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Category Archives: Genetic medicine

The Medical Minute: How the body responds to the COVID-19 vaccine – Penn State News

Posted: January 8, 2021 at 3:50 pm

By now, everyone has seen countless images of people receiving the COVID-19 vaccine. But once its injected into the upper arm, how does it actually interact with the body?

Dr. M. Fahad Khalid, chief of the Division of Hospital Medicine at Penn State Health Milton S. Hershey Medical Center, and Dr. Mohammad Ali, an infectious diseases physician at Penn State Health Holy Spirit Medical Center, say while the vaccine doesnt contain any live COVID-19 virus, it teaches the human immune system to protect against it.

Both vaccines that received Emergency Use Authorization from the U.S. Food and Drug Administration (FDA) the Pfizer-BioNTech and Moderna vaccines are mRNA (messenger RNA) vaccines. They are not live viruses. Instead, they work by giving your body a blueprint to create a piece of the virus that causes COVID-19, called a spike protein.

Once you receive the vaccine, your cells machinery uses the mRNA instructions to make the spike protein. This protein is then displayed on the cell surface, and the immune system sees it and responds to it. While mRNA is a type of genetic code, it never enters the center (nucleus) of your cells. That means it never converts into DNA, Khalid said. The mRNA itself is destroyed by the cells after they produce the spike protein.

The spike protein the vaccines create is the same one found on the surface of the virus that causes COVID-19. However, the vaccines do not contain any live virus. The spike protein itself cannot cause an infection, Ali said.

Khalid and Ali also addressed many common questions people have about both vaccines:

The vaccines were approved quickly. Are they safe? Advances in vaccinology and vaccine production allowed pharmaceutical companies to create vaccines in months. However, both vaccines followed rigorous FDA guidelines, including the normal regimen of clinical trials and Phase 1, 2 and 3 trials. Their effectiveness is tremendous, Ali said. The flu vaccine is typically 40% to 60% effective, and the COVID-19 vaccines are 94% to 95% effective.

Do people get severe allergic reactions to the vaccine? The Centers for Disease Control and Prevention (CDC) reports a limited number of incidents where people experienced a severe allergic reaction (anaphylaxis) or reaction such as hives, swelling or wheezing. The CDC recommends against people taking the vaccine who had a prior severe allergic reaction to any ingredient in the COVID-19 vaccine. People who have had allergic reactions to other vaccines should ask their doctor about taking the COVID-19 vaccine. People with nonvaccine-related allergies food allergies, pet allergies, seasonal allergies are safe to get vaccinated, says the CDC.

Will the vaccine side effects be worse than getting COVID-19? Possible side effects, such as swelling or pain at the injection site, fever, headache or muscle pain, are temporary. Those side effects arent nearly as bad as severe cases of COVID-19, which can be fatal, Khalid said.

Do I need a vaccine if I already had COVID-19? Yes. Currently, the CDC recommends vaccination even in people who have had COVID-19 in the past. This is because we do not know how long immunity to the virus lasts after someone is infected.

Do I need to wear a mask after getting the COVID-19 vaccine? Yes, you must continue to wear a mask, practice social distancing and continue to wash your hands. The vaccine protects you from getting sick with COVID-19, but researchers still dont know if individuals can still get infected and transmit the virus to others.

Is there any kind of microchip tracking in the vaccines? No. The vaccine also will not cause infertility. Theres a lot of misinformation out there, Ali said. The most trustworthy resource for accurate information is the CDC website.

Alison Enimpah, a registered nurse who provided direct care for COVID-19 patients at the Milton S. Hershey Medical Center, was among the earliest group of health care workers to get vaccinated. Shell receive her second dose later this month. The vaccine adds a layer of reassurance that were making forward progress in keeping ourselves and our community safe during the pandemic, she said.

TheMedical Minuteis a weekly health news feature produced by Penn State Health. Articles feature the expertise of faculty, physicians and staff, and are designed to offer timely, relevant health information of interest to a broad audience.

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DNA-editing method shows promise to treat mouse model of progeria – National Institutes of Health

Posted: January 8, 2021 at 3:50 pm

News Release

Wednesday, January 6, 2021

Using a recently developed DNA base-editing technique, researchers correct accelerating aging disorder.

Researchers have successfully used a DNA-editing technique to extend the lifespan of micewith thegenetic variationassociated withprogeria, a rare genetic disease that causes extreme premature aging in children and can significantly shorten their life expectancy. The studywas published in the journalNature, and was a collaboration between the National Human Genome Research Institute (NHGRI), part of the National Institutes of Health; Broad Institute of Harvard and MIT, Boston; and the Vanderbilt University Medical Center, Nashville, Tennessee.

DNA is made up of four chemical bases A, C, G and T. Progeria, which is also known as Hutchinson-Gilford progeria syndrome, is caused by a mutation in the nuclear laminA(LMNA) gene in which one DNA base C is changed to a T. This change increases the production of the toxic protein progerin, which causes the rapid aging process.

Approximately 1 in 4 million children are diagnosed with progeria within the first two years of birth, and virtually all of these children develop health issues in childhood and adolescence that are normally associated with old age, including cardiovascular disease (heart attacks and strokes), hair loss, skeletal problems, subcutaneous fat loss and hardened skin.

For this study, researchers used a breakthrough DNA-editing technique calledbase editing, which substitutes a single DNA letter for another without damaging the DNA, to study how changing this mutation might affect progeria-like symptoms in mice.

"The toll of this devastating illness on affected children and their families cannot be overstated," said Francis S. Collins, M.D., Ph.D., a senior investigator in NHGRI's Medical Genomics and Metabolic Genetics Branch, NIH director and a corresponding author on the paper. "The fact that a single specific mutation causes the disease in nearly all affected children made us realize that we might have tools to fix the root cause. These tools could only be developed thanks to long-term investments in basic genomics research.

The study follows another recent milestone for progeria research, as theU.S. Food and Drug Administration approved the first treatment for progeriain November 2020, a drug called lonafarnib. The drug therapy provides some life extension, but it is not a cure. The DNA-editing method may provide an additional and even more dramatic treatment option in the future.

David Liu, Ph.D., and his lab at the Broad Institute developed the base-editing method in 2016, funded in part by NHGRI.

"CRISPR editing, while revolutionary, cannot yet make precise DNA changes in many kinds of cells," said Dr. Liu, a senior author on the paper. "The base-editing technique we've developed is like a find-and-replace function in a word processor. It is extremely efficient in converting one base pair to another, which we believed would be powerful in treating a disease like progeria.

To test the effectiveness of their base-editing method, the team initially collaborated with the Progeria Research Foundation to obtain connective tissue cells from progeria patients. The team used the base editor on theLMNAgene within the patients cells in a laboratory setting. The treatment fixed the mutation in 90% of the cells.

The Progeria Research Foundation was thrilled to collaborate on this seminal study with Dr. Collinss group at the NIH and Dr. Lius group at Broad Institute, said Leslie Gordon, M.D., Ph.D., a co-author andmedical director of The Progeria Research Foundation, which partially funded the study. These study results present an exciting new pathway for investigation into new treatments and the cure for children with progeria.

Following this success, the researchers tested the gene-editing technique by delivering a single intravenous injection of the DNA-editing mix into nearly a dozen mice with the progeria-causing mutation soon after birth. The gene editor successfully restored the normal DNA sequence of theLMNAgene in a significant percentage of cells in various organs, including the heart and aorta.

