Life on the scales: simple mathematical relationships underpin much of biology and ecology.A mouse lives just a few years, while an elephant can make it to age 70. In a sense, however, both animals fit in the same amount of life experience. In its brief life, a mouse squeezes in, on average, as many heartbeats and breaths as an elephant does. Compared with those of an elephant, many aspects of a mouse's life--such as the rate at which its cells burn energy, the speed at which its muscles twitch, its gestation time, and the age at which it reaches maturity--are sped up by the same factor as its life span is. It's as if in designing a mouse, someone had simply pressed the fast-forward button on an elephant's life. This pattern relating life's speed to its length also holds for a sparrow, a gazelle gazelle, name for the many species of delicate, graceful antelopes of the genus Gazella, inhabiting arid, open country. Most gazelles are found only in Africa, but several species range over N Africa and SW Asia; the Persian, or goitered, gazelle ( , and a person--virtually any of the birds and mammals, in fact. Small animals live fast and die young, while big animals plod through much longer lives. "It appears as if we've been gifted with just so much life," says Brian Enquist, an ecologist at the University of Arizona (body, education) University of Arizona - The University was founded in 1885 as a Land Grant institution with a three-fold mission of teaching, research and public service. in Tucson. "You can spend it all at once or slowly dribble it out over a long time." Scientists have long known that most biological rates appear to bear a simple mathematical relationship to an animal's size: They are proportional to the animal's mass raised to a power that is a multiple of 1/4. These relationships are known as quarter power scaling Power scaling of a laser is increasing its output power without changing the geometry, shape, or principle of operation. Power scalability is considered an important advantage in a laser design. laws. For instance, an animal's metabolic rate Noun 1. metabolic rate - rate of metabolism; the amount of energy expended in a give period basal metabolic rate, BMR - the rate at which heat is produced by an individual in a resting state appears to be proportional to mass to the 3/4 power, and its heart rate is proportional to mass to the--1/4 power. The reasons behind these laws were a mystery until 8 years ago, when Enquist, together with ecologist James Brown
James Joseph Brown (May 3 1933[1][2] – December 25 2006), commonly referred to as "The Godfather of Soul" and " of the University of New Mexico The University of New Mexico (UNM) is a public university in Albuquerque, New Mexico. It was founded in 1889. It also offers multiple bachelor's, master's, doctoral, and professional degree programs in all areas of the arts, sciences, and engineering. in Albuquerque and physicist Geoffrey West Geoffrey West (b. 1940) is a physicist. He was born "in a rural town in western England and moved to London when he was 13." [1] He received a bachelor's degree in physics from Cambridge and pursued graduate studies in California at Stanford. of Los Alamos Los Alamos (lôs ăl`əmōs', lŏs), uninc. town (1990 pop. 11,455), seat of Los Alamos co., N central N.Mex. It is on a long mesa extending from the Jemez Mts. The U.S. (N.M.) National Laboratory proposed a model to explain quarter-power scaling in mammals (SN: 10/16/99, p. 249). They and their collaborators have since extended the model to encompass plants, birds, fish and other creatures. In 2001, Brown, West, and several of their colleagues distilled their model to a single formula, which they call the master equation, that predicts a species' metabolic rate in terms of its body size and temperature. "They have identified the basic rate at which life proceeds," says Michael Kaspari, an ecologist at the University of Oklahoma University of Oklahoma, abbreviated OU, is a coeducational public research university located in the U.S. state of Oklahoma. Founded in 1890, it existed in Oklahoma Territory near Indian Territory 17 years before the two became the state of Oklahoma. in Norman. In the July 2004 Ecology, Brown, West, and their colleagues proposed that their equation can shed light not just on individual animals' life processes but on every biological scale, from subcellular sub·cel·lu·lar adj. 1. Situated or occurring within a cell: subcellular organelles. 2. Smaller in size than ordinary cells: subcellular organisms. 3. molecules to global ecosystems. In recent months, the investigators have applied their equation to a host of phenomena, from the mutation rate In genetics, the mutation rate is the chance of a mutation occurring in an organism or gene in each generation (or, in the case of multicellular organisms, cell division). See Luria-Delbrück experiment. in cellular DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. to Earth's carbon cycle. Carlos Martinez del Rio The Martinez del Rio Family The Martinez del Rio family in Mexico shares with few others the top echelon of Mexico's most prominent families. The family has been important in shaping Mexico's politics, economy and society from the time of Mexican independence from Spain, , an ecologist at the University of Wyoming UW is a national research university prominent in the fields of environment and natural resource research, specializing in agriculture, energy, geology, and water resource related fields. in Laramie, hails the team's work as a major step forward. "I think they have provided us with a unified theory Unified Theory may refer to:
