Prashansa Agrawal

The Dynamic Character of the BCL2 Promoter i-Motif Provides a Mechanism for Modulation of Gene Expression by Compounds That Bind Selectively to the Alternative DNA Hairpin Structure

It is generally accepted that DNA predominantly exists in duplex form in cells. However, under torsional stress imposed by active transcription, DNA can assume nonduplex structures. The BCL2 promoter region forms two different secondary DNA structures on opposite strands called the G-quadruplex and the i-motif. The i-motif is a highly dynamic structure that exists in equilibrium with a flexible hairpin species. Here we identify a pregnanol derivative and a class of piperidine derivatives that differentially modulate gene expression by stabilizing either the i-motif or the flexible hairpin species. Stabilization of the i-motif structure results in significant upregulation of the BCL2 gene and associated protein expression; in contrast, stabilization of the flexible hairpin species lowers BCL2 levels. The BCL2 levels reduced by the hairpin-binding compound led to chemosensitization to etoposide in both in vitro and in vivo models. Furthermore, we show antagonism between the two classes of compounds in solution and in cells. For the first time, our results demonstrate the principle of small molecule targeting of i-motif structures in vitro and in vivo to modulate gene expression.

Solution structure of the major G-quadruplex formed in the human VEGF promoter in K+: insights into loop interactions of the parallel G-quadruplexes

Vascular endothelial growth factor (VEGF) proximal promoter region contains a poly G/C-rich element that is essential for basal and inducible VEGF expression. The guanine-rich strand on this tract has been shown to form the DNA G-quadruplex structure, whose stabilization by small molecules can suppress VEGF expression. We report here the nuclear magnetic resonance structure of the major intramolecular G-quadruplex formed in this region in K+ solution using the 22mer VEGF promoter sequence with G-to-T mutations of two loop residues. Our results have unambiguously demonstrated that the major G-quadruplex formed in the VEGF promoter in K+ solution is a parallel-stranded structure with a 1:4:1 loop-size arrangement. A unique capping structure was shown to form in this 1:4:1 G-quadruplex. Parallel-stranded G-quadruplexes are commonly found in the human promoter sequences. The nuclear magnetic resonance structure of the major VEGF G-quadruplex shows that the 4-nt middle loop plays a central role for the specific capping structures and in stabilizing the most favored folding pattern. It is thus suggested that each parallel G-quadruplex likely adopts unique capping and loop structures by the specific middle loops and flanking segments, which together determine the overall structure and specific recognition sites of small molecules or proteins. LAY SUMMARY: The human VEGF is a key regulator of angiogenesis and plays an important role in tumor survival, growth and metastasis. VEGF overexpression is frequently found in a wide range of human tumors; the VEGF pathway has become an attractive target for cancer therapeutics. DNA G-quadruplexes have been shown to form in the proximal promoter region of VEGF and are amenable to small molecule drug targeting for VEGF suppression. The detailed molecular structure of the major VEGF promoter G-quadruplex reported here will provide an important basis for structure-based rational development of small molecule drugs targeting the VEGF G-quadruplex for gene suppression.

The Major G-Quadruplex Formed in the Human BCL-2 Proximal Promoter Adopts a Parallel Structure with a 13-nt Loop in K+ Solution

The human BCL-2 gene contains a 39-bp GC-rich region upstream of the P1 promoter that has been shown to be critically involved in the regulation of BCL-2 gene expression. Inhibition of BCL-2 expression can decrease cellular proliferation and enhance the efficacy of chemotherapy. Here we report the major G-quadruplex formed in the Pu39 G-rich strand in this BCL-2 promoter region. The 1245G4 quadruplex adopts a parallel structure with one 13-nt and two 1-nt chain-reversal loops. The 1245G4 quadruplex involves four nonsuccessive G-runs, I, II, IV, V, unlike the previously reported bcl2 MidG4 quadruplex formed on the central four G-runs. The parallel 1245G4 quadruplex with the 13-nt loop, unexpectedly, appears to be more stable than the mixed parallel/antiparallel MidG4. Parallel-stranded structures with two 1-nt loops and one variable-length middle loop are found to be prevalent in the promoter G-quadruplexes; the variable middle loop is suggested to determine the specific overall structure and potential ligand recognition site. A limit of 7 nt in loop length is used in all quadruplex-predicting software. Thus, the formation and high stability of the 1245G4 quadruplex with a 13-nt loop is significant. The presence of two distinct interchangeable G-quadruplexes in the overlapping region of the BCL-2 promoter is intriguing, suggesting a novel mechanism for gene transcriptional regulation and ligand modulation.

