Biodiversity at Risk

Natural history collections help us understand biodiversity past, present, and future. Take a look at what specimens can tell you about our changing world.

By Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Carolina parakeet, ORN-3095 (1857-05-01/1857-05-31) by Robert KennicottChicago Academy of Sciences / Peggy Notebaert Nature Museum

We are in the midst of a sixth mass extinction

At one time, the Carolina parakeet— Eastern North America’s only native parrot species—inhabited a territory from Florida to the Great Lakes. Human persecution and introduced diseases brought about the parakeet’s eventual extinction in 1918... Today, scientists estimate that we are losing dozens of species every day. Why? Many reasons. Extinction is a natural part of evolution, and not all extinction is bad. However, humans are currently speeding up the natural rate of extinction.

European starling, ORN-9183 (1940-10-13) by Earl G. WrightChicago Academy of Sciences / Peggy Notebaert Nature Museum

Humans endanger biodiversity when they introduce invasive species, or non-natives that have the ability to out-compete native species. In 1890, the American Acclimatization Society released 16 European starlings in New York City’s Central Park. The organization’s poetic goal was to establish populations of every bird mentioned in Shakespeare’s works in North America. In their new home, the starling population grew exponentially—today, an estimated 150 to 200 million inhabit North America and compete with eastern bluebirds, tree swallows, northern flickers, and other birds for nesting sites. Starlings also cause an estimated $800 million in damage to U.S. agriculture each year.

Norway maple, BOT-1426 (1896-05/1896-08) by L. M. UmbachChicago Academy of Sciences / Peggy Notebaert Nature Museum

The Norway maple is another example of an invasive species. It was introduced by British horticulturalists to North America in the mid-1700s, and grew in popularity in the 1870s and 1880s in American cities as an “ornamental variety” that adapted well to urban streets and parks. Soon, Norway maples “escaped” the city and began to dominate native forests. These trees produce large quantities of seeds that can quickly germinate. When full-grown, Norway maples create dense shade and displace native trees and other plants.

White heelsplitters, MAL-18436 (1902) by A. MielichChicago Academy of Sciences / Peggy Notebaert Nature Museum

Humans also endanger biodiversity through their impacts on climate change. Climate change will result in changes to temperature and precipitation patterns, which will modify the distribution of plants and animals and disrupt food webs. Climate change is very complex, making it impossible to know exactly how each species will respond to it--not all species will be adversely affected. We can, however, use our existing knowledge of historic species ranges and habits to predict how climate change will affect them. These mussels, for example, may soon find their midwestern habitats unsuitable to continue living in.

Passenger pigeon, ORN-3 (1914/1914)Chicago Academy of Sciences / Peggy Notebaert Nature Museum

What seems plentiful now may not be forever

In 1857—the same year that the Chicago Academy of Sciences was founded—a select committee of the Ohio State Senate debated a bill to protect the passenger pigeon, a common bird in Eastern North America. They found that, “the passenger pigeon needs no protection. Wonderfully prolific, having the vast forests of the North as its breeding grounds, traveling hundreds of miles in search of food, it is here today and elsewhere tomorrow, and no ordinary destruction can lessen them, or be missed from the myriads that are yearly produced.” Less than 60 years later, the passenger pigeon was driven to extinction by human actions, including overhunting and habitat destruction.

Passenger pigeons (1914/1914)Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Many of the passenger pigeons in the Chicago Academy of Sciences were "collected" from meat markets during the late 1800s and early 1900s. These birds were a common food source.

Band-tailed pigeon, ORN-9172 (1940-06-05) by Howard K. GloydChicago Academy of Sciences / Peggy Notebaert Nature Museum

Conservation and restoration are essential

Ranging from the Pacific northwest, down the California coast, and into the desert Southwest and Mexico, the band-tailed pigeon can be identified by its long tail with a wide, pale band at the tip. Based on genetic studies, the band-tailed pigeon is one of the closest living relatives of the extinct passenger pigeon. Some scientists are interested in using genetics to restore or reconstruct extinct species, and this isn't as much science fiction as it might seem. However, protecting species while they are still alive is the best way to conserve our biodiversity.

