On April 3, 2019 Bio-Path Holdings, Inc., (NASDAQ: BPTH), a biotechnology company leveraging its proprietary DNAbilize antisense RNAi nanoparticle technology to develop a portfolio of targeted nucleic acid cancer drugs, reported that data from pre-clinical studies supporting the potential of BP1003, a novel liposome-incorporated STAT3 oligodeoxynucleotide inhibitor, for the treatment of pancreatic cancer, non-small cell lung cancer (NSCLC) and acute myelogenous leukemia (AML) were presented in a poster at the American Association for Cancer Research (AACR) (Free AACR Whitepaper) Annual Meeting 2019 today in Atlanta, GA (Press release, Bio-Path Holdings, APR 3, 2019, View Source [SID1234535001]).

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The poster, entitled "BP1003, a Novel Liposome-Incorporated STAT3 Antisense Oligodeoxynucleotide Inhibitor," was presented by Ana Tari Ashizawa, Ph.D., Vice President of Research and Development at Bio-Path.

The poster highlights four antisense oligo sequences directed against STAT3 mRNA identified by Bio-Path and manufactured using DNAbilize antisense RNAi nanoparticle technology. Cell viability tests and Western blots were conducted to determine the inhibitory effects of liposome-incorporated STAT3 antisense oligo on NSCLC and AML cells. An ex vivo live tissue sensitivity assay (LTSA) was performed with a panel of 20 pancreatic ductal adenocarcinoma (PDAC) patient-derived xenografts (PDX) to study the overall activity of BP1003 alone, and in combination with gemcitabine. Using previously defined criteria, tissue slice viability inhibition greater than 30% and with a p<0.05 was considered to be a response. For validation of ex vivo results, PDAC PDX tumor bearing mice were administered BP1003 and gemcitabine twice a week for 28 days. Tumor volumes were monitored for up to 49 days.

The most potent liposome-incorporated STAT3 antisense sequence in decreasing NSCLC cell viability was selected as the drug candidate BP1003. Further validation in AML cells demonstrated that BP1003 inhibited cell viability and STAT3 protein expression. In the ex vivo LTSA assay, BP1003 at a dose of 10 µM significantly inhibited the tissue slice viability in 9 out of 18 PDAC PDXs by more than 30% (p<0.05). The combination of BP1003 and gemcitabine further enhanced ex vivo efficacy of BP1003 in a subset of PDXs. In the in vivo study with PDAC PDX models, a combination of BP1003 and gemcitabine caused tumor regression during the 28-day drug treatment period. This anti-cancer activity was maintained for another 21 days, even when drug treatment had ceased.

Preclinical pancreatic cancer models demonstrated that BP1003 successfully penetrated the stroma into pancreatic tumors. As previously reported, Bio-Path’s lead drug candidate, prexigebersen, has been tested in the above-described ex vivo pancreatic cancer preclinical model, and the results also demonstrated that prexigebersen penetrated the pancreatic tumors. Finally, the results in pancreatic cancer showed that BP1003 inhibited tumor slice viability in 9 of 18 PDAC PDXs.

"We believe these data suggest that between our two drug candidates, BP1003 and prexigebersen, Bio-Path will be able to treat human pancreatic tumors. The Company expects to initiate a Phase I study of prexigebersen for the treatment of solid tumors in 2019, including a cohort of metastatic pancreatic cancer patients. We plan to complete Investigational New Drug (IND) enabling studies in 2019 and to file an IND application for a Phase I study of BP1003 for the treatment of pancreatic cancer in 2020," stated Peter Nielsen, Chief Executive Officer of Bio-Path.

"We developed BP1003, a novel liposome-incorporated STAT3 antisense oligodeoxynucleotide, as a specific inhibitor of STAT3 as it is thought to be one of the most important genes involved with a variety of cancers. STAT3 is considered to be an undruggable target, which has hampered the development of a therapy for it. Inhibition of STAT3 requires a systemic RNAi solution, such as DNAbilize, in order to exert its anti-cancer activity," noted Dr. Tari Ashizawa.

"These data are very encouraging and suggest that our two drug candidates, BP1003 and prexigebersen, are active against pancreatic cancer which is often treatment refractory and lethal. As with prexigebersen, studies to date have shown BP1003 to be generally safe and well-tolerated in preclinical models. We believe there is a great potential for the additional development of BP1003 as a treatment for NSCLC, AML and a variety of metastatic cancers," added Mr. Nielsen.

About Signal Transducer and Activator of Transcription 3 (STAT3)

Signal Transduction and Activator of Transcription-3 (STAT3), though typically inactive in normal cells, is aberrantly active in cancer cells. The abilities of tumor cells to proliferate uncontrollably, resist apoptosis, induce vasculature formation, and invade distant organs are well-recognized hallmarks of cancer. STAT3 is a regulator of the genes involved in these cancer processes. More recently, the capability of tumors to evade immune surveillance and avoid destruction by the immune system has also gained significant acceptance in the cancer research field. STAT3, which is a point of convergence for many oncogenic pathways, has emerged as a critical mediator of tumor immune evasion at multiple levels.

Activation of STAT3 has been found in many types of cancers, including NSCLC, AML, and PDAC. Activation of STAT3 correlates with poor clinical outcome, high grade disease and metastasis, and has been linked with resistance to chemotherapy, including gemcitabine, considered a standard-of-care agent for advanced PDAC. Therefore, inhibition of STAT3 in combination with chemotherapy is expected to produce enhanced clinical benefit.