Thermogenic plants have the ability to raise their temperature above that of the surrounding air. Heat is generated in the mitochondria, as a secondary process of cellular respiration called thermogenesis. Alternative oxidase and uncoupling proteins similar to those found in mammals enable the process, which is still poorly understood.
YouTube Encyclopedic
-
1/3Views:498 254133 1861 864
-
Plants That Keep Themselves Warm
-
The Complicated Relationship Between Insects And Plants | Compilation
-
Skunk Cabbage melts snow and ice! Five Fascinating Facts you should know including Thermogenesis!
Transcription
[Intro] Being warm-blooded is really convenient. For one thing, you can go outside when it’s snowing or hot without having to worry too much about your body processes shutting down. But not all organisms regulate their body temperature, because it’s a big drain on energy resources. It’s mostly just birds, mammals… and some plants. A few hundred species of plants produce their own heat in a process called thermogenesis, and some of them use that heat to regulate their body temperature. It’s based on the same idea as warm-bloodedness in animals: energy can be released as heat. Plenty of your normal, everyday metabolic processes, like digestion, release heat as a byproduct. But if that’s not enough, you can also shiver, causing the chemical processes involved in muscle contractions to release more heat. When an animal can’t shiver -- like a newborn human baby, or a hibernating bear -- it can burn brown fat instead, a special kind of fat that’s full of glucose and produces lots of heat when it’s broken down. But plants can’t shiver, and they don’t have brown fat. So plants produce heat using another mechanism, a type of cellular respiration known as thermogenic respiration that takes place in their mitochondria. Mitochondria are usually described as the powerhouses of the cell, and for good reason: their job is to store energy in the form of the molecule ATP. But in thermogenic respiration, the mitochondria skip the ATP and just release the energy as heat. At the most basic level, thermogenesis just keeps these plants warmer than their surroundings. But a handful of species, like the eastern skunk cabbage and the sacred lotus, take it one step further, with feedback mechanisms that they use to keep their body temperatures within a certain range -- or thermoregulate. In thermoregulatory plants, decreasing internal temperatures trigger more cyanide-resistant respiration, keeping them warm. And if their temperatures get too high, they just produce less heat and start to cool off. Now thermogenesis might seem like a huge waste of energy -- and it is. But for these plants, the advantages make the energy loss worth it. In some cases, it helps them avoid frost or keep snow away. The skunk cabbage, for example, can melt through snow, giving it early access to pollinating insects while other plants are still buried. But many thermogenic plants are tropical, so they wouldn’t have much reason to develop resistance to frost. And plenty of plants bloom just fine when it’s cold out. Other plants are trying to attract pollinators, either by providing the perfect temperature for mating insects, or just by making themselves smellier. Like a dumpster on a hot day, a warmer plant will smell a lot worse. For instance, when a dead horse arum is blooming, it releases more than a hundred volatile compounds in its attempt to lure hungry bugs to the smell of rotting flesh. It only blooms for a couple of days every few years, so it needs to attract as many pollinators as possible. But it also needs to trap them there for a while. In the dead horse arum, the female florets mature on the first day, but the male florets mature on the second day. So the pollinators are most effective if they stick around long enough for both phases. When a fly crawls down into the base of the flower, a series of spines keep them from getting out again. Hopefully, the fly’s picked up pollen from an earlier-blooming flower, so the female florets get pollinated. The next day, the male florets release their pollen, which attaches to the fly. Then, the spines wither, so the fly can go free, and it falls for the same trick again, landing on what it thought was a lump of dead flesh but turns out to be another flower in disguise. Good news for the bugs though: there might be benefits for them too. One study looked at the species of beetles that pollinate thermoregulating philodendrons. Normally, these beetles have to produce lots of heat themselves so that they can stay active at night. But the researchers found that when the insects were trapped in the flowers overnight, they only needed to use about half as much energy. For an insect, landing a thermogenic plant is like curling up next to a nice, warm radiator. Just… one that happens to smell like a dead horse. Thanks for watching this SciShow Dose and thanks especially to our patrons on Patreon. This episode’s President of Space is SR Foxley. If you’d like to be President of Space or get other cool rewards for supporting SciShow content, head on over to patreon.com/scishow. And of course, as always, if you want to keep getting smarter with us you can go to youtube.com/scishow and subscribe.
The role of thermogenesis
Botanists are not completely sure why thermogenic plants generate large amounts of excess heat, but most agree that it has something to do with increasing pollination rates. The most widely accepted theory states that the endogenous heat helps in spreading chemicals that attract pollinators to the plant.[1] For example, the Voodoo lily uses heat to help spread its smell of rotting meat.[2] This smell draws in flies which begin to search for the source of the smell. As they search the entire plant for the dead carcass, they pollinate the plant.[3]
Other theories state that the heat may provide a heat reward for the pollinator: pollinators are drawn to the flower for its warmth. This theory has less support because most thermogenic plants are found in tropical climates.
