Basic fibroblast growth factor selectively increases AMPA-receptor subunit GluR1 protein level and differentially modulates Ca2+ responses to AMPA and NMDA in hippocampal neurons.

The excitatory neurotransmitter glutamate is believed to play important roles in development, synaptic plasticity, and neurodegenerative conditions. Recent studies have shown that neurotrophic factors can modulate neuronal excitability and survival and neurite outgrowth responses to glutamate, but the mechanisms are unknown. The present study tested the hypothesis that neurotrophic factors modulate responses to glutamate by affecting the expression of specific glutamate-receptor proteins. Exposure of cultured embryonic rat hippocampal cells to basic fibroblast growth factor (bFGF) resulted in a concentration-dependent increase in levels of alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA)-receptor subunit GluR1 protein as determined by western blot, dot-blot, and immunocytochemical analyses. In contrast, bFGF did not alter levels of GluP2/3, GluR4, or the NMDA-receptor subunit NR1. Nerve growth factor did not affect GluR1 levels. Calcium-imaging studies revealed that elevation of [Ca2+]i, resulting from selective AMPA-receptor activation, was enhanced in bFGF-pretreated neurons. On the other hand, [Ca2+]i responses to NMDA-receptor activation were suppressed in bFGF-treated neurons, consistent with previous studies showing that bFGF can protect neurons against NMDA toxicity. Moreover, neurons pretreated with bFGF were relatively resistant to the toxicities of glutamate and AMPA, both of which were shown to be mediated by NMDA receptors. These data suggest that differential regulation of the expression of specific glutamate-receptor subunits may be an important mechanism whereby neurotrophic factors modulate activity-dependent neuronal plasticity and vulnerability to excitotoxicity.

Estrogen receptor mRNA alterations in the developing rat hippocampus.

We previously reported transiently elevated ER protein levels in the postnatal rat hippocampus suggesting that this brain region may be sensitive to estrogenic trophic and organizational influences during a 'critical period' of sexual differentiation. In order to examine whether alterations in ER gene expression underlie the ontogenetic pattern of the hippocampal ER, we examined ER mRNA levels over the early postnatal period and in adult rats. This was accomplished by both a highly quantitative RNase protection assay and in situ hybridization histochemistry. Hippocampal ER mRNA levels increased significantly (P < 0.005) between birth and postnatal day (PDN) 4 when peak concentrations were found and then declined by PND-10. Adult male hippocampal ER mRNA values were similar to those found in newborn and PND-10 animals but were significantly less (P < 0.05) than those observed on PND-4. Results from the in situ hybridization experiments correlated well with those from the RNase protection analysis. High levels of ER mRNA were present in the CA3 pyramidal layer with somewhat lower labeling intensities present in CA1 and the dentate gyrus of the PND-4 animal. In contrast, adult male animals demonstrated little hybridization throughout the hippocampus. Thus, the temporal pattern in ER mRNA levels in the hippocampus found in the present study correlates well with our previous developmental profile of the ER protein. These findings suggest that the ontogeny of ER in the hippocampus is regulated by alterations in ER gene expression in specific neuronal populations.

Effect of testosterone and its metabolites upon the level of vasopressin messenger ribonucleic acid in the hypothalamus of the hyperosmotically stimulated male rat.

We previously reported that gonadal steroids modify the expression of arginine vasopressin (AVP) in the hypothalamus of rats administered 2% sodium chloride solution for 5 days. Gonadectomy prevented, and testosterone (T) replacement restored, enhanced AVP mRNA levels in the supraoptic nucleus (SON) of male rats receiving this hyperosmotic challenge. The present study investigated the effects of the androgenic and estrogenic metabolites of T on hypothalamic AVP mRNA levels in response to chronic hyperosmolality. Gonadectomized male rats receiving 2% NaCl for 5 days and treated with T, dihydrotestosterone (DHT), or DHT+estradiol (E2), but not E2 alone or empty implants, had increased AVP mRNA levels compared to gonadectomized animals receiving tap water. Our results support a role for T and DHT-mediated effects upon the enhanced accumulation of AVP mRNA in the SON of male rats receiving a chronic hyperosmotic challenge.

