Genes modificadores en enfermedades poliglutamínicas.

Las enfermedades poliglutamínicas constituyen un grupo creciente de enfermedades neurodegenerativas humanas, causadas por la expansión de secuencias repetitivas de CAG que son traducidas para dar lugar a proteínas con dominios poliglutamínicos expandidos. La edad de inicio es un marcador fenotípico para estas enfermedades, y muestra una gran variación en  las familias afectadas. El número de repeticiones de CAG contenido en los genes causales, explica entre el 47 y 80% de la variabilidad observada en la edad de inicio. Para explicar la varianza restante ha sido propuesta la hipótesis de la existencia de genes modificadores. Aquí realizamos una revisión actualizada acerca de esta temática, abordando las estrategias más usadas para su identificación, los principales hallazgos obtenidos y sus implicaciones. La identificación de estos genes contribuye al esclarecimiento de los mecanismo patológicos involucrados en estas enfermedades, y puede conducir a la proposición y diseño de estrategias terapéuticas potenciales

GENES MODIFICADORES EN ENFERMEDADES POLIGLUTAMÍNICAS Modifying genes in poliglutaminic diseases

Las enfermedades poliglutamínicas constituyen un grupo creciente de enfermedades neurodegenerativas humanas, causadas por la expansión de secuencias repetitivas de CAG que son traducidas para dar lugar a proteínas con dominios poliglutamínicos expandidos. La edad de inicio es un marcador fenotípico para estas enfermedades, y muestra una gran variación en las familias afectadas. El número de repeticiones de CAG contenido en los genes causales, explica entre el 47 y 80% de la variabilidad observada en la edad de inicio. Para explicar la varianza restante ha sido propuesta la hipótesis de la existencia de genes modificadores. Aquí realizamos una revisión actualizada acerca de esta temática, abordando las estrategias más usadas para su identificación, los principales hallazgos obtenidos y sus implicaciones. La identificación de estos genes contribuye al esclarecimiento de los mecanismo patológicos involucrados en estas enfermedades, y puede conducir a la proposición y diseño de estrategias terapéuticas potenciales.<br>Poliglutaminic diseases are an increasing group of human neurodegenerative diseases caused by the expansion of repetitive sequences of CAG which give way to expanded poliglutaminic domains proteins. Ages of onset are a phenotypic marker for these diseases and show a great variation in the affected families. The number of CAG content repetitions in the causal genes, explains a 47 to 80 % of the variability of the age of onset. To explain the remaining variability, the hypothesis of modifying genes has been proposed. We have performed an updated revision of the the subject approaching the more utilized techniques to its identification, the principal findings and its implications. The identification of these genes contribute to clarify the involved pathological mechanisms in these diseases and might conduct to the proposition of potential therapeutic strategies

Spinocerebellar Ataxia Type 2 Is Associated with the Extracellular Loss of Superoxide Dismutase but Not Catalase Activity

BackgroundSpinocerebellar ataxia type 2 (SCA2) is an inherited and still incurable neurodegenerative disorder. Evidence suggests that pro-oxidant agents as well as factors involved in antioxidant cellular defenses are part of SCA2 physiopathology.AimTo assess the influence of superoxide dismutase (SOD3) and catalase (CAT) enzymatic activities on the SCA2 syndrome.MethodClinical, molecular, and electrophysiological variables, as well as SOD3 and CAT enzymatic activities were evaluated in 97 SCA2 patients and in 64 age- and sex-matched control individuals.ResultsSpinocerebellar ataxia type 2 patients had significantly lower SOD3 enzymatic activity than the control group. However, there were no differences between patients and controls for CAT enzymatic activity. The effect size for the loss of patients’ SOD3 enzymatic activity was 0.342, corresponding to a moderate effect. SOD3 and CAT enzymatic activities were not associated with the CAG repeat number at the ATXN2 gene. SOD3 and CAT enzymatic activities did not show significant associations with the age at onset, severity score, or the studied electrophysiological markers.ConclusionThere is a reduced SOD3 enzymatic activity in SCA2 patients with no repercussion on the clinical phenotype

Redox Imbalance Associates with Clinical Worsening in Spinocerebellar Ataxia Type 2

Background. Spinocerebellar ataxia type 2 (SCA2) is a neurodegenerative disease presenting with redox imbalance. However, the nature and implications of redox imbalance in SCA2 physiopathology have not been fully understood. Objective. The objective of this study is to assess the redox imbalance and its association with disease severity in SCA2 mutation carriers. Methods. A case-control study was conducted involving molecularly confirmed SCA2 patients, presymptomatic individuals, and healthy controls. Several antioxidant parameters were assessed, including serum thiol concentration and the superoxide dismutase, catalase, and glutathione S-transferase enzymatic activities. Also, several prooxidant parameters were evaluated, including thiobarbituric acid-reactive species and protein carbonyl concentrations. Damage, protective, and OXY scores were computed. Clinical correlates were established. Results. Significant differences were found between comparison groups for redox markers, including protein carbonyl concentration (F=3.30; p=0.041), glutathione S-transferase activity (F=4.88; p=0.009), and damage (F=3.20; p=0.045), protection (F=12.75; p<0.001), and OXY (F=7.29; p=0.001) scores. Protein carbonyl concentration was positively correlated with CAG repeat length (r=0.27; p=0.022), while both protein carbonyl concentration (r=−0.27; p=0.018) and OXY score (r=−0.25; p=0.013) were inversely correlated to the disease duration. Increasing levels of antioxidants and decreasing levels of prooxidant parameters were associated with clinical worsening. Conclusions. There is a disruption of redox balance in SCA2 mutation carriers which depends on the disease stage. Besides, redox changes associate with markers of disease severity, suggesting a link between disruption of redox balance and SCA2 physiopathology