[Does childhood obesity affect sexual development?]. / Beeinflusst die kindliche Adipositas die Pubertätsentwicklung?

The process of pubertal development is only partly understood and is influenced by many different factors. During the twentieth century there was a general trend toward earlier pubertal development. Fat mass is thought to be a major inducer of puberty. Owing to the rising epidemic of childhood obesity, the relationship between body composition in children and the rate and timing of puberty needs to be investigated. Some studies suggest that central obesity is associated with an earlier onset of pubertal development. Rapid weight gain in early life is linked to advanced puberty in both sexes. A clear correlation exists between increasing body mass index (BMI) and earlier pubertal development in girls. In boys the data are controversial: The majority of studies propose that there is an earlier puberty and voice break in obese boys, but some studies show the opposite. There are several factors and mechanisms that seem to link obesity and puberty, for example, leptin, adipocytokines, and gut peptides. Important players include genetic variation and environmental factors (e.g., endocrine-disrupting chemicals). This article presents the latest studies and evidence on this topic, underlining the inconsistencies in the data and, therefore, the need for further research in this area.

Functional characterization of a heterozygous GLI2 missense mutation in patients with multiple pituitary hormone deficiency.

CONTEXT: The GLI2 transcription factor is a major effector protein of the sonic hedgehog pathway and suggested to play a key role in pituitary development. Genomic GLI2 aberrations that mainly result in truncated proteins have been reported to cause holoprosencephaly or holoprosencephaly-like features, sometimes associated with hypopituitarism. OBJECTIVE: Our objective was to determine the frequency of GLI2 mutations in patients with multiple pituitary hormone deficiency (MPHD). DESIGN: Patients were selected from participants in the Genetics and Neuroendocrinology of Short Stature International Study (GeNeSIS) program. Patients with mutations within established candidate genes were excluded. PATIENTS: A total of 165 patients with MPHD defined as GH deficiency and at least 1 additional pituitary hormone deficiency were studied regardless of the presence of extrapituitary clinical manifestations. MAIN OUTCOME MEASURES: Prevalence of GLI2 variations in MPHD patients was assessed and detailed phenotypic characterization is given. Transcriptional activity of identified GLI2 variants was evaluated by functional reporter assays. RESULTS: In 5 subjects, 4 heterozygous missense variants were identified, of which 2 are unpublished so far. One variant, p.R516P, results in vitro in a complete loss of protein function. In addition to GH deficiency, the carrier of the mutation demonstrates deficiency of thyrotrope and gonadotrope function, a maldescended posterior pituitary lobe, and polydactyly, but no midline defects. CONCLUSIONS: For the first time, we show that heterozygous amino acid substitutions within GLI2 may lead to MPHD with mild extrapituitary findings. The phenotype of GLI2 mutations is variable, and penetrance is incomplete. GLI2 mutations are associated with anterior pituitary hypoplasia, and frequently, ectopy of the posterior lobe occurs.

Tandem mass spectrometric determination of succinylacetone in dried blood spots enables presymptomatic detection in a case of hepatorenal tyrosinaemia.

Tyrosinaemia type I, or fumarylacetoacetase deficiency, causes hepatorenal damage by accumulation of fumarylacetoacetate. Patients are generally in good condition at birth, but are at risk of developing serious metabolic crises with liver failure and hepatic coma. An early start of treatment with NTBC and a tyrosine-balanced diet can prevent harm to the patients. The application of tandem mass spectrometry to newborn screening allows for easy determination of tyrosine to detect the presence of hypertyrosinaemia in the neonate, but most patients with tyrosinaemia type I do not present with high tyrosine levels at the time of newborn screening. We report on a 7-week-old girl presenting with acute hepatopathy and severe coagulopathy due to tyrosinaemia type I. The metabolic screening, which was performed by tandem mass spectrometry at the age of 48 h, had revealed normal values for tyrosine and methionine that were well within ranges observed in the general population and equally normal ratios of methionine/tyrosine and tyrosine/serine. In this patient even lowering the cut-off levels for tyrosine and methionine would not have provided better sensitivity. Residual blood spots from the newborn screening filter paper were retrospectively analysed using a specific mass-spectrometric method for the detection of succinylacetone and revealed a 5-fold elevated succinylacetone concentration. This indicates that identification of all newborns with hepatorenal tyrosinaemia is only possible by determination of succinylacetone as part of the newborn screening process.

