ectotrophic

简明释义

英[ektəʊˈtrɒfɪk]美[ˌektəˈtrɑːfɪk]

外生的

[生物] 体外营养的

英英释义

单词用法

同义词

反义词

例句

1.In the economy meaning, there are 77 edulis fungi, 43 medical fungi, 24 poisonous fungi, 93 ectotrophic mycorrhiza fungi and 32 wood rotten fungi.

在经济价值方面，有食用菌77种，药用菌43种，毒菌24种，木材腐朽菌93种，树木共生菌32种。

2.In the economy meaning, there are 77 edulis fungi, 43 medical fungi, 24 poisonous fungi, 93 ectotrophic mycorrhiza fungi and 32 wood rotten fungi.

在经济价值方面，有食用菌77种，药用菌43种，毒菌24种，木材腐朽菌93种，树木共生菌32种。

3.In the species, there are 57 edulis fungi, 38 medical fungi, 25 ectotrophic mycorrhiza fungi and 66 wood rotten fungi.

这些真菌中，食用菌57种，药用菌38种，外生菌根菌25种，木材致腐菌66种。

4.The study focused on the role of ectotrophic 外生营养的 fungi in forest ecosystems.

这项研究集中在ectotrophic 外生营养的真菌在森林生态系统中的作用。

5.Researchers found that ectotrophic 外生营养的 bacteria can significantly enhance plant growth.

研究人员发现，ectotrophic 外生营养的细菌可以显著促进植物生长。

6.In aquatic environments, ectotrophic 外生营养的 organisms play a crucial role in nutrient cycling.

在水生环境中，ectotrophic 外生营养的生物在养分循环中发挥着关键作用。

7.The presence of ectotrophic 外生营养的 microorganisms was essential for soil health.

存在ectotrophic 外生营养的微生物对土壤健康至关重要。

8.Agricultural practices can benefit from ectotrophic 外生营养的 relationships between plants and fungi.

农业实践可以从植物与真菌之间的ectotrophic 外生营养的关系中受益。

作文

In the realm of ecology and biology, the term ectotrophic refers to organisms that derive their nutrition from external sources, particularly in environments where they interact closely with other organisms. This concept is especially important when studying various ecosystems and understanding the relationships between different species. For example, many fungi are known to be ectotrophic, forming symbiotic relationships with plant roots. This relationship not only benefits the fungi by providing them with carbohydrates produced through photosynthesis but also aids the plants in nutrient absorption, particularly phosphorus, which is often limited in soil. As such, the ectotrophic nature of these fungi plays a crucial role in the health and sustainability of many ecosystems. Moreover, the study of ectotrophic organisms extends beyond fungi to include various bacteria and other microorganisms. These organisms often thrive in nutrient-rich environments and can significantly impact the biogeochemical cycles within their ecosystems. For instance, certain ectotrophic bacteria are vital for the decomposition of organic matter, breaking it down into simpler substances that can be reused by plants and other organisms. This process is essential for maintaining soil fertility and supporting plant growth, which in turn supports entire food webs. Understanding the role of ectotrophic organisms is also critical in the context of environmental conservation. As human activities continue to alter natural habitats, the delicate balance maintained by these organisms can be disrupted. For example, pollution can lead to a decline in ectotrophic populations, which may result in reduced nutrient cycling and soil degradation. Conservation efforts must therefore consider the importance of these organisms and strive to protect their habitats. In addition, the concept of ectotrophic relationships can be applied to broader ecological principles. The interdependence of species within an ecosystem highlights the need for a holistic approach to environmental management. By recognizing the significance of ectotrophic interactions, we can better appreciate the complexity of ecological networks and the potential consequences of disrupting them. Education and awareness about the importance of these organisms can empower communities to engage in sustainable practices that support biodiversity and ecosystem health. In conclusion, the term ectotrophic encapsulates a vital aspect of ecological interactions that underscores the interconnectedness of life on Earth. By fostering a deeper understanding of ectotrophic organisms and their roles within ecosystems, we can enhance our efforts in conservation and sustainability. As we face increasing environmental challenges, embracing the knowledge of how organisms depend on one another will be key to preserving the delicate balance of our planet's ecosystems. Therefore, it is imperative that we continue to study and protect ectotrophic relationships as part of our commitment to a healthier environment for future generations.

在生态学和生物学领域，术语ectotrophic指的是从外部来源获取营养的生物，特别是在它们与其他生物密切互动的环境中。这个概念在研究各种生态系统和理解不同物种之间的关系时尤为重要。例如，许多真菌被认为是ectotrophic的，它们与植物根系形成共生关系。这种关系不仅通过光合作用提供碳水化合物来使真菌受益，还帮助植物吸收营养，尤其是土壤中常常有限的磷。因此，这些真菌的ectotrophic特性在许多生态系统的健康和可持续性中发挥着至关重要的作用。 此外，对ectotrophic生物的研究还扩展到各种细菌和其他微生物。这些生物通常在富含营养的环境中繁荣生长，并能显著影响其生态系统内的生物地球化学循环。例如，某些ectotrophic细菌对有机物的分解至关重要，将其分解为植物和其他生物可以重新利用的简单物质。这个过程对于维持土壤肥力和支持植物生长至关重要，而植物又支持整个食物网。 理解ectotrophic生物的角色在环境保护的背景下也至关重要。随着人类活动不断改变自然栖息地，这些生物维持的微妙平衡可能会受到破坏。例如，污染可能导致ectotrophic种群的下降，这可能导致营养循环减少和土壤退化。因此，保护工作必须考虑到这些生物的重要性，并努力保护它们的栖息地。 此外，ectotrophic关系的概念可以应用于更广泛的生态原则。生态系统内物种间的相互依存突显了环境管理需要整体性的方法。通过认识到ectotrophic相互作用的重要性，我们可以更好地欣赏生态网络的复杂性以及破坏它们的潜在后果。关于这些生物重要性的教育和意识可以使社区参与支持生物多样性和生态系统健康的可持续实践。 总之，术语ectotrophic概括了生态相互作用的一个重要方面，强调了地球上生命的相互联系。通过加深对ectotrophic生物及其在生态系统中角色的理解，我们可以增强在保护和可持续发展方面的努力。面对日益严峻的环境挑战，拥抱生物如何相互依赖的知识将是保护我们星球生态系统微妙平衡的关键。因此，我们必须继续研究和保护ectotrophic关系，以履行我们对未来世代的健康环境的承诺。