Your search keyword '"Kong Qp"' showing total 5 results

1. Methylation entropy landscape of Chinese long-lived individuals reveals lower epigenetic noise related to human healthy aging.

Author

Wang HT, Xiao FH, Gao ZL, Guo LY, Yang LQ, Li GH, and Kong QP

Subjects

Aged, Aged, 80 and over, Female, Humans, Male, Aging genetics, East Asian People genetics, Entropy, Longevity genetics, DNA Methylation genetics, Epigenesis, Genetic, Healthy Aging genetics

Abstract

The transition from ordered to noisy is a significant epigenetic signature of aging and age-related disease. As a paradigm of healthy human aging and longevity, long-lived individuals (LLI, >90 years old) may possess characteristic strategies in coping with the disordered epigenetic regulation. In this study, we constructed high-resolution blood epigenetic noise landscapes for this cohort by a methylation entropy (ME) method using whole genome bisulfite sequencing (WGBS). Although a universal increase in global ME occurred with chronological age in general control samples, this trend was suppressed in LLIs. Importantly, we identified 38,923 genomic regions with LLI-specific lower ME (LLI-specific lower entropy regions, for short, LLI-specific LERs). These regions were overrepresented in promoters, which likely function in transcriptional noise suppression. Genes associated with LLI-specific LERs have a considerable impact on SNP-based heritability of some aging-related disorders (e.g., asthma and stroke). Furthermore, neutrophil was identified as the primary cell type sustaining LLI-specific LERs. Our results highlight the stability of epigenetic order in promoters of genes involved with aging and age-related disorders within LLI epigenomes. This unique epigenetic feature reveals a previously unknown role of epigenetic order maintenance in specific genomic regions of LLIs, which helps open a new avenue on the epigenetic regulation mechanism in human healthy aging and longevity., (© 2024 The Authors. Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.)

Published

2024

2. Scrutiny of genome-wide somatic mutation profiles in centenarians identifies the key genomic regions for human longevity.

Author

Wang HT, Zhao L, Yang LQ, Ge MX, Yang XL, Gao ZL, Cun YP, Xiao FH, and Kong QP

Subjects

Aged, 80 and over, Humans, Aging genetics, Mutation genetics, Genomics, Centenarians, Longevity genetics

Abstract

Somatic mutations accumulate with age and are associated closely with human health, their characterization in longevity cohorts remains largely unknown. Here, by analyzing whole genome somatic mutation profiles in 73 centenarians and 51 younger controls in China, we found that centenarian genomes are characterized by a markedly skewed distribution of somatic mutations, with many genomic regions being specifically conserved but displaying a high function potential. This, together with the observed more efficient DNA repair ability in the long-lived individuals, supports the existence of key genomic regions for human survival during aging, with their integrity being of essential to human longevity., (© 2023 The Authors. Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.)

Published

2024

3. System-level metabolic modeling facilitates unveiling metabolic signature in exceptional longevity.

Author

Li GH, Han F, Xiao FH, Gu KS, Shen Q, Xu W, Li WX, Wang YL, Liang B, Huang JF, Xiao W, and Kong QP

Subjects

Aged, 80 and over, Aging genetics, Aging metabolism, Humans, Metabolomics, Transcriptome genetics, Healthy Aging, Longevity genetics

Abstract

Although it is well known that metabolic control plays a crucial role in regulating the health span and life span of various organisms, little is known for the systems metabolic profile of centenarians, the paradigm of human healthy aging and longevity. Meanwhile, how to well characterize the system-level metabolic states in an organism of interest remains to be a major challenge in systems metabolism research. To address this challenge and better understand the metabolic mechanisms of healthy aging, we developed a method of genome-wide precision metabolic modeling (GPMM) which is able to quantitatively integrate transcriptome, proteome and kinetome data in predictive modeling of metabolic networks. Benchmarking analysis showed that GPMM successfully characterized metabolic reprogramming in the NCI-60 cancer cell lines; it dramatically improved the performance of the modeling with an R 2 of 0.86 between the predicted and experimental measurements over the performance of existing methods. Using this approach, we examined the metabolic networks of a Chinese centenarian cohort and identified the elevated fatty acid oxidation (FAO) as the most significant metabolic feature in these long-lived individuals. Evidence from serum metabolomics supports this observation. Given that FAO declines with normal aging and is impaired in many age-related diseases, our study suggests that the elevated FAO has potential to be a novel signature of healthy aging of humans., (© 2022 The Authors. Aging Cell published by the Anatomical Society and John Wiley & Sons Ltd.)

Published

2022

4. Tracing the origins of Hakka and Chaoshanese by mitochondrial DNA analysis.

Author

Wang WZ, Wang CY, Cheng YT, Xu AL, Zhu CL, Wu SF, Kong QP, and Zhang YP

Subjects

Asian People genetics, China, Emigration and Immigration, Haplotypes, History, Ancient, Humans, Population Dynamics, Principal Component Analysis, Sequence Alignment, Sequence Analysis, DNA, Asian People history, DNA, Mitochondrial chemistry

Abstract

Hakka and Chaoshanese are two unique Han populations residing in southern China but with northern Han (NH) cultural traditions and linguistic influences. Although most of historical records indicate that both populations migrated from northern China in the last two thousand years, no consensus on their origins has been reached so far. To shed more light on the origins of Hakka and Chaoshanese, mitochondrial DNAs (mtDNAs) of 170 Hakka from Meizhou and 102 Chaoshanese from Chaoshan area, Guangdong Province, were analyzed. Our results show that some southern Chinese predominant haplogroups, e.g. B, F, and M7, have relatively high frequencies in both populations. Although median network analyses show that Hakka/Chaoshanese share some haplotypes with NH, interpopulation comparison reveals that both populations show closer affinity with southern Han (SH) populations than with NH. In consideration of previous results from nuclear gene (including Y chromosome) research, it is likely that matrilineal landscapes of both Hakka and Chaoshanese have largely been shaped by the local people during their migration southward and/or later colonization in southern China, and factors such as cultural assimilation, patrilocality, and even sex-bias in the immigrants might have played important roles during the process.

Published

2010

5. Identification of Native American founder mtDNAs through the analysis of complete mtDNA sequences: some caveats.

Author

Bandelt HJ, Herrnstadt C, Yao YG, Kong QP, Kivisild T, Rengo C, Scozzari R, Richards M, Villems R, Macaulay V, Howell N, Torroni A, and Zhang YP

Subjects

Asian People genetics, Base Sequence, Haplotypes genetics, Humans, Molecular Sequence Data, Mutation genetics, Research Design, Sequence Analysis, DNA, United States, American Indian or Alaska Native genetics, DNA, Mitochondrial genetics, Founder Effect

Abstract

In this study, a detailed analysis of both previously published and new data was performed to determine whether complete, or almost complete, mtDNA sequences can resolve the long-debated issue of which Asian mtDNAs were founder sequences for the Native American mtDNA pool. Unfortunately, we now know that coding region data and their analysis are not without problems. To obtain and report reasonably correct sequences does not seem to be a trivial task, and to discriminate between Asian and Native American mtDNA ancestries may be more complex than previously believed. It is essential to take into account the effects of mutational hot spots in both the control and coding regions, so that the number of apparent Native American mtDNA founder sequences is not erroneously inflated. As we report here, a careful analysis of all available data indicates that there is very little evidence that more than five founder mtDNA sequences entered Beringia before the Last Glacial Maximum and left their traces in the current Native American mtDNA pool.

Published

2003