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Immunology

Opdivo and Yervoy Combination Wins Accelerated Approval for HCC – PharmaLive

The U.S. Food and Drug Administration (FDA) gave an accelerated greenlight to Bristol-Myers Squibbs combination of Opdivo and Yervoy as a treatment for hepatocellular carcinoma in patients who have been previously treated with Bayers Nexavar (sorafenib).

Approval for the combination treatment was based on results from the Phase I/II CheckMate-040 trial in which Opdivo and Yervoy showed an overall response rate of 33% in this patient population. Of those, 8% had a complete response and 24% showed a partial response. Duration of responses (DOR) ranged from 4.6 to 30.5 months, with 88% lasting at least six months, 56% at least 12 months and 31% at least 24 months, BMS said.

Anthony B. El-Khoueiry, BMS lead investigator and phase I program director at the Keck School of Medicine, University of Southern California, said the overall response rate observed in the Opdivo and Yervoy combination of the CheckMate-040 trial underscores the potential of this dual immunotherapy as a possible treatment option for patients.

Opdivo (nivolumab) and Yervoy (ipilimumab) are cornerstones of BMS immunology treatments. Opdivo, a programmed death-1 (PD-1) immune checkpoint inhibitor, has been approved for the treatment of multiple cancers, including patients with advanced renal cell carcinoma who have received prior anti-angiogenic therapy. Yervoy targets CTLA-4, a protein receptor that regulates the immune system.

The FDA gave the nod under accelerated approval. Continued approval in this indication may be contingent upon verification and description of clinical benefit in confirmatory trials, the company noted. The Opdivo and Yervoy combination is the first and only dual immunotherapy approved in this setting, BMS said. The company added that this is the fourth regulatory approval for cancer from the FDA for the combination treatment. The combination treatment had been previously granted both Breakthrough Therapy Designation for this indication and a Priority Review from the FDA.

Hepatocellular carcinoma (HCC) is the most common type of liver cancer in adults. HCC represents about 80% of all primary liver cancers. The disease occurs most often in people with chronic liver diseases, such as cirrhosis caused by hepatitis B or hepatitis C infection.

Adam Lenkowsky, general manager and head of U.S. Oncology, Immunology and Cardiovascular at Bristol-Myers Squibb, said there is a critical need to provide patients with aggressive forms of cancer such as HCC with new treatment options that may offer clinically meaningful and ultimately durable responses. The approval, Lenkowsky said, builds on the companys legacy in pioneering immunotherapy treatments.

The incidence of liver cancer is rising in the United States, and HCC is the most common and aggressive form of the disease, Andrea Wilson, president and founder of Blue Faery: The Adrienne Wilson Liver Cancer Association, said in a statement. Todays approval provides a new option for patients with HCC previously treated with sorafenib, giving the community more hope.

Last year, Eli Lilly snagged regulatory approval for Cyramza as a single agent for the second-line treatment of patients with hepatocellular carcinoma (HCC) who have an alpha-fetoprotein (AFP) and have previously been treated with sorafenib. Also in 2019, Alameda, Calif.-based Exelixis, Inc. won approval for its HCC treatment, Cabometyx (cabozantinib).

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Opdivo and Yervoy Combination Wins Accelerated Approval for HCC - PharmaLive

Immunology

UF Health researcher finds compounds that could potentially block COVID-19 – WCJB

GAINESVILLE, Fla. (WCJB) A UF Health researcher said he may have found compounds that could potentially block a coronavirus infection.

Assistant professor of pathology, immunology and lab medicine, David Ostrov, has used computer simulations to find three compounds that interact with the enzyme Human Ace-2. The virus uses this enzyme to infect cells in the body.

The simulations were run at the request of the Global Virus Network, an international group of scientists working to combat viral disease.

"They have compounds that they have reason to believe will interact with Human Ace-2, and what they asked us to do is try to determine if their compounds have the potential to bind Ace-2 in a manner that blocks the interaction with the coronavirus," Ostrov said.

The findings now must be validated by his peers.

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UF Health researcher finds compounds that could potentially block COVID-19 - WCJB

Immunology

‘Dr Tedros’, the WHO Chief Leading the Fight Against the Pandemic – The New York Times

GENEVA Tedros Adhanom Ghebreyesus, head of the World Health Organization (WHO), has become the public face of the global fight against coronavirus.

Here are some details of his career:

- A former health minister and foreign minister of Ethiopia, he was elected in May 2017 as the WHO's first African director-general, vowing to make universal health care his central priority.

His surprise appointment that year of Zimbabwes President Robert Mugabe as a goodwill ambassador outraged Western donors and activists and he was forced to withdraw it.

- Tedros, who goes by the name of Dr. Tedros, was born in Asmara, Eritrea. Now 55, he holds a doctorate of philosophy in community health and a master of science in immunology of infectious diseases, both from British universities.

- He is the first director-general in the WHO's 72-year history not to be a medical doctor. Since taking the helm, he has instituted reforms at the U.N. agency's headquarters in Geneva and 150 country offices, with a total of 7,000 staff.

- Tedros prides himself on going into the field to support WHO operations, making 10 trips to eastern Democratic Republic of Congo during its 19-month-old Ebola epidemic, now close to being halted.

- Weeks after the new coronavirus emerged in China, he flew to Beijing, returning with lavish praise for the Chinese leadership's commitment to fighting the disease through drastic lockdowns and other measures.

Lawrence Gostin, professor of global health law at Georgetown University Law School, told Reuters: "He's very political, there is no question. And sometimes he is too political."

"But what I love about him is that he wears his heart on his sleeve. He is out there personally, becoming the face of WHO, the face of the epidemic."

- Tedros, who now describes the new coronavirus as a pandemic, has voiced concern at the disease's "alarming levels of spread and severity", adding: "We have rung the alarm bell loud and clear."

