Chronic hypersecretion of luteinizing hormone in transgenic mice disrupts both ovarian and pituitary function, with some effects modified by the genetic background.

When the pituitary or hypothalamus becomes resistant to steroid negative feedback, a vicious cycle ensues, resulting in chronic hypersecretion of luteinizing hormone (LH) from the pituitary and steroids from the ovaries. In women, LH hypersecretion is implicated in infertility, miscarriages, and development of granulosa cell tumors. Progress in defining the underlying mechanisms of LH toxicity, however, has been limited by the lack of well-defined animal models. To that end, we have developed a new transgenic mouse model (alpha-LHbetaCTP) wherein LH hypersecretion occurs chronically and results in several dire pathological outcomes. Chronic hypersecretion of LH was achieved by introducing a transgene containing a bovine alpha subunit promoter fused to the coding region of a chimeric LHbeta subunit. The alpha subunit promoter directs transgene expression only to gonadotropes. The LHbeta chimera contains the carboxyl-terminal peptide (CTP) of the human chorionic gonadotropin beta subunit linked to the carboxyl terminus of bovine LHbeta. This carboxyl extension extends the half-life of LH heterodimers that contain the chimeric beta subunit. In intact alpha-LHbetaCTP females, serum LH is elevated five- to ten-fold in comparison to nontransgenic littermates. Levels of testosterone (T) and estradiol (E2) also are elevated, with an overall increase in the T-to-E2 ratio. These transgenic females enter puberty precociously but are anovulatory and display a prolonged luteal phase. Anovulation reflects the absence of gonadotropin-releasing hormone (GnRH) and the inability to produce a pre-ovulatory surge of LH. The ovaries are enlarged, with reduced numbers of primordial follicles and numerous, giant, hemorrhagic follicles. Despite the pathological appearance of the ovary, females can be superovulated and mated. Although pregnancy occurs, implantation is compromised due to defects in uterine receptivity. In addition, pregnancy fails at midgestation, reflecting a maternal defect presumably due to estrogen toxicity. When the transgene is in a CF-1 background, all females develop granulosa cell tumors and pituitary hyperplasia by five months of age. They die shortly thereafter due to bladder atony and subsequent kidney failure. When the transgene is placed in other strains of mice, their ovaries develop a luteoma rather than a granulosa cell tumor and the pituitary develops pituitary hyperplasia followed by adenoma. In summary, alpha-LHbetaCTP mice provide a direct association between abnormal secretion of LH and development of a number of ovarian and pituitary pathological responses.

Two uncompetitive, activated, and transport sites of the Na+/H+ exchanger for pH regulation in perfused rat kidney.

The purpose of this study is to assess the effect of an apparent alteration in intracellular pH and the effect of amiloride on the activity of the Na+/H+ antiporter in perfused rat kidney. Rat kidney-Na+ retention was determined using tracer 22Na in perfusate composed of HCl-glycine buffer (pH 3.80 to pH 5.92) or NH4OH-glycine buffer (pH 6.22-7.95) containing Na+ to match physiologic concentrations. Plotting renal Na+ retention for 10 min versus pH in absence of amiloride showed two classical uncompetitive activator curves for H+, one curve from pH 4.19 to 5.10 and another from pH 6.22 to 7.95. H+ acts as an uncompetitive reversible binding substrate with the receptor triggering activation of the exchanger already sequestered with Na+, thus yielding two Ka values for the exchanger suggesting non-first order kinetics. Using an equation derived for uncompetitive-activation binding of Nao+ and Hi+, plotting [mM Na+ mg protein-1 10 min-1]-1 versus [H+], two linear plots are observed on Cartesian coordinates with abscissa intersecting at 47 +/- 1 microM, pKa = 4.32 +/- 0.02 (pH 4.19-5.10) and 4.21 +/- 0.02 microM, pKa = 5.38 +/- 0.01 (pH 6.22-7.95), respectively. Perfusing buffer containing 2 mM amiloride, completely inactivated the antiporter showing stronger inhibition between pH 3.80 and 5.92. Results suggest the presence of two uncompetitive binding sites for H+ with the Na+/H+ exchanger. One is a high affinity binding site at physiological intracellular apparent pH, and another is a low affinity binding site at ischaemic apparent pH, implying the existence of two titration sites for intracellular pH regulation.

Chronic hypersecretion of luteinizing hormone in transgenic mice selectively alters responsiveness of the alpha-subunit gene to gonadotropin-releasing hormone and estrogens.

