On November 6, 2018 Purdue Pharma L.P. reported that the first patient has been enrolled in a Phase 1 investigator-initiated clinical trial of tinostamustine, an investigational treatment, in patients with newly-diagnosed unmethylated O6-Methylguanine-DNA-methyltransferase (MGMT) glioblastoma multiforme (unmethylated nGBM),1 the most common and aggressive type of primary malignant brain tumor.2 Now open at The University of Texas MD Anderson Cancer Center, the open-label, non-randomized trial will investigate the safety profile, maximum tolerated dose (MTD), and efficacy of tinostamustine (Press release, Purdue Pharma, NOV 6, 2018, View Source [SID1234530936]).

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Glioblastoma is an incurable cancer with a very poor prognosis.2 Median overall survival is only 15 months and survival rates have shown no notable improvement in the past 30 years.3,4 The current standard of care for the disease includes surgery and postoperative radiation therapy with concurrent and adjuvant chemotherapy using temozolomide.5-7 Prognosis is significantly worse for patients with the unmethylated MGMT form of glioblastoma because that tumor type is less likely to respond to currently available treaments.8 Under current standard of care, the two-year overall survival rate was 46 percent in patients with MGMT-methylated nGBM versus 14 percent in patients with unmethylated nGBM.8

"We are excited to see tinostamustine advance into a Phase 1 study in patients with unmethylated glioblastoma multiforme, an extremely aggressive and fatal form of brain tumor," said John Renger, PhD, vice president, Head of Research & Development and Regulatory Affairs, Purdue Pharma. "The limited brain penetration of some medications across the blood-brain barrier contributes to the poor prognosis of this disease, however, preclinical data suggest tinostamustine may have the potential to cross the blood-brain barrier to deliver therapeutic central nervous system concentrations."

The dual-acting therapy candidate tinostamustine, previously known as EDO-S101, is a novel and potentially first-in-class alkylating deacetylase inhibitor (AK-DACi) therapy. Clinical research is underway to evaluate its ability to improve access to and break the DNA strands within cancer cells, and counteract the cancer cells’ attempts to repair the DNA damage.9-12

The potential utility of tinostamustine in the treatment of glioblastoma is supported by various pre-clinical data, and the molecule has shown anti-tumor activity in multiple in-vitro models of glioblastoma. In a pharmacokinetic analysis of tinostamustine administered to murine models by IV bolus and continuous IV infusion (CIVI), tinostamustine crossed the blood-brain barrier with central nervous system (CNS) penetration of 16.5 percent and 13.8 percent for IV bolus and CIVI administrations, respectively.13 CNS penetration with adequate therapeutic CNS concentration is essential for the treatment of brain tumors.

Tinostamustine is an investigational treatment and it is not approved for use in glioblastoma patients. Tinostamustine is also in development for a range of rare or difficult-to-treat blood cancers and advanced solid tumors. The completion of the first-in-human Phase 1 dose escalation study of tinostamustine in patients with relapsed or refractory (difficult-to-treat) hematological malignancies for which there are no available therapies was announced recently, and a Phase 1/2 study in advanced solid tumors was initiated in 2017. Tinostamustine is being developed in the US by Mundipharma EDO on behalf of Purdue Pharma.

To find out more about the study, visit clinicaltrials.gov.

This release discusses an investigational new drug under development and is not intended to convey conclusions about efficacy or safety. There is no guarantee that such investigational drug will successfully complete clinical development or receive regulatory approval.

On November 6, 2018 Sensei Biotherapeutics, Inc., a clinical-stage biopharmaceutical company developing precision immuno-oncology therapies, reported that clinical and immunological data from the Phase 1 clinical trial of SNS-301 will be highlighted in a poster presentation at the Society for Immunotherapy of Cancer (SITC) (Free SITC Whitepaper)’s (SITC) (Free SITC Whitepaper) 33rd Annual Meeting, to be held November 9-11, 2018 in Washington, D.C (Press release, Sensei Biotherapeutics, NOV 6, 2018, View Source [SID1234530933]). Data showed rapid and significant antigen-specific B-cell and T-cell responses induced by SNS-301, a first-in-class cancer immunotherapy targeting human aspartate β-hydroxylase (ASPH), a novel tumor-specific embryonic antigen.