(Editing by Giles Elgood)

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'Dr Tedros', the WHO Chief Leading the Fight Against the Pandemic - The New York Times

Immunology

Harbour BioMed Tacks on $75M to Advance Broad Biologics Pipeline – Xconomy

XconomyBoston

A biotech born out of an antibody platform company has added another $75 million to its investment haul, money it says will allow it to advance its clinical-stage compounds and continue to build its portfolio of earlier-stage therapeutics.

Shanghai-based Harbour BioMed emerged in 2016 after acquiring technology developed by Harbour Antibodies, a Dutch company that built a business around licensing out its antibody drug discovery technologytwo kinds of mice genetically engineered to create fully human antibodies, rather than engineered antibodies from mouse DNA.

Since then, Harbour BioMed, which launched with a plan focusing on drug development, has established a pipeline of experimental oncology and immunology treatments, including some developed using those mouse models.

Its most advanced proprietary candidate is HBM4003, a Phase 1 cancer immunotherapy designed to block the immune-system protein CTLA-4. (That is also the target of ipilimumab (Yervoy), which was the first FDA-approved checkpoint inhibitor, a type of immunotherapy.) A trial, underway in Australia, is the first in an international development program that will include studies in the US, EU and China, the company says. Its other immune-oncology programs are preclinical.

Its immunology products pipeline includes five in-licensed clinical-stage programs. Harbour BioMed is evaluating its most advanced, the dry eye disease treatment tanfanercept, with partner HanAll in a Phase 3 clinical trial. It has the rights to that and its other immunology programs in-licensed from HanAll in the China market.

Harbour BioMed founder and CEO Jingsong Wang previously worked at Sanofi (NYSE: SNY) as head of China R&D and head of translational medicine for the Asia Pacific region. In January 2019 Harbour BioMed added another Sanofi vet: Atul Deshpande, most recently global operations lead of Sanofi Genzymes dupilumab (Dupixent) franchise, who joined as chief strategy officer and head of US operations.

Since we have this in-house technology and really significant expertise in antibody engineering and antibody production itself, we have a lot of leverage in terms of playing around with different targets and formats of molecules, Deshpande says. That kind of innovation is what his team in the US is primarily focused on, he added.

The company says it plans to put its new money toward accelerating the advancement of its clinical-stage drug candidates and continuing to build its preclinical pipeline.

Harbour says its mouse models are especially useful because they eliminate the need for antibody humanization. And one of the two strains it has developed can generate antibodies that are smaller than usualthey consist of only heavy chains, rather than heavy chains and light chains like typical antibodieswhich makes them useful in the development of antibody fragment-based therapeutics such as nanobodies, bi-specific antibodies, and CAR-T.

Instead of solely licensing out the technology, as the iteration of the company from which it acquired the mouse models did, Harbour has entered into a number of collaborationsincluding one with the Mount Sinai Heath System in New York announced this month, through which the academic medical system will use the antibody discovery platform to seek potential treatments for COVID-19 as part of a larger multiyear collaboration to develop antibodies for treatment and prevention of disease.

The investment, announced Thursday, stemmed from a continuation of the conversations we started in preparation for the round B, an $85 million financing the company completed in August 2018, Deshpande says.

New investors that participated in the financingwhich the company dubbed its B plus roundwere Korean multinational SK Holdings, the Hong Kong-based Greater Bay Area Fund, Efung Capital, Zheshang Venture Capital, Zhejiang University Future Capital, and JT New Century. Earlier investors, including Legend Capital, private equity firm Advantech Capital, and GIC, a Singaporean sovereign wealth fund, also kicked in funds.

Harbour has about 170 employees, mostly in China in offices in Suzhou and Shanghai. About 10 people with the company work in Cambridge, MA. The company also has an office in Rotterdam, The Netherlands, where the mouse model technology was invented, which focuses on advancing those platforms.

Sarah de Crescenzo is an Xconomy editor based in San Diego. You can reach her at sdecrescenzo@xconomy.com.

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Harbour BioMed Tacks on $75M to Advance Broad Biologics Pipeline - Xconomy

Immunology

GEMoaB Announces Internationally Renowned Experts to Newly Formed Strategic and Scientific Advisory Board – Yahoo Finance

DRESDEN, Germany, March 12, 2020 /PRNewswire/ -- GEMoaB, a biopharmaceutical company focused on the development of next generation immunotherapies for hard-to-treat cancers, today announced the appointment of five distinguished scientific, clinical and public affairs leaders to its inaugural Strategic and Scientific Advisory Board. The group will provide counsel to support the continued development of the company's proprietary immune-oncology platforms and help to shape the company's broader strategic and scientific decisions and plans.

GEMoaB Logo (PRNewsfoto/GEMoaB GmbH)

"We are thrilled to have this group of experts join our Strategic and Scientific Advisory Board," said Michael Pehl, CEO of GEMoaB. "We look forward to working closely with our Strategic and Scientific Advisory Board members as we continue to build a fully integrated and leading biopharmaceutical company and accelerate our UniCAR, RevCAR and ATAC pipeline efforts to bring them to cancer patients in need."

Members of GEMoaB's Strategic and Scientific Advisory Board are:

Professor Dr. Gerhard Ehninger Gerhard is GEMoaB's co-founder and Chief Medical Officer and will chair the Strategic and Scientific Advisory board. He is a pioneer in the field of cancer cell therapies and has dedicated his career to clinical and translational oncology research. Gerhard was Head of Hematology & Oncology, University Hospital 'Carl Gustav Carus', Technical University Dresden, Germany as well as the former President of the German Society of Hematology and Oncology (DGHO). Furthermore, Gerhard is co-founder of the German Bone Marrow Donor Registry (DKMS), Chief Executive Officer and founding shareholder at Cellex Gesellschaft fr Zellgewinnung mbH and founding shareholder of GEMoaB Monoclonals GmbH.

