Macarena Ruiz-Ferrer

Silencing of ubiquinone biosynthesis genes extends life span in Caenorhabditis elegans

Ubiquinone (coenzyme Q; Q) is a key factor in the mitochondria electron transport chain, but it also functions as an antioxidant and as a cofactor of mitochondrial uncoupling proteins. Furthermore, Q isoforms balance in Caenorhabiditis elegans is determined by both dietary intake and endogenous biosynthesis. In the absence of synthesis, withdrawal of dietary Q8 in adulthood extends life span. Thus, Q plays an important role in the aging process and understanding its synthesis acquires a new impetus. We have identified by RNA interference (RNAi) eight genes, including clk‐1, involved in ubiquinone biosynthesis in C. elegans feeding animals with dsRNA‐containing Escherichia coli HT115 strains. Silenced C. elegans showed lower levels of both endogenous Q9 and Q8 provided by diet, produced less superoxide without a significant modification of mitochondrial electron chain, and extended life span compared with non‐interfered animals. E. coli strains harboring dsRNA also interfered with their own Q8 biosynthesis. These findings suggest that more efficient electron transport between a lower amount of Q and electron transport capacity of the mitochondrial complexes leads to less production of reactive oxygen species that contributes to extension of life span in the nematode C. elegans.

Hirschsprung's disease as a model of complex genetic etiology.

Hirschsprung disease (HSCR), or aganglionic megacolon, is a developmental disorder characterised by the absence of ganglion cells along variable length of the distal gastrointestinal tract, leading to the most common form of functional intestinal obstruction in neonates and children. Aganglionosis is attributed to a failure of neural crest cells to migrate, proliferate, differentiate or survive during enteric nervous system (ENS) development in the embryonic stage. The incidence of HSCR is estimated at 1/5000 live births and most commonly presents sporadically with reduced penetrance and male predominance, although it can be familial and may be inherited as autosomal dominant or autosomal recessive. In 70% of cases, HSCR occurs as an isolated trait and in the other 30% HSCR is associated with other congenital malformation syndromes. HSCR has a complex genetic etiology with several genes and loci being described as associated with either isolated or syndromic forms. These genes encode for receptors, ligands (especially those participating in the RET and EDNRB signaling transduction pathways), transcriptional factors or other cell elements that are usually involved in the neural crest cell development and migration that give rise to ENS. Nevertheless, the RET proto-oncogene is considered the major disease causing gene in HSCR. A common RET variant within the conserved transcriptional enhancer sequence in intron 1 has been shown to be associated with a great proportion of sporadic cases and could act as a modifier by modulating the penetrance of mutations in other genes and possibly of those mutations in the RET proto-oncogene itself.

A Novel Point Variant in NTRK3, R645C, Suggests a Role of this Gene in the Pathogenesis of Hirschsprung Disease

Hirschsprung disease (HSCR) is a developmental disorder characterized by the absence of ganglion cells in the myenteric and submucosal plexuses due to a defect in the migration process of neural crest neuroblasts. Manifestation of the disease has been linked to the dysfunction of two principal signalling pathways involved in the enteric nervous system (ENS) formation: the RET‐GDNF and the EDN3‐EDNRB receptor systems. However, the NTF3/NTRK3 signalling pathway plays an essential role in the development of the ENS suggesting a potential role for those genes in the pathogenesis of HSCR. We have sought to evaluate the candidature of the NTRK3 gene, which encodes the TrkC receptor, as a susceptibility gene for Hirschsprung disease. Using dHPLC technology we have screened the NTRK3 coding region in 143 Spanish HSCR patients. A total of four previously described polymorphisms and 12 novel sequence variants were detected. Of note, the novel R645C mutation was detected in 2 affected siblings of a HSCR family also carrying a RET splicing mutation. Using bioinformatics tools we observed that the presence of an additional cysteine residue might implicate structural alterations in the mutated protein. We propose haploinsufficiency as the most probable mechanism for the NTRK3 R645C mutation. NTRK3 and RET mutations in this family only appear together in the HSCR patients, suggesting that they per se are necessary but not sufficient to produce the phenotype. In addition, it is quite probable that the contribution of other still unidentified modifier genes, may be responsible for the different phenotypes (length of aganglionosis) in the two affected members.

