Human mitochondrial haplogroup H: the highest VO2max consumer--is it a paradox?

Mitochondrial background has been demonstrated to influence maximal oxygen uptake (VO(2max), in mLkg(-1)min(-1)), but this genetic influence can be compensated for by regular exercise. A positive correlation among electron transport chain (ETC) coupling, ATP and reactive oxygen species (ROS) production has been established, and mitochondrial variants have been reported to show differences in their ETC performance. In this study, we examined in detail the VO(2max) differences found among mitochondrial haplogroups. We recruited 81 healthy male Spanish Caucasian individuals and determined their mitochondrial haplogroup. Their VO(2max) was determined using incremental cycling exercise (ICE). VO(2max) was lower in J than in non-J haplogroup individuals (P=0.04). The H haplogroup was responsible for this difference (VO(2max); J vs. H; P=0.008) and this group also had significantly higher mitochondrial oxidative damage (mtOD) than the J haplogroup (P=0.04). In agreement with these results, VO(2max) and mtOD were positively correlated (P=0.01). Given that ROS production is the major contributor to mtOD and consumes four times more oxygen per electron than the ETC, our results strongly suggest that ROS production is responsible for the higher VO(2max) found in the H variant. These findings not only contribute to a better understanding of the mechanisms underneath VO(2max), but also help to explain some reported associations between mitochondrial haplogroups and mtOD with longevity, sperm motility, premature aging and susceptibility to different pathologies.

Steady exercise removes VO(2max) difference between mitochondrial genomic variants.

It has been clearly established that mitochondrial variants, among other potential factors, influence on VO(2max). With this study we sought to determine whether this genetic predisposition could be modified by steady exercise. Mitochondrial genetic variants were determined in 70 healthy controls (CON) and in 77 athletes who trained regularly (50 cyclists, aerobic training (AER), and 27 runners of 400m, anaerobic training (NoAER)). All of them were male Spanish Caucasian individuals. A maximum graded exercise test (GXT) in cycle-ergometer was performed to determine VO(2max) (mL kg(-1)min(-1)). Our results confirmed that, in CON, VO(2max) (P=0.007) was higher in Non-J than J individuals. Furthermore, we found that AER and NoAER showed, as it could be expected, higher VO(2max) than CON, but not differences between mitochondrial variants have been found. According with these findings, the influence of mitochondrial DNA (mtDNA) variants on VO(2max) has been confirmed, and a new conclusion has arisen: the steady exercise is able to remove this influence. The interest of these promising findings in muscular performance should be further explored, in particular, the understanding of potential applications in sport training and in muscle pathological syndromes.

Human mitochondrial variants influence on oxygen consumption.

This work investigates if human mitochondrial variants influence on maximal oxygen consumption (VO(2max)). With this purpose we recruited, as a uniform population in term of nutritional habits and life style, 114 healthy male Spanish subjects that practiced fitness exercises 3-4 times a week. Once mtDNA haplogroups were determined, we found that J presents with lower VO(2max) (P=0.02) than nonJ variants. J has been related with a lower efficiency of electron transport chain (ETC), diminished ATP and ROS production. Thus, the difficult to compensate the mitochondrial energetic deficiency could explain the accumulation of J haplogroup in LHON and multiple sclerosis. Furthermore, the lower ROS production associated to J could also account for the accrual of this variant in elderly people consequent to a decreased oxidative damage.

Association of human mitochondrial DNA variants with plasma LDL levels.

Increasing evidence supports the relationship between mitochondrial DNA variability and differences in energy metabolism, which may have pathophenotypic consequences. MtDNA pathological mutation has been also described to be associated with hypercholesterolemia. The target of this work consisted in studying the possible existence of an association between the mitochondrial DNA variability and plasma cholesterol levels. For this, two populations of 61 sedentary and 83 sportsmen were used to estimate the association of the lipidemic levels with the mitochondrial DNA variant harboured by them. Triglycerides, HDL-c, LDL-c and cholesterol/HDL-c were essayed, and mitochondrial DNA polymorphisms were assessed by HVR I sequencing and PCR/RFLP analysis. Major Caucasian mtDNA clades (HV, JT, U and IWX) did not associate with lipidemic levels in the sedentary population. However, in the case of a more disciplined population in term of nutritional habits and life style as sportsmen are, a significantly higher and lower level of LDL-c was associated with HV and JT clade, respectively. This observation could have relevant significance for metabolic distress diseases affecting plasma cholesterol levels.

Mitochondrial lineages distribution in the Spanish population: anticipating association studies

La variación genética en el mtDNA ha sido ampliamente utilizada para dar una perspectiva de la historia demográfica humana. En este estudio, nosotros hemos analizado esta variabilidad en 686 muestras del Centro y Norte de España. La frecuencia de los haplogrupos en la población española es muy similar a la observada en otros estudios sobre esta población y a las frecuencias en las poblaciones europeas. Un análisis más profundo del haplogrupo mitocondrial U mostró diferencias con las poblaciones del norte de Europa. El conocimiento de la distribución de frecuencias de los haplogrupos en nuestra población supone un resultado importante para el diseño de estudios sobre enfemedades mitocondriales. Además, nuestros resultados son también importantes en los estudios forenses

The genetic variation in mtDNA has been widely used to give a maternal genetic perspective of the human demographic history. Here, we have studied this variability in 686 samples coming from the Centre and North of Spain. These results showed that haplogroup frequencies were similar to other Spanish studies and European populations. Haplogroups from the HV lineage were over-represented in the Spanish population. A deeper analysis of the mitochondrial haplogroup U showed differences with Northern Europe populations. The frequencies of haplogroups found give them high valour when experimental design for mitochondrial disorder studies in population is planted. In addition, the use of these data is also important for forensic studies

Differences of sperm motility in mitochondrial DNA haplogroup U sublineages.

We had previously shown that sperm from men harbouring haplogroup T mtDNAs swim less vigorously than those from haplogroup H. However, the biochemical basis of this motility was difficult to investigate because of the multiple mutations, the most important of which affected respiratory complex I for which there is no crystal structure. To more thoroughly study the relationship between mtDNA variation and differences in mitochondrial energy metabolism, we turned to the analysis of sperm baring haplogroup U mtDNAs. Haplogroup U is a monophyletic ancient and thus heterogeneous maternal lineage that is broadly distributed among European individuals. Several sublineages of haplogroup U were found to be associated with differences in sperm motility and vitality. These differences could be related to a highly conserved missense mutation in the mtDNA COIII gene (V91) and several equally conserved mutations in the cytochrome b (cytb) gene. Moreover, the lineages with the cytb mutations were substantially enriched in northern Europe, while those lacking these mutations were more prevalent in southern Europe. We suggest that some of these ancient conserved cytb missense mutations permitted our ancestors to adapt to cold by partially uncoupling mitochondrial oxidative phosphorylation (OXPHOS).