Angiotensin converting enzyme insertion allele in relation to high altitude adaptation

Norboo²,

Biomedicine & Pharmacotherapy

et al. 2005

Self Cite

The effect of aging on blood pressure (BP) and heart rate (HR) was investigated in a cross-sectional study in the high-altitude community of Leh, Ladakh (altitude: 3524 m) and a Japanese community in U town, Hokkaido (altitude: 25 m). BP and HR were obtained in a sitting position from 332 subjects 13-81 years of age in Ladakh, and from 216 Japanese citizens, 24-79 years of age. Measurements were taken after a 2-min rest, using a semi-automated BP device (UA-767 PC, A&D Co. LTD, Tokyo). High-altitude people showed higher diastolic BP and HR values than lowland people (83.2 vs. 76.9 mmHg and 78.6 vs. 69.2 bpm, P < 0.001), but no difference in systolic BP. Highland people also showed a steeper BP increase with age than the lowland people (systolic BP: 0.7476 vs. 0.3179 mmHg/year, P < 0.0005; diastolic BP: 0.3196 vs. 0.0750 mmHg/year, P < 0.001). This chronoecologic investigation in Ladakh examined the circulation as a physiological system at highaltitude. Our data indicate the need for a more comprehensive cardiovascular assessment for a better diagnosis and a more fruitful treatment. Longitudinal observations of effects of socio-ecologic factors on the cardiovascular system should help prevent strokes and other cardiovascular events, especially at high altitude.

Section: Discussionmentioning

confidence: 89%

Effect of aging on blood pressure in Leh, Ladakh, a high-altitude (3524 m) community, by comparison with a Japanese town

Norboo²,

Biomedicine & Pharmacotherapy

et al. 2005

Self Cite

Wilderness & Environmental Medicine

“…38 Whatever the race, individuals with II genotype have the lowest circulating ACE levels, DD homozygotes have the highest ACE levels, and ID heterozygotes have intermediate levels. 9,10,38 One outstanding study demonstrated an allele skew with a significant excess of the I allele and II genotype in elite male British mountaineers who ascended beyond 7,000 m without the use of supplemental oxygen. 12 Following a line of this study, it was shown that the I allele of the ACE gene is associated with maintenance of SpO 2 during rapid ascent to altitudes over 5,000 m. 39 Regarding high-altitude residents, Qadar Pasha et al 10 reported that the I allele and II genotype of ACE I/D polymorphism were significantly prevalent in high-altitude natives of Ladakhis, who reside for their lifetime at over 3600 m compared to lowland residents in the same region.…”

Section: Genotypic Distributions and Allelic Frequencies Of The Ace Imentioning

confidence: 99%

“…[9][10][11] The ACE gene is chosen primarily as a candidate gene because the I allele has been shown to be associated with Caucasian mountain climbers who ascended to extremely high altitude without supplemental oxygen. 12 The objective of this study was to investigate ACE I/D polymorphism in Sherpas in order to evaluate the possible involvement of this polymorphism in high altitude adaptation in Sherpas.…”

Section: Introductionmentioning

confidence: 99%

Adaptation to High Altitude in Sherpas: Association with the Insertion/Deletion Polymorphism in the Angiotensin-Converting Enzyme Gene

Droma

Hanaoka

Basnyat

et al. 2008

Objective-Sherpas are well known for their physical strength at high altitudes. They adapt to high altitude so well that little acute or chronic mountain sickness has been documented in them. The possible genetic basis for this adaptation is, however, unclear. The objective of this study was to elucidate the genetic background underlying this characteristic among Sherpas with respect to the angiotension-converting enzyme (ACE) gene. Conclusions-These findings suggest that the over-represented I allele of the ACE gene in Sherpas might be one of the fundamental genetic factors responsible for maintaining physiological low-altitude ACE activity at high altitude, which may have an advantageous physiological role in adapting to a high-altitude environment. Methods-We2

“…ARNT (SG specific), whose protein product binds to HIF-α to regulate adaptation to hypoxia 37 , has been mentioned as a target of positive selection in the human Tibetan population 45 . ACE (SG specific), which functions in blood pressure regulation and carries variants responsible for high-altitude pulmonary hypertension (HAPH) 38 , has been reported to have a role in high-altitude adaptation of human populations [46][47][48] . In comparison, no significant signatures of selection were observed in hemoglobin genes, which have been identified as critical genes for oxygen binding and resistance to hypoxia in other high-altitude mammals [49][50][51][52][53] .…”

Section: Volume 48 | Number 8 | August 2016 Nature Genetics L E T T Ementioning

confidence: 99%

Genomic analysis of snub-nosed monkeys (Rhinopithecus) identifies genes and processes related to high-altitude adaptation

et al. 2016

4 7 OPENThe snub-nosed monkey genus Rhinopithecus includes five closely related species distributed across altitudinal gradients from 800 to 4,500 m. Rhinopithecus bieti, Rhinopithecus roxellana, and Rhinopithecus strykeri inhabit high-altitude habitats, whereas Rhinopithecus brelichi and Rhinopithecus avunculus inhabit lowland regions. We report the de novo whole-genome sequence of R. bieti and genomic sequences for the four other species. Eight shared substitutions were found in six genes related to lung function, DNA repair, and angiogenesis in the high-altitude snub-nosed monkeys. Functional assays showed that the high-altitude variant of CDT1 (Ala537Val) renders cells more resistant to UV irradiation, and the high-altitude variants of RNASE4 (Asn89Lys and Thr128Ile) confer enhanced ability to induce endothelial tube formation in vitro. Genomic scans in the R. bieti and R. roxellana populations identified signatures of selection between and within populations at genes involved in functions relevant to high-altitude adaptation. These results provide valuable insights into the adaptation to high altitude in the snub-nosed monkeys.