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Cell Biology

What will be the biggest scientific breakthrough of 2020? – Stuff.co.nz

Cheap, re-purposed cancer drugs, negative carbon-emissions technology, calculating how fast the universe is expandingand huge leaps forward in quantum computing.

Will one of these be the biggest scientific breakthrough of 2020?

We asked a handful of New Zealand's top scientists what "Eureka!" moments might be on the cards next year but even with their formidable combined brain power and expertise, some found it hard to answer and hinted it was difficult to sheet home specific advances to any one year.

And, as one scientist says, 2020's most ground-breaking discovery may come as a total surprise, made accidentally by a student in a lab late one night.

READ MORE:*Scientists are baffled: What's up with the universe?*Medicine already in use may help cancer treatments*Roger Hanson: How you figure out the age of the universe*Doing my part not only to be carbon neutral but carbon negative

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2020's most ground-breaking discovery may come as a total surprise, made accidentally by a student in a lab late one night.

Wellington's Gillies McIndoe Research Institute is carrying out cutting-edge research into ways of treating cancer without radiotherapy, chemotherapy or surgery.

The institute's founder and executive director, Dr Swee Tan, believes significant steps will be made in 2020 towards "re-purposing" existing drugs for cancer treatment.

Tan, a plastic surgeon and medical researcher who has received international recognition for dealing with life-threatening and disfiguring conditions, saiddrugs licensed and marketed for a particular treatment often had other benefits.

"They can be re-purposed for another condition, for the treatment of cancer. This is usually with drugs that have been around for some time they are off-patent, so they become generic, which means they cost next to nothing.

"Another advantage is their safety profile is well understood."

Wellington's Gillies McIndoe Research Institute's founder and executive director, Dr Swee Tan, believes significant steps will be made in 2020 towards "re-purposing" existing drugs for cancer treatment.

Globally, 18 million new cancer cases are diagnosed each year, resulting in nearly 10 million deaths.

"In New Zealand alone, new cancer cases are about 25,000 a year, and on top of that there are 11,000 non-melanoma skin cancers.

"The incidence of cancer is predicted to increase by 50 per cent by 2035, which is just around the corner. We are completely unprepared for that."

The increased incidence of cancer largely bowel, breast, prostate and lung cancers, and melanoma is mostly because people are living longer and due to lifestyle and diet, Tan says.

"Part of the problem now is the expense of treatment. In New Zealand, we spend $1 billion a year to treat cancer, and that is just the fiscal cost, that doesn't count emotional or personal.

"The cost is escalating because of the novel cancer drugsand, at some point, we are not going to be able to afford treatment for cancer.

"This creates disparity in access to treatment because some of these drugs are not funded and, if you have the means, you can buy it, but I don't think that is a good way to run a society. I think a society should allow people to access healthcare, regardless of personal circumstance."

Royal Society Te Aprangi/VIMEO

New Zealand is as vulnerable as all countries to the global growth in antimicrobial resistance that is making some diseases untreatable. Dr Siouxsie Wiles, a microbiologist from the University of Auckland, a Royal Society Te Aprangi Councillor and an expert adviser on the report on antimicrobial resistance produced by Royal Society Te Aprangi explains why it is such a big issue for us.

The institute has been undertaking a clinical trial based on drug re-purposing to control cancer stem cells, the proposed origin of cancer.

"It consists of a combination of low-cost, off-patent, oral medications to control cancer stem cells. We believe this would be more effective than using a single drug.

"For the cost of the drug itself, it costs about $4000 a year a patient, compared with the average cancer treatment, which is about $50,000 per patient.

"You have to prove it is effective first. The big issue with drug re-purposing is 'big pharma' is not interested because there is no money in it. The only way that we can realise the potential is for philanthropy and government to support initiatives like this."

Propranolol, a beta-blocker, had been added to the treatment for melanoma and angiosarcoma.

During 2020, GMRI would also be working on treatments for disfiguring keloid scars.

"They can cause quite significant issues with quality of life. They affect about 2 per cent of the general population, but in dark-skinned races, especially from the African continent, incidence can be up to 16 per cent.

"Treatment is really quite unsatisfactory, hence the reason why we are researching a solution. If you do surgery to remove it, almost every single one returns. Sometimes surgery is followed by radiotherapy to prevent recurrence. Topical chemotherapy is also used.

"What we have found is stem cells as the underlying problem. We are doing further work, which may allow us to develop a simpler, more effective, low-cost treatment taken by mouth, or by applying to the keloid lesion directly."

University of Auckland molecular biologist Dr Hilary Sheppard, a specialist in developmental and stem-cell biology, thinks there will be more emphasis next year on the gene-editing of adult cells.

University of Auckland microbiologist,associate professor Siouxsie Wiles, a specialist in infectious diseases and antimicrobial resistance, says there are "desperately" needed breakthroughs in her field next year and beyond, including:

- Rapid "bedside" diagnostic tests that are cheap and can tell the medical practitioner if the patient has a bacterial or viral infection "a bonus if it can tell, if bacterial, what antibiotics would kill the bacterium responsible".

- Effective vaccines for tuberculosis, gonorrhoea, Staphylococcus aureus, Group A and B Streptococci, giardia "I could go on and on".

- Drugs that can kill carbapenemase-producing Enterobacteriaceae "a very scary group of organisms that are becoming untreatable".

"The other breakthroughs we need aren't scientific, they are political," she says.

"[We need] a global agreement on tackling antimicrobial resistance, which would include incentives to bring the pharmaceutical industry back in to antimicrobial development.