Longitudinal imaging reveals pituitary enlargement preceding hypoplasia in two brothers with combined pituitary hormone deficiency attributable to PROP1 mutation.

Mutations of the PROP-1 gene cause combined pituitary hormone deficiency. Progressive ACTH/cortisol insufficiency is found in a few patients. Congenital hypoplasia of the anterior pituitary gland is the most common magnetic resonance imaging finding in patients with PROP-1 mutations. We present two brothers with compound heterozygosity for the two mutations 150delA and 301-302delAG of the PROP-1 gene. Both showed combined pituitary hormone deficiency of GH, TSH, PRL, and gonadotropins, as is typical for PROP-1 deficiency. We observed a developing insufficiency of ACTH and cortisol secretory capacity in both patients. Computed tomography revealed an enlarged pituitary in the older brother at 3.5 yr of age. Repeated magnetic resonance imaging after 12 yr showed a constant hypoplasia of the anterior pituitary lobe. Similarly, magnetic resonance imaging of the younger brother showed a constant enlargement of the anterior pituitary gland until 10 yr. At the age of 11 yr, the anterior pituitary was hypoplastic. The reason for pituitary enlargement in early childhood with subsequent decrease in pituitary size is not known. We speculate that altered expression of early transcription factors could be involved. Because both patients have the same PROP-1 mutations and an identical pattern of combined pituitary hormone deficiency, we suggest that early pituitary enlargement may be the typical course in such patients in whom pituitary surgery is not indicated.

GH transcription factors.

The pituitary transcription factor Pit-1 is expressed during the later differentiation stages of anterior pituitary development and Pit-1 mutations have been identified as the cause of a combined pituitary hormone deficiency (CPHD) for GH, prolactin and TSH. Mutations within the human Pit-1 gene can either impair the DNA binding of this transcription factor, or while leaving DNA binding capabilities unimpaired, decrease its function within the transactivation complex. Approximately half of all patients with this phenotype do not show any defect within the Pit-1 gene. Prop-1, a recently discovered transcription factor of anterior pituitary development, seemed a likely candidate for such mutations. Prop-1 mutations, however, have been found so far to induce a combined pituitary hormone deficiency for GH, prolactin, TSH and gonadotropins. We describe here a group of patients with isolated and combined pituitary hormone deficiencies who were screened for Pit-1 and Prop-1 mutations to characterize the phenotypic spectrum of defects within these two genes.

Combined pituitary hormone deficiency: role of Pit-1 and Prop-1.

During fetal development of the anterior pituitary gland, a number of sequential processes occur that affect cell differentiation and proliferation. Molecular analyses have revealed several steps that are required for pituitary cell line specification and have identified specific factors that control these steps. The gene encoding the pituitary transcription factor 1 (Pit-1) is expressed during differentiation steps that take place quite late in the development of the anterior pituitary gland. Clinically, patients with mutations of the PIT1 gene are characterized by severe deficiencies in growth hormone (GH) and prolactin (PRL), and often develop secondary hypothyroidism. A second pituitary transcription factor is known as Prophet of Pit-1 (Prop-1), and a mutation of the Prop1 gene has been detected in Ames dwarf mice. Several Prop1 mutations have been identified that structurally affect the 'paired-like' DNA-binding domain of the Prop-1 protein molecule. Patients with PROP1 mutations show combined pituitary hormone deficiency. These patients exhibit secondary hypogonadism in addition to the deficiencies of GH, PRL and thyroid-stimulating hormone (TSH) also seen in patients with PIT1 mutations. Although all are in the subnormal range, the levels of GH, PRL and TSH in patients with PROP1 mutations are, on average, slightly higher than in patients with PIT1 mutations. Some degree of hypocortisolism may necessitate cortisol substitution in patients with PROP1 mutations.

