (0.02-0.04%) on all of the days studied, but never in large luteal cells. Cell death was rarely seen up to Day 100, but had increased in incidence by Day 142 (P less than 0.01). Luteal progesterone content, 55.2 +/- 15.9 nmol/g on Day 30, was not significantly changed on Days 60, 100 or 142. It is concluded that (1) structural regression of the CL of pregnancy does not begin until much later than the time (about Day 50) when pregnancy ceases to depend on the CL; (2) structural luteal regression begins before parturition, but its time of onset and/or rate of progression vary widely between animals; and (3) large and small luteal cells remain as distinctive populations throughout pregnancy, and their numbers at all stages can be accounted for by survival of the cells which differentiate during the genesis of the CL.     

Taurine content of isolated rat alveolar type I cells.

1. Rat alveolar type I cells were isolated by enzymatic digestion and purified by centrifugal elutriation and specific surface adsorption. 2. The identity of the harvested cells was confirmed using electronic cell sizing and transmission electron microscopy. 3. Purified cell preparations contained 4.6 +/- 2.3 x 10(6) type I cells/rat lung with a purity of 79 +/- 3%. 4. Isolated type I cells exhibited the following characteristics: mean cell volume = 716 +/- 48 microns 3; diameter = 11.1 +/- 0.7 microns; and cell water content = 0.50 +/- 0.03 microliter/10(6) cells. 5. Taurine content of these alveolar type I cells was measured by HPLC. 6. The intracellular taurine concentration of type I cells was 0.14 +/- 0.07 mM, a value close to that of plasma (0.1 mM).     

Comparison of subpopulations of luteal cells obtained from cyclic and superovulated ewes

Peripheral blood samples were collected daily (Days 1-10 after ovulation) and analysed for progesterone content. Luteal tissue was collected on Day 10 after the LH surge, or Day 10 after hCG injection from cyclic and superovulated ewes, respectively. The tissue was enzymically dispersed and an aliquant was utilized for measurement of cell diameters, and staining for 3 beta-hydroxy-delta 5-steroid dehydrogenase-delta 5, delta 4-isomerase activity (3 beta-HSD). The remaining cell preparation was separated into small (10-22 micron) and large (greater than 22 micron) cell fractions by elutriation. Small and large cell suspensions were incubated (37 degrees C, 2 h) in the presence or absence or ovine LH (100 ng/ml) or dbcAMP (2 mM) and progesterone content of the medium was measured. Superovulation did not affect circulating progesterone concentrations, when expressed per mg luteal tissue recorded; basal progesterone production by small or large luteal cells; the unresponsiveness of large luteal cells to ovine LH or dbcAMP; the ratio of small:large cells recovered by dissociation the mean diameter of total cells; or the mean diameter of large cells. However, the mean cell diameter and LH stimulation of progesterone production by small cells were greater (P less than 0.05) in luteal tissue collected from superovulated than in that from cyclic ewes. These differences appear to be an amplification of basic function. Therefore, we conclude that corpora lutea obtained from superovulated ewes can be used to study functional aspects of small and large cells.     

Changes in the distribution of sizes of ovine luteal cells during the estrous cycle

The ovine corpus luteum is composed of two types of steroidogenic cells, which are referred to as small and large luteal cells. In this study, the size and number of steroidogenic cells were determined in corpora lutea collected on Days 4, 8, 12, and 16 of the estrous cycle. Corpora lutea were dissociated into single-cell suspensions that were stained for 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD) activity, a marker for steroidogenic cells. The size of 3 beta-HSD-positive cells was measured with a Zeiss Videoplan Image Analyzer. On Day 4, most of the 3 beta-HSD-positive cells were less than 18 microns in diameter, the median being 11.2 microns. By Day 8, the number of 3 beta-HSD-positive cells increased 3-fold, and the median diameter increased to 12.8 microns. Although the number of 3 beta-HSD-positive cells was reduced by approximately 50% on Day 16, the median size on Days 12 and 16 was 14.6 and 16.8 microns, respectively. The ratio of large (greater than 18 microns) to small (less than 18 microns) luteal cells was 0.11 +/- 0.03 on Day 4; the ratio increased linearly to 0.67 +/- 0.09 by Day 16. This increase between Days 4 and 12 was attributable to an overall increase in the size of the cells; the increase between Days 12 and 16, however, was due to a loss of small luteal cells. When the experiment was conducted near the end of the breeding season, before animals became anestrous, the median size of the luteal cells did not change at different times of the estrous cycle but remained constant throughout. These data suggest that development of the corpus luteum is associated with an increase in the size and number of steroidogenic luteal cells, and that luteolysis is associated with a preferential loss of small luteal cells.     

