Chander Parkash Puri

Progesterone receptors: various forms and functions in reproductive tissues.

The unequivocal role of progesterone in a variety of events like ovulation, mammary gland development, establishment and maintenance of pregnancy etc are well established. Also the data are accumulating on its role in male reproductive events. In vertebrates and humans, the biological activity of progesterone is mediated by two progesterone receptor proteins PR-A and PR-B, that arise from the same gene and are the members of nuclear receptor superfamily of transcriptional factors. Several studies have demonstrated that the blockage of progesterone receptor using antiprogestins impairs folliculogenesis, ovulation, implantation and pregnancy. Progesterone receptor (PR), have also been detected in human spermatozoa. However, unlike the conventional PR, sperm PR was localized on the membrane and showed distinct characteristics in terms of its size. There are data to demonstrate the inhibition of progesterone driven functions such as hyperactive motility, acrosome reaction on neutralization of sperm membrane PR with specific antibodies against PR. Further significant decrease in the % of PR positive spermatozoa was observed in infertile cases as compared to the fertile men. This indicated that PR can serve as the marker to define the fertilizing potential of the spermatozoa. Recently we have also shown that the PR is expressed in human testis. This reinforced that this PR protein is an inherent testicular protein and not a secretion of accessory reproductive organs. This review compiles the major observations on the forms of the progesterone receptor in various reproductive tissues.

Protein profiling of human endometrial tissues in the midsecretory and proliferative phases of the menstrual cycle

OBJECTIVE To identify the proteins displaying differential expression in midsecretory phase endometrium as compared with proliferative phase endometrium. DESIGN Prospective study with two groups of women in the midsecretory or proliferative phase. SETTING Clinical research outpatient department. PATIENT(S) Healthy, regularly cycling women of proven fertility. INTERVENTION(S) Collection of endometrial biopsy samples. MAIN OUTCOME MEASURE(S) Image analysis software was used to compare two-dimensional protein maps of midsecretory phase endometrial tissues (MSE) with maps of proliferative phase endometrial tissues (PROE) and midsecretory phase uterine fluids (MSU). Matrix-assisted laser desorption/ionization time of flight in tandem (MALDI-TOF-TOF) analysis was carried out to identify eight proteins that were differentially expressed between the two phases and also to identify the spots that shared similar coordinates in the two-dimensional maps of MSE and MSU. RESULT(S) Densitometry analysis and subsequent MALDI-TOF-TOF analysis revealed up-regulation of calreticulin, the beta chain of fibrinogen, adenylate kinase isoenzyme 5, and transferrin in the PROE and of annexin V, alpha1-antitrypsin, creatine kinase, and peroxidoxin 6 in MSE compared with the other phase. Superimposition of the two-dimensional maps of MSE on those of MSU revealed the presence of heat-shock protein 27, transferrin, and alpha1-antitrypsin precursor in both endometrial tissues and uterine secretions. CONCLUSION(S) Differentially expressed proteins identified in the present study could be of relevance in endowing the endometrium with receptivity.

Effects of an Antiprogestin Onapristone on the Endometrium of Bonnet Monkeys: Morphometric and Ultrastructural Studies

Abstract Our previous studies demonstrated the ability of low doses of antiprogestin ZK 98.299 (onapristone) to inhibit fertility in bonnet monkeys. In the present study cumulative effects of low doses of ZK 98.299 on the endometrial cytoarchitecture of bonnet monkeys were analyzed. Treatment with either the vehicle (n = 3) or onapristone at 2.5 mg (n = 4) or 5.0 mg (n = 3) was initiated on Day 5 of the first menstrual cycle and thereafter repeated every third day for four to seven consecutive cycles. The last treatment cycles were anovulatory in two animals treated with 2.5 mg and all animals treated with 5.0 mg. Endometrial biopsies were collected on Day 8 after the midcycle estradiol peak in ovulatory menstrual cycles and on Day 20 in anovulatory menstrual cycles during the last treatment cycle. Ultrathin sections of the fixed endometrium were stained with toluidine blue for morphometric analysis and uranyl acetate and lead citrate for ultrastructural analysis. The ZK 98.299-treated animals showed a dose-dependent endometrial atrophy as evident by a decrease in the height and diameter of the glands and early signs of compaction in the stroma. Ultrastructural analysis also revealed dose-dependent degenerative changes in the subcellular organelles such as the nucleus, mitochondria, endoplasmic reticulum, lysosomes, and Golgi apparatus. This suggests that long-term treatment with low doses of ZK 98.299 leads to the suppression of estrogen-dependent endometrial proliferation. However, this blockade operates independent of estradiol receptor (ER) and progesterone receptor (PR) concentrations as the expressions of these steroid receptors did not show any significant changes even after prolonged treatment. The study demonstrated an antiestrogenic effect of ZK 98.299 on endometrium after prolonged treatment in bonnet monkeys.

