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- Transcription, translation, membrane properties, mitochondrial respiration, microtubule and microfilament-mediated processes, plastids, and all other essential cell functions retain activity over a broad temperature range, and furthermore, all of these processes remain in balance [ 2 ].
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Nov 28, 2019 · Peter G. Kevan, University Professor Emeritus at the School of Environmental Sciences, University of Guelph, explores here how plants regulate their body temperatures, including the implications in this respect for climate change science & policy
May 22, 2008 · In this addendum we discuss the central role of AOX in heat production and how post-translational mechanisms may provide the fine control necessary for thermoregulation. Key words: alternative oxidase, Nelumbo nucifera, thermogenic plants, uncoupling proteins. Go to: Heating in Plants.
- Jennifer R Watling, Nicole M Grant, Rebecca Elizabeth Miller, Sharon Robinson
- 10.4161/psb.3.8.6341
- 2008
- Plant Signal Behav. 2008 Aug; 3(8): 595-597.
Nov 9, 2017 · The importance of temperature as a physical factor on the distribution of organisms is a consequence of its direct influence on molecular (DNA, proteins) or supramolecular (membranes, chromosomes) structures, which results from merely a thermodynamic effect. 10, 11 These changes are usually fast; therefore, changes in the ambient temperature can...
- Catarina C. Nievola, Camila P. Carvalho, Victória Carvalho, Edson Rodrigues
- 10.1080/23328940.2017.1377812
- 2017
- Temperature (Austin). 2017; 4(4): 371-405.
Feb 17, 2020 · February 17, 2020. Understanding plant thermoregulation in the face of climate change. Plants possess the fascinating ability to control their body temperature. This physiological process is fundamental for the growth, reproduction, and survival of numerous species of plants.
- Overview
- Key points
- Introduction
- Mechanisms of thermoregulation
- Behavioral strategies
- Increasing heat production—thermogenesis
- Controlling the loss and gain of heat
- Circulatory mechanisms
- Vasoconstriction and vasodilation
- Countercurrent heat exchange
How behavior, anatomy, and physiology help animals regulate body temperature.
•Many animals regulate their body temperature through behavior, such as seeking sun or shade or huddling together for warmth.
•Endotherms can alter metabolic heat production to maintain body temperature using both shivering and non-shivering thermogenesis.
•Vasoconstriction—shrinking—and vasodilation—expansion—of blood vessels to the skin can alter an organism's exchange of heat with the environment.
•A countercurrent heat exchanger is an arrangement of blood vessels in which heat flows from warmer to cooler blood, usually reducing heat loss.
•Some animals use body insulation and evaporative mechanisms, such as sweating and panting, in body temperature regulation.
•Many animals regulate their body temperature through behavior, such as seeking sun or shade or huddling together for warmth.
•Endotherms can alter metabolic heat production to maintain body temperature using both shivering and non-shivering thermogenesis.
•Vasoconstriction—shrinking—and vasodilation—expansion—of blood vessels to the skin can alter an organism's exchange of heat with the environment.
•A countercurrent heat exchanger is an arrangement of blood vessels in which heat flows from warmer to cooler blood, usually reducing heat loss.
Why do lizards sunbathe? Why do jackrabbits have huge ears? Why do dogs pant when they're hot? Animals have quite a few different ways to regulate body temperature! These thermoregulatory strategies let them live in different environments, including some that are pretty extreme.
Polar bears and penguins, for instance, maintain a high body temperature in their chilly homes at the poles, while kangaroo rats, iguanas, and rattlesnakes thrive in Death Valley, where summertime highs are over 100∘F (38∘C )1 .
As a refresher, animals can be divided into endotherms and ectotherms based on their temperature regulation.
•Endotherms, such as birds and mammals, use metabolic heat to maintain a stable internal temperature, often one different from the environment.
•Ectotherms, like lizards and snakes, do not use metabolic heat to maintain their body temperature but take on the temperature of the environment.