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"These data clinically confirm the immunogenicity and mechanism of action of SNS-301, as we see strong, ASPH-targeted activation of the immune system in patients who received the immunotherapy. Taken together, the data indicate that SNS-301 is capable of overcoming central immune tolerance. We plan to target ASPH with both cancer vaccines and cell therapies to benefit different patient populations," said John Celebi, President and Chief Executive Officer of Sensei Biotherapeutics. "Based on these encouraging results, we look forward to initiating a Phase 2 trial for SNS-301 in various hematological malignancies and solid tumors in early 2019."

Twelve patients with biochemically recurrent prostate cancer who were screened for ASPH using Sensei’s proprietary companion diagnostic were treated with SNS-301 in the Phase 1, multi-center, proof-of-concept study. SNS-301 was administered every 21 days via intradermal injection using a fixed dose-escalation schema through which patients received between 8 and 23 doses at three different dose ranges, and the recommended Phase 2 dose was determined based on the immunogenicity data and changes seen in prostate specific antigen (PSA) doubling times at the three evaluated doses. Highlights of the immunogenicity data from the SNS-301 Phase 1 study presented at SITC (Free SITC Whitepaper) include:

Natural Killer (NK) cell levels in patients treated with SNS-301 were higher than NK cell levels in healthy donors, indicating activation of the innate immune system.
All patients evaluable for immune profiling experienced dose-dependent, ASPH-specific immune responses including B-cell, T-cell and antibody responses.
Increases in activated interferon gamma (IFN-γ) releasing T cells were demonstrated, and both ASPH-specific CD4+ helper T cells and CD8+ cytotoxic T cells showed dose-dependent activation over the first six cycles of SNS-301 dosing with peak responses often occurring after only three or four doses.
An average of eight to ten-fold increase in the percentage of ASPH-specific CD8+ T cells was observed post-treatment, compared to baseline measurements.
Anti-ASPH antibody titers increased in a dose-dependent manner over the first four to six cycles (80-120 days) after administration of SNS-301. This increase in antibody response correlated with concomitant increases in the percentages of ASPH-specific B cells, as measured by flow cytometry.
An average five to seven-fold increase in the percentage of ASPH-specific B-cell responses was observed post-treatment, compared to baseline measurements.
Eight out of the twelve patients (67%) achieved improvements in PSA doubling time and/or absolute PSA level, leading to decreased PSA velocity and suggesting a disease stabilizing effect of SNS301.
Based on evaluation of the three different dose ranges (2 x 1010, 1 x 1011, 3 x 1011 particles), immune responses occurred more rapidly at the two higher doses, as compared to the lower dose. Immunologic efficacy generally correlated with biochemical responses in these patients.
In the Phase 1 study, SNS301 was well tolerated with a favorable safety profile at all three dose levels with no dose-limiting toxicities or grade 4 or 5 adverse events.

About SNS-301
SNS-301 is a first-in-class cancer immunotherapy targeting human aspartate β-hydroxylase (ASPH), a cell surface enzyme that is normally expressed during embryonic development. Following embryonic development, the protein is no longer expressed in healthy adults. Expression of ASPH is uniquely upregulated in more than 20 different types of cancer and is related to cancer cell growth, cell motility and invasiveness. ASPH alters signaling that occurs through the Notch pathway and its expression levels in various tumors are inversely correlated with disease prognosis. SNS-301 is a bio-engineered, inactivated bacteriophage virus expressing a fusion protein of native bacteriophage gpD (gene product D) and a selected domain of ASPH. SNS-301 is designed to overcome immune tolerance and induce robust and durable ASPH-specific humoral and cellular responses. SNS-301 is paired with a companion diagnostic to ensure appropriate patient selection and is delivered easily through an intradermal injection to aid in generating robust immune response.

On November 6, 2018 Atreca, Inc., a biotechnology company focused on developing novel therapeutics based on a deep understanding of the human immune response, reported that it will present results from a study that further demonstrates the ability of the Company’s proprietary Discovery Engine, featuring the Company’s Immune Repertoire Capture (IRC) technology, to identify antibodies from treatment-responsive cancer patients that bind to non-autologous tumor tissue (Press release, Atreca, NOV 6, 2018, View Source [SID1234530932]). The study will be presented at the Society for Immunotherapy of Cancer (SITC) (Free SITC Whitepaper)’s (SITC) (Free SITC Whitepaper) 33rd Annual Meeting being held November 7-11, 2018, at the Walter E. Washington Convention Center in Washington, D.C.

