MA Liang

基本信息

姓名：马亮

性别：男  

职称：“百人计划”副教授

导师类型：博士生导师

学历：博士研究生

研究方向：动物生理生态学、机理生态位模型、生物多样性保护

办公地点：中山大学深圳校区医学园2栋1203A

电子邮箱：maliang26@mail.sysu.edu.cn

现招收生态学、动物学、资源与环境、计算机科学等方向的博士后和研究生，欢迎联系。

研究方向

1. 陆生脊椎动物在成体和胚胎阶段对环境变化的生理响应
2. 微气候模型和动物模型的开发与验证
3. 全球变化下的生物多样性保护对策

教育经历

2012/09-2017/07，中国科学院动物研究所，生态学博士

2015/10-2016/10，美国华盛顿大学（西雅图），联合培养博士

2008/09-2012/07，北京林业大学，农学学士

工作经历

2022/09-至今，中山大学，“百人计划”副教授，青年研究员；

2019/09-2022/08，美国普林斯顿大学，Associate Research Scholar；

2017/07-2019/08，中国科学院动物研究所，博士后；

学术兼职

担任《Nature Communications》、《Methods in Ecology and Evolution》、《Conservation Biology》、《Global Ecology and Biogeography》、《Diversity and Distributions》、《Proceedings of the Royal Society B: Biological Sciences》等刊物审稿人。担任《Fundamental Research》青年编委。

论文专著

1.Stark G, Ma L, Zeng ZG, Du WG, Levy O. Cool shade and not-so-cool shade: How habitat loss may accelerate thermal stress under current and future climate. Global Change Biology. 2023;29(22):6201-6216.

2.Nneji LM, Azevedo JA, Oyebanji OO, et al. Patterns of species richness and turnover in endemic amphibians of the Guineo-Congolian rain forest. Diversity and Distributions. 2023;29(8):1035-1051.

3.Mi C#, Song K#, Ma L#, et al. Optimizing protected areas to boost the conservation of key protected wildlife in China. The Innovation. 2023;4(3).

4.Mi C#, Ma L#, Yang M, et al. Global protected areas as refuges for amphibians and reptiles under climate change. Nature Communications. 2023;14(1):1389.

5.Ma L, Hou C, Jiang ZW, Du WG. Divergent effects of climate change on the egg-laying opportunity of species in cold and warm regions. Conservation Biology. 2023;37(3):e14056.

6.Ma L*, Conradie SR, Crawford CL, et al. Global patterns of climate change impacts on desert bird communities. Nature communications. 2023;14(1):211.

7.Liang D, Giam X, Hu S, Ma L, Wilcove DS. Assessing the illegal hunting of native wildlife in China. Nature. 2023;623(7985):100-105.

8.Jiang ZW#, Ma L#, Mi CR, Tao SA, Guo F, Du WG. Distinct responses and range shifts of lizard populations across an elevational gradient under climate change. Global Change Biology. 2023;29(10):2669-2680.

9.Stark G, Ma L, Zeng ZG, Du W guo, Levy O. Rocks and vegetation cover improve body condition of desert lizards during both summer and winter. Integrative and Comparative Biology. 2022;62(4):1031-1041.

10.Mi C#, Ma L#, Wang Y, Wu D, Du W, Sun B. Temperate and tropical lizards are vulnerable to climate warming due to increased water loss and heat stress. Proceedings of the Royal Society B. 2022;289(1980):20221074.

11.Ma L, Levy O, Buckley LB, Hou C, Du W guo. Variable impacts on reproductive energetics may render oviparous squamates more vulnerable to climate warming than viviparous species. Ecography. 2022;2022(5):e05624.

12.Deme GG, Hao X, Ma L, Sun B, Du W. Elevational variation in reproductive strategy of a widespread lizard: High-elevation females lay fewer but larger eggs. Asian Herpetol Res. Published online 2022:198-204.

13.Sun B jun#, Ma L#, Wang Y#, et al. Latitudinal embryonic thermal tolerance and plasticity shape the vulnerability of oviparous species to climate change. Ecological Monographs. 2021;91(3):e01468.

14.Sun B jun, Ma L, Wang Y, et al. Embryonic thermal tolerance shapes the vulnerability of lizards to climate change. Bulletin of the Ecological Society of America. 2021;102(3):1-4.