Many of the mice cell types still maintained the corrected DNA sequence six months after the treatment. In the aorta, the results were even better than expected, as the edited cells seemed to have replaced those that carried the progeria mutation and dropped out from early deterioration. Most dramatically, the treated mice's lifespan increased from seven months to almost 1.5 years. The average normal lifespan of the mice used in the study is two years.

As a physician-scientist, its incredibly exciting to think that an idea youve been working on in the laboratory might actually have therapeutic benefit, said Jonathan D. Brown, M.D., assistant professor of medicine in the Division of Cardiovascular Medicine at Vanderbilt University Medical Center. Ultimately our goal will be to try to develop this for humans, but there are additional key questions that we need to first address in these model systems.

Funding for the study was supported in part by NHGRI, the NIH Common Fund, the National Institute of Allergy and Infectious Diseases, the National Institute of Biomedical Imaging and Engineering, the National Institute of General Medical Sciences, the National Heart, Lung and Blood Institute and the National Center for Advancing Translational Sciences.

The National Human Genome Research Institute (NHGRI) is one of the 27 institutes and centers at the NIH, an agency of the Department of Health and Human Services. The NHGRI Division of Intramural Research develops and implements technology to understand, diagnose and treat genomic and genetic diseases. Additional information about NHGRI can be found at: https://www.genome.gov.

About the National Institutes of Health (NIH):NIH, the nation's medical research agency, includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. NIH is the primary federal agency conducting and supporting basic, clinical, and translational medical research, and is investigating the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit http://www.nih.gov.

NIHTurning Discovery Into Health

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Based on genes, nearly everyone is likely to have an atypical response to at least one drug – Scope

Posted: January 8, 2021 at 3:50 pm

Every drug, from morphine to ibuprofen, has a standard dose -- a sort of one-size-fits all recommendation. But a new study suggests that when it comes to drug doses, "one size fits all" rarely applies.

Stanford Medicine professor Russ Altman, MD, PhD, and a team of scientists found that almost everyone (99.5% of individuals) is likely to have an abnormal or "atypical" response to at least one therapeutic drug. This, at least, is the case for people in the United Kingdom, as the study's data came from the UK Biobank, a project that collects, studies and shares data.

The research found that nearly a quarter of the study's participants had been prescribed a drug for which they were predicted to have an atypical response, based on their genetic makeup. On average, participants were predicted to have an atypical response to 10 drugs.

"Ultimately, the hope is that we can show how pervasive drug response variability is and encourage more doctors to rethink the standard prescription protocols that are largely used today and use genetic testing to predict and adjust forthis variability," said Altman, who is an expert in pharmacogenetics, a field that studies the intersection of drugs and genetics.

An "atypical" drug response encompasses a lot of things; but generally speaking, it means a certain drug might not affect one person the way it does another.

For instance, someone who has an atypical metabolic response might process that drug more efficiently, strengthening its initial effects but decreasing its efficacy over time. On the flip side, it could mean that that person is unable to metabolize the drug at all, leaving them without therapeutic aid, or even with dangerous side effects.

These differences in response to a drug are partially due to our genetics. Specific proteins -- workhorse molecules in the body -- break down drugs in order for the body to benefit from the therapeutic. Those proteins are regulated by a specific group of genes. Natural variation in those genes leads to differences in how an individual's body reacts to a given drug molecule.

Altman and his team, including graduate students and first authors of the study Greg McInnes and Adam Lavertu, analyzed data from nearly 500,000 participants.

For 230,000 participants in the study, the team had primary care data going back about 30 years. That includes which drugs had been prescribed, the dose, and all of the patient's different diagnoses. The researchers also had access to detailed genetic information about each patient. They paid special attention to genetic variations in a group of genes that are known to influence the human drug response.

By comparing an individual's genetics against the variations known to exist in the group of drug-response-associated genes, the researchers could predict how any given patient might respond to a drug.

"Pharmacogenetics as a field has been around for a long time, but it hasn't really been adopted into clinical use," McInnes told me. "It's been growing in the last few years as more people realize the impact that it could have on personalized health. For a long time, it's been this overlooked aspect of genetics that I think is actually one of the most clinically actionable advances that has come out of human genetics."

What's more, he said, the wide variability in the human drug response applies to common therapeutics most everyone has encountered or is familiar with -- ibuprofen, codeine, statins and beta blockers among others.

Moving forward, Lavertu says that the goal is to expand drug-gene variant interaction analyses into more diverse populations. The data from the UK Biobank provided critical insight, but it was largely only representative of a British population, where the majority shares European ancestry. A next step for the researchers is to investigate the same genes in the Million Veteran Program, a government research program with a more diverse study population, that is examining how genes, lifestyle and military exposures affect health and illness.

"Our hope is that doing more of these studies will help us find new relationships between genetic variants and drug response, so that pharmacogenetics can benefit more people," Lavertu said.

Photo byMicha Parzuchowski

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Developmental Biologist Kathryn Anderson Dies at 68 – The Scientist

Posted: January 8, 2021 at 3:50 pm

Kathryn Anderson, a developmental biologist at the Memorial Sloan Kettering Cancer Center known for her work detailing the genetics of early embryogenesis, died November 30 at age 68.

Throughout her scientific career, Anderson used rigorous genetic screening assays to identify mutations suspected of disrupting cell division and differentiation in model systems. Having identified a gene of interest, she would then turn to a technique known as forward genetics, creating model organisms such as fruit flies and mice with a particular phenotype to better understand its molecular underpinnings. Using these tools, Anderson made important contributions to scientists understanding of several genetic pathwaysmost notably the Toll and Hedgehog pathwaysrequired for proper development of these animals.

Kathryn was fearless and very open-minded, Tatiana Omelchenko, a senior research scientist in Andersons lab who uses confocal microscopy to do live imaging of mouse embryos, tells The Scientist. Every lab has its own environment and its own mood, and when you stepped into Kathryns lab, you immediately felt very focused.

Born in La Jolla, California, in 1952, Anderson became interested in science at a young age, stemming back to an article in LIFEthat included a detailed image of a human fetus, according to an interview released shortly after her death. She attended the University of California, Berkeley, where she earned her undergraduate degree in biochemistry before heading to a graduate program in neurodevelopment at Stanford University in 1973.

Anderson left that program after only two years, earning a masters degree in neuroscience, and spent the next several years looking for her scientific niche. She enrolled briefly in medical school at the University of California, San Diego, an experience that led her to realize her love of basic research. The clinical work wasnt my cup of tea, Anderson shared in a 2005 biography. The lab was where I felt most at home.

Ultimately, Anderson landed at the University of California, Los Angeles, studying the developmental genetics of Drosophilaunder the guidance of biologist Judith Lengyel. For her PhD work, Anderson showed that in the first two hours after fertilization, the development of Drosophilaembryos remains under maternal control, with maternal RNA and proteins directing cell division and differentiation within the egg.

Looking to further her study of fruit flies, Anderson next traveled to the Max Planck Institute for Developmental Biology in Germany as a postdoc to work with Drosophilageneticist Christiane Nsslein-Volhard. In 1995, Nsslein-Volhard would share a Nobel Prize for her work using mass screenings to identify mutations that disrupt embryonic development, and Anderson would continue studying a handful of the genes identified in these early screens throughout her career.