Professor Dr. Michael BachmannDr. Bachmann is an internationally leading expert in tumor immunology and founding shareholder of GEMoaB Monoclonals GmbH. Dr. Bachmann is Director of the Institute for Radiopharmaceutical Cancer Research, Helmholtz-Center Dresden, Germany as well as Head of Radioimmunology, Helmholtz-Center Dresden, Germany. In addition, Dr. Bachmann is Head of Tumor Immunology, University Cancer Center (UCC), University Hospital 'Carl Gustav Carus', Technical University Dresden, Germany and Deputy Head of the Working Group Tumor Immunology of the German Society for Immunology (Deutsche Gesellschaft fr Immunologie, DGfI).

Professor Dr. Bob Lwenberg Dr. Lwenberg's unique scientific career has focused on the pathobiology, molecular diagnostic, clinical and translational research of acute myeloid leukemia. Dr Lwenberg is Professor of Hematology and is the former Chairman of the Department of Hematology at Erasmus University Medical Center, Rotterdam, the Netherlands. Dr. Lwenberg was one of the founders and has served as President of the European Hematology Association (EHA). He has been president of the International Society of Experimental Hematology and the International Society of Hematology. He is former Chairman of the Scientific Advisory Board and current member of the Board of the European School of Hematology (Paris). He founded and subsequently served as the first president of the Dutch-Belgian Cooperative Group on Hemato-Oncology in Adults (HOVON), one of the leading cooperative clinical trial consortia in hemato-oncology in Europe. Between 2013-2020, Dr. Lwenberg was the Editor-in-Chief of Blood, the official journal of the American Society of Hematology. Bob Lwenberg is an elected member of the Royal Academy of Sciences and Arts of the Netherlands.

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Dr. Thomas de Maizire Dr. de Maizire is a member of the German Parliament, Member of the Finance Committee of the German Parliament, former German Federal Minister and has throughout his distinguished career served in multiple key public and governmental roles in Germany. Dr. de Maizire has been Head of State Chancellery of Mecklenburg-Vorpommern, Minister of State and Head of State Chancellery of Saxony, Minister of State of Finance of Saxony, Minister of State of Justice of Saxony, Minister of State of the Interior of Saxony, Federal Minister and Head of Federal Chancellery of Germany, German Federal Minister of the Interior and German Federal Minister of Defence.

Professor Dr. Katy Rezvani Dr. Rezvani is the Director of Translational Research, Medical Director of the MD Anderson GMP and Cell Therapy Laboratory and Chief, Section of Cellular Therapy, Department of Stem Cell Transplant and Cellular Therapy, MD Anderson Cancer Center in Houston/Texas, USA. Dr. Rezvani joined the faculty at the MDACC in 2012 from the Hammersmith Hospital in London, where she was Director of the allogeneic adult stem cell transplant program, Medical Director of the GMP facility and Director of the Transplant Immunology Research Laboratory. Dr. Rezvani has an active research laboratory program in transplantation immunology where the focus of her research group is to study the role of natural killer cells (NK) cells in mediating immunity against leukemia, and to understand the mechanisms of tumor-induced NK cell dysfunction

"Our efforts are focused on maximizing the potential of engineered cellular therapies in hematology and oncology," said Professor Dr. Gerhard Ehninger, GEMoaB's co-founder and Chief Medical Officer. "The deep expertise and past experiences of all of our Strategic and Scientific Advisory Board members will bolster GEMoAB's ability to positively impact patients' lives."

About GEMoaB

GEMoaB is a privately-owned, clinical-stage biopharmaceutical company that isaiming to become a globally leading biopharmaceutical company. By advancing its proprietary UniCAR, RevCAR and ATAC platforms, the company will discover, develop, manufacture and commercialize next generation immunotherapies for the treatment of cancer patients with a high unmet medical need.

GEMoaB has a broad pipeline of product candidates in pre-clinical and clinical development for the treatment of hematological malignancies as well as solid tumors. Its clinical stage assets GEM333, an Affinity-Tailored Adaptor for T-Cells (ATAC) with binding specificity to CD33 in relapsed/refractory AML, and GEM3PSCA, an ATAC with binding specificity to PSCA for the treatment of castrate-resistant metastatic prostate cancer and other PSCA expressing late-stage solid tumors, are currently investigated in Phase I studies and globally partnered with Bristol-Myers Squibb/Celgene. A Phase IA dose-finding study of the first UniCAR asset, UniCAR-T-CD123 for treatment of relapsed/refractory AML and ALL has been initiated, UniCAR-T-PSMA against CRPC and other PSMA-expressing late-stage solid tumors, is planned to be tested in a Phase I study initiated by H2 2020.

Manufacturing expertise, capability and capacity are key for developing cellular immunotherapies for cancer patients. GEMoaB has established a preferred partnership with its sister company Cellex in Cologne, a world leader in manufacturing hematopoietic blood stem cell products and a leading European CMO for CAR-T cells, co-operating in that area with several large biotech companies.

About UniCAR

GEMoaB is developing a rapidly switchable universal CAR-T platform, UniCAR, to improve the therapeutic window and increase efficacy and safety of CAR-T cell therapies in more challenging cancers, including solid tumors. Standard CAR-T cells depend on the presence and direct binding of cancer antigens for activation and proliferation. An inherent key feature of the UniCAR platform is a rapidly switchable on/off mechanism (less than 4 hours after interruption of TM supply) enabled by the short pharmacokinetic half-life and fast internalization of soluble adaptors termed targeting modules (TMs). These TMs provide the antigen-specificity to activate UniCAR gene-modified T-cells (UniCAR-T) and consist of a highly flexible antigen-binding moiety, linked to a small peptide motif recognized by UniCAR-T.

