Trophic effects of basic fibroblast growth factor on fetal rat hypothalamic cells: interactions with insulin-like growth factor I

The existence of different growth factors within a single brain region suggests that developing brain cells are exposed to a variety of trophic factors throughout neurogenesis. Cooperative interactions between growth factors are known to orchestrate growth and differentiation of various cell types. We explored the possibility that two growth factors may interact in promoting in vitro growth in fetal hypothalamic cells. We found that basic fibroblast growth factor (b-FGF) exerts trophic effects on primary mixed hypothalamic cell cultures, on enriched hypothalamic neuronal cultures, and on hypothalamic glial cultures. In addition, b-FGF increased the growth rate of two virally transformed hypothalamic cell lines. Since insulin-like growth factor I (IGF-I) also promotes growth of rat hypothalamic cells in vitro, we examined the combined effects of b-FGF and IGF-I on hypothalamic cells. Significantly higher numbers of neurite-bearing cells were present in primary mixed hypothalamic cultures when b-FGF and IGF-I were added together than were added separately. The effect was additive. These results establish b-FGF as a putative hypothalamic neurotrophic factor and demonstrate potential coordinate interactions between IGF-I and b-FGF in stimulating the growth or survival of developing hypothalamic cells.

Cryopreservation of human brain tissue

Tissues from products of conception were examined to determine the feasibility of obtaining viable neural tissue after suction abortion at 9-12 weeks of gestation. The ventral mesencephalon, a prototype region whose maturation can be monitored and which is a potential tissue for transplantation, was identified in 32 of 120 cases. The tissue was then screened for the presence of infectious agents, while being held at -196 degrees C in cryopreservative solutions. Three of 32 specimens were found to be contaminated by normal vaginal bacteria; all other viral, fungal, and mycoplasma testing was negative. Thawed brain fragments retained high viability after storage in liquid nitrogen and when grown in vitro exhibited neuronal morphology, tyrosine hydroxylase immunoreactivity, and dopamine production. We have demonstrated that human fetal brain tissue can be cryopreserved in a manner which not only retains viability but allows normal phenotypic differentiation after thawing.

Estrogen effects on the tuberoinfundibular dopaminergic system in the female rat brain

Estrogen effects on tyrosine hydroxylase (TH), monoamine oxidase types A and B (MAO), and dopamine (DA) in microdissected regions of the hypothalamus, preoptic area and substantia nigra (SNR) of the female rat brain were investigated. Ovariectomized (OVX) young adult female rats were implanted with single silastic capsules containing 100% estradiol valerate (EV). Control rats received empty silastic capsules. Two weeks following capsule insertion, EV decreased TH activity and DA concentration in the arcuate nucleus (AN) while no significant changes in TH activity or DA concentration were observed in the SNR, ventromedial nucleus (VMN), suprachiasmatic nucleus, paraventricular nucleus, medial preoptic nucleus, or the periventricular preoptic nucleus. Although estrogen suppressed TH and DA in the AN, 2 weeks following removal of the estrogen containing capsules, TH activity and DA concentration were restored to control (OVX) levels. Suppression of MAO activity occurred in both the AN and the VMN of rats implanted with EV capsules and returned to OVX levels following the removal of the estradiol load. These results revealed that estrogen effects on TH and MAO activities and DA concentration in the midbrain are region specific and reversible; and that among the dopaminergic systems studied, estrogen effects on TH and DA are confined to the tuberoinfundibular dopaminergic system (TIDAS). Furthermore, these results support our hypothesis that estrogen is a key regulator of DA function in the TIDAS via effects on TH. The importance of these findings to the control of gonadotropin secretion and reproductive cyclicity is discussed.

