The flushing effect and expression of follicle stimulating hormone receptor rariants in sheep.

Hand, Jacqelyn M.

January 1900

Master of Science / Department of Animal Sciences and Industry / Timothy G. Rozell / Timothy G. Rozell / An increase in pre-mating dietary energy positively influences ovulation and lambing rates, and this practice is known as nutritional flushing. The mechanisms of flushing, however, are still unknown. Increasing dietary energy approximately two weeks before breeding likely increases the production of insulin-like growth factor I (IGF-I) within the ovary, which stimulates the synthesis of follicle stimulating hormone receptor (FSHR). Several alternatively spliced transcripts of the FSHR have been identified in sheep. Each variant form is believed to be produced according to the stage of follicle development. This study was carried out to evaluate expression patterns of the FSHR variant forms (FSHR-1, FSHR-2 and FSHR-3) in the sheep ovary in response to different flushing diets. For this experiment, yearling Rambouillet ewes (n=93) were allocated among 6 different energy type treatment diets, either prairie or alfalfa hay based, for at least two weeks in combination with the insertion of a controlled internal drug releasing device (CIDR). Two of the treatment groups had commercially available block supplements provided and two had rolled corn supplemented. Mid-ventral laparotomy was performed on each ewe 3.5 to 4 days after CIDR removal. Follicles 4 mm and greater were aspirated and categorized as either medium (M; 4 to 6 mm) or large (L; > 6 mm). Total RNA was extracted from granulosa cells (GC) and reverse transcribed followed by qPCR of the resulting cDNA using specifically designed primer sets for each variant of the FSHR and for the LH receptor. Changes in live weight were different (P < 0.01) between treatment diets but there were no statistical differences for NEFA concentrations between any of the treatments nor were there differences for body condition (mean = 3.0) or lambing rate. Therefore, it is likely a flushing response did not occur in this study. Expression of FSHR-1was different between M and L follicles (P < 0.01) and tended to be different for ewes fed alfalfa hay (P = 0.05). Overall mean expression of FSHR-3 was greater than expression of FSHR-1 or FSHR-2 (P < 0.01), although there was no difference between M and L follicles, or between treatment diets. The concentration of estradiol in follicular fluid was not different between the treatment diets or follicle sizes nor was expression of lutenizing hormone receptor (LHR), indicating that follicles were similar developmentally. The FSHR-1 form seemed to be the variant most likely to be involved in later stages of follicular development, and is potentially involved in follicle rescue. For all follicles, FSHR-3 was the more highly expressed form of the FSHR and may likely be essential throughout antral follicle development. Further research is required to determine the exact mechanism whereby initial energy status of ewes seems critical for the increased ovulation rate that occurs after energy supplementation (i.e. the flushing response).

Follicle

Nutritional flushing

Sheep

Animal Sciences (0475)

Identification Of Domains Of The Follicle Stimulating Hormone Receptor Involved In Hormone Binding And Signal Transduction