Quantitative ultrastructure of the luteal cell of the 16-day-pregnant rat and its relation to progesterone secretion

The ultrastructure of luteal cells of five Day-16 pregnant rats were examined morphometrically to determine the relationship between the quantity of steroidogenic organelles and membranes and reported rates of progesterone secretion (2.3 micrograms/h). Each rat had 11.8 +/- 1.0 corpora lutea (mean +/- s.e.m.) with an average volume of 4.5 +/- 0.1 microliter. There were 210 000 +/- 10 000 luteal cells per CL and the luteal cell cytoplasm was composed of smooth endoplasmic reticulum (18%), mitochondria (10.6%), lipid droplets (8.9%) and granules (0.6%). The surface area of the smooth endoplasmic reticulum was 192 cm2 per CL, and that of the outer and inner mitochondrial membranes was 20 and 34 cm2, respectively. For each square micrometre of these membranes, respectively, 62, 590 and 355 molecules of progesterone would have been secreted per second. The luteal cell appears to secrete its major steroid hormone at a rate 50 times greater than that reported for the Leydig cell of the testis when secretion is expressed in terms of molecules per unit mass of steroidogenic cell or area of steroidogenic membrane.     

A comparative study in twelve mammalian species of volume densities, volumes, and numerical densities of selected testis components, emphasizing those related to the Sertoli cell

Morphometric studies were performed on 12 mammalian species (degu, dog, guinea pig, hamster, human, monkey, mouse, opossum, rabbit, rat, stallion, and woodchuck) to determine volume density percentage (Vv%), volume (V), and numerical density (Nv) of seminiferous tubule components, especially those related to the Sertoli cell, and to make species comparisons. For most species, measurements were taken both from stages where elongate spermatids were deeply embedded within the Sertoli cell and from stages near sperm release where elongate spermatids were in shallow crypts within the Sertoli cell. Montages, prepared from electron micrographs, were used to determine Vv% of Sertoli cell components in seminiferous tubules. Excluding the tubular lumen, the Sertoli cell occupied from a high of 43.1% (woodchuck) to a low of 14.0% (mouse) of the tubular epithelium. There was a strong negative correlation (r = -0.83; P less than 0.005) of volume occupancy of Sertoli cells with sperm production. Nuclear volume, as determined by serial reconstruction using serial thick sections, ranged from a high of 848.4 microns 3 (opossum) to a low of 273.8 microns 3 (degu). There was no correlation (r = 0.02) of nuclear volume with volume occupancy (Vv%) in the tubule. Sertoli cell volume was determined by point-counting morphometry at the electron-microscope level as the product of the nuclear size and points determined over the entire cell divided by points over the nucleus. Sertoli cell V ranged from 2,035.3 microns 3 (degu) to 7,011.6 microns 3 (opossum) and was highly correlated (r = 0.85; P less than 0.001) with nuclear size. However, there was no significant correlation between the Sertoli cell size (V) and volume occupancy (Vv%; r = 0.13) or sperm production (r = -0.21). Stereological estimates of the numerical density (Nv) of Sertoli cells ranged from a high of 101.9 x 10(6) (monkey) to a low of 24.9 x 10(6) (rabbit) cells per cm3 of testicular tissue. There was no correlation of numerical density of Sertoli cells with sperm production (r = 0.002). A negative correlation was, however, observed between the numerical density of the Sertoli cells and the Sertoli cell size (r = -0.79; P less than 0.002). Data from the present study are compared with those previously published. This is the first study to compare Sertoli cell morphological measurements using unbiased sampling techniques. Morphometric data are provided which will serve as a basis for other morphometric studies.     

