Agreement between the GAITRite walkway system and a stopwatch-footfall count method for measurement of temporal and spatial gait parameters.

Objective: To determine the agreement for measurements of stride length, cadence, and walking speed obtained from the GAITRite system and the stopwatch-footfall count technique.

Design: Criterion standard.

Setting: Research laboratory in a physical therapy education program.

Ascorbic acid-dependent cytoprotection of ovarian cells by leukocyte and nonleukocyte peroxidases.

Luteal cells contain high levels of ascorbic acid that is secreted by stimulation with agents like luteinizing hormone (LH) and prostaglandin F2 alpha (PGF2 alpha). One role for interstitial ascorbic acid, we propose, may be the detoxification of H2O2 by regeneration of catalytically active peroxidase. By serving as a preferred secondary substrate, ascorbic acid regenerates the catalytically active peroxidase that is inhibited irreversibly by H2O2 alone.

Prostaglandin f2alpha treatment in vivo, but not in vitro, stimulates protein kinase C-activated superoxide production by nonsteroidogenic cells of the rat corpus luteum.

Luteal regression is associated with the generation of reactive oxygen species (ROS). To determine the nature of the ROS generator, cells isolated from luteinized rat ovaries were examined for ROS production using luminol-amplified chemiluminescence (LCL). Cells cultured for 2-48 h exhibited minimal LCL, but there was a significant (30- to 50-fold), rapid (maximum at 3-5 min), and dose-dependent increase in LCL in response to phorbol ester (phorbol 12-myristate 13-acetate; TPA; ED50 = 0.

Accumulation of ascorbate by endocrine-regulated and glucose-sensitive transport of dehydroascorbic acid in luteinized rat ovarian cells.

The corpus luteum is notable for very high levels of ascorbic acid. In luteal cells, ascorbic acid depletion occurs as a result of consumption during radical scavenging, inhibition of ascorbic acid uptake, and stimulation of its secretion. Oxidation of ascorbic acid generates dehydroascorbic acid (DHAA).

Hormone induction of ascorbic acid transport in immature granulosa cells.

Ascorbic acid serves a vital role as an antioxidant, and like FSH, it inhibits apoptosis of granulosa cells in cultured follicles. In contrast, reactive oxygen species block the action of FSH and induce DNA damage in these cells. As the uptake of ascorbic acid by granulosa cells may be a site for regulation, we examined the nature of this process and whether uptake is under hormone control.

Cytokine induction of heat shock protein in human granulosa-luteal cells.

The infiltration of leukocytes is a characteristic feature of luteolysis in humans. Leukocytes are known to generate physiological inducers of cell stress such as cytokines which have been implicated as mediators of functional luteal regression. In cells exposed to stress, a response characterized by an increase in heat shock protein (HSP) synthesis occurs.

Endocrine regulation of ascorbic acid transport and secretion in luteal cells.

Luteal ascorbic acid depletion by LH and prostaglandin (PG) F2 alpha is well known, but how such depletion occurs is not. We therefore investigated the nature and regulation of ascorbic acid uptake and depletion in the rat CL and luteal cells. In vivo studies showed that blockade of steroidogenesis by aminoglutethimide prevented ascorbate depletion by LH, but not PGF2 alpha.

Heat shock protein-70 induction mediates luteal regression in the rat.

Induction of heat shock protein 70 (HSP-70) is associated with inhibition of hormone-sensitive steroidogenesis and interruption of cholesterol translocation to or into the mitochondria. A number of pharmacological and physiological inhibitors of luteal cell function stimulate HSP-70 synthesis via activation of the heat shock transcription factor (HSF). In the present study we address the following questions: 1) is HSP-70 synthesis increased during prostaglandin F2 alpha (PGF2 alpha)-induced luteolysis or natural luteal regression? 2) Does blocking HSP-70 synthesis reverse the inhibition of hormone-sensitive steroidogenesis induced by heat stress and PGF2 alpha? Gel-retardation assays demonstrated HSF activation within 7.

Modulation of cholesteryl ester hydrolase messenger ribonucleic acid levels, protein levels, and activity in the rat corpus luteum.

