First universal common ancestor

Long before compartmentalized biology like FUCA appeared, life is hypothesized to have emerged through the organization of a pre-cellular era in the RNA world. In this era, self-replicating RNA molecules would have both stored genetic information and catalyzed chemical reactions. Translation machinery and the genetic code is universally present in all known cells and viruses, indicating a single origin for biological systems (monophyly). FUCA is thought to have been the first organism capable of biological translation, using RNA molecules to convert information into peptides and produce proteins. This first translation system is thought to have formed at the same time as an error-prone early genetic code. FUCA would be the first biological system to have a genetic code that dictates specific protein assembly. The development of FUCA would have been a gradual process initially without the genetic code. FUCA is hypothesized to have arisen from the ribosome, a complex made of RNA and proteins that evolved from a more primitive ribonucleoprotein machinery. FUCA appeared when the early peptidyl transferase center first emerged and when RNA world replicators could bond amino acids into short chained oligopeptides. The first genes of FUCA most likely encoded ribosomal components, primitive tRNA-aminoacyl transferases, and other proteins that helped stabilize and maintain biological translation. These random peptides may have bound back to the single strand nucleic acid polymers which increased their stability and the robustness of the system, binding other stabilizing molecules. When FUCA matured, its genetic code was then completely established. It has been proposed that FUCA was composed by a population of open-systems, exchanging components and information with the environment, and a population of self-replicating ribonucleoproteins. The progenote era began when these interaction systems arrived. These systems reached maturity when self-organization processes resulted in the emergence of a genetic code. This genetic code was, for the first time, able to organize an ordered interaction between nucleic acids and proteins through the formation of a biological language. This caused pre-cellular open systems to start to accumulate information and self-organizing, producing the first genomes by the assembling biochemical pathways. The pathways probably appeared in different progenote populations that independently evolved. Viruses might have evolved after FUCA but before LUCA according to the reduction hypothesis, where giant viruses evolved from primordial cells that became parasitic. == Progenotes ==

Progenotes (also called ribocytes or ribocells) are open or semi-open biological systems capable of intensely exchanging genetic information, before the existence of cells and LUCA. The term progenote was coined by Carl Woese in 1977, The meaning of progenote changed over time, when in the 1980s, Doolittle and Darnell used the term to refer to the single ancestor of all three domains of life, now referred to as the last universal common ancestor (LUCA).'''''' The terms ribocyte and ribocell refer to progenotes as early forms of ribosomes (protoribosomes), hypothetical primitive cellular organisms with self-replicating RNA In Carl Woese's Darwinian threshold period of cellular evolution, progenotes are also thought to have had RNA rather than DNA as informational molecule. Ribosomal RNA is thought to have emerged before cells or viruses, during the time when progenotes existed. FUCA is thought to have organized the transition from initial biological systems to mature progenotes. Because ribocytes used RNA to store their genetic information, == See also ==