One such gene, known as Toll, turned out to play an important role in dorsal-ventral (D-V) differentiationdictating, as Anderson said in her biography, how a fly embryo knows its back from its belly. In addition to probing the function of Toll,Anderson continued building out the wider Toll pathway after returning to the University of California, Berkeley, as an assistant professor in 1985, and later in her own lab at the Sloan Kettering Institute, which she launched in 1996 at Memorial Sloan Kettering. During this time, Anderson and her team identified roughly a dozen genes involved in cell differentiation along the D-V axis, and she used similar screening methods to better understand Tolls role in innate immunity of Drosophila. Her findings were noted by geneticists Jules Hoffmann and Bruce Beutler, whose study of Toll-like receptors in both fruit fly and mammalian immunity would later earn them a Nobel Prize.

Kathryn Anderson

Memorial Sloan Kettering Cancer Center

After her successes in fruit flies, Anderson began thinking about applying her same methods to the study of mice. She spent a year on sabbatical in the lab of Rosa Beddington at the National Institute for Medical Research in the UK, where she showed that Toll had no analogous role in the D-V differentiation of mammals. It demonstrated, she said in a 2016 interview with Development, that there are things about early mammalian development that you cant figure out by extrapolating from flies.

Back at the Sloan Kettering Institute, Anderson began once again using mass genetic screenings, this time to identify mutations of interest in mice, and then studying them in fine detail. These were lengthy experiments that often took years to yield results. I think her major contribution is discovering the functions and roles of genes through this mutagenesis screen, Omelchenko says. This is amazing because . . . the mouse embryo model is quite complex, but she did the work.

Anderson and her team screened more than 12,000 mutations, selecting roughly 40 that produce obvious phenotypic disruptions midway through gestation. Working diligently over many years, Anderson identified previously unknown pathways that have since prompted new research directions in the field of developmental biology.

Through her screening, for example, Anderson identified a previously unknown relationship between ciliamicroscopic, hairlike structures on the outside of some cellsand proper signaling of the Hedgehog pathway that dictates cell differentiation in mammalian embryos. Further research showed that components of this pathway are enriched in cilia, while mice with certain mutations in genes involved in Hedgehog signaling lacked cilia altogether in a structure called the node that directs gastrulation in vertebrate embryos. That turned out to be pretty amazing, actually: theres this whole organelle required for Hedgehog signaling in vertebrates, but not in flies, Anderson said in her Developmentinterview. Its a geneticists dream, but raises the question of why organize the genome like this: there are so many weak points in Hedgehog signalingand Hedgehog is so vital.

For her contributions to the field of developmental biology, Anderson was inducted into the National Academy of Sciences in 2002 and elected as a member of the Institute of Medicine of the National Academies in 2008. In addition, she was awarded the Thomas Hunt Morgan Medal for lifetime contributions to the science of genetics in 2012, the Federation of American Societies for Experimental Biologys Excellence in Science Award in 2014, and the Society for Developmental Biologys Edwin G. Conklin Medal for distinguished and sustained research in 2016, among other honors.

Prior to her death, Anderson had spoken about the possible extension of her research into human genetics, as disruptions in hedgehog signaling have since been linked both to birth defects and to a series of diseases referred to as ciliopathies. It was, however, a line of questioning she planned to leave to other scientists, content to continue her methodical work exploring mutations in mice.

Many scientists are very quiet people, but contemporary society requires you to be very loud [so] that people will listen to you, Omelchenko says. Kathryn is such a great example of being quiet, being a very deep thinker, and at the same time becoming a very successful and bright scientist. I think I will keep learning from her even though she has passed away.

Anderson is survived by her husband, Timothy Bestor, a geneticist at Columbia University.

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ProPath Appoints Soft Tissue Tumor Expert, Julia A. Bridge, M.D., as Director of Cytogenetics and FISH – Business Wire

Posted: January 8, 2021 at 3:50 pm

DALLAS--(BUSINESS WIRE)--ProPath, the largest fully physician-owned pathology practice in the United States, today announced that Julia A. Bridge, M.D., a board-certified pathologist and geneticist with an extensive medical career and expertise in solid tumor molecular testing, has joined the ProPath team.

Dr. Bridge, who recently directed the Molecular Pathology Research Division at the Translational Genomics Research Institute in Phoenix, AZ, will be directing ProPaths fluorescence in situ hybridization (FISH) and cytogenetics team. She will also be incorporating her testing expertise in bone/soft tissue tumors for ProPaths molecular pathology team.

We are thrilled to have Dr. Bridge join our team, said Cory A. Roberts, M.D., President, Chairman and CEO of ProPath. She has a rare combination of expertise in both anatomic pathology and cytogenetics that make her an expert with an international consultative practice. Her ability to interpret microscopic morphology in concert with her unsurpassed knowledge of the molecular and genetic signature of tumors is unsurpassed and will carry ProPaths abilities in these areas to the forefront of all practices.

Dr. Bridge received her medical degree from the University of Nebraska Medical Center and completed her pathology residency at the University of Kansas Medical Center followed by clinical cytogenetic and molecular fellowships at the University of Nebraska Medical Center and the Southwest Biomedical Research Institute in Scottsdale Arizona.

Dr. Bridge serves or has served on editorial boards for pathology, orthopedic, and genetics journals, in consulting or advisory board positions for cancer networks and industry (including as key investigator for landmark FDA approvals for two novel gene-based tests), the national Childrens Oncology Group Soft Tissue Sarcoma and Ewing sarcoma committees, College of American Pathology (CAP) Glioma Expert Panel, and Secretarial Appointee to the national Department of Veterans Affairs Genomic Medicine Program Advisory Committee. She has authored greater than 300 scientific articles, chapters, review papers, digital and web-based materials, and is co-author or co-editor of several books (e.g. AFIP Atlas of Tumor Pathology; 4th Series, Fascicle 2: Tumors of the Bones and Joints and editions of the WHO Classification of Tumours of Soft Tissue and Bone). Dr. Bridge is the current President of the United States and Canadian Academy of Pathology.

About ProPath:

ProPath is the largest, nationwide, fully physician-owned pathology practice in the United States. Led by a team of world-class physicians and scientists, ProPath routinely diagnoses cases from 45 states and several foreign countries. Its over 500 employees reside in 10 states and staff labs and facilities in three states. For 55 years, ProPaths mission has been to provide patient-centered, high quality and effective medical diagnostics, prognostics and research that creates better patient outcomes.

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ProPath Appoints Soft Tissue Tumor Expert, Julia A. Bridge, M.D., as Director of Cytogenetics and FISH - Business Wire

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Alnylam Reports Positive Topline Results from HELIOS-A Phase 3 Study of Vutrisiran in Patients with hATTR Amyloidosis with Polyneuropathy – Business…

Posted: January 8, 2021 at 3:50 pm

CAMBRIDGE, Mass.--(BUSINESS WIRE)--Alnylam Pharmaceuticals, Inc. (Nasdaq: ALNY), the leading RNAi therapeutics company, announced today that the HELIOS-A Phase 3 study of vutrisiran, an investigational RNAi therapeutic in development for the treatment of transthyretin-mediated (ATTR) amyloidosis, met its primary and both secondary endpoints at nine months in patients with hATTR amyloidosis with polyneuropathy. The primary endpoint was the change from baseline in the modified Neuropathy Impairment Score (mNIS+7) at 9 months as compared to historical placebo data from the APOLLO Phase 3 study of patisiran. The two secondary endpoints were changes in quality of life assessed by the Norfolk Quality of Life Questionnaire-Diabetic Neuropathy (Norfolk QoL-DN) and gait speed assessed by the timed 10-meter walk test (10-MWT) compared to historical placebo. Vutrisiran met the primary endpoint (p less than 0.001) and achieved statistically significant results (p less than 0.001) for each of the Norfolk QoL-DN and 10-MWT secondary endpoints. In addition, vutrisiran treatment showed improvement compared to placebo on the exploratory cardiac biomarker endpoint, NT-proBNP (nominal p less than 0.05). Vutrisiran also demonstrated an encouraging safety and tolerability profile.

