Function
Pol III
The RPC25/RPC8-RPC17/RPC9 subcomplex binds the transcripts emerging from the exit pore, which facilitates elongation.
Interactions
RPC2 contributes to catatylic activity in the polymerase, and forms the active center of the polymerase along with the largest subunit. It is suggested that RPC helps to open and close the cleft.
RPC1 forms active center together with RPC2
forms a bridging helix that crosses the cleft near the active site, acts as a ratchet that moves the enlongating transcript through polIII
The of the polymerase moves the DNA by bridging helix, which allows transcription to proceed. This takes place by a ratcheting motion. It promotes translocation of polIII by allowing nucleotides to be added continuously
RPC6 recruits pol III to the preinitiation complex, and contributes to an initiation-competent configuration for pol III
RPC4 is needed for tRNA synthesis!!
The RPC53/RPC4-RPC37/RPC5 subcomplex functions to terminate transcription and reinitiate transcription, by providing a binding site for the terminator.
RPAC1 helps to open and close the cleft
RPC10 involved in transcription reinitiation and RNA cleavage during termination
Origin
Pols are ocomposed of mobile elements which move relative to each other, resulting in conformational between subcomplexse
RNA Polymerase III is part of the transcription machinery of eukaryotes, handling genes encoding for small structured RNAs: tRNAs, spliceosomal U6 snRNA and 5S rRNA. pol III is the largest yet structurally least characterized eukaryotic RNA polymerase.
Elongation is the process of adding nucleotides to a growing RNA strand. The elongation complex of RNA Polymerase III serves several function
A 2015 deposition to PDB by Hoffman et al used electron cryomicroscopy to elucidate the structure shown on this page, came from Saccharomyces cerevisiae.
Tihs
Structural highlights