Gap junctions in the hypothalamic arcuate neurons of ovariectomized and estradiol-treated rats

Freeze-fracture methodology was used to study the organization of the neuronal plasma membrane in the rat arcuate nucleus, an estrogen sensitive area of the hypothalamus. Freeze-fracture replicas were prepared from 6 adult ovariectomized rats injected with a single dose of 17 beta-estradiol and from 6 ovariectomized littermates injected with vehicle. Rats were sacrificed 2 days after the injection. Occasional gap junctions were observed in freeze-fractured neuronal membranes from both groups of animals and their incidence was increased (P less than 0.01) in estradiol treated rats. This study demonstrates gap junctions in arcuate neurons and suggests that these structures may be affected by gonadal hormones.

The effects of estradiol on the growth patterns of estrogen receptor-positive hypothalamic cell lines

Although it appears that the perinatal development of sexual phenotype in the rodent brain is determined by exposure to estradiol, generated locally via aromatization of androgen, the mechanisms underlying this process are not fully understood. We have, therefore, developed an in vitro model of hormone action based upon examining the effects of sex steroids on SV-40-transformed fetal rat hypothalamic cell lines. Using serum-free growth factor-deficient conditions the effects of 17 alpha- and 17 beta-estradiol, testosterone, dihydrotestosterone (DHT), and tamoxifen on survival of two estrogen-binding rat hypothalamic cell lines were examined. In one cell line, RCF-8, both 17 beta-estradiol and testosterone increased survival at picomolar concentrations. This effect was blocked by tamoxifen, but could not be reproduced by the nonaromatizable androgen DHT or the inactive isomer 17 alpha-estradiol. In the other cell line, RCA-6, addition of 17 beta-estradiol led to inhibition of cellular proliferation, which was reversed by the addition of tamoxifen. In an estrogen receptor-negative hypothalamic cell line, RCF-12, estradiol had no net effect on the growth pattern. In summary, the estrogen-binding capacity and the responsiveness to physiological concentrations of estradiol and testosterone, but not DHT, make the RCF-8 cell line a potential in vitro model of hypothalamic sexual differentiation. The use of estrogen-sensitive hypothalamic cell lines provides a unique opportunity for studying the cellular mechanisms underlying this process.

Estrogen effects on the synaptology and neural membranes of the rat hypothalamic arcuate nucleus

The concept of estrogen-induced "sexual differentiation of the brain" has been a useful focus for investigation. However, it has become clear that the action of estrogen on the rat brain is lifelong, including effects on neurogenesis in the fetus, synaptogenesis in the newborn, and synaptic remodeling in the adult. Estrogen imparts sex differences in the rat's brain by shaping synaptology, postsynaptic membranes, and glia within the arcuate nucleus. These effects of estrogen on the arcuate nucleus also could underlie sexual maturation in both sexes and the development of senescent constant estrus in females.

Trophic effects of insulin-like growth factor-I on fetal rat hypothalamic cells in culture

The hypothesis that insulin-like growth factor-I is a trophic factor for primary fetal rat hypothalamic cells was tested, since we previously reported a potent mitogenic effect of this peptide on virally-transformed hypothalamic cells. It was found that insulin-like growth factor-I produced significant and dose-dependent increases in the survival of fetal hypothalamic neurons in primary mixed glial/neuronal cultures. By 48 h in vitro, cultures treated with insulin-like growth factor-I (6 nM) had twice as many neurite-bearing cells as controls, while by day 15 a five-fold difference was present. The peptide was similarly active in promoting neuronal survival in neuron-enriched (98% neurons) hypothalamic cultures. Mixed hypothalamic cultures had specific binding sites for insulin-like growth factor-I. In addition, the neurons grown in the presence of insulin-like growth factor-I had a more differentiated morphology and had significantly higher levels of protein kinase C, an enzyme that increases during neurite formation and synaptogenesis. Finally, glial-enriched cultures (greater than 99% glial cells) obtained from the fetal hypothalamus showed increased [3H]thymidine incorporation in response to insulin-like growth factor-I. These results further support the contention that insulin-like growth factor-I is a neurotrophic factor and suggest that it may participate in the normal development of the hypothalamus by increasing neuronal survival/differentiation and stimulating glial growth.

