The shortness of Pygmies is associated with severe under-expression of the growth hormone receptor.

The stature is a highly heritable trait controlled by genetic and environmental factors. The African Pygmies represent a paradigmatic example of non-disease-related idiopathic short stature (ISS), showing a similar endocrine profile of Caucasian individuals with ISS. Pygmy children show normal anthropometric and endocrine parameters until puberty, while adult Pygmies show normal baseline and post-stimulation serum growth hormone (GH) levels but low values of baseline serum GH-binding protein (GHBP) and insulin-like growth factor-I (IGF-I). This discrepancy suggests a defective response to GH occurring in adulthood since Pygmies lack both the pubertal serum IGF-I surge and the growth spurt. However, sequencing of the key genes of the GH-IGF-I axis failed to identify Pygmy specific variants or haplotypes. We therefore aimed at assessing whether the quantitative gene expression profile of two key genes of the GH-IGF-I axis, GH and GHR, was also similar in low-stature and normal stature populations. We showed that the GH gene expression is 1.8-fold reduced and the GH receptor (GHR) gene expression is 8-fold reduced in adult Pygmies in comparison with sympatric adult Bantu, and that this reduction is not associated with sequence variants of the GHR gene. The marked decrease of the GHR expression in Pygmies is associated with reduced serum levels of the IGF-I and GHBP. Our results, documenting a markedly reduced GHR gene expression in adult Pygmies, could contribute to elucidate the mechanisms involved in ISS in Caucasoid subjects.

Ultrastructural definition of apoptosis in heart failure.

Cardiac myocytes die through apoptosis, oncosis, and autophagy. Apoptosis affects single cells and is morphologically characterized by nuclear fragmentation with generation of apoptotic bodies that can be seen either within dying cells or free in the interstitial spaces. Dead myocytes are removed by macrophages through phagocytosis without triggering inflammation. The circulating markers of myocyte necrosis are not increased by apoptosis. The morphologic changes of the induction and early execution phases are seen at electron microscopy while late fragmentation is visible on both light and electron microscopy. Immunoelectron microscopy provides combined functional and structural information showing cytochrome c immuno-labelling release from mitochondria, TUNEL labelling of apoptotic nuclei, annexin V translocation in the outer plasma cell layer. Oncosis is characterized by specific morphologic features that may coexist with apoptosis, especially in ischemic myocardium. Autophagy is a defense process that is associated with significant myocardial damage and necrosis when removal of the lysosomal content is impaired. Morphological features of apoptosis, oncosis, and autophagocytosis may coexist at the same time. Although dead myocytes showing characteristics of autophagy and apoptosis are rarely observed in human decompensated hearts, autophagic vacuoles, and early apoptotic changes may be seen more often in morphologically viable myocytes. Such features may occur in failing hearts of both ischemic and non-ischemic etiology. The shared mode of cardiac myocyte death in failing human hearts of different etiologies suggests that preservation of myocyte integrity may be possible by similar therapeutic strategies.

Barth syndrome associated with compound hemizygosity and heterozygosity of the TAZ and LDB3 genes.

Barth syndrome is an X-linked recessive disorder caused by the tafazzin (TAZ) gene mutations and includes dilated cardiomyopathy (DCM) with left ventricular non-compaction, neutropenia, skeletal myopathy, abnormal mitochondria and 3-methylglutaconic aciduria. Dilated cardiomyopathy with left ventricular non-compaction transmitted as an autosomal dominant condition has also been associated with LIM domain-binding 3 (LDB3) gene defects. We describe a family in which the 12-year-old proband had left ventricular non-compaction and DCM. His mother had five miscarriages, two other sons who died in infancy, and a healthy son and daughter. The proband showed left ventricular non-compaction-DCM, skeletal myopathy, recurrent oral aphthous ulcers and cyclic neutropenia. The DCM progressively improved with age; medical therapy was discontinued at 5 years of age. At present, left ventricular function is normal and arrhythmias are absent. Magnetic resonance imaging documented left ventricular non-compaction. However, oral aphthous ulcers and cyclic neutropenia have recurred. In the proband we identified two novel mutations, one of maternal origin in the TAZ gene (p.[Glu202ValfsX15]) and one of paternal origin in the LDB3 gene (p.[Thr350Ile]). The mother, brother and father are healthy; although the latter two show prominent left ventricle trabeculation without dysfunction. Expression studies of TAZ and LDB3 genes were conducted in family members and controls. In the proband, brother and father, LDB3 expression was similar to control cases. TAZ and LDB3 expression progressively declined with age in control both blood and myocardial samples. However, an endomyocardial biopsy performed in the proband at 6 months of age, showed significantly lower TAZ and LDB3 expression than in age-matched myocardial controls. We believe that the clinical, genetic and expression data support the hypothesis that tafazzins are essential during fetal and early post-natal life.