Congenital central hypothyroidism due to a homozygous mutation in the thyrotropin beta-subunit gene follows an autosomal recessive inheritance.

A 5-month-old infant of nonconsanguineous parents had severe hypothyroidism. Undetectable serum levels of T3 and T4 in combination with an undetectable baseline TSH level led to the diagnosis of central hypothyroidism. Administration of TRH failed to increase serum TSH, but not PRL, confirming isolated TSH deficiency. Measurement of the TSH in serum with three different immunoassays that recognize different epitopes of the TSH molecule failed to detect TSH, suggesting an aberrant or absent TSH. Direct sequencing of the entire coding region of the human TSH beta-subunit gene revealed a homozygous single base pair deletion in codon 105, resulting in a frame shift with a premature stop at codon 114. The truncated TSH beta peptide lacks the terminal five amino acids. Furthermore, the cysteine in codon 105 that is believed to be important for the interaction of the TSH beta-subunit with the alpha-subunit, is replaced with a valine (C105V), supporting the theory of a conformational change in the TSH molecule. Genotyping confirmed that the proposita was homozygous for this mutation, whereas her unaffected parents, the paternal grand-mother, and the maternal grandfather were heterozygous. Thus, isolated TSH deficiency follows an autosomal recessive mode of inheritance in this kindred.

Mutations in PROP1 cause familial combined pituitary hormone deficiency.

Combined pituitary hormone deficiency (CPHD) in man denotes impaired production of growth hormone (GH) and one or more of the other five anterior pituitary hormones. Mutations of the pituitary transcription factor gene POU1F1 (the human homologue of mouse Pit1) are responsible for deficiencies of GH, prolactin and thyroid stimulating hormone (TSH) in Snell and Jackson dwarf mice and in man, while the production of adrenocorticotrophic hormone (ACTH), luteinizing hormone (LH) and follicle stimulating hormone (FSH) is preserved. The Ames dwarf (df) mouse displays a similar phenotype, and appears to be epistatic to Snell and Jackson dwarfism. We have recently positionally cloned the putative Ames dwarf gene Prop1, which encodes a paired-like homeodomain protein that is expressed specifically in embryonic pituitary and is necessary for Pit1 expression. In this report, we have identified four CPHD families with homozygosity or compound heterozygosity for inactivating mutations of PROP1. These mutations in the human PROP1 gene result in a gene product with reduced DNA-binding and transcriptional activation ability in comparison to the product of the murine df mutation. In contrast to individuals with POU1F1 mutations, those with PROP1 mutations cannot produce LH and FSH at a sufficient level and do not enter puberty spontaneously. Our results identify a major cause of CPHD in humans and suggest a direct or indirect role for PROP1 in the ontogenesis of pituitary gonadotropes, as well as somatotropes, lactotropes and caudomedial thyrotropes.

GH and TSH deficiency.

Hypothyroidism is a recognised complication of GH therapy in GH deficient children. The mechanisms involved include direct effects on thyroid function but also result from the close interrelationship of pituitary cell-lines that differentiate during embryonic development of the anterior pituitary gland. Among numerous pituitary transcriptionfactors that orchestrate pituitary organogenesis Pit-1 was the first to be recognised and is the most extensively studied. Mutations in the Pit-1 gene account for a form of combined pituitary hormone deficiency for GH, Prolactin (Prl) and TSH (CPHD). Despite the variability of the clinical presentation of this syndrome at the time of initial diagnosis, all forms finally result in severe retardation of growth and development due to GH-deficiency and hypothyroidism. More than half of the families with a combined pituitary hormone deficiency have not disclosed any Pit-1 abnormalities. Evidence is accumulating that Prop-1, a transcriptionfactor expressed temporarily in the fetal anterior pituitary, could be a candidate for patients with a Pit-1 phenotype without any Pit-1 gene abnormalities.

