Chandraiah Lagisetti

Sudemycins, novel small molecule analogues of FR901464, induce alternative gene splicing

Two unrelated bacterial natural products, FR901464 and pladienolide B, have previously been shown to have significant antitumor activity in vivo. These compounds target the SF3b subunit of the spliceosome, with a derivative of pladienolide (E7107) entering clinical trials for cancer. However, due to the structural complexity of these molecules, their research and development has been significantly constrained. We have generated a set of novel analogues (Sudemycins) that possess the pharmacophore that is common to FR901464 and pladienolide, via a flexible enantioselective route, which allows for the production of gram quantities of drug. These compounds demonstrate cytotoxicity toward human tumor cell lines in culture and exhibit antitumor activity in a xenograft model. Here, we present evidence that Sudemycins are potent modulators of alternative splicing in human cells, both of endogenous genes and from minigene constructs. Furthermore, levels of alternative splicing are increased in tumor cells relative to normal cells, and these modifications can be observed in human tumor xenografts in vivo following exposure of animals to the drug. In addition, the change in the splicing pattern observed with the Sudemycins are similar to that observed with Spliceostatin A, a molecule known to interact with the SF3b subunit of the spliceosome. Hence, we conclude that Sudemycins can regulate the production of alternatively spliced RNA transcripts and these alterations are more prevalent in tumors, as compared to normal cells, following drug exposure. These studies suggest that modulation of alternative splicing may play a role in the antitumor activity of this class of agents.

Synthetic mRNA splicing modulator compounds with in vivo antitumor activity.

We report our progress on the development of new synthetic anticancer lead compounds that modulate the splicing of mRNA. We also report the synthesis and evaluation of new biologically active ester and carbamate analogues. Further, we describe initial animal studies demonstrating the antitumor efficacy of compound 5 in vivo. Additionally, we report the enantioselective and diastereospecific synthesis of a new 1,3-dioxane series of active analogues. We confirm that compound 5 inhibits the splicing of mRNA in cell-free nuclear extracts and in a cell-based dual-reporter mRNA splicing assay. In summary, we have developed totally synthetic novel spliceosome modulators as therapeutic lead compounds for a number of highly aggressive cancers. Future efforts will be directed toward the more complete optimization of these compounds as potential human therapeutics.

Antitumor compounds based on a natural product consensus pharmacophore.

We report the design and highly enantioselective synthesis of a potent analogue of the spliceosome inhibitor FR901464, based on a non-natural product scaffold. The design of this compound was facilitated by a pharmacophore hypothesis that assumed key interaction types that are common to FR901464 and an otherwise unrelated natural product (pladienolide). The synthesis allows for the preparation of numerous novel analogues. We present results on the in vitro activity for this compound against several tumor cell lines.

Sudemycin E influences alternative splicing and changes chromatin modifications

Sudemycin E is an analog of the pre-messenger RNA splicing modulator FR901464 and its derivative spliceostatin A. Sudemycin E causes the death of cancer cells through an unknown mechanism. We found that similar to spliceostatin A, sudemycin E binds to the U2 small nuclear ribonucleoprotein (snRNP) component SF3B1. Native chromatin immunoprecipitations showed that U2 snRNPs physically interact with nucleosomes. Sudemycin E induces a dissociation of the U2 snRNPs and decreases their interaction with nucleosomes. To determine the effect on gene expression, we performed genome-wide array analysis. Sudemycin E first causes a rapid change in alternative pre-messenger RNA splicing, which is later followed by changes in overall gene expression and arrest in the G2 phase of the cell cycle. The changes in alternative exon usage correlate with a loss of the H3K36me3 modification in chromatin encoding these exons. We propose that sudemycin E interferes with the ability of U2 snRNP to maintain an H3K36me3 modification in actively transcribed genes. Thus, in addition to the reversible changes in alternative splicing, sudemycin E causes changes in chromatin modifications that result in chromatin condensation, which is a likely contributing factor to cancer cell death.

Pre-mRNA splicing-modulatory pharmacophores: The total synthesis of herboxidiene, a pladienolide-herboxidiene hybrid analog and related derivatives

Herboxidiene is a natural product that has previously been shown to exhibit antitumor activity by targeting the spliceosome. This activity makes herboxidiene a valuable starting point for the development of anticancer drugs. Here, we report an improved enantioselective synthesis of herboxidiene and the first report of its biologically active totally synthetic analog: 6-norherboxidiene. The synthesis of the tetrahydropyran moiety utilizes the novel application of inverse electron-demand Diels-Alder chemistry and the Ferrier-type rearrangement as key steps. We report, for the first time, cytotoxicity IC50s for synthetic herboxidiene and analogs in human tumor cell lines. We have also demonstrated that synthetic herboxidiene and its analogs can potently modulate the alternate splicing of MDM-2 pre-mRNA.

