On September 16, 2020 Roche reported that it will publish its Sales Results for the 3rd Quarter of 2020 prior to the opening of the Swiss Stock Exchange on Thursday, October 15th, 2020 (Press release, Hoffmann-La Roche, SEP 16, 2020, View Source [SID1234565217]).

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On September 16, 2020 Alligator Bioscience (Nasdaq Stockholm: ATORX) reported that the United States Patent and Trademark Office (USPTO) has issued U.S. Patent No. 10,774,150 which covers compositions of matter directed to Alligator’s bispecific drug candidate ATOR-1015 (Press release, Alligator Bioscience, SEP 16, 2020, View Source [SID1234565215]). The granted patent’s earliest expiry year is 2036.

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"ATOR-1015 constitutes a new concept, a tumor-localizing bispecific CTLA-4 antibody. Our invention addresses one of the key challenges within immuno-oncology, i.e. the narrow therapeutic window of CTLA-4 drugs. This is now protected by a granted US patent", commented Per Norlén, CEO at Alligator Bioscience.

ATOR-1015 is developed for the treatment of metastatic cancer. Promising safety data from the ongoing ATOR-1015 Phase I clinical study was presented at ASCO (Free ASCO Whitepaper) in June 2020. The Phase I dose escalation study is planned to be completed during the fourth quarter 2020 and the subsequent Phase Ib efficacy study in malignant melanoma is due to start in 2021.

The information was submitted for publication, through the agency of the contact person set out above, at 08:30 a.m. CEST on September 16, 2020.

On September 15, 2020 Cue Biopharma, Inc. (NASDAQ: CUE), a clinical-stage biopharmaceutical company engineering a novel class of injectable biologics to selectively engage and modulate targeted T cells within the body, reported the peer-reviewed publication of preclinical data focused on the in vivo detection of tumor antigen-specific T cells in a paper published in Nature Methods titled, "In vivo detection of antigen-specific CD8 T cells by immuno-positron emission tomography (Press release, Cue Biopharma, SEP 15, 2020, View Source [SID1234608295])." The study was co-authored by Steven C. Almo, Ph.D., co-founder of Cue Biopharma, professor and chair of biochemistry, professor of physiology & biophysics and the Wollowick Family Foundation chair in multiple sclerosis and immunology at Albert Einstein College of Medicine and Hidde Ploegh, Ph.D., a renowned expert in molecular immunology and a member of the program in cellular and molecular medicine at Boston Children’s Hospital.

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In this work, researchers employed dimeric protein scaffolds to develop a novel immuno-positron emission tomography (immunoPET) imaging approach. These protein scaffolds, known as synTacs, consist of Fc-based covalent peptide-major histocompatibility complex (pMHC) dimers, which form the core structure of Cue Biopharma’s Immuno-STAT (Selective Targeting and Alteration of T cells) platform. By targeting synTacs labelled with positron emitting isotopes against specified tumor antigens, researchers were able to specifically and non-invasively detect tumor antigen-specific T cells in murine solid tumor models. In the same study, similar application of synTacs deploying viral antigens could detect and engage virus-specific T cells in the lung tissue.

"These studies demonstrate the remarkable breadth of applications supported by the Immuno-STAT platform, as it enables clinical applications for highly selective targeted treatments of cancer, autoimmune diseases and infectious diseases, but, also as demonstrated in the Nature Methods paper, the potential to serve as prognostics and diagnostics for mechanism-of-action and treatment efficacy by revealing the in vivo distribution of the biologic and its target T cells in diseased tissue," said Dr. Almo.

"This work highlights the power of the Sortase A coupling technology developed in our lab, as it readily allowed the site-specific, stoichiometric and highly reproducible installation of PET imaging tags (64Cu2+ and 89Zr4+ and 18F) for the in vivo tracking of antigen-specific T cells targeting tumor cells and virally infected cells in the disease tissue. These advances highlight the strength of modular biologic platforms, like the Immuno-STAT platform, that can be deployed for targeting and tracking antigen-specific effector lymphocytes in the patients to gain predictive insights into pharmacodynamic and clinical responses," elaborated Dr. Ploegh.

