Project description:To understand the mechanisms controlling platelet-derived growth factor receptor beta (PDGFR-beta) expression in malignancies, we have cloned and characterized the first functional promoter of the human PDGFR-beta gene, which has been confirmed by luciferase reporter gene assays. The transcription initiation sites were mapped by primer extension. Promoter deletion experiments demonstrate that the proximal, highly GC-rich region (positions -165 to -139) of the human PDGFR-beta promoter is crucial for basal promoter activity. This region is sensitive to S1 nuclease and likely to assume a non-B-form DNA secondary structure within the supercoiled plasmid. The G-rich strand in this region contains a series of runs of three or more guanines that can form multiple different G-quadruplex structures, which have been subsequently assessed by circular dichroism. A Taq polymerase stop assay has shown that three different G-quadruplex-interactive drugs can each selectively stabilize different G-quadruplex structures of the human PDGFR-beta promoter. However, in transfection experiments, only telomestatin significantly reduced the human PDGFR-beta basal promoter activity relative to the control. Furthermore, the PDGFR-beta mRNA level in Daoy cells was significantly decreased after treatment with 1 muM telomestatin for 24 h. Therefore, we propose that ligand-mediated stabilization of specific G-quadruplex structures in the human PDGFR-beta promoter can modulate its transcription.

Project description:The G-quadruplexes (G4s) formed in the PDGFR-β gene promoter are transcriptional modulators and amenable to small-molecule targeting. Berberine (BER), a clinically important natural isoquinoline alkaloid, has gained increasing attention due to its potential as anticancer drug. We previously showed that the PDGFR-β gene promoter forms a unique vacancy G4 (vG4) that can be filled in and stabilized by guanine metabolites, such as dGMP. Herein, we report the high-resolution NMR structure of a ternary complex of berberine bound to the dGMP-fill-in PDGFR-β vG4 in potassium solution. This is the first small-molecule complex structure of a fill-in vG4. This ternary complex has a 2:1:1 binding stoichiometry with a berberine molecule bound at each the 5'- and 3'-end of the 5'-dGMP-fill-in PDGFR-β vG4. Each berberine recruits the adjacent adenine residue from the 5'- or 3'-flanking sequence to form a "quasi-triad plane" that covers the external G-tetrad of the fill-in vG4, respectively. Significantly, berberine covers and stabilizes the fill-in dGMP. The binding of berberine involves both π-stacking and electrostatic interactions, and the fill-in dGMP is covered and well-protected by berberine. The NMR structure can guide rational design of berberine analogues that target the PDGFR-β vG4 or dGMP-fill-in vG4. Moreover, our structure provides a molecular basis for designing small-molecule guanine conjugates to target vG4s.

Project description:Aberrant expression of PDGFR-? is associated with a number of diseases. The G-quadruplexes (G4s) formed in PDGFR-? gene promoter are transcriptional modulators and amenable to small molecule targeting. The major G4 formed in the PDGFR-? gene promoter was previously shown to have a broken G-strand. Herein, we report that the PDGFR-? gene promoter sequence forms a vacancy G-quadruplex (vG4) which can be filled in and stabilized by physiologically relevant guanine metabolites, such as dGMP, GMP, and cGMP, as well as guanine-derivative drugs. We determined the NMR structure of the dGMP-fill-in PDGFR-? vG4 in K+ solution. This is the first structure of a guanine-metabolite-fill-in vG4 based on a human gene promoter sequence. Our structure and systematic analysis elucidate the contributions of Hoogsten hydrogen bonds, sugar, and phosphate moieties to the specific G-vacancy fill-in. Intriguingly, an equilibrium of 3'- and 5'-end vG4s is present in the PDGFR-? promoter sequence, and dGMP favors the 5'-end fill-in. Guanine metabolites and drugs were tested and showed a conserved selectivity for the 5'-vacancy, except for cGMP. cGMP binds both the 3'- and 5'-end vG4s and forms two fill-in G4s with similar population. Significantly, guanine metabolites are involved in many physiological and pathological processes in human cells; thus, our results provide a structural basis to understand their potential regulatory functions by interaction with promoter vG4s. Moreover, the NMR structure can guide rational design of ligands that target the PDGFR-? vG4.

