On January 8, 2020 Alector, Inc. (Nasdaq: ALEC), a clinical-stage biotechnology company pioneering immuno-neurology, reported that Arnon Rosenthal, Ph.D., co-founder and chief executive officer of Alector, will present a company overview at the J.P. Morgan 38th Annual Healthcare Conference on Wednesday, January 15, 2020 at 4:30 p.m. PT (Press release, Alector, JAN 8, 2020, View Source [SID1234552839]). The conference is being held January 12-16, 2020 in San Francisco .

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A live webcast of the presentation will be available on the "Events & Presentations" page within the Investors section of the Alector website at View Source A replay will be available on the Alector website for 30 days following the event. For further information, please contact [email protected].

On January 8, 2020 Adaptive Biotechnologies Corporation (Nasdaq: ADPT), a commercial stage biotechnology company that aims to translate the genetics of the adaptive immune system into clinical products to diagnose and treat disease, reported that Palmetto GBA, a Medicare Administrative Contractor (MAC) that assesses diagnostic technologies through its MolDX program, has expanded coverage of the clonoSEQ Assay to include monitoring minimal residual disease (MRD) in Medicare patients with chronic lymphocytic leukemia (CLL) (Press release, Adaptive Biotechnologies, JAN 8, 2020, View Source [SID1234552838]). This adds to existing Medicare coverage in B-cell acute lymphoblastic leukemia (ALL) and multiple myeloma, which was established in January 2019. Medicare coverage for clonoSEQ is aligned with clinical practice guidelines in covered disease states which support assessing MRD at multiple time points throughout therapy to monitor treatment response and help predict patient outcomes. This expanded coverage policy is effective immediately and continues the positive momentum for clonoSEQ with over 175M lives covered to date.

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"Patients with CLL who achieve undetectable MRD have better outcomes than those with detectable MRD," said Javier Pinilla-Ibarz, M.D., Ph.D., Senior Member and Head of the Lymphoma program in the Department of Malignant Hematology at Moffit Cancer Center. "As newer therapies emerge for CLL that can help patients achieve very deep remissions, assessment of MRD can help guide clinical care by determining a patient’s response to therapy and informing that patient’s prognosis."

MRD refers to the remaining number of cancer cells that may be present in a patient’s body during and after treatment and that may eventually lead to recurrence of the disease. MRD testing is performed as a series of tests throughout a patient’s cancer journey to monitor for remission, detect relapse, determine response to treatment and inform care. Controlled trials have shown that even the smallest amounts of residual disease significantly predict a patient’s long-term clinical outcomes.

"Data are mounting to support the clinical benefits of MRD measurement in lymphomas and leukemias, including CLL, to help assess a patient’s prognosis, measure response to therapy and inform treatment decisions," said Lance Baldo, chief medical officer, Adaptive Biotechnologies. "The Medicare coverage expansion validates this growing body of evidence and provides patients living with CLL greater access to highly sensitive, standardized MRD testing."

clonoSEQ is the only test authorized by the U.S. Food and Drug Administration (FDA) to detect and monitor minimal residual disease in any lymphoid cancer. At the 2019 American Society of Hematology (ASH) (Free ASH Whitepaper) Annual Meeting, an unprecedented amount of data was presented demonstrating the clinical significance of MRD in blood cancers and further validating it as one of the strongest predictors of patient outcomes.

About the clonoSEQ Assay

The clonoSEQ Assay was granted de novo designation and marketing authorization by FDA for the detection and monitoring of minimal residual disease (MRD) in patients with multiple myeloma (MM) and B-cell acute lymphoblastic leukemia (ALL) using DNA from bone marrow samples. clonoSEQ is the first and only FDA-authorized in vitro diagnostic assay for MRD testing. It is also the first clinical diagnostic powered by immunosequencing to receive FDA clearance. clonoSEQ leverages Adaptive’s proprietary immunosequencing platform to identify and quantify specific DNA sequences found in malignant cells, allowing clinicians to assess and monitor MRD during and after treatment. The assay provides standardized, accurate and sensitive measurement of MRD that allows physicians to predict patient outcomes, assess response to therapy over time, monitor patients during remission and detect potential relapse. Clinical practice guidelines in hematological malignancies recognize that MRD status is a reliable indicator of clinical outcomes and response to therapy, and clinical outcomes are strongly associated with MRD levels measured by the clonoSEQ Assay in patients diagnosed with ALL and MM. More than 175 million people in the US now have access to clonoSEQ through Medicare and private payor coverage.

