The human KRAS proto-oncogene contains a critical nuclease hypersensitive element (NHE) upstream of the major transcription initiation site. In this article, we demonstrate by primer-extension experiments, PAGE, chemical footprinting, CD, UV and FRET experiments that the G-rich strand of NHE (32R) folds into intra-molecular G-quadruplex structures. Fluorescence data show that 32R in 100 mM KCl melts with a biphasic profile, showing the formation of two distinct G-quadruplexes with Tm of ∼55°C (Q1) and ∼72°C (Q2). DMS-footprinting and CD suggest that Q1 can be a parallel and Q2 a mixed parallel/antiparallel G-quadruplex. When dsNHE (32R hybridized to its complementary) is incubated with a nuclear extract from Panc-1 cells, three DNA–protein complexes are observed by EMSA. The complex of slower mobility is competed by quadruplex 32R, but not by mutant oligonucleotides, which cannot form a quadruplex structure. Using paramagnetic beads coupled with 32R, we pulled down from the Panc-1 extract proteins with affinity for quadruplex 32R. One of these is the heterogeneous nuclear ribonucleoprotein A1, which was previously reported to unfold quadruplex DNA. Our study suggests a role of quadruplex DNA in KRAS transcription and provides the basis for the rationale design of molecular strategies to inhibit the expression of KRAS.
The promoter of the human KRAS proto-oncogene contains a structurally polymorphic nuclease hypersensitive element (NHE) whose purine strand forms a parallel G-quadruplex structure (called 32R). In a previous work we reported that quadruplex 32R is recognized by three nuclear proteins: PARP-1, Ku70 and hnRNP A1. In this study we describe the interaction of recombinant hnRNP A1 (A1) and its derivative Up1 with the KRAS G-quadruplex. Mobility-shift experiments show that A1/Up1 binds specifically, and also with a high affinity, to quadruplex 32R, while CD demonstrates that the proteins strongly reduce the intensity of the 260 nm-ellipticity—the hallmark for parallel G4-DNA—and unfold the G-quadruplex. Fluorescence resonance energy transfer melting experiments reveal that A1/Up1 completely abrogates the cooperative quadruplex-to-ssDNA transition that characterizes the KRAS quadruplex and facilitates the association between quadruplex 32R and its complementary polypyrimidine strand. When quadruplex 32R is stabilized by TMPyP4, A1/Up1 brings about only a partial destabilization of the G4-DNA structure. The possible role played by hnRNP A1 in the mechanism of KRAS transcription is discussed.
The murine KRAS promoter contains a G-rich nuclease hypersensitive element (GA-element) upstream of the transcription start site that is essential for transcription. Pulldown and chromatin immunoprecipitation assays demonstrate that this GA-element is bound by the Myc-associated zinc finger (MAZ) and poly(ADP-ribose) polymerase 1 (PARP-1) proteins. These proteins are crucial for transcription, because when they are knocked down by short hairpin RNA, transcription is downregulated. This is also the case when the poly(ADP-ribosyl)ation activity of PARP-1 is inhibited by 3,4-dihydro-5-[4-(1-piperidinyl) butoxyl]-1(2H) isoquinolinone. We found that MAZ specifically binds to the duplex and quadruplex conformations of the GA-element, whereas PARP-1 shows specificity only for the G-quadruplex. On the basis of fluorescence resonance energy transfer melting and polymerase stop assays we saw that MAZ stabilizes the KRAS quadruplex. When the capacity of folding in the GA-element is abrogated by specific G 3 T or G 3 A point mutations, KRAS transcription is down-regulated. Conversely, guanidine-modified phthalocyanines, which specifically interact with and stabilize the KRAS G-quadruplex, push the promoter activity up to more than double. Collectively, our data support a transcription mechanism for murine KRAS that involves MAZ, PARP-1 and duplex-quadruplex conformational changes in the promoter GA-element.Guanine-rich sequences have the potential to fold into intramolecular G-quadruplex (or G4-DNA) structures that are stabilized by planar arrays of four guanines paired by Hoogsteen hydrogen bonds (G-tetrad) (1). Quadruplex-forming sequences (QFS) 2 are present in prokaryotic and eukaryotic genomes, promoter regions, micro-and mini-satellite repeats, telomeres, rDNA, and the vertebrate immunoglobulin heavy chain switch regions (2). Recent bioinformatic search analyses have shown a surprisingly high presence in the human genome of QFS, on the order of 3-4 ϫ 10 5 (3, 4). The gene distribution of QFS is highly skewed because tumor suppressor genes have a very low level of QFS, whereas proto-oncogenes have a high level of such sequences (5). There seems to be a correlation between QFS and genomic instability; a low level of QFS in tumor suppressor genes is associated with genomic stability, and a high level is associated with genomic instability (5). Furthermore, the observation that QFS are often located in the region surrounding the transcription start sites of the genes and within cis-elements suggests that they may be involved in transcription regulation. This hypothesis has been formulated for a number of genes including CMYC, KRAS, C-MYB, VEGF, PDGFA, CKIT, and human insulin (6 -13). The best studied G-rich sequence folding into a G-quadruplex, whose function has been correlated with a mechanism of transcription regulation, is the one found in the promoter of the CMYC gene (6). Upstream of the P1 promoter, controlling about 80% of transcription, there is a QFS that can fold into a G-quadruplex. When this quadruplex is d...
Summary We identified UHRF1 as a binding factor for DNA interstrand crosslink (ICL) lesions through affinity purification of ICL-recognition activities. UHRF1 is recruited to DNA lesions in vivo and binds directly to ICL-containing DNA. UHRF1-deficient cells display increased sensitivity to a variety of DNA damages. We found that loss of UHRF1 led to retarded lesion processing and reduced recruitment of ICL repair nucleases to the site of DNA damage. UHRF1 interacts physically with both ERCC1 and MUS81, two nucleases involved in the repair of ICL lesions. Depletion of both UHRF1 and components of the Fanconi anemia pathway resulted in increased DNA damage sensitivity compared to defect of each mechanism alone. These results suggest that UHRF1 promotes recruitment of lesion-processing activities via its DNA damage recognition affinity and functions as a nuclease recruitment scaffold in parallel to the Fanconi anemia pathway.
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