George J. Kokoris

Implantation of normal fetal preoptic area into hypogonadal mutant mice: Temporal relationships of the growth of gonadotropin-releasing hormone neurons and the development of the pituitary/testicular axis

Central nervous system tissue which included the preoptic area (an area rich in gonadotropin-releasing hormone neurons) was taken from normal 17-day fetal mice and transplanted into the infundibular recess of the third ventricle of the hypothalamus of 90-day male mutant hypogonadal mouse hosts that are unable to synthesize the neurohormone, gonadotropin-releasing hormone. The growth and development of gonadotropin-releasing hormone neurons and fibers in the donor and host tissue as well as recovery of the pituitary-testicular axis were followed from 10 to 120 days post-implantation. Testicular growth was evident in 94% of the hypogonadal animals within 30 days post-implantation, continued for 90 days but showed no further increase during the remainder of the experiment. Increases in seminal vesicle weight, an index of testosterone secretion, were measurable at 30 days and continued through to the end of the experiment. Pituitary concentrations of gonadotropins were doubled at 30 days over that seen in the control mutant mouse and were maintained thereafter at normal or supranormal concentrations. In contrast plasma levels of gonadotropins, although above baseline at 30 days, never reached normal circulating levels. Nevertheless, it appeared that the concentration of luteinizing hormone achieved was sufficient to initiate and maintain testicular growth and testosterone secretion for the entire duration of the experiment. Immunocytochemical analysis of brain tissue was used to determine the presence and numbers of gonadotropin-releasing hormone neurons in the transplant and the distribution of their fibers in the donor and host tissue. The numbers of immunoreactive gonadotropin-releasing hormone neurons present at the time of sacrifice ranged from 3 to 140. Fiber outgrowth from the donor cells into the host was noted as early as 10 days post-implantation and the density of outgrowth continued to increase over the course of the experiment. Positive fibers tended to accumulate over the tuberoinfundibular sulci as they do in normal animals. In those instances where the transplant was placed a long distance from the median eminence, the gonadotropin-releasing hormone axons grew on the internal surface of the third ventricle until they reached these specific exit zones. These studies indicate that in the mutant hypogonadal mouse, central nervous system transplants from normal fetal mice can maintain the function of the pituitary-gonadal axis for periods of up to 120 days post-implantation. Outgrowth of the neurosecretory fibers begins very soon after implantation and the axons tend to follow pathways seen in normal tissue.(ABSTRACT TRUNCATED AT 400 WORDS)

Plasma LH rises rapidly following mating in hypogonadal female mice with preoptic area (POA) brain grafts

Hypogonadal female mice, genetically deficient in gonadotropin releasing hormone (GnRH), respond to preoptic area (POA) grafts obtained from normal fetal or neonatal mice with increased gonadotropin levels, ovarian and uterine development and continual vaginal estrus rather than spontaneous ovulatory cyclicity. Previous studies showed that such mice became pregnant following one overnight pairing with a normal male, indicating reflex ovulation. The present study evaluated plasma LH concentrations in relation to mating. Plasma LH levels in the hpg females with POA grafts were significantly elevated 10 min following the male partners ejaculation, but were no different than baseline at 30, 60 or 120 min following the males ejaculation. The post-copulatory plasma LH levels of 3.0 +/- 0.6 ng/ml (mean +/- S.E.M.) were considerably lower than the proestrous LH surge seen in the normal females in the colony (16.8 +/- 4.8 ng/ml), but in at least 4 of 10 hpg mice the levels were sufficient to induce ovulation as proved by pregnancy following this single mating. Grafts contained GnRH-reactive cells and fibers that projected to the median eminence of the host brains.

Implantation of fetal preoptic area into the lateral ventricle of adult hypogonadal mutant mice: The pattern of gonadotropin-releasing hormone axonal outgrowth into the host brain

