Cheetahs are spotted cats whose current natural habitat is mostly in sub-Saharan Africa. They are the fastest land animal on Earth, with the ability to sprint at speeds of about 120 kilometers per hour (75 miles per hour). They can accelerate from 0 to 97 kilometers per hour (60 miles per hour) in 3 seconds, making them faster than most sports cars. Cheetahs use their acceleration and speed to chase down and catch gazelles and other prey. Cheetahs have small heads, lean bodies, and long legs. They have a yellowish-tan coat with distinctive black spots.


Cheetahs face extinction pressure from climate change, hunting by humans, and habitat destruction. Cheetahs also have a low rate of reproductive success, meaning they are not always able to reproduce. With fewer offspring, the population can neither grow nor adapt to environmental changes.

Evolution of Cheetahs


There are various theories concerning cheetah evolution, but a popular one holds that cheetahs descended from the same ancestor as the American puma. About 10,000 to 12,000 years ago, around the end of the last ice age, an extinction event took place that wiped out many large mammal species around the world. The wild cheetahs of North America and Europe went extinct. This left only the Asian and African populations of cheetahs. Since then, stress from climate change, habitat loss, and human activities have put pressure on the remaining species. Today, cheetahs are found in the wild in several locations in Africa and a small portion of Iran. Scientists estimate that fewer than 8,000 African cheetahs are living in the wild and that there may be fewer than 50 Asian cheetahs left in the world.

Bottleneck Events


Cheetahs today are heading toward extinction. However, this is not the first time cheetahs have faced extinction. Genetic analysis of wild cheetahs shows they may have survived two historical bottleneck events. In biology, a bottleneck event occurs when something happens to sharply reduce the size of a population. When this happens, the few remaining individuals end up mating with relatives; this process is called inbreeding. Inbreeding reduces the size of the gene pool, which in turn can decrease genetic variability. When genetic variability is reduced in a population, it is harder for the remaining population to adapt to changes in their environment. In a very small population, any mutations that occur are much more likely to be passed on to offspring.


The first bottleneck event that cheetahs may have undergone occurred around 100,000 years ago when they expanded into Asia, Europe, and Africa. This range expansion is believed to have occurred rapidly, dispersing the cheetahs over a very large area and thus restricting their ability to exchange genes.


The second likely bottleneck event occurred about 10,000 to 12,000 years ago. That's about when the last ice age ended. The wild cheetahs of North America and Europe went extinct, leaving only the Asian and African populations. As large mammals died out across the world, the number of surviving cheetahs dwindled. This led to extreme inbreeding. Even though the number of living cheetahs grew to as many as 100,000 during the 19th century, their genetic variability remained low due to the extreme bottleneck event that took place thousands of years prior.

Cheetah Genes Today


Cheetah populations today have relatively low genetic variability. One way to test for the degree of inbreeding is to perform a skin graft. This involves transplanting a piece of skin from one cheetah onto another to see if the receiving cheetah accepts or rejects the graft. In inbred populations, skin grafts are easily accepted by individuals unrelated to the donor. This occurs among cheetahs, suggesting they have lost some genetic diversity. Another sign of inbreeding are asymmetrical skulls. In inbred animals, the skull is more asymmetrically shaped. This is true of cheetah skulls in certain museum collections.


A third line of evidence for inbreeding comes from cheetahs’ high homozygosity. Homozygosity is a measure of the genetic similarity between individuals in a population. Cheetah genomes typically exceed 90 percent homozygosity. By contrast, domestic cats and dogs, while also commonly inbred, have significantly lower rates of homozygosity. 


Cheetahs are facing different threats. These threats are collectively pushing them toward extinction. Humans are threatening the species by infringing on its habitat, hunting individuals, and perpetuating climate change. Experts believe cheetahs may also suffer from infectious diseases spread by domestic cats. Cheetahs struggle to cope with these pressures in part because they lack genetic variability. Evidence suggests cheetahs have faced genetic bottlenecks in the past and survived. As the population of wild cheetahs dwindles, only time will tell if it can survive the current genetic bottleneck.


Cheetahs: On the Brink of Extinction, Again

Cheetah's struggle to reproduce, which along with human-caused pressures to their population, puts their species in jeopardy. The IUCN Red List classifies this big cat species as vulnerable.


event that drastically reduces the size of a breeding population resulting in less genetic diversity


substance that causes or quickens a chemical reaction, without being affected by it.


(deoxyribonucleic acid) molecule in every living organism that contains specific genetic information on that organism.


proteins produced in living cells that act as catalysts to accelerate the vital processes of an organism.


process of complete disappearance of a species from Earth.


part of DNA that is the basic unit of heredity.

gene pool

all the available genes in a breeding population

genetic diversity

difference or variety of units of inheritance (genes) in a species.


differences in the genes among individual members of a species.


breeding animals that are closely related genetically


sudden variation in one or more characteristics caused by a change in a gene or chromosome.


living or once-living thing.


total number of people or organisms in a particular area.


one of many complex compounds, made of chains of amino acids, that make up the majority of all cellular structures and are necessary for biological processes.

reproductive success

passing genes on to the next generation