Masa-aki Hattori

Isoelectric focusing and gel filtration studies on the heterogeneity of avian pituitary luteinizing hormone

Abstract The heterogeneity of avian pituitary LH was shown by means of isoelectric focusing and gel filtration studies coupled with radioimmunoassay. The immunoreactive LH (IR-LH) in anterior pituitary extracts from male quail and chickens contained four components with isoelectric points of 9.8 (component I), 9.4 (component II), 9.0 (component III), and 8.5 (component IV). All IR-LH components possessed the ability to bind to rat ovarian LH receptors but the estimates of potency obtained by the radioreceptor assay did not agree with those from radioimmunoassay. Sephadex G-100 gel filtration of the four individual components obtained from chicken pituitary LH indicated the presence of an LH with a molecular weight of 23,500–25,000 together with a component having double the molecular weight. The components differed in the relative amounts of the larger molecular weight component. The large component was also found in a gel filtration of the extract of chicken anterior pituitary glands. The amounts of the various components were changed in male quail by photostimulation. After 21 days of photostimulation, the amounts of all the components, especially of component I, had increased markedly.

Sialic acid moiety is responsible for the charge heterogeneity and the biological potency of rat lutropin

To elucidate a possible role of sialic acid moiety in the electrical heterogeneity of rat pituitary lutropin, seven components separated were individually treated with neuraminidase. Some intermediates with isoelectric points corresponding to the native components were concomitantly seen at the serial stages of the enzyme treatment. All the treated components showed an isoelectric point of about 10.0 which was the same to the isoelectric point of one of the seven components. Desialylation of the components with less biological activity caused enhancement of the in vitro cyclic AMP producing- and testosterone producing-activities as well as the binding activity to the receptor. It is concluded that the number of sialic acid moiety in lutropin is responsible for the charge heterogeneity and the biological potency of the hormone.

Gonadotropic regulation of circadian clockwork in rat granulosa cells

The circadian clock is responsible for the generation of circadian rhythms in hormonal secretion and metabolism. These peripheral clocks could be reset by various cues in order to adapt to environmental variations. The ovary can be characterized as having highly dynamic physiology regulated by gonadotropins. Here, we aimed to address the status of circadian clock in the ovary, and to explore how gonadotropins could regulate clockwork in granulosa cells (GCs). To this end, we mainly utilized the immunohistochemistry, RT-PCR, and real-time monitoring of gene expression methods. PER1 protein was constantly abundant across the daily cycle in the GCs of immature ovaries. In contrast, PER1 protein level was obviously cyclic through the circadian cycle in the luteal cells of pubertal ovaries. In addition, both FSH and LH induced Per1 expression in cultured immature and mature GCs, respectively. The promoter analysis revealed that the Per1 expression was mediated by the cAMP response element binding protein. In cultured transgenic GCs, both FSH and LH also induced the circadian oscillation of Per2. However, the Per2 oscillation promoted by FSH quickly dampened within only one cycle, whereas the Per2 oscillation promoted by LH was persistently maintained. Collectively, these findings strongly suggest that both FSH and LH play an important role in regulating circadian clock in the ovary; however, they might exert differential actions on the clockwork in vivo due to each specific role within ovarian physiology.

Up-regulation of Per1 expression by estradiol and progesterone in the rat uterus.

It has been established that estrogen can alter circadian rhythms in behavior and endocrine physiology in rodents. The uterus is a reproductive organ that is critically dependent on regulation by ovarian steroids. Here, we examined the expression of Per1 in different compartments of the uterus, and explored whether the ovarian steroids could regulate Per1 expression employing ovariectomized rat uterus. RT-PCR analysis showed that Per1 was cyclically expressed in the uterus. As revealed by in situ hybridization, the staining intensity of Per1 mRNA was stronger at ZT 8 than at ZT 0 in the uterine luminal epithelium (LE), stroma (S), and myometrium (M) compartments, but was not changed in the glandular epithelium (GE). Both in situ hybridization and immunofluorescence analyses revealed that estradiol (E(2)) administration induced high expression of Per1 in the LE, GE, and M, and less expression in the S compartment. Progesterone (P(4)) treatment resulted in an obvious enhancement of Per1 expression in the LE, GE, and S, but unchanged in the M compartment. Furthermore, the E(2)- and P(4)-activated Per1 expression was significantly repressed by their respective antagonists, ICI182 780 and RU486. These findings were further supported by RT-PCR analysis of Per1 expression in cultured uterine stromal cells. Collectively, the present data indicate that E(2) and P(4) might be involved in modification of circadian rhythm via direct regulation of the expression of clock genes.