Based on these positive results, the Company plans to submit a New Drug Application (NDA) for vutrisiran with the U.S. Food and Drug Administration (FDA) in early 2021, and to follow with regulatory filings in additional countries, such as Brazil and Japan. The Company plans to submit a Marketing Authorisation Application (MAA) in the EU upon obtaining the results of the 18-month analysis expected in late 2021 as previously aligned with the European Medicines Agency (EMA).

We are excited to report positive topline results from the HELIOS-A study, which show that vutrisiran reduces neurologic impairment and improves quality of life in patients with hATTR amyloidosis with polyneuropathy as soon as 9 months, with an encouraging safety and tolerability profile. In addition, were very pleased to see evidence for reversal of polyneuropathy manifestations of disease and also favorable effects on the exploratory cardiac endpoint, NT-proBNP. We believe that vutrisiran, as a low-dose, once-quarterly, subcutaneously administered therapy, has the potential to be a highly attractive therapeutic option for patients living with this progressive, life-threatening, multi-system disease. We look forward to presenting the full 9-month results from HELIOS-A at a medical meeting in early 2021 and to announcing additional 18-month results, including additional exploratory cardiac endpoint data, in late 2021, said Akshay Vaishnaw, M.D., Ph.D., President of R&D at Alnylam. We would like to recognize and extend our profound gratitude to the patients, caregivers, investigators, and study staff who are participating in HELIOS-A and who, through their commitment during an especially difficult year, have helped make possible another potential advancement in the treatment of hATTR amyloidosis with polyneuropathy. We look forward to initiating our regulatory filings in early 2021 as we work to bring this investigational treatment one step closer to patients with this rare disease.

HELIOS-A (NCT03759379) is a Phase 3 global, randomized, open-label study to evaluate the efficacy and safety of vutrisiran. The study enrolled 164 patients with hATTR amyloidosis with polyneuropathy at 57 sites in 22 countries. Patients were randomized 3:1 to receive either 25mg of vutrisiran (N=122) via subcutaneous injection once every three months or 0.3 mg/kg of patisiran (N=42) via intravenous infusion once every three weeks (as a reference comparator) for 18 months. The primary endpoint is the change from baseline in mNIS+7 score at 9 months1, relative to historical placebo. Secondary endpoints at 9 months are the change from baseline in the Norfolk QoL-DN score and the timed 10-MWT, relative to historical placebo. Changes from baseline in NT-proBNP were evaluated as an exploratory endpoint at 9 months. The efficacy results of vutrisiran in HELIOS-A are compared to historical placebo control data from the landmark APOLLO Phase 3 study, which evaluated the efficacy and safety of patisiran in a patient population similar to that studied in HELIOS-A. Additional secondary endpoints at 18 months will be evaluated in the HELIOS-A study, including change from baseline in mNIS+7, Norfolk QoL-DN, 10-MWT, modified body mass index (mBMI), Rasch-built Overall Disability Scale (R-ODS), and serum transthyretin (TTR) levels. Additional exploratory cardiac endpoint data at the 18-month time point will be evaluated, including NT-proBNP, echocardiographic measures and cardiac amyloid assessments with technetium scintigraphy imaging. Following the 18-month study period, all patients are eligible to receive vutrisiran for an additional 18 months as part of an open-label extension study. Full 9-month results will be presented at a medical conference in early 2021 and topline 18-month results, including further exploratory cardiac endpoint data, are expected to be announced in late 2021.

Vutrisiran demonstrated an encouraging safety profile. There were two study discontinuations (1.6 percent) due to adverse events in the vutrisiran arm by Month 9, both due to deaths, neither of which was considered related to study drug. There were two serious adverse events (SAEs) deemed related to vutrisiran by the study investigator, consisting of dyslipidemia and urinary tract infection. Treatment emergent adverse events (AEs) occurring in 10 percent or more patients included diarrhea, pain in extremity, fall and urinary tract infections, with each of these events occurring at a similar or lower rate as compared with historical placebo. Injection site reactions (ISRs) were reported in five patients (4.1 percent) and were all mild and transient. There were no clinically significant changes in liver function tests (LFTs).

The HELIOS-A results reinforce our commitment to building an industry-leading franchise of medicines for the treatment of ATTR amyloidosis which began with the development and approval of ONPATTRO as a treatment for patients with hATTR amyloidosis with polyneuropathy. Indeed, the vutrisiran results from HELIOS-A now serve as a second example of the potential for RNAi therapeutics to have a meaningful impact for patients, showing the ability to halt and potentially even reverse polyneuropathy manifestations of the disease. Furthermore, our robust development program, including the APOLLO-B and HELIOS-B studies, investigates the potential of patisiran and vutrisiran, respectively, to treat the cardiac manifestations of disease across a broad spectrum of patients with ATTR amyloidosis, said John Maraganore, Ph.D., Chief Executive Officer of Alnylam. We believe that our ATTR amyloidosis franchise will be a significant driver of Alnylams growth in the years to come, with the potential to position Alnylam as a top tier biopharma company.

Vutrisiran has been granted Orphan Drug Designation in the United States and the European Union for the treatment of ATTR amyloidosis. Vutrisiran has also been granted a Fast Track designation in the United States for the treatment of the polyneuropathy of hATTR amyloidosis in adults. The safety and efficacy of vutrisiran are being evaluated in the comprehensive HELIOS clinical development program and have not yet been evaluated by any health authority. The ongoing HELIOS-B Phase 3 clinical trial in patients with ATTR amyloidosis with cardiomyopathy was initiated in late 2019 and is currently enrolling at sites around the world. Together, the HELIOS-A and -B studies are intended to demonstrate the broad impact of vutrisiran across the multisystem manifestations of disease and the full spectrum of patients with ATTR amyloidosis.

Conference Call InformationAlnylam management will discuss the HELIOS-A results via conference call on Thursday, January 7, 2021, at 8:00 am ET. A webcast presentation will also be available on the Investors page of the Companys website, http://www.alnylam.com. To access the call, please dial 877-312-7507 (domestic) or +1-631-813-4828 (international) five minutes prior to the start time and refer to conference ID 4398564. A replay of the call will be available beginning at 11:00 am ET on the day of the call. To access the replay, please dial 855-859-2056 (domestic) or +1-404-537-3406 (international) and refer to conference ID 4398564.

About hATTR AmyloidosisHereditary transthyretin (TTR)-mediated amyloidosis (hATTR) is an inherited, progressively debilitating, and often fatal disease caused by mutations in the TTR gene. TTR protein is primarily produced in the liver and is normally a carrier of vitamin A. Mutations in the TTR gene cause abnormal amyloid proteins to accumulate and damage body organs and tissue, such as the peripheral nerves and heart, resulting in intractable peripheral sensory-motor neuropathy, autonomic neuropathy, and/or cardiomyopathy, as well as other disease manifestations. hATTR amyloidosis, represents a major unmet medical need with significant morbidity and mortality affecting approximately 50,000 people worldwide. The median survival is 4.7 years following diagnosis, with a reduced survival (3.4 years) for patients presenting with cardiomyopathy.

