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The oncogene MYC is deregulated and overexpressed in a high variety of human
cancers and is considered an important driver in tumorigenesis. The MYC protein
binds to virtually all active promoters of genes which are also bound by the RNA
Polymerase II (RNAPII). This results in the assumption that MYC is a transcription
factor regulating gene expression. The effects of gene expression are weak and often
differ depending on the tumor entities or MYC levels. These observations could
argue that the oncogene MYC has additional functions independent of altering gene
expression. In relation to this, the high diversity of interaction partners might be
important. One of them is the RNAPII associated Factor I complex (PAF1c).
In this study, direct interaction between PAF1c and MYC was confirmed in an
in-vitro pulldown assay. ChIP sequencing analyses revealed that knockdown of PAF1c
components resulted in reduced MYC occupancy at active promoters. Depletion
or activation as well as overexpression of MYC led to reduced or enhanced global
occupancy of PAF1c in the body of active genes, arguing that MYC and PAF1c
bind cooperatively to chromatin. Upon PAF1c knockdown cell proliferation was
reduced and additionally resulted in an attenuation of activation or repression of
MYC-regulated genes. Interestingly, knockdown of PAF1c components caused an
accumulation in S-phase of cells bearing oncogenic MYC levels. Remarkably, enhanced
DNA damage, measured by elevated gH2AX and pKAP1 protein levels, was observed
in those cells and this DNA damage occurs specifically during DNA synthesis.
Strikingly, MYC is involved in double strand break repair in a PAF1c-dependent
manner at oncogenic MYC levels.
Collectively the data show that the transfer of PAF1c from MYC onto the RNAPII
couples the transcriptional elongation with double strand break repair to maintain
the genomic integrity in MYC-driven tumor cells.
Expression of the MYC oncoprotein, which binds the DNA at promoters of most transcribed genes, is controlled by growth factors in non-tumor cells, thus stimulating cell growth and proliferation.
Here in this thesis, it is shown that MYC interacts with SPT5, a subunit of the RNA polymerase II (Pol II) elongation factor DSIF. MYC recruits SPT5 to promoters of genes and is required for its association with Pol II. The transfer of SPT5 is mediated by CDK7 activity on TFIIE, which evicts it from Pol II and allows SPT5 to bind Pol II.
MYC is required for fast and processive transcription elongation, consistent with known functions of SPT5 in yeast. In addition, MYC increases the directionality of promoters by stimulating sense transcription and by suppressing the synthesis of antisense transcripts.
The results presented in this thesis suggest that MYC globally controls the productive assembly of Pol II with general elongation factors to form processive elongation complexes in response to growth-factor stimulation of non-tumour cells. However, MYC is found to be overexpressed in many tumours, and is required for their development and progression.
In this thesis it was found that, unexpectedly, such overexpression of MYC does not further enhance transcription but rather brings about squelching of SPT5. This reduces the processivity of Pol II on selected set of genes that are known to be repressed by MYC, leading to a decrease in growth-suppressive gene transcription and uncontrolled tumour growth