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"Atreca has built a proprietary and unique discovery platform that enables us to discover, in a very efficient and industrialized manner from active immune responses, antibodies that can serve as the foundation of therapeutics," said Tito A. Serafini, Ph.D., Chief Strategy Officer and an Atreca founder. "The results to be presented at this conference provide another example of what this Discovery Engine enables in oncology; namely, our ability to identify tumor-targeting antibodies in treatment-responsive patients with the potential to be developed into therapeutics designed to treat large patient groups. Our most advanced program, ATRC-101, which we anticipate entering clinical trials in 2019, is a product of this approach."

In the study, (Abstract #O3; Title: Anti-tumor immune responses in metastatic breast cancer exceptional responder patients) to be presented both as an oral presentation and a poster by William Robinson, M.D., Ph.D., Professor of Medicine at Stanford University and an Atreca Founder, Atreca researchers collaborated with researchers led by Joyce O’Shaughnessy, M.D., at Baylor University Medical Center and Texas Oncology. Atreca researchers investigated the properties of antibodies identified in the active immune response of eleven metastatic breast cancer patients who had exceptional and durable responses to systemic therapy. Of the patient-derived antibodies assessed, over 40% displayed specific immunoreactivity to breast carcinoma tissue from unrelated patients, but not to adjacent tissue, indicating that they bind to public tumor antigens. Multiple antibody lineages, predominantly of the IgG2 subclass, showed evidence of convergent antibody evolution across patients, and a subset of responder antibodies drove killing of tumor cells in in vitro functional assays.

Abstract Title: Anti-tumor immune responses in metastatic breast cancer exceptional responder patients (Abstract #O3)

Oral Presentation

Concurrent Session 216: Role of B cells in Immunotherapy & Toxicity
Date & Time: Saturday, Nov. 10, 6:10 – 6:25 p.m. EST
Location: East Salon ABC
Atreca also has a second presentation. Details are below:

Abstract Title: The identification of potent anti-tumor antibodies applicable for ADC therapeutics from patients undergoing immunotherapy (Abstract #P1)

Poster Display (for both posters)

Date & Time: Friday, Nov. 9, from 8 a.m. – 8 p.m. EST and Saturday, Nov. 10, from 8 a.m. – 12 p.m. EST
Presentation Hours: Friday, Nov. 9, 12:45 – 2:15 p.m. EST and 6:30 – 8 p.m. EST
Location: Hall E

On November 6, 2018 Vedanta Biosciences, a clinical-stage company developing a new category of therapies for immune-mediated diseases based on rationally-defined consortia of human microbiome-derived bacteria, reported preclinical data for VE800, the Company’s orally-administered, live biotherapeutic product candidate in immuno-oncology (Press release, Vedanta Biosciences, NOV 6, 2018, View Source [SID1234530930]). The study showed that VE800 elicited an anti-tumor immune response as a monotherapy and also enhanced effects of immune checkpoint inhibitors. Additionally, the results describe a mechanism of action for VE800 as the robust interferon-gamma producing CD8+ (cytotoxic) T cell response was elicited via activation of dendritic cells. The data will be presented at the Society for Immunotherapy of Cancer (SITC) (Free SITC Whitepaper)’s (SITC) (Free SITC Whitepaper) 33rd Annual Meeting by Dr. Bruce Roberts, Chief Scientific Officer of Vedanta Biosciences, on November 8. Vedanta Biosciences expects to initiate a clinical study of VE800 in mid-2019.

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"Our work shows that VE800 induces robust tumor infiltration by cytotoxic T cells – one of the strongest predictors of response to checkpoint inhibitors – and promotes suppression of tumor growth and enhanced survival in a range of cancer models," said Bruce Roberts, Ph.D., Chief Scientific Officer of Vedanta Biosciences. "To our knowledge, VE800 is the most advanced immuno-oncology product candidate based on a defined consortium of human microbiome-derived bacteria, a therapeutic modality that Vedanta is pioneering. With our cGMP manufacturing processes in place, we’re well-positioned to take VE800 into the clinic in the coming months."