Agrawal, Gaurav

11 1900

The glycoprotein hormones, Luteinizing Hormone (LH), human Chorionic Gonadotropin (hCG), Follicle Stimulating Hormone (FSH) and Thyroid Stimulating Hormone (TSH) are heterodimeric proteins with an identical α-subunit associated noncovalently with the hormone specific β-subunit and play important roles in reproduction and overall physiology of the organism (Pierce & Parsons, 1981). The receptors of these hormones belong to the family of G-protein coupled receptors (GPCR) and have a large extracellular domain (ECD)comprising of 9-10 leucine rich repeats (LRR) followed by a flexible hinge region, a seven helical transmembrane domain (TMD) and a C terminal cytoplasmic tail (Vassart et al, 2004). Despite significant sequence and structural homologies observed between the ECDs of the receptors and the specific β-subunits of the hormones, the hormone-receptor pairs exhibit exquisite specificity with very low cross-reactivity with other members of the family. Several biochemical, immunological and molecular biological tools have been employed to elucidate the structure– function relationship of the hormones and their receptors. These studies also helped in deciphering some of the regions present in both the hormones and the receptors involved in maintaining the specificity of their interaction (Fan & Hendrickson, 2005b; Fox et al, 2001; Wu et al, 1994). However, the complete understanding of the hormone-receptor contact sites and mechanism of receptor activation are still an enigma. Understanding the molecular details of these phenomena can lead to the development of novel strategies of regulating hormone action. Binding of FSH to FSHR occurs in the large extracellular NH2-terminal domain where the participation of the LRRs (amino acids 18-259) is essential to determine the ligand selectivity (Dias & Van Roey, 2001; Fan & Hendrickson, 2005a; Szkudlinski et al, 2002). In fact, mutations in these regions lead to reduction in binding of the agonist to the receptor. It is not known how the signal from the large extracellular domain liganded complex is transmitted to the TMD (amino acids 367-695). It is envisioned that hormone binding to the LRRs leads to series of conformational changes leading activation of the TMD resulting in signal transduction. The recently reported crystal structure of the single chain form of FSH in complex with the leucine rich repeats of the FSHR (amino acids 1-268) (Fan & Hendrickson, 2005b), although provides detailed understanding of the molecular interactions of the LRRs with the hormone, fails to provide any insights into mechanism of receptor activation as the information regarding critical interaction of the hormone with TMD. This structure also did not provide any information on the role of the hinge region (amino acids 259-366) that connects the LRRs to the TMD in hormone binding and activation of the receptor. In the present study an attempt has been made to understand the role of the hinge region in hormone binding and signal transduction. The overall objective of the study is to elucidate the molecular details of the hormone receptor interactions, particularly FSH-FSHR interaction. Antibodies to glycoprotein hormones and their receptors have often provided insights into the mechanism of hormone-receptor interactions and signal transduction. While the TSH receptor antibodies and their effects on the overall physiology have been well documented (Khoo & Bahn, 2007; Rapoport & McLachlan, 2007), reports of such antibodies against FSHR or LHR and their possible effects on the reproductive functions are not available. In the present study, effects of FSHR antibodies with different specificities on FSH-FSHR interactions have been investigated. Antibodies to different regions of rat FSHR, were raised and extensively characterized and their effects of FSH-FSHR interactions and signaling were investigated. It was found that a polyclonal antibody against the hinge of the receptor (RF2 antiserum, amino acids 218-336), while having no significant effect on hormone binding and response could stimulate the receptor by itself bypassing the hormone. This stimulation of FSHR was very specific as this antiserum could not stimulate LHR or TSHR and could be blocked by preincubating the antibody with the antigen. Through competition experiments with different synthetic peptides of human FSHR, a stretch of hinge region corresponding to amino acids 296-331 was identified as the site recognized by the stimulatory antibody. This antibody did not interfere in hormone binding and could also bind to the pre-formed hormone-receptor complex suggesting that the binding site of the antibody may not participate directly in hormone binding. Subsequently the antibody was extensively characterized for its effect of hormone receptor interactions (Chapter 2). Previous studies considered the hinge region to be an inert linker connecting the LRRs to the TMD, a structural entity without any known functional significance (Vlaeminck-Guillem et al, 2002). However, the data with RF2 antibody suggested a direct role of the hinge region in signal transduction. Therefore, a systematic study to dissect the role to hinge region in hormone binding and signal transduction was conducted. Several truncations, deletions, activating and inactivating point mutations in the FSHR were generated to understand the mechanism of receptor activation. Firstly, these mutant receptors were characterized for their ability to translocate to the cell surface when transfected in the cultured mammalian cells. Secondly, affinity of all the mutant receptors for the hormone was determined in order to understand the effect of mutations on hormone binding. Finally, the cAMP response of these mutant receptors to the hormone and the stimulatory antibody was investigated to understand