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Tag: Kulp

Wistar Scientists Successfully Engineer a Goldilocks Construct: Therapeutic Antibody Could Be a Future Medicine to Improve Outcomes for Melanoma

In recent years, multimodal therapies have emerged as a route to treat cancer by delivering different types of treatments together to improve effectiveness. However, the more modalities there are, the more complex the production and effects of these lifesaving treatments can become.

Wistar researchers have engineered a linked molecule that enables a three-modality therapy for treating melanoma. They accomplished this by connecting a cytokine and an antibody—which would ordinarily be administered separately—and then engineering a form that was pro-inflammatory enough to fight the cancer cells but not so inflammatory as to cause complications or reduce survival outcomes, according to a recently published study in Frontiers in Immunology.

“We took aspects of a cancer treatment regimen and tried to simplify that by combining antibody and cytokine together,” said Nicholas Tursi, the lead author on the study and a graduate student researcher in the lab of Dr. David Weiner, executive vice president, director of the Vaccine & Immunotherapy Center, and W.W. Smith Charitable Trust Distinguished Professor at The Wistar Institute. “I focused on engineering an intermediate cytokine that is efficacious but also has an acceptable pro-inflammatory profile—a Goldilocks approach.”

The engineered “Goldilocks” cytokine Tursi and his colleagues, including Dr. Weiner and Dr. Daniel Kulp, Associate professor in Wistar’s Vaccine & Immunotherapy Center, engineered to test their antibody cytokine chimera was called HL2-KOA1, a modified designer version of the T cell growth factor IL-2. This engineered molecule used in a combination therapeutic regimen was effective at promoting survival in a rigorous melanoma model.

“What this suggests is that we could use other antibodies or cytokines to engineer the immune response to further extend efficacy,” said Tursi. He is hopeful that this research will serve as the foundation for developing other antibody cytokine chimeras that work for melanoma and potentially other cancers.

A Wistar Journey Through the Past, Present, and Future of Immunization Work

Vaccines are a crucial public health tool in its’ arsenal against diseases. Resurgences of diseases long thought eradicated are popping up decades later in sewage waters here and abroad, and we’ve witnessed what the impact of war has on countries whose health systems have crumbled under the ravages of war—we are not as far removed as we’d like to be from diseases once prevented by vaccines. With more than half a century of basic research for vaccine development, The Wistar Institute plays an integral role in immunization around the globe.

Rubella, rabies, and rotavirus. Wistar scientists developed vaccines for these diseases that are used in immunization programs worldwide. The rubella vaccine by Wistar scientists effectively ended the pandemic in the United States, as declared by the CDC in 2005. Two rabies vaccinations developed from the Institute addresses the disease in both animals and humans. In 2006, Wistar and collaborators created a rotavirus vaccine which became part of the regular immunization schedule for U.S. babies and is used or approved in over 45 countries. And we’re just getting started.

“Immunization is possibly one of the most impactful medical interventions ever developed. Millions of lives are saved each year by vaccination, and we live healthier and longer lives due to vaccines.” states David Weiner, Ph.D., Executive Vice President, Director of Wistar’s Vaccine & Immunotherapy Center, and W.W. Smith Charitable Trust Professor in Cancer Research, in the Immunology, Microenvironment & Metastasis Program at Wistar’s Ellen and Ronald Caplan Cancer Center.

This National Immunization Awareness Month, we have shared a few snapshots of current vaccine development projects at the Institute as well as what these researchers’ hopes are for the future of immunization.

Tackling Both Infectious Disease and Cancer with Immunization

Dr. Weiner’s research takes on both infectious disease and cancer. His work encompasses developing new ways to build and deliver synthetic nucleic acid vaccines – particularly advancing a new approach that drives self-assembly of an antigen into a more potent vaccine inside a vaccinated person. This approach gives the body the genetic information to become the factory to create the vaccine. Furthermore, his lab is developing new types of cancer therapeutic vaccines with the goals of creating strong anti-cancer immunity and eradicating cancer cells.

Weiner’s collaborations with public and private institutions is centered around novel immunization technology developed from his lab called DNA-encoded monoclonal antibodies (DMAbs) against diseases such as COVID-19, Zika, and Ebola.

Regarding the future, he shares, “Together with our collaborators, we hope to move new prototype HIV vaccines into human clinical trials later this year, and continue to advance vaccines for emerging pathogens, as well as cancer immunotherapies.”

Developing DNA Vaccines

Ami Patel, Ph.D., Caspar Wistar Fellow in the Vaccine and Immunotherapy Center, focuses her scientific efforts on DNA vaccines which have potential to be more stable and economical over traditional vaccine production. “We are trying to understand how different vaccines work in the body. How do vaccines generate different types of immune responses and can we use this to understand protection against infectious diseases. We are using this information to help develop the next generation of potential vaccines.” she says.

Patel emphasizes the importance of vaccines for young children and adults by calling back to various infectious diseases like polio that are no longer very common because of immunization. “Vaccines help protect us against serious disease. Some of us remember the discomfort of chicken pox as children. There is now a vaccine.”

While she calls the COVID-19 pandemic “devastating to global health”, Patel also recognizes the pandemic’s challenges proved fertile ground for an extraordinary collaborative time for biomedical scientists. “My hope is for vaccine researchers across different disciplines to continue to work together to help us understand different infectious diseases and develop better vaccines.”

Zooming in on a Nanoscale

In collaboration with Weiner, Daniel Kulp, Ph.D., associate professor in the Vaccine and Immunotherapy Center, has embraced nanotechnology in his vaccine research. “We are developing rationally engineered nanoparticle vaccines that can elicit extremely broad coronavirus immunity providing a proof-of-concept that a pan-coronavirus vaccine is possible,” Kulp elaborates.