THE BIOLOGICAL CLOCK In 1883, German physiologist Max Rubner Max Rubner [ru:bner] (June 2, 1854, Munich - April 27, 1932, Berlin) was a German physiologist (Physiologe), hygienist (Hygieniker). He taught as a professor at the Marburg University (1885-), Berlin University (1891-1909; 1909-1922), proposed that an animal's metabolic rate is proportional to its mass raised to the 2/3 power. This idea was rooted in simple geometry. If one animal is, say, twice as big as another animal in each linear dimension, then its total volume, or mass, is 23 times as large, but its skin surface is only 22 times as large. Since an animal must dissipate metabolic heat through its skin, Rubner reasoned that its metabolic rate should be proportional to its skin surface, which works out to mass to the 2/3 power. In 1932, however, animal scientist Max Kleiber of the University of California, Davis The University of California, Davis, commonly known as UC Davis, is one of the ten campuses of the University of California, and was established as the University Farm in 1905. looked at a broad range of data and concluded that the correct exponent is 3/4 not 2/3. In subsequent decades, biologists have found that the 3/4-power law appears to hold sway from microbes to whales, creatures of sizes ranging over a mind-boggling 21 orders of magnitude. For most of the past 70 years, ecologists had no explanation for the 3/4 exponent. "One colleague told me in the early '90s that he took 3/4-scaling as 'given by God,'" Brown recalls. The beginnings of an explanation came in 1997, when Brown, West, and Enquist described metabolic sealing in mammals and birds in terms of the geometry of their circulatory systems. It turns out, West says, that Rubner was on the right track in comparing surface area with volume, but that an animal's metabolic rate is determined not by how efficiently it dissipates heat through its skin but by how efficiently it delivers fuel to its cells. Rubner should have considered an animal's "effective surface area," which consists of all the inner surfaces across which energy and nutrients pass from blood vessels Blood vessels Tubular channels for blood transport, of which there are three principal types: arteries, capillaries, and veins. Only the larger arteries and veins in the body bear distinct names. to cells, says West. These surfaces fill the animal's entire body, like linens stuffed into a laundry machine. The idea, West says, is that a space-filling surface scales as if it were a volume, not an area. If you double each of the dimensions of your laundry machine, he observes, then the amount of linens you can fit into it scales up by 23, not 22. Thus, an animal's effective surface area scales as if it were a three-dimensional, not a two-dimensional, structure. This creates a challenge for the network of blood vessels that must supply all these surfaces. In general, a network has one more dimension than the surfaces it supplies, since the network's tubes add one linear dimension. But an animal's circulatory system isn't four dimensional, so its supply can't keep up with the effective surfaces' demands. Consequently, the animal has to compensate by scaling back its metabolism according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. a 3/4 exponent. Though the original 1997 model applied only to mammals and birds, researchers have refined it to encompass plants, crustaceans, fish, and other organisms. The key to analyzing many of these organisms was to add a new parameter: temperature. Mammals and birds maintain body temperatures between about 36[degrees]C and 40[degrees]C, regardless of their environment. By contrast, creatures such as lash, which allign their body temperatures with those of their environments, are often considerably colder. Temperature has a direct effect on metabolism--the hotter a cell, the faster its chemical reactions run. In 2001, after James Gillooly, a specialist in body temperature, joined Brown at the University of New Mexico, the researchers and their collaborators presented their master equation, which incorporates the effects of size and temperature. An organism's metabolism, they proposed, is proportional to its mass to the 3/4 power times a function in which body temperature appears in the exponent. The team found that its equation accurately predicted the metabolic rates of more than 250 species of microbes, plants, and animals. These species inhabit many different habitats, including marine, freshwater, temperate, and tropical ecosystems. The equation gave the researchers a way to compare organisms with different body temperatures--a person and a crab, or a lizard and a sycamore tree--and thereby enabled the team not just to confirm previously known scaling laws but also to discover new ones. For instance, in 2002, Gillooly and his colleagues found that hatching times for eggs in birds, fish, amphibians amphibians members of the animal class Amphibia. Includes frogs, toads, newts, salamanders and cecilians all capable of living on land or in water. , and plankton plankton: see marine