Szabla Natalia, Maria Labecka Anna, Antoł Andrzej, Sobczyk Łukasz, Angilletta Michael J, Czarnoleski Marcin
Life History Evolution Group, Institute of Environmental Sciences, Faculty of Biology, Jagiellonian University, Gronostajowa 7, 30-387 Kraków, Poland.
Life History Evolution Group, Institute of Environmental Sciences, Faculty of Biology, Jagiellonian University, Gronostajowa 7, 30-387 Kraków, Poland; MR Consulting Sp. z o.o. Środowiskowa sp.k., Szosa Chełmińska 177-181, 87-100 Toruń, Poland.
J Insect Physiol. 2024 Sep;157:104671. doi: 10.1016/j.jinsphys.2024.104671. Epub 2024 Jul 6.
Environmental gradients cause evolutionary and developmental changes in the cellular composition of organisms, but the physiological consequences of these effects are not well understood. Here, we studied experimental populations of Drosophila melanogaster that had evolved in one of three selective regimes: constant 16 °C, constant 25 °C, or intergenerational shifts between 16 °C and 25 °C. Genotypes from each population were reared at three developmental temperatures (16 °C, 20.5 °C, and 25 °C). As adults, we measured thorax length and cell sizes in the Malpighian tubules and wing epithelia of flies from each combination of evolutionary and developmental temperatures. We also exposed flies from these treatments to a short period of nearly complete oxygen deprivation to measure hypoxia tolerance. For genotypes from any selective regime, development at a higher temperature resulted in smaller flies with smaller cells, regardless of the tissue. At every developmental temperature, genotypes from the warm selective regime had smaller bodies and smaller wing cells but had larger tubule cells than did genotypes from the cold selective regime. Genotypes from the fluctuating selective regime were similar in size to those from the cold selective regime, but their cells of either tissue were the smallest among the three regimes. Evolutionary and developmental treatments interactively affected a fly's sensitivity to short-term paralyzing hypoxia. Genotypes from the cold selective regime were less sensitive to hypoxia after developing at a higher temperature. Genotypes from the other selective regimes were more sensitive to hypoxia after developing at a higher temperature. Our results show that thermal conditions can trigger evolutionary and developmental shifts in cell size, coupled with changes in body size and hypoxia tolerance. These patterns suggest links between the cellular composition of the body, levels of hypoxia within cells, and the energetic cost of tissue maintenance. However, the patterns can be only partially explained by existing theories about the role of cell size in tissue oxygenation and metabolic performance.
环境梯度会导致生物体细胞组成发生进化和发育变化,但其影响的生理后果尚未得到充分理解。在此,我们研究了在三种选择条件之一中进化的黑腹果蝇实验种群:恒定16°C、恒定25°C,或16°C和25°C之间的代际转移。每个种群的基因型在三种发育温度(16°C、20.5°C和25°C)下饲养。成年后,我们测量了来自进化和发育温度每种组合的果蝇马氏管和翅上皮的胸长和细胞大小。我们还将这些处理的果蝇暴露于短时间几乎完全缺氧的环境中,以测量其耐缺氧能力。对于任何选择条件下的基因型,无论组织如何,在较高温度下发育都会导致果蝇体型更小且细胞更小。在每个发育温度下,来自温暖选择条件的基因型身体和翅细胞更小,但与来自寒冷选择条件的基因型相比,其管细胞更大。来自波动选择条件的基因型在大小上与来自寒冷选择条件的基因型相似,但其两种组织的细胞在三种条件中是最小的。进化和发育处理交互影响果蝇对短期麻痹性缺氧的敏感性。来自寒冷选择条件的基因型在较高温度下发育后对缺氧的敏感性较低。来自其他选择条件的基因型在较高温度下发育后对缺氧更敏感。我们的结果表明,热条件可引发细胞大小的进化和发育变化,同时伴有体型和耐缺氧能力的改变。这些模式表明身体的细胞组成、细胞内缺氧水平和组织维持的能量成本之间存在联系。然而,这些模式只能部分地由关于细胞大小在组织氧合和代谢性能中作用的现有理论来解释。
