Tandra R. Chakraborty

Aging-Related Changes in Ovarian Hormones, Their Receptors, and Neuroendocrine Function

Ovarian steroid hormones exert a broad range of effects on the body and brain. In the nervous system, estrogen and progesterone have crucial feedback actions on the hypothalamic neurons that drive the reproductive axis. In addition, hormones exert a variety of actions on other traditionally nonreproductive functions such as cognition, learning and memory, neuroprotection, mood and affective behavior, and locomotor activity. The actions of hormones on the hypothalamus are largely mediated by their nuclear hormone receptors, the two estrogen receptors, ERα and ERβ, and the two progesterone receptor isoforms, PR-A and PR-B. Thus, changes in the circulating concentrations of estrogens and progestins during the life cycle can result in differential activation of their receptors. Furthermore, changes in the numbers, activity, and distribution of hypothalamic ERs and PRs can occur as a function of developmental age. The purpose of this article is to review the literature on the causes and consequences of alterations in steroid hormones, their neural receptors, and their interactions on reproductive senescence. We have also discussed several important experimental design considerations, focusing on rodent models in current use for understanding the mechanisms of menopause in women.

Stereologic analysis of estrogen receptor alpha (ERα) expression in rat hypothalamus and its regulation by aging and estrogen

The estrogen receptor alpha (ERα) in the hypothalamus plays important roles in the regulation of reproductive development, physiology, and behavior. However, the expression of the ERα may change during aging or in response to varying estrogen levels. The present study measured changes in the numbers of ERα‐expressing cells in specific hypothalamic and preoptic nuclei of ovariectomized female Sprague‐Dawley rats at three ages (young [3–4 months], middle‐aged [10–12 months], or old [24–26 months]) and with or without estrogen replacement. Numbers of ERα‐immunoreactive neurons were quantified in four regions relevant to reproductive function: the anteroventral periventricular nucleus (AVPV), medial preoptic nucleus (MPN), arcuate nucleus (ARH), and ventromedial nucleus (VMN), using an unbiased stereologic approach. In the AVPV and VMN, significant age‐related increases in the numbers of ERα‐expressing cells from the middle‐aged to the old group were detected, and no differences were observed in the MPN and ARH, indicating that ERα neuron number is maintained or even elevated during aging. No significant effects of estrogen on ERα cell number were detected in any of the four regions studied. Therefore, ERα cell number in the rat hypothalamus and preoptic area changes with aging in a region‐specific manner. J. Comp. Neurol. 466:409–421, 2003.

Analysis of knockout mice suggests a role for VGF in the control of fat storage and energy expenditure

BackgroundPrevious studies of mixed background mice have demonstrated that targeted deletion of Vgf produces a lean, hypermetabolic mouse that is resistant to diet-, lesion-, and genetically-induced obesity. To investigate potential mechanism(s) and site(s) of action of VGF, a neuronal and endocrine secreted protein and neuropeptide precursor, we further analyzed the metabolic phenotypes of two independent VGF knockout lines on C57Bl6 backgrounds.ResultsUnlike hyperactive VGF knockout mice on a mixed C57Bl6-129/SvJ background, homozygous mutant mice on a C57Bl6 background were hypermetabolic with similar locomotor activity levels to Vgf+/Vgf+ mice, during day and night cycles, indicating that mechanism(s) other than hyperactivity were responsible for their increased energy expenditure. In Vgf-/Vgf- knockout mice, morphological analysis of brown and white adipose tissues (BAT and WAT) indicated decreased fat storage in both tissues, and decreased adipocyte perimeter and area in WAT. Changes in gene expression measured by real-time RT-PCR were consistent with increased fatty acid oxidation and uptake in BAT, and increased lipolysis, decreased lipogenesis, and brown adipocyte differentiation in WAT, suggesting that increased sympathetic nervous system activity in Vgf-/Vgf- mice may be associated with or responsible for alterations in energy expenditure and fat storage. In addition, uncoupling protein 1 (UCP1) and UCP2 protein levels, mitochondrial number, and mitochondrial cristae density were upregulated in Vgf-/Vgf- BAT. Using immunohistochemical and histochemical techniques, we detected VGF in nerve fibers innervating BAT and Vgf promoter-driven reporter expression in cervical and thoracic spinal ganglia that project to and innervate the chest wall and tissues including BAT. Moreover, VGF peptide levels were quantified by radioimmunoassay in BAT, and were found to be down-regulated by a high fat diet. Lastly, despite being hypermetabolic, VGF knockout mice were cold intolerant.ConclusionWe propose that VGF and/or VGF-derived peptides modulate sympathetic outflow pathways to regulate fat storage and energy expenditure.

