Isolation and characterization of microvascular endothelial cells from developing corpus luteum.

We have isolated and characterized microvascular endothelial cells from the developing rabbit corpus luteum. The isolated cells express Factor VIII-related antigen and angiotensin-converting enzyme, internalize acetylated low-density lipoprotein, and form capillary-like tubules in collagen gel cultures. Of the mitogens tested, only basic fibroblast growth factor stimulated the proliferation of these cells. Transforming growth factor-beta 1 and tumor necrosis factor-alpha strongly inhibited the proliferation of these endothelial cells. Platelet-derived growth factor, epidermal growth factor, insulin-like growth factor-1, histamine, prostaglandins, sex steroids, and interleukin-6 (interferon-beta 2) had no effect on the proliferation of these microvascular endothelial cells from the corpus luteum, whereas interleukin-1 alpha and 1 beta were mildly inhibitory. Endothelial cells are an essential component of corpus luteum physiology. Therefore, the availability of these cells will allow us to investigate the potential interactions between endothelial cells and luteal cells in vitro.     

A quantitative study of changes in the human corpus luteum microvasculature during the menstrual cycle

Endothelial cells are the most abundant cell type in the corpus luteum (CL), and changes in blood vessels have been proposed to play a pivotal role in CL regression. We have studied quantitatively the changes in the human granulosa-luteal microvasculature in CL of various ages: young (Days 17-19 of the cycle), mature (Days 20-24), old (Days 25-27), early regressing (follicular phase of the following cycle), and late regressing (luteal phase of the following cycle). Blood vessels were identified by immunohistochemical staining for the endothelial cell marker CD34. Because of the anisotropy of blood vessels, both vertical and transverse sections of the granulosa-lutein layer (GLL) were used to estimate relative (volume, surface, and length densities) and absolute (mean cross-sectional area) vascular variables. Full luteinization from young to mature CL was accompanied by a 61% increase in the mean cross-sectional area of vascular profiles and a 52% increase in the mean volume of granulosa-lutein cells, as an estimator of changes in the volume of the GLL. In old and early regressing CL, there was a progressive increase in relative structural vascular variables, due to the shrinkage of the GLL, whereas the mean cross-sectional area of capillaries showed a 53% decrease from mature to old CL. Finally, in late regressing CL, there was a decrease in most relative structural variables, in spite of the increasingly shrunken GLL. The decrease in the capillary diameter found at the late luteal phase most likely leads to a decreased blood flow, and early changes in blood vessels could initiate and/or accelerate CL regression.     

Gonadotropin and steroid regulation of matrix metalloproteinases and their endogenous tissue inhibitors in the developed corpus luteum of the rhesus monkey during the menstrual cycle

The factors regulating the dynamic expression of matrix metalloproteinases (MMPs) and their tissue inhibitors (TIMPs) in the primate corpus luteum (CL) during the menstrual cycle are unknown. We hypothesized that LH or progesterone (P) regulate interstitial-collagenase (MMP-1), the gelatinases (MMP-2 and -9), TIMP-1, and TIMP-2 in the CL. Hormone ablation/replacement was performed in rhesus monkeys on Days 9-11 of the luteal phase in five treatment groups (n = 4/group): control (no treatment), antide (GnRH antagonist), antide + LH; antide + LH + trilostane (TRL; 3beta-hydroxysteroid dehydrogenase inhibitor), and antide + LH + TRL + R5020 (nonmetabolizable progestin). On Day 12, the CL was removed and the RNA and protein isolated for real-time polymerase chain reaction and immunoassays, respectively. The MMP-1 mRNA increased 20-fold with antide, whereas LH replacement maintained MMP-1 mRNA at control levels. Likewise, TRL increased MMP-1 mRNA 54-fold, and R5020 prevented this effect. Immunodetectable MMP-1 protein also increased with antide or TRL; these increases were abated with LH or R5020. Gelatinase mRNA and/or protein levels increased with antide (e.g., 3-fold, MMP-2 mRNA), and LH replacement reduced protein levels (e.g., 11-fold, MMP-2). The TRL increased MMP-9, but not MMP-2, expression; however, R5020 replacement had no effect on mRNA or protein levels. The LH treatment increased TIMP-1 and -2 mRNA and TIMP-1 protein expression compared to controls and antide groups, whereas R5020 enhanced only immunodetectable TIMP-1. These data strongly suggest that LH suppresses MMP-1 in the primate CL via P and that it also suppresses gelatinases, either at the mRNA (MMP-2) or protein (MMP-2 and -9) levels, perhaps in part via steroids, including P. In contrast, LH promotes TIMP expression, perhaps via steroids, including P.     

