Book 1 Reading and Speaking (1108795), страница 14
Текст из файла (страница 14)
What are the basic taxonomic differences between the main classes of animals?3. What basic adaptations have animals developed to different environments where animal live?4. What environments can animals never adapt to? Why? Are there other organisms that can live there?5. What is the role of species diversity in the stability of ecosystem?6. What role do parasites and predators play in keeping biodiversity?Exercise 2. You are going to read a text about bird migrations. The following figures will be used in thetext. What do you think they refer to?• 30,000 km• 100 hours• 500 beats• 9000 m• 21 gramsExercise 3.
Now read the text to check your answers.Have Wings, Will Travel: Avian Adaptations to MigrationBy Mary DeinleinAvian AeronauticsFlight affords the utmost in mobility and has made possible the evolution of avian migration as a means ofexploiting distant food resources and avoiding the physiological stress associated with cold weather. Variations inthe patterns of migration are nearly as numerous as the birds that migrate. While some species move only a fewkilometers up and down mountain slopes, others will travel hundreds or even thousands of kilometers, oftentraversing vast bodies of water or tracts of inhospitable terrain.One record holder in long-distance travel is the Arctic Tern (Sterna paradisaea), which makes an annualround-trip of about 30,000 kilometers between opposite ends of the globe, from Arctic breeding grounds toAntarctic seas.
This feat is possible because terns are adapted for feeding at sea, allowing them to refuel en route.Even more amazing are the aerial voyages of the landbirds and shorebirds whose transoceanic flights must beaccomplished non-stop. The Pacific Golden-Plover (Pluvialis fulva) flies continuously for more than 100 hours totravel the 5,000- to 7,000-kilometer distance from northern Siberia and Alaska to Hawaii and other islands in thePacific Ocean.The Blackpoll Warbler's (Dendroica striata) over-water flight from the coast of New England or southernCanada to South America keeps it aloft for 80 to 90 continuous hours over a distance of 3,000 to 4,000 kilometers,an effort which researchers Tim and Janet Williams conclude "requires a degree of exertion not matched by anyother vertebrate; in man the metabolic equivalent would be to run a 4 minute mile for 80 hours. Even the tiny Rubythroated Hummingbird (Archilochus colubris), weighing only about as much as a penny, makes the 1,000-kilometer,24-hour spring flight across the Gulf of Mexico from the Yucatan Peninsula to the southern coast of the UnitedStates.So how do they do it? What specialized adaptations allow birds to accomplish such prodigious feats ofendurance?Bird BasicsTo understand how superbly adapted birds are to their highly mobile way of life, one must first consider thequintessential characteristics that distinguish birds from all other animals.
Feathers, the trademark of the ClassAves, provide the insulation necessary to maintain a high "engine" (body) temperature, ranging from 107 to 113degrees F across species. Additionally the long feathers of the wings act as airfoils which help generate the liftnecessary for flight. Well-developed pectoral muscles power the flapping motion of the wings. A streamlined bodyshape and a lightweight skeleton composed of hollow bones minimize air resistance and reduce the amount ofenergy necessary to become and remain airborne.Keeping the hard-running avian engine running smoothly requires super-efficient circulatory and respiratorysystems. Birds have a large, four-chambered heart which proportionately weighs six times more than a humanheart.
This, combined with a rapid heartbeat (the resting heart rate of a small songbird is about 500 beats perminute; that of a hummingbird is about 1,000 beats per minute) satisfies the rigorous metabolic demands of flight.The avian respiratory system—the most efficient in the animal kingdom—consists of two lungs plus special airsacs, and takes up 20% of a bird's volume compared to 5% in a human.
Unlike mammalian or reptilian lungs, thelungs of birds remain inflated at all times, with the air sacs acting as bellows to provide the lungs with a constantsupply of fresh air.34Migratory ManiaIn addition to these general avian characteristics, migratory birds exhibit a suite of specialized traits. Migrantsgenerally have longer, more pointed wings than non-migratory species, a feature which further minimizes airresistance. Also, the pectoral muscles of migrants tend to be larger and composed of fibers which are more richlysupplied with nutrient- and oxygen-carrying blood vessels and energy-producing mitochondria, making the pectoralmuscles of migrants especially efficient at energy production and use.Many migrants face the additional challenge of flying at high altitudes.
