Terminaatio ja antiterminaatiofaktorit prokaryoottisessa solussa , Q-proteiini - (Katsaus bakteerin puolelle)

Antitermination factors

Antitermination is the prokaryotic cell's aid to fix premature termination of RNA synthesis during the transcription of RNA. It occurs when the RNA polymerase ignores the termination signal,and continues elongating its transcript until a second signal is reached and it provides a mechanism whereby one or more genes at the end of an operon can be switched either on or off, depending on the polymerase either recognizing or not recognizing the termination signal.

Antitermination is used by some phages to regulate progression from one stage of gene expression to the next. The lambda gene N, codes for an antitermination protein (pN) that is necessary to allow RNA polymerase to read through the terminators located at the ends of the immediate early genes. Another antitermination protein, pQ, is required later in phage infection. pN and pQ act on RNA polymerase as it passes specific sites. These sites are located at different relative positions in their respective transcription units.

UUUUUUU

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3125153/

https://www.ncbi.nlm.nih.gov/pubmed/10230402/

 In bacteria, an intrinsic transcription termination signal appears in RNA as a hairpin followed by approximately eight uridines (U stretch) at the 3' terminus. This signal leads to rapid dissociation of the ternary elongation complex (TEC) into RNA, DNA, and an RNA polymerase. We demonstrate that the hairpin inactivates and then destabilizes TEC by weakening interactions in the RNA-DNA hybrid-binding site and the RNA-binding site that hold TEC together. Formation of the hairpin is restricted to the moment when TEC reaches the point of termination and depends upon melting of four to five hybrid base pairs that follow the hairpin's stem. The U stretch-induced pausing at the point of termination is crucial, providing additional time for hairpin formation. These results explain the mechanism of termination and aid in understanding of how cellular factors modulate this process.