The presence of leukotriene C4-binding sites in bovine corpora lutea of pregnancy

The presence of binding sites for [3H]leukotriene (LT) C4 in bovine corpora lutea of pregnancy was investigated with quantitative light microscopic autoradiography. Silver grains were found over small (15-20 microns) and large (20-50 microns) luteal cells and arteriolar smooth muscle. Vascular endothelial cells, erythrocytes in arteriolar lumen, and fibroblasts, on the other hand, contained very few or no net grains. The grain distribution over luteal cells and arteriolar smooth muscle was reduced (p less than 0.001) after coincubation with excess unlabeled LTC4 but not with excess unlabeled LTA4, LTB4, LTD4, LTE4, prostaglandin (PG)E2, PGF2 alpha or PGI2. The large luteal cells contained 16.1 net grains per cell, which was 6.4 and 7.0 times the number of specific grains as in small luteal and arteriolar smooth muscle cells, respectively (p less than 0.001). When the net grains were corrected for cell area differences, large luteal cells and arteriole smooth muscle cells contained a similar number of grains-which was two times as many as those found in small luteal cells. These findings suggest that LTC4 can potentially regulate functions of not only luteal cells but also luteal vasculature.     

Origin of different cell types in the bovine corpus luteum as characterized by specific monoclonal antibodies

Specific monoclonal antibodies to granulosa and thecal cell surface antigens were produced and used to determine the contributions of theca and granulosa cells to the bovine corpus luteum (CL). Binding of each antibody was examined on collagenase-dispersed luteal cells from 18 cycling and 14 pregnant heifers by indirect immunofluorescence. The percent binding of the large luteal cells to granulosa antibody (GrAb) declined (P less than 0.01) as the age of the CL advanced: 77 +/- 6, 47.5 +/- 3, and 30 +/- 2 for Days 4-6, 10-12 and 16-18, respectively. Further reduction in binding of GrAb to large cells occurred between 50 and 100 days of pregnancy and no labeling was seen thereafter. Fourteen percent of the small luteal cells were bound by GrAb on Days 4-6 of the cycle, and none were labeled during subsequent stages. In contrast, when thecal antibody (TAb) was used, the proportions of large cells that were labeled increased (P less than 0.01) between Days 4-6 (10 +/- 1.3%) and 10-12 (46 +/- 3%). The percentage of large cells bound by TAb then remained unchanged until midpregnancy, declined as pregnancy advanced, and disappeared during late gestation. A majority of small luteal cells were bound by TAb throughout the estrous cycle: 70 +/- 4%, 69 +/- 3% and 58 +/- 6% at Days 4-6, 10-12, 16-18, respectively. Labeling of small cells by TAb occurred throughout pregnancy but declined (P less than 0.05) as gestation advanced. These studies suggest that the large cells of the early cyclic CL are derived from granulosa cells, while most of the small cells are of thecal origin. Small cells develop into large cells as the age of the CL increases. Granulosa-derived cells disappear during early pregnancy, while cells of thecal origin persist throughout pregnancy.     

收缩活动促进新生大鼠培养心室肌细胞的^3H—亮氨酸...

To determine whether contraction could influence cell growth, the rate of protein synthesis (3H-leucine incorporation) and cell diameter and volume were measured in cultured neonatal rat cardiac myocytes beating spontaneously or arrested by high potassium. In medium supplemented with 10% calf serum, the 3H-leucine incorporation for 24 h in contracting myocytes (CMC) was significantly higher by 14.2% than that in quiescent myocytes (QMC), i.e. 1,229 +/- 29 cpm/10(5) cells vs. 1,076 +/- 60 cpm/10(5) cells (P < 0.01, n = 5 for each group). The cell diameter and cell volume in QMC group were respectively 15.14 +/- 0.42 microns and 1,842 +/- 123 microns3, while in the CMC group the corresponding figures reached to 16.82 +/- 0.64 microns3 and 2,495 +/- 210 microns3, increased by 11.1% and 35.5% respectively (P < 0.01, n = 6 for each group). With prolongation of culture time, the differences in these parameters between CMC and QMC became even more significant. In all these experiments, there was no significant difference in cell number between the two groups (P > 0.05). It is concluded that contraction per se can accelerate protein synthesis and cell growth in neonatal rat ventricular myocardium.     

