中国现代人群上、下肢形态与环境温度的相关性分析

doi:10.16359/j.cnki.cn11-1963/q.2020.0071

摘要/Abstract

摘要：

观察中国不同区域内现代人群四肢形态变化是否与艾伦法则相一致。本文搜集中国各区域102处地点的现代人群上、下肢测量性状中17项指标,探讨其与温度（年平均温度、年最高温度、年最低温度和气温年较差）间的线性关系。结果表明,随着环境温度降低,中国现代人的上肢相对长度逐渐变短,前臂和手则逐渐增粗;下肢（下肢全长、大腿长和小腿长）逐渐变长,且下肢相对长度同样渐增。手长、手宽、上臂围和前臂围与气温年较差呈正相关,而身高上肢长指数与气温年较差呈负相关;下肢全长、大腿长、足长和小腿围与气温年较差呈正相关。环境温度作为一项选择性压力,作用于上肢发育或形态塑造过程的显著程度上要高于下肢。中国现代人群的四肢形态变化规律并不完全符合艾伦法则,可能与遗传、地理环境、功能性需求、生存策略和营养等因素共同影响现代人群的四肢发育密切相关。

关键词: 艾伦法则, 中国现代人群, 温度, 四肢, 环境适应性

Abstract:

Environmental temperature has a significant impact on human body size and its proportions, which is often referred to as Allen’s rule, that warm-regional species tend to display shorter appendages (limbs, ears and tails) than cold-region ones. But recent studies have paid less attention to this Allen’s rule in physical anthropology. Thus, this paper studies the relationships between absolute and relative limb size and temperature among different regional populations to test whether Allen’s rule exists in modern Chinese populations. We collected 17 measurements of the upper and lower limbs in modern Chinese populations from 102 sites, and took mean annual temperature (MAT), annual highest temperature, annual lowest temperature and annual range of temperature as the temperature indices.
As the environmental temperature decrease, the upper limb tends to become shorter and robust, and the lower limbs become longer. The results also showed a positive correlation of most limb measurements and MAT, whereas the stature-upper limb length index is negatively correlated with MAT. Based on the above results, we suggest the temperature can be taken as an environmental selection pressure that play more important roles in shaping the upper limbs than that of the lower limbs. Moreover, the variation of limb morphology in modern Chinese populations is not completely in accordance with Allen’s rule, which may be associated with the development of body proportions under the combined effect of influential factors including genetic background, geographical climate conditions, functional requirements (biped or dexterous manipulation), survival strategy and nutrition.

Key words: Allen’s rule, Modern Chinese populations, Temperature, Limbs, Environmental adaptation

中图分类号:

Q981

杜抱朴, 杜靖. 中国现代人群上、下肢形态与环境温度的相关性分析[J]. 人类学学报, 2021, 40(04): 644-652.

DU Baopu, DU Jing. Relationships between the limb morphology and environmental temperature in modern Chinese populations as revealed by correlation analysis[J]. Acta Anthropologica Sinica, 2021, 40(04): 644-652.

图/表 1

参考文献 41

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指标 Values	n	男性 Male				n	女性 Female
指标 Values	n	MAT	AHT	ALT	ART	n	MAT	AHT	ALT	ART
UEL	126	-0.09	-0.07	-0.12	0.17	125	-0.08	-0.06	-0.11	0.15
UAL	96	0.05	0.05	0.02	0.03	95	0.05	0.06	0.03	0.02
FML	96	-0.09	-0.08	-0.10	0.15	95	-0.06	-0.05	-0.07	0.09
HL	115	-0.15	-0.14	-0.16	0.21*	114	-0.14	-0.14	-0.15	0.20*
HB	99	-0.47**	-0.46**	-0.46**	0.35**	98	-0.43**	-0.42**	-0.42**	0.32**
LEL	121	-0.47**	-0.46**	-0.49**	0.49**	121	-0.36**	-0.33**	-0.38**	0.35**
TL	93	-0.20	-0.23*	-0.21*	0.34**	92	-0.15	-0.16	-0.16	0.29**
LL	94	-0.30**	-0.25*	-0.33**	0.10	93	-0.22*	-0.14	-0.25*	-0.04
FL	100	-0.37**	-0.38**	-0.37**	0.41**	99	-0.22*	-0.21*	-0.25*	0.31*
FB	97	-0.10	-0.09	-0.10	0.07	96	-0.09	-0.08	-0.10	0.07
BC	100	-0.18	-0.19	-0.20*	0.43**	99	-0.16	-0.18	-0.18	0.42**
MFC	82	-0.33**	-0.33**	-0.35**	0.43**	81	-0.29**	-0.28**	-0.30**	0.38**
MTC	98	-0.03	-0.06	-0.03	0.28**	97	0.06	0.04	0.05	0.20
CC	84	-0.17	-0.20	-0.17	0.41**	83	-0.19	-0.20	-0.20	0.40**
SSHI	114	-0.07	-0.06	-0.09	0.17	113	-0.09	-0.07	-0.10	0.13
SULLI	107	0.54**	0.54**	0.54**	-0.49**	107	0.47**	0.46**	0.47**	-0.46**
SLLLI	107	-0.27**	-0.25*	-0.26**	0.18	107	-0.21*	-0.19	-0.22*	0.14

指标 Values	n	男性 Male				n	女性 Female
指标 Values	n	MAT	AHT	ALT	ART	n	MAT	AHT	ALT	ART
UEL	126	-0.09	-0.07	-0.12	0.17	125	-0.08	-0.06	-0.11	0.15
UAL	96	0.05	0.05	0.02	0.03	95	0.05	0.06	0.03	0.02
FML	96	-0.09	-0.08	-0.10	0.15	95	-0.06	-0.05	-0.07	0.09
HL	115	-0.15	-0.14	-0.16	0.21*	114	-0.14	-0.14	-0.15	0.20*
HB	99	-0.47**	-0.46**	-0.46**	0.35**	98	-0.43**	-0.42**	-0.42**	0.32**
LEL	121	-0.47**	-0.46**	-0.49**	0.49**	121	-0.36**	-0.33**	-0.38**	0.35**
TL	93	-0.20	-0.23*	-0.21*	0.34**	92	-0.15	-0.16	-0.16	0.29**
LL	94	-0.30**	-0.25*	-0.33**	0.10	93	-0.22*	-0.14	-0.25*	-0.04
FL	100	-0.37**	-0.38**	-0.37**	0.41**	99	-0.22*	-0.21*	-0.25*	0.31*
FB	97	-0.10	-0.09	-0.10	0.07	96	-0.09	-0.08	-0.10	0.07
BC	100	-0.18	-0.19	-0.20*	0.43**	99	-0.16	-0.18	-0.18	0.42**
MFC	82	-0.33**	-0.33**	-0.35**	0.43**	81	-0.29**	-0.28**	-0.30**	0.38**
MTC	98	-0.03	-0.06	-0.03	0.28**	97	0.06	0.04	0.05	0.20
CC	84	-0.17	-0.20	-0.17	0.41**	83	-0.19	-0.20	-0.20	0.40**
SSHI	114	-0.07	-0.06	-0.09	0.17	113	-0.09	-0.07	-0.10	0.13
SULLI	107	0.54**	0.54**	0.54**	-0.49**	107	0.47**	0.46**	0.47**	-0.46**
SLLLI	107	-0.27**	-0.25*	-0.26**	0.18	107	-0.21*	-0.19	-0.22*	0.14