"Failing that, nationalisation of pharmaceutical companies so that development of drugs isn't a for-profit initiative."

Phil Doyle/Stuff

University of Auckland microbiologist, associate professor Siouxsie Wiles, says a global agreement on tackling antimicrobial resistance is desperately needed.

University of Auckland molecular biologist Dr Hilary Sheppard, a specialist in developmental and stem-cell biology, thinks there will be more emphasis next year on the gene-editing of adult cells.

"We have seen some major breakthroughs this year, such as the versatile tool which allows for gene-editing with increased precision over existing tools so the technique is becoming more reliable and safer. Hopefully, next year, we will see these newer techniques being tested in clinically relevant cells.

"As part of that, I hope we will see a community-wide discussion about the ethics of gene-editing with a particular focus on adult cells. Personally, I do not think we should be editing germline cells or embryos at least not for the next five years, while the ethical issues are debated.

"Part of gene-editing is knowing what DNA sequence needs to be edited, so I think I hope this could be the year where personalised medicine and individual genotyping takes off.

"Our research focuses on patients with a fragile skin condition called epidermolysis bullosa (EB). We are pushing to get patients with EB genotyped so that we can perform gene-editing on their skin cells we can't do anything useful without this information.

"Currently, we are paying for the genotyping out of our research budgets. Of course, genotyping raises its own ethical and societal issues, so I hope we will see more discussion about this."

In 2020, results should start rolling in from clinical trials using edited T-cells against melanoma and edited bone-marrow cells to treat patients with sickle-cell anaemia, Sheppard says.

"These are very exciting times. I'm sure we'll see more clinical trials targeting previously untargeted disorders soon perhaps for conditions like Duchenne muscular dystrophy and cystic fibrosis."

RNZ

In this podcast, The Detail's Sharon Brettkelly talks to Auckland University physics professor Shaun Hendy about his no-flying mission for the whole of last year.

While Tan, Sheppard and Wiles are looking for discoveries on the tiniest of scales, other scientists are grappling with the biggest question in the universe.

Theoretical cosmologist and University of Auckland professor of physics Richard Easther is among those hoping for a resolution of what has become known as "Hubble tension" a growing disagreement in calculations of how fast the universe is expanding, which has repercussions on its likely age.

The Hubble Constant the number that tells us how fast the universe was expanding has always been hard to measure, he says.

"There was a period of time when a whole different bunch of approaches to measuring it had converged on a single value, which is fascinating. But just over the last couple of years, it seems like there are now two different sets of numbers you get and they've pulled apart a little bit.

"You know, there's this joke that science isn't so much about people saying 'Eureka!' but about someone looking at something and going, 'well, you know, that's funny'.

"This is increasingly resembling one of those moments.

"The numbers are clustering around two values one that would put it in the early to mid-70s [kilometres per second per megaparsec], and one that would put it in the mid- to late 60s, and the uncertainty in the measurements is such that they don't really overlap with each other.

"As the individual measurements get more accurate, the sharpness of the disagreement is growing."

University of Auckland physicist, professor Shaun Hendy, is expecting leaps ahead in clean energy in 2020.

Does it matter? Of course, Easther says.

"There are different physical assumptions that go into the different measurementsandso, if there is a real discrepancy, it would tell us there's something about the expansion of the universe that we don't understand.

"It's hinting at that. The implication seems to be that the story is one step more complicated than current models of the expanding universe might recognise.

"One thought is, that in one set of numbers, there's something that got missed and kind of got away. The other possibility is, there's something kind of physical, that isn't included in our current thinking of the expanding universe.

"The idea that there is something interesting going on is something that cosmologists over the course of the last year have grown substantially more willing to entertain."

Chris Skelton/STUFF

Nicola Gaston is an Associate Professor in the Department of Physics at the University of Auckland and Co-Director of the MacDiarmid Institute for Advanced Materials and Nanotechnology.

At the University of Otago, associate professor Mikkel Andersen, a physicist in the university's Dodd-Walls Centre for Photonic and Quantum Technologies, has been making astounding international discoveries and controlling the movement of individual atoms in a world-first laboratory experiment.

Such control opens up possibilities for a "second quantum technology revolution" and quantum supremacy, something Andersen says will creep closer in 2020.

The first quantum revolution was made possible by the discovery of quantum mechanics in the 1920s, leading to the development of transistors and lasers, the building blocks of all computers.

In the second, he says quantum computers of fewer than 100 atoms will ultimately be able to out-compete "the world's combined conventional computing power".

"Reaching quantum supremacy means that a quantum computer will be able to do calculations that cannot be done on the world's conventional computers. I do not know if it will happen next year, but it will happen eventually.

"In recent years, Google, IBM, Microsoft and a lot of others have invested enormously in development of quantum computers. Quantum supremacy is likely still some years away, but it is one of those things that would clear all the headlines if it happened in 2020."

University of Auckland physicist,professor Shaun Hendy, agrees.

"Google declared quantum supremacy last month they demonstrated that a quantum computer could beat a conventional computer, albeit at a very niche task.

"We'll see more of this next year, as quantum computers start to stretch their legs just don't expect to see one on your phone any time soon."

Ross Giblin

Victoria University of Wellington's professor James Renwick hopes to see breakthroughs in climate change science which reduce greenhouse gas emissions.

Hendy is also expecting leaps ahead in clean energy in 2020.

"We will continue to see the cost of solar and battery technologies fall, to the extent that they will start to disrupt other energy systems. We have seen this already in Australia, where it has become a defining political issue.