Phosphatidic Acid Synthesis in Mitochondria TOPOGRAPHY OF FORMATION AND TRANSMEMBRANE MIGRATION

The topography of formation and migration of phosphatidic acid (PA) in the transverse plane of rat liver mitochondrial outer membrane (MOM) were investigated. Isolated mitochondria and microsomes, incubated with sn-glycerol 3-phosphate and an immobilized substrate palmitoyl-CoA-agarose, synthesized both lyso-PA and PA. The mitochondrial and microsomal acylation of glycerophosphate with palmitoyl-CoA-agarose was 80–100% of the values obtained in the presence of free palmitoyl-CoA. In another series of experiments, both free polymyxin B and polymyxin B-agarose stimulated mitochondrial glycerophosphate acyltransferase activity approximately 2-fold. When PA loaded mitochondria were treated with liver fatty acid binding protein, a fifth of the phospholipid left the mitochondria. The amount of exportable PA reduced with the increase in the time of incubation. In another approach, PA-loaded mitochondria were treated with phospholipase A2. The amount of phospholipase A2-sensitive PA reduced when the incubation time was increased. Taken together, the results suggest that lysophosphatidic acid (LPA) and PA are synthesized on the outer surface of the MOM and that PA moves to the inner membrane presumably for cardiolipin formation.

Estrous cycle in ob/ob and ovariectomized female mice and its relation with estrogen and leptin.

Hormones like leptin and estrogen have been suggested to increase energy expenditure and modulate estrous cycle. The aim of this study was to investigate the stages of estrous cycle in mouse models with contrasting leptin and estrogen levels. Estrous cycle of wild type (WT), WT ovariectomized (OVX), ob/ob and ob/ob OVX was observed by obtaining vaginal smear and staining with Papanicolaou (PAP) procedure. Quantitative analysis showed cellular morphology and predominance of cellular content across the estrous cycle. Microscopical and quantitative counts showed a 4-5 day regular cycle in WT mouse, WTOVX were acyclic, infertile and hardly showed any cells, ob/ob and ob/ob OVX were both acyclic, infertile and were at persistent estrous or persistent metaestrous phase. Enzyme-Immunometric Assay results showed that leptin levels were about 3 fold higher in WTOVX than WT mouse (p<0.0001) with beta-estradiol values being negligible in WTOVX. The beta-estradiol levels for ob/ob and WT were similar. These results suggest that although leptin and estrogen play an important role in the estrous cycle, they are not the sole factor influencing the cycle. It is probable that in the absence of leptin and decrease in sex steroid hormones with increase in acyclicity, the central nervous system probably interprets the circulation as absence of energy stores and shuts down reproduction indicated by the changes in the estrous cycle.

Quantification of VGF- and pro-SAAS-derived peptides in endocrine tissues and the brain, and their regulation by diet and cold stress.