American beaver, MAM-2015.13.168Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Restoration often works best when it focuses on providing quality habitat. Beavers are the largest rodents native to North America and are known for their ability to construct lodges and dams that help to create wetland habitats. During the 1700s and 1800s, beaver fur was in great demand for hats and coats. Millions of beaver were killed, almost to the point of extinction. Today, however, their populations have recovered and can be found in the Chicago region.

Elephant tusk, MAM-2015.13.176Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Climate change increases the threat to global biodiversity

Elephants are severely threatened by poaching and habitat loss. Plantations of sugar, coffee, and other things we buy consume elephant habitats, so their populations are often isolated in relatively small reserves. Major changes in these habitats due to climate change could make them unsuitable for elephants, who have nowhere better to go. Elephants can tolerate hot weather as long as they can find enough water and forage, and cold weather so long as they can find additional or higher-quality food. But traveling farther to find food and water may not be an option in the relatively small, isolated habitats left for elephants.

Elephant skin, MAM-5102 (1975-10-01/1975-10-31)Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Zoos, like the one where this elephant lived, can play an important role in conservation.

American pikaChicago Academy of Sciences / Peggy Notebaert Nature Museum

Pika are adorable relatives of rabbits that live on the talus slopes of mountains worldwide. During the summer, they make hay from the flowers and grasses of surrounding fields, which they later eat during the winter. Pika live on talus slopes because they offer shelter from predators, but also because they exist on higher parts of mountains where it is relatively cool year-round. Brief heat waves of more than 77° F (25°C) can kill pikas. Pikas also need the weather to cooperate in order for them to make hay—too wet and the hay will mold, too dry and the plants they harvest won’t be able to grow.

Redwood wood sample (1894)Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Redwoods are the world’s tallest trees, bristle cones are the oldest, and aspen cover the most ground. To attain such extremes, these species require a stable climate for thousands of years. If the climate becomes unsuitable for reproduction, adult trees—which tolerate extremes that would kill seedlings—may still live for decades or centuries, but the forest will eventually disappear.

American alligator, HERP-FICChicago Academy of Sciences / Peggy Notebaert Nature Museum

One of the world’s 23 species of crocodilians, the American alligator lives throughout most of the southeastern United States. Like all crocodilians, it eats almost any kind of meat, but only hunts from water. The water also offers shelter from predators and extreme temperatures. Crocodilians, like many other reptiles, have “temperature-dependent sex determination.” A 1.8 °F (1°C) change in temperature could produce all males or all females, and a gender imbalance could cause species to go extinct.

Nine-banded armadillo, MAM-5091Chicago Academy of Sciences / Peggy Notebaert Nature Museum

We already see evidence of species moving away from their homes

Climate change is affecting the natural habitats that species depend on. Some species are able to migrate away from their historic ranges in search of more suitable habitat. Armadillos like hot weather, and can tolerate brief cold spells but not a continuation of cold weather. Prior the 1850's, this kept the nine-banded armadillo south of the Rio Grande River. Since then, the degree of range expansion of this species per year is ten times faster than the average rate expected for a mammal, with populations now established as far north as central Missouri, southern Kansas, western Tennessee, southern Illinois, and isolated reports in central Illinois and Nebraska. Temperature and rainfall are thought to have limited their northern distribution, and recent range expansion may have been aided by climatic change.

Eastern fox squirrel, study skin (1898-10-11) by R. WhitwantChicago Academy of Sciences / Peggy Notebaert Nature Museum

Population balances shift along with climate and resources

There are 278 species of squirrel in the world. Many of them are highly specialized, but the grey squirrel and the fox squirrel, the most common species in North America, can tolerate a wide range of climates, living from the tip of Florida to southern Canada. In Chicago, we often see grey squirrels more commonly in urban areas, and fox squirrels more often in suburban neighborhoods. Each species thrives under different environmental conditions and resources.