About VutrisiranVutrisiran is an investigational, subcutaneously administered RNAi therapeutic in development for the treatment of ATTR amyloidosis, which encompasses both hereditary (hATTR) and wild-type (wtATTR) amyloidosis. It is designed to target and silence specific messenger RNA, blocking the production of wild-type and variant transthyretin (TTR) protein before it is made. Quarterly administration of vutrisiran may help to reduce deposition and facilitate the clearance of TTR amyloid deposits in tissues and potentially restore function to these tissues. Vutrisiran utilizes Alnylams Enhanced Stabilization Chemistry (ESC)-GalNAc-conjugate delivery platform, designed for increased potency and high metabolic stability that allows for infrequent subcutaneous injections. The safety and efficacy of vutrisiran have not been evaluated by the U.S. Food and Drug Administration, European Medicines Agency or any other health authority.

About RNAiRNAi (RNA interference) is a natural cellular process of gene silencing that represents one of the most promising and rapidly advancing frontiers in biology and drug development today. Its discovery has been heralded as a major scientific breakthrough that happens once every decade or so, and was recognized with the award of the 2006 Nobel Prize for Physiology or Medicine. By harnessing the natural biological process of RNAi occurring in our cells, a new class of medicines, known as RNAi therapeutics, is now a reality. Small interfering RNA (siRNA), the molecules that mediate RNAi and comprise Alnylams RNAi therapeutic platform, function upstream of todays medicines by potently silencing messenger RNA (mRNA) the genetic precursors that encode for disease-causing proteins, thus preventing them from being made. This is a revolutionary approach with the potential to transform the care of patients with genetic and other diseases.

About Alnylam PharmaceuticalsAlnylam (Nasdaq:ALNY) is leading the translation of RNA interference (RNAi) into a whole new class of innovative medicines with the potential to transform the lives of people afflicted with rare genetic, cardio-metabolic, hepatic infectious, and central nervous system (CNS)/ocular diseases. Based on Nobel Prize-winning science, RNAi therapeutics represent a powerful, clinically validated approach for the treatment of a wide range of severe and debilitating diseases. Founded in 2002, Alnylam is delivering on a bold vision to turn scientific possibility into reality, with a robust RNAi therapeutics platform. Alnylams commercial RNAi therapeutic products are ONPATTRO (patisiran), GIVLAARI (givosiran), OXLUMO (lumasiran), and, in Europe, Leqvio (inclisiran). Alnylam has a deep pipeline of investigational medicines, including six product candidates that are in late-stage development. Alnylam exceeded the goals first established in 2015 under its "Alnylam 2020" strategy of building a multi-product, commercial-stage biopharmaceutical company with a sustainable pipeline of RNAi-based medicines to address the needs of patients who have limited or inadequate treatment options. Alnylam is headquartered in Cambridge, MA. For more information about our people, science and pipeline, please visit http://www.alnylam.com and engage with us on Twitter at @Alnylam or on LinkedIn.

Alnylam Forward Looking StatementsVarious statements in this release concerning Alnylam's future expectations, plans and prospects, including, without limitation, expectations regarding the direct or indirect effects on Alnylams business, activities and prospects as a result of the COVID-19 pandemic, or delays or interruptions resulting therefrom and the success of Alnylams mitigation efforts, Alnylam's views and plans with respect to the potential for RNAi therapeutics, including vutrisiran and patisiran, expectations regarding the safety and efficacy of vutrisiran as a treatment for hATTR amyloidosis with polyneuropathy, and its potential to have a meaningful impact on the course of this disease, expectations regarding the potential of vutrisiran and patisiran to treat the cardiac manifestations of ATTR amyloidosis across a broad spectrum of patients, Alnylams prospects for building an industry-leading ATTR amyloidosis franchise and to become a top-tier biopharma company, the expected timing for the filing of regulatory submissions for vutrisiran the presentation of full 9-month results and the announcement of 18-month topline results, including exploratory cardiac endpoint data, constitute forward-looking statements for the purposes of the safe harbor provisions under The Private Securities Litigation Reform Act of 1995. Actual results and future plans may differ materially from those indicated by these forward-looking statements as a result of various important risks, uncertainties and other factors, including, without limitation: the direct or indirect impact of the COVID-19 global pandemic or any future pandemic, such as the scope and duration of the outbreak, government actions and restrictive measures implemented in response, the availability of safe and effective vaccine(s), material delays in diagnoses of rare diseases, initiation or continuation of treatment for diseases addressed by Alnylam products, or in patient enrollment in clinical trials, potential supply chain disruptions, and other potential impacts to Alnylams business, the effectiveness or timeliness of steps taken by Alnylam to mitigate the impact of the pandemic, and Alnylams ability to execute business continuity plans to address disruptions caused by the COVID-19 or any future pandemic; Alnylam's ability to discover and develop novel drug candidates and delivery approaches and successfully demonstrate the efficacy and safety of its product candidates, including vutrisiran; the pre-clinical and clinical results for its product candidates, which may not be replicated or continue to occur in other subjects or in additional studies or otherwise support further development of product candidates for a specified indication or at all; actions or advice of regulatory agencies, which may affect the design, initiation, timing, continuation and/or progress of clinical trials or result in the need for additional pre-clinical and/or clinical testing; delays, interruptions or failures in the manufacture and supply of its product candidates or its or its partner Novartis marketed products, including ONPATTRO, GIVLAARI, OXLUMO and Leqvio (in Europe); obtaining, maintaining and protecting intellectual property; intellectual property matters including potential patent litigation relating to its platform, products or product candidates; obtaining regulatory approval for its product candidates, including vutrisiran, and the success of its partner Novartis, in obtaining regulatory approval for inclisiran in the U.S. and elsewhere, and maintaining regulatory approval and obtaining pricing and reimbursement for its products, including ONPATTRO, GIVLAARI, and OXLUMO, as well as its partner Novartis success obtaining pricing and reimbursement for Leqvio; progress in continuing to establish an ex-United States infrastructure; successfully launching, marketing and selling its approved products globally, including ONPATTRO, GIVLAARI, and OXLUMO, and achieving net product revenues for ONPATTRO within its revised expected range during 2020; Alnylams ability to successfully expand the indication for ONPATTRO in the future; competition from others using technology similar to Alnylam's and others developing products for similar uses; Alnylam's ability to manage its growth and operating expenses within the ranges of guidance provided by Alnylam through the implementation of further discipline in operations to moderate spend and its ability to achieve a self-sustainable financial profile in the future without the need for future equity financing; Alnylams ability to establish and maintain strategic business alliances and new business initiatives; Alnylam's dependence on third parties, including Novartis for the continued development and commercialization of Leqvio, Regeneron for development, manufacture and distribution of certain products, including eye and CNS products, and Vir for the development of ALN-COV and other potential RNAi therapeutics targeting SARS-CoV-2 and host factors for SARS-CoV-2; the outcome of litigation; the risk of government investigations; and unexpected expenditures; as well as those risks more fully discussed in the "Risk Factors" filed with Alnylam's most recent Quarterly Report on Form 10-Q filed with the Securities and Exchange Commission (SEC) and in other filings that Alnylam makes with the SEC. In addition, any forward-looking statements represent Alnylam's views only as of today and should not be relied upon as representing its views as of any subsequent date. Alnylam explicitly disclaims any obligation, except to the extent required by law, to update any forward-looking statements.

1 In alignment with the EMA, the primary endpoint of change from baseline in mNIS+7 will be evaluated at 18 months to support an MAA.

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Global Biotechnology Services Market Report 2020: Market to Grow at a CAGR of 5% from 2019 to 2020 Due to COVID-19 and Increase in R&D Activities -…

Posted: January 8, 2021 at 3:50 pm

DUBLIN, Jan. 8, 2021 /PRNewswire/ -- The "Biotechnology Services Global Market Report 2020-30: COVID-19 Growth and Change" report has been added to ResearchAndMarkets.com's offering.

