'' consists of four cells. One hypothesis for the origin of multicellularity is that a group of function-specific cells aggregated into a slug-like mass called a
grex, which moved as a multicellular unit. This is essentially what
slime molds do. Another hypothesis is that a primitive cell underwent nucleus division, thereby becoming a
coenocyte. A membrane would then form around each nucleus (and the cellular space and organelles occupied in the space), thereby resulting in a group of connected cells in one organism (this mechanism is observable in
Drosophila). A third hypothesis is that as a unicellular organism divided, the daughter cells failed to separate, resulting in a conglomeration of identical cells in one organism, which could later develop specialized tissues. This is what plant and animal
embryos do as well as colonial
choanoflagellates. Because the first multicellular organisms were simple, soft organisms lacking bone, shell, or other hard body parts, they are not well preserved in the fossil record. One exception may be the
demosponge, which may have left a chemical signature in ancient rocks. The earliest fossils of multicellular organisms include the contested
Grypania spiralis and the fossils of the black shales of the
Palaeoproterozoic Francevillian Group Fossil B Formation in
Gabon (
Gabonionta). The
Doushantuo Formation has yielded 600 million year old microfossils with evidence of multicellular traits. Until recently,
phylogenetic reconstruction has been through
anatomical (particularly
embryological) similarities. This is inexact, as living multicellular organisms such as
animals and
plants are more than 500 million years removed from their single-cell ancestors. Such a passage of time allows both
divergent and
convergent evolution time to mimic similarities and accumulate differences between groups of modern and extinct ancestral species. Modern phylogenetics uses sophisticated techniques such as
alloenzymes,
satellite DNA and other molecular markers to describe traits that are shared between distantly related lineages. The evolution of multicellularity could have occurred in several different ways, some of which are described below:
The symbiotic theory This theory suggests that the first multicellular organisms occurred from
symbiosis (cooperation) of different species of single-cell organisms, each with different roles. Over time these organisms would become so dependent on each other that they would not be able to survive independently, eventually leading to the incorporation of their genomes into one multicellular organism. Each respective organism would become a separate lineage of differentiated cells within the newly created species. This kind of severely co-dependent symbiosis can be seen frequently, such as in the relationship between
clown fish and
Riterri sea anemones. In these cases, it is extremely doubtful whether either species would survive very long if the other became extinct. However, the problem with this theory is that it is still not known how each organism's DNA could be incorporated into one single
genome to constitute them as a single species. Although such symbiosis is theorized to have occurred (e.g.,
mitochondria and
chloroplasts in animal and plant cells—
endosymbiosis), it has happened only extremely rarely and, even then, the genomes of the endosymbionts have retained an element of distinction, separately replicating their DNA during
mitosis of the host species. For instance, the two or three symbiotic organisms forming the composite
lichen, although dependent on each other for survival, have to separately reproduce and then re-form to create one individual organism once more.
The cellularization (syncytial) theory This theory states that a single unicellular organism, with multiple
nuclei, could have developed
internal membrane partitions around each of its nuclei. Many protists such as the
ciliates or
slime molds can have several nuclei, lending support to this
hypothesis. However, the simple presence of multiple nuclei is not enough to support the theory. Multiple nuclei of ciliates are dissimilar and have clear differentiated functions. The
macronucleus serves the organism's needs, whereas the
micronucleus is used for sexual reproduction with exchange of genetic material. Slime molds
syncitia form from individual amoeboid cells, like syncitial tissues of some multicellular organisms, not the other way round. To be deemed valid, this theory needs a demonstrable example and mechanism of generation of a multicellular organism from a pre-existing syncytium.
The colonial theory The colonial theory of
Haeckel, 1874, proposes that the symbiosis of many organisms of the same species (unlike the
symbiotic theory, which suggests the symbiosis of different species) led to a multicellular organism. At least some – it is presumed land-evolved – multicellularity occurs by cells separating and then rejoining (e.g.,
cellular slime molds) whereas for the majority of multicellular types (those that evolved within aquatic environments), multicellularity occurs as a consequence of cells failing to separate following division. The mechanism of this latter colony formation can be as simple as incomplete
cytokinesis, though multicellularity is also typically considered to involve
cellular differentiation. The advantage of the Colonial Theory hypothesis is that it has been seen to occur independently in 16 different protoctistan phyla. For instance, during food shortages the amoeba
Dictyostelium groups together in a colony that moves as one to a new location. Some of these amoeba then slightly differentiate from each other. Other examples of colonial organisation in protista are
Volvocaceae, such as
Eudorina and
Volvox, the latter of which consists of up to 500–50,000 cells (depending on the species), only a fraction of which reproduce. For example, in one species 25–35 cells reproduce, 8 asexually and around 15–25 sexually. However, it can often be hard to separate colonial
protists from true multicellular organisms, as the two concepts are not distinct; colonial protists have been dubbed "pluricellular" rather than "multicellular".
GK-PID About 800 million years ago, a minor genetic change in a single molecule called
guanylate kinase protein-interaction domain (GK-PID) may have allowed organisms to go from a single cell organism to one of many cells.
The role of viruses Genes borrowed from
viruses and
mobile genetic elements (MGEs) have recently been identified as playing a crucial role in the differentiation of multicellular tissues and organs and even in sexual reproduction, in the fusion of egg cells and sperm. Such fused cells are also involved in metazoan membranes such as those that prevent chemicals from crossing the
placenta and the brain body separation. Two viral components have been identified. The first is
syncytin, which came from a virus. The second identified in 2002 is called
EFF-1, which helps form the skin of
Caenorhabditis elegans, part of a whole family of FF proteins. Felix Rey, of the Pasteur Institute in Paris, has constructed the 3D structure of the EFF-1 protein and shown it does the work of linking one cell to another, in viral infections. The fact that all known cell fusion molecules are viral in origin suggests that they have been vitally important to the inter-cellular communication systems that enabled multicellularity. Without the ability of cellular fusion, colonies could have formed, but anything even as complex as a sponge would not have been possible.
Oxygen availability hypothesis This theory suggests that the oxygen available in the atmosphere of early Earth could have been the limiting factor for the emergence of multicellular life. This hypothesis is based on the correlation between the emergence of multicellular life and the increase of oxygen levels during this time. This would have taken place after the
Great Oxidation Event but before the most recent rise in oxygen. Mills concludes that the amount of oxygen present during the
Ediacaran is not necessary for complex life and therefore is unlikely to have been the driving factor for the origin of multicellularity.
Snowball Earth hypothesis A
snowball Earth event is a geological event where the entire surface of the Earth is covered in snow and ice. Snowball events are thought to have happened several times throughout the Earth's history, and during the
Cryogenian, two snowball events happened in quick succession – the
Sturtian and
Marinoan glaciations. These glaciations could have been the catalyst for the evolution of complex multicellular life. The time between the Sturtian and Marinoan glaciations may have allowed for planktonic algae to dominate the seas, making way for rapid diversification of biota for both plant and animal lineages. Complex life quickly emerged and diversified in what is known as the
Cambrian explosion shortly after the Marinoan. Xiao
et al. suggest that between the period of time known as the "
Boring Billion" and the snowball Earth, simple life could have had time to innovate and evolve, which could later lead to the evolution of multicellularity.
Predation hypothesis The predation hypothesis suggests that to avoid being eaten by predators, simple single-celled organisms evolved multicellularity to make it harder to be consumed as prey. Herron et al. performed laboratory evolution experiments on the single-celled green alga,
Chlamydomonas reinhardtii, using paramecium as a predator. They found that in the presence of this predator,
C. reinhardtii does indeed evolve simple multicellular features. == Experimental evolution ==