suberized
简明释义
adj. (细胞壁)栓化的
v. 使(细胞壁)栓化(suberize 的过去式)
英英释义
单词用法
木栓化细胞壁 | |
木栓化根系 | |
木栓化结构 | |
木栓化外皮 | |
木栓化树皮 | |
植物中的木栓化组织 |
同义词
| 塞住的 | 植物的根部被塞住以防止水分流失。 | ||
| 栓皮质的 | 树皮的栓皮层保护树木免受害虫侵害。 |
反义词
| 非木栓化的 | The non-suberized tissues allow for greater water and nutrient absorption. | 非木栓化的组织允许更大的水分和养分吸收。 | |
| 可渗透的 | Permeable membranes are essential for certain biological processes. | 可渗透的膜对于某些生物过程是至关重要的。 |
例句
1.Suberinite occurs commonly in Mesozoic coal measures and terrestrial organic matter source rocks in Northwest China, which is formed from suberized cell walls, particularly in plant periderm.
西北中生界煤系烃源岩中普遍含有木栓质体,它来源于植物周皮的木栓化细胞壁。
2.Suberinite occurs commonly in Mesozoic coal measures and terrestrial organic matter source rocks in Northwest China, which is formed from suberized cell walls, particularly in plant periderm.
西北中生界煤系烃源岩中普遍含有木栓质体,它来源于植物周皮的木栓化细胞壁。
3.Suberinite is formed from suberized cell walls.
硅藻土是由蜂窝状的细胞壁形成的。
4.In botany, the term suberized 栓化的 refers to tissues that have undergone a transformation to become more protective.
在植物学中,术语栓化的 栓化的指的是已经经历转变以变得更具保护性的组织。
5.The outer layer of the cork oak tree is composed of suberized 栓化的 cells that provide insulation.
橡树的外层由栓化的 栓化的细胞组成,提供绝缘。
6.The suberized 栓化的 bark of some trees helps in reducing water loss.
一些树木的栓化的 栓化的树皮有助于减少水分流失。
7.The suberized 栓化的 layer acts as a barrier against pathogens.
这个栓化的 栓化的层作为对病原体的屏障。
8.Research shows that suberized 栓化的 roots can enhance drought resistance in plants.
研究表明,栓化的 栓化的根部可以增强植物的抗旱能力。
作文
In the study of plant biology, the term suberized refers to the process by which certain plant tissues become impregnated with suberin, a waxy substance that serves various protective functions. This phenomenon is particularly significant in the context of plant adaptation and survival in diverse environments. For instance, the outer layers of cork oak trees are composed of suberized cells, which not only provide insulation but also protect the tree from pests and diseases. The presence of suberin in these cells creates a barrier that prevents water loss while allowing the tree to maintain its necessary functions. The importance of suberized tissues extends beyond just protection; they also play a crucial role in the overall physiology of plants. These tissues can be found in roots, stems, and leaves, where they help regulate the exchange of gases and water. In roots, for example, the suberized endodermis acts as a selective barrier, controlling the uptake of minerals and water from the soil. This selectivity ensures that the plant can absorb essential nutrients while keeping harmful substances at bay.Moreover, understanding the suberized structures in plants has practical applications in agriculture and horticulture. Farmers and gardeners can utilize knowledge about these tissues to improve crop resilience against environmental stressors such as drought or disease. By selecting or breeding plants with enhanced suberized characteristics, they can cultivate varieties that require less water and are more resistant to pathogens.In addition to agricultural benefits, the study of suberized plant tissues has implications for material science. Suberin is being researched for its potential use in creating biodegradable materials that could replace synthetic polymers. This is particularly relevant in today's world, where plastic pollution is a pressing issue. By harnessing the properties of suberized substances, scientists aim to develop sustainable alternatives that mimic the natural protective qualities of plant tissues.Furthermore, the process of suberization is not limited to just one type of plant. It occurs across various species, indicating a common evolutionary strategy among plants to adapt to their environments. For example, many desert plants have highly suberized tissues that allow them to thrive in arid conditions by minimizing water loss. Similarly, aquatic plants may exhibit different forms of suberization to protect themselves from pathogens present in their watery habitats.In conclusion, the concept of suberized tissues in plants is a fascinating area of study that encompasses aspects of biology, agriculture, and material science. The protective qualities provided by suberin are vital for plant survival and have inspired innovative solutions to some of the world's most pressing challenges. As researchers continue to explore the intricacies of suberized structures, we can expect to uncover even more applications and benefits that these remarkable plant adaptations offer to humanity and the environment.
在植物生物学研究中,术语suberized指的是某些植物组织被木栓质浸透的过程,木栓质是一种蜡状物质,具有多种保护功能。这种现象在植物适应和生存于不同环境中的背景下尤为重要。例如,橡树的外层由suberized细胞组成,这些细胞不仅提供绝缘作用,还保护树木免受害虫和疾病的侵袭。这些细胞中木栓质的存在形成了一种屏障,防止水分流失,同时允许树木维持其必要的功能。Suberized组织的重要性不仅限于保护;它们在植物的整体生理中也发挥着至关重要的作用。这些组织可以在根部、茎部和叶子中找到,它们帮助调节气体和水分的交换。例如,在根部,suberized内皮层作为选择性屏障,控制从土壤中吸收矿物质和水分。这种选择性确保植物能够吸收必需的营养素,同时将有害物质挡在外面。此外,理解suberized结构在植物中的作用在农业和园艺中具有实际应用。农民和园丁可以利用有关这些组织的知识来提高作物对环境压力的抵抗力,例如干旱或疾病。通过选择或培育具有增强suberized特性的植物,他们可以培育出需要更少水分且对病原体更具抵抗力的品种。除了农业利益之外,对suberized植物组织的研究对材料科学也有影响。木栓质正在被研究用于制造可生物降解材料,以替代合成聚合物。这在当今世界尤为相关,因为塑料污染是一个紧迫的问题。通过利用suberized物质的特性,科学家们旨在开发可持续替代品,模仿植物组织的自然保护特性。此外,suberization的过程并不限于一种植物。它发生在各种物种中,表明植物在适应环境方面的共同进化策略。例如,许多沙漠植物具有高度suberized的组织,使它们能够在干旱条件下生存,最小化水分流失。类似地,水生植物可能表现出不同形式的suberization,以保护自己免受水域中病原体的侵害。总之,植物中suberized组织的概念是一个迷人的研究领域,涵盖了生物学、农业和材料科学的各个方面。木栓质提供的保护特性对植物的生存至关重要,并激发了对一些世界上最紧迫挑战的创新解决方案。随着研究人员继续探索suberized结构的复杂性,我们可以期待发现更多这些显著植物适应性为人类和环境提供的应用和益处。
