Cloning and analysis of the cDNA encoding the horse and donkey luteinizing hormone beta-subunits.

The coding regions of the horse (Equus caballus) and donkey (E. asinus) luteinizing hormone (LH) beta-subunit transcripts were cloned from pituitary gland RNA, in order to investigate their relationships to the corresponding equine chorionic gonadotropin (CG) beta-subunits and to further understand the unusual receptor-binding properties of equine LH and CG. The horse and donkey LH beta-subunit sequences were very similar (97% identity at the nucleotide (nt) level; 93% at the amino acid (aa) level), confirming their very close evolutionary linkage and also indicating that the C-terminal extension in both subunits occurred prior to the divergence of horse and donkeys. Furthermore, sequence comparisons and Southern blot analysis confirmed that in donkeys, as in horses, the pituitary (LH) and placental (CG) beta-subunits are almost certainly derived from a single gene. This contrasts with primates which have a single LH beta gene expressed in the pituitary and a family of separate CG beta genes that are expressed in the placenta. The deduced aa sequences also revealed several differences between the horse and donkey LH/CG beta-subunits that could explain their differences in biological activity. In addition, the study confirmed that the donkey subunit contains an additional Cys residue that is not present in other gonadotropin beta-subunits.

Cloning and analysis of the cDNA for the common alpha-subunit of the donkey pituitary glycoprotein hormones.

Reverse transcription-PCR was used to clone the coding region of the donkey (Equus asinus) glycoprotein hormone alpha-subunit transcript from pituitary gland RNA. The donkey alpha-subunit sequence demonstrated considerable identity with the horse (97% at the nucleotide level), confirming the very close evolutionary linkage between these two species. The predicted amino acid sequence revealed that the donkey alpha-subunit has the same unusual C-terminus as the horse alpha-subunit, when compared with all other mammalian alpha-subunits, including a Tyr-His transposition between positions 87 and 93 and Ile instead of Ser as the C-terminal residue. Since recent evidence indicates important involvement of this region of the alpha-subunit in receptor binding, these findings provide a possible partial explanation for the unique biological properties of the equine gonadotrophins.

Expression of an in vitro biologically active equine LH/CG without C-terminal peptide (CTP) and/or beta26-110 disulphide bridge.

The C-terminal region of the beta subunit of the human chorionic gonadotrophin (hCG) is implied in heterodimer stability (beta26-110 disulphide bridge), in vitro LH bioactivity (region beta102-110) and in in vivo LH bioactivity (beta CTP). Like the hCG beta, the equine eLH and eCG beta subunits, also possess a C-terminal extension (CTP). But, in contrast to hCG, eLH and eCG bind to both LH and FSH receptors in species other than the horse. This allows investigation of the roles of the beta subunit C-terminal region of a eLH/CG recombinant molecule on both LH and FSH activities. To do so, the CTP was deleted and/or the beta26-110 disulphide bond was mutated and the resulting mutated beta subunits were transiently co-expressed with common alpha subunit in COS7 cells. These regions were also deleted in a betaalphaeLH/CG single chain also expressed in COS7 cells. The hormones produced were characterized by different ELISAs and in vitro LH and FSH bioassays. Mutation of the 26-110 disulphide bond and deletion of the betaCTP led to a decrease in eLH/CG heterodimer production. Double mutation promoted an additive effect on production of the heterodimer and of the corresponding tethered eLH/CG. The elimination of the beta26-110 disulphide bond in the betaalpha single chain had no effect on its production. However, neither the 26-110 disulphide bond nor the CTP mutations affected dimer stability and bioactivities of the secreted heterodimers and/or single chain molecules. Therefore, in contrast to hCG, the 26-110 S-S bond of the recombinant eLH/CG beta subunit does not seem to be essential for eLH/CG dimer stability upon secretion and expressing LH and FSH bioactivities.

beta-Subunit 102-104 residues are crucial to confer FSH activity to equine LH/CG but are not sufficient to confer FSH activity to human CG.