biology. plankton Marine and freshwater organisms that, because they are unable to move or are too small or too weak to swim against water currents, exist in a drifting, floating state. follow a scaling law with a 1/4 exponent. When the researchers filter out the effects of body temperature, most species adhere closely to quarter-power laws for a wide range of properties, including not only life span but also population growth rates Growth Rates The compounded annualized rate of growth of a company's revenues, earnings, dividends, or other figures. Notes: Remember, historically high growth rates don't always mean a high rate of growth looking into the future. . The team is now applying its master equation to more life processes--such as cancer growth rates and the amount of time animals sleep. "We've found that despite the incredible diversity of life, from a tomato plant to an amoeba amoeba: see ameba. amoeba One-celled protozoan that can form temporary extensions of cytoplasm (pseudopodia) in order to move about. Some amoebas are found on the bottom of freshwater streams and ponds. to a salmon, once you correct for size and temperature, many of these rates and times are remarkably similar," says Gillooly. A single equation predicts so much, the researchers contend, because metabolism sets the pace for myriad biological processes. An animal with a high metabolic rate processes energy quickly, so it can pump its heart quickly, grow quickly, and reach maturity quickly. Unfortunately, that animal also ages and dies quickly, since the biochemical reactions involved in metabolism produce harmful by-products called free radicals, which gradually degrade cells. "Metabolic rate is, in our view, the fundamental biological rate," Gillooly says. There is a universal biological clock, he says, "out it ticks in units of energy Because energy is defined via work, the SI unit for energy is the same as the unit of work – the joule (J), named in honour of James Prescott Joule and his experiments on the mechanical equivalent of heat. , not units of time." SCALING UP The researchers propose that their framework can illuminate not just properties of individual species, such as hours of sleep and hatching times, but also the structure of entire communities and ecosystems. Enquist, West, and Karl Niklas of Cornell University have been looking for Looking for In the context of general equities, this describing a buy interest in which a dealer is asked to offer stock, often involving a capital commitment. Antithesis of in touch with. scaling relationships in plant communities, where they have uncovered previously unnoticed patterns. The researchers have found, for instance, that in a mature forest, the average distance between trees of the same mass follows a quarter-power scaling law, as does trunk diameter. These two scaling laws are proportional to each other, so that on average, the distance between trees of the same mass is simply proportional to the diameter of their trunks. "When you walk in a forest, it lOOKS random, but it's actually quite regular on average,' West says. "People have been measuring size and density of trees for 100 years, but no one had noticed these simple relationships." The researchers have also discovered that the number of trees of a given mass in a forest follows the same scaling law governing the number of branches of a given size on an individual tree. "The forest as a whole behaves as if it is a very large tree," West says. Gillooly, Brown, and their New Mexico colleague Andrew Allen have now used these scaling laws to estimate the amount of carbon that is stored and released by different plant ecosystems. Quantifying the role of plants in the carbon cycle is critical to understanding global warming, which is caused in large part by carbon dioxide carbon dioxide, chemical compound, CO2, a colorless, odorless, tasteless gas that is about one and one-half times as dense as air under ordinary conditions of temperature and pressure. released to the atmosphere when animals metabolize me·tab·o·lize v. 1. To subject to metabolism. 2. To produce by metabolism. 3. To undergo change by metabolism. metabolize to subject to or be transformed by metabolism. food or machines burn fossil fuels. Plants, by contrast, pull carbon dioxide out of the air for use in photosynthesis. Because of this trait, some ecologists have proposed planting more forests as one strategy for counteracting global warming. In a paper in an upcoming Functional Ecology, the researchers estimate carbon turnover and storage in ecosystems such as oceanic phytoplankton phytoplankton Flora of freely floating, often minute organisms that drift with water currents. Like land vegetation, phytoplankton uses carbon dioxide, releases oxygen, and converts minerals to a form animals can use. , grasslands, and old-growth forests. To do this, they apply their scaling laws to the mass distribution of plants and the metabolic rate of individual plants. The model predicts, for example, how much stored carbon is lost when a forest is cut down to make way for farmlands or development. Martinez del Rio cautions that ecologists making practical conservation decisions need more-detailed information than the scaling laws generally give. "The scaling laws are useful, but they're a blunt tool, not a scalpel," he says. SCALING DOWN The team's