About ATAC

GEMoaB's platform of Affinity-Tailored Adaptors for T-Cells (ATAC) is characterized by high binding affinity to tumor antigens and lower affinity to the CD3 antigen on effector T-cells, preventing T-cell auto-activation in pre-clinical models. Safety and tolerability of the treatment are also increased by the relatively short serum half-life (60 min). The use of fully humanized antibodies reduces the risk of immunogenicity even in case of chronic dosing. Half-life extended ATACs are in pre-clinical development.

More information can be found at http://www.gemoab.com.

Forward-looking Statements

This announcement includes forward-looking statements that involve risks, uncertainties and other factors, many of which are outside of our control, that could cause actual results to differ materially from the results and matters discussed in the forward looking statements. Forward looking statements include statements concerning our plans, goals, future events and or other information that is not historical information.

The Company does not assume any liability whatsoever for forward-looking statements. The Company assumes that potential partners will perform and rely on their own independent analyses as the case may be. The Company will be under no obligation to update the Information.

GEMoaB Monoclonals GmbHTatzberg 4701307 DresdenGERMANY

For further information please contactConstanze Medackc.medack@gemoab.com; Tel.: +49 351 4466-45027

Investor ContactMichael Pehlm.pehl@gemoab.com; Tel.: +49 351 4466-45030

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SOURCE GEMoaB

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GEMoaB Announces Internationally Renowned Experts to Newly Formed Strategic and Scientific Advisory Board - Yahoo Finance

Immunology

Test Kits, Antiviral Drugs And Vaccines: The Science You Need To Know About Coronavirus – Iowa Public Radio

For resources on the coronavirus, visit the CDCs page here. NPRs coverage of the coronavirus outbreak is available here.

What does it take to make an effective vaccine quickly? Why are testing kits so hard to find? What makes this coronavirus so virulent? Well dig deep into the science you need to know.

Tina Hesman Saey, senior writer on molecular biology for Science News. (@thsaey)

Dr. Yvonne Maldonado,An expert on infectious diseases. Professor of pediatrics and health research and policyat Stanford University Medical School. (@StanfordMed)

Dr. Mark Denison, professor of pathology, microbiology, immunology and pediatrics at Vanderbilt University. (@DenisonLab)

Science News:Repurposed drugs may help scientists fight the new coronavirus As the new coronavirus makes its way around the world, doctors and researchers are searching for drugs to treat the ill and stop the spread of the disease, which has already killed more than 3,800 people since its introduction in Wuhan, China, in December.

The culprit virus is in the same family as the coronaviruses that caused two other outbreaks, severe acute respiratory syndrome and Middle East respiratory syndrome. But the new coronavirus may be more infectious. In early March, the number of confirmed cases of the new disease, called COVID-19, had exceeded 100,000, far surpassing the more than 10,600 combined total cases of SARS and MERS.

Health officials are mainly relying on quarantines to try to contain the virus spread. Such low-tech public health measures were effective at stopping SARS in 2004, Anthony Fauci, director of the U.S. National Institute of Allergy and Infectious Diseases, said January 29 in Arlington, Va., at the annual American Society for Microbiologys Biothreats meeting.

Science News: What you need to know about coronavirus testing in the U.S. U.S. government officials say a million promised tests for diagnosing coronavirus infections will soon be in the mail. But that still leaves many state and local laboratories without the ability to test for the virus, crucial for curbing its spread around the country.

Some states have developed their own tests. Clinical testing companies are now joining the ranks. LabCorp announced March 5 that physicians or other authorized health care providers could already order its test. Quest Diagnostics announced the same day that the company will also offer commercial tests as soon as March 9, pending U.S. Food and Drug Administration reviews.

Participation of those two commercial laboratories could greatly expand testing capacity in the United States. But for now, we still find ourselves as a country with pretty limited capacity to test, says Michael Mina, an epidemiologist at the Harvard T.H. Chan School of Public Health in Boston.

STAT News: To develop a coronavirus vaccine, synthetic biologists try to outdo nature Even as companies rush to develop and test vaccines against the new coronavirus, the Bill and Melinda Gates Foundation and the National Institutes of Health are betting that scientists can do even better than whats now in the pipeline.

If, as seems quite possible, the Covid-19 virus becomes a permanent part of the worlds microbial menagerie rather than being eradicated like the earlier SARS coronavirus, next-gen approaches will be needed to address shortcomings of even the most cutting-edge vaccines: They take years to develop and manufacture, they become obsolete if the virus evolves, and the immune response they produce is often weak.

With Gates and NIH funding, the emerging field of synthetic biology is answering the SOS over Covid-19, aiming to engineer vaccines that overcome these obstacles. Its all of us against the bug, said Neil King of the University of Washington, who has been part of the hunt for a coronavirus vaccine since 2017.

This article was originally published on WBUR.org.

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Test Kits, Antiviral Drugs And Vaccines: The Science You Need To Know About Coronavirus - Iowa Public Radio

Immunology

Covid-19 immunotherapy to be developed by CEL-SCI. – Pharmaceutical Technology

]]> This scanning electron microscope image shows SARS-CoV-2 (yellow)also known as 2019-nCoV, the virus that causes Covid-19. Credit: NIAID-RML.

Visit our Covid-19 microsite for the latest coronavirus news, analysis and updates

Follow the latest updates of the outbreakon ourtimeline.

Biotechnology company CEL-SCI has begun efforts to develop an immunotherapy for the potential treatment of Covid-19 coronavirus infection.

The company will leverage its LEAPS peptide technology, which could enable immunotherapeutic peptides with antiviral, as well as anti-inflammatory effects.

CEL-SCI notes that LEAPS peptides will use conserved regions of coronavirus proteins to induce protective cell-mediated T-cell responses and also decrease viral load.

In addition to acting on the viral infection, these peptides should trigger a protective response.