Horse LH/CG (eLH/CG) and donkey LH/CG (dkLH/CG) are strictly LH-specific in their respective homologous species. However, both bind to the FSH receptors from non-equid species, whereas the zebra hormone (zbLH/CG) does not. The FSH/LH ratio of eLH/CG and of the alphadkbetae hybrid is about tenfold higher than that of dkLH/CG and of the alphaebetadk hybrid, showing that the betae subunit contains the structural features responsible for the high FSH activity of eLH/CG. Only six amino acid positions (51, 94, 95, 102, 103 and 106) are unique to the betae subunit when compared with the betadk and betazb subunits. The Gly-Pro and Val-Phe sequences in positions 102-103 of betadk and betae respectively were swapped by site-directed mutations and the mutated beta-subunits cDNAs were cotransfected in COS cells with either alphae or alphadk subunit cDNA. Other mutations were also introduced in 102-103 dkLH/CG beta-subunit: Ala-Ala, Gly-Ala or Ala-Pro. These mutations with Ala-Ala, Gly-Ala or Ala-Pro in the 102-103 betadkLH/CG subunit did not change the FSH/LH ratio of dkLH/CG but the Gly(102)-Pro(103)-->Val(102)-Phe(103) mutation promoted a marked increase in the FSH/LH activity ratio. This was observed with the two heterodimers containing alphae or alphadk. Conversely, the Val(102)-Phe(103) mutation in betae led to a dramatic drop in FSH/LH activity ratio of eLH/CG, to a level similar to that of dkLH/CG. Since all FSHs possess a Gly residue at position 104, we introduced the Gly(102)-Pro(103)-Arg(104)-->Val(102)-Phe(103)-Gly(104) mutation in betadk with the expectation that the increase in FSH activity observed with the Gly(102)-Pro(103)-->Val(102)-Phe(103) mutation could be potentiated. In fact, the additional Arg(104)-->Gly(104) mutation was found to abolish the increase in FSH activity observed with Gly(102)-Pro(103)-->Val(102)-Phe(103). Mutations Gly(102)-Pro(103)-->Val(102)-Arg(103) or Gly(102)-Pro(103)-Lys(104)--> Val(102)-Arg(103)-Gly(104) were also introduced in human CGbeta (hCGbeta) to compare the impact of these amino acid changes in the well-studied gonadotrophin hCG. The betahCG mutants obtained, co-expressed either with the human or the horse alpha-subunit, did not display any FSH activity. In conclusion, the 102-104 sequence in eLH/CG beta-subunits appears to be of utmost importance for their binding to FSH receptors. However, these results obtained with equid beta-subunits are not transposable to other gonadotrophins as similar mutations in hCGbeta did not lead to any increase in FSH activity.

Expression of horse and donkey LH in COS-7 cells: evidence for low FSH activity in donkey LH compared with horse LH.

Horse (Equus caballus) luteinizing hormone (eLH) and chorionic gonadotrophin (eCG), which have the same amino acid sequence, are unusual in that, although they express only LH activity in equids, they express dual LH and FSH activities in all other species tested. Donkey (Equus asinus) LH (dkLH) and CG (dkCG), which also share an identical peptide backbone, have been less well characterized and conflicting results concerning their FSH activity in heterologous species have appeared in the literature. In order to assess and compare the intrinsic LH and FSH activities of the horse and donkey LHs in heterologous species, recombinant eLH (r.eLH/CG) and recombinant dkLH (r.dkLH/CG) were expressed, for the first time, in COS-7 cells. Their LH activities were assessed in a rat Leydig cell bioassay, and their FSH activities were estimated in a bioassay using Y1 cells stably expressing the human FSH receptor. Human CG (hCG) was expressed (r.hCG) and analysed in the same system. The results showed that, whereas r.dkLH/CG was about twice as active as r.eLH/CG in the LH bioassay, it was five times less active than r.eLH/CG in the FSH bioassay; r.hCG was about three times less active than r.eLH/CG in the LH bioassay but was completely inactive in the FSH bioassay. These results confirm that dkLH/CG possesses significant FSH activity in heterologous species that is not attributable to contamination with FSH.

Evidence that the alpha-subunit influences the specificity of receptor binding of the equine gonadotrophins.