Molecular cloning and expression of dead end homologue in chicken primordial germ cells

Chicken primordial germ cells (PGCs) dynamically migrate towards the prospective gonadal area through the germinal crescent region and bloodstream at early embryonic stages. To date, chicken PGCs have been mainly identified by histochemical and immunohistochemical methods or by their morphological characteristics. However, their origin, migration and differentiation are not fully understood because of the lack of specific PGC molecular markers. Here, we have isolated the chicken dead end homologue (CDH) in order to clone its full-length cDNA with an open reading frame of 329 amino acids. The RNA-binding motif present in CDH at amino acids 54–133 was highly homologous to those in the dead end proteins of human, mouse and Xenopus. The temporal and spatial distribution of PGCs was also investigated by in situ hybridization (ISH) on whole-mount embryos with CDH cRNA as a probe. Chicken embryos from stage X to stage 20 were subjected to ISH. The hybridized samples were then sectioned to analyse the translocation of PGCs. CDH-positive cells could be counted from stage X to stage 4, with minimally 30 cells at the blastderm and approximately 260 cells at the germinal crescent. Thus, specific expression of CDH mRNA has been established in chicken PGCs located at the blastderm, germinal crescent and prospective gonadal area by ISH and reverse transcription/polymerase chain reaction. We conclude that isolated CDH is specifically expressed in chicken PGCs during embryogenesis.

Alterations of circadian clockworks during differentiation and apoptosis of rat ovarian cells

Ovarian development is related to cell proliferation, differentiation, and apoptosis of granulosa cells and luteal cells under the control of various modulators, including follicle-stimulating hormone (FSH), luteinizing hormone (LH), and growth factors. In the present study, the expression of clock genes and the related regulation mechanism were analyzed in different ovarian cell types during differentiation and apoptosis. The authors focused on the circadian expression of Per2 as a core clock gene for the maintenance of circadian rhythms. By using a real-time monitoring system of the Per2 promoter activity, the circadian oscillation was analyzed in the granulosa and luteal cells from preantral follicles, antral follicles, and corpora lutea of immature Per2 promoter–destabilized luciferase transgenic rats that were primed with diethylstilbestrol, equine chorionic gonadotropin (eCG), and/or human CG. In addition, transcript levels of Per2, Bmal1, Clock, and Nampt were quantified by quantitative polymerase chain reaction (qPCR). Immunohistochemical studies revealed strong circadian rhythmicity of PER2 protein in the luteal cells, but apparently little rhythmicity in granulosa cells of both preantral and antral follicles. In vitro monitoring of promoter activity showed generation of several oscillations in luteal cells after exposure to dexamethasone (DXM), whereas oscillatory amplitudes of immature and mature granulosa cells were rapidly attenuating. The circadian rhythm of the Bmal1 transcript levels, but not the Per2 transcript, was very weak in the granulosa cells, as compared with that in luteal cells. Granulosa cells gained a strong circadian rhythm ability of the Per2 promoter activity after stimulation with FSH for 3 days. In contrast, LH had little effect on the circadian rhythm before stimulation of granulosa cells with FSH, probably owing to lack of LH receptor. In luteal cells, induction of apoptosis by inhibiting progesterone synthesis resulted in deregulation of Per2 circadian oscillation. Transcript levels of Bmal1 and Clock, but not Per2 and Nampt, were significantly decreased in apoptotic luteal cells. The Bmal1 transcript level was particularly reduced. Consequently, these results strongly suggest the circadian clockwork alters in ovarian cells during follicular development, luteinization, and apoptosis, and expression of Bmal1 may be related to the switch-on and switch-off of the circadian oscillation. (Author correspondence: mhattori@agr.kyushu-u.ac.jp)

Downregulation of core clock gene Bmal1 attenuates expression of progesterone and prostaglandin biosynthesis-related genes in rat luteinizing granulosa cells

Ovarian circadian oscillators have been implicated in the reproductive processes of mammals. However, there are few reports regarding the detection of ovarian clock-controlled genes (CCGs). The present study was designed to unravel the mechanisms through which CCG ovarian circadian oscillators regulate fertility, primarily using quantitative RT-PCR and RNA interference against Bmal1 in rat granulosa cells. Mature granulosa cells were prepared from mouse Per2-destabilized luciferase (dLuc) reporter gene transgenic rats. A real-time monitoring system of Per2 promoter activity was employed to detect Per2-dLuc oscillations. The cells exposed to luteinizing hormone (LH) displayed clear Per2-dLuc oscillations and a rhythmic expression of clock genes (Bmal1, Per1, Per2, Rev-erbα, and Dbp). Meanwhile, the examined ovarian genes (Star, Cyp19a1, Cyp11a1, Ptgs2, Lhcgr, and p53) showed rhythmic transcript profiles except for Hsd3b2, indicating that these rhythmic expression genes may be CCGs. Notably, Bmal1 small interfering (si)RNA treatment significantly decreased both the amplitude of Per2-dLuc oscillations and Bmal1 mRNA levels compared with nonsilencing RNA treatment in luteinizing granulosa cells. Depletion of Bmal1 by siRNA decreased the transcript levels of clock genes (Per1, Per2, Rev-erbα, and Dbp) and examined ovarian genes (Star, Cyp19a1, Cyp11a1, Ptgs2, Hsd3b2, and Lhcgr). Accordingly, knockdown of Bmal1 also inhibited the synthesis of progesterone and prostaglandin E2, which are associated with crucial reproductive processes. Collectively, these data suggest that ovarian circadian oscillators regulate the synthesis of steroid hormones and prostaglandins through ovarian-specific CCGs in response to LH stimuli. The present study provides new insights into the physiologic significance of Bmal1 related to fertility in ovarian circadian oscillators.

