Gary J. Romano

Estrogen regulation of proenkephalin gene expression in the ventromedial hypothalamus of the rat: temporal qualities and synergism with progesterone

Estrogen has been shown to increase proenkephalin (PE) mRNA levels in neurons of the ventrolateral aspect of the ventromedial hypothalamic nucleus (VL-VM). In this series of experiments, we examined the temporal qualities of this induction by determining both the latency of the estrogen-induced elevation in PE mRNA levels and the rate at which the message levels decline following removal of estrogen. In addition we have examined the effects of progesterone on PE gene expression in the VL-VM of estrogen-primed rats. The latency of the estrogen-induced elevation in PE mRNA levels was found to be relatively short: PE mRNA levels were increased 2-fold within 1 h of estrogen replacement. Following estrogen removal the levels of PE mRNA declined rapidly. Progesterone treatment attenuated this decline, prolonging the estrogen-induced elevation of PE mRNA levels. These results suggest that estrogen rapidly increases PE mRNA levels through a mechanism that probably involves alterations in both the rate of appearance and the rate of degradation of the message. Together, the short latency of the estrogen-induced elevation and the rapid rate of decay following estrogen removal indicate that PE gene expression is highly sensitive to fluctuating estrogen levels. The effect of progesterone suggests that this enkephalinergic system may be regulated by both estrogen and progesterone during the estrous cycle.

Sex difference in estradiol regulation of progestin receptor mRNA in rat mediobasal hypothalamus as demonstrated by in situ hybridization.

Previous studies have shown that estrogen increases the level of progestin receptors (PR) to a greater extent in female than in male rat hypothalamus. In order to determine if sex-specific regulation of the PR protein might be attributable to estrogenic effects on the PR message, in situ hybridization was used to assess sex differences in levels of estrogen-inducible PR mRNA in specific brain nuclei. Here, we report a sexually differentiated pattern of estrogen-regulated PR gene expression. In female hypothalamus, estrogen administered to gonadectomized rats induced a 3.6- and a 3.3-fold increase in PR mRNA in the ventrolateral aspect of the ventromedial nucleus and arcuate nucleus, respectively, but failed to alter the level of PR mRNA in the same neuronal groups of the male. Hormone treatment did not affect the levels of PR mRNA in the dorsomedial or medial amygdaloid nuclei of either sex. These results lead towards a molecular explanation of sex differences in female reproductive behavior by revealing an estrogen-dependent up-regulation of the message for PR, a transcription factor, in a region- and sex-specific fashion.

Estradiol Regulation of Estrogen Receptor Messenger Ribonucleic Acid in Rat Mediobasal Hypothalamus: An in situ Hybridization Study

We have used in situ hybridization to investigate estradiol regulation of estrogen receptor (ER) mRNA in regions of the mediobasal hypothalamus which contain ER and are related to specific neuroendocrine functions. Ovariectomized rats were treated with oil or 10 μg estradiol benzoate for 2, 4, 18 or 24 h. Brains were sectioned and hybridized with a [3 H]single‐stranded DNA probe prepared from the pORF cDNA of the human ER gene and exposed to autoradiographic emulsion for 4 months. Specificity of labeling was determined by counting the number of grains over cells in hypothalamic regions known to bind estradiol, compared to cells in the thalamus and cortex, and by comparing with sections pretreated with ribonuclease or hybridized with a [3 H]single‐stranded message‐sense (control) probe. Labeling for ER mRNA was distributed differently than glucocorticoid and thyroid hormone receptor mRNAs, and was regulated by estrogen differently than progestin receptor mRNA. These differences indicated specific hybridization for ER mRNA. ER‐expressing cells constituted 11.5% of the cells in the dorsomedial nucleus, 30% of the cells in the arcuate nucleus and 43% in the ventromedial nucleus, in close accordance with previous studies of ER autoradiography and binding. Quantitative analysis showed that the highest level of ER mRNA was present in the ovariectomized controls. ER mRNA levels fell 42% (ventromedial), 64% (arcuate), or remained unchanged (dorsomedial) 18 h following estradiol benzoate treatment. The pattern of decrease was similar for cells in the ventromedial nucleus and arcuate nucleus. These data show that estrogen regulation of ER mRNA in brain parallels that reported for MCF‐7 cells and rat uterus. These results also demonstrate that in situ hybridization can be used to detect and measure the relative level of a low abundance mRNA in a heterogeneous tissue in which only 12% to 40% of the cells in limited regions express the message.