Specific detection of intratumoral T cells by this newly developed immunoPET approach provides further support that the core component of the Immuno-STAT scaffold can penetrate into the tumors and directly engage tumor-resident T cells. These data highlight the modular nature and the broad applicability of the Immuno-STAT platform to selectively deliver cargoes, such as imaging agents or immunomodulatory signals to tumor-resident T cells.

Anish Suri, Ph.D., president and chief scientific officer of Cue Biopharma, commented, "We are highly encouraged by these results, as they highlight the inherent advantages of our engineered biologics platforms. Data showing the efficient penetration of the HPV16 E7 targeted synTac into solid tumors are particularly noteworthy, as similar technologies are unable to deliver cargoes past the tumor periphery. Further, this synTac is analogous to our lead asset, CUE-101, which carries a covalently linked IL-2 variant and is currently being evaluated in a Phase 1 trial in HPV16 driven head and neck squamous cell carcinoma."

Albert Einstein College of Medicine and its faculty members acknowledge the following relationships with Cue Biopharma, Inc.: Dr. Almo holds equity in Cue Biopharma, Inc., receives royalties from existing license agreements between Einstein and Cue, and is a member of its Science Advisory Board. Albert Einstein College of Medicine holds equity in Cue and receives royalties from existing licensing agreements.

On September 15, 2020 Strand Therapeutics reported that it is positioned to reshape the future of oncology (Press release, Strand Therapeutics, SEP 15, 2020, View Source [SID1234573056]). The company is genetically programming RNA not just to deliver a gene of interest, but to control the location, timing and intensity of therapeutic protein expression using mRNA-encoded logic circuits.

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That controllability is an important feature, and one that’s been lacking for mRNA gene therapies. With it, mRNA gene therapy has the potential to supplant traditional DNA-based gene therapy, offering a gene delivery technology that is easier and safer.

The idea to program mRNA was developed at Massachusetts Institute of Technology’s Synthetic Biology Center and spun out of the labs scientific co-founders Darrell Irvine, Ph.D. and Ron Weiss, Ph.D., where co-founders Tasuku Kitada, Ph.D., now president and head of R&D, and Jacob Becraft, Ph.D., CEO, worked as researchers.

Kitada and Becraft were the first to create synthetic gene circuits using synthetic mRNA, showing that post-transcriptional circuits could be "wired" to create a variety of networks that enabled cell type-specific expression and small molecule-based control of gene expression from synthetic mRNA.

In the MIT research lab of Ron Weiss, the pair led the team that developed the world’s first synesthetic biology programming language for mRNA.

"You can make it so that rather than DNA or RNA just expressing a protein, it can respond to inputs. Our body is filled with natural genetic circuits," Becraft told BioSpace.

Traditional DNA-based gene therapy uses viral vectors or nanoparticles to deliver a gene to the nucleus of a cell, where it is transcribed into mRNA. The mRNA then carries those instructions outside the nucleus and into the cytoplasm where protein is produced. Once the gene is in place, its expression can be up- or down-regulated. The challenge is that, "The cells protect their nucleus," Becraft noted. That makes it difficult for a gene to enter.

mRNA, however, doesn’t access the nucleus. Instead it accesses the cytoplasm. This approach to gene therapy is easier from a drug delivery perspective, and safer, because "it doesn’t run the risk of DNA mutating the genome," Becraft explained.

"We take the approach that the mRNA molecule doesn’t need to be changed structurally. We make regular, non-modified RNA, but make that mRNA smarter, able to operate autonomously and sense its surroundings," he said.

Strand Therapeutics does that by engineering the sequences of the nucleotides rather than changing the biochemical makeup of the RNA. In 2018, researchers showed that mRNA can deliver RNA therapeutic proteins, alongside those that encode for RNA-binding proteins in their genetic circuits.

In August, Irvine and Weiss published a paper in Nature Cancer showing the technology can simulate multiple mechanisms in known orders to stimulate multiple targets at once, creating a full-fledged immune response. Working in mice, they used multifunctional oncolytic nanoparticles to deliver self-replicating IL-12 RNA that was encapsulated in lipids.

The system promoted immunogenic cancer cell death, stimulated danger sensors in transfected cells, and modulated the immune cells for a greater anti-tumor immune response. In several of the mouse models, a single injection to the tumor eradiated those tumors, caused uninjected tumors to regress, and induced a protective immune memory.

