On September 16, 2020 The Institute of Cancer Research reported that Results from an early-stage trial demonstrate that using a combination of two precision medicines to target hard-to-treat cancers was safe and showed promise in a range of solid tumour types (Press release, The Institute of Cancer Research, SEP 16, 2020, View Source [SID1234565271]).

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The trial, led by a team at the Institute of Cancer Research (ICR) in London and the Royal Marsden NHS Foundation Trust, combined AstraZeneca/Merck’s PARP inhibitor Lynparza (olaparib) with the investigational medicine capivasertib, an AKT Kinase inhibitor.

The researchers used the drug combination to target two weaknesses in cancer, namely a damaged system for repairing DNA and ‘addiction’ to the AKT molecule which fuels tumour growth.

In the Phase I trial, researchers gave 64 patients with advanced solid tumours, including those with breast cancer, ovarian cancer and prostate cancers, combinations of Lynparza and capivasertib.

The trial found that the drug combination was safe to use and also efficiently hit the specified targets, and showed promise against a variety of advanced cancers, including those that had become resistant to chemotherapy.

According to the ICR, many of the patients who responded to the treatment had mutations in the genes involved in repairing DNA, including the BRCA genes.

"This new clinical trial is a terrific example of how we can now translate scientific discoveries about the biology of cancer cells into innovative new cancer treatments with real benefits for patients," said Professor Paul Workman, Chief Executive of the ICR.

"It’s also an example of the pioneering strategy we have adopted at the ICR of targeting cancer evolution and drug resistance – often through the use of combination treatments to hit multiple targets at once and block off escape routes, just as is done with diseases like HIV," he added.

The trial was funded by AstraZeneca, with the backing of the Cancer Research UK Experimental Cancer Medicine Centre Combinations Alliance.

Following the promising early results, later-stage clinical trials are planned to assess the drug combination’s benefit and to study its effect in patients whose tumours do not have faults in the AKT gene or related to DNA repair.

On September 16, 2020 Samsung Biologics (207940.KS) reported that it has entered into a service agreement with Panolos Bioscience to develop PB101, an Fc-fusion protein intended to treat solid tumors (Press release, Samsung BioLogics, SEP 16, 2020, View Source [SID1234565269]).

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Under this agreement, Samsung Biologics will provide a full scope of its development services from cell line development, process development, to non-clinical and clinical material manufacturing.

According to Panolos, PB101 is expected to suppress tumor angiogenesis more effectively by targeting VEGF-A and PlGF simultaneously, overcoming the limitations of existing treatments. Leveraging Samsung Biologics’ robust capabilities and expertise in developing complex proteins, Panolos intends to achieve successful IND approval for validation to further establish the substance as the new platform known as αARTTM(anti-angiogenesis-based Artifact Re-targeting Tri-specifics) to treat various VEGF related illnesses.

Dr. Hyeseong Lim, CEO of Panolos Bioscience stated, "PB101 is itself a promising candidate as a treatment for solid tumors and VEGF-related diseases. Furthermore, it is also a platform technology that has demonstrated its versatility as a foundation on which multi-specific biologics can be developed. Through close collaborative efforts, Panolos will endeavor to deliver quality biopharmaceuticals to address global unmet medical needs."

"We are extremely proud to be partnering with Panolos in bringing PB101 closer to market," said Dr. Tae Han Kim, CEO Samsung Biologics. "By delivering faster and better development services and helping our clients focus on discovery, we will continue supporting biotech companies in their efforts to help patients in need all around the globe."

On September 16, 2020 Yufan Biotechnologies reported that Exhaustion of T-cells is a key reason why CAR T-cell therapy may fail to control cancer (Press release, Yufan Biotechnologies, SEP 16, 2020, View Source [SID1234565268]). Recent work led by Xuebin Liao, PhD, Professor of Pharmaceutical Science at Tsinghua University (Si et al., Cancer Cell 2020) shows that HPK1 (hematopoietic progenitor kinase 1) promotes T cell exhaustion via NFkB-Blimp1 activation and that blocking HPK1, either by gene knockout or by small-molecule inhibitors, is an attractive strategy to improve CAR T-cell immunotherapy . These innovative approaches are being evaluated clinically by Yufan Biotechnologies, co-founded by Professor Liao and Yan Zhang, CEO.

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Yufan Biotechnologies has now partnered with Abound Bio, Inc, a life sciences company with world-renowned expertise in finding antibodies to direct CAR T-cells against cancer targets. Abound Bio was co-founded by Dimiter Dimitrov, PhD, and John Mellors, MD, CEO. The three-year partnership covers the incorporation of antibodies to novel cancer targets into the enhanced, HPK1-inhibited CAR T-cell platform.

