Adaptive mechanisms of freeze avoidance in plants: A brief update
•Freeze avoidance strategies in plants are diverse.•Infrared video thermography has provided a wealth of information on ice nucleation and propagation.•Freezing under field conditions is difficult to mimic in environmental chambers.•Plant structure and various endogenous compounds can significantly...
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| Published in | Environmental and experimental botany Vol. 99; pp. 133 - 140 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
Amsterdam
Elsevier B.V
01.03.2014
Elsevier |
| Subjects | |
| Online Access | Get full text |
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| Abstract | •Freeze avoidance strategies in plants are diverse.•Infrared video thermography has provided a wealth of information on ice nucleation and propagation.•Freezing under field conditions is difficult to mimic in environmental chambers.•Plant structure and various endogenous compounds can significantly impact how plants freeze and are injured.
Freeze avoidance has evolved in plants in response to selection pressures brought about by exposure to freezing temperatures. It is a multifaceted adaptive mechanism with many attributes. Despite the prevalence of freeze avoidance as an adaptive mechanism, little research has been devoted in recent times to understanding the underlying mechanisms and regulation of freeze avoidance. Therefore, there is no shortage of questions that need to be addressed. Inherent in understanding how plants respond to freezing temperatures is the need to also understand the properties of water at different temperatures and how the interaction of water with biological substances affects these properties. This review provides an overview of the subject of biological ice nucleation and propagation and how various aspects of plant structure and composition can affect the freezing process. Deep supercooling of plant tissues represents the most extreme example of freeze avoidance. The potential role of anti-nucleating substances in defining the ability to deep supercool is also discussed. The importance of studying intact plants in their natural environments is emphasized. Although, this adds a high degree of complexity to investigations, it is in this context that adaptive mechanisms have evolved and play a role in the biology and survival of plants. |
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| AbstractList | •Freeze avoidance strategies in plants are diverse.•Infrared video thermography has provided a wealth of information on ice nucleation and propagation.•Freezing under field conditions is difficult to mimic in environmental chambers.•Plant structure and various endogenous compounds can significantly impact how plants freeze and are injured.
Freeze avoidance has evolved in plants in response to selection pressures brought about by exposure to freezing temperatures. It is a multifaceted adaptive mechanism with many attributes. Despite the prevalence of freeze avoidance as an adaptive mechanism, little research has been devoted in recent times to understanding the underlying mechanisms and regulation of freeze avoidance. Therefore, there is no shortage of questions that need to be addressed. Inherent in understanding how plants respond to freezing temperatures is the need to also understand the properties of water at different temperatures and how the interaction of water with biological substances affects these properties. This review provides an overview of the subject of biological ice nucleation and propagation and how various aspects of plant structure and composition can affect the freezing process. Deep supercooling of plant tissues represents the most extreme example of freeze avoidance. The potential role of anti-nucleating substances in defining the ability to deep supercool is also discussed. The importance of studying intact plants in their natural environments is emphasized. Although, this adds a high degree of complexity to investigations, it is in this context that adaptive mechanisms have evolved and play a role in the biology and survival of plants. Freeze avoidance has evolved in plants in response to selection pressures brought about by exposure to freezing temperatures. It is a multifaceted adaptive mechanism with many attributes. Despite the prevalence of freeze avoidance as an adaptive mechanism, little research has been devoted in recent times to understanding the underlying mechanisms and regulation of freeze avoidance. Therefore, there is no shortage of questions that need to be addressed. Inherent in understanding how plants respond to freezing temperatures is the need to also understand the properties of water at different temperatures and how the interaction of water with biological substances affects these properties. This review provides an overview of the subject of biological ice nucleation and propagation and how various aspects of plant structure and composition can affect the freezing process. Deep supercooling of plant tissues represents the most extreme example of freeze avoidance. The potential role of anti-nucleating substances in defining the ability to deep supercool is also discussed. The importance of studying intact plants in their natural environments is emphasized. Although, this adds a high degree of complexity to investigations, it is in this context that adaptive mechanisms have evolved and play a role in the biology and survival of plants. |
| Author | Wisniewski, Michael Gusta, Lawrence Neuner, Gilbert |
| Author_xml | – sequence: 1 givenname: Michael surname: Wisniewski fullname: Wisniewski, Michael email: michael.wisniewski@ars.usda.gov organization: United States Department of Agriculture, Agricultural Research Service, Kearneysville, WV, USA – sequence: 2 givenname: Lawrence surname: Gusta fullname: Gusta, Lawrence organization: Department of Plant Science, University of Saskatchewan, Saskatoon, Canada – sequence: 3 givenname: Gilbert surname: Neuner fullname: Neuner, Gilbert organization: Institute of Botany, University of Innsbruck, Innsbruck, Austria |
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| Keywords | Biological ice nucleation Infrared video thermography Deep supercooling Ice propagation Alpine ecology Frost injury Infrared thermography Ice nucleus Propagation Plant ecology Updating Ice Mechanism Supercooling Frost effect Damage Avoidance Freeze Adaptation |
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| Snippet | •Freeze avoidance strategies in plants are diverse.•Infrared video thermography has provided a wealth of information on ice nucleation and... Freeze avoidance has evolved in plants in response to selection pressures brought about by exposure to freezing temperatures. It is a multifaceted adaptive... |
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| SubjectTerms | Alpine ecology Biological and medical sciences Biological ice nucleation Deep supercooling Frost injury Fundamental and applied biological sciences. Psychology ice nucleation Ice propagation Infrared video thermography plant tissues selection response supercooling temperature |
| Title | Adaptive mechanisms of freeze avoidance in plants: A brief update |
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