Charles Wright (October 29, 1811 – August 11, 1885) was an American botanist.
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Nature's smallest factory: The Calvin cycle - Cathy Symington
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Transcription
You're facing a giant bowl of energy packed Carbon Crunchies. One spoonful. Two. Three. Soon, you're powered up by the energy surge that comes from your meal. But how did that energy get into your bowl? Energy exists in the form of sugars made by the plant your cereal came from, like wheat or corn. As you can see, carbon is the chemical backbone, and plants get their fix of it in the form of carbon dioxide, CO2, from the air that we all breath. But how does a plant's energy factory, housed in the stroma of the chloroplast, turn a one carbon gas, like CO2, into a six carbon solid, like glucose? If you're thinking photosynthesis, you're right. But photosynthesis is divided into two steps. The first, which stores energy from the sun in the form of adenosine triphosphate, or ATP. And the second, the Calvin cycle, that captures carbon and turns it into sugar. This second phase represents one of nature's most sustainable production lines. And so with that, welcome to world's most miniscule factory. The starting materials? A mix of CO2 molecules from the air, and preassembled molecules called ribulose biphosphate, or RuBP, each containing five carbons. The initiator? An industrious enzyme named rubisco that welds one carbon atom from a CO2 molecule with the RuBP chain to build an initial six carbon sequence. That rapidly splits into two shorter chains containing three carbons each and called phosphoglycerates, or PGAs, for short. Enter ATP, and another chemical called nicotinamide adenine dinucleotide phosphate, or just NADPH. ATP, working like a lubricant, delivers energy, while NADPH affixes one hydrogen to each of the PGA chains, changing them into molecules called glyceraldehyde 3 phosphates, or G3Ps. Glucose needs six carbons to form, made from two molecules of G3P, which incidentally have six carbons between them. So, sugar has just been manufactured, right? Not quite. The Calvin cycle works like a sustainable production line, meaning that those original RuBPs that kicked things off at the start, need to be recreated by reusing materials within the cycle now. But each RuBP needs five carbons and manufacturing glucose takes a whole six. Something doesn't add up. The answer lies in one phenomenal fact. While we've been focusing on this single production line, five others have been happening at the same time. With six conveyor belts moving in unison, there isn't just one carbon that gets soldered to one RuBP chain, but six carbons soldered to six RuBPs. That creates 12 G3P chains instead of just two, meaning that all together, 36 carbons exist: the precise number needed to manufacture sugar, and rebuild those RuBPs. Of the 12 G3Ps pooled together, two are siphoned off to form that energy rich six carbon glucose chain. The one fueling you via your breakfast. Success! But back on the manufacturing line, the byproducts of this sugar production are swiftly assembled to recreate those six RuBPs. That requires 30 carbons, the exact number contained by the remaining 10 G3PS. Now a molecular mix and match occurs. Two of the G3Ps are welded together forming a six carbon sequence. By adding a third G3P, a nine carbon chain is built. The first RuBP, made up of five carbons, is cast from this, leaving four carbons behind. But there's no wastage here. Those are soldered to a fourth G3P molecule, making a seven carbon chain. Added to a fifth G3P molecule, a ten carbon chain is created, enough now to craft two more RuBPs. With three full RuBPs recreated from five of the ten G3Ps, simply duplicating this process will renew the six RuBP chains needed to restart the cycle again. So the Calvin cycle generates the precise number of elements and processes required to keep this biochemical production line turning endlessly. And it's just one of the 100s of cycles present in nature. Why so many? Because if biological production processes were linear, they wouldn't be nearly as efficient or successful at using energy to manufacture the materials that nature relies upon, like sugar. Cycles create vital feedback loops that repeatedly reuse and rebuild ingredients crafting as much as possible out of the planet's available resources. Such as that sugar, built using raw sunlight and carbon converted in plant factories to become the energy that powers you and keeps the cycles revolving in your own life.
History
Wright was born in Wethersfield, Connecticut,[1] the son of James Wright and Mary née Goodrich. He studied classics and mathematics at Yale,[1] and in October 1835 moved to Natchez, Mississippi to tutor a plantation owner's family. His employer's business failed two years later, and he moved to Texas, working as a land surveyor and teacher. He surveyed ground for the Pacific Railroad Company.[2] During this time, he also collected plants for Asa Gray. Gray thought of Wright as one of his most trusted collectors.[3][4]
In 1849, he joined an army expedition (with Gray's help)[2] through Texas, botanising from Galveston to San Antonio and then on to El Paso. But he had to walk most of the 673 miles, (which took over 104 days effort).[5] He collected seeds of Penstemon baccharifolius (Hook), between Texas and El Paso, which were later given to William Hooker. Also, Castilleja lanata (found near the Rio Grande) and Castilleja integra (found in the Organ Mountains, near El Paso).[6] In the spring of 1851, he joined the United States and Mexican Boundary Survey (also with Gray's help).
