auxocyte

简明释义

英[ˈɔːksəˌsaɪt]美[ˈɔːksəˌsaɪt]

n. [细胞] 性母细胞；生长细胞；增大母细胞

英英释义

单词用法

同义词

反义词

例句

1.The results showed that: (1) the auxocyte abortion of Jin a took place at the stage of sporogenous cell division.

结果表明，1晋a不育系雄性败育的主要时期是在造孢细胞增殖——小孢子母细胞形成时期。

2.The results showed that: (1) the auxocyte abortion of Jin a took place at the stage of sporogenous cell division.

结果表明，1晋a不育系雄性败育的主要时期是在造孢细胞增殖——小孢子母细胞形成时期。

3.The study focused on the role of auxocytes in cellular differentiation.

这项研究集中于辅助细胞在细胞分化中的作用。

4.Researchers discovered that auxocytes can influence the growth of neighboring cells.

研究人员发现辅助细胞可以影响邻近细胞的生长。

5.In the lab, we observed how auxocytes respond to environmental changes.

在实验室中，我们观察了辅助细胞如何对环境变化作出反应。

6.The presence of auxocytes was crucial for successful tissue regeneration.

存在辅助细胞对成功的组织再生至关重要。

7.Understanding the function of auxocytes can lead to advancements in regenerative medicine.

理解辅助细胞的功能可能会推动再生医学的发展。

作文

In the fascinating world of biology, the study of cells and their functions is paramount to understanding life itself. Among the myriad of cell types, one particularly interesting type is the auxocyte, which plays a crucial role in various biological processes. The term auxocyte refers to a specific type of cell that is involved in the growth and development of certain organisms, particularly in the context of algae and some plants. These cells are known for their ability to divide and contribute to the overall increase in size and biomass of the organism. Understanding the function of auxocytes can provide insights into how organisms adapt to their environment. For instance, in aquatic ecosystems, the presence of auxocytes can significantly influence the productivity of algal blooms, which in turn affects the entire food web. When conditions are favorable, such as optimal light and nutrient availability, auxocytes proliferate, leading to rapid growth of algal populations. This phenomenon is not only important for the ecosystem but also has implications for human activities, such as fisheries and water quality management. Moreover, auxocytes are often studied in the context of climate change. As global temperatures rise and nutrient runoff increases due to agricultural practices, the behavior of auxocytes may change, leading to more frequent and severe algal blooms. These blooms can deplete oxygen in water bodies, creating dead zones that are detrimental to aquatic life. Therefore, understanding the biology and ecology of auxocytes is essential for predicting and managing the impacts of environmental changes. In addition to their ecological significance, auxocytes have potential applications in biotechnology. Researchers are exploring ways to harness the growth capabilities of auxocytes for biofuel production and other sustainable practices. By optimizing the conditions under which these cells thrive, scientists hope to develop efficient methods for producing renewable energy sources, thus contributing to a more sustainable future. Furthermore, the study of auxocytes extends beyond mere academic interest; it has real-world implications for conservation efforts. By understanding how these cells function and respond to environmental stressors, conservationists can develop strategies to protect vulnerable ecosystems. For example, monitoring the health of auxocyte populations can serve as an indicator of ecosystem health, allowing for timely interventions when necessary. In conclusion, the auxocyte is more than just a cell type; it is a key player in the intricate web of life. Its role in growth, environmental adaptation, and potential biotechnological applications underscores the importance of studying this unique cell. As we continue to explore the complexities of biology, the auxocyte serves as a reminder of the interconnectedness of all living organisms and the delicate balance that sustains our planet. Understanding and protecting these cells will be vital as we face the challenges of the future, ensuring that ecosystems remain resilient and capable of supporting diverse forms of life.

在生物学的迷人世界中，细胞及其功能的研究对于理解生命本身至关重要。在众多细胞类型中，有一种特别有趣的细胞类型是auxocyte，它在各种生物过程中发挥着关键作用。术语auxocyte指的是一种特定类型的细胞，它参与某些生物体的生长和发育，特别是在藻类和一些植物的背景下。这些细胞以其分裂和促进生物体整体增大和生物量增加的能力而闻名。 了解auxocyte的功能可以提供有关生物体如何适应环境的见解。例如，在水生生态系统中，auxocyte的存在可以显著影响藻类繁盛的生产力，这反过来又影响整个食物网。当条件有利时，例如最佳光照和营养物质的可用性，auxocyte会大量繁殖，导致藻类种群的快速增长。这一现象不仅对生态系统重要，而且对人类活动，如渔业和水质管理也有影响。 此外，auxocyte通常在气候变化的背景下进行研究。随着全球气温上升和由于农业活动导致的营养物质流失，auxocyte的行为可能会发生变化，从而导致更频繁和严重的藻类繁盛。这些繁盛会耗尽水体中的氧气，造成对水生生命有害的死区。因此，了解auxocyte的生物学和生态学对于预测和管理环境变化的影响至关重要。 除了它们的生态意义外，auxocyte在生物技术中也具有潜在应用。研究人员正在探索如何利用auxocyte的生长能力来生产生物燃料和其他可持续实践。通过优化这些细胞繁荣的条件，科学家希望开发出高效的可再生能源生产方法，从而为更可持续的未来做出贡献。 此外，auxocyte的研究不仅仅是学术兴趣；它对保护工作具有实际意义。通过了解这些细胞如何运作以及如何应对环境压力，保护主义者可以制定保护脆弱生态系统的策略。例如，监测auxocyte种群的健康状况可以作为生态系统健康的指标，从而在必要时及时采取干预措施。 总之，auxocyte不仅仅是一种细胞类型；它是生命复杂网络中的关键角色。它在生长、环境适应和潜在生物技术应用中的作用突显了研究这一独特细胞的重要性。随着我们继续探索生物学的复杂性，auxocyte提醒我们所有生物体之间的相互联系以及维持我们星球的微妙平衡。理解和保护这些细胞将是我们面临未来挑战时的重要任务，确保生态系统保持韧性并能够支持多样的生命形式。