Timeline of evolution

Cells resembling prokaryotes appear. These first organisms are chemoautotrophs: they use carbon dioxide as a carbon source and oxidize inorganic materials to extract energy. Later, prokaryotes evolve glycolysis, a set of chemical reactions that free the energy of organic molecules such as glucose. Glycolysis generates ATP molecules as short term energy currency and is used in almost all organisms unchanged to this day. Lifetime of the last universal ancestor; the split between the bacteria and the archaea occurs.

Insects evolve on land and in fresh water from the myriapods. Some fresh water lobe-finned fish (Sarcopterygii) develop legs and give rise to the Tetrapoda. This happens in the water; tetrapods (Ichthyostega , Acanthostega and Pederpes finneyae) then use their legs to move out onto land, probably to hunt insects. Lungs and swim bladders evolve. Amphibians today still retain many characteristics of the early tetrapods.

Lystrosaurus is a common herbivore that survives the extinction. The archosaurs split from other reptiles. Teleosts evolve from among the Actinopterygii (ray-finned fish), and eventually become the dominant fish group. Atmospheric oxygen, at 10%, is one third of its former level, so animals with air sac breathing systems will do well (present-day bird respiration exemplifies the air sac system). Some spores of bacteria Bacillus strain 2-9-3 (Sali bacillus marismortui) are trapped in salt crystals known as halite in New Mexico. They are re-animated in AD 2000 and have multiplied rapidly. Currently the world oldest living organism.

From synapsids come the first mammal precursors, therapsids, and more specifically the eucynodonts. Initially, they stay small and shrew-like. All mammals have milk glands for their young, and they keep a constant body temperature. Also, one of a pair of autosomes acquires gene SRY (derived from the SOX3 gene of the X chromosome) to become the Y chromosome, which has been decreasing in length since. Gymnosperms (mostly conifers) are the dominant land plants. Plant eaters will grow to huge sizes during the dominance of the gymnosperms to have space for large guts to digest the poor food offered by gymnosperms.

Marine reptiles include Ichthyosaurs and Plesiosaurs. Ammonites and belemnites flourish. Dinosaurs survive the extinction and grow to large size, but the thecodonts, or "socket-toothed" reptiles, die out. Modern amphibians evolve: the Lissamphibia; including Anura (frogs), Urodela (salamanders), and Caecilia. Geminiviridae, a diverse group of viruses, are traceable to this epoch or earlier<ref>"Viruses of nearly all the major classes of organisms—animals, plants, fungi and bacteria/archaea—probably evolved with their hosts in the seas, given that most of the evolution of life on this planet has occurred there. This means that viruses also probably emerged from the waters with their different hosts, during the successive waves of colonisation of the terrestrial environment." Origins of Viruses (URL accessed on January 9, 2005)</ref>.

Without the presence of the giant and diurnal dinosaurs, mammals can increase in diversity and size. Some will later return back to the sea (whales, sirenians, seals) and others will evolve flight (bats). A group of small, nocturnal and arboreal, insect-eating mammals called the Archonta branches into what will be the primates, treeshrews, and bats. Primates have binocular vision and grasping digits, features that help them to jump from one tree branch to another. One example of a proto-primate is Plesiadapis which is extinct by 45 million years ago.

Human ancestors speciate from the ancestors of the chimpanzees. The latest common ancestor is Sahelanthropus tchadensis (Chad, Sahara, west of Rift Valley). The earliest in the human branch is Orrorin tugenensis (Millennium Man, Kenya). Chimpanzees and humans share 98% of DNA: biochemical similarities are so great that their hemoglobin molecules differ by only one amino acid. One group of chimps can have more genetic diversity than all of the six billion humans alive today, due to later population bottlenecking on the human lineage. Both chimpanzees and humans have a larynx that repositions during the first two years of life to a spot between the pharynx and the lungs, indicating that the common ancestors have this feature, a precursor of speech.

Gorillas die out on the South bank of the Congo River. North and South America become joined, allowing migration of animals. Modern horses, Equus first appear. Deinotherium (4 m tall), is a gigantic cousin of the elephant, with downward pointing tusks in the lower jaw.

The glyptodon, a giant armadillo the size of a Volkswagen Beetle, lives in southern Peru.

Humans in the Blombos cave in South Africa make tools from bones, show symbolic thinking by creating ochre paintings. They also collect and pierce holes through sea shells to make necklaces. Giant beavers (Castoroides ohioensis, Toronto, Canada) largest rodents, length up to 2.5 m, dies out 10,000 years ago.

Extinction of woolly mammoth. Domestication of dogs (first domesticated animal) from Gray Wolf subspecies (Canis lupus pallipes). All modern dogs today (5 main groups, about 400 breeds) belong to a single subspecies Canis lupus familiaris.

Holocene extinction event continues with the observed rate of extinction rising dramatically in the last 50 years. Most biologists believe <ref>The American Museum of Natural History National Survey Reveals Biodiversity Crisis (URL accessed on February 23, 2006)</ref> that we are at this moment at the beginning of a tremendously accelerated anthropogenic mass extinction. E.O. Wilson of Harvard, in The Future of Life (2002), estimates that at current rates of human destruction of the biosphere, one-half of all species of life will be extinct in 100 years.