Increased accumulation of oxytocin messenger ribonucleic acid in the hypothalamus of the female rat: induction by long term estradiol and progesterone administration and subsequent progesterone withdrawal.

To examine a possible role for gonadal steroid hormones in the enhanced accumulation of hypothalamic oxytocin (OT) messenger RNA (mRNA) and peptide in late pregnancy, we used an established model (22) in which sequential administration of estradiol (E2) and progesterone (P) SILASTIC capsules to ovariectomized rats is followed by removal of P. Long term and sustained E2 combined with abrupt P withdrawal mimics the gonadal steroid hormone pattern of late gestation in the rat (22). Using this paradigm, we demonstrate that OT mRNA is increased in the rat hypothalamus after long term P treatment, but only in the presence of E2 and only when P capsules are removed 48 h before killing. Furthermore, we show that P replacement in primiparous rats during late pregnancy blunts the increase in OT mRNA normally observed at the end of gestation. Our results support a role for E2 priming and P withdrawal in the enhanced accumulation of OT mRNA in the hypothalamus of the female rat.

Effect of gonadal steroids upon hypothalamic oxytocin expression.

Oxytocin (OT) has been implicated in reproductive events. Gonadal steroids, which are also essential for reproduction, may in these instances influence the expression of the OT gene. The relationship between gonadal steroids and OT expression is incompletely understood. First, although estrogen (E) induces OT expression in heterologous in vitro systems and the OT gene contains an estrogen response element, evidence for a stimulatory effect of E upon OT mRNA in vivo as in the rat hypothalamus has been lacking. Second, an enhanced and coordinated expression of OT and vasopressin (AVP), mRNA during late pregnancy and lactation is not expected. This is especially true in lactation, during which suckling selectively activates OT, not AVP, neurons. We now report that E does increase OT mRNA levels in the rat hypothalamus. Ovariectomized rats were implanted initially with E, followed by progesterone (P) 48 hrs later; both were sustained for 12 days and the P implants were removed 48 hrs prior to sacrifice. By in situ and Northern blot hybridizations, OT, but not AVP, mRNA was increased in the hypothalamus of animals receiving this regimen compared to sham treated cohorts. A similar phenomenon associated with exposure to E and P followed by P withdrawal occurs in physiologic states such as day 21 of pregnancy, day 10-12 of lactation, and with interruption of the suckling stimulus for 48 hrs. If E was not administered or if P was not withdrawn prior to sacrifice, no increase was found in OT mRNA. Our data highlight the pivotal role of P withdrawal in the induction of the hypothalamic OT gene in the E-primed rat.

Gonadal steroid hormone receptors and sex differences in the hypothalamo-pituitary-adrenal axis.

The rapid activation of stress-responsive neuroendocrine systems is a basic reaction of animals to perturbations in their environment. One well-established response is that of the hypothalamo-pituitary-adrenal (HPA) axis. In rats, corticosterone is the major adrenal steroid secreted and is released in direct response to adrenocorticotropin (ACTH) secreted from the anterior pituitary gland. ACTH in turn is regulated by the hypothalamic factor, corticotropin-releasing hormone. A sex difference exists in the response of the HPA axis to stress, with females reacting more robustly than males. It has been demonstrated that in both sexes, products of the HPA axis inhibit reproductive function. Conversely, the sex differences in HPA function are in part due to differences in the circulating gonadal steroid hormone milieu. It appears that testosterone can act to inhibit HPA function, whereas estrogen can enhance HPA function. One mechanism by which androgens and estrogens modulate stress responses is through the binding to their cognate receptors in the central nervous system. The distribution and regulation of androgen and estrogen receptors within the CNS suggest possible sites and mechanisms by which gonadal steroid hormones can influence stress responses. In the case of androgens, data suggest that the control of the hypothalamic paraventricular nucleus is mediated trans-synaptically. For estrogen, modulation of the HPA axis may be due to changes in glucocorticoid receptor-mediated negative feedback mechanisms. The results of a variety of studies suggest that gonadal steroid hormones, particularly testosterone, modulate HPA activity in an attempt to prevent the deleterious effects of HPA activation on reproductive function.