"It will play out differently in New Zealand, because our grid is already more than 80 per cent renewable, while many of our industrial energy systems are not. Expect to see some of our big industrial corporates Fonterra, NZ Steel etc moving to greener industrial processes."

Victoria University of Wellington's Professor James Renwick, head of the school of geography, environment and earth sciences, hopes to see breakthroughs in climate change science which reduce greenhouse gas emissions.

He points to work being done at the Cawthron Institute in Nelson into the benefits of using the seaweed Asparagopsis armata as cattle feed. Chemicals in the red seaweed reduce microbes in the stomachs of cattle that make them burp when eating grass.

Renwick is also excited about the use of artificial intelligence (AI) and machine learning to help with severe weather prediction.

"Weather forecasters are totally inundated with information these days, volumes of radar data and satellite data coming through every 10 minutes. So, AI can help in making sense of all that, and what is the most important in determining where, for example, a severe storm will happen."

University of Otago associate professor Mikkel Andersen believes a "second quantum technology revolution" and quantum supremacy will creep closer in 2020.

Auckland University of Technology senior lecturer Dr Mahsa Mohaghegh also foresees huge steps forward in AI and its applications next year and beyond.

"In the medical sector, AI is being used to speed up symptom recognition and diagnosis. Early warning signs can be easily detected, allowing fast reaction.

"Environment and climate monitoring using AI can assist with weather-cycle predictions, frost warnings, and harvest alerts. Automated irrigation is possible using moisture and temperature sensors."

There are also uses in New Zealand's burgeoning space industry, in traffic management and in the "smart home" of the future, she says.

"New Zealand is a leader and frontrunner in the development of AI and related fields. The next 10 years of technology development are set to be exciting."

David White

Auckland University of Technology senior lecturer Dr Mahsa Mohaghegh foresees huge steps forward in AI and its applications next year.

University of Auckland physicist, associate professor Nicola Gaston, co-director of the Victoria University of Wellington-hosted MacDiarmid Institute for Advanced Materials and Nanotechnology, told Stuff scientific discovery did not happen "one year at a time".

"Discoveries that impact on our lives next year will be built on work that has been going on for decades. The biggest discoveries of next year will be the ones that impact on our lives in a decade or two.

"But there is no competition between this fundamental scientific work of discovery and the development of technologies. The two go in tandemand, perhaps in 2020, we can try to appreciate that."

That may be finding a way of moving to negative emissions technologies, or changing the chemistry of materials so they are recyclable and avoid environmental pollution.

"The most important breakthrough of 2020 will be one that none of us sees.

"It'll be a dedicated student or post-doc in a lab somewhere, or up late at night on a computer, who solves the last remaining piece of one of the puzzles that underpin so much of what we hope technology can do for us in the future."

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What will be the biggest scientific breakthrough of 2020? - Stuff.co.nz

Cell Biology

CYTOVIA Therapeutics and the New York Stem Cell Foundation Research Institute enter into a partnership to develop iPSC derived CAR NK Therapeutics -…

Press release content from Globe Newswire. The AP news staff was not involved in its creation.

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NEW YORK, Jan. 09, 2020 (GLOBE NEWSWIRE) -- The New York Stem Cell Foundation (NYSCF) Research Institute today announced a partnership with Cytovia Therapeutics Inc. (Cytovia) to develop new disease treatments that leverage human stem cell research and novel gene editing techniques. NYSCF will be a key partner to Cytovia in using stem cells to advance novel therapeutic targets for cancer.

Cytovia leverages NK cells to make these novel therapeutics more specific to cancer cells. NK or natural killer cells are immune cells that scan the body and attack infected or abnormal cells, often serving as a first line of defense against cancer. CAR (chimeric antigen receptor) NK cells are genetically engineered to better locate and attack tumors. CAR NK-based treatments are currently showing promise in clinical trials and could serve as a potent and cost-efficient alternative to current immunotherapies. Establishing high-quality, stem-cell-derived NKs and CAR NKs will help improve these treatments and accelerate their path to the clinic.

The NYSCF Research Institute is a pioneer and acknowledged leader in stem cell technology, having developed the NYSCF Global Stem Cell Array, the premier automated robotic platform for reprogramming adult cells into induced pluripotent stem cells (iPSCs). These iPSCs carry the genetic blueprint of the person from whom they are derived and can be turned into any cell type in the body, allowing scientists to study disease mechanisms in affected cells or modify them for use in therapeutics.

Our mission is to bring lifesaving treatments to patients around the world and we are excited to further this goal in partnership with Cytovia, says NYSCF CEO and founder Susan L. Solomon. It is critical that we collaborate with partners using our technology and expertise to bring innovative treatments to the market.

We are delighted to collaborate with the NYSCF Research Institute to develop iPSC-derived NK and CAR NK therapeutics, says Dr. Daniel Teper, CEO of Cytovia. By integrating NYSCFs world-class stem cell know-how and the precision gene-editing research conducted at the University of California San Francisco, Cytovia aims to become a leader in NK cell therapeutics for the treatment of cancer.

About The New York Stem Cell Foundation Research Institute The New York Stem Cell Foundation (NYSCF) Research Institute is an independent non-profit organization accelerating cures and better treatments for patients through stem cell research. The NYSCF global community includes over 190 researchers at leading institutions worldwide, including the NYSCF Druckenmiller Fellows, the NYSCF Robertson Investigators, the NYSCF Robertson Stem Cell Prize Recipients, and NYSCF Research Institute scientists and engineers. The NYSCF Research Institute is an acknowledged world leader in stem cell research and in the development of pioneering stem cell technologies, including the NYSCF Global Stem Cell Array, which is used to create cell lines for laboratories around the globe. In 2019, NYSCF launched its Womens Reproductive Cancers Initiative, which aims to shift paradigms in the way these cancers are studied and treated, in collaboration with leading cancer experts across the globe. NYSCF focuses on translational research in an accelerator model designed to overcome barriers that slow discovery and replace silos with collaboration. For more information, visit http://www.nyscf.org.

