BACKGROUNDTesticular germ cell tumours (TGCT) are thought to originate from fetal germ cells that fail to differentiate normally, but no animal model for these events has been described. We evaluated the marmoset (Callithrix jacchus) as a model by comparing perinatal germ cell differentiation with that in humans.METHODSImmunohistochemical profiling was used to investigate germ cell differentiation (OCT4, NANOG, AP-2γ, MAGE-A4, VASA, NANOS-1) and proliferation (Ki67) in fetal and neonatal marmoset testes in comparison with the human and, to a lesser extent, the rat.RESULTSIn marmosets and humans, differentiation of gonocytes into spermatogonia is associated with the gradual loss of pluripotency markers such as OCT4 and NANOG, and the expression of germ cell-specific proteins such as VASA. This differentiation occurs asynchronously within individual cords during fetal and early postnatal life. This contrasts with rapid and synchronous germ cell differentiation within and between cords in the rat. Similarly, germ cell proliferation in the marmoset and human occurs throughout perinatal life, in contrast to rats in which proliferation ceases during this period.CONCLUSIONSThe marmoset provides a good model for normal human germ cell differentiation and proliferation. The perinatal marmoset may be a useful model in which to establish factors that lead to failure of normal germ cell differentiation and the origins of TGCT.
BACKGROUNDAbnormal fetal testis development can result in disorders of sex development (DSDs) and predispose to later testicular dysgenesis syndrome (TDS) disorders such as testicular germ cell tumours. Studies of human fetal testis development are hampered by the lack of appropriate model, and intervention systems. We hypothesized that human fetal testis xenografts can recapitulate normal development.METHODSHuman fetal testes (at 9 weeks, n = 4 and 14–18 weeks gestation, n = 6) were xenografted into male nude mice for 6 weeks, with or without hCG treatment of the host, and evaluated for normal cellular development and function using immunohistochemistry, triple immunofluorescence and testosterone assay. The differentiation and proliferation status of germ cells within xenografts was quantified and compared with age-matched controls.RESULTSXenografts showed >75% survival with normal morphology. In the first-trimester xenografts seminiferous cord formation was initiated and in first- and second-trimester grafts normal functional development of Sertoli, Leydig and peritubular myoid cells was demonstrated using cell-specific protein markers. Grafts produced testosterone when hosts were treated with hCG (P = 0.004 versus control). Proliferation of germ cells and differentiation from gonocytes (OCT4+) into pre-spermatogonia (VASA+) occurred in grafts and quantification showed this progressed comparably with age-matched ungrafted controls.CONCLUSIONSHuman fetal testis tissue xenografts demonstrate normal structure, function and development after xenografting, including normal germ cell differentiation. This provides an in vivo system to study normal human fetal testis development and its susceptibility to disruption by exogenous factors (e.g. environmental chemicals). This should provide mechanistic insight into the fetal origins of DSDs and TDS disorders.
Background-Growth hormone (GH) has been used to promote growth in both the short and long term in a number of dysmorphic syndromes, including Turner syndrome. As this condition shares many clinical features with Noonan syndrome, it would seem logical to treat the latter group with GH. Aims-To assess the short and long term response to GH therapy in patients with Noonan syndrome. Methods-Analysis of patients with Noonan syndrome in the Pharmacia & Upjohn International Growth Study (this postmarketing database contains data on the majority of patients currently treated with GH in the UK). A questionnaire was also sent to participating clinicians. Results-Data on 66 patients (54 males) were available for study. At the start of GH therapy children were short, compared with both normal and Noonan children. During the first year of GH therapy height velocity increased from a mean of 4.9 to 7.2 cm per year. For patients treated long term with GH, mean height SDS increased from −2.9 pretreatment to −2.6 after one year and −2.3 after five years. Of the 10 patients at near final height, only one had a height above the 3rd centile for normal adults and above the mean for untreated Noonan patients. The mean increment in final height was 3.1 cm (range −1.1 to 6.5 cm). Conclusions-GH therapy in patients withNoonan syndrome will improve height velocity in the short term. Longer-term therapy results in a waning of eVect; initial indications are that final height is not improved substantially in most patients. (Arch Dis Child 2001;84:440-443)
We have attempted to investigate the role of imprinting in the phenotype of Turner's syndrome. Sixty-three patients were investigated for parental origin of the retained normal X chromosome; 43 were found to retain the maternal X (XM) and 20 the paternal (Xe). The relationship be-
To study the ontogeny of spontaneous pulsatile LH and FSH secretion before the onset of puberty, plasma LH and FSH were measured by an ultrasensitive time-resolved immunoflurometric assay in 16 boys and 6 girls, aged 6.5 +/- 0.2 yr (+/- SEM; range, 4.4-8.0) with short stature. Eight male patients with idiopathic hypogonadotropic hypogonadism (Kallmann's syndrome), aged 24.1 +/- 3.4 yr, were also investigated. Blood samples were withdrawn at 10- to 20-min intervals for 12 h from 2000-0800 h. Pituitary responsiveness was assessed by a standard iv LHRH challenge test. LH and/or FSH pulses were detectable in all but two prepubertal subjects. In boys, low amplitude LH (0.16 +/- 0.06 U/L) and FSH (0.19 +/- 0.03 U/L) pulses were detectable at mean frequencies of 2.19 +/- 0.37 and 2.13 +/- 0.46 pulses/12 h, respectively. In girls, low amplitude LH (0.29 +/- 0.18 U/L) pulses, but higher (P less than 0.05 compared to boys) amplitude FSH (1.62 +/- 1.05 U/L) pulses were observed at frequencies of 1.71 +/- 0.56 and 1.67 +/- 0.53 pulses/12 h, respectively. Mean FSH in prepubertal girls (1.95 +/- 0.88 U/L) was significantly (P less than 0.05) higher than that in boys (0.46 +/- 0.07 U/L), but mean LH was not different at 0.17 +/- 0.07 and 0.10 +/- 0.03 U/L, respectively. Patients with Kallmann's syndrome had mean LH and FSH levels indistinguishable from those of prepubertal boys. Nocturnal augmentation of pulsatile LH or FSH secretion was observed in 74% of children (71% in girls and 75% in boys), but in none of the eight patients with Kallmann's syndrome. A close temporal association was observed between sleep onset and the appearance of nocturnal pulsatile gonadotropin secretion. The FSH response to exogenous LHRH in prepubertal girls was significantly greater than that in patients with Kallmann's syndrome and prepubertal boys, but LH responses were not different. Our results show that pulsatile LH and FSH secretion occurs in the majority of boys and girls in midchildhood, with a robust association with nocturnal sleep onset. Between the ages of 4-8 yr, these low amplitude and low frequency pulses are unable to activate gonadal function. The regulation of FSH secretion in prepubertal girls appears to be different from that in prepubertal boys.(ABSTRACT TRUNCATED AT 400 WORDS)
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