Down-regulation of circadian clock gene period 2 in uterine endometrial stromal cells of pregnant rats during decidualization

Circadian rhythms are modulated in a variety of peripheral tissues, including in the uterus where endometrial stromal cells (UESCs) undergo proliferation and differentiation (decidualization) during gestation. Here the authors focused on circadian rhythms in UESCs during implantation and decidualization in rodents. As revealed by analyses of cultured UESCs from pregnant Per2 promoter–dLuc transgenic rats, Per2 oscillation of ∼24 h was observed in response to dexamethasone. Per2 oscillation was enhanced in UESCs during implantation, whereas they were attenuated during decidualization. In vivo studies showed that PER2 protein in the uteri displayed a peak at zeitberger time 4 (ZT 4) (day 4.50 of gestation) and a trough at ZT 12 (day 4.83), indicating its circadian rhythmicity. Conversely, no significant circadian rhythm of the PER2 protein was observed during decidualization. Fluorescent immunohistochemical studies also supported circadian rhythmicity of the PER2 protein in its intracellular distribution. In accordance with Per2 mRNA expression, a circadian rhythm of vascular endothelial growth factor (Vegf) gene expression, having several E-box or E-box–like sites at the upstream of the transcription start site, was observed during implantation, showing a peak at ZT 0 and a trough at ZT 12. In contrast, Vegf mRNA expression displayed no circadian rhythm during decidualization. Collectively, the present results prove that Per2 oscillation is down-regulated in UESCs during decidualization. It is strongly suggested that cellular differentiation in UESCs interferes with circadian clockwork. (Author correspondence: mhattori@agr.kyushu-u.ac.jp)

Contribution of FSH and triiodothyronine to the development of circadian clocks during granulosa cell maturation

The involvement of FSH and triiodothyronine (T(3)) in circadian clocks was investigated using immature granulosa cells of ovaries during the progress of cell maturation. Granulosa cells were prepared from preantral follicles of mouse Period2 (Per2)-dLuc reporter gene transgenic rats injected subcutaneously with the synthetic nonsteroidal estrogen diethylstilbestrol. Analysis of the cellular clock of the immature granulosa cells was performed partly using a serum-free culture system. Several bioluminescence oscillations of Per2-dLuc promoter activity were generated in the presence of FSH + fetal bovine serum, but not in the presence of either FSH or serum. As revealed by bioluminescence recording and analysis of clock gene expression, the granulosa cells lack the functional cellular clock at the immature stage, although Lhr was greatly expressed during the period of cell maturation. The granulosa cells gained a strong circadian rhythm of bioluminescence during stimulation with FSH, whereas LH reset the cellular clock of matured granulosa cells. During strong circadian rhythms of clock genes, the Star gene showed significant expression in matured granulosa cells. In contrast, T(3) showed an inhibitory effect on the development of the functional cellular clock during the period of cell maturation. These results indicate that FSH provides a cue for the development of the functional cellular clock of the immature granulosa cells, and T(3) blocks the development of the cellular clock.

Difference of Japanese quail LH-RF from mammalian LH-RF revealed by biological and immunochemical studies

Abstract When rat and Japanese quail hypothalamic extracts (HE) were prepared by acid or acid-ethanol extraction, LH-releasing activity of quail HE on rat pituitary glands was very low as compared with that of rat HE, both in vitro and in vivo . However, quail HE was higher in activity than was rat HE when tested on quail pituitary glands in vitro . The inhibition curve of rat HE was parallel to that of synthetic LH-RH in a radioimmunoassay system with the antisynthetic LH-RH serum, while quail HE did not show any significant cross-reaction. The antisynthetic LH-RH serum did not inhibit the biological activity of quail HE in vitro . These observations indicated a species-specificity among these LH-RFs. When quail hypothalami were extracted with neutral phosphate-buffered saline, a cross-reactive substance was found, though the inhibition curve was not parallel to that of synthetic LH-RH. Immunohistochemical observation using the same antisynthetic LH-RH serum and peroxidase-labeled anti-rabbit γ-globulin serum indicated the presence of immunoreactive substance(s) in the quail hypothalamus. The relationship between the immunoreactive substance(s) and cross-reaction in radioimmunoassay is also discussed.