About Cytovia Therapeutics Inc. Cytovia is dedicated to the development of transformational cancer immunotherapies, addressing several of the most challenging unmet medical needs including the prevention of cancer relapse and metastasis. Cytovia focuses on Natural Killer (NK) cell biology and applies precision medicine tools to develop the right therapy for the right patient at the right stage of the disease. Cytovia has secured access to multiple advanced technologies, including allogeneic cell therapy, multispecific antibodies, and cytokines. Cytovia establishes development partnerships to accelerate time-to-market and commercialization alliances in order to optimize rapid adoption of its novel immunotherapies. Learn more at cytoviatx.com

Contact information:CYTOVIA Therapeutics:Anna Baran-DjokovicVP, Corporate Affairs anna@cytoviatx.com

Cytovia Media Contact: Charlotte Tomic charlotte@tomiccommmunications.com Cell: 9178825243

NYSCF Research InstituteDavid McKeonChief of Staff dmckeon@nyscf.org

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CYTOVIA Therapeutics and the New York Stem Cell Foundation Research Institute enter into a partnership to develop iPSC derived CAR NK Therapeutics -...

Cell Biology

East Carolina University Researcher Is Conquering Disease | Greenville – Patch.com

From East Carolina University:

By Doug Boyd

January 9 2020

Byron Aguilar is studying how a group of signaling proteins called Rho GTPases, which play a role in several common cellular functions, might affect the development of not only cancer but also Alzheimer's disease.

He's been working on that for the past six years as a postdoctoral scholar in the Department of Anatomy and Cell Biology in the Brody School of Medicine at East Carolina University.

Postdoctoral scholars are researchers who have completed their doctoral degrees and are working with a faculty mentor to further their knowledge and skills.

The ZCL compound is one Aguilar developed while researching cancer treatments.

Originally from the Pacific island of Guam, Aguilar was a graduate student at Florida A&M University and was presenting his research at a conference when ECU anatomy and cell biology professor Qun Lu began asking him about his work. And asking and asking.

"I was actually a bit annoyed by it all," Aguilar recalled. "At the end, he told me the reason he was asking all those questions is he was looking for a postdoc. So then I asked him if there was anything else he wanted to know."

Soon after, Aguilar arrived in Greenville. The National Cancer Institute funded his first few years of research, and the Alzheimer's Association is funding him now. That's because some of the drugs he developed, the ZCL compounds, have shown the ability to target the development of cancer cells as well as the cellular processes that lead to Alzheimer's disease. ZCL compounds regulate Rho GTPase activity.

"It's because of the support of so many people at ECU that I can focus wholeheartedly on research," he said.

Aguilar said his postdoc experience has given him a chance to work on the early stages of drug development as well as delve into the next step, which is animal testing. He also recently traveled to the M.D. Anderson Cancer Center in Houston for a business development workshop, which he said gave him a glimpse of what it would take to drive the development of his drugs to the next step, human clinical trials.

Aguilar will complete his postdoctoral work in December but might stay at ECU for further research, start a spinoff company with ECU collaboration or pursue an opportunity at another university or in industry.

"The more I learn about cancer and Alzheimer's disease, the more I learn they are not controlled by just one thing. They're controlled by multiple things, possibly even the same things," he said. And in many cases, those factors are aggravated by the effects of aging.

"I'm trying to understand how these things are connected and how I can make a drug that can help patients," he added.

In addition to his research, Aguilar founded a postdoctoral grant review group to share his experiences in grant writing. He has given educational presentations to dementia care professionals and patient families across eastern North Carolina. He's also vice president of the Postdoctoral Association at ECU.

"Byron is a well-rounded scientist and person always willing to lend a helping hand," said Lu. "He is one of my best postdoctoral fellows over the past 20 years. Besides his devotion to research, he stands out in being a wonderful citizen of community."

ECU's 30 postdoctoral scholars span 18 departments across the university's academic affairs, health sciences and research divisions. Former postdocs have taken positions at research campuses, public and private universities, and pharmaceutical companies, among others.

Aguilar's research has been funded by the National Cancer Institute and the Alzheimer's Association.

This press release was produced by East Carolina University. The views expressed here are the author's own.

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East Carolina University Researcher Is Conquering Disease | Greenville - Patch.com

Cell Biology

Emergex Raises More Than US$11 Million in a Series A Round to Progress Its Pipeline of Set-Point Vaccines for Infectious Diseases – Business Wire

ABINGDON, England--(BUSINESS WIRE)--Emergex Vaccines Holding Limited (Emergex), a biotechnology company developing set-point vaccines to prevent serious infectious diseases, today announced that it has secured over US$11 million in a Series A round. Vickers Venture Partners (Vickers), a top-ranked global early stage Venture Capital company led the round and Dr. Finian Tan, Chairman of Vickers Venture Partners, will join the Emergex Board as a non-executive director.