"We are very excited by the potential to improve cancer therapy through the combination of Yufan’s enhanced CAR T-cell technology and Abound’s highly-specific antibodies," said John Mellors, CEO of Abound Bio.

"Dr. Dimitrov and Dr. Mellors are leading scientists. Our partnership with Abound Bio has the potential to improve CAR T-cell products for cancer therapy," said Yan Zhang, CEO of Yufan Biotechnologies.

The agreement covers 10 cancer targets over multiple years with shared inventorship and development rights for the new technologies.

On September 16, 2020 OCTIMET Oncology NV, a clinical-stage Belgian life science company with a focus on the development of highly selective, differentiated MET kinase inhibitors, reported the licensing of the Greater China rights for its lead clinical compound OMO-1 and a second preclinical asset exclusively to Shanghai Allist Pharmaceuticals Co., Ltd (Press release, Octimet Oncology, SEP 16, 2020, View Source [SID1234565266]).

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OMO-1 is an oral, highly selective small molecule MET kinase inhibitor, that has demonstrated potent single agent and combination activity in a range of preclinical cancer models.

OMO-1 has been evaluated in a monotherapy setting as well as in combination with small molecule EGFR tyrosine kinase inhibitors (TKIs) in Europe, showing a favorable safety profile and early signs of efficacy in MET-selected cancer patients. Allist will drive the clinical development of this compound in China, initially focusing on expanding the combination data with Allist’s third generation EGFR TKI Furmonertinib (AST2818). In China, more than 38% of NSCLC patients harbor activating EGFR mutations, making the region ideal for completing expanded clinical efficacy studies more rapidly whilst addressing a large potential market.

"We are proud to have Shanghai Allist Pharmaceuticals Co., Ltd. as a partner in developing this exciting therapeutic agent," said Shelley Margetson, Chief Executive Officer of OCTIMET. "Development in China is strategically important for OMO-1 and we look forward to seeing the results of the combination studies with Allist’s EGFR TKI compound, thereby making a difference for cancer patients in need of efficacious targeted therapies."

"MET amplification is known to be a key driver of resistance to EGFR TKIs. We are excited to explore further the combination of OMO-1, a differentiated selective MET kinase inhibitor, with our innovative third generation EGFR TKI Furmonertinib and look forward to generating significant efficacy data that will aim to meet clinical unmet need in providing further treatment for seriously ill cancer patients who have few other therapy options," said Ms. Sandy Mou, the CEO from Allist Pharmaceuticals.

About OMO-1

OMO-1 is a small molecule inhibitor of the enzymatic activity of the MET receptor tyrosine kinase (RTK). The MET gene has been shown to be responsible for some hereditary types of cancer. In addition, inappropriate MET activation has been shown in most types of solid tumors, often correlating with poor prognosis (Trusolino et al 2010, Gheradi et al 2012).

About EGFR Tyrosine Kinase Inhibitors

Lung cancer is the leading cause of cancer-related mortality worldwide. Of all lung cancer cases, 80–85% are non-small-cell lung cancers (NSCLC), and the majority of these cases are in advanced or metastatic stage (III or IV) at the time of diagnosis. Among these patients with NSCLC, a substantial number are harboring activating EGFR mutations, ranging from 10% in Europe to 38.4% in Asia. During the past years, EGFR tyrosine kinase inhibitors (TKIs) have been developed and have become standard first-line treatment for patients with EGFR mutation-positive NSCLC. Various trials showed higher response rates and improved progression-free survival (PFS) for first-line treatment with the EGFR TKIs afatinib, erlotinib, and gefitinib compared to platinum-based doublet therapy in patients with activating EGFR-mutated NSCLC.

On September 16, 2020 Kanazawa University reported in Nature Communications the mechanism making some lung-cancer patients resistant to the drug osimertinib (Press release, Kanazawa University, SEP 16, 2020, View Source [SID1234565264]). In addition, they suggest a combined drug treatment resolving osimertinib resistance in the case of cancer cells expressing low amounts of AXL, a protein belonging to the class of receptor tyrosine kinases.