The major G-quadruplex formed in the human platelet-derived growth factor receptor β promoter adopts a novel broken-strand structure in K+ solution.

Overexpression of platelet-derived growth factor receptor β (PDGFR-β) has been associated with cancers and vascular and fibrotic disorders. PDGFR-β has become an attractive target for the treatment of cancers and fibrotic disorders. DNA G-quadruplexes formed in the GC-rich nuclease hypersensitivity element of the human PDGFR-β gene promoter have been found to inhibit PDGFR-β transcriptional activity. Here we determined the major G-quadruplex formed in the PDGFR-β promoter. Instead of using four continuous runs with three or more guanines, this G-quadruplex adopts a novel folding with a broken G-strand to form a primarily parallel-stranded intramolecular structure with three 1 nucleotide (nt) double-chain-reversal loops and one additional lateral loop. The novel folding of the PDGFR-β promoter G-quadruplex emphasizes the robustness of parallel-stranded structural motifs with a 1 nt loop. Considering recent progress on G-quadruplexes formed in gene-promoter sequences, we suggest the 1 nt looped G(i)NG(j) motif may have been evolutionarily selected to serve as a stable foundation upon which the promoter G-quadruplexes can build. The novel folding of the PDGFR-β promoter G-quadruplex may be attractive for small-molecule drugs that specifically target this secondary structure and modulate PDGFR-β gene expression.

Insight into the Complexity of the i-Motif and G-Quadruplex DNA Structures Formed in the KRAS Promoter and Subsequent Drug-Induced Gene Repression

Activating KRAS mutations frequently occur in pancreatic, colorectal, and lung adenocarcinomas. While many attempts have been made to target oncogenic KRAS, no clinically useful therapies currently exist. Most efforts to target KRAS have focused on inhibiting the mutant protein; a less explored approach involves targeting KRAS at the transcriptional level. The promoter element of the KRAS gene contains a GC-rich nuclease hypersensitive site with three potential DNA secondary structure-forming regions. These are referred to as the Near-, Mid-, and Far-regions, on the basis of their proximity to the transcription start site. As a result of transcription-induced negative superhelicity, these regions can open up to form unique DNA secondary structures: G-quadruplexes on the G-rich strand and i-motifs on the C-rich strand. While the G-quadruplexes have been well characterized, the i-motifs have not been investigated as thoroughly. Here we show that the i-motif that forms in the C-rich Mid-region is the most stable and exists in a dynamic equilibrium with a hybrid i-motif/hairpin species and an unfolded hairpin species. The transcription factor heterogeneous nuclear ribonucleoprotein K (hnRNP K) was found to bind selectively to the i-motif species and to positively modulate KRAS transcription. Additionally, we identified a benzophenanthridine alkaloid that dissipates the hairpin species and destabilizes the interaction of hnRNP K with the Mid-region i-motif. This same compound stabilizes the three existing KRAS G-quadruplexes. The combined effect of the compound on the Mid-region i-motif and the G-quadruplexes leads to downregulation of KRAS gene expression. This dual i-motif/G-quadruplex-interactive compound presents a new mechanism to modulate gene expression.

Structure-Guided Synthesis and Mechanistic Studies Reveal Sweetspots on Naphthyl Salicyl Hydrazone Scaffold as Non-Nucleosidic Competitive, Reversible Inhibitors of Human Ribonucleotide Reductase

Ribonucleotide reductase (RR), an established cancer target, is usually inhibited by antimetabolites, which display multiple cross-reactive effects. Recently, we discovered a naphthyl salicyl acyl hydrazone-based inhibitor (NSAH or E-3a) of human RR (hRR) binding at the catalytic site (C-site) and inhibiting hRR reversibly. We herein report the synthesis and biochemical characterization of 25 distinct analogs. We designed each analog through docking to the C-site of hRR based on our 2.7 Å X-ray crystal structure (PDB ID: 5TUS). Broad tolerance to minor structural variations preserving inhibitory potency is observed. E-3f (82% yield) displayed an in vitro IC50 of 5.3 ± 1.8 μM against hRR, making it the most potent in this series. Kinetic assays reveal that E-3a, E-3c, E-3t, and E-3w bind and inhibit hRR through a reversible and competitive mode. Target selectivity toward the R1 subunit of hRR is established, providing a novel way of inhibition of this crucial enzyme.