master equation may resolve a long-standing controversy in evolutionary biology: Why do the fossil record and genetic data often give different estimates of when certain species diverged? Geneticists This is a list of people who have made notable contributions to genetics. The growth and development of genetics represents the work of many people. This list of geneticists is therefore by no means complete. Contributors of great distinction to genetics are not yet on the list. calculate when two species branched apart in the phylogenetic tree by looking at how much their DNA differs and then estimating how long it would have taken for that many mutations to occur. For instance, genetic data put the divergence of rats and mice at 41 million years ago. Fossils, however, put it at just 12.5 million years ago. The problem is that there is no universal clock that determines the rate of genetic mutations in all organisms, Gillooly and his colleagues say. They propose in the Jan. 4 Proceedings of the National Academy of Sciences The Proceedings of the National Academy of Sciences of the United States of America, usually referred to as PNAS, is the official journal of the United States National Academy of Sciences. that, instead, the mutation clock--like so many other life processes--ticks in proportion to metabolic rate rather than to time. The DNA of small, hot organisms should mutate mu·tate intr. & tr.v. mu·tat·ed, mu·tat·ing, mu·tates To undergo or cause to undergo mutation. [Latin m faster than that of large, cold organisms, the researchers argue. An organism with a rewed-up metabolism generates more mutation-causing free radicals, they observe, and it also produces offspring faster, so a mutation becomes lodged in the population more quickly. When the researchers use their master equation to correct for the effects of size and temperature, the genetic estimates of divergence times--including those of rats and mice--line up well with the fossil record, says Allen, one of the paper's coauthors. The team plans to use its metabolic framework to investigate why the tropics tropics, also called tropical zone or torrid zone, all the land and water of the earth situated between the Tropic of Cancer at lat. 23 1-2°N and the Tropic of Capricorn at lat. 23 1-2°S. are so much more diverse than temperate zones are and why there are so many more small species than large ones. Most evolutionary biologists have tended to approach biodiversity questions in terms of historical events, such as landmasses separating, Kaspari says. The idea that size and temperature are the driving threes behind biodiversity is radical, he says. "I think if it holds up, it's going to rewrite our evolutionary-biology books," he says. ENTHUSIASM AND SKEPTICISM While the metabolic-sealing theory has roused much enthusiasm, it has its limitations. Researchers agree, for instance, that while the theory produces good predictions when viewed on a scale from microbes to whales, the theory is rife with exceptions when it's applied to animals that are relatively close in temperature and size. For example, large animals generally have longer life spans than small animals, but small dogs live longer than large ones. Brown points out that the metabolic-sealing law may be useful by calling attention to such exceptions. "If you didn't have a general theory, you wouldn't know that big dogs are something interesting to look at," he observes. Many questions of particular interest to ecologists concern organisms that are close in size. Metabolic theory may not explain, for example, why certain species coexist or why particular species invade a given ecosystem, says John Harte, an ecologist at the University of California, Berkeley The University of California, Berkeley is a public research university located in Berkeley, California, United States. Commonly referred to as UC Berkeley, Berkeley and Cal . Some scientists question the very underpinnings of the team's model. Raul Suarez, a comparative physiologist at the University of California, Santa Barbara History The predecessor to UCSB, Santa Barbara State College, focused on teacher training, industrial arts, home economics, and foreign languages. Intense lobbying by an interest group in the City of Santa Barbara led by Thomas Storke and Pearl Chase persuaded the State disputes the model's starting assumption that an animal s metabolic rate is determined by how efficiently it can transport resources from blood vessels to cells. Suarez argues that other factors are equally important, or even more so. For instance, whether the animal is resting or active determines which organs are using the most energy at a given time. "Metabolic scaling is a many-splendored thing," he says. Suarez' concern is valid, agrees Kaspari. However, he says, the master equation's accurate predictions about a huge range of phenomena are strong evidence in its favor. Ecologists, physiologists, and other biologists appear to be unanimous on one point: The team's model has sparked a renaissance for biological-sealing theory. "West and Brown deserve a great deal of credit for rekindling the interest of the scientific community in this phenomenon of metabolic scaling," Suarez says. "Their ideas have stimulated a great deal of discussion and debate, and that's a good thing." |
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