Only a few RFamide peptides have been identified in mammals, although they have been abundantly found in invertebrates. Here we report the identification of a human gene that encodes at least three RFamide-related peptides, hRFRP-1-3. Cells transfected with a seven-transmembrane-domain receptor, OT7T022, specifically respond to synthetic hRFRP-1 and hRFRP-3 but not to hRFRP-2. RFRP and OT7T022 mRNAs are expressed in particular regions of the rat hypothalamus, and intracerebroventricular administration of hRFRP-1 increases prolactin secretion in rats. Our results indicate that a variety of RFamide-related peptides may exist and function in mammals.
Relaxin 3/INSL 7 has recently been identified as a new member of the insulin/relaxin superfamily. Although it was reported to be dominantly expressed in the brain, its detailed distribution and function in the central nervous system are still obscure. In the present study we demonstrated that in the rat relaxin 3 was mainly expressed in neurons of the nucleus incertus (NI) of the median dorsal tegmental pons. Other relaxin 3-expressing neurons were scattered in the pontine raphe nucleus, the periaqueductal gray and dorsal area to the substantia nigra in the midbrain reticular formation. Relaxin 3-immunoreactive fibers projected particularly densely in the septum, hippocampus, lateral hypothalamus and intergeniculate leaflet of the thalamus. Ultrastructural examination revealed that relaxin 3 was localized in the dense-cored vesicles in the perikarya and was also observed in the synaptic terminals of axons. As almost all relaxin 3-containing neurons express corticotropin-releasing factor (CRF) type 1 receptor in the NI, we examined the response of relaxin 3 neurons to intracerebroventricular administration of CRF; 65% of relaxin 3 neurons expressed c-Fos 2 h after intracerebroventricular administration of 1 microg CRF. We then confirmed that c-Fos was induced in 60% of relaxin 3 neurons in the NI and the expression of relaxin 3 mRNA increased significantly in the NI after water-restraint stress. Collectively, these results suggest that relaxin 3 produced in the NI is released from nerve endings and is involved in the regulation of the stress response.
We have recently identified RFamide-related peptide (RFRP) gene that would encode three peptides (i.e., RFRP-1, -2, and -3) in human and bovine, and demonstrated that synthetic RFRP-1 and -3 act as specific agonists for a G protein-coupled receptor OT7T022. However, molecular characteristics and tissue distribution of endogenous RFRPs have not been determined yet. In this study, we prepared a monoclonal antibody for the C-terminal portion of rat RFRP-1. As this antibody could recognize a consensus sequence among the C-terminal portions of rat, human, and bovine RFRP-1, we purified endogenous RFRP-1 from bovine hypothalamus on the basis of immunoreactivity to the antibody. The purified bovine endogenous RFRP-1 was found to have 35-amino-acid length that corresponds to 37-amino-acid length in human and rat. We subsequently constructed a sandwich enzyme immunoassay using the monoclonal antibody and a polyclonal antibody for the N-terminal portion of rat RFRP-1, and analyzed the tissue distribution of endogenous RFRP-1 in rats. Significant levels of RFRP-1 were detected only in the central nervous system, and the highest concentration of RFRP-1 was detected in the hypothalamus. RFRP-1-positive nerve cells were detected in the rat hypothalamus by immunohistochemical analyses using the monoclonal antibody. In culture, RFRP-1 lowered cAMP production in Chinese hamster ovary cells expressing OT7T022 and it was abolished by pre-treatment with pertussis toxin, suggesting that OT7T022 couples G(i)/G(o) in the signal transduction pathway.