Optimization of Antitumor Modulators of Pre-mRNA Splicing

The spliceosome regulates pre-mRNA splicing, which is a critical process in normal mammalian cells. Recently, recurrent mutations in numerous spliceosomal proteins have been associated with a number of cancers. Previously, natural product antitumor agents have been shown to interact with one of the proteins that is subject to recurrent mutations (SF3B1). We report the optimization of a class of tumor-selective spliceosome modulators that demonstrate significant in vivo antitumor activity. This optimization culminated in the discovery of sudemycin D6, which shows potent cytotoxic activity in the melanoma line SK-MEL-2 (IC50 = 39 nM) and other tumor cell lines, including JeKo-1 (IC50 = 22 nM), HeLa (IC50 = 50 nM), and SK-N-AS (IC50 = 81 nM). We also report improved processes for the synthesis of these compounds. Our work supports the idea that sudemycin D6 is worthy of further investigation as a novel preclinical anticancer agent with application in the treatment of numerous human cancers.

Mutant U2AF1-expressing cells are sensitive to pharmacological modulation of the spliceosome

Somatic mutations in spliceosome genes are detectable in ∼50% of patients with myelodysplastic syndromes (MDS). We hypothesize that cells harbouring spliceosome gene mutations have increased sensitivity to pharmacological perturbation of the spliceosome. We focus on mutant U2AF1 and utilize sudemycin compounds that modulate pre-mRNA splicing. We find that haematopoietic cells expressing mutant U2AF1(S34F), including primary patient cells, have an increased sensitivity to in vitro sudemycin treatment relative to controls. In vivo sudemycin treatment of U2AF1(S34F) transgenic mice alters splicing and reverts haematopoietic progenitor cell expansion induced by mutant U2AF1 expression. The splicing effects of sudemycin and U2AF1(S34F) can be cumulative in cells exposed to both perturbations—drug and mutation—compared with cells exposed to either alone. These cumulative effects may result in downstream phenotypic consequences in sudemycin-treated mutant cells. Taken together, these data suggest a potential for treating haematological cancers harbouring U2AF1 mutations with pre-mRNA splicing modulators like sudemycins.

Radiosynthesis of antitumor spliceosome modulators

A set of novel antitumor agents (the sudemycins) has recently been described that are analogs of the natural product FR901464. We report the radiosynthesis of two of these antitumor drug lead compounds, using a three step procedure: (1) ester hydrolysis, (2) Lindlars catalyst/tritium gas to give a (S,Z)-4-acetoxypent-2-enoic acid derivative, and finally (3) amide bond formation. These labeled analogs are useful in developing a better understanding of the pharmacological properties of this new class of therapeutic lead compounds.

Abstract 4193: A triple exon-skipping luciferase reporter assay identifies a new CLK inhibitor scaffold

The splicing of pre-mRNA is a critical process in normal cells and is deregulated in cancer. Compounds that modulate this process have recently been shown to target a specific vulnerability in tumors. We have developed a novel cell-based assay that specifically activates luciferase in cells exposed to SF3B1 targeted compounds, such as sudemycin D6. This assay was used to screen a combined collection of approved drugs and bioactive compounds. This screening approach identified several active hits, the most potent of which were CGP-74514A and aminopurvalanol A, both have been reported to be cyclin-dependent kinases (CDKs) inhibitors. We found that these compounds, and their analogs, show significant cdc2-like kinase (CLK) inhibition and clear structure-activity relationships (SAR) at CLKs. We prepared a set of analogs and were able to ‘dial out’ the CDK activity and simultaneously developed CLK inhibitors with low nanomolar activity. Thus, we have demonstrated the utility of our exon-skipping assay and identified new molecules that exhibit potency and selectivity for CLK, as well as some structurally related dual CLK/CDK inhibitors. Citation Format: Yihui Shi, Jaehyeon Park, Chandraiah Lagisetti, Wei Zhou, Lidia C. Sambucetti, Thomas R. Webb. A triple exon-skipping luciferase reporter assay identifies a new CLK inhibitor scaffold [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 4193. doi:10.1158/1538-7445.AM2017-4193

Structure-based drug discovery for influenza by targeting the cap-snatching endonuclease activity

An estimated 3-4 million severe illnesses and 500,000 deaths annually are associated with influenza. Seasonal influenza vaccines are targeted against dominant circulating strains of the virus, leaving those exposed to drifted or zoonotic strains at risk for infection. Most small molecule influenza drugs act as neuraminidase inhibitors or M2-ion channel inhibitors, and these drugs are becoming ineffective due to the emergence of resistance mutations. The viral RNA-dependent RNA polymerase (RdRp) has emerged as an attractive drug target: it is essential to viral replication and is better conserved than surface proteins. Using the recently determined crystal structure of the ‘capsnatching’ endonuclease domain of the viral RdRp, and applying the structure-based drug discovery approach, we have developed a potent class of inhibitors based on the 5,6-dihydroxypyrimidine scaffold. These inhibitors show inhibitory activity against the purified enzyme in nanomolar range and in cell-based assays in micromolar range. Crystal structures of the protein-inhibitor complexes show the preferred binding modes for these compounds and reveal that the active site can undergo considerable reorganization upon inhibitor-binding. These structures provide opportunities for exploiting crucial interactions at the active site for improving the drug-like properties of these potent inhibitors.