Two novel granin-like polypeptides, VGF and pro-SAAS, which are stored in and released from secretory vesicles and are expressed widely in nervous, endocrine, and neuroendocrine tissues, play roles in the regulation of body weight, feeding, and energy expenditure. Both VGF and pro-SAAS are cleaved into peptide fragments, several of which are biologically active. We utilized a highly sensitive and specific radioimmunoassay (RIA) to immunoreactive, pro-SAAS-derived PEN peptides, developed another against immunoreactive, VGF-derived AQEE30 peptides, and quantified these peptides in various mouse tissues and brain regions. Immunoreactive AQEE30 was most abundant in the pituitary, while brain levels were highest in hypothalamus, striatum, and frontal cortex. Immunoreactive PEN levels were highest in the pancreas and spinal cord, and in brain, PEN was most abundant in striatum, hippocampus, pons and medulla, and cortex. Since both peptides were expressed in hypothalamus, a region of the brain that controls feeding and energy expenditure, double label immunofluorescence studies were employed. These demonstrated that 42% of hypothalamic arcuate neurons coexpress VGF and SAAS peptides, and that the intracellular distributions of these peptides in arcuate neurons differed. By RIA, cold stress increased immunoreactive AQEE30 and PEN peptide levels in female but not male hypothalamus, while a high fat diet increased AQEE30 and PEN peptide levels in female but not male hippocampus. VGF and SAAS-derived peptides are therefore widely expressed in endocrine, neuroendocrine, and neural tissues, can be accurately quantified by RIA, and are differentially regulated in the brain by diet and cold stress.

Expression of Estrogen Receptor α in the Anteroventral Periventricular Nucleus of Hypogonadal Mice

Gonadotropin-releasing hormone-1 (GnRH-1) neurons play critical roles in the development and maintenance of reproductive function in all vertebrates. Due to a truncation in the GnRH-1 gene, hypogonadal (hpg) mice are unable to synthesize GnRH-1 and are Infertile. These animals develop in the complete absence of exposure to gonadal steroid hormones, making them an interesting model for understanding brain sexual differentiation and dimorphism. We studied expression of the estrogen receptors (ERs) α and β in the medial anteroventral periventricular nucleus (mAVPV), an important reproductive neuroendocrine brain region, in wild-type and hpg mice of both sexes. Adult wild-type and hpg mice of the same genetic background were used to quantify numbers of ERα and ERβ immunoreactive cells in the mAVPV using a stereologic approach. Quantitative analyses showed that ERα cell numbers were significantly higher In hpg than wild-type mice, irrespective of sex. Qualitatively, ERα-immunoreactive cells were concentrated more densely along the ventricular zone of the AVPV of wild-type female mice compared with wild-type male mice or hpg male and female mice. No ERβ-immunoreactive cells were detected in the mAVPV of any mice, a result that was surprising because ERβ expression is abundant in the mAVPV of rats. These results on ERα provide additional evidence that the female brain is not the “default” organizational pattern, because neither ERα cell number nor its distribution in hpg mice, which develops with a deficiency of reproductive hormones, resembles that of the wild-type female mouse. Differences in ERα expression may be due in part to the absence of gonadal steroid hormones, although they more likely to also involve othc factors, potentially GnRH itself.

Stereological analysis of estrogen receptor expression in the hypothalamic arcuate nucleus of ob/ob and agouti mice.

Circulating gonadal steroid levels affect metabolic homeostasis by regulating appetite and food intake. The actions of estrogen are mediated through its two receptors ERalpha and ERbeta. ERalpha expression is necessary to maintain normal food intake, body weight and adiposity. Leptin plays a central role in regulating feeding behavior, homeostasis and reproduction. It is known that there is an effect of estrogen and leptin on feeding behavior. The present study was undertaken 1) to assess the changes in the reproductive cycle in obese, infertile ob/ob mice with no circulating leptin and infertile, obese, agouti (Ay/a) mice with high circulating leptin levels, 2) to evaluate the hypothalamic distribution of ERalpha and ERbeta, and 3) to analyze the differences in expression of ERs related to leptin and beta-estradiol levels in these mouse lines. The results show that the ob/ob and Ay/a mice were acyclic and were at a persistent estrous phase. The beta-estradiol levels were similar between WT, ob/ob and Ay/a mice. Stereologic analysis showed that there were significantly higher numbers of ERalpha-immunoreactive cells in ob/ob mice irrespective of sex when compared to wild-type (WT) in arcuate nucleus (ARH) and no significant change in ERbeta immunoreactive cell numbers in ARH or paraventricular nucleus (PVN). Ovariectomy in female wild-type mice caused a 50% increase of ERalpha-immunoreactive cells. Results suggest that leptin and estrogen act via the same neuronal circuits to affect reproduction, neuroendocrine and behavioral processes. However, estrogen levels and acyclicity have more profound effect on the regulation of ERalpha cell numbers in the ARH than circulating leptin levels.