Group process and success in meeting the Joint Commission on Accreditation of Healthcare Organizations review.

Attention to and use of group process with hospital staff can contribute significantly to success in preparing for and passing a review by the Joint Commission on Accreditation of Healthcare Organizations. Group format, key elements, stages of group development, factors to facilitate group work, and the role of the leader are addressed.

Cytoplasmic oxytocin and vasopressin gene transcripts decline postpartum in the hypothalamus of the lactating rat.

Oxytocin (OT) and vasopressin (AVP) gene expression are enhanced in the rat hypothalamus in late gestation and during the second and third weeks of lactation. We report that during the first 3 postpartum days, OT and AVP cytoplasmic mRNAs in the supraoptic and paraventricular nuclei of lactating rats decreased dramatically, reaching less than one fifth of peak gestational levels by day 2 postpartum. Differences in the temporal pattern of OT and AVP expression were observed in the supraoptic and paraventricular nuclei from days 4-10 of lactation. We also compared OT and AVP cytoplasmic mRNAs isolated from the hypothalamus of day 3 lactating rats to cohorts that had litters removed at the time of parturition. Lactating rats had significantly lower OT and AVP cytoplasmic mRNA levels than their nonlactating cohorts. We further compared OT and AVP cytoplasmic mRNAs in the hypothalamus of day 12 lactating rats that had been ovariectomized or sham ovariectomized on day 3 of lactation. Ovariectomized day 12 lactating animals had significantly lower OT and AVP cytoplasmic mRNA levels than their intact cohorts. These data refute the hypothesis that lactation is characterized by persistently elevated hypothalamic cytoplasmic OT and AVP mRNAs produced as a result of continuous stimulation by suckling and suggest that ovarian steroids may exert a modulatory effect on hypothalamic OT and AVP expression during early lactation.

Pediatric home care & public policy.

As children with disabilities and chronic illnesses live longer and benefit from medical and technical advances, their need for pediatric home care increases. This article outlines ways in which advocates of children's health can rally support for home care in the community and with their legislators.

The ontogeny of estrogen receptors in heterochronic hippocampal and neocortical transplants demonstrates an intrinsic developmental program.

We investigated the intrinsic vs. environmental regulation of estrogen receptor (ER) ontogeny in the neocortex, hippocampus and hypothalamus by employing a heterochronic transplantation paradigm. These studies were based on previous reports demonstrating that neural ER develop asynchronously with quantitatively distinct ontogenetic profiles in various brain regions. Fetal (E14-15) hippocampal, frontal cortical or hypothalamic preoptic area (HPOA) primordial tissue was grafted into frontal cortical lesion cavities made in newborn (PND-0) rats. Thus, the grafted tissue was 1 week younger than the host. Two and 4 weeks following transplantation surgery, which corresponds to a theoretical donor age of PND-7 and PND-21, the grafts, a region of the host neocortex surrounding the transplant, and the host hippocampus, frontal cortex or HPOA (depending on graft type) were assayed for ER content using in vitro binding assays. ER concentration in hippocampal grafts at theoretical age PND-7 were significantly higher than those found in the host (PND-14) hippocampus and in the host neocortex adjacent to the transplant. By theoretical graft age PND-21, ER concentration in hippocampal transplants had decreased to levels comparable to those found in the host. This developmental pattern is analogous to that previously reported for the in situ hippocampus. A similar profile of ER concentration corresponding to the donor age developmental timetable was observed in neocortical grafts. ER levels in HPOA grafts did not change from theoretical donor age PND-7 to PND-21, which also corresponds to the normal ontogenetic profile. These data suggest that region-specific developmental patterns of ER expression in the rat brain are specified by embryonic day 14.

Estrogen receptors are present in neocortical transplants.

Fetal neocortical tissue was grafted into neocortical lesion cavities made in newborn rats. After two weeks survival, in vitro binding of [3H]-estradiol to cytosolic preparations provided evidence of estrogen receptors within the transplants. The observed high levels correspond to previous work demonstrating elevated estrogen receptor levels during the first postnatal week in the rat cerebral cortex.