His collections from these two trips, formed the basis of Gray's Plantae Wrightianae (1852–53). He found around 50 new plants in the area.[3]
Between 1853 and 1856, he took part in the Rodgers-Ringgold North Pacific Exploring and Surveying Expedition,[1] collecting plants in Madeira, Cape Verde, Cape Town, Sydney, Hong Kong, the Bonin Islands, Japan (at Hakodate, Tanegashima, the Bonin Islands and the Ryukyu Islands including Okinawa)[7] and the western side of the Bering Strait. He collected over 500 specimens while the ships were delayed at Simon's Bay, near Cape Town.[1]
Wright left the expedition at San Francisco in February 1856 and went south to Nicaragua.[2] His collection of plants from Hong Kong was used by George Bentham for his Flora Hongkongensis (1861).
Between 1856 and 1867, he led a scientific expedition to Cuba.[2] In 1859 he joined Juan Gundlach in the area around Monteverde, and in the winter of 1861-62 they explored together around Cárdenas. He was also still in communication with Asa Gray and via him, Charles Darwin, discussing orchids.[8] This was possible because at the start of the American Civil War, he was in Cuba and Gray kept him there until 1864 to keep Wright safe and his ongoing botanical work intact.[9] In 1871, he went with the US Commission to Santo Domingo.[2]
From 1875 to 1876, he was the librarian of the Bussey Institution at Harvard University.[10]
His lichen specimens were given to Edward Tuckerman.[1]
Legacy
Charles Wright is commemorated in the names of a number of plants, including Datura wrightii, the genus Carlowrightia (wrightworts) and Geissorhiza wrightii (Baker).[1] George Engelmann named a small cactus after him, Wright's fishhook (Sclerocactus uncinatus var. wrightii).[5] He is also commemorated in the name of the American grey flycatcher (Empidonax wrightii ) found near El Paso. Tropidophis wrighti (Wright's dwarf boa) was also named after him.[2]
Charles Wright Elementary School in Wethersfield, Connecticut is named after him.[12]
See also
References
- Barbara and Richard Mearns - Audubon to Xantus, The Lives of Those Commemorated in North American Bird Names ISBN 0-12-487423-1
- Richard A Howard Charles Wright in Cuba, 1856-1867 ISBN 0-89887-059-3
- ^ a b c d e f Mary Gunn and L. E. W. Codd Botanical Exploration Southern Africa, p. 381, at Google Books
- ^ a b c d e f Bo Beolens, Michael Watkins and Michael GraysonThe Eponym Dictionary of Reptiles, p. 290, at Google Books
- ^ a b Carolyn DodsonA Guide to Plants of the Northern Chihuahuan Desert, p. 24, at Google Books
- ^ Dupree, A. Hunter (1988). Asa Gray, American Botanist, Friend of Darwin. Baltimore, MD: Johns Hopkins University Press. pp. 165–166. ISBN 978-0-801-83741-8.
- ^ a b Dan Lewis Fische Early Southwest Ornithologists, 1528-1900, p. 82-83, at Google Books
- ^ Francis Whittier PennellThe Scrophulariaceae of Eastern Temperate North America at Google Books
- ^ Barnes, Peter. "Japan's botanical sunrise". barnes-botany.co.uk. Archived from the original on 23 April 2012. Retrieved 23 December 2014.
- ^ Charles Darwin The Correspondence of Charles Darwin:, Volume 12; Volume 1864, p. 212, at Google Books
- ^ Dupree, p. 310
- ^ OBITUARY RECORD OF GRADUATES OF YALE COLLEGE Deceased during the Academical Year ending in June 3 1856 (PDF). 1856. pp. 302–03.
- ^ International Plant Names Index. C.Wright.
- ^ Zymaris, Eva; Polansk, Rob (12 May 2017). "Kindergartner receives 'princess' treatment for last day of cancer treatment". wfsb.com. Archived from the original on 16 May 2017. Retrieved 15 July 2017.
External links
Works by or about Charles Wright at Wikisource- Plantae Wrightianae e Cuba Orientali by A. Grisebach at the Biodiversity Heritage Library.
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This page was last edited on 28 November 2023, at 10:18