Yolk sac failure in embryopathy due to hyperglycemia: horseradish peroxidase uptake in the assessment of yolk sac function

We described previously the morphologic alterations of the visceral endodermal yolk sac cells of rat conceptuses cultured under hyperglycemic conditions which occurred concomitantly with major embryonic malformations. To determine whether the transport function of the yolk sac was impaired simultaneously as a result of these hyperglycemic conditions, horseradish peroxidase was used as a tracer protein to assess the transport function of the visceral endodermal yolk sac cells of conceptuses cultured in both control and hyperglycemic media. Cellular uptake of peroxidase, which was added to the culture medium for 3 or 24 hours, was observed in controls. This differed from the marked diminution in peroxidase uptake seen in conceptuses cultured in hyperglycemic medium. These results demonstrate that during hyperglycemia-induced embryopathy, there is concomitant yolk sac failure evidenced by morphologic alterations and impaired endocytosis. These findings therefore strengthen our hypothesis that diabetes-related malformations, as demonstrated experimentally in rat conceptuses, are associated with impairment in the structure and functions of the visceral yolk sac cells during a critical period of organogenesis.

Estradiol induces rapid remodelling of plasma membranes in developing rat cerebrocortical neurons in culture

Exo-endocytotic images and intramembrane particles were quantitatively assessed in freeze-fracture replicas from the plasma membrane of dispersed fetal rat cortical neurons (day 16 gestation) grown for 24 days in culture. The addition of 10(-10) M 17 beta-estradiol to the culture medium resulted in a significant increase in the numerical density of exo-endocytotic images within 1 min. A further increase of the number of exo-endocytotic images associated to a significant decrease in the number of intramembrane particles was observed in cells exposed for 10 min to 17 beta-estradiol. Similar results were observed when the cells were exposed to 17 beta-estradiol for 17 days. No effects on exo-endocytotic images and intramembrane particles were observed when 17 alpha-estradiol was added, instead of 17 beta-estradiol, to the cultures. These results indicate that physiological levels of 17 beta-estradiol can have rapid effects upon the ultrastructure of the neuronal membrane of developing cerebrocortical neurons.

Immunoregulatory activity in supernatants from cultures of normal human trophoblast cells of the first trimester

Supernatants from isolated trophoblast cell cultures (trophoblastic fluid) derived from first-trimester human placentas were assessed for immunoregulatory activity. Trophoblastic fluid at different days of culture consistently inhibited the blast transformation of allogenic lymphocytes. This suppressor effect had no apparent correlation with biosynthesis of human chorionic gonadotropin by trophoblast cells, since this hormone was secreted into the culture fluid only for the initial 3 days. However, the culture fluids of such purified trophoblast cells contained an immunosuppressive factor, pregnancy-associated plasma protein A, which was measurable throughout the culture period of 8 days. The presence of pregnancy-associated plasma protein A in significant amounts in trophoblastic fluid collected at daily intervals indicated a continuous secretion ability of pregnancy-associated plasma protein A by trophoblast cells in culture parallel to the suppressive immunoregulatory effect of the fluid. Such immunosuppressive effect was absent in the culture fluids of control BeWo malignant trophoblast cells; the BeWo cell culture fluids had markedly reduced levels of pregnancy-associated plasma protein A. The culture supernatant of normal trophoblast cells of placentas from first-trimester pregnancy activated in vitro the generation of a population of suppressor lymphocytes. This effect is generally considered responsible for immunologic tolerance. Therefore demonstration of immunosuppressive effects and the presence of relatively high levels of pregnancy-associated plasma protein A in trophoblastic fluid indicate that such proteins secreted by the trophoblast cells may be important in the local immunoregulatory processes of the fetal allograft.

