Genetic and molecular analysis of the CLDN14 gene in Moroccan family with non-syndromic hearing loss

BACKGROUND:

Hearing loss is the most prevalent human genetic sensorineural defect. Mutations in the CLDN14 gene, encoding the tight junction claudin 14 protein expressed in the inner ear, have been shown to cause non-syndromic recessive hearing loss DFNB29.

AIM:

We describe a Moroccan SF7 family with non-syndromic hearing loss. We performed linkage analysis in this family and sequencing to identify the mutation causing deafness.

MATERIALS AND METHODS:

Genetic linkage analysis, suggested the involvement of CLDN14 and KCNE1 gene in deafness in this family. Mutation screening was performed using direct sequencing of the CLDN14 and KCNE1 coding exon gene.

RESULTS:

Our results show the presence of c.11C>T mutation in the CLDN14 gene. Transmission analysis of this mutation in the family showed that the three affected individuals are homozygous, whereas parents and three healthy individuals are heterozygous. This mutation induces a substitution of threonine to methionine at position 4.

CONCLUSION:

These data show that CLDN14 gene can be i mplicated in the development of hearing loss in SF7 family; however, the pathogenicity of c.11C>T mutation remains to be determined.     

Immunolocalization of H(+)-ATPase and IRT1 enzymes in N(2)-fixing common bean nodules subjected to iron deficiency

The demand for iron in leguminous plants increases during symbiosis, as the metal is utilised for the synthesis of various Fe-containing proteins in both plant and bacteroids. However, the acquisition of this micronutrient is problematic due to its low bioavailability at physiological pH under aerobic conditions. Induction of root Fe(III)-reductase activity is necessary for Fe uptake and can be coupled to the rhizosphere acidification capacity linked to the H⁺-ATPase activity. Fe uptake is related to the expression of a Fe²⁺ transporter (IRT1). In order to verify the possible role of nodules in the acquisition of Fe directly from the soil solution, the localization of H⁺-ATPase and IRT1 was carried out in common bean nodules by immuno-histochemical analysis. The results showed that these proteins were particularly abundant in the central nitrogen-fixing zone of nodules, around the periphery of infected and uninfected cells as well as in the vascular bundle of control nodules. Under Fe deficiency an over-accumulation of H⁺-ATPase and IRT1 proteins was observed especially around the cortex cells of nodules. The results obtained in this study suggest that the increase in these proteins is differentially localized in nodules of Fe-deficient plants when compared to the Fe-sufficient condition and cast new light on the possible involvement of nodules in the direct acquisition of Fe from the nutrient solution.     

Widespread Wolbachia infection in terrestrial isopods and other crustaceans

Wolbachia bacteria are obligate intracellular alpha-Proteobacteria of arthropods and nematodes. Although widespread among isopod crustaceans, they have seldom been found in non-isopod crustacean species. Here, we report Wolbachia infection in fourteen new crustacean species. Our results extend the range of Wolbachia infections in terrestrial isopods and amphipods (class Malacostraca). We report the occurrence of two different Wolbachia strains in two host species (a terrestrial isopod and an amphipod). Moreover, the discovery of Wolbachia in the goose barnacle Lepas anatifera (subclass Thecostraca) establishes Wolbachia infection in class Maxillopoda. The new bacterial strains are closely related to B-supergroup Wolbachia strains previously reported from crustacean hosts. Our results suggest that Wolbachia infection may be much more widespread in crustaceans than previously thought. The presence of related Wolbachia strains in highly divergent crustacean hosts suggests that Wolbachia endosymbionts can naturally adapt to a wide range of crustacean hosts. Given the ability of isopod Wolbachia strains to induce feminization of genetic males or cytoplasmic incompatibility, we speculate that manipulation of crustacean-borne Wolbachia bacteria might represent potential tools for controlling crustacean species of commercial interest and crustacean or insect disease vectors.     

Optimization of sugarcane bagasse conversion by hydrothermal treatment for the recovery of xylose

This work aims at the valorization of sugarcane bagasse by extracting xylose which is destined to the production of xylitol after purification and hydrogenation. Our approach consists in applying the principle of biorefinery to sugarcane bagasse because of its hemicellulose composition (particularly rich in xylan: (92%)). Optimizing of the thermal treatment was investigated. A treatment at 170 °C for 2 h was found optimal, with higher solubilzation of hemicellulose than that at 150 °C and lower degradation of sugar monomers than 190 °C. Recovery of xylose was high and the purity of xylose solution (78%) allows expecting an easy purification and separation of xylose before hydrogenation. Analysis of thermal hydrolyzates shows the presence of xylan oligomers and polymers with large distribution of DPs. This fraction should be submitted to enzymatic treatment to recover more xylose monomer.     