Previously, the LEAPS peptides were tested against another respiratory virus, called pandemic influenza (H1N1), in studies performed in alliance with the National Institutes for Allergies and Infectious Diseases (NIAID).

Findings in mice models showed protection from morbidity and mortality via activation of T-cell responses instead of an inflammatory response.

CEL-SCI cellular immunology senior vice-president of research Daniel Zimmerman said: We believe that a LEAPS Covid-19 coronavirus peptide will reduce or arrest the progression of the virus infection and prevent tissue damage from inflammation resulting from lung infection by the virus.

In short, we believe that we can stimulate the correct immune responses to the virus without producing unwanted inflammatory responses associated with lung tissue damage. That should be particularly important in the older population who is at highest risk of dying from this virus.

The proposed LEAPS peptides will target antigens in Covid-19s NP protein and trigger cytolytic T-cell responses, said the company.

CEL-SCI adds that cytolytic T-cell responses target the cellular factories infected by the virus within the host and eliminate the source of the infection.

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Covid-19 immunotherapy to be developed by CEL-SCI. - Pharmaceutical Technology

Anatomy

Understanding SARS-CoV-2 and the drugs that might lessen its power – The Economist

Mar 12th 2020

THE INTERCONNECTEDNESS of the modern world has been a boon for SARS-CoV-2. Without planes, trains and automobiles the virus would never have got this far, this fast. Just a few months ago it took its first steps into a human host somewhere in or around Wuhan, in the Chinese province of Hubei. As of this week it had caused over 120,000 diagnosed cases of covid-19, from Troms to Buenos Aires, Alberta to Auckland, with most infections continuing to go undiagnosed (see article).

But interconnectedness may be its downfall, too. Scientists around the world are focusing their attention on its genome and the 27 proteins that it is known to produce, seeking to deepen their understanding and find ways to stop it in its tracks. The resulting plethora of activity has resulted in the posting of over 300 papers on MedRXiv, a repository for medical-research work that has not yet been formally peer-reviewed and published, since February 1st, and the depositing of hundreds of genome sequences in public databases. (For more coverage of covid-19 see our coronavirus hub.)

The assault on the vaccine is not just taking place in the lab. As of February 28th Chinas Clinical Trial Registry listed 105 trials of drugs and vaccines intended to combat SARS-CoV-2 either already recruiting patients or proposing to do so. As of March 11th its American equivalent, the National Library of Medicine, listed 84. This might seem premature, considering how recently the virus became known to science; is not drug development notoriously slow? But the reasonably well-understood basic biology of the virus makes it possible to work out which existing drugs have some chance of success, and that provides the basis for at least a little hope.

Even if a drug were only able to reduce mortality or sickness by a modest amount, it could make a great difference to the course of the disease. As Wuhan learned, and parts of Italy are now learning, treating the severely ill in numbers for which no hospitals were designed puts an unbearable burden on health systems. As Jeremy Farrar, the director of the Wellcome Trust, which funds research, puts it: If you had a drug which reduced your time in hospital from 20 days to 15 days, thats huge.

Little noticed by doctors, let alone the public, until the outbreak of SARS (severe acute respiratory syndrome) that began in Guangdong in 2002, the coronavirus family was first recognised by science in the 1960s. Its members got their name because, under the early electron microscopes of the period, their shape seemed reminiscent of a monarchs crown. (It is actually, modern methods show, more like that of an old-fashioned naval mine.) There are now more than 40 recognised members of the family, infecting a range of mammals and birds, including blackbirds, bats and cats. Veterinary virologists know them well because of the diseases they cause in pigs, cattle and poultry.

Virologists who concentrate on human disease used to pay less attention. Although two long-established coronaviruses cause between 15% and 30% of the symptoms referred to as the common cold, they did not cause serious diseases in people. Then, in 2002, the virus now known as SARS-CoV jumped from a horseshoe bat to a person (possibly by way of some intermediary). The subsequent outbreak went on to kill almost 800 people around the world.

Some of the studies which followed that outbreak highlighted the fact that related coronaviruses could easily follow SARS-CoV across the species barrier into humans. Unfortunately, this risk did not lead to the development of specific drugs aimed at such viruses. When SARS-CoV-2similarly named because of its very similar genomeduly arrived, there were no dedicated anti-coronavirus drugs around to meet it.

A SARS-CoV-2 virus particle, known technically as a virion, is about 90 nanometres (billionths of a metre) acrossaround a millionth the volume of the sort of cells it infects in the human lung. It contains four different proteins and a strand of RNAa molecule which, like DNA, can store genetic information as a sequence of chemical letters called nucleotides. In this case, that information includes how to make all the other proteins that the virus needs in order to make copies of itself, but which it does not carry along from cell to cell.

The outer proteins sit athwart a membrane provided by the cell in which the virion was created. This membrane, made of lipids, breaks up when it encounters soap and water, which is why hand-washing is such a valuable barrier to infection.

The most prominent protein, the one which gives the virions their crown- or mine-like appearance by standing proud of the membrane, is called spike. Two other proteins, envelope protein and membrane protein, sit in the membrane between these spikes, providing structural integrity. Inside the membrane a fourth protein, nucleocapsid, acts as a scaffold around which the virus wraps the 29,900nucleotides of RNA which make up its genome.

Though they store their genes in DNA, living cells use RNA for a range of other activities, such as taking the instructions written in the cells genome to the machinery which turns those instructions into proteins. Various sorts of virus, though, store their genes on RNA. Viruses like HIV, which causes AIDS, make DNA copies of their RNA genome once they get into a cell. This allows them to get into the nucleus and stay around for years. Coronaviruses take a simpler approach. Their RNA is formatted to look like the messenger RNA which tells cells what proteins to make. As soon as that RNA gets into the cell, flummoxed protein-making machinery starts reading the viral genes and making the proteins they describe.

