Genetic Variations Creating MicroRNA Target Sites in the FXN 3′-UTR Affect Frataxin Expression in Friedreich Ataxia

Computational microRNA (miRNA) target prediction is one of the key means for deciphering the role of miRNAs in development and disease. Here, we present the DIANA-microT web server as the user interface to the DIANA-microT 3.0 miRNA target prediction algorithm. The web server provides extensive information for predicted miRNA:target gene interactions with a user-friendly interface, providing extensive connectivity to online biological resources. Target gene and miRNA functions may be elucidated through automated bibliographic searches and functional information is accessible through Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways. The web server offers links to nomenclature, sequence and protein databases, and users are facilitated by being able to search for targeted genes using different nomenclatures or functional features, such as the genes possible involvement in biological pathways. The target prediction algorithm supports parameters calculated individually for each miRNA:target gene interaction and provides a signal-to-noise ratio and a precision score that helps in the evaluation of the significance of the predicted results. Using a set of miRNA targets recently identified through the pSILAC method, the performance of several computational target prediction programs was assessed. DIANA-microT 3.0 achieved there with 66% the highest ratio of correctly predicted targets over all predicted targets. The DIANA-microT web server is freely available at www.microrna.gr/microT.

Friedreich ataxia is a progressive neurodegenerative disorder caused by loss of function mutations in the frataxin gene. In order to unravel frataxin function we developed monoclonal antibodies raised against different regions of the protein. These antibodies detect a processed 18 kDa protein in various human and mouse tissues and cell lines that is severely reduced in Friedreich ataxia patients. By immunocytofluorescence and immunocytoelectron microscopy we show that frataxin is located in mitochondria, associated with the mitochondrial membranes and crests. Analysis of cellular localization of various truncated forms of frataxin expressed in cultured cells and evidence of removal of an N-terminal epitope during protein maturation demonstrated that the mitochondrial targetting sequence is encoded by the first 20 amino acids. Given the shared clinical features between Friedreich ataxia, vitamin E deficiency and some mitochondriopathies, our data suggest that a reduction in frataxin results in oxidative damage.

The clinical features of 115 patients from 90 families with Friedreich's ataxia are described. Onset of symptoms was before the age of 25 (mean 10.52) years in all the index cases. An analysis of early cases suggested that limb and truncal ataxia and absent tendon reflexes in the legs were the only consistent diagnostic criteria within five years of presentation. Dysarthria, signs of pyramidal tract dysfunction in the legs and loss of joint position and vibration sense are not necessarily present during the first five years of symptoms, but appear to develop eventually in all cases. Scoliosis and ECG evidence of cardiomyopathy were found in over two-thirds of the patients studied; pes cavus, distal amyotrophy, optic atrophy, nystagmus and deafness were all less frequent. The disorder was gradually progressive in all cases. The mean age of losing the ability to walk was 25 years; 95 per cent were chair-bound by the age of 44 years. About 10 per cent of the patients had diabetes mellitus which was controlled by oral hypoglycaemic drugs in one quarter. Diabetes appeared to be associated with a higher incidence of optic atrophy and deafness. Diabetes also clustered within sibships; the risk of an individual with Friedreich's ataxia developing diabetes if an affected sib has it is over 40 per cent. Similarly, cardiomyopathy ran true within affected members of the same sibship, but there were instances of discordance which suggest that the development of the non-neurological features of Friedreich's ataxia may be controlled by modifying genes rather than heterogeneity of the main gene. Segregation analysis and an increased consanguinity rate amongst parents of patients (5.55 per cent) confirmed that this disorder is of autosomal recessive inheritance. A study of 101 first degree relatives of the patients with Friedreich's ataxia failed to demonstrate any neurological or electrocardiographic abnormalities which could be ascribed to the heterozygous state.