Astrocytic shape and glial fibrillary acidic protein immunoreactivity are modified by estradiol in primary rat hypothalamic cultures

Primary cultures from fetal rat hypothalamus (embryonic day 15-16) were grown for 9 days in a serum-free medium and then fixed and immunostained for glial fibrillary acidic protein (GFAP). The majority of the GFAP-immunoreactive astrocytes were flat, polygonal, without processes and showed a low intensity immunoreactivity which was restricted to the perinuclear region. Elongated, process-bearing astrocytes, with an intense immunoreactivity in the soma and processes, were also observed in a smaller proportion (30%). Addition of estradiol (10(-12) to 10(-8) M) to the culture medium 24 h before GFAP immunostaining resulted in an increased proportion (59-69%) of process-bearing, intense immunoreactive cells. This effect was blocked by tamoxifen (10(-8) M). The total number of GFAP-immunoreactive astrocytes was not modified by estrogen or tamoxifen. These results indicate that estradiol may modulate the cell shape and the distribution of GFAP in astrocytes in culture and suggest that astrocytes can be a target for sex steroids during development of the central nervous system.

Sex differences in plasma membrane concanavalin A binding in the rat arcuate neurons

Previous studies have shown that synaptic connections and organization of neuronal membranes are sexually dimorphic in the arcuate nucleus of developing and adult rats. These sex differences can be abolished by the perinatal androgenization of females. In this study the label-fracture method of Pinto da Silva and Kan was used in order to determine whether membrane sex differences are related to the glycoconjugates in neuronal plasma membranes. Six Sprague-Dawley female rats treated with testosterone on the day of birth, six control females injected with vehicle and six intact males were studied when they were 100 days old. The arcuate nucleus was dissected and incubated for 2 hours in a solution of 0.25 mg/ml concanavalin A, washed in buffer and incubated for 3 hours in a suspension of horseradish peroxidase-coated colloidal gold. Then, freeze-fracture replicas of the arcuate nucleus were prepared. Colloidal gold labeling was observed to be codistributed with intramembrane particles in the outer membrane face of the neuronal perikaryal plasma membrane. The numerical density of small (less than 10 nm) intramembrane particles and colloidal gold particles was significantly greater in control female membranes when compared to males or to androgenized females. The labeling was significantly reduced when the arcuate nucleus was incubated with concanavalin A in presence of 0.5 M methyl-alpha-manopyranoside. These findings indicate a sex difference in the density and distribution of glycoconjugates and intramembranous particles in the neuronal plasma membrane that is dependent on the perinatal levels of sex steroids and is concordant with, and could be the cause of, sex differences in the pattern of synaptic contacts.

Tamoxifen in combination with cytotoxic chemotherapy in advanced epithelial ovarian cancer. A prospective randomized trial

One hundred patients with Stage III and IV epithelial ovarian cancer participated in a prospective randomized study to determine whether the addition of tamoxifen, an estrogen agonist-antagonist, to standard cytotoxic chemotherapy (doxorubicin, cis-diamminedichloroplatinum) would significantly improve survival. Fifty-one patients received the standard cytotoxic chemotherapy and 49 received tamoxifen as well. No significant difference in overall or progression-free survival between these two patient groups was observed. Cytosol steroid receptor determinations were performed on tumor samples from 72 patients. No correlation was evident between therapy and cytosol estrogen and progestin receptor content of the tumors. This study suggests that the strategy of combining an antiproliferative, hormonally active agent with cytotoxic chemotherapy for management of advanced ovarian cancer may be inappropriate.