Founded in 2016, Emergex focuses on developing vaccines that prevent virulent diseases such as Zika, Dengue Fever, Ebola and even pandemic Flu. The Companys set-point vaccines deliver experimentally-derived pathogen peptide data via quantum-sized nanoclusters to prime the immune system to recognise subsequent infections, mimicking natural infection and preventing severe manifestation of the disease. Emergexs T-cell vaccines elicit different responses than traditional antibody-producing vaccines, eliminating allergic, autoimmune or antibody-mediated side effects.

Emergexs underlying platform technology enables rapid development of vaccines to entire families of pathogens, compared to traditional approaches that can take years to develop and scale vaccines for single pathogens. As purely synthetic vaccines with no biological components, Emergexs vaccines are much safer as they carry no infection risk from live attenuated pathogens; are much cheaper to produce since they do not require culturing; and can be conveniently transported and administered even in remote parts of the world as they can be stored and handled at room temperature.

The financing supports the progress of Emergexs development pipeline, including a first-in-man Phase 1 clinical trial of its Flavivirus (Dengue) vaccine in Switzerland, as well as Phase 1b clinical trials in the endemic regions of Singapore and Brazil. Proceeds will also support the Universal Influenza and Filovirus programmes through the preclinical stages and early clinical trials. In parallel, Emergex will continue to identify peptide libraries for a range of infectious disease indications to further expand and diversify the Companys development pipeline.

Professor Thomas Rademacher, CEO and co-founder of Emergex, commented, Attracting such high calibre investors is an endorsement of our development pipeline and validation of the potential our technologies hold in the field of infectious diseases. These new funds will support us to achieve some significant value-enhancing milestones as we progress our lead vaccine candidates into clinical development.

In addition to leading this financing, Vickers Venture Partners will assist Emergex with growth at the strategic level, by leveraging its experienced team of technical experts who have a strong track record in helping life science companies raise capital and scale up, and connecting Emergex to its networks of investment and industry partners.

Dr Finian Tan, Chairman of Vickers Venture Partners and a new Emergex non-executive director, added, With todays rising global population, the risk posed by infectious diseases is greater than ever before. As such, it is vital that we value and pursue innovation to ensure we have effective healthcare options. We see great potential in Emergexs technology as it allows vaccines to be produced quickly, administered easily and sold at a fraction of current prices. We believe that this would revolutionize the entire world of vaccines and increase access to a larger number of people around the world.

Over the last year, Emergex achieved significant milestones, including demonstrating an excellent safety profile for the base particle that will be used for all its vaccines and an excellent safety profile for the final dengue vaccine construct. The Company also signed a collaboration agreement with A*STARs IMCB in Singapore to develop a vaccine for Hand, Foot & Mouth disease, and secured a state-of-the-art R&D facility at Milton Park near Oxford, bringing in-house its own up-stream capabilities to drive development of its vaccines.

About Emergex

Emergex, a UK-based biotechnology company headquartered in Abingdon, UK, is pioneering the development of set-point vaccines to address some of the worlds most immediate health threats such as Dengue Fever, Zika, Ebola, pandemic flu and serious intra-cellular bacterial infections.

These set-point vaccines are population based and modify the initial immune status of recipients in a way that primes their immune systems to recognise subsequent infectious agents much like a natural infection would do, preventing an acute or severe manifestation of the disease.

Emergex combines validated technologies together with the very latest scientific insights to develop its vaccines, including using synthetic peptide codes determined on actual infected cells and using a proprietary gold nanoparticle carrier system for programming.

The Company has a growing pipeline of vaccine candidates. The most advanced development programme is a vaccine for Dengue Fever, which may also be disease modifying for other Flaviviruses such as the Zika and Yellow Fever viruses. Emergex also has programmes in development for a universal Influenza vaccine and a universal Filovirus vaccine (including viruses such as Ebola and Marburg) and discovery programmes for a Yellow Fever Booster vaccine and a Chikungunya vaccine.

Emergex has partnered with the Institute of Molecular and Cell Biology (IMCB) of Singapore to develop a vaccine for the emerging threat of Hand, Foot and Mouth (HFM) disease and has signed a Memorandum of Understanding (MoU) with Brazil-based Oswaldo Cruz Foundation Fiocruz for the development of viral vaccines. This initially covers the development of a vaccine that universally targets diseases within the flavivirus family such as Dengue Fever, Zika and Yellow Fever but could be expanded to include the development of vaccines to target other viral families that are endemic to the region.

Find out more online at http://www.emergexvaccines.com.

About Vickers Venture Partners

Vickers Venture Partners is a global venture capital firm focused on early-stage investments in the technological and geographical mega trends of the world. The firms portfolio covers life sciences, technology, media, and telecommunications as well as consumer and financial services. The partners track records include hits such as Baidu.com, Inc, Focus Media Holding Ltd, Kongzhong Corp, Cambridge Real Estate Investment Trust, Sunfun Info Co., Asian Food Channel (trade sale), UUCUN (trade sale), TWG Tea (trade sale), RTG Asia (trade sale), JJE (trade sale), Hillstone (trade sale, IPO), M-Daq (trade sale), Tenfen (trade sale), Kuyun (trade sale) and Mainspring (trade sale). The total market value of the companies that the partners have helped grow exceeds US$90 billion today. Vickers Venture Partners announced that they are targeting to raise US$500 million for their latest fund VI and have started investing from it after their first close in Oct 2019.

Vickers Venture Partners was founded by Dr Finian Tan together with his co-founders Dr Khalil Binebine, Dr Jeffrey Chi, Dr Damian Tan, Linda Li and Raymond Kong in 2005. It is headquartered in Singapore with offices in Kuala Lumpur, Shanghai, Hong Kong, New York, San Diego, Silicon Valley and London.