Grey squirrel, MAM-731 (1930-07-21) by Vera Y. FosterChicago Academy of Sciences / Peggy Notebaert Nature Museum

Brown rat, MAM-4894 (1937-12-30) by Bruce WathallChicago Academy of Sciences / Peggy Notebaert Nature Museum

Rats are another diverse group of rodents that can be found all around the world. Two species, the black rat and the brown rat, are perhaps best known as pests that spread disease and destroy food supplies. Brown rats prefer cool weather. Because they live underground, they can avoid a few hot days just by staying home. If it stays hot for too long, though, the tree-climbing black rat will soon take over the territory.

Cougar, MAM-4287 (1893/1893) by H. N. RustChicago Academy of Sciences / Peggy Notebaert Nature Museum

Some species have nowhere to go

By the mid 1800s, humans had eliminated large predators like cougars and wolves from Illinois. Trappers and settlers viewed these hunters as competitors for beaver, deer, and other useful wild animals. After farming began, settlers killed cougars and wolves to protect their livestock. Populations of cougars and wolves have not rebounded in Illinois, and even if an effort was made to re-introduce them, the habitat they would need has long been destroyed.

Franklin's Ground SquirrelChicago Academy of Sciences / Peggy Notebaert Nature Museum

Franklin's ground squirrel, a state threatened species in Illinois, could face possibly-insurmountable challenges adapting to climate change. Franklin's ground squirrel is a grassland mammal that inhabits areas with tall, dense herbaceous cover. Such areas are fragmented even in its current Midwestern range. If climate change forced this species to migrate north, the availability of suitable habitat would severely limit the establishment of new populations.

Scaleshell, MAL-19741 Scaleshell, MAL-19741 (1903-09-05) by L. E. DanielsChicago Academy of Sciences / Peggy Notebaert Nature Museum

Unionids are a group of freshwater mussels that reach their greatest diversity in the United States, and that also supply freshwater pearls. Unionids, including the scale shell pictured here, are the world’s most endangered group of animals, in part because they require such high quality water conditions. Dams and diversion of streams can destroy local populations. When runoff deposits excess sediment or nutrients into the water, or when it changes the water temperature or stream flow, mussels may also be negatively impacted. Although unionids can live in warmer water, they require seasonality to stimulate reproduction. Even if they could reproduce, it’s likely that the fish populations they need as larval hosts would also be negatively affected.

Tuberous grasspink orchid, BOT-777 (1871-06-19) by H. H. BabcockChicago Academy of Sciences / Peggy Notebaert Nature Museum

Orchids are usually considered tropical flowers, but did you know that there are many native to the United States, including nearly 50 species found in Illinois? Unfortunately, half of these are gone or nearly so. Like tropical orchids, our native species are a very diverse group that require specific conditions to grow successfully. Our native orchids become inactive during the winter, but an unseasonal cold snap can easily kill new flowers in spring, preventing reproduction. Similarly, our orchids can grow well in hot weather, but if it warms up too soon orchids may flower before their pollinators are active, preventing seed creation. Finally, orchids do not disperse very well, meaning that when environmental conditions do change, they have a difficult time adjusting.

American black bear, MAM-2203 (1932-08-18) by Edwin V. KomarekChicago Academy of Sciences / Peggy Notebaert Nature Museum

Black bears are omnivores that eat a variety of plants and animals. These large mammals need a lot of space—the typical territory for a male black bear is between 15 and 80 square miles. As trappers and hunters killed bears for their valuable fur and meat, and as farmers destroyed large tracts of natural habitat to make room for agriculture, bears were eliminated from their historic range in the Midwest. Bears still live in much of the rest of the country, but their existence may be threatened as climate change affects access to resources, and as humans continue to encroach on suitable habitat.