clonoSEQ is a single-site assay performed at Adaptive Biotechnologies. It is also available as a CLIA-regulated laboratory developed test (LDT) service for use in other lymphoid cancers. For important information about the FDA-cleared uses of clonoSEQ, including the full intended use, limitations, and detailed performance characteristics, please visit www.clonoSEQ.com/technical-summary.

On January 8, 2020 CStone Pharmaceuticals ("CStone" or the "Company", HKEX: 2616) reported that the first patient has been dosed in the Phase III GEMSTONE-304 study of the Company’s anti-PD-L1 antibody CS1001 in combination therapy as first-line treatment in patients with advanced esophageal squamous cell carcinoma (ESCC) (Press release, CStone Pharmaceauticals, JAN 8, 2020, View Source [SID1234552811]). The GEMSTONE-304 trial is a multicenter clinical study designed to evaluate the efficacy and safety of CS1001 in combination with 5-fluorouracil plus cisplatin (FP) doublet chemotherapy in the first-line treatment of unresectable locally advanced, relapsed, or metastatic ESCC.

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According to the GLOBOCAN data released in 2018, there are approximately 307,000 new incidences of esophageal cancer and 283,000 cases of esophageal cancer-related deaths in China annually. The incidence and mortality rates of esophageal cancer are ranked 5th and 4th respectively among all tumor types nationwide. Epidemiological data indicate that 90% of all esophageal cancer cases in China are ESCC, and around 70% of ESCC cases were locally advanced or metastatic at the time of diagnosis. The platinum-based doublet chemotherapy is the current standard of care first-line treatment for patients with advanced ESCC, but it has limited efficacy. Existing data on this first-line treatment for advanced ESCC suggest an objective response rate (ORR) of 35%, a median progression-free survival (PFS) of less than six months, and a median overall survival (OS) of less than one year. There are no alternative treatments for ESCC patients who have failed the first-line treatment.

CS1001 is an investigational anti-PD-L1 antibody developed by CStone. Results released at the 2019 Chinese Society of Clinical Oncology (CSCO) Annual Meeting have shown that, as of July 1, 2019, the Phase Ib trial of CS1001 in combination with the FP chemotherapy regimen in first-line treatment of ESCC achieved an ORR of 77.8% with durable response as well as good overall safety and tolerability.

"Esophageal cancer is one of the tumor types that are particularly prevalent in China, with over 50% of the world’s new esophageal cancer cases and related deaths occurring in the country. Furthermore, the lack of more effective treatments for this patient population has long represented an urgent unmet clinical need," said Dr. Frank Jiang, Chairman and CEO of CStone. "I am glad that we have dosed the first patient in the GEMSTONE-304 trial. I hope CS1001 will continue to demonstrate its clinical promise in its development programs, and soon be proven as a new treatment option for ESCC patients in China."

"Early symptoms of esophageal cancer are relatively silent; as a result, esophageal cancer patients are commonly diagnosed at advanced stages for which there are very limited treatment options. Furthermore, no immunotherapy has been approved for the first-line treatment of ESCC. Recent results from the Phase Ib trial of CS1001 have already demonstrated promising preliminary antitumor efficacy in advanced ESCC. We will continue accelerate this Phase III trial with our best effort. Should this clinical program lead to successful outcomes, it will be a major breakthrough for advanced ESCC patients who are in urgent need of effective therapies," noted Dr. Jason Yang, Chief Medical Officer of CStone.