Characterization of angiotensin II receptors in the rat fetus

The presence of AII receptors during early and late embryonic development was studied by binding of 125I[Sar1, Ile8] AII to whole mouse blastocysts and membrane-rich fractions from rat conceptuses, 7 to 21 days in gestation. In early mouse embryos there was no detectable binding under a variety of experimental conditions. However, in late gestation rat fetuses, specific and high affinity binding was observed, with a concentration of sites similar in membranes from whole and eviscerated fetuses. Using less than 100 micrograms of membrane protein, binding was time and temperature dependent, maintaining equilibrium from 30 to 120 min at 23 degrees C and it was enhanced by addition of Mg+2 up to 5 mM, EGTA 2 mM and dithiothreitol up to 2.5 mM. Scatchard analysis of the binding data indicated Kd values ranging between 0.7 and 0.9 nM. Binding was first detectable at day 10 (14.3 +/- 2.3 fmol/mg), increasing to 104 +/- 16, 2,625 +/- 168, 5,993 +/- 152 and 5,902 +/- 92 by days 12, 15, 18, and 21 of gestational age, respectively. Since the functional significance of these binding sites depends on the availability of the agonist ligand, acid extracts from eviscerated 10-day-old fetuses were analyzed for the presence of AII. Measurement of AII by radioimmunoassay revealed immunoreactive AII-like material (845 pg/g of tissue), with an elution pattern identical to that of AII standard in a Sephadex G-50 column. This material was bioactive, as demonstrated by its ability to displace 125I[Sar1, Ile8]AII from adrenal glomerulosa membranes, an effect which was abolished by pretreatment of the extract with AII antibody.(ABSTRACT TRUNCATED AT 250 WORDS)

Growth promoting effects of IGF-I on fetal hypothalamic cell lines under serum-free culture conditions

Recent evidence indicates that the insulin-like family of peptides may act as endogenous trophic factors in the central nervous system. To further examine this possibility we have investigated the effects of three insulin-like peptides on the in vitro growth of fetal hypothalamic cell lines. Two virally transformed rat hypothalamic cell lines which have been developed in our laboratory (A-6 and F-12) were used. Cells were plated at varying densities and cultured in the presence or absence of either insulin-like growth factor I (IGF-I), insulin, or multiplication stimulating activity (MSA or IGF-II), in serum-free medium for 1 wk. Cell growth was assessed by counting or by measuring cellular incorporation of 3H-thymidine. Of the three peptides tested IGF-I was the most potent in eliciting cell growth. Insulin also stimulated growth of both cell lines, but was 100 times less potent for A-6 cells while it was equipotent with IGF-I in F-12 cells. MSA had no effect on either cell line. Both IGF-I and insulin showed dose-response effects in increasing cell growth. We also found that the two cell lines had the greatest response to IGF-I at low cell densities. Finally, time-course experiments suggested that a continued presence of the peptide is essential for the growth-promoting effects. We conclude that IGF-I is a potent growth factor for virally transformed cell lines derived from the rat fetal hypothalamus. Since both IGF-I immunoreactivity and IGF-I receptors have been located in this diencephalic area these results suggest that IGF-I may constitute a mitogenic signal for hypothalamic cells during neurogenesis.

Immunohistochemical localization of renin and angiotensin II in human ovaries

Ovaries from six women with normal menstrual cycles, a follicle wall biopsy specimen from a gonadotropin-stimulated preovulatory ovary, and a corpus luteum of pregnancy were examined by immunohistochemistry for the presence of immunoreactive renin and angiotensin II. Both antisera densely stained thecal and stromal cells (interstitial complex) and luteal cells. Whereas granulosa cells in developing follicles were either unstained or lightly stained, the heavily luteinized granulosa cells of the preovulatory stimulated follicle were strongly positive for immunoreactive renin and angiotensin II. These anatomic findings are consistent with gonadotropin-stimulated local production of both renin and angiotensin II in the human ovary and support the functional roles proposed for the ovarian renin-angiotensin system in follicle development, ovulation, and luteal function and during pregnancy.