Find out more online at http://www.vickersventure.com.

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Emergex Raises More Than US$11 Million in a Series A Round to Progress Its Pipeline of Set-Point Vaccines for Infectious Diseases - Business Wire

Cell Biology

A New "Census" of the Zebrafish Brain – Technology Networks

The zebrafish is a master of regeneration: If brain cells are lost due to injury or disease, it can simply reproduce them - contrary to humans where this only happens in the fetal stage. However, the zebrafish is evolutionarily related to humans and, thus, possesses the same brain cell types as humans. Can a hidden regeneration potential also be activated in humans? Are therapies for stroke, craniocerebral trauma and presently incurable diseases such as Alzheimer's and Parkinson's possible?

Dresden scientists have succeeded in determining the number and type of newly formed neurons in zebrafish; practically conducting a census in their brains. Following an injury, zebrafish form new neurons in high numbers and integrate them into the nervous system, which is the reason for their amazing brain regeneration ability.

The study was conducted as a collaboration project made in Dresden; scientists from the Center for Regenerative Therapies TU Dresden (CRTD) combined their expertise in stem cell biology with the latest methods from the DRESDEN-concept Genome Center and complex bioinformatic analyses from the Max Planck Institute for the Physics of Complex Systems and the Center for Systems Biology Dresden.

For their study, the team led by Dr. Christian Lange and Prof. Dr. Michael Brand from the CRTD used adult transgenic zebrafish in whose forebrain they were able to identify the newborn neurons. The forebrain of the zebrafish is the equivalent to the human cerebral cortex, the largest and functionally most important part of the brain. The Dresden research team investigated the newborn and mature neurons as well as brain stem cells using single cell sequencing. Thus, they discovered specific markers for newborn neurons and were able to comprehensively analyze which types of neurons are newly formed in the adult brain of the zebrafish.

The scientists discovered two types of neurons that can be newly formed; projection neurons, which create connections between brain areas, and internal neurons, which serve to fine-tune the activity of the projection neurons. The researchers also investigated the data obtained from brain cell sequencing of mice and found that zebrafish and mice have the same cell types. This also makes these results highly relevant for humans.

"On the basis of this study, we will further investigate the regeneration processes that take place in zebrafish. In particular, we will study the formation of new neurons after traumatic brain damage and their integration," explains Prof. Dr. Michael Brand, CRTD Director and senior author of the study. "We hope to gain insights that are relevant for possible therapies helping people after injuries and strokes or suffering from neurodegenerative diseases. We already know that a certain regenerative ability is also present in humans and we are working on awakening this potential. The results of our study are also important for understanding the conditions under which transplanted neurons can network with the existing ones and thus could let humans re-gain their former mental performance.

Reference

Lange et al. (2020) Single cell sequencing of radial glia progeny reveals diversity of newborn neurons in the adult zebrafish brain. Development. DOI: https://doi.org/10.1093/ajcn/nqz232

This article has been republished from the following materials. Note: material may have been edited for length and content. For further information, please contact the cited source.

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A New "Census" of the Zebrafish Brain - Technology Networks

Cell Biology

Discovery of cellular ‘hands’ could have implications in the fields of cell, developmental biology – News-Medical.net

The protein, called syndecan-4, combines with fellow cell membrane proteins, called integrins, to form protruding 'hands' that sense the environment outside the cell.

Both proteins sit in the cell membrane, with one end pointing inside the cell and the other outside. They are therefore in a prime position to sense conditions outside the cell and convert signals to biochemical messages that change conditions inside the cell. In doing so, they're able to drive some of the cellular processes behind cancer and other diseases.

The early-stage research, conducted by a team at Imperial College London, Queen Mary University of London, and Tampere University in Finland, could present a new research pathway and drug target for certain cancer types.

Lead researcher Dr Armando del Ro Hernndez, of Imperial's Department of Bioengineering, said:

Our findings could have immediate implications in the fields of cell and developmental biology, and lead to developments in several diseases including cancer and fibrosis."

The paper is published today in Nature Materials.

Syndecan-4 exists in nearly every human cell and is already known for its role in cardiovascular disease. However its potential roles in cancer biology and drug development have thus far been overlooked.

To study syndecan-4 the research team, led by Dr del Ro Hernndez, used biophysical, cell biology, and computational techniques.

The team found that activating these cellular 'hands' triggers a pathway with key roles in disease development, involving a cellular protein called the yes-associated protein (YAP).

YAP triggers some of the typical hallmarks of cancer. It reduces cells' ability to program their own death, in a process called apoptosis. Cells initiate apoptosis when they age or malfunction, so halting apoptosis allows diseased, even cancerous, cells to spread. YAP also controls the development of blood vessels - a hallmark of cancer as tumor growth requires extra blood flow.

They also found that syndecan-4 helps cells respond to movements outside themselves, by creating tension in the cytoskeleton - the 'scaffolding' within cells. This makes cells stiffen, which activates an enzyme called PI3K that regulates additional hallmarks of cancer.

It does this by converting the movements outside the cell into biochemical signals which, the researchers found, 'tune' the way the cells respond to tension and movement.

Dr del Ro Hernndez said: "The way cells interact with their environment could inform how we engineer tissues and mimic human organs for drug design. Syndecan-4 could now play a fundamental part in this endeavor."

Co-lead author Dr Stephen Thorpe of Queen Mary University of London said:

As syndecan-4 is expressed on almost all of our cells, the mechanisms we've uncovered could be targeted to alter any number of diseases and biological processes."