Steroid hormones can act either at the level of the hypothalamus or the pituitary to regulate gonadotropin subunit gene expression. However, their exact site of action remains controversial. Using the bovine gonadotropin alpha-subunit promoter linked to an expression cassette encoding the beta-subunit of LH, we have developed a transgenic mouse model where hypersecretion of LH occurs despite the presence of elevated ovarian steroids. We used this model to determine how hypersecretion of LH could occur when steroid levels are pathological. During transition from the neonatal period to adulthood, the endogenous LHbeta subunit gene becomes completely silent in these mice, whereas the alpha-directed transgene and endogenous alpha-subunit gene remain active. Interestingly, gonadectomy stimulates expression of the endogenous alpha and LHbeta subunit genes as well as the transgene; however, only the endogenous LHbeta gene retains responsiveness to 17beta-estradiol and GnRH. In contrast, LH levels remain responsive to negative regulation by androgen. Thus, alpha-subunit gene expression, as reflected by both the transgene and the endogenous gene, has become independent of GnRH regulation and, as a result, unresponsive to estradiol-negative feedback. This process is accompanied by a decrease in estrogen receptor alpha gene expression as well as an increase in the expression of transcription factors known to regulate the alpha-subunit promoter, such as cJun and P-LIM. These studies provide in vivo evidence that estrogen-negative feedback on alpha and LHbeta subunit gene expression requires GnRH input, reflecting an indirect mechanism of action of the steroid. In contrast, androgen suppresses alpha-subunit expression in both transgenic and nontransgenic mice. This suggests that androgens must regulate alpha-subunit promoter activity independently of GnRH. In addition to allowing the assessment of site of action of sex steroids on alpha-subunit gene expression, these studies also indicate that chronic exposure of the pituitary to LH-dependent ovarian hyperstimulation leads to a heretofore-undescribed pathological condition, whereby normal regulation of alpha, but not LHbeta, subunit gene expression becomes compromised.

Characterization of the equine glycoprotein hormone alpha-subunit gene reveals divergence in the mechanism of pituitary and placental expression.

The equine glycoprotein hormone alpha-subunit gene is expressed in both pituitary and placenta, unlike that of all other nonprimate mammals studied, in which expression is limited to pituitary. Previous studies of the 5'-flanking region of the equine alpha-subunit promoter have revealed unique characteristics as well as similarities with the human alpha-subunit promoter, which demonstrates a similar pattern of tissue-specific expression. We have cloned and sequenced the equine alpha-subunit gene and have used tissue culture systems and transgenic mice to characterize its expression. Unlike the human promoter, the cloned equine alpha-subunit promoter failed to direct trophoblast-specific expression in either tissue culture or transgenic mouse models, suggesting an entirely different mechanism for expression. In contrast, the equine alpha-subunit promoter was able to direct gonadotroph expression in both tissue culture and transgenic mouse models. In alphaT3-1 cells, 550 base pair (bp) was sufficient for expression. This expression involves promoter elements identified in other species as playing a role in gonadotroph expression, but mutation of these elements reveals differences in their relative contributions to promoter activity. In mice, 2800 bp of 5'-flanking sequence allowed specific expression in gonadotrophs but not in thyrotrophs or placenta. The pattern of estrogen regulation observed in transgenic mice matched neither the repression that has been observed with human and bovine alpha-subunit promoters in transgenic mice nor the stimulation in mRNA levels reported in mares, suggesting a unique mechanism that is not recapitulated in the transgenic model. Thus the equine alpha-subunit promoter uses a combination of conserved and unique features of gene regulation to direct its pattern of tissue-specific expression.

Enhanced production of human immunodeficiency virus type 1 by in vitro-infected alveolar macrophages from otherwise healthy cigarette smokers.

Since cellular activation is required for replication of human immunodeficiency virus type 1 (HIV-1), the capacity of alveolar macrophages (AM) from smokers, which are relatively activated, and nonsmokers to support the production of HIV-1JR-FL was examined. Peak HIV-1 p24 antigen level in culture supernatants of infected AM from 13 smokers was significantly higher than that of 13 nonsmokers: 31,394 +/- 8295 versus 7037 +/- 2550 pg/mL (mean +/- SE; P < .002). This difference could not be explained on the basis of viral entry, extent of reverse transcription, or release of monokines, including tumor necrosis factor-alpha, interleukin-1 beta or -6, and granulocyte-macrophage colony-stimulating factor. HIV-1 production by blood monocytes from smokers and nonsmokers infected in vitro was negligible. Thus, cigarette smoking selectively increases the susceptibility of AM to productive infection with HIV-1. This finding provides a biologic plausibility to observations that smoking may enhance the progression of AIDS.