autogenous regulation

简明释义

自身第

英英释义

例句

1.The success of the coral reef depends on its ability to perform autogenous regulation in response to environmental stressors.

珊瑚礁的成功依赖于其对环境压力源进行自我调节的能力。

2.Understanding autogenous regulation helps in developing better conservation strategies for endangered species.

理解自我调节有助于制定更好的濒危物种保护策略。

3.In a controlled environment, autogenous regulation can lead to more stable growth conditions for plants.

在控制环境中，自我调节可以为植物提供更稳定的生长条件。

4.The concept of autogenous regulation is crucial in understanding how ecosystems maintain balance.

理解生态系统如何维持平衡的关键在于自我调节的概念。

5.The study revealed that fish populations utilize autogenous regulation to adapt to changing water conditions.

研究表明，鱼类种群利用自我调节来适应变化的水质条件。

作文

In the realm of biology and ecology, the concept of autogenous regulation plays a crucial role in understanding how organisms maintain homeostasis and adapt to their environments. Autogenous regulation refers to the ability of an organism to regulate its internal environment independently, without relying on external factors. This self-regulating mechanism is vital for survival, as it allows organisms to respond effectively to changes in their surroundings while maintaining optimal conditions for their physiological processes.One of the most prominent examples of autogenous regulation can be observed in thermoregulation among mammals. Mammals possess the ability to maintain a stable body temperature despite fluctuations in environmental temperatures. This is achieved through various physiological mechanisms such as sweating, shivering, and altering blood flow to the skin. For instance, when exposed to cold temperatures, a mammal will shiver to generate heat and constrict blood vessels to minimize heat loss. Conversely, in hot conditions, sweating helps cool the body down through evaporative cooling. This remarkable ability to regulate body temperature exemplifies autogenous regulation in action.Plants also exhibit forms of autogenous regulation, particularly in their growth and development. Through processes like phototropism and gravitropism, plants can adjust their growth direction in response to light and gravity, respectively. For example, a plant may bend towards a light source to maximize photosynthesis, demonstrating its ability to regulate its growth based on environmental cues. This adaptability is essential for optimizing resource acquisition and ensuring survival in varying conditions, showcasing another aspect of autogenous regulation.In addition to individual organisms, autogenous regulation can also be observed at the population and ecosystem levels. For instance, predator-prey dynamics often illustrate how populations can self-regulate through natural mechanisms. When a prey population increases, it may lead to a rise in predator numbers due to increased food availability. However, as the predator population grows, it can result in a decline in the prey population, which eventually causes the predator population to decrease as well. This cyclical interaction demonstrates how populations can regulate themselves over time, reflecting the principles of autogenous regulation in ecological systems.Understanding autogenous regulation is crucial for various fields, including conservation biology, medicine, and environmental science. By recognizing how organisms and ecosystems self-regulate, scientists and researchers can develop more effective strategies for conservation and management. For instance, understanding the autogenous regulation mechanisms of endangered species can aid in creating appropriate conservation plans that support their natural behaviors and needs.In conclusion, autogenous regulation is a fundamental concept in biology that underscores the ability of organisms and ecosystems to maintain stability and adapt to changes. Whether through physiological processes in animals or growth adjustments in plants, this self-regulatory capability is essential for survival. Moreover, recognizing the importance of autogenous regulation at various biological levels can enhance our understanding of ecological interactions and inform conservation efforts aimed at preserving biodiversity. As we continue to explore the complexities of life, the significance of autogenous regulation remains a cornerstone of biological study, highlighting the intricate balance that sustains life on Earth.

在生物学和生态学领域，自生调节的概念在理解有机体如何维持稳态和适应其环境方面发挥着至关重要的作用。自生调节是指有机体独立调节其内部环境的能力，而不依赖于外部因素。这种自我调节机制对生存至关重要，因为它使有机体能够有效地响应周围环境的变化，同时维持其生理过程的最佳条件。其中一个最显著的例子是哺乳动物的温度调节。哺乳动物具有在环境温度波动的情况下维持稳定体温的能力。这是通过各种生理机制实现的，例如出汗、颤抖和改变血液流向皮肤。例如，当暴露在寒冷的环境中时，哺乳动物会颤抖以产生热量，并收缩血管以减少热量损失。相反，在炎热的条件下，出汗通过蒸发冷却帮助降低体温。这种调节体温的惊人能力展示了自生调节的实际应用。植物也表现出形式的自生调节，尤其是在其生长和发育方面。通过光向性和重力向性等过程，植物可以根据光和重力的变化调整其生长方向。例如，植物可能会向光源弯曲，以最大化光合作用，展示了其根据环境线索调节生长的能力。这种适应性对于优化资源获取和确保在不同条件下的生存至关重要，展示了自生调节的另一个方面。除了个体有机体，自生调节还可以在种群和生态系统层面上观察到。例如，捕食者-猎物动态通常说明种群如何通过自然机制自我调节。当猎物种群增加时，捕食者数量可能会因食物供应增加而上升。然而，随着捕食者数量的增长，可能导致猎物种群的下降，这最终导致捕食者种群的减少。这种循环互动展示了种群如何随时间自我调节，反映了生态系统中的自生调节原则。理解自生调节对多个领域至关重要，包括保护生物学、医学和环境科学。通过认识到有机体和生态系统自我调节的方式，科学家和研究人员可以制定更有效的保护和管理策略。例如，了解濒危物种的自生调节机制可以帮助制定支持其自然行为和需求的适当保护计划。总之，自生调节是生物学中的一个基本概念，强调了有机体和生态系统维持稳定和适应变化的能力。无论是通过动物的生理过程还是植物的生长调整，这种自我调节能力对生存至关重要。此外，认识到自生调节在各个生物层面的重要性可以增强我们对生态互动的理解，并为旨在保护生物多样性的保护工作提供信息。随着我们继续探索生命的复杂性，自生调节的重要性仍然是生物学研究的基石，突显了维持地球生命的微妙平衡。