Professor Vesa Hytnen of Tampere University said: "Better understanding of cellular mechanosensing opens possibilities to develop treatments for conditions like cancer and fibrosis."

Next, the research team will further investigate syndecan-4's links to specific diseases like pancreatic cancer.

Dr del Ro Hernandez said:

Our next approach will involve syndecan-4 as a key contributor in disease. We hope this will lead to new insights into disease mechanisms."

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Discovery of cellular 'hands' could have implications in the fields of cell, developmental biology - News-Medical.net

Cell Biology

Fitzpatrick elected to microscopy society governing council – Washington University School of Medicine in St. Louis

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Noted for his expertise in cellular imaging, 3D microscopy

Fitzpatrick

James Fitzpatrick, PhD, a professor of neuroscience and of cell biology and physiology at Washington University School of Medicine in St. Louis, has been elected biological sciences director of the Microscopy Society of America. He will serve a three-year term on the societys governing council beginning in 2020.

An expert in biological imaging, Fitzpatrick is the director of the Washington University Center for Cellular Imaging. The center boasts 16 state-of-the-art light, X-ray and electron microscopes including a 300kV Titan Krios cryo-electron microscope and provides imaging expertise and support to researchers at the university and elsewhere.

Fitzpatricks research is focused on developing ways to correlate microscopy using charged particles such as electrons or ions with light microscopy of the same sample. By combining the advantages of charged-particle microscopy methods which generate finely detailed grayscale images at nanoscale resolution and light microscopy which uses color-coded labels to flag molecules or internal cellular structures of interest Fitzpatrick aims to advance our understanding of biological processes in human health and disease. He also is working to use artificial intelligence methods to develop new tools to visualize and manipulate image data obtained from different techniques.

The Microscopy Society of America is dedicated to the promotion and advancement of techniques and applications of microscopy and microanalysis in relevant scientific disciplines. Fitzpatrick plans to use his position on the societys governing council to increase trainee engagement with the society, cultivate mentorship opportunities for early-career scientists and advocate for increased diversity in the community.

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Fitzpatrick elected to microscopy society governing council - Washington University School of Medicine in St. Louis

Cell Biology

Vapers Reported Adverse Health Effects Online for Years: Study – The Scientist

An analysis of language on an electronic cigarette users online discussion forum shows vapers reported adverse health effects online for at least seven years, long before vaping-associated pulmonary illness, or VAPI, was recognized by the medical community last summer, researchers reported January 3 in the Journal of Medical Internet Research.

The sudden uptick in symptoms and conditions related to VAPI comes at least 10 years after e-cigarette products gained widespread popularity in the United States, including the rise in popularity of JUUL and marijuana vape products, Prue Talbot, a professor of cell biology at the University of California, Riverside, who led the research, says in a media release. Our data, which shows many of the symptoms characterizing the current patients have been reported online for at least seven years, suggests cases similar to those in the current VAPI epidemic have existed previously and been unreported or simply not linked to vaping.

To conduct the study, Talbot and her team collected information from an e-cigarette forum posted between January 2008 and July 2015 and used a web crawler to analyze the language to evaluate the health effects of vaping. Of the 41,000 posts analyzed, 17 percent mentioned positive health effects, 38 percent were neutral, and 45 percent mentioned negative health effects. Although positive symptoms were not frequently reported in the forum, some individuals did mention reduced tiredness, insomnia, and wheezing, while the negative health effects included headache, throat pain, coughing, itching, and uneasiness, similar to some of the symptoms listed for VAPI.

Our data underscore the idea that e-cigarette use is not free of adverse health effects and suggest that the epidemic we are seeing now will continue to grow given the many reports in the forum of symptoms characteristic of VAPI, My Hua, a graduate student in Talbots lab, says in the release. It is important that vigilant reporting of cases, tracking symptoms, and engaging in research on the health effects related to e-cigarette use be continued and expanded to understand and contain VAPI.

Ashley Yeager is an associate editor atThe Scientist. Email her atayeager@the-scientist.com. Follow her on Twitter@AshleyJYeager.

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Vapers Reported Adverse Health Effects Online for Years: Study - The Scientist

Cell Biology

Where Are They Now? Top 3 Biotech Startups From NextGen Bio Class of 2018 – BioSpace

Every year, BioSpace analyzes the biotech industry, looking for the hot new biotech startups to watch. We then produce the NextGen Bio Class of, twenty companies ranked based on several categories, including Finance, Collaborations, Pipeline, and Innovation. The companies were typically launched no more than 18 months before the list was created.

We thought it would be insightful to look back at our previous lists to see where some of those companies are today. Heres a look at the top three companies from the Top 20 Life Science Startups to Watch in 2018.

#1. BlueRock Therapeutics. Founded in 2016, BlueRock was #1 on our list of companies to watch in 2018. With facilities in Ontario, Canada; Cambridge, Massachusetts; and New York, New York, BlueRock launched in December 2016 with a $225 million Series A financing led by Bayer AG and Versant Ventures. The company focuses on cell therapies to regenerate heart muscle in patients who have had a heart attack or chronic heart failure, as well as therapies for patients with Parkinsons disease.

In October 2017, BlueRock and Seattle-based Universal Cells entered into a collaboration and license deal to create induced pluripotent stem (iPS) cell lines that can be used in the manufacture of allogeneic cellular therapies. Shortly afterwards, the company established its corporate headquarters in Cambridge, and in April 2018, established a research-and-development hub in New York City, as well as formalizing a sponsored research collaboration with the Center for Stem Cell Biology at Memorial Sloan Kettering (MSK) Cancer Center. The collaboration focuses on translating Ketterings expertise in creating multiple types of authentic neural cells from stem cells to address diseases of the central and peripheral nervous system. BlueRock also received $1 million from the State of New York and Empire State Development under its economic development initiatives program.