Implication of glutamate, isocitrate and malate deshydrogenases in nitrogen assimilation in the cadmium-stressed tomato

Tomato seedlings grown on nitric medium and treated with various cadmium concentrations (0 to 50 microM) were used. Results obtained show that cadmium remains predominantly located in the roots, which then seem to play the role of trap-organs. Increasing cadmium concentration in the medium leads particularly to a decrease in NO3- accumulation, together with a decrease in the activity of glutamine synthetase and in the quantity of plastidic isoform ARNm (GS2), and, on the contrary, to an increase of the cytosolic isoform ARNm (GS1). On the other hand, stimulations were observed for NADH-dependent glutamate synthase, NADH-dependent glutamate dehydrogenase, ARNm quantity of this enzyme, ammonium accumulation, and protease activity. In parallel, stimulations were observed for NAD+ and NADP+-dependent malate dehydrogenase and NADP+-dependent isocitrate dehydrogenase. These results were discussed in relation to the hypothesis attributing to the dehydrogenase enzymes (GDH, MDH, ICDH) an important role in the plant defence processes against cadmium-induced stresses.     

Identification of a Novel Mouse Brachyury (<Emphasis Type="Italic">T</Emphasis>) Allele Causing a Short Tail Mutation in Mice

Mutations in T-box genes are associated with numerous disease states in humans. The objective of this paper was to characterize the T ^shao , a specific T-box mutation, in mice. T ^shao , a short-tailed mutant mouse strain in a B6 background, was obtained by ethylnitrosourea mutagenesis. Microsatellite genomic scans mapped the location of the mutation. RT–PCR was used to amplify the identified region and the product was sequenced. DNA of the region was sequenced and scanned for mutations. Tails of T ^shao mice were mostly curly with tail length ranging from less than 1 cm (tail bud) to half of the normal length. T ^shao presented single dominance gene inheritance, and homozygous mutant mice died approximately at E10. Scans of the F2 generation mapped the mutant gene to chromosome 17, near D17Mit143. The Brachyury (T) gene was identified as a potential candidate gene in this location. To confirm this, RT–PCR was performed on RNA from intercrossed 8.5-day embryos, and products were sequenced. A 67-nucleotide deletion in exon 2 of the mutant T gene was identified. Further sequencing of the genomic DNA from this region identified a T to A transversion at the 67th nucleotide of exon 2. The T ^shao mutation is a result of a deletion in exon 2 causing the early termination and loss of function of protein encoded by the T gene, manifesting as a short tail phenotype.     

Protein and Peroxidase Modulations in Sunflower Seedlings (Helianthus annuus L.) Treated with a Toxic Amount of Aluminium

The aim of this study is to investigate the effect of aluminium treatment on peroxidases activities and protein content in both soluble and cell-wall-bound fractions of sunflower leaves, stems and roots. Fourteen-day-old seedlings, grown in a nutrient solution, were exposed to a toxic amount of aluminium (500 μM AlNO₃) for 72 h. Under stress conditions, biomass production, root length and leaf expansion were significantly reduced. Also, our results showed modulations on soluble and ionically cell-wall-bound peroxidases activities. In soluble fraction, peroxidases activities were enhanced in all investigated organs. This stimulation was also observed in ionically cell-wall-bound fraction in leaves and stems. Roots showed a differential behaviour: peroxidase activity was severely reduced. Lignifying peroxidases activities assayed using coniferyl alcohol and H₂O₂ as substrates were also modulated. Significant stimulation was shown on soluble fraction in leaves, stems and roots. In ionically cell-wall-bound fraction lignifying peroxidases were enhanced only in stems but severely inhibited in roots. Also, aluminium toxicity caused significant increase on cell wall protein content in sunflower roots.     

Structural requirements for substrate recognition of Mycobacterium tuberculosis 14 alpha-demethylase: implications for sterol biosynthesis

Sterol 14 alpha-demethylase (14DM) is a cytochrome P-450 involved in sterol biosynthesis in eukaryotes. It was reported that Mycobacterium smegmatis also makes cholesterol and that cholesterol is essential to Mycobacterium tuberculosis (MT) infection, although the origin of the cholesterol is unknown. A protein product from MT having about 30% sequence identity with eukaryotic 14 alpha-demethylases has been found to convert sterols to their 14-demethyl products indicating that a sterol pathway might exist in MT. To determine the optimal sterol structure recognized by MT 14DM, binding of 28 sterol and sterol-like (triterpenoids) molecules to the purified recombinant 14 alpha-demethylase was examined. Like eukaryotic forms, a 3 beta-hydroxy group and a 14 alpha-methyl group are essential for substrate acceptability by the bacterial 14 alpha-demethylase. The high affinity binding of 31-norcycloartenol without detectable activity indicates that the Delta(8)-bond is required for activity but not for binding. As for plant 14 alpha-demethylases, 31-nor-sterols show a binding preference for MT 14DM. Similar to enzymes from mammals and yeast, a C24-alkyl group is not required for MT 14DM binding and activity, whereas it is for plant 14 alpha-demethylases.Thus, substrate binding to MT 14DM seems to share common features with all eukaryotic 14 alpha-demethylases, the MT form seemingly having the broadest substrate recognition of all forms of 14 alpha-demethylase studied so far. - Bellamine, A., A. T. Mangla, A. L. Dennis, W. D. Nes, and M. R. Waterman. Structural requirements for substrate recognition of Mycobacterium tuberculosis 14 alpha-demethylase: implications for sterol biosynthesis. J. Lipid Res. 2001. 42: 128;-136.