Previous studies have shown that the induction of functional luteolysis (loss of progesterone production) with either prostaglandin F2 alpha (PGF2 alpha) treatment or hypophysectomy (APX) diminished neutral cholesteryl ester hydrolase (CEH) activity in the corpus luteum (CL) and that prolactin (PRL) replacement of APX animals prevented luteolysis and maintained CEH activity at control levels. More recent studies have shown that CEH is the same protein as hormone-sensitive lipase (HSL) and that CEH/HSL activity may be regulated by phosphorylation. However, the possibility that CEH/HSL activity may be under transcriptional and/or translation control has not been excluded.

Peroxisomes and sterol carrier protein-2 in luteal cell steroidogenesis: a possible role in cholesterol transport from lipid droplets to mitochondria.

In the present investigation, we have studied peroxisomes and sterol carrier protein-2 (SCP2) in control and luteinizing hormone stimulated rat luteal cells. Superovulated immature rats in mid-luteal phase (8 days after ovulation) were divided into two groups (n = 4/group) and treated with vehicle (0.2 ml saline), or luteinizing hormone (LH, 20 micrograms/rat).

Physiological and pharmacological inhibitors of luteinizing hormone-dependent steroidogenesis induce heat shock protein-70 in rat luteal cells.

Heat shock protein (HSP) synthesis increases in cells with a broad range of stress conditions. We recently showed that induction of HSP-70 is associated with inhibition of hormone-sensitive steroidogenesis, but not hormone-sensitive cAMP accumulation, in rat luteal cells by a mechanism associated with interruption of cholesterol translocation in mitochondria. As HSP induction may be an early mediator of luteal regression, we investigated whether physiological and pharmacological inhibitors of luteal function would induce HSP-70 in rat luteal cells.

A cell adhesion receptor antiserum abolishes, whereas laminin and fibronectin glycoprotein components of extracellular matrix promote, luteinization of cultured rat granulosa cells.

We recently showed that structural regression is marked by an endocrine-induced increase in matrix metalloproteinase activity specific for basement membrane, which suggests that extracellular matrix (ECM) may play an important role in sustaining luteal cell function. Such a role for ECM has been demonstrated for cultured mammary epithelial cells, hepatocytes, and keratinocytes. To test this hypothesis, granulosa cells from preovulatory follicles that were induced to luteinize by gonadotropin stimulation in vivo were examined.

Lipid hydroperoxides evoke antigonadotropic and antisteroidogenic activity in rat luteal cells.

At functional luteolysis, the rat corpus luteum generates hydrogen peroxide (H2O2), which is known to rapidly inhibit gonadotropin-sensitive cAMP and progesterone production in isolated luteal cells. Lipid peroxides also increase markedly in the rat corpus luteum with the onset of functional luteolysis, and H2O2 is a potent inducer of lipid peroxidation. However, the actions of lipid peroxides on cell function are unknown.

Ovarian vitamin E accumulation: evidence for a role of lipoproteins.

Reactive oxygen species, such as superoxide, hydrogen peroxide, and lipid peroxides, impair luteal function. Vitamin E, a lipophilic antioxidant vitamin, provides a major avenue of protection by scavenging free radicals and terminating lipid peroxidation. We previously showed that ovarian vitamin E levels increase after functional regression (loss of progesterone production) of the corpus luteum in the pseudopregnant rat and the objective of the present studies was to determine the mechanism(s) that resulted in such increased levels of vitamin E.

Inhibition of protein synthesis and hormone-sensitive steroidogenesis in response to hydrogen peroxide in rat luteal cells.

Hydrogen peroxide (H2O2) is generated in the corpus luteum at functional luteal regression and produces rapid antigonadotropic effects in rat luteal cells. However, the mechanism by which peroxide interrupts LH- and cAMP-sensitive progesterone synthesis is unknown. The post-cAMP site of H2O2 action is due to the reduced cholesterol availability in mitochondria, and this process is well known to be dependent on protein synthesis.

Heat shock protein induction blocks hormone-sensitive steroidogenesis in rat luteal cells.

A variety of agents induce heat shock proteins (HSPs) in addition to heat shock. The heat shock response and its effects on luteal function have not been investigated, but provocatively, many of the agents known to induce HSPs impair progesterone synthesis in luteal cells. We therefore investigated whether HSP induction might influence luteal function.

Coordinate induction and activation of metalloproteinase and ascorbate depletion in structural luteolysis.

