Aproximación al conocimiento de las bases genéticas del ictus. Consorcio español de genética del ictus / Exploring the genetic basis of stroke. Spanish stroke genetics consortium

El presente artículo revisa la evolución de los estudios en genética del ictus desde la aproximación por gen candidato hasta los recientes estudios de genome wide association. Se destaca la complejidad de esta afección por sus muy variados mecanismos etiopatogénicos, las dificultades que comporta el estudio de su componente genético y las soluciones que se han aportado. Se subraya en especial el valor de las colaboraciones entre distintos centros, ya sea de manera puntual o sobre todo a través de la creación de consorcios estables. Esta estrategia actualmente se hace imprescindible a la hora de realizar estudios de alta calidad científica que permitan seguir avanzando en el conocimiento de las bases genéticas del ictus tanto en etiología, como en tratamiento y prevención

This article provides an overview of stroke genetics studies ranging from the candidate gene approach to more recent studies by the genome wide association. It highlights the complexity of stroke owing to its different aetiopathogenic mechanisms, the difficulties in studying its genetic component, and the solutions provided to date. The study emphasises the importance of cooperation between the different centres, whether this takes places occasionally or through the creation of lasting consortiums. This strategy is currently essential to the completion of high-quality scientific studies that allow researchers to gain a better knowledge of the genetic component of stroke as it relates to aetiology, treatment, and prevention

Exploring the genetic basis of stroke. Spanish stroke genetics consortium.

This article provides an overview of stroke genetics studies ranging from the candidate gene approach to more recent studies by the genome wide association. It highlights the complexity of stroke owing to its different aetiopathogenic mechanisms, the difficulties in studying its genetic component, and the solutions provided to date. The study emphasises the importance of cooperation between the different centres, whether this takes places occasionally or through the creation of lasting consortiums. This strategy is currently essential to the completion of high-quality scientific studies that allow researchers to gain a better knowledge of the genetic component of stroke as it relates to aetiology, treatment, and prevention.

Mitochondrial DNA background modifies the bioenergetics of NARP/MILS ATP6 mutant cells.

Mutations in the mitochondrial DNA (mtDNA) encoded subunit 6 of ATPase (ATP6) are associated with variable disease expression, ranging from adult onset neuropathy, ataxia and retinitis pigmentosa (NARP) to fatal childhood maternally inherited Leigh's syndrome (MILS). Phenotypical variations have largely been attributed to mtDNA heteroplasmy. However, there is often a discrepancy between the levels of mutant mtDNA and disease severity. Therefore, the correlation among genetic defect, bioenergetic impairment and clinical outcome in NARP/MILS remains to be elucidated. We investigated the bioenergetics of cybrids from five patients carrying different ATP6 mutations: three harboring the T8993G, one with the T8993C and one with the T9176G mutation. The bioenergetic defects varied dramatically, not only among different ATP6 mutants, but also among lines carrying the same T8993G mutation. Mutants with the most severe ATP synthesis impairment showed defective respiration and disassembly of respiratory chain complexes. This indicates that respiratory chain defects modulate the bioenergetic impairment in NARP/MILS cells. Sequencing of the entire mtDNA from the different mutant cell lines identified variations in structural genes, resulting in amino acid changes that destabilize the respiratory chain. Taken together, these results indicate that the mtDNA background plays an important role in modulating the biochemical defects and clinical outcome in NARP/MILS.

Genotype-phenotype correlation in the 5703G>A mutation in the tRNA(ASN) gene of mitochondrial DNA.

The 5703G>A mutation in the tRNA gene of mitochondrial DNA seems to show a tissue-specific phenotype: early age of clinical presentation, progressive external ophthalmoplegia, fatigability and 'extremely thin appearance'. We report a second patient with the same mutation and phenotype.

Exercise intolerance resulting from a muscle-restricted mutation in the mitochondrial tRNA(Leu (CUN)) gene.

BACKGROUND: Some patients presenting with isolated lifelong exercise intolerance and ragged-red fibres, harbour skeletal-muscle restricted mutations in their mitochondrial DNA. AIM: To identify the molecular defect in a patient presenting with lifelong exercise intolerance, ragged-red fibres and deficiencies of complexes III and IV in skeletal muscle. METHODS: The muscle biopsy was studied for activities of the respiratory chain, histochemical stains, and sequencing the tRNA genes of mitochondrial DNA. RESULTS: The patient had a heteroplasmic mutation in the tRNA(Leu (CUN)) gene of mitochondrial DNA (G12334A). Clinical and morphological data as well as restriction fragment length polymorphism (RFLP) and single-fibre polymerase chain reaction (PCR) analyses strongly indicate that this molecular defect is the primary cause of the myopathy. CONCLUSION: Mutations in any mitochondrial gene should be considered in the differential diagnosis of patients with lifelong exercise intolerance, even when the neurological examination is normal.

Effect of iron salts, haemosiderins, and chelating agents on the lymphocytes of a thalassaemia patient without chelation therapy as measured in the comet assay.