Transient elevation of estrogen receptors in the neonatal rat hippocampus.

The presence of sex differences in hippocampal morphology and function suggests that this brain region may be sensitive to the organizational actions of gonadal steroids. We therefore examined the postnatal development of estrogen receptor (ER) in the rat hippocampal formation. ER was measured by the in vitro binding of [3H]estradiol to a cytosolic preparation. Radioinert R2858 (moxestrol) was used to determine nonspecific binding. Hippocampal ER concentrations increased from birth through postnatal day (PND) 4 when levels peaked (10.05 +/- 1.2 fmol/mg protein); these were maintained through PND-7 (9.45 +/- 1.4) and declined thereafter to low levels characteristic of the adult (2.05 +/- 0.35). This ontogenic profile is similar to that found in several neocortical regions, as well as in the cingulate cortex, but is distinct from that observed in the hypothalamus, where ER levels remain high in the adult. Saturation analysis of PND-7 hippocampal cytosols demonstrated a single, high affinity binding site (Kd: 5.51 +/- 1.7 X 10(-10) M). [3H]Estradiol binding was specific in that it was displaced by radioinert R2858, diethylstilbestrol (DES), and 17 beta-estradiol but not by nonestrogenic steroids. Significantly greater ER levels were found in hippocampal nuclear extracts from DES-treated PND-7 animals compared to controls (9.74 +/- 2.27 vs. 0.49 +/- 0.24 fmol/mg DNA, P less than 0.01). The presence of functional ER was also shown by the ability of receptors to be retained on DNA cellulose. DNA cellulose column chromatography elution profiles for PND-7 hippocampal and medial basal hypothalamic (MBH) cytosols following incubation with [3H]estradiol were similar. The presence of elevated hippocampal ER levels during the perinatal critical period and evidence of functional transformation to the DNA binding state following DES treatment in vivo or estrogen incubation in vitro suggests that the hippocampus is a potential substrate for estrogen-mediated organizational events.

Adaptive plasticity in primate spinal stretch reflex: persistence.

Monkeys can gradually change the amplitude of the wholly segmental, largely monosynaptic, spinal stretch reflex (SSR) when confronted by a task requiring such change (15-19). Change develops over months and may reverse and redevelop at similarly slow rates. We investigated the persistence of SSR amplitude change over nonperformance periods of up to 38 days. Eight animals with chronic EMG electrodes learned to maintain elbow angle and a given level of biceps background EMG against constant extension torque. At random times, a brief additional extension torque pulse elicited the biceps SSR. In the control mode, reward always followed. Under the SSR increase or SSR decrease mode, reward occurred only if the absolute value of biceps EMG in the SSR interval was above or below a set value. Animals completed 3,000-6,000 trials/day over data-collection periods of 2-17 mo. Animals worked first under the control mode for up to 60 days and then under the SSR increase or SSR decrease mode for up to 274 days. Mode was switched once or twice more (SSR increase to SSR decrease or vice versa) over subsequent months. Animals responded to each SSR increase or SSR decrease mode exposure with gradual mode-appropriate change in SSR amplitude. Mode exposures were interrupted by gaps in performance of 10-38 days. Gaps produced transient 10- to 15% decreases in SSR amplitude under the control mode. This nonspecific decrease disappeared over the first week of postgap performance. Under the control mode, gaps had no other effects on SSR amplitude.(ABSTRACT TRUNCATED AT 250 WORDS)

Reduced day-to-day variation accompanies adaptive plasticity in the primate spinal stretch reflex.

Monkeys can change the amplitude of the spinal stretch reflex (SSR), or M1, when reward is made contingent on amplitude. The present study demonstrates that reduced SSR day-to-day variation accompanies such adaptive SSR change. This finding supports the assumption that initial, phase I, SSR change results from contingency-appropriate stabilization of tonic activity in relevant descending spinal cord pathways.

Lunar sample 14425: characterization and resemblance to high-magnesium microtektites.