About CS1001

CS1001 is an investigational monoclonal antibody directed against PD-L1 being developed by CStone. Authorized by the U.S. based Ligand Corporation, CS1001 is developed by the OMT transgenic animal platform, which can generate fully human antibodies in one step. As a fully human, full-length anti-PD-L1 monoclonal antibody, CS1001 mirrors natural G-type immune globulin 4 (IgG4) human antibody, which can reduce the risk of immunogenicity and potential toxicities in patients, potentially representing a unique advantage over similar drugs.

CS1001 has completed a Phase 1 dose-escalation study in China, in which the drug showed good tolerability. During Phase 1a and 1b stages of the study, CS1001 produced sustained clinical benefits in multiple tumor types.

CS1001 is being investigated in a number of ongoing clinical trials, including one Phase 1 bridging study in the U.S. In China, its clinical program includes one multi-arm Phase 1b study, two pivotal Phase 2 studies, and four Phase 3 studies for several tumor types.

On January 7, 2020 Theolytics, a UK biotech harnessing viruses to combat cancer, reported the closing of a US $6.8 million (UK £5 million) Series A round (Press release, Theolytics, JAN 7, 2020, View Source [SID1234630929]). The round was co-led by Epidarex Capital and Taiho Ventures LLC with participation from existing investor, Oxford Sciences Innovation (OSI). The financing will be used to progress the company’s pipeline of candidates towards human clinical trials.

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Theolytics is focused on creating a step-change in the oncolytic viral therapy field, by using its phenotypic screening platform to discover and develop highly efficacious, targeted candidates, suitable for intravenous delivery and optimised for a chosen cancer patient population.

Charlotte Casebourne, CEO of Theolytics said, "Oncolytic viruses represent a unique therapeutic paradigm within oncology. Theolytics’ platform technology enables a fundamental shift in what is possible; combining the power of bioselection with a patient-centric approach to drug discovery, we are able to address many of the challenges that have prevented the field from delivering on its full potential. Our team are committed to discovering and developing candidates for some of the most challenging cancers, and I’m delighted that Epidarex and Taiho Ventures have chosen to support us on our journey."

Henning Steinhagen, Venture Partner at Epidarex Capital said, "The oncolytic viral therapy field continues to gain momentum and Theolytics caught our eye with their highly promising indication-specific bioselection platform. Theolytics combines multiple key features we are looking for when investing: world class science, highly driven innovators, and a disruptive technology that has the potential to generate a strong pipeline of proprietary and significantly more efficacious therapeutics. We look forward to supporting Theolytics in leveraging its innovative platform to establish a pipeline of patient-centric next-generation oncolytic viruses, which promises to dramatically improve the treatment of cancer."

Sakae Asanuma, President at Taiho Ventures, LLC, the corporate venture arm of Taiho Pharmaceutical Co. Ltd., said, "Taiho is delighted to co-lead this Series A financing and work with Theolytics to deliver the innovative oncolytic virotherapy generated by their unique proprietary platform technology, which should provide cancer patients with the promise of dramatically improving clinical outcomes."

Dr Kenneth Powell, Chair of the Board welcomed Henning Steinhagen, Venture Partner at Epidarex, and Sakae Asanuma, President at Taiho Ventures as new Board members, stating, "I look forward to working with our new investors to bring these promising approaches to cancer patients."

On January 7, 2020 Sanford Burnham Prebys Medical Discovery Institute reported that identified a new way to boost the immune system’s ability to fight cancer (Press release, Sanford-Burnham Medical Research Institute, JAN 7, 2020, View Source [SID1234553267]). The study, which was performed in collaboration with NYU Langone’s Perlmutter Cancer Center, used a mouse model to identify the importance of the Siah2 protein in the control of immune cells called T regulatory cells (Tregs), which limit the effectiveness of currently used immunotherapies. The research, which offers a new avenue to pursue immunotherapy in cases where the treatment fails, was published today in Nature Communications.

