Application of a fluorescent dye to study connectivity between third ventricular preoptic area grafts and host hypothalamus.

The mutant hypogonadal (hpg) mouse lacks a functioning gene for the neurohormone gonadotropin releasing hormone (GnRH). Previous studies from our laboratory had indicated that the initiation and maintenance of reproductive function in these mice could be brought about by the implantation of normal fetal grafts into adult hosts. Testicular or ovarian growth and other indicators of normal neurosecretory output were always accompanied by survival of GnRH neurons and growth of GnRH axons into the host median eminence where such axons terminate on the hypophysial portal capillaries. To determine if other connections exist between graft and the host hypothalamus, small crystals of the carbocyanine dye, 1,1'-dioctadecyl-3,3,3',3'-tetramethyl-indocarbocyanine perchlorate (DiI) were applied to either graft or host after fixation of the brain. Tissue sections were analyzed for retrograde and and anterograde movement of the dye. When crystals were placed on the graft, labeled axons were found in the host median eminence or in the host hypothalamus taking an arching trajectory toward the median eminence. Retrogradely labeled neurons in the host were few in number and largely confined to the host arcuate nucleus. With DiI crystals applied to the basal hypothalamus, labeled axons were distributed widely in the host but much sparser in the graft. Axons appeared to enter primarily at sites where the graft and host interface lacked an ependymal lining. Small numbers of retrogradely labeled neurons were also seen in the graft. Most were cells of very simple morphology and were distributed randomly in the graft. When double label experiments were carried out most DiI positive cells in the graft contained GnRH. These results indicate the connectivity between host hypothalamus and the third ventricular preoptic area grafts exists but is limited in nature.

Relationship of glia to GnRH axonal outgrowth from third ventricular grafts in hpg hosts.

The homozygous mutant hypogonadal (hpg) mouse lacks a functional gene for the neuropeptide gonadotropin releasing hormone (GnRH). The consequence of this defect is an infantile reproductive tract in adulthood. This condition can be reversed by the implantation of normal fetal preoptic area tissue that contains GnRH neurons. Reversal is always preceded by the outgrowth of GnRH axons into the host target tissue, the median eminence, by a stereotyped pathway. In the current experiments we investigated the cellular nature of the path taken by early emerging GnRH axons focusing on their relationship with astrocytic components and with the specialized ependymal population of this area, the tanycytes. In control tissue glial fibrillary acid protein (GFAP) immunoreactivity was confined to the exterior of cerebral blood vessels and glial limitans. Both GFAP and vimentin, another intermediate filament protein, marked the specialized ependymal cells of this region, the tanycytes. There was a robust reactive astrocytic response to the injury of transplantation in both the donor and host tissue within 5 days of implantation and the reactive astrocytes persisted for 60 days. These cells were GFAP-positive and were present in many areas of the host along the cannula tract and not confined to the area of GnRH axonal outgrowth. Vimentin, another intermediate filament, marked only the specialized ependymal cells of this region, the tanycytes, in both control and grafted tissue. Despite the profound reactive gliosis, GnRH axons were shown to exit the implant as early as 5 days after grafting suggesting that the gliotic process did not constitute a barrier to this phenomenon. At the light microscopic level, double label immunocytochemical studies did not reveal any specific association between GFAP or vimentin-positive cellular processes and these pioneer GnRH fibers. However, since normal GnRH axons had been reported to travel in tanycytic channels through the medial basal hypothalamus we reinvestigated the pattern of early emerging GnRH axons at the ultrastructural level. With this higher resolution, GnRH axons were found adjacent to glial elements along their entire traverse from the graft-host interface, through the host basal hypothalamus to their termination on the hypophysial portal capillaries. At the interface, GnRH-positive axons appeared to exit via glial channels similar to those described in other developing and regenerating systems. In the host, GnRH immunoreactive axonal profiles were surrounded by glial processes though the latter could not be further defined as tanycytic or astroglial. Other, immunonegative, axons were frequently seen in axonal bundles or fascicles and not necessarily in contact with glia.(ABSTRACT TRUNCATED AT 400 WORDS)

Are neurons of the arcuate nucleus necessary for pathfinding by GnRH fibers arising from third ventricular grafts?

The hypogonadal (hpg) mouse lacks GnRH due to a severe truncation of the gene by which it is encoded. This results in an infertile animal with an infantile reproductive system. When fetal or 1-day postnatal septal/preoptic area of a normal mouse is grafted into the third ventricle of an hpg mouse, GnRH-containing fibers grow out of the grafts and innervate the host median eminence (ME), a normal target of these fibers. GnRH axons exiting the graft course follow a very stereotyped pathway through host tissue. They are observed passing through the ependymal wall of the ventricle directly into the ME or arching through the host arcuate nucleus to terminate in the host ME. Given the fixed pattern of outgrowth, we wanted to determine if the neurons of the arcuate nucleus, which lie between the graft and its target, are exerting an influence on the growth and direction of these fibers. The excitotoxin monosodium glutamate (MSG) has been shown to destroy the vast majority of arcuate neurons when administered neonatally. Mutant host animals treated with MSG received fetal grafts of normal septal/preoptic area. Brains were examined for GnRH fiber outgrowth 30 days later to assess early outgrowth which preferentially uses the arcuate route. We report here that the pattern of outgrowth is virtually identical to that observed in saline-injected, grafted animals. There is also no difference in the success rate of grafts placed in control vs MSG-treated hosts nor in the stimulation of testicular growth. The results of this experiment imply that axonal outgrowth to the ME does not rely on arcuate neurons for guidance information or trophic substances. These functions may be subserved by glia, tanycytes/ependyma, or the target.