Progestin metabolism in the rhesus monkey corpus luteum

For the purpose of describing the pathway by which estrogens are synthesized in the rhesus monkey ($\text{Macaca}$$\text{mulatta}$) corpus luteum (CL), CL were obtained during the midluteal phase of the menstrual cycle and fragments incubated with equimolar amounts of [7-³H]pregnenolone plus [4-¹⁴C]progesterone. Metabolites including ³H-progesterone, ³H, ¹⁴C-20α-dihydroprogesterone, ³H, ¹⁴C-17-hydroxyprogesterone, ³H-estrone and ³H-estradiol-17β appeared in the medium during the first 20 minutes of incubation, ³H, ¹⁴C-Androstenedione was not consistently noted until after 60 minutes. Despite the fact that the ¹⁴C/³H-17-hydroxyprogesterone ratio quickly approached a constant value in the medium, ¹⁴C-estrogens were not detected in the medium or tissue fragments suggesting that progesterone was not a principal precursor for estrogen synthesis. As evidenced by the observation that the ¹⁴C/³H-progesterone ratio was significantly higher in luteal fragments than the 17-hydroxyprogesterone ratio, 17-hydroxyprogesterone appeared to be synthesized from pregnenolone both by way of progesterone and by another route which did not include progesterone. C₂₁- and C₁₈-Steroids were more concentrated in tissue fragments after 120 minutes of incubation than in the medium indicating that these steroids were sequestered by luteal tissue.     

Localization of androgen receptor in the follicle and corpus luteum of the primate ovary during the menstrual cycle

Ovarian androgens may act locally to modulate follicular and luteal function in various species. This study examined the distribution of androgen receptors within the primate ovary throughout the menstrual cycle. Ovaries were collected from rhesus and cynomolgus monkeys during the early, mid-, and late (n = 3-5 per stage) follicular and luteal phases of the cycle. The tissues were processed for indirect immunocytochemical localization of androgen receptors with a specific monoclonal antibody against human androgen receptor (AN1-15). In addition, ovaries (n = 3) were collected from rhesus monkeys for biochemical detection of androgen receptor using 3H-androgen and AN1-15. Specific immunocytochemical staining, as determined by comparing adjacent tissue sections incubated with either AN1-15 or a nonspecific control antibody, was exclusively nuclear. Androgen receptor was detected in the germinal epithelium and ovarian stroma at all stages of the cycle. The thecal and granulosa cells of growing follicles, and of many but not all atretic follicles, contained androgen receptors. Luteinizing granulosa cells of the periovulatory follicle and luteal cells from the early and midluteal phase stained intensely for androgen receptor. Regressing corpora lutea of the late luteal phase also stained for androgen receptor; however, fully regressed corpora lutea in the early follicular phase of the next cycle did not exhibit receptor staining. Luteal cells that were androgen receptor-positive also stained histochemically for the presence of 3 beta-hydroxysteroid dehydrogenase. Sucrose gradient analysis with radiolabeled androgen demonstrated a shift in the androgen receptor peak in monkey ovarian tissue upon addition of AN1-15, confirming the presence of androgen receptor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Morphological manifestations of the functional activity of the menstrual corpus luteum

A histomorphological investigation of the corpus luteum has been performed in 60 women with an unchanged menstrual cycle. Physiological changes of the corpus luteum are reliably reflected in the karyometry results, in correlation between immature, mature and distrophic luteocytes, their mitotic activity and in total thickness of the parenchymatous layer. The parameters taken into account are united into a total index of the corpus luteum activity, its functional significance is proved when a parallel estimation of microelements content (zinc and copper) is performed in the corpus luteum tissues. The morphometric indices used demonstrate that the menstrual corpus luteum is mainly formed at the expense of a combined hypertrophy of granulous and theca-lutein cells and maturation of the preceding cellular forms. Regressive changes are characterized by a decreasing volume of the nuclei and distrophic changes of luteocytes, which are especially manifested at the end of the menstrual cycle.     

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)     

Inhibition of the monkey corpus luteum with 15-methyl prostaglandins

The corpus luteum inhibiting properties of eighteen 15-methyl prostaglandin analogs were determined in the rhesus monkey during concomitant stimulation of the corpus luteum with chorionic gonadotropin. The methyl ester of (15S)-15-methyl PGF_2^α (15M-PGF_2^α, 12.5 mg/monkey) lowered serum progesterone to 12% of pretreatment values within 24 hours, however progesterone returned to normal limits within 48 hours. Elongation of the top side-chain by two carbons (2a,2b-dihomo-15M-PGF_2^α methyl ester, 13 mg/monkey), substitution of a hydroxymethyl group at carbon 1 (2-decarboxy-2-hydroxymethyl-15M-PGF_2^α, 12 mg/monkey), or the formation of the carbon 1 amide (15M-PGF_2^α amide, 12.5 mg/monkey) improved the inhibitory activity of 15M-PGF_2^α; serum progesterone for these 3 analogs was depressed to 15–30% of pretreatment levels within 24 hours, and did not return to control values. Luteal function was not inhibited (12 or more mg/monkey) when the 15-methyl group was placed in the R configuration, the top side chain was shortened by two carbons, an amino group was substituted for carbon 1, the 5-oxa modification was added, or the 1,9-lactone was formed. Some other modifications of 15M-PGF_2^α were also inactive, although not all were tested at equivalent doses: 2,2-difluoro; 4,5-cis-didehydro; 9,11-dideoxy-9α,11α-dichloro; 11-deoxy; 17-phenyl; 1,15-lactone; and the p-benzamidophenyl ester of 2a,2b-dihomo-15M-PGF_2^α. (15S)-15-Methyl PGE₂ methyl ester (1 mg/monkey) depressed serum progesterone concentrations to 42% of pretreatment values within 24 hours; 2a,2b-dihomo-11-deoxy-(15S)-15-methyl PGE₂ methyl ester was inactive (5 mg/monkey). A corpus luteum inhibiting action of certain 15-methyl prostaglandins can be demonstrated in the rhesus monkey.     