First contact between a virion and a cell is made by the spike protein. There is a region on this protein that fits hand-in-glove with ACE2, a protein found on the surface of some human cells, particularly those in the respiratory tract.

ACE2 has a role in controlling blood pressure, and preliminary data from a hospital in Wuhan suggest that high blood pressure increases the risks of someone who has contracted the illness dying of it (so do diabetes and heart disease). Whether this has anything to do with the fact that the viruss entry point is linked to blood-pressure regulation remains to be seen.

Once a virion has attached itself to an ACE2 molecule, it bends a second protein on the exterior of the cell to its will. This is TMPRSS2, a protease. Proteases exist to cleave other proteins asunder, and the virus depends on TMPRSS2 obligingly cutting open the spike protein, exposing a stump called a fusion peptide. This lets the virion into the cell, where it is soon able to open up and release its RNA (see diagram).

Coronaviruses have genomes bigger than those seen in any other RNA virusesabout three times longer than HIVs, twice as long as the influenza viruss, and half as long again as the Ebola viruss. At one end are the genes for the four structural proteins and eight genes for small accessory proteins that seem to inhibit the hosts defences (see diagram). Together these account for just a third of the genome. The rest is the province of a complex gene called replicase. Cells have no interest in making RNA copies of RNA molecules, and so they have no machinery for the task that the virus can hijack. This means the virus has to bring the genes with which to make its own. The replicase gene creates two big polyproteins that cut themselves up into 15, or just possibly 16, short non-structural proteins (NSPs). These make up the machinery for copying and proofreading the genomethough some of them may have other roles, too.

Once the cell is making both structural proteins and RNA, it is time to start churning out new virions. Some of the RNA molecules get wrapped up with copies of the nucleocapsid proteins. They are then provided with bits of membrane which are rich in the three outer proteins. The envelope and membrane proteins play a large role in this assembly process, which takes place in a cellular workshop called the Golgi apparatus. A cell may make between 100 and 1,000 virions in this way, according to Stanley Perlman of the University of Iowa. Most of them are capable of taking over a new celleither nearby or in another bodyand starting the process off again.

Not all the RNA that has been created ends up packed into virions; leftovers escape into wider circulation. The coronavirus tests now in use pick up and amplify SARS-CoV-2-specific RNA sequences found in the sputum of infected patients.

Because a viral genome has no room for free riders, it is a fair bet that all of the proteins that SARS-CoV-2 makes when it gets into a cell are of vital importance. That makes each of them a potential target for drug designers. In the grip of a pandemic, though, the emphasis is on the targets that might be hit by drugs already at hand.

The obvious target is the replicase system. Because uninfected cells do not make RNA copies of RNA molecules, drugs which mess that process up can be lethal to the virus while not necessarily interfering with the normal functioning of the body. Similar thinking led to the first generation of anti-HIV drugs, which targeted the process that the virus uses to transcribe its RNA genome into DNAanother thing that healthy cells just do not do.

Like those first HIV drugs, some of the most promising SARS-CoV-2 treatments are molecules known as nucleotide analogues. They look like the letters of which RNA or DNA sequences are made up; but when a virus tries to use them for that purpose they mess things up in various ways.

The nucleotide-analogue drug that has gained the most attention for fighting SARS-CoV-2 is remdesivir. It was originally developed by Gilead Sciences, an American biotechnology firm, for use against Ebola fever. That work got as far as indicating that the drug was safe in humans, but because antibody therapy proved a better way of treating Ebola, remdesivir was put to one side. Laboratory tests, though, showed that it worked against a range of other RNA-based viruses, including SARS-CoV, and the same tests now show that it can block the replication of SARS-CoV-2, too.

There are now various trials of remdesivirs efficacy in covid-19 patients. Gilead is organising two in Asia that will, together, involve 1,000 infected people. They are expected to yield results in mid- to late-April. Other nucleotide analogues are also under investigation. When they screened seven drugs approved for other purposes for evidence of activity against SARS-CoV-2, a group of researchers at the State Key Laboratory of Virology in Wuhan saw some potential in ribavirin, an antiviral drug used in the treatment of, among other things, hepatitis C, that is already on the list of essential medicines promulgated by the World Health Organisation (WHO).

Nucleotide analogues are not the only antiviral drugs. The second generation of anti-HIV drugs were the protease inhibitors which, used along with the original nucleotide analogues, revolutionised the treatment of the disease. They targeted an enzyme with which HIV cuts big proteins into smaller ones, rather as one of SARS-CoV-2s NSPs cuts its big polyproteins into more little NSPs. Though the two viral enzymes do a similar job, they are not remotely relatedHIV and SARS-CoV-2 have about as much in common as a human and a satsuma. Nevertheless, when Kaletra, a mixture of two protease inhibitors, ritonavir and lopinavir, was tried in SARS patients in 2003 it seemed to offer some benefit.

Another drug which was developed to deal with other RNA-based virusesin particular, influenzais Favipiravir (favilavir). It appears to interfere with one of the NSPs involved in making new RNA. But existing drugs that might have an effect on SARS-CoV-2 are not limited to those originally designed as antivirals. Chloroquine, a drug mostly used against malaria, was shown in the 2000s to have some effect on SARS-CoV; in cell-culture studies it both reduces the viruss ability to get into cells and its ability to reproduce once inside them, possibly by altering the acidity of the Golgi apparatus. Camostat mesylate, which is used in cancer treatment, blocks the action of proteases similar to TMPRSS2, the protein in the cell membrane that activates the spike protein.

