@Article{phyton.2025.064729,
AUTHOR = {Ali Salehi Sardoei, Bahman Fazeli-Nasab},
TITLE = {Physiological and Molecular Mechanisms of Freezing in Plants},
JOURNAL = {Phyton-International Journal of Experimental Botany},
VOLUME = {94},
YEAR = {2025},
NUMBER = {6},
PAGES = {1601--1630},
URL = {http://www.techscience.com/phyton/v94n6/62655},
ISSN = {1851-5657},
ABSTRACT = {The ability of plants to tolerate cold is a complex process. When temperatures drop or freeze, plant tissues can develop ice, which dehydrates the cells. However, plants can protect themselves by preventing ice formation. This intricate response to cold stress is regulated by hormones, photoperiod, light, and various factors, in addition to genetic influences. In autumn, plants undergo morphological, physiological, biochemical, and molecular changes to prepare for the low temperatures of winter. Understanding cellular stress responses is crucial for genetic manipulation aimed at enhancing cold resistance. Early autumn frosts or late spring chills can cause significant damage to plants, making it essential to adapt in autumn to survive winter conditions. While the general process of acclimatization is similar across many plant species, variations exist depending on the specific type of plant and regional conditions. Different plant organs exhibit varying degrees of damage from cold stress, and by applying agricultural principles, potential damage can be largely controlled. Timely reinforcement and stress prevention can minimize cold-related damage. Research has shown that in temperate climates, low temperatures restrict plant growth and yield. However, the intricate structural systems involved remain poorly understood. Over the past decade, studies have focused on the molecular mechanisms that enable plants to adapt to and resist cold stress. The gene signaling system is believed to play a crucial role in cold adaptation, and researchers have prioritized this area in their investigations. This study critically examines plant responses to cold stress through physiological adaptations, including calcium signaling dynamics, membrane lipid modifications, and adjustments in antioxidant systems. These mechanisms activate downstream gene expression and molecular functions, leading to key resistance strategies. Additionally, we explore the regulatory roles of endogenous phytohormones and secondary metabolites in cold stress responses. This review aims to enhance our foundational understanding of the mechanisms behind plant cold adaptation.},
DOI = {10.32604/phyton.2025.064729}
}