天然防冻现象的分子机制及其在低温保存中的应用

IF 3.5 2区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Lingyu Shi, Chuanbao Zang, Zhicheng Liu, Gang Zhao
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引用次数: 0

摘要

由于结晶和渗透失衡等低温损伤会损害生物组织和细胞的完整性,因此低温保存是一项严峻的挑战。与此相反,自然界中的各种生物却表现出卓越的耐冻能力,它们利用复杂的分子机制在极寒环境中生存下来。本综述探讨了耐冻物种的适应策略,包括对特定基因、蛋白质和代谢途径的调控,以提高它们在低温环境中的生存能力。然后,我们讨论了旨在模拟这些自然现象以保存细胞和组织完整性的低温保存技术的最新进展。我们将特别关注葡萄糖代谢、microRNA 表达和低温保护蛋白调节在改善低温保存结果方面的作用。从研究天然防冻机制中获得的启示为冷冻保存技术的发展提供了前景广阔的方向,并有可能应用于医学、农业和自然保护领域。未来的研究应旨在进一步阐明这些分子机制,以开发出更有效、更可靠的低温保存方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecular mechanisms of natural antifreeze phenomena and their application in cryopreservation

Cryopreservation presents a critical challenge due to cryo-damage, such as crystallization and osmotic imbalances that compromise the integrity of biological tissues and cells. In contrast, various organisms in nature exhibit remarkable freezing tolerance, leveraging complex molecular mechanisms to survive extreme cold. This review explores the adaptive strategies of freeze-tolerant species, including the regulation of specific genes, proteins, and metabolic pathways, to enhance survival in low-temperature environments. We then discuss recent advancements in cryopreservation technologies that aim to mimic these natural phenomena to preserve cellular and tissue integrity. Special focus is given to the roles of glucose metabolism, microRNA expression, and cryoprotective protein modulation in improving cryopreservation outcomes. The insights gained from studying natural antifreeze mechanisms offer promising directions for advancing cryopreservation techniques, with potential applications in medical, agricultural, and conservation fields. Future research should aim to further elucidate these molecular mechanisms to develop more effective and reliable cryopreservation methods.

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来源期刊
Biotechnology and Bioengineering
Biotechnology and Bioengineering 工程技术-生物工程与应用微生物
CiteScore
7.90
自引率
5.30%
发文量
280
审稿时长
2.1 months
期刊介绍: Biotechnology & Bioengineering publishes Perspectives, Articles, Reviews, Mini-Reviews, and Communications to the Editor that embrace all aspects of biotechnology. These include: -Enzyme systems and their applications, including enzyme reactors, purification, and applied aspects of protein engineering -Animal-cell biotechnology, including media development -Applied aspects of cellular physiology, metabolism, and energetics -Biocatalysis and applied enzymology, including enzyme reactors, protein engineering, and nanobiotechnology -Biothermodynamics -Biofuels, including biomass and renewable resource engineering -Biomaterials, including delivery systems and materials for tissue engineering -Bioprocess engineering, including kinetics and modeling of biological systems, transport phenomena in bioreactors, bioreactor design, monitoring, and control -Biosensors and instrumentation -Computational and systems biology, including bioinformatics and genomic/proteomic studies -Environmental biotechnology, including biofilms, algal systems, and bioremediation -Metabolic and cellular engineering -Plant-cell biotechnology -Spectroscopic and other analytical techniques for biotechnological applications -Synthetic biology -Tissue engineering, stem-cell bioengineering, regenerative medicine, gene therapy and delivery systems The editors will consider papers for publication based on novelty, their immediate or future impact on biotechnological processes, and their contribution to the advancement of biochemical engineering science. Submission of papers dealing with routine aspects of bioprocessing, description of established equipment, and routine applications of established methodologies (e.g., control strategies, modeling, experimental methods) is discouraged. Theoretical papers will be judged based on the novelty of the approach and their potential impact, or on their novel capability to predict and elucidate experimental observations.
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