Novel mutations at RET ligand genes preventing receptor activation are associated to Hirschsprung’s disease

Hirschsprung disease (HSCR) is a developmental disorder characterized by the absence of ganglion cells along variable lengths of the distal gastrointestinal tract. The major susceptibility gene for the disease is the RET proto-oncogene, which encodes a receptor tyrosine kinase activated by the glial cell-derived neurotrophic factor (GDNF) family ligands. We analyzed the coding sequence of GDNF, NTRN, and, for the first time, ARTN and PSPN in HSCR patients and detected several novel variants potentially involved in the pathogenesis of HSCR. In vitro functional analysis revealed that the variant R91C in PSPN would avoid the correct expression and secretion of the mature protein. Moreover, this study also highlighted the role of both this variant and F127L in NRTN in altering RET activation by a significant reduction in phosphorylation. To support the role of PSPN R91C in HSCR phenotype, enteric nervous system (ENS) progenitors were isolated from human postnatal gut tissues and expression of GFRα4, the main co-receptor for PSPN, was demonstrated. This suggests that not only GDNF and NRTN but also PSPN might promote survival of precursor cells during ENS development. In summary, we report for the first time the association of PSPN gene with HSCR and confirm the involvement of NRTN in the disease, with the identification of novel variants in those genes. Our results suggest that the biological consequence of the mutations NTRN F127L and PSPN R91C would be a reduction in the activation of RET-dependent signaling pathways, leading to a defect in the proliferation, migration, and/or differentiation process of neural crest cells within the developing gut and thus to the typical aganglionosis of the HSCR phenotype.

267 Spanish Exomes Reveal Population-Specific Differences in Disease-Related Genetic Variation

Recent results from large-scale genomic projects suggest that allele frequencies, which are highly relevant for medical purposes, differ considerably across different populations. The need for a detailed catalog of local variability motivated the whole-exome sequencing of 267 unrelated individuals, representative of the healthy Spanish population. Like in other studies, a considerable number of rare variants were found (almost one-third of the described variants). There were also relevant differences in allelic frequencies in polymorphic variants, including ∼10,000 polymorphisms private to the Spanish population. The allelic frequencies of variants conferring susceptibility to complex diseases (including cancer, schizophrenia, Alzheimer disease, type 2 diabetes, and other pathologies) were overall similar to those of other populations. However, the trend is the opposite for variants linked to Mendelian and rare diseases (including several retinal degenerative dystrophies and cardiomyopathies) that show marked frequency differences between populations. Interestingly, a correspondence between differences in allelic frequencies and disease prevalence was found, highlighting the relevance of frequency differences in disease risk. These differences are also observed in variants that disrupt known drug binding sites, suggesting an important role for local variability in population-specific drug resistances or adverse effects. We have made the Spanish population variant server web page that contains population frequency information for the complete list of 170,888 variant positions we found publicly available (http://spv.babelomics.org/), We show that it if fundamental to determine population-specific variant frequencies to distinguish real disease associations from population-specific polymorphisms.

A map of human microRNA variation uncovers unexpectedly high levels of variability.

BackgroundMicroRNAs (miRNAs) are key components of the gene regulatory network in many species. During the past few years, these regulatory elements have been shown to be involved in an increasing number and range of diseases. Consequently, the compilation of a comprehensive map of natural variability in a healthy population seems an obvious requirement for future research on miRNA-related pathologies.MethodsData on 14 populations from the 1000 Genomes Project were analyzed, along with new data extracted from 60 exomes of healthy individuals from a population from southern Spain, sequenced in the context of the Medical Genome Project, to derive an accurate map of miRNA variability.ResultsDespite the common belief that miRNAs are highly conserved elements, analysis of the sequences of the 1,152 individuals indicated that the observed level of variability is double what was expected. A total of 527 variants were found. Among these, 45 variants affected the recognition region of the corresponding miRNA and were found in 43 different miRNAs, 26 of which are known to be involved in 57 diseases. Different parts of the mature structure of the miRNA were affected to different degrees by variants, which suggests the existence of a selective pressure related to the relative functional impact of the change. Moreover, 41 variants showed a significant deviation from the Hardy-Weinberg equilibrium, which supports the existence of a selective process against some alleles. The average number of variants per individual in miRNAs was 28.ConclusionsDespite an expectation that miRNAs would be highly conserved genomic elements, our study reports a level of variability comparable to that observed for coding genes.

A complex additive model of inheritance for Hirschsprung disease is supported by both RET mutations and predisposing RET haplotypes

Purpose: The RET proto-oncogene is considered to be the major susceptibility gene involved in Hirschsprung disease. Traditional RET germline mutations account for a small subset of Hirschsprung disease patients, but several studies have shown that there is a specific haplotype of RET associated with the sporadic forms of Hirschsprung disease. We have investigated for RET germline mutations and analyzed the RET haplotypic distribution in carriers versus noncarriers of RET germline mutations.Methods: We have screened the coding region of RET in 106 Spanish Hirschsprung disease patients using dHPLC technology. Statistical comparisons of the distribution of RET haplotypes between sporadic patients with and without a RET germline mutation were performed.Results: Nine novel germline mutations and one previously described were identified. A significant over-transmission of the “Hirschsprung disease haplotype” was detected when comparing transmitted versus nontransmitted alleles in the group of Hirschsprung disease triads without mutation. However, no distortion of the transmission of alleles was found in the group of mutated families.Conclusions: These results would be concordant with a complex additive model of inheritance. The whole findings seem to suggest that low-penetrance mutations would be necessary but not sufficient and the additional presence of the “Hirschsprung disease haplotype” could contribute to the manifestation of the disease.