Horse LH/chorionic gonadotrophin (eLH/CG) exhibits, in addition to its normal LH activity, a high FSH activity in all other species tested. Donkey LH/CG (dkLH/CG) also exhibits FSH activity in other species, but about ten times less than the horse hormone. In order to understand the molecular basis of these dual gonadotrophic activities of eLH/CG and dkLH/CG better, we expressed, in COS-7 cells, hybrids between horse and donkey subunits, between horse or donkey alpha-subunit and human CG beta (hCG beta), and also between the porcine alpha-subunit and horse or donkey LH/CG beta. The resultant recombinant hybrid hormones were measured using specific FSH and LH in vitro bioassays which give an accurate measure of receptor binding specificity and activation. Results showed that it is the beta-subunit that determines the level of FSH activity, in agreement with the belief that it is the beta-subunit which determines the specificity of action of the gonadotrophins. However, donkey LH/CG beta combined with a porcine alpha-subunit exhibited no FSH activity although it showed full LH activity. Moreover, the hybrid between horse or donkey alpha-subunit and hCG beta also exhibited only LH activity. Thus, the low FSH activity of dkLH/CG requires an equine (donkey or horse) alpha-subunit combined with dkLH/CG beta. These results provide the first evidence that an alpha-subunit can influence the specificity of action of a gonadotrophic hormone.

Topography of equine chorionic gonadotropin epitopes relative to the luteinizing hormone and follicle-stimulating hormone receptor interaction sites.

In order to localize the epitopes of equine chorionic gonadotropin (eCG) involved in interaction with luteinizing hormone (LH) and follicle-stimulating hormone (FSH) receptors, we used 14 monoclonal anti-eCG antibodies (mAbs). Different effects of these mAbs on the bioactivities of eCG were observed in in vitro bioassays, but the effects of each mAb on the two bioactivities were similar for all but four mAbs. All mAbs were found to inhibit the binding of eCG to LH receptors except 3A3 mAb, in radioreceptor assay. Six mAbs, which were strong inhibitors of eCG binding to LH receptors and of both bioactivities, recognized the same area on the alpha subunit of eCG. All others, except 3A3, recognized epitopes close to the former, and close to each other. 3A3 mAb had a hyperstimulatory effect on FSH bioactivity, and was the only mAb that did not inhibit binding. It appeared to recognize a different epitopic area. These observations suggest that there is a main antigenic area on eCG, which corresponds to the interaction site of eCG with both receptors. It mostly involves the alpha subunit and to a lesser extent the beta subunit.

Expression of a single betaalpha chain protein of equine LH/CG in milk of transgenic rabbits and its biological activity.

Equine chorionic gonadotropin (eCG) is a heavily glycosylated glycoprotein composed of non-covalently linked alpha- and beta-subunits. eCG possesses the particularity to bind to both LH and FSH receptors in species other than horses and to have a prolonged plasma half-life. All these properties make it of utmost interest for livestock fertilization program. Up to now, the only source of eCG is the serum of pregnant mare. Rabbit mammary gland is considered as a system able to produce recombinant glycoproteins in sufficient quantity for pharmaceutical use. Here we described the production of a recombinant single betaalpha chain of eLH/CG in the milk of transgenic rabbit. The construction of a single-chain permits to by-pass the problem of association-dissociation of the subunits. This recombinant hormone is greatly expressed (21.7 mg/l) and presents similar in vitro LH and FSH bioactivities. However, betaalphaeLH/CG shows an extremely rapid clearance (approximately 10 min), which could explain the absence of in vivo biological activity. So the rabbit mammary gland is not appropriate for the production of a recombinant active eLH/CG.

Identification of amino-acids in the alpha-subunit first and third loops that are crucial for the heterospecific follicle-stimulating hormone activity of equid luteinizing hormone/choriogonadotropin.

