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A ribozyme, or RNA enzyme, is an RNA molecule that can catalyze a chemical reaction. Many natural ribozymes catalyze either their own cleavage or the cleavage of other
RNAs, but they have also been found to catalyze the aminotransferase activity of the ribosome. Investigators studying the origin of life have
produced ribozymes in the laboratory that are capable of catalyzing their own
synthesis under very specific conditions.
Before the discovery of ribozymes, only proteins were known to have catalytic
activity. In 1967, Carl Woese, Francis Crick, and Leslie
Orgel were the first to suggest that RNA could act as a catalyst based upon findings that it can form complex secondary structures. The first ribozyme was discovered in the
1980s by Thomas R. Cech, who was studying RNA splicing in the ciliated protozoan Tetrahymena
thermophila. This ribozyme was found in the intron of a RNA transcript and removed itself from the transcript.
Although ribozymes are quite rare in the cell, their roles are sometimes essential to life. For example, the functional part of the ribosome, the molecular
machine that translates RNA into proteins, is
fundamentally a ribozyme.
RNA can also act as a hereditary molecule, which encouraged Walter
Gilbert to propose that in the past, the cell used RNA as both
the genetic material and the structural and catalytic molecule , rather than dividing these functions between DNA and protein as they are today. This hypothesis became known as
the "RNA world hypothesis" of the origin of life.
If ribozymes were the first molecular machines used by early life, then today's remaining ribozymes -- such as the ribosome
machinery -- could be considered living fossils of a life based primarily
on nucleic acids.
A recent test-tube study of prion folding suggests that an RNA may catalyze the pathological protein conformation in the manner of a chaperone enzyme.
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