Yet another theory is that the heat helps protect against frost damage, allowing the plant to germinate and sprout earlier than otherwise. For example, the skunk cabbage generates heat, which allows it to melt its way through a layer of snow in early spring.[4] The heat, however, is mostly used to help spread its pungent odor and attract pollinators.
Characteristics of thermogenic plants
Most thermogenic plants tend to be rather large. This is because the smaller plants do not have enough volume to create a considerable amount of heat. Large plants, on the other hand, have a lot of mass to create and retain heat.[5]
Thermogenic plants are also protogynous, meaning that the female part of the plant matures before the male part of the same plant. This reduces inbreeding considerably, as such a plant can be fertilized only by pollen from a different plant. This is why thermogenic plants release pungent odors to attract pollinating insects.
Examples
Thermogenic plants are found in a variety of families, but Araceae in particular contains many such species. Examples from this family include the dead-horse arum (Helicodiceros muscivorus), the eastern skunk cabbage (Symplocarpus foetidus), the elephant foot yam (Amorphophallus paeoniifolius), elephant ear (Philodendron selloum), lords-and-ladies (Arum maculatum), and voodoo lily (Typhonium venosum). The titan arum (Amorphophallus titanum) uses thermogenically created water vapor to disperse its scent—that of rotting meat—above the cold air that settles over it at night in its natural habitat. Contrary to popular belief, the western skunk cabbage (Lysichiton americanus), a close relative from the family Araceae, is not thermogenic.[6] Outside Araceae, the sacred lotus (Nelumbo nucifera) is thermogenic and endothermic, able to regulate its flower temperature to a certain range,[7] an ability shared by at least one species in the non-photosynthetic parasitic genus Rhizanthes, Rhizanthes lowii.[8]
Heat production
Many endothermy plant species rely on alternative oxidase (AOX), which is an enzyme in the mitochondria organelle and is a part of the electron transport chain.[9] The reduction of mitochondrial redox potential by alternative oxidase increases unproductive respiration. This metabolic process creates an excess of heat which warms thermogenic tissue or organs.[10] Plants containing this alternative oxidase are unaffected by the effects of cyanide because AOX acts as electron acceptor collecting electrons from ubiquinol while bypassing the third electron complex. The AOX enzyme then reduces oxygen molecules to water without the presence of a proton gradient which in turn is very inefficient yielding a drop in free energy from Ubiquinol to oxygen which is released in heat.[11]
References
- ^ Plantguy (16 January 2010). "Plants That Heat Themselves". How Plants Work. Retrieved 4 December 2012.
- ^ Turner M (August 2010). "Plant of the month: Voodoo Lily". Turner Photographics. Retrieved 4 December 2012.
- ^ Schultz N (22 December 2008). "Giant Stinking Flower". NewScientist. Retrieved 4 December 2012.
- ^ "Skunk Cabbage". National Wildlife Federation. Archived from the original on 25 November 2012. Retrieved 4 December 2012.
- ^ Seymour R, Schultze-Motel P (1997). "Heat Producing Flowers" (PDF). Endeavor. 3. 21 (3): 125–129. doi:10.1016/s0160-9327(97)80222-0. Archived from the original (PDF) on 25 May 2014.
- ^ Onda Y, Kato Y, Abe Y, Ito T, Morohashi M, Ito Y, et al. (February 2008). "Functional coexpression of the mitochondrial alternative oxidase and uncoupling protein underlies thermoregulation in the thermogenic florets of skunk cabbage". Plant Physiology. 146 (2): 636–45. doi:10.1104/pp.107.113563. PMC 2245847. PMID 18162588.
- ^ Yoon CK (1 October 1996). "Heat of Lotus Attracts Insects And Scientists". The New York Times. Retrieved 14 November 2012.
- ^ Patiño S, Grace J, Bänziger H (August 2000). "Endothermy by flowers of Rhizanthes lowii (Rafflesiaceae)". Oecologia. 124 (2): 149–155. Bibcode:2000Oecol.124..149P. doi:10.1007/s004420050001. PMID 28308173. S2CID 22301706.
- ^ Watling JR, Grant NM, Miller RE, Robinson SA (August 2008). "Mechanisms of thermoregulation in plants". Plant Signaling & Behavior. 3 (8): 595–7. doi:10.4161/psb.3.8.6341. PMC 2634508. PMID 19704809.
- ^ Ito K, Seymour RS (December 2005). "Expression of uncoupling protein and alternative oxidase depends on lipid or carbohydrate substrates in thermogenic plants". Biology Letters. 1 (4): 427–30. doi:10.1098/rsbl.2005.0338. PMC 1626365. PMID 17148224.
- ^ Ito K, Ogata T, Seito T, Umekawa Y, Kakizaki Y, Osada H, Moore AL (September 2020). "Degradation of mitochondrial alternative oxidase in the appendices of Arum maculatum". The Biochemical Journal. 477 (17): 3417–3431. doi:10.1042/BCJ20200515. PMC 7505559. PMID 32856714.
This page was last edited on 17 November 2022, at 14:17