Impairment of haemoglobin synthesis occurs in the genetic diseases known as thalassaemia. The consequent chronic anaemia leads to increased dietary iron absorption which results in iron overload. Treatment through regular blood transfusions increases oxygen capacity, but also adds iron from haemoglobin. An essential treatment, in parallel with transfusions, is the use of chelating agents to remove the excess iron. Thalassaemia patients are particularly at risk of free radical damage. Human lymphocytes from normal individuals can be investigated in vitro as a model system in the presence of free radicals in the Comet assay. This assay measures DNA damage, particularly DNA strand breakage. We examined cells from an Australian thalassaemic patient (sickle/beta thal double heterozygote-sickle phenotype) who had not yet received chelation therapy to determine if the cells were more sensitive to simulated iron overload and to haemosiderins. Lymphocytes from the patient were received as frozen samples after 28 h on dry ice and then placed in liquid nitrogen. Normal lymphocytes frozen under the same conditions and normal nonfrozen lymphocytes were compared. The lymphocytes from a normal female did not respond in vitro to ferric chloride (FeCl(3)) or haemosiderin but did to ferrous chloride (FeCl(2)) and ferrous sulphate (FeSO(4)). Deferoxamine appeared to reduce the response to FeCl(2) and FeSO(4) but deferiprone did not. When the lymphocytes from the nonchelated patient were treated with FeSO(4) and hydrogen peroxide, deferoxamine and deferiprone both reduced the response. Over the same dose range of iron salt (FeSO(4)), the lymphocytes from the thalassaemic patient were more sensitive, with much higher background levels of damage and induced damage. When deferiprone and deferoxamine were compared over a nontoxic range, deferiprone appeared to produce a greater reduction of damage in lymphocytes of the thalassaemia patient. Ferritin iron appears to be more available than haemosiderin iron in reactions leading to DNA damage. Haemosiderin containing higher amounts of the goethite-like (alpha-FeOOH) iron oxide phase leads to lower levels of DNA damage.

Effects of iron salts and haemosiderin from a thalassaemia patient on oxygen radical damage as measured in the comet assay.

Thalassaemia is a group of genetic diseases where haemoglobin synthesis is impaired. This chronic anaemia leads to increased dietary iron absorption, which develops into iron overload pathology. Treatment through regular transfusions increases oxygen capacity but also provides iron through the red cells' haemoglobin. An essential treatment, in parallel with transfusions, is the use of chelating agents to remove the excess iron deposited in tissues. These deposits are found in the liver, spleen, heart, and pancreas and are associated with cardiac failure and diabetes. The deposits in these tissues of patients have been isolated as haemosiderin. Thalassaemia patients are particularly at risk of free radical induced damage. Thus, the present study has investigated, as a model system, human cells in vitro in the Comet assay in the presence of free radicals. This assay measures DNA damage, particularly DNA strand breakage. The effects of iron overload on cells oxidatively stressed with hydrogen peroxide (H(2)O(2)) have been determined as well as the effect of the chelating agent, deferoxamine. Iron overload was simulated with ferric (FeCl(3)) and ferrous chloride (FeCl(2)), ferrous sulphate (FeSO(4)) and haemosiderins. Both human lymphocytes from a male and a female donor and human adenocarcinoma colonic cells showed an increase in DNA damage in the Comet assay after treatment with H(2)O(2). Ferric chloride produced an increase in DNA damage in human colonic cells, but little or no damage in human lymphocytes. Ferrous chloride also produced weak DNA damage in human lymphocytes, but ferrous sulphate produced a dose-related response. Deferoxamine produced no DNA damage. When H(2)O(2) was combined with FeCl(3), FeCl(2), or FeSO(4), the DNA damage produced was as least as great as or slightly greater than with H(2)O(2) alone. When deferoxamine was combined with H(2)O(2) and FeSO(4) there was a consistent decrease in response. There was little or no decrease in response when deferoxamine was combined with H(2)O(2) and FeCl(3) or FeCl(2), but at high (100-300microm) doses there were changes in the appearance of cellular DNA from Comet tails to dense centres surrounded by a diffuse area. This was probably as a consequence of chelation processes. Haemosiderin produced no damage. The three fractions of haemosiderin examined were of three different densities and from a Thai patient where the oxyhydroxide phase is the ferrihydrite. The colour change was similar to that for FeCl(3), but the level of the ferric ion in the haemosiderin was possibly too low in the sample to produce a response. The next stage is to examine peripheral lymphocytes from thalassaemic patients, with and without chelation therapy, whose cells may be more sensitive to simulated iron overload and to lower levels of haemosiderin. Teratogenesis Carcinog. Mutagen. 20:11-26, 2000.

Investigation of mutant frequency at the HPRT locus and changes in microsatellite sequences in healthy young adults.

In an attempt to understand the inter-individual variation that occurs in in vivo mutant frequency at the HPRT locus, we have examined the effect of polymorphisms in genes for metabolic enzymes on the mutation rate. In the same population of human volunteers, the background variant frequency in a number of microsatellite sequences was studied to determine individual variation in the capacity to repair mismatches in these sequences. The HPRT mutant frequency of T-cells isolated from a group of 49 healthy, non-smoking adults varied from 0.25 to 9.64 x 10(-6). The frequency of polymorphisms in CYP1A1, GSTM1 and NAT2 among these individuals was similar to those published, and when subjected to univariate analysis these polymorphisms showed no influence on the HPRT mutant frequency. However, there was a significant interaction between the GSTM1 null genotype and the slow acetylator status in NAT2 (P < 0.05) which was associated with higher mutant frequency. Analysis of 30 microsatellite sequences in 20 HPRT proficient clones per individual showed only six alterations in total, giving an overall mutation rate per allele of 0.01%, whilst three alterations were found in five HPRT deficient clones per individual examined for changes in 10 microsatellites, giving an overall mutation rate per allele of 0.3%. Thus, the alterations detected are probably due to background mutations and not to differences in mismatch repair capacity.