OBJECTIVE: To identify amino-acids in the alpha-subunit important for expression of heterospecific FSH activity of horse (e) LH/choriogonadotropin (CG) (eLH) and donkey (dk) LH/CG (dkLH) (FSH/LH ratio ten times higher for eLH than for dkLH); this FSH activity absolutely requires an equid (donkey or horse) alpha-subunit combined with an equid beta-LH subunit. DESIGN: Chimeric alpha-subunits possessing the first 63 amino-acids of the porcine (p) and the last 33 amino-acids of the donkey alpha-subunit (alphap-dk) and the inverse (alphadk-p) were constructed. Porcine-specific amino-acids were introduced by mutagenesis in donkey alpha-subunit at positions 70, 85, 89, 93 and 96 (alphadk5xmut), 18 (alphadkK18E) or 78 (alphadkI78A). METHODS: These different alpha-subunits were co-transfected in COS-7 cells with beta-eLH, beta-dkLH and beta-eFSH. The LH and FSH bioactivities of the dimers were then assessed in two heterologous in vitro bioassays. RESULTS: alphap-dk or alphadk-p exhibited FSH activity when co-expressed with beta-eLH but not with beta-dkLH. alphadkK18E or alphadkI78A gave hybrids with no FSH activity and important LH activity when expressed with beta-dkLH. alphadkI78A/betaeLH displayed an FSH/LH ratio as low as that of dkLH. However, mutation at 78 in alpha-dk had no effect on FSH bioactivity when co-expressed with beta-eFSH. CONCLUSIONS: Amino-acids present in both the first two-thirds and the last third of the alpha-subunit of equid LHs are involved in their heterologous biospecificity. Ile alpha78 exerts as strong an influence on it as the beta102-103 residues. By contrast, this residue plays no role in the FSH specificity of eFSH.

Structure-function relationships and mechanism of action of pituitary and placental gonadotrophins.

Data from the author's laboratory on relationships between structure and function of equine luteinizing hormone, follicle-stimulating hormone and choriogonadotrophin as well as their mechanisms of action are reviewed and compared with their human counterparts. Polymorphism of these hormones and problems associated with their purification are discussed as well as the association and dissociation of their alpha- and beta-subunits. The affinity of receptor binding, the superactivity of membrane transduction and homologous desensitization of target cells by non-stimulatory doses of the gonadotrophins are also reviewed.

Patterns of plasma LH, FSH, oestradiol and corticosteroids from birth to the first oestrous cycle in Meishan gilts.

Hormonal changes associated with pubertal development in a breed of pig exhibiting early puberty were determined. In Expt 1, blood from prepubertal Meishan gilts was collected at about 1 (n = 5), 10 (n = 5), 20 (n = 4), 30 (n = 5), 50 (n = 5), 70 (n = 10), 80 (n = 10) and 90 (n = 7) days of age. In Expt 2, females were sampled between 99 and 116 days of age before (n = 16) or during (n = 9) the first oestrous cycle. Serial blood samples were collected through a jugular catheter at 20 min intervals. In Expt 2, age at puberty was determined by daily examination for oestrus and weekly evaluation of plasma progesterone and found to occur at 111 days of age. Hormone profiles determined at least 19 days before the first oestrus were grouped to constitute a prepubertal stage. In Expt 1, mean concentration of LH was high at 1 day of age, significantly lower at 10 days and showed nonsignificant variations until 90 days. Frequency of LH pulses increased between 10 and 50 days (0.42 versus 0.85 pulse h-1, P < 0.05), decreased between 50 and 70 days (0.49 pulse h-1, P < 0.05) and remained low thereafter. Amplitude of LH pulses was high between 1 and 30 days and declined progressively until 80 days. Mean concentration of FSH was high between 1 and 20 days and decreased progressively until 80 days (7.2 and 2.3 ng ml-1, respectively, at 20 and 80 days, P < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning, sequencing and functional expression of zebra (Equus burchelli) LH.

Although donkey luteinizing hormone exhibits a very high degree of amino acid sequence identity with horse LH, its FSH activity in non-equine species is tenfold lower. The coding regions of the common zebra (Equus burchelli) glycoprotein hormone alpha-subunit and LH beta-subunit transcripts were cloned by reverse transcription-PCR from pituitary gland RNA to investigate more precisely the structure-function relationships of this gonadotrophin family. Zebra LH was then expressed in COS-7 cells and its LH and FSH activities were assessed in a rat Leydig cell bioassay (for LH) and in a cell line stably expressing the human FSH receptor bioassay (for FSH). The recombinant zebra LH, although displaying LH activity similar to that of recombinant donkey and horse LH, had no detectable FSH activity. The LH amino acid sequences of these three species are very similar, leaving only very few amino acids as potential candidates to explain the difference in their FSH activities. Moreover, according to the difference in FSH bioactivity and to the percentage identity between the sequences, the common zebra is phylogenetically closer to the donkey than it is to the horse.