Biotechnology Services Global Market Report 2020-30: COVID-19 Growth and Change provides the strategists, marketers and senior management with the critical information they need to assess the global biotechnology services market.

Major players in the biotechnology services market are Novartis, Fisher BioService, Pfizer, Novo Nordisk, BioAlps, Precision for Medicine, Sartorius and Aldevron.

The global biotechnology services market is expected to increase from $142.92 billion in 2019 to $150.06 billion in 2020 at a compound annual growth rate (CAGR) of 5.0%. The growth is mainly due to the COVID-19 outbreak that has led to an increase in research and development activities. The market is expected to grow further and reach $210.96 billion in 2023 at a CAGR of 12.03%. Biotechnology services is the second-largest sector after biopharmaceuticals which is anticipated to emerge significantly due to increasing research and development activities.

The biotechnology services market consists of the sales of biotechnology services and related goods by entities (organizations, sole traders and partnerships) that engage in conducting research and experimental development in biotechnology. Only goods and services traded between entities or sold to end consumers are included.

North America was the largest region in the biotechnology services market in 2019. Asia-Pacific is expected to be the fastest-growing region in the forecast period.

In May 2018, Illumina, a US-based biotechnology company serving in research, clinical and applied markets, acquired Edico Genome for an undisclosed amount. The acquisition is expected to reduce sequencing data acquisition. Edico Genome's Bio-IT platform DRAGEN uses field-programmable gate array (FPGA) technology with software algorithms and helps in reducing data footprint and time for results. The DRAGEN platform complements Illumina's sequencing portfolio and helps the customer in reducing investment in IT infrastructure and improve overall efficiency.

The biotechnology services market covered in this report is segmented by service into prevention and disease control; public engagement activities; health education and research; food biotechnology services; donor recruitment; tissue collection; cell processing and isolation; research and development. It is also segmented by industry into clinical research organizations (CROs); contract manufacturers organizations (CMOs); contract research and manufacturing services (CRAMs) and by area of application into pharmaceutical; biotechnological; academic; clinical trial; healthcare sector.

The risk related to genetic data is anticipated to limit the growth of the biotechnology services market. The biotechnological approach of transferring specially created genes for modification in characteristics to create genetically modified organisms (GMOs) has always been considered a threat to human and environmental health. According to the report of the World Conservation Union, there are numerous environmental risks likely to occur by the use of GMOs, which include interbreeding, antibiotic resistance, impact on the ecosystem, creation of new or worse viruses, competition with natural species, unpredictable and unintended effects and ethical concerns.

Collaborations and partnerships between industry players are a growing trend in the field of biotech services. In Dec 2019, Interpace Pharma, a subsidiary of Interpace Biosciences, dealing in pharmacogenomics testing, genotyping and biorepository services, collaborated with Genecast Biotechnology Co. Ltd for jointly developing, promoting, and offering translational studies and clinical trial solutions to the industry. This partnership is expected to benefit pharmaceutical and biotech companies to accelerate their biomarker-driven drug development and precision medicine.

The increasing pervasiveness of conditions like hepatitis B, diabetes and cancer is driving the research in biotechnology. Biotechnology uses research tools from biology and chemistry to study the genetic material of bacteria and viruses to check the disease-producing agent. Oncology research is most prominent among biopharma companies. Stem cell treatment, using a monoclonal antibody for therapy and genome sequencing is progressing in medical applications. The sales of global biotech drugs are expected to reach $284 billion in 2020.

According to Data-Driven Investor, all sectors of biotech companies together spend 20% of their budget on research and development, accounting for nearly $750 billion in 2018. Therefore, the rising pervasiveness of diseases and huge expenses on R&D is predicted to contribute to the growth of the biotechnology services market.

Key Topics Covered:

1. Executive Summary

2. Biotechnology Services Market Characteristics

3. Biotechnology Services Market Size and Growth 3.1. Global Biotechnology Services Historic Market, 2015 - 2019, $ Billion 3.1.1. Drivers of the Market 3.1.2. Restraints on the Market 3.2. Global Biotechnology Services Forecast Market, 2019 - 2023F, 2025F, 2030F, $ Billion 3.2.1. Drivers of the Market 3.2.2. Restraints on the Market

4. Biotechnology Services Market Segmentation 4.1. Global Biotechnology Services Market, Segmentation by Service, Historic and Forecast, 2015-2019, 2023F, 2025F, 2030F, $ Billion

4.2. Global Biotechnology Services Market, Segmentation by Industry, Historic and Forecast, 2015-2019, 2023F, 2025F, 2030F, $ Billion

4.3. Global Biotechnology Services Market, Segmentation by Area of Application, Historic and Forecast, 2015-2019, 2023F, 2025F, 2030F, $ Billion

5. Biotechnology Services Market Regional and Country Analysis 5.1. Global Biotechnology Services Market, Split by Region, Historic and Forecast, 2015-2019, 2023F, 2025F, 2030F, $ Billion

Companies Mentioned

For more information about this report visit https://www.researchandmarkets.com/r/oagrsu

Research and Markets also offers Custom Research services providing focused, comprehensive and tailored research.

Media Contact:

Research and Markets Laura Wood, Senior Manager [emailprotected]

For E.S.T Office Hours Call +1-917-300-0470 For U.S./CAN Toll Free Call +1-800-526-8630 For GMT Office Hours Call +353-1-416-8900

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SOURCE Research and Markets

http://www.researchandmarkets.com

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Prowess of Bionano Genomics’ Saphyr System in Uncovering Novel Genetic Variations That Cause Cancer and Genetic Disease in Full Display at ASHG 2020 -…

Posted: October 28, 2020 at 3:51 am

SAN DIEGO, Oct. 27, 2020 (GLOBE NEWSWIRE) -- Bionano Genomics, Inc. (Nasdaq: BNGO) announced that human genetics researchers using the Saphyr system will present their results at the American Society of Human Genetics (ASHG) Annual Meeting, being held virtually at http://www.ashg.org between October 27-30. The impact of structural variation analysis using the Saphyr system will be demonstrated at ASHG with 18 oral and poster presentations which cover an expanding array of diseases like cancer predisposition, microdeletion syndromes, repeat expansion disorders, neurodegenerative diseases, disorders of sex development and a variety of other genetic diseases. Additionally, these presentations show Saphyrs abilities to elucidate the exact structure of complex genomic rearrangements such as large inversions, chromothripsis and low copy repeats.

The scientific importance and quality of the studies utilizing Saphyr and presented at ASHG have increased year over year, said Erik Holmlin, Ph.D., CEO of Bionano. As more scientists present and publish their important discoveries made with Saphyr, an increasing number of potential future Saphyr users become aware of its prowess in uncovering novel genetic variants that contribute to cancer and genetic disease, which could drive more adoption and utilization for basic genetic research and clinical studies alike.

Below is a summary of key presentations to be given at ASHG 2020 featuring the use of Bionanos optical genome mapping technology:

Live Presentation October 29, 2020, 11:45AM-12:00PMDeciphering Genomic InversionsChristopher M. Grochowski, Baylor College of MedicineGenomic inversions are a class of structural variation (SV) relevant in evolution, speciation, and human disease but challenging to detect and resolve using current genomic assays. While short-read WGS can detect a fraction of copy number neutral inversions, those mediated by repeats or accompanied by CNVs remain challenging. The utilization of multiple technologies and visualization of unbroken DNA through long molecule approaches facilitate detection ofin cisevents and resolution of SVs containing two or more breakpoint junctions.

