Genomic Structure of the Porcine CYP19 Locus and Expression of the CYP19A3 Paralog.

Proper, tissue-specific regulation of CYP19, the gene encoding aromatase, the key enzyme of estrogen synthesis, is essential for reproductive processes. Here, we analyzed transcriptional regulation of the porcine CYP19 in female and male gonads and brain by 5'RACE and RT-PCR and comprehensively mapped the pig CYP19 locus by in silico analysis. Our data revealed that the complete locus, including three paralogous copies, CYP19A1, CYP19A2 and CYP19A3, spans approximately 330 kb of the porcine chromosome 1. The locus also harbors the first exon of the Gliomedin gene (GLDN) in reverse orientation. Only transcripts of the CYP19A3 paralog were substantially expressed in gonads and hypothalamus. We identified CYP19A3-associated untranslated exons approximately 160 kb and 50 kb distal from the first codon. The 5´ untranslated regions of transcripts were derived from either a proximal or from one of these distal untranslated exons. Transcripts including only untranslated exons could be amplified from testis, thus suggesting long non-coding transcripts. The data revealed an additional layer of complexity in the regulation of the porcine CYP19 locus. Tissue-specific expression is not only achieved by tissue- and stage-specific expression of the three different CYP19 paralogs, but also by directing the expression of CYP19A3 from different, proximal and distal promoter regions.

Alteration of the mare's immune system by the synthetic progestin, altrenogest.

PROBLEM: Progestins are immunomodulatory in a variety of species. In the horse, the most commonly administered synthetic progestin is altrenogest (ALT), but its effect on the immune system of the non-pregnant mare is unknown. METHODS: Peripheral blood mononuclear cells (PBMCs) from diestrous mares were incubated with varying concentrations of progesterone (P4) or ALT to assess intracellular production of IFNγ and the expression of select cytokines. Additionally, ten mares received either ALT or VEH daily utilizing a switchback design beginning on the day of ovulation and continuing for 7 days. Circulating PBMCs and endometrial biopsies were obtained to assess the production and expression of the same cytokines. RESULTS: In vitro, both P4 and ALT caused a dose-dependent decrease in intracellular IFNγ in PBMCs. P4 caused a dose-dependent decrease in the expression of IFNγ, IL-10 and IL-4, while ALT caused an increase in the expression of IL-6 and IL-1ß in PBMCs. In vivo, ALT suppressed the intracellular levels of IFNγ in PBMCs on d6. While control mares experienced a decrease in IL-1ß expression from d0 to d6, ALT-treated mares did not. In the endometrium, ALT increased the expression of IL-1RN and IFNγ in comparison with VEH-treated mares. CONCLUSION: P4 and ALT appear to alter the immune system of the non-pregnant mare both systemically in addition to locally within the endometrium. Further research is necessary to determine the pathways through which this synthetic progestin functions on the immune system of the horse, and the consequences it may have.

Serum anti-Müllerian hormone concentrations in stallions: developmental changes, seasonal variation, and differences between intact stallions, cryptorchid stallions, and geldings.

Anti-Müllerian hormone (AMH), a homodimeric glycoprotein, is secreted early in fetal life when it exerts a crucial function in sexual differentiation. The secretion of AMH in male humans persists after birth and is characterized by high prepubertal concentrations followed by a significant decrease at the onset of puberty. The expression of AMH in the normal and cryptorchid equine testis is well characterized but data regarding circulating AMH concentrations are lacking. The objectives of this study were to determine serum AMH concentrations in neonatal colts and fillies, prepubertal colts, and postpubertal stallions, and to evaluate variations in serum AMH related to season and gonadal status of stallions. In addition, we examined the presence and determined concentrations of AMH in seminal plasma of mature stallions. Serum AMH concentrations were significantly higher in neonatal colts than in neonatal fillies. Moreover, concentrations of AMH are high in prepubertal colts whereas significantly lower concentrations were detected after puberty. In intact mature stallions, season influenced AMH concentrations with significantly higher concentrations during spring and summer. Serum AMH concentrations were significantly higher in cryptorchid stallions compared with intact stallions or geldings. Finally, AMH was identified in seminal plasma of intact mature stallions, but there was no significant correlation between serum and seminal plasma AMH concentrations. In conclusion, serum AMH concentration varies with sex in the neonatal period, postnatal sexual development and season, and serum AMH concentration can be used as a biomarker for the presence of testicular tissue.

Costs and consequences of cellular compartmentalization and substrate competition among human enzymes involved in androgen and estrogen synthesis.

The impact of compartmental expression of steroidogenic enzymes and of changes in flux through delta5 and delta4 metabolism on sex steroid synthesis was investigated by rebuilding pathways using recombinant enzyme expression by infection of insect cells with recombinant baculovirus constructs. Human cytochromes 17alpha-hydroxylase/17,20-lyase (P450c17) and aromatase (P450arom), always coexpressed with their redox partner NADPH-P450 oxidoreductase (CPR) and 3beta-hydroxysteroid dehydrogenase/delta5-4 isomerase (3betaHSD; types 1 or 2), were compartmentally expressed in different cell populations or coexpressed together with pregnenolone (100 nM) as substrate. Estrone was compared among cell compartments expressing different enzyme combinations or in cells coexpressing all enzymes (experiment 1). Additionally, P450c17, 3betaHSD, and CPR were all coexpressed, and androstenedione was measured in cells with different 3betaHSD expression levels or activity using an inhibitor, trilostane (experiment 2). Steroids were measured by immunoassay and mass spectrometry. In experiment 1, partitioning of P450c17, P450arom, and 3betaHSD markedly decreased estrone synthesis in comparison to cells coexpressing enzymes in different combinations. However, partitioning P450arom with 3betaHSD from P450c17 in different cell populations resulted in more estrone than either of the other two-cell compartment models. In experiment 2 (cells coexpressing P450c17, 3betaHSD, and CPR), androstenedione secretion was (paradoxically) higher at lower levels of 3betaHSD, and partial inhibition of 3betaHSD by trilostane also increased androstenedione when 3betaHSD expression was high. We conclude 1) that tissue or cell-specific, partitioned expression of sex steroid synthesizing enzymes limits rather than maximizes estrogen synthesis and 2) that limiting metabolism by 3betaHSD can paradoxically promote androgen synthesis when 3betaHSD expression is high by promoting delta5-steroid flux.