15.Ma L*, Mi C rong, Qu J peng, Ge D yan, Yang Q sen, Wilcove DS. Predicting range shifts of pikas (Mammalia, Ochotonidae) in China under scenarios incorporating land use change, climate change and dispersal limitations. Diversity and Distributions. 2021;27(12):2384-2396.

16.Jiang Z, Ma L*, Han X. Higher Body Temperatures and Earlier Parturition in Response to Hypoxia Experienced by Pregnant Lizards. Asian Herpetological Research. 2021;(2):228-233.

17.Jiang ZW, Ma L, Mi CR, Du WG. Effects of hypoxia on the thermal physiology of a high-elevation lizard: implications for upslope-shifting species. Biology Letters. 2021;17(3):20200873.

18.Huey RB, Ma L, Levy O, Kearney MR. Three questions about the eco-physiology of overwintering underground. Ecology Letters. 2021;24(2):170-185.

19.Li X, Wu P, Ma L, Huebner C, Sun B, Li S. Embryonic and post-embryonic responses to high-elevation hypoxia in a low-elevation lizard. Integrative Zoology. 2020;15(4):338-348.

20.Li X, Wang C, Tang G, et al. Does light exposure during embryonic development affect cognitive behavior in a lizard? Asian Herpetol Res. 2020;11:56-62.

21.Ye YZ#, Ma L#, Sun BJ#, et al. The embryos of turtles can influence their own sexual destinies. Current Biology. 2019;29(16):2597-2603.

22.Du WG, Shine R, Ma L, Sun BJ. Adaptive responses of the embryos of birds and reptiles to spatial and temporal variations in nest temperatures. Proceedings of the Royal Society B. 2019;286(1915):20192078.

23.Zhang Q, Han X, Hao X, et al. A simulated heat wave shortens the telomere length and lifespan of a desert lizard. Journal of thermal biology. 2018;72:94-100.

24.Sun BJ, Ma L, Li SR, et al. Phenology and the physiological niche are co-adapted in a desert-dwelling lizard. Functional ecology. 2018;32(11):2520-2530.

25.Ma L, Sun BJ, Li SR, Hao X, Bi JH, Du WG. The vulnerability of developing embryos to simulated climate warming differs between sympatric desert lizards. Journal of Experimental Zoology Part A: Ecological and Integrative Physiology. 2018;329(4-5):252-261.

26.Ma L, Sun B jun, Cao P, Li X han, Du W guo. Phenotypic plasticity may help lizards cope with increasingly variable temperatures. Oecologia. 2018;187:37-45.

27.Ma L, Buckley LB, Huey RB, Du WG. A global test of the cold-climate hypothesis for the evolution of viviparity of squamate reptiles. Global Ecology and Biogeography. 2018;27(6):679-689.

28.Wang Y, Zeng ZG, Ma L, Li SR, Du WG. Food restriction affects maternal investment but not neonate phenotypes in a viviparous lizard. Zoological Research. 2017;38(2):81.

29.Li SR, Wang Y, Ma L, Zeng ZG, Bi JH, Du WG. Thermal ecology of three coexistent desert lizards: Implications for habitat divergence and thermal vulnerability. Journal of Comparative Physiology B. 2017;187:1009-1018.

30.张博, 马亮, 李树然, et al. 北京及邻近地区蛇类存疑种分布及讨论. Published online 2017.

31.Wu B, Liang L, Ma L, Du W. Effects of pesticide exposure on embryonic development and hatchling traits of turtles. Asian Herpetological Research. 2016;7(1):28-33.

32.Sun BJ, Li T, Gao J, Ma L, Du WG. High incubation temperatures enhance mitochondrial energy metabolism in reptile embryos. Scientific Reports. 2015;5(1):8861.

33.Liang L, Sun BJ, Ma L, Du WG. Oxygen-dependent heat tolerance and developmental plasticity in turtle embryos. Journal of Comparative Physiology B. 2015;185:257-263.

34.Ma L, Sun BJ, Li SR, Sha W, Du WG. Maternal thermal environment induces plastic responses in the reproductive life history of oviparous lizards. Physiological and Biochemical Zoology. 2014;87(5):677-683.

35.马亮, 赵玉泽, 高云, et al. 北京松山国家级自然保护区两栖爬行动物资源调查. 四川动物. 2012;(2):307-310.