Leila Ayadi scite author profile

Many proteins necessary for sound transduction have been discovered through positional cloning of genes that cause deafness1–3. In this study, we report that mutations of LRTOMT are associated with profound non-syndromic hearing loss at the DFNB63 locus on human chromosome 11q13.3-q13.4. LRTOMT has two alternative reading frames and encodes two different proteins, LRTOMT1 and LRTOMT2, that are detected by Western blot analyses. LRTOMT2 is a putative methyltransferase. During evolution, novel transcripts can arise through partial or complete coalescence of genes4. We provide evidence that in the primate lineage LRTOMT evolved from the fusion of two neighboring ancestral genes, which exist as separate genes (Lrrc51and Tomt) in rodents.

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Abasic Sites in Duplex DNA: Molecular Modeling of Sequence-Dependent Effects on Conformation

Ayadi

Coulombeau

Lavery

1999

Biophysical Journal

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Molecular modeling calculations using JUnction Minimization of Nucleic Acids (JUMNA) have been used to study sequence effects on the conformation of abasic sites within duplex DNA. We have considered lesions leading to all possible unpaired bases (X), adenine, guanine, cytosine, or thymine contained within two distinct sequence contexts, CXC and GXG. Calculations were carried out on DNA 11-mers using extensive conformational search techniques to locate the most stable abasic conformations and using Poisson-Boltzmann corrected electrostatics to account for solvation effects. The results, which are in very good agreement with available experimental data, point to strong sequence effects on both the position of the unpaired base (intra or extrahelical) and on the overall curvature induced by the abasic lesion. For CXC, unpaired purines are found to lie within the helix, while unpaired pyrimidines are either extrahelical or in equilibrium between the intra and extrahelical forms. For GXG, all unpaired bases lead to intrahelical forms, but with marked, sequence-dependent differences in induced curvature.

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The Impact of Abasic Sites on DNA Flexibility

Ayadi

Coulombeau

Lavery

2000

Journal of Biomolecular Structure and Dynamics

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We use internal coordinate molecular mechanics calculations to study the impact of abasic sites on the conformation and the mechanics of the DNA double helix. Abasic sites, which are common mutagenic lesions, are shown to locally modify both the groove geometry and the curvature of DNA in a sequence dependent manner. By controlled twisting and bending, it is also shown that these lesions modify the deformability of the duplex, generally increasing its flexibility, but again to an extent which depends on the nature of the abasic site and on the surrounding base sequence. Both the conformational and mechanical influence of this type of DNA damage may be significant for recognition and repair mechanisms.

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Leila Ayadi

Mutations of LRTOMT, a fusion gene with alternative reading frames, cause nonsyndromic deafness in humans

Abasic Sites in Duplex DNA: Molecular Modeling of Sequence-Dependent Effects on Conformation

The Impact of Abasic Sites on DNA Flexibility

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