In the preclinical study, VE800 was assessed alone and in combination with various checkpoint inhibitors in colon carcinoma and melanoma tumor models. VE800 was assessed for its ability to induce CD8+ T cells, an important marker of anti-tumor response, as well for its ability to influence accumulation of tumor infiltrating lymphocytes. The study was conducted in collaboration with Dr. Kenya Honda of Keio University, a leader in the microbiome field and a scientific co-founder of Vedanta Biosciences.

Data highlights include:

1. VE800 robustly promoted induction of interferon-gamma producing CD8+ T cells via activation of intestinal dendritic cells and stimulation of interferon-gamma producing CD8+ T cells in a manner dependent on the transcription factor BATF3
2. VE800 enhanced the anti-tumor activity of both anti-PD-1 and anti-CTLA4 antibodies by increasing the level of tumor infiltrating CD8+ T cells
3. VE800 also promoted systemic immune cell activation as evidenced by accumulation of CD8+ T cells in the spleen.

Unlike fecal transplants or single strain approaches to microbiome modulation, Vedanta Biosciences uses pure, clonal cell banks to produce defined collections, or consortia, of bacterial strains designed to effect durable therapeutic changes in a patient’s microbiota. This bypasses the need to rely on direct sourcing of fecal donor material of inconsistent composition.

About VE800
VE800 is Vedanta Biosciences’ oral immuno-oncology product candidate. It consists of a rationally-defined bacterial consortium that activates cytotoxic CD8+ T cells, a type of white blood cell that is the predominant effector in cancer immunotherapy. In preclinical studies, VE800 has been shown to enhance the ability of these T cells to infiltrate tumors, thereby promoting suppression of tumor growth and improving survival. Data also suggest that VE800 may enhance the effects of checkpoint inhibitors. Vedanta Biosciences is evaluating VE800 alone and in combination with checkpoint inhibitors as a potential treatment for patients with advanced or metastatic cancers.

On November 6, 2018 Jnana Therapeutics reported that Joanne Kotz, Ph.D., a company co-founder, has been named Chief Executive Officer (Press release, Jnana Therapeutics, NOV 6, 2018, View Source [SID1234530929]). Dr. Kotz has served as Jnana’s president since December 2017.

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"Joanne has demonstrated exceptional leadership in guiding the company through its early stages of growth, and we believe she is the ideal person to bring Jnana through its next phase and execute on the company’s vision to unlock SLC transporters as a therapeutic class," said Dr. Amir Nashat, a member of Jnana’s Board of Directors and a managing partner at Polaris Partners. Dr. Nashat also served previously as the company’s interim Chief Executive Officer. "She has built a talented team and a collaborative, empowering culture, while also leading important work to validate Jnana’s proprietary drug discovery platform. Together these position Jnana for even greater success going forward."

Dr. Kotz has broad life sciences experience in research, business, and operations. She helped formulate the initial scientific strategy for Jnana and has led the business and operations of the company since its launch in January 2017. Prior to founding Jnana, she held a leadership position in the F-Prime Biomedical Research Initiative, whose mission is to advance the discovery of novel therapeutic agents for the treatment of neurodegenerative disease by funding early-stage research in academia and biotech companies. Prior to F-Prime, Dr. Kotz was a director at the Broad Institute, where she played a leadership role in creating and guiding partnerships to advance drug discovery efforts, including the Broad-Bayer collaboration in oncology that resulted in the identification of multiple drug candidates. She received a Ph.D. in chemistry from the University of California, Berkeley and conducted postdoctoral research at the Necker Children’s Hospital in Paris and at Genentech.

"I am very proud of what the Jnana team has accomplished to date," said Dr. Kotz. "We have made significant progress in advancing our technology platform, which is the first to explicitly target the SLC family of metabolite transporters, established a strategic collaboration with Neurocrine Biosciences to discover new medicines for central nervous system disorders, and recruited a strong team committed to making a positive impact on patients and their families. I am honored to have been chosen to serve as CEO, and look forward to guiding Jnana’s efforts to transform our knowledge of SLCs into new therapeutics for patients lacking viable treatment options."