Big brown bats (1930-07-03) by Don A. SpencerChicago Academy of Sciences / Peggy Notebaert Nature Museum

We don't know how many species will react to climate change

There are more than 1,000 species of bats found all around the world filling important roles in local ecosystems, from dispersing seeds to suppressing insect pests. Many bat species only live in warm places. However, some species hibernate when food is scarce, needing cool temperatures to slow their metabolism so that they do not starve to death before food is plentiful again. Bats often hibernate in caves, and in damp caves fungi can grow. In some circumstances, a fungus can attack hibernating bats and may kill the entire population. Bat species may be unable to adapt or migrate quickly enough to be successful in a world altered by climate change.

Karner blue butterfly, ENT-2015.15.1 (2014-09-01/2014-09-30) by Sarah M. KlepingerChicago Academy of Sciences / Peggy Notebaert Nature Museum

The beautiful adult stage of the Karner blue butterfly that you see here is the last of a series of miraculous transformations that began with an egg laid on a specialized host plant. For their host plant, Karner blue butterflies only use lupine that naturally grows in open clearings along the dunes and forests of the Great Lakes. Hot weather causes butterfly larvae to develop more rapidly, causing subsequent generations to be small and weak. Hotter and/or drier weather can also change the time of lupines’ germination and blooming, potentially leaving young Karner blues with no food. Karner blue caterpillars are vulnerable to bacterial and fungal infection if weather gets too wet, though.

Dragonfly specimensChicago Academy of Sciences / Peggy Notebaert Nature Museum

The earliest dragonflies lived in ancient swamps that formed today’s coal deposits. Although we see dragonflies flitting about streams, ponds, fields, and maybe our own backyards, they spend most of their lives underwater as voracious predators. Many dragonfly species do very well in hot climates, but as temperature increases, nymphs (dragonfly youngsters) may transform into adults more quickly. Conversely, weather that is too cold will kill adult dragonflies.

Canada lynx, MAM-2603Chicago Academy of Sciences / Peggy Notebaert Nature Museum

Lynx look a lot like bobcats—in fact, they are closely related. The biggest difference between the two species is the luxurious fur and huge padded feet of the lynx that allow it to survive in areas with cold deep snow. Hot spells can cause snow to melt early, making it hard for lynx to travel and hunt. Lynx might starve to death or have their territory invaded by bobcats, coyotes, and other competitors. Wet weather can be dangerous for lynx as well because it can saturate their coats and expose them to hypothermia (dangerously low body temperature).

Kirtland's warbler, ORN-17301 (1884-03-01) by C. J. MaynardChicago Academy of Sciences / Peggy Notebaert Nature Museum

Kirtland's warblers are highly specialized birds that pass through our backyards every spring and autumn, during migration. These birds winter in the Bahamas, but, in the summer, migrate to find young jack pine stands in northern Michigan. Too-old or too-young trees are unsuitable for breeding, and forests that are too sparse are accessible to brown cowbirds, a nest parasite. Kirtland’s warblers can only nest in jack pine stands that are 6 to 15 years old—warmer and/or wetter climates promote the growth of other tree species that can outcompete jack pines. Increased droughts, on the other hand, might allow more fires to keep forests small and young, allowing jack pines to compete successfully against other trees and making more nesting habitat for Kirtland’s warblers. However, drought could also negatively affect the birds’ wintering grounds in the Bahamas.

A Look at the Chicago Academy of Sciences CollectionsChicago Academy of Sciences / Peggy Notebaert Nature Museum

The specimens shown in this exhibit don't take care of themselves... Take a behind-the-scenes look at how we preserve biological collections to last for hundreds of years so that future generations can also have access to this rich scientific resource.

Credits: Story

Content presented here was modified from text written for the in-house exhibits "Nature's Struggle" (2014) and "Weather to Climate" (2016). All rights reserved by the Chicago Academy of Sciences / Peggy Notebaert Nature Museum.

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The story featured may in some cases have been created by an independent third party and may not always represent the views of the institutions, listed below, who have supplied the content.
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