Not all drugs need to target the virus. Some could work by helping the immune system. Interferons promote a widespread antiviral reaction in infected cells which includes shutting down protein production and switching on RNA-destroying enzymes, both of which stop viral replication. Studies on the original SARS virus suggested that interferons might be a useful tool for stopping its progress, probably best used in conjunction with other drugs

Conversely, parts of the immune system are too active in covid-19. The virus kills not by destroying cells until none are left, but by overstimulating the immune systems inflammatory response. Part of that response is mediated by a molecule called interleukin-6one of a number of immune-system modulators that biotechnology has targeted because of their roles in autoimmune disease.

Actemra (tocilizumab) is an antibody that targets the interleukin-6 receptors on cell surfaces, gumming them up so that the interleukin-6 can no longer get to them. It was developed for use in rheumatoid arthritis. China has just approved it for use against covid-19. There are anecdotal reports of it being associated with clinical improvements in Italy.

While many trials are under way in China, the decline in the case rate there means that setting up new trials is now difficult. In Italy, where the epidemic is raging, organising trials is a luxury the health system cannot afford. So scientists are dashing to set up protocols for further clinical trials in countries expecting a rush of new cases. Dr Farrar said on March 9th that Britain must have its trials programme agreed within the week.

International trials are also a high priority. Soumya Swaminathan, chief scientist at the WHO, says that it is trying to finalise a master protocol for trials to which many countries could contribute. By pooling patients from around the world, using standardised criteria such as whom to include and how to measure outcomes, it should be possible to create trials of thousands of patients. Working on such a large scale makes it possible to pick up small, but still significant, benefits. Some treatments, for example, might help younger patients but not older ones; since younger patients are less common, such an effect could easily be missed in a small trial.

The caseload of the pandemic is hard to predict, and it might be that even a useful drug is not suitable in all cases. But there are already concerns that, should one of the promising drugs prove to be useful, supplies will not be adequate. To address these, the WHO has had discussions with manufacturers about whether they would be able to produce drugs in large enough quantities. Generic drug makers have assured the organisation that they can scale up to millions of doses of ritonavir and lopinavir while still supplying the HIV-positive patients who rely on the drugs. Gilead, meanwhile, has enough remdesivir to support clinical trials and, thus far, compassionate use. The firm says it is working to make more available as rapidly as possible, even in the absence of evidence that it works safely.

In the lab, SARS-CoV-2 will continue being dissected and mulled over. Details of its tricksiness will be puzzled out, and the best bits of proteins to turn into vaccines argued over. But that is all for tomorrow. For today doctors can only hope that a combination of new understanding and not-so-new drugs will do some good.

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This article appeared in the Briefing section of the print edition under the headline "Anatomy of a killer"

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Understanding SARS-CoV-2 and the drugs that might lessen its power - The Economist

Anatomy

Who Will Grey’s Hook Jo Up With Now That Alex Is Gone? – E! NEWS

Dr. Jo Wilson is back on the market.

Now that Grey's Anatomy has finally said goodbye to OG character Dr. Alex Karev in truly shocking fashion after Justin Chambers' sudden departure from the series in January, leaving Jo (Camilla Luddington) stunned as she learned her husband had children with long-lost love Izzie Stevens and was both divorcing her and leaving her all his shares in Grey Sloan Memorial, it's time to look towards the future.

Namely, Jo's future romantic prospects.

Sure, there will be a mourning period as Jo processes the way in which her world just turned upside down. But that will end and then the show will get back to what it does best: pairing her off with someone new. (And as for Luddington's real-life pregnancy with baby No. 2 that she just announced, here's hoping the show does not add an especially cruel twist to this whole Alex debacle and make her pregnant with his child after he abandoned her. There's enough baby drama going on with Amelia. We don't need any more. )

While much of Grey's' cast of male characters are already paired off, there are a few available men with whom Jo just might find a perfect match. Let's break 'em down.

Dr. Andrew DeLuca (Giacomo Gianniotti):Never forget that DeLuca and Jo did spark a connection that got him beaten to a pulp in the season 12 finale by Alex when he misunderstood what, exactly, was going on between the two in the loft. (DeLuca was just helping a very drunk Jo into bed, like a gentleman.) Now that DeLuca has ended things with Meredith (Ellen Pompeo), he and Jo could explore what was once there between the two of them. Butand it's a big butthe mania he's currently displaying, causing everyone to fear the possibility that his father's bipolar disorder may be manifesting in him, has us thinking this could also be a major recipe for disaster. Not that Grey's has every shied away from that, though.

Dr. Atticus "Link" Lincoln (Chris Carmack): The hunky new Chief of Orthopedic Surgery arrived on the show last season with a built-in history with Jo as the two were good friends growing up and have resumed their friendship, becoming the other's closest confidant at the hospital. With his relationship with a pregnant Amelia (Caterina Scorsone) on the rocks over the possibility that her baby isn't his, we could easily see Link and Jo going from leaning on one another to laying with one another, if you catch our drift. Although, if the baby is his... (Again, that sort of extra wrinkle isn't exactly one the show would try and avoid. It might just make this all the more likely.)

Dr. Cormac Hayes (Richard Flood): Sure, Cristina Yang (Sandra Oh) sent McWidow to Grey Sloan as a gift for her person, Mer. And there's no denying that the two sure have a lot in common, much more than she ever did with DeLuca, and there's certainly something brewing there. But, if we're being frank, we'd rather see the Irish new head of Pediatric Surgery remain friends with Mer, giving her someone to navigate widowhood alongside while not complicating things with romance, too. And don't forget, Jo and Hayes did share a brief, if incredibly charged moment in the nursery when she was struggling to hand off the baby that had been surrendered at Station 19. We wouldn't mind if the show let Hayes replace Alex in every sense, having him become Jo's new love and Mer's new BFF.

Someone We've Never Met: Of course, showrunner Krista Vernoff might opt to introduce a new character entirely as she sets out to chart Jo's romantic recovery post-Alex. And that might not be the worst thing. Only time will tell...