Pit-1 and pituitary function.

Several patients with pituitary dwarfism and a variable degree of hypothyroidism have been shown to have mutations in their Pit-1 gene. Pit-1 activates transcription of the growth hormone and prolactin genes and is necessary for the control of the beta-TSH gene transcription. The various mutations have different effects on the DNA binding and transactivating properties of Pit-1. Multiple pituitary hormone deficiency due to Pit-1 mutations is inherited either dominantly or recessively depending on the DNA binding properties of the mutant protein. The comparison of pheno- and genotype in patients with multiple pituitary hormone deficiency provides some insight into the function of the Pit-1 protein.

Pit-1 and hypopituitarism.

The story of Pit-1 and hypopituitarism in humans provides an excellent example of pleiotrophism or multiple phenotypic effects resulting from a single genetic alteration. It shows how defects in this single gene cause the absence o f several pituitary hormones. Three recent articles reviewed here provide examples of different mutations in this homeobox gene encoding a transcriptional activation protein that is vital to the embryologic development, survival, and differentiated function of somatotropes, lactotropes, and thyrotropes.

Genetics of growth hormone gene expression.

The regulation of pituitary GH gene expression depends on binding of transcriptional activation proteins to cis-active DNA sequences preceding the GH-1 gene. The POU homeodomain protein Pit-1 is found in the nuclei of somatotrophs, lactotrophs and thyrotrophs. It fosters differentiation of these pituitary cell types and is required for hormone production by mature cells. In theory, defects in GH secretion can be caused by mutations in the GH-1 promoter sequence or in the gene encoding Pit-1. In the former case, deficiency would be limited to GH, and in the latter deficiencies extend to prolactin (Prl) and thyrotropin (TSH) as well as to GH. Both the Pit-1 gene and the GH-1 gene have been examined in children with extreme growth failure. Studies of kindreds with GH, Prl and TSH deficiency have disclosed a variety of mutations in the Pit-1 gene. These include nonsense mutations, missense mutations that diminish binding and transcriptional activation, and also mutations that appear to increase promoter binding while eliminating transcriptional activation. This latter class of mutation exerts a dominant negative effect in vivo as well as in vitro. There are many examples of deletions in the GH-1 coding sequence. Some are very large and cause the loss of GH-1, chorionic somatomammotropin and placental GH genes. Others are very small, involving only 1 or 2 bases. They produce frameshifts and premature stop signals. All types produce complete deficiency of GH, but antibody development during treatment has proven to be quite variable. The cDNA for the GH-releasing hormone receptor has recently been cloned and sequenced.(ABSTRACT TRUNCATED AT 250 WORDS)

Mutation of the POU-specific domain of Pit-1 and hypopituitarism without pituitary hypoplasia.

A point mutation in the POU-specific portion of the human gene that encodes the tissue-specific POU-domain transcription factor, Pit-1, results in hypopituitarism, with deficiencies of growth hormone, prolactin, and thyroid-stimulating hormone. In two unrelated Dutch families, a mutation in Pit-1 that altered an alanine in the first putative alpha helix of the POU-specific domain to proline was observed. This mutation generated a protein capable of binding to DNA response elements but unable to effectively activate its known target genes, growth hormone and prolactin. The phenotype of the affected individuals suggests that the mutant Pit-1 protein is competent to initiate other programs of gene activation required for normal proliferation of somatotrope, lactotrope, and thyrotrope cell types. Thus, a mutation in the POU-specific domain of Pit-1 has a selective effect on a subset of Pit-1 target genes.