Projected land use changes in the Qinghai-Tibet Plateau at the carbon peak and carbon neutrality targets
Land use change is closely related to human activities, affecting ecological environment and species diversity, and how to make scientific observations and simulations to predict it has become a focal issue. The Qinghai-Tibet Plateau, known as the "third pole of the world", is extremely sensitive to global climate change. Its complex physical geography and unique social and human processes have made it a hot spot for global research. Land use change on the Tibetan Plateau is an important foundation of ecological security barrier, and it has significant impacts on the Tibetan Plateau, its surrounding regions and the world.
This study predicts land use changes in the Tibetan Plateau during the carbon peak (2021-2040), carbon neutral (2051-2070), and late 21st century (2081-2100) based on shared socioeconomic pathways (SSPs). In the base period (1995~2014), the areas of arable land, forest land, grassland, urban land and bare land on the Tibetan Plateau are about 14×103, 349×103, 1853×103, 0.3×103 and 235×103km2, respectively. compared with the base period, the area of grassland will decrease in the next three periods, and urban, forest land and bare land will increase. By the end of the 21st century, grassland will decrease by 6.1 to 21.7%, and woodland is the land use type with the largest increase in area, increasing by about 21.2 to 72.8%.
Xu R, Shi P, Gao M, Wang Y, Wang G, Su B, Huang J, Lin Q, Jiang T. 2023. Projected land use changes in the Qinghai-Tibet Plateau at the carbon peak and carbon neutrality targets. Science China Earth Sciences, 66(6): 1383–1398, https://doi.org/10.1007/s11430-022-1077-y
JOURNAL
Science China Earth Sciences
DOI
The release of DNA methylation map of four Chinese populations and epigenetic variation associated with Tibetans’ adaptation to Qinghai-Tibet Plateau
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Recently, a paper entitled “Genome-wide DNA methylation landscape of four Chinese populations and epigenetic variation linked to Tibetan high-altitude adaptation” was published online in the journal SCIENCE CHINA Life Sciences. This study is led by Prof. Wen Wang (Northwestern Polytechnical University), Prof. Shuhua Xu (Fudan University), Prof. Zhengsheng Sun (Chinese Academy of Sciences), and associate Prof. Peng Tian (Northwest A&F University). Using the recently developed double strand bisulfite sequencing (DSBS) in Sun lab, this study revealed both genetic and DNA methylation variation in four Chinese ethnic groups, and investigated the potential difference and association of the two mechanisms in the population. Based on the comparison of Tibetan with other lowland individuals, they proposed potential function of epigenetic regulation in Tibetans’ adaptation to Qinghai-Tibet Plateau.
DNA methylation is one of the most important epigenetic marks in eukaryotic genome, and play important role in multiple cellular processes. Ongoing researches have showed the variation of DNA methylation among different human populations, and associated with both genetic and environmental factors. China is the most populous country in the world, which is consisted of 56 recognized ethnic groups. Geographical distribution and habitat differences are obvious among some ethnic populations. The most typical example is Tibetans’ adaptation to Qinghai-Tibet Plateau, which is low in oxygen while high in UV radiation. However, until the publication of this work, few study has analyzed the variation of DNA methylation among different ethnic groups in China, not to say the role of epigenetic regulation in Tibetans’ adaptation to high-altitude.
In this work, the authors collected blood samples from 32 participants that came from four Chinese ethnic groups including Chinese Han, Tibetan, Mongolian, and Zhuang. They carried out DSBS, the recently developed high-throughput sequencing technology that could accurately identify both single-nucleotide variants and DNA methylation simultaneously at a single-base resolution by using one dataset. The results of this study suggest that DNA methylation-based epigenetic structure is largely different with the genetic structure that could clearly distinguish the four ethnic groups (Figure 1A). Only a small part of the DNA methylation sites shows ethnic difference and could separate the four groups (Figure 1B). Surprisingly, they found non-ethnic-specific DNA methylation variations correlated more significantly to the global genetic divergence than these ethnic-specific DNA methylation after excluding the influence of within-ethnic and between-ethnic difference (Figure 1C-E), suggesting ethnic-specific DNA methylation variations were determined more by environmental factors other than genetic diversifications. Interestingly, they revealed that DNA methylation differences between Tibetan and other lowland individuals were enriched around high-altitude adaptation related genes including EPAS1 and EGLN1 (Figure 2), that were critical selection signals in Tibetans’ adaptation to highland, suggesting DNA methylation alteration plays an important role in high-altitude adaptation. Besides, they also discussed the accuracy of Nanopore sequencing in human epigenomic study, and explored the reliability and feasibility of this new technology at DNA methylation identification as compared to DSBS. This work not only provide the first batch of epigenetic comparison map for some important Chinese populations and the first evidence of the association of epigenetic changes with Tibetans’ high-altitude adaptation.
See the article:
Lin, Z., Lu, Y., Yu, G., Teng, H., Wang, B., Yang, Y., Li, Q., Sun, Z., Xu, S., Wang, W., et al. (2023). Genome-wide DNA methylation landscape of four Chinese populations and epigenetic variation linked to Tibetan high-altitude adaptation. Sci China Life Sci 66, https://doi.org/10.1007/s11427-022-2284-8
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Science China Life Sciences
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