Latest news with #CarlLinnaeus


The Hindu
11-07-2025
- Health
- The Hindu
How the Cinchona tree took on malaria
One of humankind's greatest enemies has been the mosquito. More specifically, the female Anopheles mosquito that spreads malaria. Some experts reckon that the disease might have killed more than half the humans who ever lived! Yet, all along, a cure for this dreadful illness had been quietly hiding in the jungles of South America: the wrinkled red-brown bark of the Cinchona (pronounced sin-koh-nah) tree. It's easy to miss this thin evergreen tree in the dense vegetation of its natural habitat. Although indigenous people in South America had long known of its usefulness against various fevers, no one quite knows exactly how its ability to cure malaria was discovered. The story, most believe, goes back to the 15th century when Spanish colonisers and their slaves first arrived in South America, bearing the malaria-causing parasite in their bodies. Soon, bloodthirsty mosquitoes were spreading the disease and scores of people began dying of it. Respite Quinine, a chemical compound found in the bark of the Cinchona, offered a treatment and the indigenous people, who had long used it to treat various ailments, most likely passed on this remedy to the Christian missionaries or Jesuits, who had followed the colonisers into South America. Not surprisingly, Jesuit physicians pioneered the use of the Cinchona bark as a cure for malaria in Western medicine. In time, stories of the miracle cure began doing the rounds. In fact, the Swedish biologist Carl Linnaeus named the tree after a story of the Count of Chinchón — the Spanish Viceroy in Lima, Peru — who had been cured of malaria by it. By the end of the 16th century, this little South American tree was being mercilessly axed and transported to Europe in Spanish ships. Demand for quinine had soared, as European colonisers had spread their tentacles into mosquito-ridden tropical lands around the world. By the beginning of the 19th century, South American countries had banned the export of Cinchona seeds and saplings to maintain its monopoly over this priceless cure for malaria. However, importing quinine from South America was proving to be far too expensive for the other European empires. So, in a secret operation, plant hunters smuggled the seeds out of Peru and Bolivia and took them to British botanical gardens in England and India. Meanwhile, the Dutch began growing Cinchona plantations in Indonesia. For centuries, Cinchona remained the only source of quinine. It made it possible for Europeans to establish thriving tropical empires. Technological advances in the 20th century, however, allowed humans to produce artificial quinine and also uncover other cures for malaria. Finally, Cinchona could go back to being just a tree and was spared from the greed that had nearly decimated it.
Yahoo
03-06-2025
- General
- Yahoo
A bottlenose dolphin? Or Tursiops truncatus? Why biologists give organisms those strange, unpronounceable names
Most people would call it a 'field mouse,' but a scientist would ask, 'Was it Peromyscus maniculatus? Or Peromyscus leucopus?' Scientists use a system of complicated-sounding names to refer to everyday creatures, a practice heavily lampooned in the Warner Bros. cartoons featuring the Road Runner and Wile E. Coyote – or, respectively, Accelleratii incredibus and Carnivorous vulgaris. As a biologist, I use these seemingly odd names myself and help my students learn them. For most people it's a huge effort, like learning a second language. That's because it is. The science of naming and classifying organisms is called taxonomy. Scientists do this so they can be as precise as possible when discussing living things. The first word in an organism's name is its genus, which is a group of related species, such as Panthera for lions, tigers and leopards. The second word is the specific name identifying the species, usually defined as a population that can reproduce only with each other, such as Panthera leo for lion. Every two-word combination must be unique. Called binomial nomenclature, this naming system was popularized by Swedish naturalist Carl Linnaeus in the 1700s. So, humans are Homo sapiens, the red maple Acer rubrum, garlic Allium sativum, and the eastern spotted skunk Spilogale putorius. Today, biologists maintain huge databases containing the taxonomic names of plants, animals, fungi and other organisms. For instance, one of these databases – the Open Tree of Life project – includes over 2.3 million species. The scientist who discovers a species usually names it by publishing a formal description in a peer-reviewed journal. From there, the name makes its way into the databases. From then on, scientists always use that name for the organism, even if it turns out to be misleading. For example, many fossils were originally given names containing the Greek root 'saur,' which means lizard – even though paleontologists later realized dinosaurs were not lizards. To most people, these names sound inscrutable. Particularly nowadays, as science becomes more open and accessible to everyone, such arcane vocabulary can come across as old-fashioned and elitist. Given the current backlash against 'elites' and 'experts' in every field, that's a serious charge. But in a roundabout way, this seemingly exclusive practice is really a story of inclusiveness. As modern science began taking shape in Europe during the 1600s, scientists had a problem. They wanted to read and be read by others, but language got in the way. French scientists couldn't read Swedish, Swedes couldn't read Italian, and Italians couldn't read German. Also, writing about plants and animals posed a particular challenge: Many species had common names that could vary from place to place, and some common names might apply to multiple species. Scientists needed a way to be precise and consistent when referring to species, so that everyone could understand each other. To sidestep the language issue, scientists of the era mostly published their work in classical Latin. Back then, everyone learned it – at least every European man wealthy enough to attend school and become a scientist. Others published in classical Greek, also widely taught. By sticking with these more universally known languages, early scientists made sure that science was accessible to as many of their peers as possible. By the late 1700s and 1800s, translation services were broadly available, so naturalists such as Georges Cuvier could write in his native French, and Charles Darwin in his native English. Today, English has become the de facto language for science, so most scientists publish in English regardless of their native tongue. So why continue to use Latin and Greek names today? Taxonomists do it partly out of tradition, but partly because the terminology is still useful. Even without seeing a photo of the animal, a biologist might work out that Geomys bursarius – 'earth-mouse with a pouch' – was a pocket gopher. Or that Reithrodontomys fulvescens – 'groove-toothed mouse that is yellow' – is a yellow mouse with grooves on its incisors. Although taxonomists still largely adhere to the naming principles of Linnaeus, new scientific names are more and more frequently derived from non-European languages. For example, a chicken-size dinosaur discovered and named in China is called Yi qi, meaning 'strange wing' in Mandarin. Some of the more recent names are touched by whimsy, with a few honoring politicians and celebrities. Etheostoma obama is a spangled darter named after the 44th U.S. president; the Swift twisted-claw millipede – Nannaria swiftae – is named after pop star Taylor Swift. With so much of Earth's biodiversity yet to be discovered and named, remember that names are just names. What we call these species often reflects our own values and perspectives. In the future, another language – or no language at all – might rise to dominance. Artificial intelligence may act as a universal translator. This possibility would let everyone publish and read science in their own language. Predicting how technology will change our relationship with terminology is challenging, but the need for precise scientific language, including the names of species, will never go away. This article is republished from The Conversation, a nonprofit, independent news organization bringing you facts and trustworthy analysis to help you make sense of our complex world. It was written by: Nicholas Green, Kennesaw State University Read more: How many types of insects are there in the world? Thousands of undiscovered mammal species may be hidden in plain sight, new research finds Scientists discover five new species of black corals living thousands of feet below the ocean surface near the Great Barrier Reef Nicholas Green does not work for, consult, own shares in or receive funding from any company or organization that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.