Project description:Guanine (G)-oxidation to 8-oxo-7,8-dihydroguanine (OG) by reactive oxygen species in genomic DNA has been implicated with various human diseases. G-quadruplex (G4)-forming sequences in gene promoters are highly susceptible to G-oxidation, which can subsequently cause gene activation. However, the underlying G4 structural changes that result from OG modifications remain poorly understood. Herein, we investigate the effect of G-oxidation on the BLM gene promoter G4. For the first time, we show that OG can induce a G-vacancy-containing G4 (vG4), which can be filled in and stabilized by guanine metabolites and derivatives. We determined the NMR solution structure of the cGMP-fill-in oxidized BLM promoter vG4. This is the first complex structure of an OG-induced vG4 from a human gene promoter sequence with a filled-in guanine metabolite. The high-resolution structure elucidates the structural features of the specific 5'-end cGMP-fill-in for the OG-induced vG4. Interestingly, the OG is removed from the G-core and becomes part of the 3'-end capping structure. A series of guanine metabolites and derivatives are evaluated for fill-in activity to the oxidation-induced vG4. Significantly, cellular guanine metabolites, such as cGMP and GTP, can bind and stabilize the OG-induced vG4, suggesting their potential regulatory role in response to oxidative damage in physiological and pathological processes. Our work thus provides exciting insights into how oxidative damage and cellular metabolites may work together through a G4-based epigenetic feature for gene regulation. Furthermore, the NMR structure can guide the rational design of small-molecule inhibitors that specifically target the oxidation-induced vG4s.

Project description:Single-stranded DNA or RNA sequences rich in guanine (G) can adopt non-canonical structures known as G-quadruplexes (G4). Mitochondrial DNA (mtDNA) sequences that are predicted to form G4 are enriched on the heavy-strand and have been associated with formation of deletion breakpoints. Increasing evidence supports the ability of mtDNA to form G4 in cancer cells; however, the functional roles of G4 structures in regulating mitochondrial nucleic acid homeostasis in non-cancerous cells remain unclear. Here, we demonstrate by live cell imaging that the G4-ligand RHPS4 localizes primarily to mitochondria at low doses. We find that low doses of RHPS4 do not induce a nuclear DNA damage response but do cause an acute inhibition of mitochondrial transcript elongation, leading to respiratory complex depletion. We also observe that RHPS4 interferes with mtDNA levels or synthesis both in cells and isolated mitochondria. Importantly, a mtDNA variant that increases G4 stability and anti-parallel G4-forming character shows a stronger respiratory defect in response to RHPS4, supporting the conclusion that mitochondrial sensitivity to RHPS4 is G4-mediated. Taken together, our results indicate a direct role for G4 perturbation in mitochondrial genome replication, transcription processivity, and respiratory function in normal cells.

Project description:Cholangiocarcinomas (CCAs) are highly desmoplastic neoplasms with a tumour microenvironment plentiful in myofibroblasts (MFBs). MFB-derived PDGF-BB survival signalling is a mediator of CCA cell resistance to apoptotic stimuli. This raises the concept that targeting PDGFR-?, a cognate receptor of PDGF-BB, represents a potential strategy for the treatment of human CCA.Herein, we examine a role for inhibiting PDGFR-? in restoring CCA cell sensitivity to apoptotic stimuli in vitro and in vivo.We employed human CCA samples from 41 patients (19 intrahepatic and 22 extrahepatic CCA samples), the human CCA cell lines KMCH-1 and HUCCT-1 as well as shPDGFR-?-KMCH-1 and human myofibroblastic LX-2 cells for these studies. In vivo-experiments were conducted using a syngeneic rat orthotopic CCA model.Of several MFB-derived growth factors profiled, PDGF-BB and CTGF were most abundantly expressed; however, only PDGF-BB attenuated tumour necrosis factor-related apoptosis-inducing ligand (TRAIL) cytotoxicity. Co-culturing CCA cells with PDGF-BB-secreting MFBs significantly decreased TRAIL-induced CCA cell apoptosis when compared with monoculture conditions; this cytoprotective effect was abrogated in the presence of the tyrosine kinase inhibitors imatinib mesylate or linifanib, which inhibit PDGFR-?. Consistent with these findings, MFB-imparted cytoprotection also was abolished when PDGFR-? was knocked down as demonstrated in shPDGFR-?-KMCH-1 cells. Finally, administration of imatinib mesylate increased CCA cell apoptosis and reduced tumour growth in a rodent in vivo-CCA model that mimics the human disease.Targeting PDGFR-? sensitizes CCA cells to apoptotic stimuli and appears to be therapeutic in vivo.