Identification of two transmembrane regions and a cytosolic domain of rat mitochondrial glycerophosphate acyltransferase.

The topography of rat glycerophosphate acyltransferase (GAT) in the transverse plane of the mitochondrial outer membrane (MOM) was investigated. Computer analysis of the amino acid (aa) sequence derived from rat mitochondrial GAT cDNA (GenBank™ accession nos. U36771 and AF021348) predicts the presence of two possible transmembrane domains (aa 473–493 and 574–594) separated by an 80-aa stretch (aa 494–573). To determine the actual orientation of the native protein, we prepared anti-peptide antibodies to three regions: one in between (aa 543–559) and the other two (aa 420–435 and 726–740) flanking the two putative transmembrane regions. Both immunoreaction and immunoprecipitation experiments employing intact and solubilized mitochondria indicate that regions on the N- and C-terminal sides of the transmembrane regions are sequestered on the inner surface of the MOM, while the region between the transmembrane domains is present on the cytosolic face of the MOM. Additionally, two green fluorescent protein (GFP) fusion proteins consisting of full-length GAT fused to GFP at either the C terminus or inserted 115 amino acids from the N terminus were also constructed to determine the orientation of the N and C termini. COS-1 cells expressing these fusion proteins were fractionated to obtain mitochondria. Protease digestion of intact and solubilized COS-1 cell mitochondria revealed that the GFP domains of these fusion proteins are sequestered on the inner side of the MOM. The present findings indicate that GAT is a dual-spanning, transmembrane protein adopting an inverted “U” conformation in the transverse plane of the MOM, where the N and C termini are sequestered on the inner surface of the MOM, while aa 494–573 are exposed on the cytosolic surface of the MOM.

Long-Term High Fat Diet Has a Profound Effect on Body Weight, Hormone Levels, and Estrous Cycle in Mice

Background Obesity causes several health complications along with disruption of the reproductive system. The aim of the current study was to determine how long-term intake of very high fat diet (VHFD) changes the hormonal milieu, affecting the cellular morphology and reproductive cycle in female mice. Material/Methods Mice were fed on normal diet (ND) and VHFD for 2 weeks, 12 weeks, and 25–27 weeks. We assessed changes in body weight, food consumption, energy intake, cellular and tissue morphology, hormonal levels (leptin, insulin, and estradiol), and vaginal smears were performed at various time points to determine the length and cellularity at each stage of the estrous cycle. Results Mice fed on VHFD showed a significant increase in weight gain, reduction in food intake, and increase in energy intake compared to animals fed on ND, indicating that the caloric density of the diet is responsible for the differences in weight gain. Hormonal analysis showed hyperleptinemia, hyperinsulinemia, and increases in estrogen levels, along with increases in size of the islet of Langerhans and adipocytes. After 25–27 weeks, all animals fed on VHFD showed complete acyclicity; elongation of phases (e.g., diestrous), skipping of phases (e.g., metestrous), or a combination of both, indicating disruption in the reproductive cycle. Quantitative analysis showed that in the diestrous phase there was a 70% increase in cell count in VHFD compared to animals fed on ND. Conclusions The above results show that morphological and hormonal changes caused by VHFD probably act via negative feedback to the hypothalamic-pituitary axis to shut down reproduction, which has a direct effect on the estrous cycle, causing acyclicity in mice.