Most songbirds migrate at 500 to2,000 meters, but some fly as high as 6,800 meters; swans have been recorded at 8,000 meters and Bar-headedGeese (Anser indica) flying over the Himalayas at 9,000 meters. Accounting for their ability to withstand the lowlevels of oxygen available at such altitudes, the blood of migratory birds is characterized by two specializedadaptations. The oxygen-carrying capacity of the blood is enhanced by a high concentration of red blood cells.Secondly, instead of one form of hemoglobin in the red blood cells as is typical in non-migrants and other classesof vertebrates, some migratory birds possess two forms of hemoglobin which differ in their oxygen carrying andreleasing capacities.
This guarantees an adequate oxygen supply over a wide range of altitudes and allows birds toadapt rapidly to varying levels of oxygen availability.Preparing for take-offMigrants change rapidly into a "superbird state" in preparation for migration. This transformation is triggeredby an internal annual "clock," which is set by day length and weather.When it comes to fueling migration, fat is where it's at.
Fat is not only lighter and less bulky thancarbohydrates or protein, but also supplies twice as much energy. Not surprisingly, then, preparation for migrationentails a rapid weight gain program geared to increasing fat reserves. This program combines both behavioral andphysiological changes. A dramatic increase in appetite and food consumption, termed hyperphagia, begins abouttwo to three weeks before migration and persists throughout the migratory period. Accompanying this veritablefeeding frenzy is an increase in the efficiency of fat production and storage.
As a result, a migratory bird canincrease its body weight through fat deposition by as much as 10% per day (usually 1-3%). Additionally, in birdsthat are in migratory disposition, the pectoral muscles become larger and well supplied with enzymes necessary forthe oxidation, or "burning," of fat.Longer migration distances require greater amounts of fat. Non-migratory passerines maintain a "fat load" ofabout 3-5% of their lean body weight. In preparation for migration, short- and medium-distance migratory songbirdsattain a fat load of between 10 and 25%, while long-distance migrants reach fat loads of 40 to 100%.
Maximum fatloads are attained just prior to flights over major topographic barriers, such as deserts, high mountains, or largebodies of water. A typical Blackpoll Warbler at the end of its breeding season weighs about 11 grams, equivalent tothe weight of four pennies. In preparing for its transatlantic trek, it may accumulate enough fat reserves to increaseits body weight to 21 grams.Readiness for migration entails other behavioral modifications. Before migrating in the fall, many migrantswhich ordinarily eat insects will switch to a diet of berries and other fruits. At this time when food intake needs areincreasing and insect numbers are decreasing, fruits are abundant and high in carbohydrates and lipids which arereadily converted to fat. Many migrants that typically are not gregarious will flock together prior to, or during,migration.
This social behavior may result in improved predator avoidance, food finding, and orientation. Somespecies also fly in formation, a strategy that improves aerodynamics and reduces energy expenditure.A radical shift from being active exclusively during the day to migrating at night occurs in many speciesduring migration, including most shorebirds and songbirds. Possible advantages to flying at night includedecreased vulnerability to predators, reduced threat of dehydration or overheating, a greater likelihood ofencountering favorable winds and a stable air mass (rising hot air and more variable wind directions occur duringthe daytime), and time during the day to forage.Migratory birds kept in captivity exhibit behavior termed Zugunruhe, or migratory restlessness. This behavior,characterized by rapid fluttering of the wings while perching, begins at the same time that conspecifics (individualsof the same species) in the wild are setting off on migration, and persists for the same length of time required forthe wild counterparts to complete their migration.
The captive birds even orient themselves in the appropriatedirection in which they would be migrating. Over the past 15 years, this behavior has allowed researchers todemonstrate experimentally that many of the important physical and behavioral correlates to migration are under atleast partial genetic control. For instance, when migratory Blackcaps (Sylvia atricapilla ) were mated with nonmigratory individuals of the same species, 30% of the offspring exhibited Zugunruhe. When individuals whichdisplayed high levels of Zugunruhe, consistent with their long migratory routes, were bred with conspecifics withshort migration routes, the offspring displayed intermediate levels of Zugunruhe.
The results from these and othercross-breeding experiments support the hypothesis that migration and its associated patterns—such as distanceand timing—are inherited traits, at least in some species. These experiments apply to species with relatively fixedmigration routes. Many species have facultative migration patterns, moving only when food supply is low, or whenweather turns bad. Research has shown that access to food for these species greatly affects Zugunruhe.Despite this advanced understanding of some of the mechanisms behind avian migrations, the annualodysseys of billions of birds remain one of the most mysterious and amazing phenomena in the animal world.Exercise 4. What bird species are mentioned in the text? What facts are given about each of them?35Exercise 5.
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