A quantitative histochemical study of delta 5-3 beta-hydroxysteroid dehydrogenase and succinate dehydrogenase activities in the bovine corpus luteum of pregnancy

In corpora lutea of pregnancy of dairy cows delta 5-3 beta-hydroxysteroid dehydrogenase and succinate dehydrogenase were demonstrated histochemically and evaluated densitometrically. Serum progesterone was determined radioimmunologically. Activities per volume unit of delta 5-3 beta-hydroxysteroid dehydrogenase and succinate dehydrogenase in large and small luteal cells as well as progesterone concentrations, exhibited no typical and correlated pattern during pregnancy. Large luteal cells in regressive tissue regions showed weaker delta 5-3 beta-hydroxysteroid dehydrogenase activities than in maturing or well-developed tissue regions. Succinate dehydrogenase activities of small luteal cells were highest in regressive luteal tissue. The results indicate that structural development of bovine luteal tissue during pregnancy is reflected by corresponding enzyme activities.     

The response of large and small luteal cells from the pregnant rat to substrates and secretagogues

Large (greater than 22 microns) and small (12-21 microns) luteal cells from Day 8 pregnant rats were separated by elutriation after enzyme dissociation. Aliquots of cells were incubated for 4 h at 37 degrees C in Medium 199 alone (control) or with medium containing dibutyryl cyclic adenosine 3', 5'-monophosphate (cAMP) at 0.5 mM or 5 mM; rat luteinizing hormone (LH) at doses of 1, 10, 100, or 1000 ng/ml; 10 micrograms/ml 25-OH-cholesterol; or 10 ng/ml testosterone. Production of progesterone, testosterone, and estradiol was measured by radioimmunoassay. Both cell types showed a similar increase in estradiol synthesis when stimulated with LH (1 microgram/ml) or dibutyryl cAMP (5 mM); however, large luteal cells aromatized exogenous testosterone, whereas small luteal cells did not. Large luteal cells produced increased amounts of progesterone at lower doses of dibutyryl cAMP (0.5 mM) and LH (10 ng/ml), compared to small cells, which required 5 mM dibutyryl cAMP or 1 microgram/ml LH for minimal stimulation. Dibutyryl cAMP (5 mM) also resulted in an increase of testosterone release from small luteal cells. Progesterone synthesis in both cell types was enhanced by 25-OH-cholesterol. These results suggest that the two cell types differ functionally with respect to steroidogenesis during pregnancy, and that the large luteal cells appear to be the primary site of progesterone and estradiol production at this stage of pregnancy.     

Size distribution of ferret luteal cells during pregnancy

Steroidogenic cells in the corpus luteum of the ferret (Mustela putorius) during early (Days 6 and 13) to midpregnancy (Day 24) were characterized using electron microscopy, immunocytochemical localization of neurophysin, and smears of dispersed cells obtained by dissociating luteal cells with collagenase. The latter were stained for 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD) activity, and the diameters of the cells were determined with an ocular micrometer. Very small cells (less than 12 microns) stained negative for 3 beta-HSD, occurred in clumps of 5-50 cells, and were presumed to be primarily endothelial cells. 3 beta-HSD-positive cells covered a wide spectrum of sizes ranging from 14 to 56 microns and did not exist as two discrete populations. The ratio of small (less than 25 microns) to large (greater than 25 microns) cells was 1.86:1.0 on Day 6, with the 17- to 20-microns cell size class predominating. On the day of implantation (Day 13), about 75% of the cells ranged from 26 to 50 microns, with the 29-microns size predominating. By Day 24, the ratio of small-to-large cells had declined to 0.15. Nearly 90% of the cells were in the 26- to 56-microns range, the predominant size being 35 microns. All size classes of luteal cells stained negative for neurophysin on all 3 days of pregnancy studied. Luteal cells obtained on Days 6, 13, and 24 of pregnancy failed to reveal any evidence of mitosis after in vivo or in vitro colchicine treatment. We interpret these results as indicating that the 3 beta-HSD-positive luteal cells of ferrets progressively increase in size as small luteal cells complete their differentiation from granulosa cells and ultimately form larger luteal cells with somewhat different ultrastructural characteristics.     