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"While Siah2 is involved in control of activities that govern cancer development, this study offers the first direct evidence for its role in the immune system, namely in anti-tumor immunity," says Ze’ev Ronai, Ph.D., professor in Sanford Burnham Prebys’ Tumor Initiation and Maintenance Program and senior author of the study. "Our study shows that a PD-1 inhibitor can be used to treat tumors that currently do not respond to this therapy, when administered in mice lacking the Siah2 gene, thereby offering a means to expand the effectiveness of immunotherapy. The findings also provide further justification for our efforts to find a drug that blocks Siah2."

The development of cancer immunotherapies, which harness the power of an individual’s immune system to destroy tumors, has revolutionized the treatment of certain cancers. For some people with advanced melanoma, a deadly skin cancer, the treatment has extended survival to years instead of months. However, the treatment only works for about 40% of people with advanced melanoma. The study from the Ronai lab offers a new means to make this treatment effective in individuals who at present do not respond to anti-PD-1 therapy.

Ronai explains, "In our study, mice lacking the Siah2 gene were able to mount an immune attack against melanoma. Moreover, the effectiveness of Siah2 in immunotherapy was demonstrated for ‘cold’ tumors—those that do not respond to immunotherapy—which were effectively eliminated by a PD-1 blockade in Siah2-mutant mice."

"Understanding the basic mechanisms of tumor immunity will ultimately help us improve the effectiveness of immunotherapy," says Michael Rape, Ph.D., Howard Hughes Investigator and professor of Cell and Developmental Biology at University of California, Berkeley. "This study uncovers an important layer in the regulation of key immune cell components that impact the effectiveness of cancer immunotherapy, highlighting the need to develop inhibitors for Tregs, in which a Siah2 inhibitor holds promise."

Scientists have known for many years that Siah2 is involved in cellular responses to hypoxia (low oxygen) and the unfolded protein response—two processes that are exploited by tumors to keep growing. Ronai has studied the protein for nearly a decade in hopes of finding better cancer treatments: His team is currently working to develop a small molecule drug that blocks the protein. Now, Ronai’s study shows that the protein also plays an important role in regulating the immune system’s response to a tumor.

In the study, the scientists used genetically engineered mice that did not produce the Siah2 protein and then introduced BRAF-mutant melanoma—a mutation that occurs in about half of human melanomas. This approach allowed the researchers to study the role of Siah2 in the tumor’s microenvironment, of which the immune system is a major component. In the absence of the Siah2 gene, the melanoma tumors receded—a stark contrast to mice with the Siah2 gene, in which the tumor continued to grow. Giving these mice anti-PD-1 therapy effectively eliminated melanoma that otherwise resisted this therapy, demonstrating a new path to enhance the effectiveness of current immunotherapies.

Digging deeper into their findings, the scientists discovered that in the Siah2 mutant mice, the tumors were infiltrated by killer but not Treg immune cells—indicating the immune system was more active in clearing the tumors. The lack of the Treg cells was attributed to reduced proliferation and recruitment into the tumor due to the role of Siah2 and its control of cell cycle regulatory proteins.

"Our discovery only fuels our sense of urgency to find a drug that inhibits Siah2," says Ronai. "Using an arsenal of novel approaches should enable us to advance the targeting of Siah2 in both the tumors and their microenvironment."

The first author of the study is Marzia Scortegagna, Ph.D., of Sanford Burnham Prebys. Additional study authors include Yongmei Feng, Ph.D., Dennis C. Otero, Ph.D., Linda M. Bradley, Ph.D., and Yan Li, M.D., Ph.D., of Sanford Burnham Prebys; Kathryn Hockemeyer, M.D., Ph.D., Igor Dolgalev and Ioannis Aifantis, Ph.D., of NYU School of Medicine; Joanna Poźniak, Ph.D., Florian Rambow, Ph.D., and Jean-Christophe Marine, Ph.D., of VIB; Roberto Tinoco, Ph.D., of Sanford Burnham Prebys and the University of California, Irvine; Tongwu Zhang, Ph.D., and Kevin Brown, Ph.D., of the National Cancer Institute; and Marcus Bosenberg, M.D., Ph.D., of Yale School of Medicine.