Both endotherms and ectotherms have adaptations—features that arose by natural selection—that help them maintain a healthy body temperature. These adaptations can be behavioral, anatomical, or physiological. Some adaptations increase heat production in endotherms when it’s cold. Others, in both endotherms and ectotherms, increase or decrease exchange of heat with the environment.
We will look at three broad categories of thermoregulatory mechanisms in this article:
•Changing behavior
How do you regulate your body temperature using behavior? On a hot day, you might go for a swim, drink some cold water, or sit in the shade. On a cold day, you might put on a coat, sit in a cozy corner, or eat a bowl of hot soup.
Nonhuman animals have similar types of behaviors. For instance, elephants spray themselves with water to cool down on a hot day, and many animals seek shade when they get too warm. On the other hand, lizards often bask on a hot rock to warm up, and penguin chicks huddle in a group to retain heat.
Endotherms have various ways of increasing metabolic heat production, or thermogenesis, in response to cold environments.
One way to produce metabolic heat is through muscle contraction—for example, if you shiver uncontrollably when you're very cold. Both deliberate movements—such as rubbing your hands together or going for a brisk walk—and shivering increase muscle activity and thus boost heat production.
Nonshivering thermogenesis provides another mechanism for heat production. This mechanism depends on specialized fat tissue known as brown fat, or brown adipose tissue. Some mammals, especially hibernators and baby animals, have lots of brown fat. Brown fat contains many mitochondria with special proteins that let them release energy from fuel molecules directly as heat instead of channeling it into formation of the energy carrier ATP.2
To learn more about how energy is released as heat in brown fat cells, have a look at the section on uncoupling proteins in the oxidative phosphorylation article.
Animals also have body structures and physiological responses that control how much heat they exchange with the environment:
•Circulatory mechanisms, such as altering blood flow patterns
•Insulation, such as fur, fat, or feathers
•Evaporative mechanisms, such as panting and sweating
The body's surface is the main site for heat exchange with the environment. Controlling the flow of blood to the skin is an important way to control the rate of heat loss to—or gain from—the surroundings.
In endotherms, warm blood from the body’s core typically loses heat to the environment as it passes near the skin. Shrinking the diameter of blood vessels that supply the skin, a process known as vasoconstriction, reduces blood flow and helps retain heat.
On the other hand, when an endotherm needs to get rid of heat—say, after running hard to escape a predator—these blood vessels get wider, or dilate. This process is called vasodilation. Vasodilation increases blood flow to the skin and helps the animal lose some of its extra heat to the environment.
Furry mammals often have special networks of blood vessels for heat exchange located in areas of bare skin. For example, jackrabbits have large ears with an extensive network of blood vessels that allow rapid heat loss. This adaptation helps them live in hot desert environments.4
Some ectotherms also regulate blood flow to the skin as a way to conserve heat. For instance, iguanas reduce blood flow to the skin when they go swimming in cold water to help retain the heat they soaked up while on land.5,6
Many birds and mammals have countercurrent heat exchangers, circulatory adaptations that allow heat to be transferred from blood vessels containing warmer blood to those containing cooler blood. To see how this works, let's look at an example.
In the leg of a wading bird, the artery that runs down the leg carries warm blood from the body. The artery is positioned right alongside a vein that carries cold blood up from the foot. The descending, warm blood passes much of its heat to the ascending, cold blood by conduction. This means that less heat will be lost in the foot due to the reduced temperature difference between the cooled blood and the surroundings and that the blood moving back into the body's core will be relatively warm, keeping the core from getting cold.7
Figure 1. Comparison of body temperature response by ectotherm (i.e., poikilotherm) and endotherm (i.e., homeotherm) to changing ambient temperatures. Poikilotherms are also known as ectotherms...
Nov 17, 2011 · Schematic representation of the temperature tolerance of plant and animal processes. Plant proteins (black line) will show a broad range of activity and stability relative to temperature in comparison to mammalian proteins (red line) with a peak narrowly centered on body temperature.