the effects of mutations on signal transduction. The results are described in Chapter 3. The hormone binding analysis and the affinity measurement of the mutant receptors showed that the LRRs are involved in high affinity hormone binding while the hinge region may not contribute to the process. This is in agreement with the crystal structure data which showed that the hormone was bound to the truncated receptor fragment representing only the LRRs (Fan & Hendrickson, 2005b). These binding data also corroborated the earlier data indicating that the antibodies against the hinge region do not interfere in hormone-receptor interactions. Further, the analysis of different N-terminally truncated receptor mutants provided strong evidence indicating that the constraining intramolecular interactions between the extracellular and the transmembrane domains are required to maintain the FSHR in an inactive conformation in the absence of an agonist. The analysis of the constitutive basal activity of the mutant receptors in absence of hormone suggested that certain regions of the extracellular domain had an attenuating effect over the TMDs that prevented constitutive activation of the receptor. This was demonstrated by a marked increase in the basal constitutive activity of the receptor upon the complete removal of its extracellular domain. Detailed analysis of the mutants suggested that LRR portion does not contribute to this attenuating effect, but it is the hinge region that perhaps interacts with the TMDs and dampens its basal constitutive activity. This attenuating effect was further narrowed down to a small stretch of 35 amino acids (296-331) within the hinge region. It was striking that the similar stretch was identified as the binding site of the stimulatory receptor antibody. In pharmacology, an ‘inverse agonist’ is an agent which binds to the receptor and reverses the constitutive activity of receptors. Thus the hinge region of the receptor could be termed as a ‘tethered inverse agonist’ of the TMD, since it is covalently associated with the TMD and their interactions dampen the basal constitutive activity of the receptor. However, careful comparison of the activities of the mutants (receptors harboring deletions and gain-of-function mutations) with maximally stimulated wild-type FSHR indicated that these mutations of the receptor resulted only in partial activation of the serpentine domain suggesting that only the ECD in complex with the hormone is the full agonist of the receptor. Moreover, the hinge region stabilizes the TMD in an inactive conformation and the activating mutations disengage the inhibitory ECD–TMD interactions bringing about partial activation of the receptor. Most interestingly, the deletion of amino acids 296-331 from hFSHR resulted in no further response to the hormone indicating that this part of the receptor is also critical for hormonal activation, perhaps playing a dual role in the attenuation of the basal activity and a direct involvement in the hormonal activation of the receptor. Progressive sequential deletions of ten amino acids from 290 to 329 yielded similar results (high basal cAMP production with concomitant loss of hormone and antibody response) clearly demonstrating that the integrity of this region is absolutely essential for hormonal activation. In conclusion, the study provides a conclusive evidence to show that the hinge region of FSHR, although not involved in primary high affinity hormone binding, plays a critical role in the modulation of the receptor activity in absence, as well as, presence of the hormone. A large array of reproductive abnormalities is associated with malfunctioning of FSHR. To explore the possibility of using the stimulatory antibodies for therapeutic purpose, three inactivating mutations of hFSHR were analyzed. In corroboration with the earlier reports (Doherty et al, 2002; Touraine et al, 1999), the mutants A419T and L601V are incapable of transducing the signal, despite having adequate cell surface expression and wild type affinities for the hormone, mainly because of defective TMD. The RF2 antibody failed to elicit any response from these mutants suggesting that its ability to activate the receptor depends on the status of the TMD. Interestingly, the activating mutant D576G, which showed very high basal cAMP production, could be stimulated by both antibody and the hormone to the nearly wild type levels suggesting that in this mutant the interactions between the hinge region and TMD are similar to that of wild type and higher basal cAMP production could be due to different interactions of the TMD with the G-Proteins. Structure-function studies of glycoprotein hormones and their receptors have been hampered due to low levels of expression of the properly folded proteins in heterologous systems (Chazenbalk & Rapoport, 1995; Hong et al, 1999b; Peterson et al, 2000; Sharma & Catterall, 1995; Thomas & Segaloff, 1994). Previous studies from the laboratory have shown that the Pichiapastoris,which blends the advantages of both bacterial and mammalian expression systems, can be used to hyper-express biologically active hormones (Blanchard et al, 2008; Gadkari et al, 2003; Samaddar et al, 1997). In addition, the same expression system has been used to produce single chain hormone analogs (Roy et al, 2007; Setlur & Dighe, 2007). Further, methodologies for Pichiafermentation and purification of recombinant hormones from the fermentation media have been wellestablished in the laboratory. Chapter 4 describes the work carried out to express, purify and characterize a fully functional hFSHR extracellular domain. Thus a stage is now set to attempt structural studies with the receptor. The results are discussed at the end of each of these chapters and future directions have been discussed at the end of this thesis.