Abstract 3089: A novel G-quadruplex formed in the PDGFR-β promoter that is selectively targeted by a small molecule to repress transcription

Abnormal expression of PDGFR-β protein contributes to several malignancies. PDGFR-β has become increasingly attractive therapeutic target in the treatments of certain cancers. A G-quadruplex-forming nuclease hypersensitive element (NHE) in the human PDGFR-β promoter has been found to form multiple G-quadruplexes from the overlapping sequences. This G-quadruplex-forming NHE has been shown to regulate approximately 60% of basal promoter activity. Targeting transcriptional control of PDGFR-β provides an attractive target for developing inhibitors for the PDGFR-β signaling pathway, in addition to molecular targeting of the PDGFR-β protein or its cognate ligand. We have previously determined the most stable G-quadruplex formed in the PDGFR-β NHE. Interestingly, the 3′-end G-quadruplex formed in the PDGFR-β promoter NHE appears to be selectively targeted by an ellipticine analog GSA1129, which has been shown to repress PDGFR-β activity in cancer cell lines, and GSA1129 appears to shift the dynamic equilibrium in the full-length sequence to favor this structure. Therefore, characterization of the 3′-end G-quadruplex structure is important for understanding its function and for rational design of small molecules targeting this element. The 3′-end PDGFR-β G-quadruplex appears to adopt an unusual parallel G-quadruplex structure containing an imperfect GGGA tetrad at the 3′-end, as shown by DMS footprinting and CD spectroscopy. We further investigated the stability and structure of the 3′-end G-quadruplex and its interactions with GSA1129 by mutational analysis combined with NMR spectroscopy. The 3′-end G-quadruplex can be stabilized by an A-to-G mutation at position 18. However, the truncated wild-type and mutated 18-mer (Pu18) sequences appear to form predominantly dimer structure as shown by NMR. Using a 19-mer sequence Pu19 with the A-to-G mutation (Pu19A18G), a stable monomeric G-quadruplex can be formed in potassium solution, adopting a parallel-stranded structure as shown by NMR. In the wild-type 3’-end NHE sequences, the formation of a monomeric G-quadruplex in potassium can only be observed in a 20-mer Pu20 sequence with additional 3’ G20; the assignment of Pu20 G-quadruplex using site-specific 15N-G-labeled DNA sequences indicated a novel parallel-stranded G-quadruplex structure using G20 instead of A18 in the 3’-end-tetrad. The Pu20 G-quadruplex appears to have high thermo-stability as shown by CD studies; however, its specific formation can only be achieved at low potassium salt. GSA1129 can bind Pu20 and increase the 3′-end G-quadruplex stability by nearly 20 degrees. This study highlighted the dynamic nature of the 3′-end PDGFR-β G-quadruplex and the importance of identifying the proper sequence for the biologically relevant G-quadruplex structure formation. Significantly, the dynamic nature of the 3′-end G-quadruplex may make it an attractive target for drug regulation. Citation Format: Buket Onel, Prashansa Agrawal, Megan Carver, Robert Brown, Laurence Hurley, Danzhou Yang. A novel G-quadruplex formed in the PDGFR-β promoter that is selectively targeted by a small molecule to repress transcription. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 3089.

A metastable contact and structural disorder in the estrogen receptor transactivation domain

The N-terminal transactivation domain (NTD) of estrogen receptor alpha, a well-known member of the family of intrinsically disordered proteins (IDPs), mediates the receptor’s transactivation function to regulate gene expression. However, an accurate molecular dissection of NTD’s structure-function relationships remains elusive. Here, using small-angle X-ray scattering (SAXS), nuclear magnetic resonance, circular dichroism, and hydrogen exchange mass spectrometry, we show that NTD adopts an unexpectedly compact, mostly disordered conformation that undergoes structural expansion upon chemical denaturation. By combining SAXS and hydroxyl radical footprinting measurements, we derive ensemble-structures that represent the natively compact and disordered NTD. The resulting contact map for the ensemble reveals that the NTD features metastable regional and long-range contacts, including specific interactions between residues I33 and S118 that pervade the ensemble. Mutation at S118, a known regulatory site via phosphorylation, promotes conformational changes and increases coactivator binding, confirming its important structural contributions. These findings extend our understanding of IDPs’ structure and function, and how specific metastable and/or transient structural interactions within an IDP can mediate critical regulatory functions of disordered proteins.