"What we’ve done is use our programming technology to simulate multiple mechanisms in known order to kill multiple targets at once, to create a full-fledged immune response. You need to take a holistic approach and hit targets in the correct order," Becraft stressed. The platform is entering IND-enabling studies in humanized mouse models now.

"What’s different about synthetic biology is that we’re building therapies that recapitulate how biological systems work," Becraft said. "The mRNA enters into a cell and will respond to what’s happening in the cell with a feedback loop. For example, if it sees markers of a cancer cell, you build a system to recognize those inputs – like a computer program – and actuate a response. With programmable mRNA, we can stimulate multiple mechanisms and deliver multiple different cargos at once."

Strand Therapeutics’ MIT pedigree lends it immediate academic validation, but to succeed, the company also needed industry validation that the approach was not only scientifically interesting but promising to other healthcare leaders.

"It’s always good to have pharma interest, to recognize the technology’s potential," Becraft said. That’s a key tipping point."

That validation arrived in the form of multiple industry awards.

From a business development standpoint, "One of the first big awards was the Bristol-Myers Squibb 2018 Golden Ticket, recognizing Strand as an innovative startup. I say that not because of the free lab space and mentorship but because, through it, I met a member of the BMS team who was a very experienced executive in the biopharma world. She left BMS and joined another company, but we stayed in touch. Eventually, we hired her as our COO." Becraft makes a point of stressing that she wasn’t poached. "She worked at another company before joining Strand Therapeutics."

Just over a year ago, the company received $6 million in seed funding from Playground Global, Alexandria Venture Investments, ANRI and private investors. That allowed it to hire key personnel and further develop its synthetic biology platform. With that boost, it has attracted pharmaceutical partners and is pursuing multiple partnership strategies. Now, Becraft said, "We’re set to enter clinical trials in early 2022."

On September 15, 2020 Plus Therapeutics, Inc. (Nasdaq: PSTV) (the "Company"), reported that the U.S. Food and Drug Administration (FDA) has granted the Company Fast Track designation for its lead investigational drug, Rhenium NanoLiposomes (RNL), for the treatment of patients with recurrent glioblastoma (Press release, PLUS THERAPEUTICS, SEP 15, 2020, View Source [SID1234572289]). As previously reported, the Company also received orphan drug designation from the FDA for RNL for the treatment of patients with glioblastoma.

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Fast Track designation confers several benefits to the drug development program including 1) more frequent meetings with FDA to discuss the drug’s development plan, 2) more frequent written communication from FDA about such things as the design of the proposed clinical trials and use of biomarkers, 3) eligibility for Accelerated Approval and Priority Review, if relevant criteria are met, and 4) Rolling Review, which means that a drug company can submit completed sections of its New Drug Application (NDA) for review by FDA, rather than waiting until every section of the NDA is completed before the entire application can be reviewed. NDA review usually does not begin until the drug company has submitted the entire application to the FDA.

"Fast Track designation validates the potential importance of this novel radiotherapeutic for patients with recurrent glioblastoma who currently have no good treatment options," said Dr. Marc Hedrick, President and Chief Executive Officer of Plus Therapeutics. "With this designation in hand, we intend to move into Cohort 6 of the trial, one key step closer to bringing forth a novel therapy for these patients."

RNL is being evaluated in the NIH/NCI-supported, multi-center ReSPECT Phase 1 dose-finding clinical trial (NCT01906385). As reported last week, the ReSPECT trials’ Data and Safety Monitoring Board (DSMB) approved the Company to proceed to Cohort 6 of the trial, which includes increasing both the drug volume and radiation dose to 8.8 milliliters (mL) and 22.3 millicuries (mCi), respectively.

RNL is designed to safely, effectively, and conveniently deliver a very high dose of radiation, of up to 25 times greater concentration than currently used external beam radiation therapy, directly into the brain tumor for maximum effect.

About Glioblastoma

Glioblastoma (Grade IV astrocytoma) is the most common and most aggressive of the primary malignant brain tumors in adults. According to the most recent Central Brain Tumor Registry of the United States (CBTRUS) Statistical Report, on average there are nearly 12,0000 cases of glioblastoma diagnosed annually in the U.S., with historical 1-year and 5-year median survival rates of 40.8% and 6.8%, respectively.