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The effectiveness of cancer treatment is often hampered by cancer cells being heterogeneous. This is the case for EGFR-mutated lung cancer: drugs based on biomolecules of a type known as tyrosine kinase inhibitor (TKI) have been used to treat the disease, but with various levels of efficacy. (EGFR stands for "epidermal growth factor receptor", a protein playing an important role in signaling processes from the extracellular environment to a cell.) Sometimes, tumor cells are simply resistant to the drug. Now, Seiji Yano from Kanazawa University and colleagues have investigated the efficacy of the TKI osimertinib for treating EGFR-mutated lung cancer, and how it relates to the expression in tumor cells of a particular protein called AXL. They found that both AXL-high and -low expressing tumor cells showed tolerance (acquired resistance) to osimertinib, but that the mechanisms involved are different for the two situations. Moreover, the researchers suggest a way to enhance the success of osimertinib treatment for the case of AXL-low expressing tumors.

First, the scientists compared the susceptibility to osimertinib in both AXL-high and -low expressing tumor cells in in vitro experiments. They observed that osimertinib inhibited the viability of the cancer cells in both cases, but that the sensitivity to the drug was higher for AXL-low expressing EGFR-mutated lung cancer cells. They also noticed that a small number of tumor cells survived the procedure — an indication of osimertinib tolerance. These findings were consistent with results from the clinical study of the drug performed earlier on 29 patients with EGFR-mutated non-small cell lung cancer.

Through experiments aiming to understand the mechanism behind osimertinib tolerance, Yano and colleagues discovered that phosphorylation of IGF-1R was increased in AXL-low-expressing tumor cell lines, but not in AXL-high expressing tumors. (IGF-1R stands for ‘insulin-like growth factor 1 receptor’; it is a protein located on the surface of human cells. Phosphorylation is the chemical process of adding a phosphoryl group.) The researchers then found that phosphorylated IGF-1R supported the survival of AXL-low expressing tumors after exposure to osimertinib.

The scientists then tested whether the observed osimertinib resistance could be resolved by administering linsitinib, a substance known to inhibit the phosphorylation of IGF-1R. Encouraged by the positive outcome of the experiment, Yano and colleagues went further and evaluated the combination of osimertinib and linsitinib. Their conclusion was that the transient combination of linsitinib with continuous osimertinib treatment could cure or at least dramatically delay tumor recurrence in AXL-low-expressing EGFR-mutated lung cancer. More investigating needs to be done, though. Quoting the researchers: "… the safety and efficacy of the transient combination of IGF-1R inhibitor and osimertinib should be evaluated in the clinical trials."

Background

Tyrosine kinase inhibitors

A tyrosine kinase inhibitor is a drug inhibiting (that is, preventing or reducing the activity of) a specific tyrosine kinase. A tyrosine kinase is a protein (enzyme) involved in the activation of other proteins by signaling cascades. The activation happens by the addition of a phosphate group to the protein (phosphorylation); it is this step that a tyrosine kinase inhibitor inhibits. Tyrosine kinase inhibitors are used as anticancer drugs. One such drug is osimertinib, used to treat EGFR-mutated lung cancer.

AXL

AXL is a receptor tyrosine kinase — a tyrosine kinase consisting of an extracellular part, a transmembrane part (‘sitting’ within a cell membrane) and an intracellular part. AXL regulates various important cellular processes, including proliferation, survival and motility.

In recent years, it has become clear that AXL is a key facilitator of drug tolerance by cancer cells. Seiji Yano from Kanazawa University and colleagues have found that this is also the case for EGFR-mutated lung cancer. While a high expression of AXL correlates with resistance to osimertinib, such tolerance also occurs in AXL-low-expressing cancer cells. Yano and colleagues have now found that for the latter case, phosphorylation of IGF-1R (insulin-like growth factor 1 receptor) is responsible for the resistance to osimertinib.

Reference

Rong Wang, Tadaaki Yamada, Kenji Kita, Hirokazu Taniguchi, Sachiko Arai, Koji Fukuda, Minoru Terashima, Akihiko Ishimura, Akihiro Nishiyama, Azusa Tanimoto, Shinji Takeuchi, Koshiro Ohtsubo, Kaname Yamashita, Tomoyoshi Yamano, Akihiro Yoshimura, Koichi Takayama, Kyoichi Kaira, Yoshihiko Taniguchi, Shinji Atagi, Hisanori Uehara, Rikinari Hanayama, Isao Matsumoto, Xujun Han, Kunio Matsumoto, Wei Wang, Takeshi Suzuki, and Seiji Yano. Transient IGF-1R inhibition combined with osimertinib eradicates AXL-low expressing EGFR mutated lung cancer, Nature Communications 11, XX (2020).

DOI: 10.1038/s41467-020-18442-4