DNA replications In the sense that DNA replication must occur if genetic material is to be provided for the
progeny of any cell, whether
somatic or
reproductive, the copying from DNA to DNA arguably is the fundamental step in information transfer. A complex group of proteins called the
replisome performs the replication of the information from the parent strand to the complementary daughter strand.
Transcription Transcription is the process by which the information contained in a section of DNA is replicated in the form of a newly assembled piece of
messenger RNA (mRNA). Enzymes facilitating the process include
RNA polymerase and
transcription factors. In
eukaryotic cells, the primary transcript is
pre-mRNA. Pre-mRNA must be
processed for translation to proceed. Processing includes the addition of a
5' cap and a
poly-A tail to the pre-mRNA chain, followed by
splicing.
Alternative splicing occurs when appropriate, increasing the diversity of the proteins that any single mRNA can produce. The product of the entire transcription process (that began with the production of the pre-mRNA chain) is a mature mRNA chain.
Translation The mature mRNA finds its way to a
ribosome, where it gets
translated. In
prokaryotic cells, which have no nuclear compartment, the processes of transcription and translation may be linked together without clear separation. In
eukaryotic cells, the site of transcription (the
cell nucleus) is usually separated from the site of translation (the
cytoplasm), so the mRNA must be transported out of the nucleus into the cytoplasm, where it can be bound by ribosomes. The ribosome reads the mRNA triplet
codons, usually beginning with an AUG (
adenine−
uracil−
guanine), or initiator
methionine codon downstream of the
ribosome binding site. Complexes of
initiation factors and
elongation factors bring
aminoacylated transfer RNAs (tRNAs) into the ribosome-mRNA complex, matching the codon in the mRNA to the anti-codon on the tRNA. Each tRNA bears the appropriate
amino acid residue to add to the
polypeptide chain being synthesised. As the amino acids get linked into the growing peptide chain, the chain begins folding into the correct conformation. Translation ends with a
stop codon which may be a UAA, UGA, or UAG triplet. The mRNA does not contain all the information for specifying the nature of the mature protein. The nascent polypeptide chain released from the ribosome commonly requires additional processing before the final product emerges. For one thing, the correct folding process is complex and vitally important. For most proteins it requires other
chaperone proteins to control the form of the product. Some proteins then excise internal segments from their own peptide chains, splicing the free ends that border the gap; in such processes the inside "discarded" sections are called
inteins. Other proteins must be split into multiple sections without splicing. Some polypeptide chains need to be cross-linked, and others must be attached to
cofactors such as
haem (heme) before they become functional. == Additional transfers of biological sequential information ==