Hormone Receptor

Hormone Binding

Signal Transduction

Hormone-Receptor Interactions

Follicle Stimulating Hormone Receptor

Glycoprotein Hormone Receptor

FSHR Agonistic Antibodies

hFSHR Extracellular Domain

hFSH Receptor Antibody

Biochemistry

Expression of follicle stimulating hormone receptor variants during the sheep estrous cycle

Sullivan, Rachael R.

January 1900

Master of Science / Department of Animal Sciences and Industry / Timothy G. Rozell / Several alternatively-spliced mRNA transcripts of the follicle stimulating hormone receptor (FSHR) have been identified in sheep, including FSHR-1 (G protein-coupled form), FSHR-2 (dominant negative form), and FSHR-3 (growth factor type-1 form). Coupling of the FSHR to signaling pathways which activate different downstream effectors leads to speculation that specific splice variants may be transcribed under differing physiological conditions. This is the first study to correlate expression patterns of FSHR-1, FSHR-2, and FSHR-3 and development of follicles in the mature sheep ovary. In Experiment 1, 8 Suffolk-cross ewes were allowed to come into estrus naturally and were euthanized 24 (n=3), 36 (n=3), and 48 (n=2) hours after the onset of estrus. In Experiment 2, 7 Suffolk-cross ewes received CIDRs for 14 days. At CIDR removal, PMSG (500IU) was administered to treatment ewes (n=3), while controls (n=4) received no PMSG. Ewes were euthanized 24 (n=4; 2 CIDR only, 2 PMSG) or 36 (n=3; 2 CIDR only, 1 PMSG) hours later. All visible follicles were aspirated and pooled according to follicular diameter: small (≤ 2.0 mm), medium (2.1-4.0 mm), large (4.1-6.0 mm), and preovulatory (≥ 6.1 mm). Granulosa cells were separated from follicular fluid by centrifugation. Total RNA was extracted from granulosa cells (GC) and reversed transcribed. The resulting cDNA was subjected to qPCR, using primer sets designed to amplify each variant specifically. For Experiment 1, regardless of time after onset of estrus, relative expression of FSHR-3 exceeded that of both FSHR-1 and FSHR-2 in medium follicles (p < 0.01), and tended to be higher in small follicles (p=0.09). For Experiment 2, treatment with PMSG did not significantly alter expression patterns of FSHR variants (p=0.18). The FSHR-3 was expressed higher than FSHR-2 in all follicle sizes (p < 0.01) and was numerically more highly expressed than FSHR-1, although this difference was not significant (p > 0.11). These experiments show that in addition to the well characterized G protein-coupled form of the FSHR, alternatively spliced variants of the FSHR may participate in follicular dynamics during the first follicular wave of the sheep estrous cycle. Furthermore, these results would indicate that an “alternatively” spliced form of the FSHR (FSHR-3) is the predominant form of the FSHR in the sheep.

Sheep

Estrous cycle

Growth factor type

Pregnant mare serum gonadotropin

Alternative splice variants

Agriculture, General (0473)

Regulated expression of follicle stimulating hormone receptor type III in cancer causing mouse ovarian surface epithelial cells

Zimmerman, Shawn

January 1900

Master of Science / Department of Animal Sciences and Industry / Timothy G. Rozell / Follicle stimulating hormone (FSH) is known as the key hormone capable of causing proliferation of granulosa cells in the ovary. The classical receptor belongs to the G protein-coupled superfamily and is designated FSHR-1. A variant in the FSH receptor has been shown to be functional in mouse ovaries. The variant receptor is designated as FSHR-3, and when bound by FSH activates a pathway that shares similar characteristics to the growth factor type I receptor pathway, with no increase in cAMP. The FSHR-3 variant activates MAPK upon binding to FSH, and causes proliferation of cells on which it is known to be expressed. For example ID8 mouse ovarian surface epithelium cells (MOSEC), a cell line that when introduced in immunocompetent mice causes tumors similar to human ovarian cancer and which also express FSHR-3, proliferated in response to FSH. The present study explored the potential for decreasing expression of FSHR-3 protein. The RNA interference (RNAi) technique was used to insert small inhibitory RNA(siRNA) segments corresponding specifically to the R3 variant of the FSH receptor in ID8 MOSEC. Transfected cells were lysed and FSHR-3 protein was visualized using SDS Page and Western blotting analysis. A reduction in expression of FSHR-3 was observed in two of the transfection groups, with the greatest down-regulation of FSHR-3 being 30.1%. From these preliminary results we conclude that the FSHR-3 is expressed on ID8 cells, and that siRNA may be useful to reduce its expression. Thus, it may be possible to slow the growth of FSH-responsive tumors using siRNA to target the FSHR-3 receptor.

Mouse Ovarian Surface Epithelium Cells

Agriculture, Animal Pathology (0476)

Biology, Animal Physiology (0433)

Health Sciences, Oncology (0992)