Structural luteolysis was found decades ago to be induced by PRL in the hypophysectomized rat, but the mechanisms of this process are unknown. To gain information on mechanisms of luteal involution, we developed an animal model that circumvented complex surgery and provided ample tissue for analyses. Gonadotropin-synchronized ovulation and luteinization were induced in immature rats, followed by treatment with ergot alkaloid and PRL.

Hydrogen peroxide evokes antisteroidogenic and antigonadotropic actions in human granulosa luteal cells.

The nature of the luteolysin in humans is unknown. Hydrogen peroxide (H2O2), notably released by activated leukocytes, is generated in the rat corpus luteum at luteolysis and evokes luteolytic-like effects in rat luteal cells. We, therefore, evaluated the actions of H2O2 in human luteinized granulosa cells.

Mechanisms for the antigonadotropic action of the ovarian gonadotropin-releasing hormone-binding inhibitor protein/histone H2A on ovarian cells.

A GnRH-binding inhibitor (GnRH-BI) was recently purified from bovine ovaries. On the basis of amino acid composition and partial sequence analysis this antigonadotropic GnRH-BI was identified as histone H2A. In the present study the mechanism for the antigonadotropic action of histone H2A was examined and compared to that of GnRH and poly-L-lysine.

Regulation of ovarian antioxidant vitamins, reduced glutathione, and lipid peroxidation by luteinizing hormone and prostaglandin F2 alpha.

Reactive oxygen species are generated by the rat ovary, and they evoke marked antigonadotropic responses in ovarian cells. Protection against reactive oxygen species is provided by antioxidants such as vitamins C, E, and A, and reduced glutathione (GSH). Our objectives were to establish the ovarian levels of these antioxidants during development and regression of the corpus luteum of the pseudopregnant rat and to determine whether these levels were changed by an acute treatment with either a luteotropic (LH) or luteolytic (prostaglandin [PG] F2 alpha) agent.

Differential modulation of thymosin genes in the immature rat ovary by gonadotropins.

A cloned thymosin beta-10 cDNA and a synthetic oligonucleotide specific for the thymosin beta-4 gene were used to study the in vivo expression of these two genes in the immature rat ovary in response to exogenously administered gonadotropins. Despite the fact that both genes were co-expressed in the rat ovary, it became evident that they exhibit distinctly unique differential responses to in vivo hormonal challenge. Administration of pregnant mare's serum gonadotropin (PMSG) to immature rats provoked a pronounced stimulation of ovarian thymosin beta-10 expression, the maximal effect (2- to 4-fold) of which coincided with the time at which folliculogenesis was also maximally enhanced.

Evidence that hydrogen peroxide blocks hormone-sensitive cholesterol transport into mitochondria of rat luteal cells.

In luteal and granulosa cells, hydrogen peroxide abruptly inhibits activation of adenylate cyclase by receptor-bound gonadotropin and blocks steroidogenesis. In the present studies a post-cAMP site of peroxide action on inhibition of steroidogenesis was investigated. Steroidogenesis, stimulated by dibutyryl or 8-bromo-cAMP, was inhibited by hydrogen peroxide.

Inhibition of gonadotropin action and progesterone synthesis by xanthine oxidase in rat luteal cells.

Hydrogen peroxide produces marked antigonadotropic and lytic actions in luteal cells, but the effects of superoxide, the archetypal oxygen radical, are unknown. Xanthine oxidase generates superoxide, and the activity of this enzyme, and purine substrate, are increased under ischemia, such as that seen at luteal regression. We therefore examined the actions of xanthine oxidase on luteal cells to assess the effects of this enzyme and the superoxide anion on luteal function.

Thymosin gene expression is modulated by pregnant mare's serum gonadotropin, human chorionic gonadotropin, and prostaglandin F2 alpha in the immature rat ovary.

We have investigated thymosin beta 10 mRNA levels in the PMSG/hCG-treated immature rat ovary. Thymosin beta 10 mRNA was constitutively expressed as a single (greater than 600-nucleotide) abundant transcript in the immature rat ovary. Administration of a single dose (50 IU/rat) of PMSG to immature rats resulted in a gradual increase in steady state ovarian thymosin beta 10 mRNA content detectable as early as 12 h and maximal (2-to 3-fold stimulation above preinjection levels) 48 h after PMSG treatment.