Analysis of CCR5‐Δ32 and CCR2‐V64I polymorphisms in a cohort of Spanish HCV patients using Real‐time Polymerase Chain Reaction and Fluorescence Resonance Energy Transfer technologies

Summary.  Nowadays it is clear that chemokine–chemokine receptor interactions are important in chronic hepatitis C virus (HCV) infection. The objective of the present study was to elucidate the involvement of the CCR5‐Δ32 and CCR2‐V64I polymorphisms in the response to the HCV infection, as well as in the histological damage and the outcome of the infection. A cohort of 139 patients with hepatitis C and 100 healthy blood donors were analysed for both polymorphisms using real‐time polymerase chain reaction (PCR) and LightCyclerTM technology. We have detected the CCR5‐Δ32 allele in 15 of 278 HCV chromosomes (5.4%) and 15 of 200 control chromosomes (7.5%). The CCR2‐V64I allele was present in 24 of 278 HCV chromosomes (8.6%) and 19 of 200 control chromosomes (9.5%). Analysis of the histological parameters showed no statistical significance when comparing the patients carrying the variants vs the cases with the wild‐type allele. Our results seem to indicate that the CCR5‐Δ32 and CCR2‐V64I polymorphisms are not related to the response to HCV infection, histological damage and outcome of infection in our cohort of Spanish HCV patients.

NTF-3, a gene involved in the enteric nervous system development, as a candidate gene for Hirschsprung disease

Hirschsprung disease (HSCR) is a congenital disorder caused by a failure of neural crest cells to migrate, proliferate, and/or differentiate during the enteric nervous system (ENS) development. The requirement of the NTF-3/TrkC signaling for the proper development of the ENS, together with the evidences presented by animal models, led us to investigate the involvement of NTF-3 gene in HSCR. We performed both a mutational screening of NTF-3 and a complete evaluation of 3 polymorphisms as genetic susceptibility factors for HSCR. We identified a novel sequence variant, G76R, present in 2 different patients and absent in controls. We postulate that this variation could generate a lack of mature functional NTF-3 proteins in neural crest cell precursors; thus, altering the NTF-3/TrkC signaling pathway and influencing in the adequate ENS development. Although these results do not provide complete assurance of the involvement of this gene in HSCR, given the polygenic nature of the disease and its etiology, investigation of the genes encoding protein members of the signaling pathways governing the ENS development could provide new key findings in the elucidation of this complex disease.

The −670A > G polymorphism in the promoter region of the FAS gene is associated with necrosis in periportal areas in patients with chronic hepatitis C

Summary.  Evidence suggests that apoptosis of liver cells may play a significant role in the pathogenesis of hepatitis C virus (HCV) infection. One of the best characterized apoptotic pathway is that mediated by the death receptor Fas. Fas expression has been found to be up‐regulated on hepatocytes in chronic HCV infection, particularly in periportal areas. Recently, two polymorphisms have been identified in the promotor region of the FAS gene, −1377G > A and −670A > G. We have evaluated the involvement of these variants in the susceptibility to HCV infection, the severity of liver damage and progression of fibrosis in chronic hepatitis C. A cohort of 197 patients with chronic hepatitis C and 100 controls were analysed for both polymorphisms by Fluorescence Resonance Energy Transfer using specific probes and the LightcyclerTM system. In addition, liver biopsies were taken in 167 patients and scored using the Knodell classification system. We have found that the allele frequencies and the distribution of both polymorphisms do not differ significantly in the HCV cohort and in the control population. Thus, none of the polymorphisms seems to be related with susceptibility to HCV infection. However, we have examined the possible association between the two variants and the grade of necroinflammatory activity and the stage of fibrosis and we have detected an under‐representation of the −670A > G variant among those patients with higher Knodells scores (P = 0.049) and necroinflammatory activity (P = 0.036). The −670A allele was associated with higher levels of periportal necrosis (P = 0.012). In conclusion, our findings suggest an association between the −670A > G polymorphism and the grade of necrosis in periportal areas in patients with chronic hepatitis C.