A species is a group of organisms that share a genetic heritage, are able to interbreed, and to create offspring that are also fertile. Different species are separated from each other by reproductive barriers. These barriers can be geographical, such as a mountain range separating two populations, or genetic barriers that do not allow for reproduction between the two populations. Scientists have changed their definition of a species several times throughout history.
Species is one of the most specific classification that scientists use to describe animals. Scientists use a system of binomial nomenclature to describe animals without the confusion of common names. This system uses the genus as the first name, which is always capitalized, and the species name is the second name, always lower case.
Thus, some animals like the Red fox, Vulpes vulpes, are both in the genus Vulpes and their species name is vulpes. Note the capitalization difference to distinguish between genus and species. Other foxes such as the swift fox, Vulpes velox, are also part of the Vulpes genus, but barriers exist that keep them from interbreeding with the Red foxes. In this way, they remain distinct species.
Since the days of Carl Linnaeus, the creator of binomial nomenclature, animals have been constantly classified and reclassified into different groups, genre, species and subspecies. Linnaeus, classifying organisms in the 1700s, restricted his classifications to the physical attributes of various organisms.
Most organism, surprisingly, he correctly identified as being related. Others, however, he couldn’t have been more wrong about. Modern day genetic techniques have given us a much better window into the historical relationships between animals.
For instance, when Linnaeus first classified the elephant in the early 1700s, he only ever saw one specimen. The specimen was a fetal Asian elephant, the smallest of the known elephants today. Not knowing better, Linnaeus named the species Elephas maximus. Modern day scientists have been forced to reclassify the elephant several times.
The first distinction is between the Asian and African elephants, which are much different in size. Scientists then further had to distinguish between elephants that inhabited grasslands and those that lived in forests in Africa. Genetics show the populations do not interbreed and are separated by a reproductive barrier.
In the next century, Charles Darwin and Alfred Wallace separately conceived of the mechanism that creates multiple species from a single species. This process of natural selection applies adversity of different forms that organisms must overcome to reproduce.
Organisms that are better adapted to the environment are able to reproduce more, and their offspring can also increase in number. In this way, different lines of the same species can do better or worse, depending on their genetics. Eventually, two successful lines may diverge, creating a reproductive barrier between the two populations. These populations, according to Darwin and Wallace, are now considered separate species.
Since the beginning of time, this process has been occurring and dividing organisms along different successful lineages. This theory has been confirmed by a large body of evidence. Fossil evidence provides clues that animals have been constantly changing over time, in response to a variable environment.
Where Linnaeus saw animals as static, unchanging entities, it is now widely accepted that species exist on a spectrum, with some being closer related to certain species than others. Because of this, animals can often hybridize, or mate between species.
Examples of Species
Polar bears and Grizzlies
Oftentimes the only barrier to reproduction is geographic, or based on the physical location of the animals. If this changes, the animals can interbreed, and may merge into one species. This is currently being seen in the wild in polar bears and grizzly bears. As the climate changes, polar bears are forced further south, and must start exploiting different food sources.
The change in climate also allows grizzly bears to venture further north, encountering polar bears along the way. The previously separated populations now have a chance to breed, and sometimes they are successful. Hybrids have been seen in the wild, but it is not yet known if they hybrids will be successful.
There are many different situations and examples of reproductive barriers, but if the barrier can be removed, it is likely that two related species will be able to interbreed. Non-related species rarely have a possibility of breeding because they have become too different from each other.
For instance, a bat and turtle have a completely different genetic makeup. The genes that control growth in the turtle would not function in a bat, and vis-versa. In fact, they don’t even have the same number of chromosomes, which is a requirement for sexually reproducing organisms to be successful.
Dogs and Wolves
Still other animals, like dogs and wolves, are still technically the same species. While they have the same number of chromosomes and could technically breed, the domestic dog has come a long way from its wild counterpart. Dogs have not only evolved to be more cuddly and soft, but are attuned to human social cues.
Wolves operate in a much different social structure. As such, the two are very unlikely to breed in the real world. However, because they can create fertile offspring, scientists consider them the same species.
Dogs and wolves are a good example of species radiation, or the incremental changing in a population that is widely distributed. Think of a Chihuahua. If Linnaeus had classified this animal, he certainly would not have put it in the same category as a wolf.
However, a Chihuahua can breed with a slightly bigger dog, which can breed with large dog, which could easily breed with a wolf. In this way, a Chihuahua and a wolf have the same genetic basis, expressed in very different ways.
Related Biology Terms
- Hybrid – An organism produced by the crossing of two distinct species.
- Reproductive Barriers – Obstacles that prevent two animals from producing fertile offspring.
- Binomial Nomenclature – The system of naming individual species with two Latin names, the first related to their genus, the second to their species.
- Taxonomical Hierarchy – The system into which all organisms are placed for classification.
A species is a group of living organisms that can interbreed and produce fertile offspring. Members of the same species share common characteristics and can reproduce with one another.
New species can be formed through a process called speciation, which occurs when a population of organisms becomes isolated from other populations and undergoes genetic changes over time. Over generations, these genetic changes can accumulate and eventually lead to the development of a new species.
Species are classified based on their physical characteristics, genetic makeup, and evolutionary relationships. The current system of classification, called taxonomy, groups species into a hierarchy of increasingly specific categories, including domain, kingdom, phylum, class, order, family, genus, and species.
It is estimated that there are between 8.7 and 12.7 million species on Earth, although only about 1.2 million have been formally described and named by scientists.
Preserving species is important for maintaining biodiversity, which provides many benefits to humans and the environment. Biodiversity helps to regulate ecosystems, provide ecosystem services such as pollination and water filtration, and contribute to cultural and economic values. Loss of biodiversity can lead to negative impacts on human health and well-being.