Synaptic remodeling in the rat arcuate nucleus during the estrous cycle

Adult female rats showing regular vaginal cycles were studied in order to determine the number of axosomatic synapses in thin sections of the arcuate nucleus. The number of synapses per length of perikaryal membrane was significantly decreased in estrus, compared to other days of the estrous cycle (P less than 0.05). The reduction in the number of synapses in estrus was accompanied by a decrease in the percentage of the average length of perikaryal membrane covered by presynaptic terminals and by an increase in the percentage of membrane in close apposition of glial processes. Since the average perikaryal perimeter was not significantly changed during the estrous cycle, these results indicate a net decrease in the number of arcuate nucleus axosomatic synapses between proestrus and estrus, with a reinnervation of arcuate neurons between estrus and metestrus. These results suggest that there is a physiological synaptic turnover in the arcuate nucleus of the rat during the estrous cycle.

Fatty acid content of yolk sac and embryo in hyperglycemia-induced embryopathy and effect of arachidonic acid supplementation

Using the postimplantation rat conceptus model, we analyzed with gas-liquid chromatography, the fatty acid composition in major lipid groups (phospholipids, triglycerides, nonesterified fatty acids, and cholesterol esters) of yolk sacs and embryos cultured for 48 hours under control, hyperglycemic, and arachidonic acid-supplemented hyperglycemic conditions. In all experimental conditions the yolk sacs had greater fatty acid content than the embryos in all lipid groups except in nonesterified fatty acids. The fatty acid level in embryonic nonesterified fatty acids was significantly higher (p less than 0.05) in hyperglycemia-exposed embryos than found with arachidonic acid supplementation. Total yolk sac triglycerides were greater with added glucose (p less than 0.05) than with the addition of arachidonic acid to the same medium. Oleic acid, a fatty acid associated with essential fatty acid deficiency, was increased in the embryonic phospholipids and nonesterified fatty acids of conceptuses exposed to excess glucose, as well as in the culture media of this group, compared with the control or arachidonic acid-supplemented, hyperglycemic group (p less than 0.05). The results of this study demonstrate that diabetes-related embryopathy is associated with quantitative and qualitative abnormalities in major lipid groups. Furthermore, the elevation in embryonic oleic acid level suggests that the teratogenic mechanism could be related to a deficiency in essential fatty acids. The pattern of essential fatty acid deficiency and embryopathy was preventable with arachidonic acid supplementation in this experimental model.

Catecholaminergic innervation of luteinizing hormone-releasing hormone and glutamic acid decarboxylase immunopositive neurons in the rat medial preoptic area. An electron-microscopic double immunostaining and degeneration study

Catecholaminergic innervation of luteinizing hormone-releasing hormone (LHRH) and glutamic acid decarboxylase (GAD) immunoreactive neurons in the rat medial preoptic area (MPO) was studied using electron-microscopic (EM) double-label immunostaining and combinations of single- and double-label immunostaining with acute axonal degeneration. The EM double-immunostaining experiments included double staining for either tyrosine hydroxylase (TH) and LHRH, or TH and GAD. Analysis of TH and LHRH double-immunostained material revealed synaptic connections between TH immunoreactive axons and LHRH immunopositive neurons. The TH and GAD double-staining experiments also demonstrated synaptic connections between axons immunoreactive for TH and GAD immunopositive neurons. Two days following unilateral surgical transection of the ventral and dorsal noradrenergic bundles, synaptic connections were found between degenerated boutons and GAD immunoreactive neurons in the ipsilateral MPO. However, no synapses could be observed in the same area between degenerated axons and the LHRH immunopositive neurons. Following the same operation and immunostaining for TH, a moderate number of degenerating TH axons as well as a large number of nondegenerated TH immunoreactive boutons were observed. Double immunostaining for TH and GAD in MPO sections ipsilateral to the operation revealed synaptic connections between the degenerating TH immunopositive axons and GAD immunoreactive neurons. These results suggest that there are direct synaptic connections between catecholaminergic axons and GAD and LHRH immunoreactive neurons in the medial preoptic area of the rat. Some of the connections between TH immunopositive afferents and GAD immunoreactive neurons may represent connections from noradrenergic neurons in the brain stem, while the majority of TH-GAD and TH-LHRH connections may represent innervation of GABA and LHRH neurons from local dopamine-containing cells.

