catenulate
简明释义
英[kəˈtenjʊˌleɪt]美[kəˈtenjuleɪt]
adj. [生物] 链状的;成链形的
英英释义
Describing a structure that is arranged in a chain or series, often used in reference to certain types of fungi or bacteria. | 描述一种以链或系列排列的结构,常用于指某些类型的真菌或细菌。 |
单词用法
链状叶片 | |
链状真菌 | |
链状排列 | |
链状形式 |
同义词
| 链状的 | The catenulate structure of the bacteria allows for efficient communication. | 链状结构的细菌能够有效沟通。 | |
| 相连的 | The linked arrangement of the molecules created a stable compound. | 分子的相连排列形成了一个稳定的化合物。 |
反义词
| 分散的 | 种子被风散播开了。 | ||
| 孤立的 | 孤立的细胞没有形成任何簇。 |
例句
1.The results showed that nestedness is not exclusive properties of biological assemblages, mantlerock or soil catenulate structure, but can be found in a broader class of earth systems.
结果表明:嵌套性在生物群落、土被或土链结构中的性质有相似之处,即地学系统中普遍存在着嵌套性。
2.The results showed that nestedness is not exclusive properties of biological assemblages, mantlerock or soil catenulate structure, but can be found in a broader class of earth systems.
结果表明:嵌套性在生物群落、土被或土链结构中的性质有相似之处,即地学系统中普遍存在着嵌套性。
3.The biologist observed that the bacteria formed a catenulate 链状的 structure under the microscope.
生物学家观察到这些细菌在显微镜下形成了一个链状的catenulate结构。
4.The catenulate 链状的 growth pattern of the fungi was a key characteristic in identifying the species.
真菌的链状的catenulate生长模式是识别该物种的一个关键特征。
5.Many plants exhibit catenulate 链状的 formations of leaves that help maximize sunlight exposure.
许多植物表现出链状的catenulate叶片排列,以帮助最大化阳光暴露。
6.The scientist published a paper discussing the implications of catenulate 链状的 structures in cellular biology.
科学家发表了一篇论文,讨论了链状的catenulate结构在细胞生物学中的意义。
7.In her research, she noted that the catenulate 链状的 arrangement of the algae was crucial for their survival.
在她的研究中,她指出藻类的链状的catenulate排列对它们的生存至关重要。
作文
In the realm of biology, the term catenulate refers to a specific arrangement or formation of structures that are linked together in a chain-like fashion. This concept is often observed in various organisms, particularly in the study of fungi and certain types of bacteria. The significance of understanding catenulate structures lies in their functional implications within biological systems. For instance, in mycology, the morphology of fungal spores can be described as catenulate, which affects how these organisms reproduce and disperse in their environments.Consider the fascinating world of fungi, where many species exhibit catenulate characteristics. Fungi reproduce through spores, and these spores can sometimes form long chains, making them catenulate. This arrangement not only aids in the efficient dispersal of spores but also increases the likelihood of successful colonization in suitable habitats. Understanding this phenomenon allows scientists to appreciate the evolutionary advantages that such formations confer upon fungi, enhancing their survival and adaptability.Moreover, the concept of catenulate structures extends beyond fungi. In microbiology, certain bacteria exhibit catenulate growth patterns, where cells divide and remain attached to one another, forming chains. This growth pattern can influence the bacteria's ability to form biofilms, which are communities of microorganisms that adhere to surfaces. Biofilms play crucial roles in various ecological and industrial processes, including wastewater treatment and bioremediation. Hence, studying catenulate arrangements in bacteria can provide insights into their ecological interactions and potential applications in biotechnology.Furthermore, the study of catenulate formations is not limited to microorganisms. In the plant kingdom, certain species exhibit catenulate traits in their reproductive structures, such as flowers or fruits. This can affect pollination strategies and seed dispersal mechanisms. By examining these traits, botanists can better understand plant evolution and the intricate relationships between plants and their pollinators.In conclusion, the term catenulate encapsulates a fascinating aspect of biological organization, highlighting the interconnectedness of life forms. Whether in fungi, bacteria, or plants, catenulate structures serve essential functions that contribute to the survival and success of these organisms. As we continue to explore the complexities of life, the concept of catenulate arrangements offers valuable insights into the mechanisms that drive biodiversity and ecological interactions. Through this understanding, we can appreciate the beauty of nature's designs and the intricate web of life that surrounds us.
在生物学领域,术语catenulate指的是一种特定的结构排列或形成,这些结构以链式方式相互连接。这个概念通常在各种生物体中观察到,特别是在真菌和某些类型的细菌研究中。理解catenulate结构的重要性在于它们在生物系统中的功能意义。例如,在真菌学中,真菌孢子的形态可以被描述为catenulate,这影响了这些生物在其环境中的繁殖和传播。考虑真菌的迷人世界,许多物种展现出catenulate特征。真菌通过孢子繁殖,这些孢子有时会形成长链,使其成为catenulate。这种排列不仅有助于有效传播孢子,还增加了在适宜栖息地成功定殖的可能性。理解这一现象使科学家能够欣赏到这种形成所赋予真菌的进化优势,从而增强它们的生存能力和适应性。此外,catenulate结构的概念不仅限于真菌。在微生物学中,某些细菌表现出catenulate生长模式,即细胞分裂后保持相互连接,形成链状。这种生长模式可能影响细菌形成生物膜的能力,生物膜是附着在表面上的微生物群落。生物膜在各种生态和工业过程中发挥着关键作用,包括废水处理和生物修复。因此,研究细菌中的catenulate排列可以提供对其生态相互作用和生物技术潜在应用的见解。此外,catenulate形成的研究并不限于微生物。在植物王国中,某些物种在其繁殖结构(如花或果实)中表现出catenulate特征。这可能影响授粉策略和种子传播机制。通过检查这些特征,植物学家可以更好地理解植物进化及植物与授粉者之间的错综复杂关系。总之,术语catenulate概括了生物组织的一个迷人方面,突显了生命形式之间的相互联系。无论是在真菌、细菌还是植物中,catenulate结构都发挥着重要的功能,促进这些生物的生存和成功。随着我们继续探索生命的复杂性,catenulate排列的概念提供了对推动生物多样性和生态相互作用机制的宝贵见解。通过这种理解,我们可以欣赏自然设计的美丽以及环绕我们的生命网络的复杂性。