Identification of sixty-two novel and twelve known FBN1 mutations in eighty-one unrelated probands with Marfan syndrome and other fibrillinopathies.

Marfan Syndrome (MFS) is an autosomal dominant disorder of the connective tissue due to mutations of Fibrillin-1 gene (FBN1) in more than 90% of cases and Transforming Growth Factor-Beta-Receptor2 gene (TGFB2R) in a minority of cases. Genotyping is relevant for diagnosis and genotype-phenotype correlations. We describe the FBN1 genotypes and related phenotypes of 81 patients who were referred to our attention for MFS or Marfan-like phenotypes. Patients underwent multidisciplinary pertinent evaluation in the adult or paediatric setting, according to their age. The diagnosis relied on Ghent criteria. To optimise DHPLC analysis of the FBN1 gene, all coding regions of the gene were directly sequenced in 19 cases and 10 controls: heterozygous amplicons were used as true positives. DHPLC sensitivity was 100%. Then, DHPLC was used to screen 62 other cases. We identified 74 FBN1 mutations in 81 patients: 64 were novel and 17 known. Of the 81 mutations, 41 were missense (50.6%), 27, either nonsense or frameshift mutations and predicted a premature termination codon (PTC) (33%), 11 affected splice sites (13.6%), and two predicted in-frame deletions (2.5%). Most mutations (67.9%) occurred in cbEGF-like modules. Genotype was clinically relevant for early diagnosis and conclusion of the diagnostic work-up in patients with incomplete or atypical phenotypes.

A novel mtDNA point mutation in tRNA(Val) is associated with hypertrophic cardiomyopathy and MELAS.

BACKGROUND: Pathological mutations of mitochondrial (mt) DNA may cause specific diseases such as cardiomyopathies or hearing loss, or syndromes such as mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episode (MELAS) syndrome. We describe a novel mtDNA mutation in a patient with severe hypertrophic cardiomyopathy associated with MELAS. The familial phenotype included 1) hypertrophic cardiomyopathy and MELAS, 2) clinically mild cardiac hypertrophy, and 3) deafness. METHODS: The proband and her first degree relatives underwent echo and electrocardiograms, and biochemical tests. Magnetic resonance imaging of the brain was performed in the proband. mtDNA was fully analyzed by sequencing. DNA purification, polymerase chain reaction and direct automated sequencing were performed following standard procedures. Heteroplasmy of the novel mutation was quantified by densitometric analysis. RESULTS: A novel G1644A transition affecting the tRNA(Val) was identified in the proband and maternal relatives. The mutation has been interpreted as pathological because the G at the 1644 position is a highly conserved base, is heteroplasmic with higher levels of mutant DNA in the proband than in the relatives, is located in the unique tRNA(Val), is very close to a mutation described as causative of MELAS, and finally has not been found in 100 healthy controls. CONCLUSIONS: Although it is rare for patients with MELAS to be referred to cardiological evaluation because of coexisting cardiomyopathy, cardiologists should be aware of this association as well as of the non cardiac signs that may address the diagnosis to mtDNA defect-related disease in families with a variable phenotype.