Transplantation of fetal preoptic area tissue containing gonadotropin-releasing hormone neurons into the third ventricle of male hypogonadal mice resulted in an elevation of pituitary gonadotropin levels and correction of hypogonadism. This reversal of the neuroendocrine deficit was correlated with innervation of the median eminence by gonadotropin-releasing hormone axons. The specificity of fiber outgrowth suggested that local neuromodulatory factors might guide these axons to the nearby median eminence. To test this hypothesis, 14 adult hypogonadal males received unilateral fetal preoptic area grafts into the lateral ventricle, a site distant from the median eminence. After four months, healthy grafts containing numerous gonadotropin-releasing hormone neurons were seen in 9 hosts. However, none of these grafts corrected the hypogonadism of the host and there was no gonadotropin-releasing hormone innervation of the median eminence in any of these animals, thus demonstrating that the presence of gonadotropin-releasing hormone neurons in the ventricular space is itself not sufficient to stimulate the pituitary-gonadal axis. Instead, gonadotropin-releasing hormone axons coursed in the host fimbria, fornix, corpus callosum, and stria terminalis. These fibers could be traced into the anterior hippocampal area, medial and lateral septum, and the anterior hypothalamus. The distribution of these fibers included a number of regions which receive gonadotropin-releasing hormone fiber input in the normal mouse. These findings show that gonadotropin-releasing hormone neurons transplanted into the lateral ventricle can survive and extend processes into the host brain, often projecting to sites of normal gonadotropin-releasing hormone innervation. Their success in contacting these sites suggests that gonadotropin-releasing hormone fiber outgrowth may be influenced by regionally specified trophic and/or guidance factors.

Positive Feedback in Hypogonadal Female Mice with Preoptic Area Brain Transplants

When fetal preoptic area (POA) brain grafts that contain gonadotropin-releasing hormone cells are transplanted into the third ventricle of adult female hypogonadal mice, the animals respond with sexual maturation, persistent estrus, and the ability to ovulate reflexively after mating. However, the absence of normal spontaneous ovulatory cyclicity suggests an impairment in positive feedback. We, therefore, studied the effect of administration of progesterone alone or of sequential estradiol benzoate and progesterone on plasma levels of luteinizing hormone (LH) in groups of hypogonadal (HPG) mice in persistent estrus after receiving POA grafts (HPG/POA). Individual differences in responsivity to progesterone were related in part to the length of time in persistent estrus. Approximately 30% of HPG/POA grafts tested 2 months after graft showed increased levels of plasma LH. This was reduced to 10% when animals were tested 5 months after graft. Sequential administration of estradiol benzoate plus progesterone to intact HPG/POA mice was ineffective in elevating LH. The presence of corpora lutea in ovaries verified that only animals with a progesterone induced LH surge ovulated. Other HPG/POA mice were mated, and the occurrence of reflex ovulation was determined. Four of these mice delivered pups: 3 were previous responders to progesterone. One female mated again during the immediate postpartum period and delivered a second litter. Following weaning of all offspring, this animal displayed spontaneous ovarian cyclicity, confirmed by ovarian histology. This is the first proven example of spontaneous ovulation in a mutant mouse with a brain graft. The results show that some HPB/POA mice are capable of positive feedback responses, and rarely, of becoming spontaneous ovulators.

Quantitative analysis of synaptic input to gonadotropin-releasing hormone neurons in normal mice and hpg mice with preoptic area grafts

Mutant hypogonadal (hpg) mice with a truncated gene for the precursor to gonadotropin-releasing hormone (GnRH) show certain aspects of recovery of reproductive function after receiving grafts of normal preoptic area into the third ventricle. We have previously shown that GnRH neurons from within the grafts can innervate the appropriate neural-hemal target in the host. To determine if in turn these exogenously derived neurons receive a synaptic input comparable to the GnRH neurons in the normal animal we have now carried out a quantitative ultrastructural analysis to compare the synaptic input to GnRH neurons in the normal preoptic area and in the grafts. In almost all cases GnRH cells or dendrites in normal brains and within the grafts received a synaptic input. In normal animals, input to GnRH dendritic profiles was significantly greater (P less than 0.001) than to the somatic plasma membrane and this trend was also observed within the grafts though the difference was not statistically significant. In addition, no statistically significant difference was found between the input to GnRH structures within the grafts and in normal preoptic area. However, a substantial variability in input among grafted animals was evident which was not observed in normal animals. The sources of variability within the grafts are discussed and we suggest that the deficiencies and differences that exist in regulation of gonadotropin secretion among grafted hpg animals may be reflected in aberrant synaptic input.

Female sexual behavior in hypogonadal mice with GnRH-containing brain grafts

Hypogonadal female mice respond to GnRH-containing fetal preoptic area (POA) implants in the third ventricle with vaginal opening and persistent vaginal estrus, ovarian, and uterine development and increased gonadotropin secretion. When these females are mated with normal males, reflex ovulation results in pregnancy. In the present study, POA implants derived from neonatal pups, whether male or female, were also capable of supporting reproductive development in the hypogonadal female mice. Evaluation of female sexual behavior in the mice with grafts showed that these mice responded to normal males with comparable levels of lordosis as are seen in normal female mice on the proestrous days of their cycles.