Circadian clock genes are regulated through a transcriptional-translational feedback loop. Alterations of the chromatin structure by histone acetyltransferases and histone deacetylases (HDACs) are commonly implicated in the regulation of gene transcription. However, little is known about the transcriptional regulation of mammalian clock genes by chromatin modification. Here, we show that the state of acetylated histones fluctuated in parallel with the rhythm of mouse Per1 (mPer1) or mPer2 expression in fibroblast cells and liver. Mouse CRY1 (mCRY1) repressed transcription with HDACs and mSin3B, which was relieved by the HDAC inhibitor trichostatin A (TSA). In turn, TSA induced endogenous mPer1 expression as well as the acetylation of histones H3 and H4, which interacted with the mPer1 promoter region in fibroblast cells. Moreover, a light pulse stimulated rapid histone acetylation associated with the promoters of mPer1 or mPer2 in the suprachiasmatic nucleus (SCN) and the binding of phospho-CREB in the CRE of mPer1. We also showed that TSA administration into the lateral ventricle induced mPer1 and mPer2 expression in the SCN. Taken together, these data indicate that the rhythmic transcription and light induction of clock genes are regulated by histone acetylation and deacetylation.Most organisms have physiological and behavioral rhythms, so-called circadian rhythms, having an intrinsic period of approximately 24 h. The circadian clock is an endogenous oscillator that controls daily physiological and behavioral rhythms. In mammals, molecular oscillators exist in the suprachiasmatic nucleus (SCN) of the brain, a master clock (19,21,31), and also in peripheral tissues (24,48). Even in fibroblast cell lines, clock genes are induced rhythmically under certain conditions (1, 5, 47). The core circadian system consists of an interacting transcriptional-translational feedback loop of clock genes in an individual cell (11, 31). A negative feedback loop involves the regulation of two period genes (Per1 and -2) and two cryptochrome genes (Cry1 and -2) (22, 33). The rhythmic transcription is driven by the basic helix-loop-helix-PAS protein (CLOCK-BMAL1) complex, which binds the E-box on the mPer1 and mPer2 genes (14). This CLOCK-BMAL1-mediated transcription is, in turn, repressed by the translated products of clock genes, such as the mPER and mCRY protein complex, which translocate to the nucleus (14,17,22,33).On the other hand, rapid inductions of mPer1 and mPer2 are also involved in phase resetting of the circadian rhythm (3,4,34). A light pulse during subjective night induced rapid increases in mPer1 and mPer2 expression in the SCN and caused a behavioral phase shift. Thus, mPer1 and mPer2 are considered to work both in the generation of circadian rhythm and in light entrainment.It has recently become clear that histone modification plays an important role when genes are transcribed in the nucleus and basic domains in the histone N-terminal are modified, such as by phosphorylation, acetylation, methylation, or ubiquityla...
SUMMARYThe internal organs of vertebrates show distinctive left-right asymmetry. Leftward extracellular fluid flow at the node (nodal flow), which is generated by the rotational movement of node cilia, is essential for left-right patterning in the mouse and other vertebrates. However, the identity of the pathways by which nodal flow is interpreted remains controversial as the molecular sensors of this process are unknown. In the current study, we show that the medaka left-right mutant abecobe (abc) is defective for left-right asymmetric expression of southpaw, lefty and charon, but not for nodal flow. We identify the abc gene as pkd1l1, the expression of which is confined to Kupffer's vesicle (KV, an organ equivalent to the node). Pkd1l1 can interact and interdependently colocalize with Pkd2 at the cilia in KV. We further demonstrate that all KV cilia contain Pkd1l1 and Pkd2 and left-right dynein, and that they are motile. These results suggest that Pkd1l1 and Pkd2 form a complex that functions as the nodal flow sensor in the motile cilia of the medaka KV. We propose a new model for the role of cilia in left-right patterning in which the KV cilia have a dual function: to generate nodal flow and to interpret it through Pkd1l1-Pkd2 complexes.
Kisspeptin is a family of neuropeptides and the natural ligands of G protein-coupled receptor (GPR)-54. Kisspeptin/GPR-54 system is known to play a pivotal role in puberty onset and in the regulation of reproductive functions. To clarify the postnatal ontogeny of kisspeptin neurons in rat hypothalamus, we analyzed the expression patterns of kisspeptin mRNA from neonate to adult by in situ hybridization. In anteroventral periventricular nucleus (AVPV), kisspeptin mRNA were first detected at postnatal day (PND) 7 and postnatal week 3 in males and females, respectively, and the number of kisspeptin mRNA-expressing neurons increased during development in both sexes. In the arcuate nucleus (ARC), kisspeptin mRNA was present from PND3. In males, the number of kisspeptin mRNA-expressing neurons gradually increased during development. In females, the number of kisspeptin mRNA-expressing neurons in neonates was greater than in males; it significantly decreased at juvenile stages and then increased toward adulthood. These results indicate that the increase in kisspeptin mRNA expression in ARC across puberty might be involved in the onset of puberty. We also demonstrate that the kisspeptin mRNA-expressing neurons in ARC appear earlier than those in AVPV and show clear sex differences in their numbers during neonatal period.
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