Babbitt Gregory A
Center for Evolutionary Functional Genomics, The Biodesign Institute, Arizona State University Tempe, AZ 85287-5301, USA.
BMC Dev Biol. 2008 Feb 23;8:19. doi: 10.1186/1471-213X-8-19.
The accuracy by which phenotype can be reproduced by genotype potentially is important in determining the stability, environmental sensitivity, and evolvability of morphology and other phenotypic traits. Because two sides of an individual represent independent development of the phenotype under identical genetic and environmental conditions, average body asymmetry (or "fluctuating asymmetry") can estimate the developmental instability of the population. The component of developmental instability not explained by intrapopulational differences in gene or environment (or their interaction) can be further defined as internal developmental noise. Surprisingly, developmental noise remains largely unexplored despite its potential influence on our interpretations of developmental stability, canalization, and evolvability. Proponents of fluctuating asymmetry as a bioindicator of environmental or genetic stress, often make the assumption that developmental noise is minimal and, therefore, that phenotype can respond sensitively to the environment. However, biologists still have not measured whether developmental noise actually comprises a significant fraction of the overall environmental response of fluctuating asymmetry observed within a population.
In a morphometric study designed to partition developmental noise from fluctuating asymmetry in the wing morphology of a monoclonal culture of cotton aphid, Aphis gosspyii, it was discovered that fluctuating asymmetry in the aphid wing was nearly four times higher than in other insect species. Also, developmental noise comprised a surprisingly large fraction ( approximately 50%) of the overall response of fluctuating asymmetry to a controlled graded temperature environment. Fluctuating asymmetry also correlated negatively with temperature, indicating that environmentally-stimulated changes in developmental instability are mediated mostly by changes in the development time of individuals.
The amount of developmental noise revealed in this trait potentially does interfere with a substantial amount of the sensitivity of fluctuating asymmetry to change in temperature. Assuming that some genetic-based variation in individual buffering of developmental instability exists in natural aphid populations, the amount of internal developmental noise determined in this study could also substantially reduce evolvability of the aphid wing. The overall findings here suggest that individual response to the seemingly high cost of stabilizing some aspects of the phenotype may account for the frequent observation of trait and species specificity in levels of fluctuating asymmetry.
基因型再现表型的准确性在决定形态及其他表型性状的稳定性、环境敏感性和可进化性方面可能具有重要意义。由于个体的两侧在相同的遗传和环境条件下代表着表型的独立发育,平均身体不对称性(或“波动不对称性”)可以估计种群的发育不稳定性。发育不稳定性中无法用种群内基因或环境差异(或它们的相互作用)来解释的部分,可以进一步定义为内部发育噪声。令人惊讶的是,尽管发育噪声可能会影响我们对发育稳定性、发育稳态和可进化性的理解,但在很大程度上仍未得到充分研究。波动不对称性作为环境或遗传压力生物指标的支持者,通常假设发育噪声极小,因此表型能够对环境做出敏感反应。然而,生物学家尚未测量发育噪声在种群中观察到的波动不对称性的整体环境响应中是否实际占很大比例。
在一项旨在将发育噪声与棉蚜单克隆培养物翅形态的波动不对称性区分开来的形态测量研究中,发现蚜虫翅的波动不对称性几乎是其他昆虫物种的四倍。此外,发育噪声在波动不对称性对受控梯度温度环境的整体响应中占了惊人的很大比例(约50%)。波动不对称性也与温度呈负相关,这表明环境刺激引起的发育不稳定性变化主要由个体发育时间的变化介导。
该性状中揭示的发育噪声量可能确实会干扰波动不对称性对温度变化的大量敏感性。假设自然蚜虫种群中存在基于个体对发育不稳定性缓冲的一些遗传变异,本研究中确定的内部发育噪声量也可能大幅降低蚜虫翅的可进化性。这里的总体研究结果表明,个体对稳定表型某些方面的看似高昂成本的反应,可能解释了在波动不对称水平上经常观察到的性状和物种特异性。