Cryopreservation, culture, and transplantation of human fetal mesencephalic tissue into monkeys

Studies in animals suggest that fetal neural grafts might restore lost neurological function in Parkinson's disease. In monkeys, such grafts survive for many months and reverse signs of parkinsonism, without attendant graft rejection. The successful and reliable application of a similar transplantation procedure to human patients, however, will require neural tissue obtained from human fetal cadavers, with demonstrated cellular identity, viability, and biological safety. In this report, human fetal neural tissue was successfully grafted into the brains of monkeys. Neural tissue was collected from human fetal cadavers after 9 to 12 weeks of gestation and cryopreserved in liquid nitrogen. Viability after up to 2 months of storage was demonstrated by cell culture and by transplantation into monkeys. Cryopreservation and storage of human fetal neural tissue would allow formation of a tissue bank. The stored cells could then be specifically tested to assure their cellular identity, viability, and bacteriological and virological safety before clinical use. The capacity to collect and maintain viable human fetal neural tissue would also facilitate research efforts to understand the development and function of the human brain and provide opportunities to study neurological diseases.

Prognostic significance of the human yolk sac assessed by ultrasonography

Ultrasonographic examinations were conducted between 6 and 12 weeks' gestation in 77 first-trimester pregnancies with normal fetal outcome. Each examination consisted of measurements of the secondary yolk sac diameter and the fetal crown-rump length. The yolk sac was seen in all cases, and whereas its measurements demonstrated wide biologic variability, it correlated weakly (R2 = 0.39) with gestational age as confirmed by crown-rump length measurements. Growth of the yolk sac diameter, although slight, assumed a curvilinear relationship with gestational age. Such a growth profile is best described by a second-degree polynomial regression equation. The yolk sac performs important functions for embryonic development during organogenesis and the remnant of the secondary yolk sac seen on ultrasonography is often considered to be a potential predictor of fetal outcome. Our findings indicate that the size of this remnant in pregnancies with normal karyotypes and normal fetal outcomes is extremely variable. Additionally, the yolk sac size in patients with karyotypic abnormalities and spontaneous abortion were equally variable and almost all were within the normal range. In light of these findings, the secondary yolk sac size does not appear to be a sensitive predictor of embryonic integrity and pregnancy outcome.

Poissons, grenouilles, femmes et hommes: the appropriation and retention of archetypal systems for reproduction

In contradistinction to other biological systems, the reproductive mechanisms in sexually reproducing species are unique in that their success relies upon a synchronous interaction between two separate individuals. Reproduction has become increasingly more efficient as higher forms have developed internal fertilization and gestation. Although our anthropomorphic perspective has dominated the understanding of reproductive processes, 'recent discoveries' make it clear that this reproductive efficiency has been gained by retention of previously present biological mechanisms whose origins are in the vestigial excretory tracts and ducts which are the precursors of the reproductive tract. We refer to these as 'archetypal systems'. They include the interaction between sex steroid sensitive tissues and sex steroids, the renin-angiotensin system and the macrophage/monokine response to infection. Through these mechanisms the reproductive tracts have maintained control over the microenvironment in which the reproductive processes occur. Thus, gamete development in male and female, and fertilization and early embryonic existence in the female tract prior to implantation still occur in compartments which are extracorporeal, i.e., separated from blood or subendothelial spaces, and are controlled by cellular mechanisms found in ancient excretory tracts. Since the majority of the changes between lower forms and contemporary mammals are anatomical modifications which have favoured the success of these extracorporeal events within the developing, generally land-based mammals, we should take special note of lower animals, understanding the evolutionary appropriation of mechanisms designed to furnish the suitable microenvironment from the surrounding tissues.(ABSTRACT TRUNCATED AT 250 WORDS)