Project description:Cancer is a multifactorial disease driven by a combination of genetic and environmental factors. Many cancer driver mutations have been characterised in protein-coding regions of the genome. However, mutations in noncoding regions associated with cancer have been less investigated. G-quadruplex (G4) nucleic acids are four-stranded secondary structures formed in guanine-rich sequences and prevalent in the regulatory regions. In this study, we used published whole cancer genome sequence data to find mutations in cancer patients that overlap potential RNA G4-forming sequences in 5' UTRs. Using RNAfold, we assessed the effect of these mutations on the thermodynamic stability of predicted RNA G4s in the context of full-length 5' UTRs. Of the 217 identified mutations, we found that 33 are predicted to destabilise and 21 predicted to stabilise potential RNA G4s. We experimentally validated the effect of destabilising mutations in the 5' UTRs of BCL2 and CXCL14 and one stabilising mutation in the 5' UTR of TAOK2. These mutations resulted in an increase or a decrease in translation of these mRNAs, respectively. These findings suggest that mutations that modulate the G4 stability in the noncoding regions could act as cancer driver mutations, which present an opportunity for early cancer diagnosis using individual sequencing information.

Project description:Promoters process signals through recruitment of transcription factors and RNA polymerase, and dynamic changes in promoter activity constitute a major noise source in gene expression. However, it is barely understood how complex promoter architectures determine key features of promoter dynamics. Here, we employ prototypical promoters of yeast ribosomal protein genes as well as simplified versions thereof to analyze the relations among promoter design, complexity, and function. These promoters combine the action of a general regulatory factor with that of specific transcription factors, a common motif of many eukaryotic promoters. By comprehensively analyzing stationary and dynamic promoter properties, this model-based approach enables us to pinpoint the structural characteristics underlying the observed behavior. Functional tradeoffs impose constraints on the promoter architecture of ribosomal protein genes. We find that a stable scaffold in the natural design results in low transcriptional noise and strong co-regulation of target genes in the presence of gene silencing. This configuration also exhibits superior shut-off properties, and it can serve as a tunable switch in living cells. Model validation with independent experimental data suggests that the models are sufficiently realistic. When combined, our results offer a mechanistic explanation for why specific factors are associated with low protein noise in vivo. Many of these findings hold for a broad range of model parameters and likely apply to other eukaryotic promoters of similar structure.

Project description:PDGF-BB/PDGFR-ββ signaling plays very crucial roles in the process of many diseases such as liver fibrosis. However, drug candidates with selective affinities for PDGF-B/PDGFR-β remain deficient. Here, we identified a natural cyclopeptide termed destruxin A5 that effectively inhibits PDGF-BB-induced PDGFR-β signaling. Interestingly and importantly, the inhibitory mechanism is distinct from the mechanism of tyrosine kinase inhibitors because destruxin A5 does not have the ability to bind to the ATP-binding pocket of PDGFR-β. Using Biacore T200 technology, thermal shift technology, microscale thermophoresis technology and computational analysis, we confirmed that destruxin A5 selectively targets the PDGF-B/PDGFR-β interaction interface to block this signaling. Additionally, the inhibitory effect of destruxin A5 on PDGF-BB/PDGFR-ββ signaling was verified using in vitro, ex vivo and in vivo models, in which the extent of liver fibrosis was effectively alleviated by destruxin A5. In summary, destruxin A5 may represent an efficacious and more selective inhibitor of PDGF-BB/PDGFR-ββ signaling.

Project description:Vector-based systems comprised of exogenous nucleic acid sequences remain the standard for ectopic expression of a particular gene. Such systems offer robust overexpression, but have inherent drawbacks such as the tedious process of construction, excluding sequences (e.g. introns and untranslated regions) important for gene function and potential insertional mutagenesis of host genome associated with the use of viral vectors. We and others have recently reported that short double-stranded RNAs (dsRNAs) can induce endogenous gene expression by targeting promoter sequences in a phenomenon referred to as RNA activation (RNAa) and such dsRNAs are termed small activating RNAs (saRNAs). To date, RNAa has been successfully utilized to induce the expression of different genes such as tumor suppressor genes. Here, we describe a detailed protocol for target selection and dsRNA design with associated experiments to facilitate RNAa in cultured cells. This technique may be applied to selectively activate endogenous gene expression for studying gene function, interrogating molecular pathways and reprogramming cell fate.