The following Co-Labs, Poster Sessions and Abstracts are available for on-demand viewing during and after ASHG 2020:

Bionano Laboratory Co-Lab Session: Resolving Complex Haplotypes Implicated in Alzheimers and Other Neurodegenerative Diseases.Mark T. W. Ebbert, Neuroscience Department, Mayo ClinicAlzheimers disease is genetically complex with no meaningful therapies or pre-symptomatic disease diagnostics. Most of the genes implicated in Alzheimers disease do not have a known functional mutation, meaning there are no known molecular mechanisms to help understand disease etiology.

In this co-lab session, Mark T. W. Ebbert of the Mayo Clinic will discuss his teams work toward identifying functional structural mutations that drive disease in order to facilitate a meaningful therapy and pre-symptomatic disease diagnostic. Some of the genes and regions implicated in Alzheimers disease are genomically complex and cannot be resolved with short-read sequencing technologies. These regions include MAPT, CR1, and the histocompatibility complex (including the HLA genes).

3342 Bionano Poster Session: High Throughput Analysis of Disease Repeat Expansions and Contractions by Optical MappingErnest Lam, Sr Manager Bioinformatics, Bionano GenomicsRepeat expansions and contractions are associated with degenerative disorders such as facioscapulohumeral muscular dystrophy (FSHD). Southern Blotting is the gold standard for long repeat analysis but has many limitations. Optical genome mapping allows for efficient analysis of diseases associated with repeat expansion and contraction.

2190 Bionano Poster Session: Rapid Automated large Structural Variation Detection in Mouse Genome by Whole Genome SequencingJill Lai, Sr Applications Scientist, Bionano GenomicsIdentifying SVs for key model organisms such as mouse and rat is essential for genome interpretation and disease studies but has been historically difficult due to limitations inherent to available genome technologies. We updated the Saphyr analysis pipeline such that copy number variant (CNV) and SV analyses could now be applied to mouse and other non-human species, and constructed a control SV database for annotating variants, and identified strain-specific SVs/CNVs as well as variation shared among strains.

Additional presentations/abstracts featuring optical genome mapping:

3208 - Long-read sequencing and optical mapping decipher structural composition ofATXN10repeat in kindred with spinocerebellar ataxia and Parkinsons diseasePresented by Birgitt Schuele, Associate Professor, Department of Pathology, Stanford University School of Medicine

3270 - Uniparental isodisomy, structural and noncoding variants involved in inherited retinal degeneration (IRD) in three pedigreesPresented by Pooja Biswas, Ophthalmology Department, University of California, San Diego

Data CoLab: Whole Genome Map Assembly and Structural Variation Analysis with Hitachi Human Chromosome ExplorerPresented by Hitachi-High-Tech America, Inc.

2123 - High-throughput sequencing and mapping technologies applied to 10 human genomes with chromothripsis-like rearrangementsPresented by Uir Souto Melo, Mundlos Lab, Max Planck Institute for Molecular Genetics, Berlin, Germany

2165 -nanotatoR: A tool for enhanced annotation of genomic structural variantsPresented by Emmanuele Delot, Center for Genetic Medicine Research, Childrens National Hospital, Washington, DC

2998 - Highly variable structure and organization of the human 3q29 subtelomeric segmental duplicationsPresented by Umamaheswaran Gurusamy, Cardiovascular Research Institute, University of California San Francisco

2304 - Enlightening the dark matter of the genome: Whole genome imaging identifies a germline retrotransposon insertion inSMARCB1in two siblings with atypical teratoid rhabdoid tumorPresented by Mariangela Sabatella, Princess Mxima Center for Pediatric Oncology, Utrecht, Netherlands

2318 - FaNDOM: Fast Nested Distance-based seeding of Optical MapsPresented by Siavash Raeisi Dehkordi, Computer Science & Engineering, University of California San Diego, La Jolla

3023 - Structural hypervariability of low copy repeats on chromosome 22 is human specificPresented by Lisanne Vervoort, Department of Human Genetics, KU Leuven, Leuven, Belgium

3024 - Telomere-to-telomere assembly and complete comparative sequence analysis of the human chromosome 8 centromereReviewer's Choice Award RecipientPresented by Glennis Logsdon, Genome Sciences, University of Washington, Seattle, WA

3311 - Comprehensive structural variant identification with optical genome mapping and short-read sequencing for diagnosis of disorders/differences of sex development (DSD)Reviewer's Choice Award RecipientPresented by Hayk Barseghyan, Center for Genetic Medicine Research, Children's National Hospital, Washington, DC

3318 - De novo mutation and skewed X-inactivation in girl with BCAP31-related syndromePresented by H.J. Kao, Institute of Biomedical Sciences, Academia Sinica, Taipei, Taiwan

3560 - Resolving genomic structures inMECP2Duplication Syndrome provides insight into genotype-phenotype correlationsReviewer's Choice Award RecipientPresented by Davut Pehlivan, Molecular and Human Genetics, Baylor College of Medicine, Houston, TX

2157 -methometR: quantification of long-range haplotype specific methylation levels from Optical Genome MapsPresented by Surajit Bhattacharya, Center for Genetic Medicine Research, Childrens Research Institute, Childrens National Hospital, Washington, DC

About Bionano GenomicsBionano is a genome analysis company providing tools and services based on its Saphyr system to scientists and clinicians conducting genetic research and patient testing, and providing diagnostic testing for those with autism spectrum disorder (ASD) and other neurodevelopmental disabilities through its Lineagen business. Bionanos Saphyr system is a platform for ultra-sensitive and ultra-specific structural variation detection that enables researchers and clinicians to accelerate the search for new diagnostics and therapeutic targets and to streamline the study of changes in chromosomes, which is known as cytogenetics. The Saphyr system is comprised of an instrument, chip consumables, reagents and a suite of data analysis tools, and genome analysis services to provide access to data generated by the Saphyr system for researchers who prefer not to adopt the Saphyr system in their labs. Lineagen has been providing genetic testing services to families and their healthcare providers for over nine years and has performed over 65,000 tests for those with neurodevelopmental concerns. For more information, visitwww.bionanogenomics.com or http://www.lineagen.com.

Forward-Looking StatementsThis press release contains forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. Words such as may, will, expect, plan, anticipate, estimate, intend and similar expressions (as well as other words or expressions referencing future events, conditions or circumstances) convey uncertainty of future events or outcomes and are intended to identify these forward-looking statements. Forward-looking statements include statements regarding our intentions, beliefs, projections, outlook, analyses or current expectations concerning, among other things: the timing and content of the presentations identified in this press release; the effectiveness and utility of Bionanos technology in basic genetic research and clinical settings; the contribution of Saphyr to uncovering novel genetic variants that contribute to cancer and genetic disease; the benefits of Bionanos optical mapping technology and its ability to facilitate genomic analysis in future studies; and Bionanos strategic plans. Each of these forward-looking statements involves risks and uncertainties. Actual results or developments may differ materially from those projected or implied in these forward-looking statements. Factors that may cause such a difference include the risks and uncertainties associated with: the impact of the COVID-19 pandemic on our business and the global economy; general market conditions; changes in the competitive landscape and the introduction of competitive products; changes in our strategic and commercial plans; our ability to obtain sufficient financing to fund our strategic plans and commercialization efforts; the ability of medical and research institutions to obtain funding to support adoption or continued use of our technologies; the loss of key members of management and our commercial team; and the risks and uncertainties associated withour business and financial condition in general, including the risks and uncertainties described in our filings with the Securities and Exchange Commission, including, without limitation, our Annual Report on Form 10-K for the year ended December 31, 2019 and in other filings subsequently made by us with the Securities and Exchange Commission. All forward-looking statements contained in this press release speak only as of the date on which they were made and are based on management's assumptions and estimates as of such date. We do not undertake any obligation to publicly update any forward-looking statements, whether as a result of the receipt of new information, the occurrence of future events or otherwise.