Modulation of gonadotropin-releasing hormone neuronal activity as evidenced by uptake of fluorogold from the vasculature.

Peripheral injections of the tracer fluorogold (FG) and immunocytochemistry were used to study the modulation of gonadotropin-releasing hormone (GnRH) cell secretory activity in adult mice. Intraperitoneal administration of FG would make it available to all GnRH terminals outside the blood-brain barrier. The degree of capture of the dye would be linked to exocytotic (e.g., secretory) events at the nerve terminal. Single injections of tracer were made into intact mice of both sexes, and this resulted in the retrograde labeling of two-thirds of the GnRH cell bodies. Administration of identical doses to 3 week castrate mice revealed a reduction in the percentage of GnRH cells, with detectable FG, to 40% of the total. Castration did not diminish the number of GnRH cells visualized. When castrate animals received two doses of FG, the number of GnRH cells with tracer was increased to slightly greater than intact levels. This suggests that the secretory rate of individual GnRH cells might be reduced under conditions of castration. In addition, when ovariectomized females treated with estrogen and progesterone to induce luteinizing hormone (LH) surge were injected with FG just prior to that surge, over 80% of the GnRH neurons were robustly labeled with FG. These latter data are interpreted as representing GnRH neurons at maximally synchronized activity. This study suggests that peripheral administration of FG can be used in this species to follow alterations in neurosecretory rates.

Repair of reproductive deficits by neural transplantation.

Transplantation of brain tissue has been used to ameliorate the genetic lesion of the hypogonadal mutant mouse. This animal does not synthesize gonadotropin-releasing hormone (GnRH) and so has an infantile reproductive system. Implantation of normal fetal or neonatal preoptic area containing GnRH neurons reverses many aspects of the reproductive deficiency. Pituitary and plasma levels of gonadotropins rise, followed by growth of the gonads and sexual organs. Pituitary release of gonadotropins is episodic, suggesting that the grafted tissue is integrated into the "pulse generator." The vast majority of grafted animals do not show castration-induced elevations of luteinizing hormone (LH) nor respond to exogenous steroids with a depression in circulating LH. Negative feedback of gonadal steroids seems to be inoperative. In contrast, some females can show ovulatory surges of LH in response to mating (reflex ovulation), after administration of exogenous steroid (progesterone), and, on rare occasion, ovulation cycles occur spontaneously. Anatomical studies demonstrate that reproductive recovery is dependent on the outgrowth of GnRH axons to the host median eminence. Some but not all of the GnRH neurons within the grafts contribute to this innervation. GnRH axons exit into the host along well-defined pathways, recapitulating in part the paths taken by normal axons. How the graft and host are integrated to produce the panoply of reproductive responses is the subject of current study.

Identification of gonadotropin releasing hormone (GnRH) neurons projecting to the median eminence from third ventricular preoptic area grafts in hypogonadal mice.

Functional gonadotropin releasing hormone (GnRH) neurosecretory activity can be restored in genetically hypogonadal (hpg) adult mice with grafts of GnRH-containing fetal or neonatal septal-preoptic area (S/POA) tissue. Neurons implanted into the third ventricle of the host brain survive and send out axons which innervate one of the normal targets of these neurons, the median eminence (ME). Fibers terminate near primary portal vessels where GnRH is available for release into the vasculature, and this axonal outgrowth is essential for the stimulation of gonadotropin secretion, gonadal and accessory sex structure growth, gametogenesis, and fertility. Although it is known that GnRH axons reach their target, it is not known if all such neurons in a graft contribute to the projection. Taking advantage of the fact that axons in the ME, the sole host target, are outside the blood-brain barrier (BBB), long-term grafted animals were injected intraperitoneally with a retrograde tracer, Fluorogold (FG). Normal male mice were injected for comparison. Animals were sacrificed 5 days after injection and brain sections in the area of the graft were stained immunocytochemically for GnRH. In the normal male mice, two-thirds of the GnRH neurons were double-labeled with FG. In grafted individuals which showed increased gonadal growth, the percentage of labeled cells ranged from 17 to 75%. The results indicate that despite tissue injury, ectopic location, and a vastly reduced population, transplanted fetal GnRH neurons recapitulate a pattern seen in normal intact mice where some but not all neurons were capable of capturing a peripherally delivered tracer.

Structural and functional links between olfactory and reproductive systems: puberty-related changes in olfactory epithelium.

The structural and functional link between olfactory reproductive systems in male and female platyfish (Xiphophorus maculatus) is demonstrated by the connection of receptors in the nasal epithelium to a center in the brain that has a primary role in the development and functioning of the reproductive system. Profound morphological changes occur in the nasal epithelium, and LH-RH content increases in tracts of the olfactory lobe, at specific stages of sexual maturation and not according to chronological age. Our study provides new insight into the development of the mechanisms by which chemical environmental cues are received.