Selective factor 1 (also known as SL1) is a transcription factor that binds to the promoter of genes and recruits a preinitiation complex to which RNA polymerase I will bind to and begin the transcription of ribosomal RNA (rRNA). [1] [2]
SL1 was discovered by Robert Tjian and his colleagues in 1985 when they separated a HeLa cell extract into two functional fractions. [3] One factor has RNA polymerase I activity, but no ability to initiate accurate transcription of a human rRNA template. This transcription factor, SL1, showed species specificity. [4] That is, it could distinguish between the human and mouse rRNA promoter, [5] and added increasing amount of human template at the expense of the mice template. [6] Tijian and coworkers went on to show that by footprinting a partially purified polymerase 1 preparation could bind to the human rRNA promoter. In particular it causes a footprint over a region of the UCE called A site. [7] This binding is not due to polymerase I itself but to a transcription factor called upstream binding factor, UBF.
SLI functions in assembling the transcription preinitiation complex. It is also a major determinant of species-specificity in ribosomal RNA gene transcription. Research suggests that UBF and SL1 act synergistically to stimulate transcription. Recent investigation also suggests that SL1 is a target for cancer therapy. [8]
SL1 is composed of the TATA-binding protein and three TAF (TATA box-binding protein-associated factor) subunits ( TAF1A, TAF1B, and TAF1C). [9] It is therefore possible to inhibit SL1 activity with anti-TBP antibodies.
Selective factor 1 (also known as SL1) is a transcription factor that binds to the promoter of genes and recruits a preinitiation complex to which RNA polymerase I will bind to and begin the transcription of ribosomal RNA (rRNA). [1] [2]
SL1 was discovered by Robert Tjian and his colleagues in 1985 when they separated a HeLa cell extract into two functional fractions. [3] One factor has RNA polymerase I activity, but no ability to initiate accurate transcription of a human rRNA template. This transcription factor, SL1, showed species specificity. [4] That is, it could distinguish between the human and mouse rRNA promoter, [5] and added increasing amount of human template at the expense of the mice template. [6] Tijian and coworkers went on to show that by footprinting a partially purified polymerase 1 preparation could bind to the human rRNA promoter. In particular it causes a footprint over a region of the UCE called A site. [7] This binding is not due to polymerase I itself but to a transcription factor called upstream binding factor, UBF.
SLI functions in assembling the transcription preinitiation complex. It is also a major determinant of species-specificity in ribosomal RNA gene transcription. Research suggests that UBF and SL1 act synergistically to stimulate transcription. Recent investigation also suggests that SL1 is a target for cancer therapy. [8]
SL1 is composed of the TATA-binding protein and three TAF (TATA box-binding protein-associated factor) subunits ( TAF1A, TAF1B, and TAF1C). [9] It is therefore possible to inhibit SL1 activity with anti-TBP antibodies.