CONTACTSCompany Contact:Erik Holmlin, CEOBionano Genomics, Inc.+1 (858) 888-7610eholmlin@bionanogenomics.com

Investor Relations Contact:Ashley R. RobinsonLifeSci Advisors, LLC+1 (617) 430-7577arr@lifesciadvisors.com

Media Contact:Darren Opland, PhDLifeSci Communications+1 (617) 733-7668darren@lifescicomms.com

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Penn Medicine Researchers Receive $5.4 million Grant to Find Genetic Drivers of Testicular Cancer – Newswise

Posted: October 28, 2020 at 3:51 am

Newswise PHILADELPHIAThe international hunt to find more genetic risk markers for testicular cancer is expanding. A team of researchers led by Katherine L. Nathanson, MD, deputy director of the Abramson Cancer Center and the Pearl Basser Professor for BRCA-Related Research in the Perelman School of Medicine at the University of Pennsylvania, was recently awarded $5.4 million over five years from the National Institutes of Health to continue the long-standing genomics work of the TEsticular CAncer Consortium (TECAC).

A total of nearly $7 million has been awarded to TECAC, which includes researchers from 27 institutions around the world, whose collaborative goal is understand the genetic susceptibility to testicular germ cell tumors (TGCT).

TGCT are the most common cancer in the United States and Europe in men between the ages of 15 to 45, and the number of cases has continued to rise over the past 40 years. Approximately 50 percent of the risk of disease is due to genetic factors, higher than for other cancer types.

To date, TECAC has identified 22 novel susceptibility alleles, bringing the total number of risk markers to 66. Nathanson led a study in 2017 published in Nature Genetics that identified eight of those markers in previously unknown gene regions, as well as four in previously identified regions.

Members of TECAC also were the first to identify CHEK2, a moderate penetrance gene for TGCT. Penetrance refers to the proportion of people with a mutation in specific gene. Unlike other solid tumor types (e.g. breast, ovarian), the inherited risk of TGCT is likely due to multiple variants rather than any single gene.

Our work has revealed critical roles for genetic variants and mutations in testicular germ cell tumors and defined the biology of TGCTs as associated with defects in maturation of male germ cells, but theres still much more to discover with this highly heritable disease, Nathanson said. This grant will allow us to continue to pool our resources and expertise to better understand its biology and etiology, as well as provide data that can help identify men at higher risk of the disease and in need of surveillance.

The latest round of funding will focus on three projects: identify rare and common variants using whole exome genetic sequencing from biosamples of more than 2,000 men; conduct a transcriptome-wide association study, or TWAS, to identify novel candidate susceptibility genes in nearly 250,000 men (the largest to date); and further evaluate any variants or gene discovered from those two projects using tools, such as CRISPR, in cells.

Other Penn collaborators on this grant (R01 CA164947 A1) include David Vaughn, Linda Jacobs, Li-San Wang and Mingyao Li.

##

Penn Medicineis one of the worlds leading academic medical centers, dedicated to the related missions of medical education, biomedical research, and excellence in patient care. Penn Medicine consists of theRaymond and Ruth Perelman School of Medicine at the University of Pennsylvania(founded in 1765 as the nations first medical school) and theUniversity of Pennsylvania Health System, which together form a $8.6 billion enterprise.

The Perelman School of Medicine has been ranked among the top medical schools in the United States for more than 20 years, according toU.S. News & World Report's survey of research-oriented medical schools. The School is consistently among the nation's top recipients of funding from the National Institutes of Health, with $494 million awarded in the 2019 fiscal year.

The University of Pennsylvania Health Systems patient care facilities include: the Hospital of the University of Pennsylvania and Penn Presbyterian Medical Centerwhich are recognized as one of the nations top Honor Roll hospitals byU.S. News & World ReportChester County Hospital; Lancaster General Health; Penn Medicine Princeton Health; and Pennsylvania Hospital, the nations first hospital, founded in 1751. Additional facilities and enterprises include Good Shepherd Penn Partners, Penn Medicine at Home, Lancaster Behavioral Health Hospital, and Princeton House Behavioral Health, among others.

Penn Medicine is powered by a talented and dedicated workforce of more than 43,900 people. The organization also has alliances with top community health systems across both Southeastern Pennsylvania and Southern New Jersey, creating more options for patients no matter where they live.

Penn Medicine is committed to improving lives and health through a variety of community-based programs and activities. In fiscal year 2019, Penn Medicine provided more than $583 million to benefit our community.

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Canada’s Prime Minister, Justin Trudeau, Announced Today Precision NanoSystems Will Receive $18.2 Million from the Government of Canada to Develop an…

Posted: October 28, 2020 at 3:51 am

VANCOUVER, BC, Oct. 23, 2020 /PRNewswire/ -Precision Nanosystems, Inc. (PNI), a global leader in technologies and solutions in genetic medicine, announced today that it has received a commitment of up to $18.2 million in support from the Government of Canada under the Innovation, Science and Economic Development's (ISED) Strategic Innovation Fund (SIF) to develop a COVID-19 vaccine. PNI will use the investment to advance a best-in-class COVID-19 mRNA vaccine candidate to clinical trials.

PNI provides over 250 industry and academic partners with solutions for the development of vaccines, gene therapies, and cell therapies, in the areas of infectious diseases, oncology and rare diseases. With this investment from the Government of Canada, PNI's Chief Scientific Officer, Dr. Andrew Geall, and his team will use their state-of-the-art technology platforms and expertise in self-amplifying mRNA vectors, lipid-based drug delivery systems and nanomedicine manufacturing to develop a cost-effective COVID-19 vaccine.

As part of Canada's efforts to combat COVID-19, the Strategic Innovation Fund is working diligently to support projects led by the private sector for COVID-19 related vaccine and therapy clinical trials to advance Canada's medical countermeasures in the fight against COVID-19. "An effective vaccine will be critical as we work to contain the COVID-19 virus and prevent future infections.Today's contribution will support PNI to advance the development of a mRNA vaccine candidate through pre-clinical studies and clinical trials to help protect Canadians," stated the Honorable Navdeep Bains, Minister of Innovation, Science and Industry.

Bringing together its proprietary technology platforms, key partnerships and unparalleled expertise in nanomedicines, PNI is excited to be leading the development of a Made-in-Canada COVID vaccine. James Taylor, CEO and co-founder of PNI said "Since its inception PNI has executed on its mission to accelerate the creation of transformative medicines. It is an honor to be supported by the Canadian government in this global fight against COVID-19 and to further build capabilities for rapid response against COVID-19 and future pandemics"

About Precision NanoSystems Inc. (PNI)

PNI is a global leader in ushering in the next wave of genetic medicines in infectious diseases, cancer and rare diseases. We work with the world's leading drug developers to understand disease and create the therapeutics and vaccines that will define the future of medicine. PNI offers proprietary technology platforms and comprehensive expertise to enable researchers to translate disease biology insights into non-viral genetic medicines.

SOURCE Precision Nanosystems

http://www.precisionnanosystems.com

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