Measurements by energy-dispersive x-ray analysis of the surface of lunar sample 14425, a large glass bead, yield a noritic composition enriched in aluminum and magnesium and, as compared with other norites, depleted in iron and especially calcium. The sample is close in composition to the most basic microtektites. Spherical inclusions of nickel-iron, flattened where they protrude, are found to be enriched in sulfur and phosphorus, at least at the surface. The inclusions form approximately 1 percent of the volume.

Adaptive plasticity in the primate spinal stretch reflex: evidence for a two-phase process.

Monkeys can slowly increase or decrease the amplitude of the purely spinal, largely monosynaptic portion of the response to sudden muscle stretch, the spinal stretch reflex (SSR), when confronted by a task requiring such change (Wolpaw, J.R., V.A. Kieffer, R.F. Seegal, D.J. Braitman, and M.G. Sanders (1983) Brain Res. 267: 196-200; Wolpaw, J.R., D.J. Braitman, and R.F. Seegal (1983) J. Neurophysiol. 50: 1296-1311). Change occurs without alteration in initial muscle length or in background activity of agonist, antagonist, or synergist muscles. This study uses composite curves to describe in detail the development of SSR amplitude change. It reveals important, previously unexpected features of this development. SSR increase or decrease appears to occur in two distinct phases. Phase I, a nearly immediate 8% change, occurs within the first 6 hr. Phase II, a 2%/day change, continues for at least 2 months. Although phase II is much slower than phase I, its final magnitude is far greater. Phase I indicates a nearly immediate change in suprasegmental influence of the segmental arc of the SSR. Because stretch onset time is unpredictable and the SSR occurs before any other possible response, this change in descending activity must be tonic; it must be present continually, day after day, for the 5 to 7 hr/day the animal spends at the task. Phase I produces a rapid and significant increase in reward probability. Thus, it may be readily interpreted as an example of operant conditioning, provoked by the reward contingency.(ABSTRACT TRUNCATED AT 250 WORDS)

Adaptive plasticity and diurnal rhythm in the primate spinal stretch reflex are independent phenomena.

Recent studies have revealed two phenomena producing considerable variation in amplitude of the initial, purely segmental, largely monosynaptic, response to sudden muscle stretch, the spinal stretch reflex (SSR), without change in background EMG activity or initial muscle length. The first is small and short-term, a modest diurnal rhythm in SSR amplitude. The second is large and long-term, marked adaptive change in SSR amplitude which occurs gradually over weeks and months when animals are rewarded for such change. This second phenomenon may involve persistent segmental alteration, and, if so, could constitute a technically accessible substrate of memory. The present study compared the two phenomena and sought evidence of interaction between them. The diurnal rhythm persisted, without change in phase and with only minimal change in amplitude, despite the occurrence of marked adaptive change. Animals did not utilize the rhythm to increase reward percentage by altering daily performance schedules. These results suggest that the mechanisms of the diurnal rhythm and of adaptive plasticity in SSR amplitude are separate and independent. The diurnal rhythm's effect on movement was not altered by adaptive change in SSR amplitude. This effect was comparable to adaptive change's effect on movement when both were expressed as change in movement/change in SSR amplitude.

Adaptive plasticity in primate spinal stretch reflex: behavior of synergist and antagonist muscles.

Monkeys can gradually change the amplitude of the biceps spinal stretch reflex (SSR) without change in initial muscle length or biceps background electromyographic activity (EMG) (17). We investigated the concurrent behavior of synergist (brachialis and brachioradialis) and antagonist (triceps) muscles. Synergist background EMG remained stable while marked change occurred in biceps SSR amplitude. Triceps background EMG was minimal under all conditions. Thus biceps SSR amplitude change was not due to change in the background activity of closely related muscles. When biceps SSR amplitude changed, synergist SSR amplitude changed similarly but to a lesser extent. Brachialis change averaged 72% of biceps change, while brachioradialis change averaged 33%. By indicating that SSR amplitude change is relatively specific to the agonist muscle, this finding eliminates a number of nonspecific mechanisms as possible origins of SSR amplitude change. Thus it supports the potential value of the SSR as a system for studying the neuronal and synaptic bases of memory in the primate central nervous system (CNS).