Endometrial modifications during early pregnancy in bonnet monkeys (Macaca radiata)

The present study was undertaken to investigate endometrial modifications that occur before embryo invasion in bonnet monkeys (Macaca radiata). These changes were analysed in luminal epithelium, glandular epithelium and stroma of endometrial functionalis on Day 6 post ovulation from pregnant and non-pregnant animals (n = 4 each) by transmission electron microscopy. Distinct features (i.e. loss of columnar shape by epithelial cells, changes in mitochondrial size and diffused apicolateral gap junctions) were observed in the luminal and glandular epithelium in pregnant animals. Stromal compaction was also observed in pregnant animals. Further, immunogold localisation studies demonstrated significantly higher expression (P < 0.05) of oestrogen receptor alpha, an oestrogen-regulated gene, in the glandular epithelium and stroma of the endometrium in pregnant animals compared with non-pregnant animals. Expression of two other genes known to be regulated by oestradiol, namely beta-actin and cyclo-oxygenase-1, were also significantly higher (P < 0.05) in the endometria of pregnant animals. These studies demonstrate marked changes in the endometrium before embryo invasion in bonnet monkeys. These studies also indicate altered oestrogenic activity in the uterine milieu before embryo invasion.

Differential expression of calreticulin, a reticuloplasmin in primate endometrium

BACKGROUND To our knowledge, there are no data on hormonal regulation of reticuloplasmins in primate endometrium. We report the presence and modulation of expression of three reticuloplasmins in endometrium of bonnet monkeys (Macaca radiata). METHODS Receptive and non-receptive endometria obtained from vehicle-treated control and onapristone (antiprogestin)-treated animals, respectively, were compared for differentially expressed proteins by two-dimensional proteomics. Mass spectrometric analysis annotated two such proteins as calreticulin and protein disulfide-isomerase (PDI), known to be molecular chaperones in endoplasmic reticulum. We then investigated if endoplasmin, another reticuloplasmin is also differentially expressed. Expression of these reticuloplasmins was also investigated in the endometriuma during pregnancy in bonnet monkeys. Samples were analysed by immunohistochemistry and western blot (calreticulin in human endometrium), and calreticulin transcript levels in Ishikawa cell line were assessed by real time PCR. RESULTS Immunohistochemical analysis of the functionalis region of non-receptive endometria in monkeys revealed higher expression of (i) calreticulin (P < 0.01) in glandular epithelium and (ii) PDI in stroma (P < 0.0001), but no change in endoplasmin in stroma or glands, compared with receptive endometria. Protein level of all three reticuloplasmins in the stromal region of endometrial functionalis was higher in pregnant than non-pregnant animals (P < 0.05). Human endometrial calreticulin protein was higher in the estrogen-dominant (proliferative) phase than progesterone-dominant (mid-secretory) phase of the cycle. Calreticulin mRNA in Ishikawa cells is up-regulated by estrogen (P < 0.05 versus control), with a trend towards down-regulation by progesterone. CONCLUSION Our data suggest that endometrial reticuloplasmins are regulated by hormones and embryonic stimuli in a cell-type specific manner. These novel data open up new lines of investigation for elucidating the mechanisms by which hormones or embryonic stimuli influence the sub-cellular physiology of endometrium.

Expression of Endometrial Protein Kinase A During Early Pregnancy in Bonnet Monkeys (Macaca radiata)

Embryo-induced signaling pathways are considered to be important for initiation and sustenance of pregnancy. However many of these pathways remain to be deciphered in primates. In the present study, differential display RT-PCR was used to identify genes or gene fragments that are differentially expressed in endometrium of bonnet monkeys (Macaca radiata) on Day 6 of pregnancy. Of several fragments found to be differentially expressed, a fragment of 567 base pair (named GG1) was characterized in detail. GG1 was highly represented in endometrium of pregnant animals compared with that of nonpregnant animals. Sequencing analysis revealed homology of this fragment to exons 7, 8, 9, and 10 and surprisingly to intron 6 of cAMP-dependent protein kinase A (PKA) regulatory type I alpha (tissue-specific extinguisher 1) (PRKAR1A). The increased expression of this fragment in gestational endometrium was confirmed by quantitative PCR studies. Two transcripts of 3.0 kilobase (kb) and 1.5 kb were detected in Northern blot probed with labeled GG1. Protein expressions of alpha regulatory (PRKAR1A) and alpha catalytic (PRKCA) subunits of PKA were also higher in gestational endometrium compared with that in nongestational endometrium. Further in vitro studies using human endometrial explants demonstrated regulation of PRKAR1A (or GG1) and prostaglandin-endoperoxide synthase 2 or cyclooxygenase 2 (PTGS2) by estradiol. This is the first study to date on the differential expression of PKA in primate endometrium during early pregnancy and its in vitro regulation by estradiol.