Accessory olfactory bulb transplants correct hypogonadism in mutant mice

Transplantation of normal fetal gonadotropin-releasing hormone (GnRH) neurons from the accessory olfactory bulb (AOB) to the third ventricle of GnRH-deficient adult mutant mice reverses the genetically determined reduction in pituitary hormones and poorly developed gonads. The transplanted heterotopic AOB neurons adapt their morphology and secretory functions to what is observed with preoptic GnRH neurons when transplanted into deficient mice and in the normal intact mature animal. This suggests the presence of median eminence trophic factors affecting the growth, terminal sprouting, and functional behavior of the transplanted neurons.

Thymocyte maturity in male and female hypogonadal mice and the effect of preoptic area brain grafts

Hypogonadal mice with a genetic deficiency of gonadotropin-releasing hormone (GnRH) have low levels of luteinizing hormone (LH), follicle-stimulating hormone (FSH) and gonadal steroids. In this study we found differences from normal mice in many aspects of thymic development. Thymus weights and cellularity were higher in hypogonadal than in normal male mice but lower in hypogonadal than in normal females. Although all normal mice had higher proportions of mature, single staining thymocytes (CD8+ or CD4+) than seen in hypogonadal mice, there was a sex difference in the basis for this shift. Significantly more double-staining (CD8+, CD4+) thymocytes were seen in hypogonadal males than in normal males while both groups had similar single-staining populations. However, in females, both single-staining CD8+ and CD4+ thymocytes were more numerous in normal than in hypogonadal females while numbers of double-staining cells were similar in the two groups. These studies indicate that a mature thymocyte profile may be arrived at through differential effects of reproductive hormones in males and females. When brain grafts containing GnRH cells were used to correct reproductive deficits in hypogonadal mice, there were higher splenocyte counts in males with grafts, a similar trend in females, and a lower ratio of single staining CD4+ to CD8+ thymocytes in all females with grafts vs. all females without, regardless of whether or not the grafts corrected the reproductive hormone status of the recipients, indicating an effect of the graft surgery on the immune system.

The effects of the age of intracerebroventricular grafts of normal preoptic area tissue upon pituitary and gonadal function in hypogonadal (HPG) mice.

Hypogonadal mice are deficient in the hypothalamic gonadotrophic hormone releasing hormone and as a consequence postnatal testicular development does not occur. Grafting preoptic area tissue from normal mice directly into the hypogonadal third ventricle dramatically reverses the hypogonadism; however, the age of the grafted preoptic area tissue is crucial to the survival and function of the graft. Grafting embryonic tissue (E16-18) resulted in 69% of the hypogonadal mice increasing testis weight some sevenfold within 30 days (5.6 to 35 mg). Postnatal day 1 (P1) tissue grafts elicited a similar rise in testis weight in 77% of recipients, whereas P5 tissue was only successful in 22% of cases. In this experimental group, however, testis weight also increased sevenfold compared with hypogonadal untreated mice. Stimulation of testicular growth in the E16-18 and P1 experimental groups was accompanied by an increase in pituitary gonadotrophic hormone content. P10 tissue did not stimulate testis growth nor was pituitary gonadotrophic hormone control elevated and the majority of grafts failed to survive over the 30 day period of the experiment. The present study has shown that the age of grafted tissue is critical in the restoration of physiological function in hypogonadal mice, and that gonadotrophic hormone releasing hormone neurons from E16-18, P1 and P5 preoptic area grafts that survive the 30 day period of the experiment and whose axons reach the median eminence portal vessels are equipotent in stimulating pituitary gonadotrophin synthesis and secretion.

Chapter 15 Functional recovery from neuroendocrine deficits: studies with the hypogonadal mutant mouse

Publisher Summary This chapter discusses the effect on the reproductive physiology of the hypogonadal male host of grafts, containing GnRH cells that were obtained from a region not known to project to the median eminence, and the effect of preoptic area grafts placed in the lateral ventricle far from the median eminence. The chapter also presents measurement of plasma luteinizing hormone (LH) in relation to mating in hypogonadal females with preoptic area grafts to determine the presence of an ovulatory LH surge in mutant animals with preoptic area grafts. The ability of preoptic area grafts to correct deficiencies in reproductive development is an important example of successful neural transplants, demonstrating that grafted neuropeptide-secreting cells may survive, develop axonal projections into the appropriate region of the host brain, and secrete their products in a physiological manner. Graft tissue derived from neonatal mouse brain appears to result in as frequent and vigorous correction of reproductive deficiencies as does tissue derived from fetal brain. Anatomical studies confirm that there are synapses onto gonadotropin hormone-releasing hormone (GnRH) perikarya and dendrites within the grafts, although whether the source is intrinsic or extrinsic to the grafts is not yet defined.