Mutations in the luteinizing hormone/chorionic gonadotropin receptors (LH/CGRs), representatives of the G protein-coupled receptor family, have been rapidly identified over the last 20 years. This review aims to compare and analyze the data reported the activating and inactivating mutations of the LH/CGRs between human, rat, equine and fish, specifically (Japanese eel Anguilla japonica). Insights obtained through detailed study of these naturally-occurring mutations provide a further update of structure-function relationship of these receptors. Specifically, we present a variety of data on eel LH/CGR. These results provide important information about LH/CGR function in fish and the regulation of mutations of the highly conserved amino acids in glycoprotein hormone receptors.

The glycoprotein hormone family consists of luteinizing hormone (LH), follicle stimulating hormone (FSH) and thyroid stimulating hormone, which are secreted by the pituitary gland in all mammalian species, and choriogonadotropin (CG), which is secreted by the placenta in primates and equids. The hormones are composed of a common α subunit and a hormone specific β subunit which are non-covalently associated. Recent advances in biotechnology, particularly in the production of recombinant proteins, have provided opportunities to produce sufficient quantities of recombinant fish GTHs using various expression hosts. Japanese eel Anguilla japonica is one of the most important fish species being aquacultured in Japan but is hampered from the fact that this species does not reproduce in captivity. Artificial induction of gonadal maturation has been successful by administration of pituitary extracts or human chorionic gonadotropin, but the understanding the regulatory mechanism of gonadal development moderated by follicle stimulating hormone (FSH) and luteinizing hormone (LH) remains elusive due to lack of suitable amounts of eel gonadotropins (GTHs). In the present study, we produced tethered rec-eel LH and deglycosylated mutants (56, 79 and 56-79 of α subunit; 10 of β-subunit) of Asn-linked oligosaccharides in CHO suspension cells. Luteinizing hormone acts through binding to its specific receptor. Binding of ligand to the receptor activates the adenosine 3',5'-cyclic monophosphate (cAMP) pathway (McFarland et al., 1989; Ji and Ji, 1991a; Rose, 1998) and the inositol 1 phosphate (IP1) secondary messenger systems. After stimulation of eelLH/CG receptor transfected CHO cells with rec-LH wild type (wt) and mutant hormones as a ligand, production of cAMP and IP-1 were evaluated (Cisbio). cAMP IC-50 values by rec-eelLH wt; αΔ56; αΔ79; αΔ56_79 and βΔ10 were 606.2; 374.9; 100.3; 14.2 and 210.9 ng/ml, respectively. IP-1 IC-50 values by rec-eelLH wt; αΔ56; αΔ79; αΔ56.79 and βΔ10 were 28.3; 16.04; 4.3; 2.1 and 3.6ng/ml, respectively too. As seen in both of the second messenger production, general stimulatory pattern is analogous. cAMP and IP-1 stimulation by wild type and αΔ56, as well as αΔ79 and βΔ10 were approximate, but the stimulating effect of double mutant (αΔ56_ 79) was drastically higher. According to the data, deglycosylated eelLH may bind to the receptor with high affinity and cAMP production is gradually increased. Furthermore, receptor activation by tethered rec-eel mutant ligands (FreeStyle CHO-MAX Expression System) will be evaluated with β arrestin recruitment and GPCR internalization for N-linked oligosaccharides’ biological role in activation of eelLH/CGR.

Gonadotropins are heterodimers consisting an alpha chain (Cgα) and a beta chain. Interestingly, presence of complicated LH-β transcripts in rat testis was accidently found; testicular LH-β transcripts were confined in seminiferous tubules to spermatids, and the translated products were localized in the elongated spermatids. We hypothesized that mouse testis has potential to produce the tissue specific LH-β with similar structure to the rat testicular forms. To verify our hypothesis, we examined the adult mouse (ICR) testis using RT-PCR and immunohistochemistry. The PCR revealed the presence of the identical products in the reactions for three LH subunit types. The expected product sizes for mouse Cgα and LH-β known as pituitary type were 224 bp and 503 bp, respectively. The testicular type LH-β products were produced by a primer set based on the rat sequences, with unexpected size of 800 bp. Sequencing revealed that the proximal and distal parts (2-82 and 661- 773 bp, respectively) were homologous to rat testicular LH-β cDNA, and middle part (83-660 bp) was a unique mouse-specific region. Both Cgα and LH-β positive signals were in the round and elongated spermatids and mature sperms, and the LH-β signals were more intense. In conclusion, our study demonstrated that the presence and localization of the LH subunits in mouse testis. Further studies will be needed to understand the precise structure and function of mouse testicular LH.

A recent report demonstrated that in human aging brain after menopause/andropause luteinizing hormone (LH) is localized in the cytoplasm of pyramidal neurons of hippocampus and a significant increase of LH is also detected in the cytoplasm of pyramidal neurons and neurofibrillary tangles of Alzheimer's disease brain compared to age-matched control brain. It was suggested that the decreased steroid hormone production and the resulting LH expression in the neurons vulnerable to Alzheimer's disease pathology may have some relevance to the development of Alzheimer's disease. It is, however, unclear whether the presence of LH in neurons of human aging and Alzheimer's disease brain is due to intracellular LH expression or to LH uptake from extracellular sources, since gonadotropins are known to cross the blood brain barrier. Moreover, there is no report by using the brain of experimental animal that LH is expressed in such neurons as found in the human brain. In the present study, we found that LH immunoreactivity is localized in the pyramidal neurons of cerebral cortex and hippocampus of 12 and 18 months old rats but can not detect any immunoreactivity for LH in the young adult (3-5 months old) rats. To confirm that these LH immunoreactivity results from de novo synthesis in the brain but not the uptake from extracellular space, we performed RT-PCR and found that mRNA for LH is detected in several regions of brain including cerebral cortex and hippocampus. These findings suggest us that LH expression in old rat brain may play an important role in aging process of rat brain.

태반이나 생식소 등 시상하부 이외의 조직에서도 gonadotropin releasing hormone(GnRH)과 그 수용체가 발현되어 조직 특이적인 기능을 담당함은 잘 알려진 사실이다. 최근 GnRH와 그 수용체 유전자가 흰쥐 유선에서도 발현됨이 증명되었고, LH -와 -subunit와 LH 수용체에 대한 전사체 역시 흰쥐 유선에 존재함이 확인되었다 본 연구는 흰쥐 유선 LH의 발현과 유선의 분화과정 간의 상관관계를 조사하기 위해서 생식주기, 임신,

Gonadotropin-releasing hormone (GnRH)과 그 수용체가 흰쥐의 난소, 정소, 자궁, 태 반 그리고 유선 등의 생식기관에서 발현됨이 알려져 있다. 더욱이, 뇌하수체 전엽에 작용하는 GnRH의 표적 산물로 알려진 luteinizing hormone (LH)이 흰쥐 생식소에서도 발현됨이 알려졌는데, 이는 생식소 내에 GnRH-LH로 이루어진 국부 회로 (local circuit)가 존재함을 시사하는 것이다 본 연구는 LH와 그 수용