In April 2019, BlueRock partnered with Editas Medicine (which was on BioSpaces NextGen Bio Class of 2015 list) to combine their genome editing and cell therapy technologies to focus on novel engineered cell medicines. Part of the deal was to collaborate on creating novel, allogeneic pluripotent cell lines using a combination of Editas CRISPR genome editing technology and BlueRocks iPSC platform.

And finally, in August 2019, Bayer AG acquired BlueRock for the remaining stake in the company for about $240 million in cash and an additional $360 million in pre-defined development milestones.

#2. Prelude Fertility. Prelude Fertility is a bit of an outlier from the typical BioSpace NextGen company, because it isnt quite a biopharma company. It is a life sciences company whose business model is aimed at in vitro fertilization and egg freezing. It was founded with a $200 million investment by entrepreneur Martin Varsavsky. The investment was in the largest in vitro fertilization clinic in the Southeast, Reproductive Biology Associates of Atlanta, and its affiliate, My Egg Bank, the largest frozen donor egg bank in the U.S.

Since then it has expanded in various parts of the country, including adding San Francisco-based Pacific Fertility Center (PFC) to its network in September 25, 2017; partnering with Houston Fertility Institute and acquiring Vivere Health; partnering with the Advanced Fertility Center of Chicago; and in October 2018, partnered with NYU Langone Health.

In March 2019, Prelude merged with Inception Fertility to establish the Prelude Network as the fastest-growing network of fertility clinics and largest provider of comprehensive fertility services in the U.S. Inception is acting as the parent company, with the Prelude Network, both having board representatives from the previous organizations.

#3. Relay Therapeutics. Ranking #3 on our list for 2018, Relay Therapeutics launched in September 2016 with a $57 million Series A financing led by Third Rock Ventures with participation form D.E. Shaw Research. On December 14, 2017, it closed on a Series B round worth $63 million, led by BVF Partners, with new investors GV (formerly Google Ventures), Casdin Capital, EcoR1 Capital and Section 32.

The company focuses on the relationship between protein motion and function. It merges computational power with structural biology, biophysics, chemistry and biology. In December 2018, the company completed a $400 million Series C financing. It was led by the SoftBank Vision fund and included additional new investors, Foresite Capital, Perceptive Advisors and Tavistock Group. Existing investors also participated.

The company announced at the time it planned to use the funds to accelerate the implementation of its long-term strategy, expanding its discovery efforts, advancing existing programs into the clinic and improving its platform.

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Where Are They Now? Top 3 Biotech Startups From NextGen Bio Class of 2018 - BioSpace

Cell Biology

Mitochondrial Division in the Cell Is Common in Primitive and Advanced Species on Earth – Science Times

(Photo : inteng-storage.s3.amazonaws.com)There is evidence that points out that mitochondria division shared by both primitive and advanced species living today.

All living things are born out from a cell, and thus began the hot pools where the cauldrons of creation cooked up the first batches of life. It was like a cook in the kitchen throwing in everything needed to complete the first cell. From this simple amoeba, the process ofmitochondrial divisionthat lives on to this day had started. All creature, living or extinct, primitive and advanced, have inherited this cellular mechanism from the first one-celled creature ever created.

The question about how everything ties up to the living "multi-cell scientist" or the "single-celled organisms"gave birth to the concept that everything is related to the simplest "amoeba" or "protozoan". This evolutionary process has been passed and tossed all over, resulting in the belief that it might be the same for other exo-species on other planets.

Tying up the loose ends for lower to higher animals is the"endosymbiotic theory",the keyword is endo- which is inside and symbiotic which refers to the connection to something. With the endosymbiotic theory, scientists state that advanced multi-cell animal, including homo sapiens, are "eukaryotes", while single-celled creatures are "prokaryotes". Both eukaryotes and prokaryotes related to the endosymbiotic theory, and science has come up with enough evidence to support it.

According to the study, all living creatures undergo a process of energy production in their cells. With themitochondria in the cells poweringupthe division of cells, production of enzymes and chemicals happen and it keeps animals alive. This is much like a mini-factory inside so many cells that create power for adaption and evolution that led to what life there is right now. The "mitochondria" is something like a gift from these creatures' "prokaryotic ancestors" which made evolution possible.

With the knowledge that all creatures have the ancient "mitochondria" inside, the next question is how similar are advanced and primitive species. Finding the secret, how the mitochondria exactly work, is what scientists need to know. It is Pandora's box of secrets that will open a new age of knowing more about the cellular biology of every living thing today.

To probe further, scientists at the Tokyo University of Science, headed bySachihiro Matsunagadid research on "mitochondria" with red algae. To make it easier, the group used it because it had one mitochondrion only. One result that shows promise, is when proteins were phosphorylated by Aurora kinase that produced "dynamin". Later on, other experiments carried out in a human cell had the same result, and "dynamin" was found too.

The experiment proved there is indeed a connection from the Red algae to a complex human. Finding "dynamin" as a regulator of mitochondria division is an incredible find for the Japanese researchers. The impact of the result is impressive, which sheds light why mitochondria division is critical to all species from primitive to advanced.

Related Article: Breakthrough in Understanding Evolution - Mitochondrial Division Conserved Across Species

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Mitochondrial Division in the Cell Is Common in Primitive and Advanced Species on Earth - Science Times