Abstract 3090: Molecular structure of the major G-quadruplex formed in the PDGFR-β promoter nuclease hypersensitivity element and its binding with small molecules

Proceedings: AACR 107th Annual Meeting 2016; April 16-20, 2016; New Orleans, LA Overexpression of platelet-derived growth factor receptor β (PDGFR-β) is associated with multiple cancers, making PDGFR-β an attractive target for anticancer drugs. Few strategies other than molecular targeting of the PDGFR-β protein or its cognate ligand have been reported for developing inhibitors for the PDGFR-β signaling pathway. DNA G-quadruplexes (G4s) formed in the GC-rich nuclease hypersensitivity element of the human PDGFR-β gene promoter have been found to inhibit PDGFR-β transcriptional activity, and stabilization of these G4s by small-molecule compounds could serve as a mechanism for cancer therapeutics. We have shown that the major G4 formed in the PDGFR-β promoter is from the central four G-runs, adopting an intramolecular parallel-stranded structure with a broken G-strand and contains three 1-nucleotide (nt) chain-reversal loops and one lateral loop. The novel folding of the PDGFR-β G4 highlights the inherent stability of the 1-nt loops in parallel-stranded G4 structures. Elucidating the structure of the major PDGFR-β promoter G4 is important for designing small-molecule drugs to specifically target this structure to inhibit gene transcription. Using nuclear magnetic resonance (NMR) spectroscopy, we have determined the potassium solution structure of this major G4 formed in the PDGFR-β promoter. Our structure showed a unique 3’ capping structure involving three guanine nucleotides in the lateral loop. This novel capping structure is determined by the specific loop sequence as well as the broken-stranded PDGFR-β G4 folding pattern. The unique 3’ capping structure could be specifically recognized by proteins and small molecule ligands. Unrestrained molecular dynamic calculations showed that this major PDGFR-β G4 and its 3’ capping structure are stable in aqueous environment on the ns time-scale. We also investigated the binding of small-molecules to the PDGFR-β G4 using a combination of NMR, circular dichroism (CD), and fluorescence based methods to identify compounds that can selectively bind the PDGFR-β G4 over other classic parallel-stranded G-quadruplexes, such as the c-MYC promoter G4. Our study demonstrates the structural diversity in promoter G4s which may enable specific recognition and the modulation of gene expression by small-molecule drugs. Citation Format: Clement Lin, Prashansa Agrawal, Yuwei Chen, Salil Kalarn, Nanjie Deng, Laurence Hurley, Danzhou Yang. Molecular structure of the major G-quadruplex formed in the PDGFR-β promoter nuclease hypersensitivity element and its binding with small molecules. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 3090.

Abstract 5134: G-Quadruplex structure formation in the proximal promoter region of the human vascular endothelial growth factor gene

Proceedings: AACR 102nd Annual Meeting 2011‐‐ Apr 2‐6, 2011; Orlando, FL The human vascular endothelial growth factor gene, VEGF, is a key regulator of angiogenesis. It plays an important role in tumor survival, growth and metastasis. It is over-expressed in many types of human cancers including glioma and renal cell carcinoma, ovarian and pancreatic cell carcinomas. The VEGF proximal promoter region contains a poly G/poly C rich tract that is essential for basal and inducible VEGF expression. The guanine-rich (G-rich) strand on this tract is shown to form a specific secondary structure, the G-quadruplex. Here we have elucidated the solution structure of the major intramolecular G-quadruplex formed on the G-rich strand of this region in K+ solution by proton Nuclear Magnetic Resonance (NMR) spectroscopy followed by the structural calculation of the G-quadruplex using Distance Geometry Simulated Annealing (DGSA) module of XPLOR-NIH software. It is inferred that this strand adopts a well-defined parallel-stranded G-quadruplex structure, which contains three G-tetrads stabilized by Hoogsteen hydrogen bonding, as well as three double-chain reversal loops containing 1:4:1 bases, a feature important for the formation of the most thermodynamically stable conformation. The size of the 4-base loop plays a critical role in determining the most favored folded pattern of a G-quadruplex. These 4-base loop residues interact with the residues of the 3’ flanking region of VEGF sequence; also, the 1-base double-chain reversal loop on two edges of the tetrad are very stable, which overall contribute in stabilizing the 1:4:1 conformer. We have found that the two cytosines in this central 4-base loop are involved in hydrogen bonding with the 3’ terminal end residues of VEGF, which is a salient feature as this interaction is sequence-specific and differs from that in other parallel-stranded structures, e.g. c-myc, significantly. These results are also supported by the DMS footprinting results by Guo et al. (2008) which show that the guanines involved in the tetrad formation in this major G-quadruplex loop isomer 1:4:1 are well-protected against DMS methylation. Therefore, the knowledge about the secondary structure of this non B-DNA conformation of the VEGF promoter region is essential for using the G- quadruplex as a target for anticancer drugs, which could be a novel approach to anti-angiogenesis drug discovery in cancer therapy. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 102nd Annual Meeting of the American Association for Cancer Research; 2011 Apr 2-6; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2011;71(8 Suppl):Abstract nr 5134. doi:10.1158/1538-7445.AM2011-5134