Haloperidol increases proenkephalin mRNA levels in the caudate-putamen of the rat: a quantitative study at the cellular level using in situ hybridization

Previous immunocytochemical studies have shown that the opioid peptides, Met-enkephalin and Leu-enkephalin, are present in medium-sized, spiny projection neurons of the caudate-putamen. It has also been demonstrated that chronic treatment of rats with the dopamine receptor blocker, haloperidol, results in an increase in the levels of enkephalin peptides and proenkephalin mRNA in this brain region. To determine whether this increase in proenkephalin mRNA content is exhibited by all enkephalinergic neurons of the caudate-putamen or by only a subpopulation, we have used in situ nucleic acid hybridization to examine the haloperidol-induced increase in proenkephalin mRNA levels at the cellular level. Results of in situ hybridization suggest that all enkephalinergic neurons in the caudate-putamen can respond to haloperidol treatment with an increase in steady state levels of proenkephalin mRNA, and that the mean induction is an approximate 3-fold increase in the message levels. This suggests that dopamine exerts a tonic inhibitory effect on the expression of the proenkephalin gene in all of the enkephalinergic neurons of the caudate-putamen. Dot blot analysis indicated a 2.4-fold increase in the tissue levels of this mRNA. The agreement between the in situ hybridization results and dot blot analysis supports in situ hybridization as a reliable method for quantitative studies of alterations in neuropeptide precursor mRNAs in the brain.

Differential regulation of proenkephalin gene expression by estrogen in the ventromedial hypothalamus of male and female rats: implications for the molecular basis of a sexually differentiated behavior

The ventrolateral aspect of the ventromedial hypothalamic nucleus (VL-VM) contains many estrogen-concentrating neurons which mediate estrogen facilitation of reproductive behavior. Previous studies have shown that estrogen treatment increases proenkephalin (PE) gene expression in neurons of the VL-VM in ovariectomized female rats, and that enkephalin peptides may stimulate lordosis behavior. To determine whether there is a sex difference in steroid hormone regulation of PE gene expression we have examined the effects of estrogen and testosterone on PE mRNA levels in male rats. Slot blot hybridization analysis of RNA isolated from the ventromedial hypothalamus indicated that estrogen treatment increased PE mRNA levels in the VL-VM of ovariectomized female rats (2.2-fold), but had no measurable effect on PE mRNA levels in gonadectomized males. Testosterone treatment of gonadectomized males also had no effect on PE gene expression. To determine whether the sex difference in estrogen-inducibility of PE gene expression is due to the developmental effects of gonadal steroids, we have investigated the effect of estrogen on PE mRNA levels in the VL-VM of neonatally androgenized female rats. Unlike the genetic male, the androgenized females responded to estrogen treatment with a female-typical increase in PE mRNA levels (1.7-fold). Further, although the androgenized rats clearly exhibited signs of defeminization, they did exhibit estrogen-facilitated lordosis behavior when tested with manual stimulation. The PE mRNA induction in estrogen-treated androgenized rats correlated well with the lordosis scores obtained by manual stimulation testing. These results indicate that estrogen regulation of PE gene expression in the VL-VM is sexually differentiated and support the hypothesis that the enkephalinergic neurons of the VL-VM are involved in the regulation of female reproductive behavior.

Gene expression for estrogen and progesterone receptor mRNAS in rat brain and possible relations to sexually dimorphic functions

A clear neuroendocrine sex difference lies in the ability of the female rat to produce an ovulatory surge of luteinizing hormone. Preoptic neurons, as they respond to estrogen and progesterone, have been proven to be involved in this mechanism, with an emphasis on the possible participation of neurons in the anteroventral periventricular nucleus and the suprachiasmatic portion of the preoptic area (POA). Further, prominent morphological sex differences have been reported in the rat medial POA. To examine expression of the estrogen receptor (ER) and the progesterone receptor (PR) messenger RNAs (mRNAs) in these critical preoptic neurons, we have used in situ hybridization with tritiated single-stranded DNA probes complimentary for ER and PR mRNA. ER mRNA containing cells were found in the periventricular, suprachiasmatic and medical preoptic cell groups, in a manner which agrees with steroid hormone autoradiography. In the female rat, preoptic neurons expressing PR mRNA were distributed very similarly to those for ER mRNA. Moreover, in the male rat brain, all subsets of preoptic neurons which express the PR gene in the female were also detected in the male. Thus, the distribution of PR expressing cells was very similar between females and males. We conclude that the insensitivity to the male to progesterone, as regards the hormonal control of ovulation, cannot be due to a total failure of PR gene expression in a specific subset of POA neurons. Instead, male preoptic neurons must be less sensitive to neural or hormonal inducers in the physiological range or perhaps lack sufficient levels of a transcription factor linking progesterone responsive elements to the start sites of hormone-controlled genes.