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.     

Endocrine characterization of the menstrual cycle of the stumptailed monkey (Macaca arctoides).

The endocrine characterization of the menstrual cycle of the stumptailed monkey was determined and compared with that of the rhesus monkey. Serum concentrations of luteinizing hormone (LH), estradiol-17beta, and progesterone were determined on a daily basis from 5 monkeys. Differences included: 1) basal and peak concentrations of LH 40% of those in rhesus monkeys, 2) an estraidol peak occurring on the day proceding LH peak, 3) an estradiol peak on the 3rd day after LH surge and representing the highest mean estradiol value during the luteal phase, and 4) absence of the usual periovulatory decline in serum progesterone. Further experimentation is needed to understand the importance of these differences.     

Expression of mRNA and proteins for GnRH I and II and their receptors in primate corpus luteum during menstrual cycle

The differential expression of mRNA and protein of GnRH I, II and their receptors (RI and RII) in the monkey corpus luteum (CL) were measured during different stages of the luteal phase of the menstrual cycle as an initial step towards considering the role and regulation of GnRH (I and II) system during luteinization and luteolysis in primates. RT-PCR confirmed the sequence identity of PCR products and real time PCR quantified specific mRNA expressions. Proteins were localized by immunohistochemistry (IHC). Changes in mRNA expression patterns of GnRH I and II (increased) and GnRH RII (decreased) were maximal at mid-late to late stages, that is, at CL regression, where as GnRH RI was low during the entire luteal phase. However, RT-PCR and IHC studies confirmed the presence of GnRH RI at both mRNA and protein levels, respectively. IHC results showed the presence of GnRH I, II and their receptors in steroidogenic cells (granulose-luteal cells and thecal-luteal cells) across the luteal phase. Hence, GnRH I and II systems may have a role on both luteinization (from early to mid stages of CL) and luteolysis (from mid-late to very-late stages of CL). These novel findings suggest that monkey luteal GnRH system may have a role in fertility regulation in paracrine and/or autocrine manner.     

Expression and regulation of tumor necrosis factor (TNF) and TNF-receptor family members in the macaque corpus luteum during the menstrual cycle

Members of the tumor necrosis factor (TNF)-receptor (R) family may be involved in the tissue remodeling that occurs in the primate corpus luteum (CL) during development and regression. As a first step towards addressing this issue, studies assessed TNF ligand-R expression and regulation in CL collected from monkeys during the early (ECL, Days 3-5), mid (MCL, Days 7-8), mid-late (MLCL, Days 10-11), late (LCL, Days 14-16), and very late (VLCL, menses) luteal phase of the menstrual cycle. CL were also collected after gonadotropin and/or steroid ablation and replacement (with hLH and the progestin R5020) for 3 days at mid-late luteal phase. TNF-alpha, -beta, FAS ligand (FASL), and TNF-R1 mRNA levels were two- to sixfold greater (P < 0.05) at the MLCL or LCL phase as compared to earlier (ECL, MCL). In contrast, TNF-R2 and FAS mRNA levels did not change during the luteal phase. Immunohistochemical staining for TNF-beta, TNF-R1, TNF-R2, FAS, and FASL was observed in luteal cells, whereas only TNF-beta staining was observed in endothelial cells. Several TNF-R components were influenced by LH and/or steroid ablation; notably, steroid ablation reduced (P < 0.05) luteal TNF-alpha, but not TNF-beta, mRNA levels, which was prevented by progestin treatment. In contrast, steroid ablation increased (P < 0.05) luteal cell immunostaining for FAS and FASL, which was reduced by progestin treatment. Thus, several members of the TNF R-ligand family are expressed in the primate CL in an LH- and/or progestin-dependent manner. Peak expression in the late luteal phase may signify a role for the TNF-R system in death receptor-mediated apoptosis during luteolysis.     

Analysis of cell cycle subpopulations from cytometric data

As a result of experimental error, measurements of the DNA content of cells from proliferating populations give rise to histograms in which the G1-phase, S-phase and G2-phase distributions overlap. A new method for distinguishing these subpopulations is proposed, based on a model in which the S-phase subpopulation is made up of a number of uniformly overlapping log-normal curves, whose composite has a rectangular central part and sloping ends. The ratio between certain parameters of the slopes and the height of the rectangle is shown to be closely related to the degree of overlap of the constituents by a defined cubic polynomial. It is then possible to calculate the numbers of cells in each of the three phases of the cell cycle, even when only a few hundred cells have been measured.