Grey's Anatomy airs Thursdays at 9 p.m. on ABC.

Watch E! News weekday mornings at 7 a.m.!

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Who Will Grey's Hook Jo Up With Now That Alex Is Gone? - E! NEWS

Embryology

‘Child whisperer’: Mary Mello’s teaching legacy revered | Local News – Barre Montpelier Times Argus

MONTPELIER Mary Mello will say farewell to Union Elementary School after 50 years of teaching at the end of the school year.

Its very, very good work (in kindergarten) at the beginning, when they come in, theyre so full of enthusiasm, they think they know it all and they cant wait to learn more, and thats a wonderful setting for a teacher, Mello said. Your big job is to keep that going. You dont want them to lose that incredible curiosity about the world and the thrill for them when they learn something.

Born in 1946, Mello grew up in Boston and received a bachelors degree in English from Northeastern University in 1969 and a masters in education from Johnson State College in 1980.

Mello first started teaching in the 1969-1970 school year at a private school in Boston before moving to Vermont in 1972, when she started at UES, teaching first and second grades, and then in kindergarten from 1983 onward, where Mello said she found her calling.

Mello said when dealing with children with attention deficits or lack of focus, she would adopt a more individualistic approach to teaching and learning.

With young children, youre going to do less work with large groups and more work with small groups, so individualizing is a very natural part of what youre doing in kindergarten, Mello said. You would have to know your children pretty well to group them.

Even in math, were doing more small-group work, and we have set up for them to work independently when working with small groups, so you can take every child when they come in as far as they can go, she added.

Mello said she focused on teaching children to read to help them develop other academic skills later on.

If they can become excited and engaged about reading, I make sure that I keep that going, Mello said.

Milestones in education for Mello include a 1975 law that said special-education students should not be isolated from mainstream learning.

Ive seen things evolve over time ... with special education, which required that all students receive an education in the least-restrictive environment, Mello said. That meant that all children could be included in a public-school education.

Now, we find ways to support children so they can feel included and at home here, no matter what cognitive, physical difficulties, challenges they had. Vermont was a good pioneer in that, the idea that all children belong here and its our job to make sure we understand any challenges theyre dealing with, she added.

Mello also noted changes, over the years, in racial and ethnic diversity in the school system.

National Life is bringing in a lot of families from overseas, so our children are getting to know people they wouldnt have known until they were adults, Mello said. Weve had a lot of families from India, but Ive also taught children from Russia, Nicaragua, and two years ago, there were seven different languages spoken in my classroom such as Japanese, Russian, Hispanic, Indian (and) American Indian. It really does add a lot to the richness of the education of these children.

Mello said the school systems English language-learner teachers encourage children and families to preserve their lingual and cultural origins, and UES encourages children of different nationalities to participate in presentations about their family backgrounds, bring in flags of their home countries, and bring national dishes to potluck dinners with families to share with others.

You want to make every child know that theyre welcome and that they belong here, but you also dont want them to lose the things they have from having that special background, too, Mello said.

Another milestone for Mello was teaching the grandchild of a child she once taught.

It was only once, but that was a milestone when I had the grandson of one of the children I first taught, Mello said. I taught his grand aunt, and then a couple of years later, I had his grandfather and then I had his mother, and then two years ago, I had him, she said.

It seems like Im participating in something that teachers must have done a lot when you had the old one-roomed schoolhouses, that the school was the center of the community, and Miss whoever, she had your mother, she had your father, Mello added.

Fellow teacher Dena Cody has worked for 11 years with Mello on the kindergarten team at UES.

Mary has inspired me her dedication to the children and families in Montpelier is unwavering, Cody said. I always think of her as the child whisperer. She just has a way of working with children that helps them to grow and learn.

I always meet people and tell them I work at Union and Im a kindergarten teacher, and they always say, Is my teacher still there, Mrs. Mello? Just the other day, I was at the orthodontist and the dental hygienist said, Mary was my teacher, and this woman is so successful and happy and had such great things to say about her.

Cody recalled how Mello would teach an embryology class in kindergarten.

Ive only known her 11 years, and every year, shes hatched in every single class, Cody said. In the spring, shes always hatching chicks.

Cody also noted Mello has always maintained a rigorous professional development regimen through her years as a teacher.

She never stopped learning, she kept up with her studies ... best practices in math, best practices in literacy, best practices in science, Cody said. She always wanted to do what was best for kids, so if (that) meant a course, she took it. Thats an inspiration in itself. She herself is always learning.

Cody said Mello would also care for other students in the school.

She goes above and beyond for every kid in her class, and even in my class she looks after all of them, Cody said. Its not just her class. Shell peek out and see someone who needs help and is always there to help. Im really going to miss her, and its hard for me to even say. I wish she would stay. I dont want her to leave.

Mello taught Montpelier parent Emma Bay-Hansen and her brother, and her daughter.

Mary Mello was my kindergarten teacher 37 years ago in 1983, Bay-Hansen said. I was thrilled to learn that she would become my daughters kindergarten teacher a few years ago.

Mrs. Mello is the type of teacher that children fall in love with. My daughter goes back to visit her all the time. She is an incredible educator. Her patience, calming energy and depth of experience give her this magical quality a surreal, perfect version of what you dream a kindergarten teacher to be. We will all remember Mrs. Mello as one of the greatest teachers Montpelier has ever known, she added.

Mello said shes retiring to allow a younger generation to succeed her.

I think people tend to leave teaching sooner because they know they have to be very active, Mello said. I didnt want to get to the point where someone said, You cant do this anymore. I wanted to leave before then.

Mello plans to continue writing for The Bridge, and will volunteer to teach early literacy in a pre-school class at The Family Center in Montpelier. She also plans to spend more time with her grandchildren.

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'Child whisperer': Mary Mello's teaching legacy revered | Local News - Barre Montpelier Times Argus