Effect of rate of change of luteinizing hormone concentration on in-vitro progesterone secretion within rat corpora lutea during differentiation.

Immature rats were injected with pregnant mares' serum gonadotrophin followed by human chorionic gonadotrophin (hCG). Ovaries were removed 0, 2, 5 or 8 days after hCG and either prepared for morphometric analysis or perifused with 0, 5 or 30 ng luteinizing hormone (LH)/min. In a second study, ovaries were removed on Day 2 or 8 and perifused with 0.1 mg 8-br-cyclic adenosine 5'-phosphate/ml (8-br-cAMP). On Day 0, the granulosa cells of the preovulatory follicles were small (53 +/- 0.5 microns2) with a cytoplasmic to nuclear (Cy:Nu) ratio less than or equal to 1.5. By Day 2, corpora lutea (CL) were present and composed of 95% small luteal cells (diameter less than 125 microns2, Cy:Nu greater than or equal to 3.0) and 5% large luteal cells (diameter greater than 125 microns2, Cy:Nu ratio greater than or equal to 3.0). The percentage of large luteal cells increased to 36 +/- 7% by Day 5, suggesting that they are derived from a select population of small luteal cells. Basal progesterone secretion increased from 38 +/- 5 on Day 0 to 1010 +/- 48 pg/mg/ml on Day 8. The rate of 5 ng LH/min stimulated progesterone secretion on Days 0, 2 and 8; 30 ng LH/min stimulated progesterone secretion on Days 0, 2 and 8, but not on Day 5; 8-br-cAMP stimulated progesterone secretion on both Days 2 and 8. These data demonstrate that once granulosa cells are induced to luteinize they lose their capacity to secrete progesterone in response to 5 ng LH/min and do not regain their responsiveness to LH rate until they completely differentiate. The loss of this LH responsiveness appears to be due to an inability to stimulate sufficient intracellular cAMP concentrations, since cAMP stimulates progesterone secretion on both Days 2 and 8.     

Relationships between Leydig cell morphometry and plasma testosterone during postnatal development of the monkey, Macaca fascicularis

In neonates (0 to 3-4 months), the testis contained a mean number of 4.6 X 10(6) Leydig cells representing 4.2 % of its volume; Leydig cell cytoplasm contained 10.2 % of SER. In infants (up to 45 months), Leydig cells regressed but their number increased; their volume density did not change. Leydig cell cytoplasmic volume (454 microns3 ), which was about 2.5-fold less than in neonates (1 119 microns3 ) or adults (1 170 microns3 ), contained only 8.7% of SER. During meiosis stage (38-52 months). Leydig cell numbers and volume density did not vary but the cells reached a maximal size and an amount of SER comparable with that at birth was measured. When spermatogenesis was complete, the Leydig cells represented no more than 0.8% of testis volume, but their number and SER content were significantly increased. Except for a significant decrease when spermatogenesis was completed, Leydig cell lipid content did not change during development, and the volume density of mitochondria did not vary. The mean level of plasma testosterone was 2 ng/ml in neonates and 0.4 ng/ml in infants; it increased to 3 ng/ml during onset of meiosis and reached 10 ng/ml in adults. The profile of testosterone was positively and significantly correlated with the total volume and total number of Leydig cells (P less than 0.01 and P less than 0.02, respectively) and with changes in their cytoplasmic volume (P less than 0.001). Moreover, plasma testosterone levels were positively and significantly correlated with changes in Leydig cell SER content i.e. SER volume density and mean absolute volume per cell (P less than 0.001), total SER in the whole testis (P less than 0.01).