While the Kulp laboratory is developing several promising vaccines, he emphasizes that his goal is to assess these candidates in humans. He says, “We are working to reduce barriers for launching small experimental medicine clinical trials allowing for broader evaluation of our best vaccine concepts. Through this type of work, I have high hopes that our generation can claim credit for the eradication of SARS-CoV-2.”

Kulp expresses that “Vaccines are one of the single most effective medical technologies humans have developed saving hundreds of millions of lives. Vaccines do not work without immunizations. This message is incredibly important.”

Highlighting Vaccine Research at The Wistar Institute Through the Penn-CHOP-Wistar Vaccine Symposium

From HIV to COVID-19, Wistar scientists are at the forefront of vaccine development. Read our recap of the recent Vaccine Symposium and the impactful research in progress at the Institute.

This past Monday, The Wistar Institute, University of Pennsylvania Perelman School of Medicine, and Children’s Hospital of Philadelphia held the Penn-CHOP-Wistar Vaccine Symposium. Hosted both in-person at the Smilow Center for Translational Research and online, the all-day event covered the history of vaccines and current vaccine research from the three sponsoring institutions.

Keynote speaker and Wistar professor emeritus Stanley Plotkin, M.D., is a prominent researcher who is known for the development of the rubella vaccine while he was a virologist at The Wistar Institute. Furthermore, his years of work helping in vaccine efforts for rabies, rotavirus, and cytomegalovirus have stimulated much innovation in the biomedical research community.
After giving a brief history of vaccines, Plotkin proclaimed “Vaccinology has taken off. … We are now in a golden age of vaccinology.”

The Symposium’s research presentations opened with Wistar’s Daniel Kulp, Ph.D., Associate Professor in the Vaccine & Immunotherapy Center, and his work on a novel COVID-19 nanoparticle vaccine. Amelia Escolano, Ph.D., Assistant Professor in the Vaccine & Immunotherapy Center, also spoke about her efforts investigating immunization strategies for HIV. Wistar’s Vaccine & Immunotherapy Center Director David B. Weiner, Ph.D., gave a summary of his research into the genetic delivery of vaccines, calling the innovation of vaccinology in Pennsylvania among these institutions “extraordinary”.

The current global pandemic has reinforced the need for scientific solutions and a deeper understanding of human diseases. It is the studies and ideas from research centers like The Wistar Institute and its colleagues that propel forward biomedicine. As keynote speaker Plotkin stated, “Pandemics have occurred throughout the history of humankind and will continue to do so in the future. Infectious diseases of humans will continue to happen. Therefore, we must act against them.”

Wistar Study Opens the Door to Faster, Cheaper HIV Vaccine Research

For the first time, scientists have developed an DNA-encoded immunogen that produces Tier-2 antibodies—the kind that matter for combatting HIV

Nearly four decades after its discovery, HIV has killed 36.3 million people, with no vaccine in sight. Part of the reason vaccine development has been slow is because trialing candidate vaccines that produce Tier-2 neutralizing antibodies—the kind that matter for combatting HIV—has always required long and expensive experiments in large animal models like rabbits and macaque monkeys.

An effective HIV vaccine needs to produce antibodies that protect against the most common variants of HIV, which are categorized as “Tier 2” viruses based on how quickly and easily they can be neutralized by antibodies (more quickly/easily than Tier 3, less than Tier 1).

A new study by scientists at The Wistar Institute shows a quicker, less expensive path to developing this tier of antibodies. For the first time, these scientists have demonstrated a method for eliciting Tier-2 neutralizing antibodies in mice.

“Mice are the workhorse of vaccine design and development because you can iterate lots of concepts in that model due to cost and time constraints,” said Daniel Kulp, Ph.D., associate professor in the Vaccine & Immunotherapy Center at The Wistar Institute.

The scientists developed an immunogen—a substance that causes an immune response—called a native-like trimer, which they administered to mice. Importantly, they encoded the immunogen in DNA, which turns the host bodies (in this case the mice) into “antigen factories” instead of requiring what would otherwise be a complex and expensive vaccine manufacturing process.

They then compared the results from the mice who received the DNA-encoded native-like trimer to results from mice who received a standard protein immunization. Only those mice that received the DNA-encoded native-like trimer developed Tier-2 neutralizing antibodies.

From there, they were able to isolate and examine the atomic structure of one of the antibodies that their immunogen had produced. “The structure gives us incredible insight into how this antibody is able to neutralize the virus,” said Kulp.

“Our data demonstrates the value of this approach as a tool to create surgically tailored immunity against a difficult pathogen’s vulnerable sites, in this case for HIV,” said coauthor David B. Weiner, Ph.D., executive vice president and director of the Vaccine & Immunotherapy Center and the W.W. Smith Charitable Trust Professor in Cancer Research at The Wistar Institute.

Wistar Scientists Move HIV Vaccine Research Forward by Developing an Immunogen that Produces Tier-2 Antibodies—the Kind That Matter for Combatting HIV

PHILADELPHIA — (Feb. 4, 2022) — Nearly four decades after its discovery, HIV has killed 36.3 million people, with no vaccine in sight. However, a new study by researchers at The Wistar Institute, an international biomedical research leader in cancer, immunology, infectious disease, and vaccine development, takes a promising step in the direction of developing an HIV vaccine.

The findings, published in Nature Communications, demonstrate the promise of using a unique native-like trimer to develop Tier-2 neutralizing antibodies—the kind that matter for combatting HIV—in mice for the first time.

Previously, eliciting these types of antibodies using candidate vaccines required long and expensive experiments in large animal models creating a significant bottleneck on HIV-1 vaccine development. “With our new finding, we have opened the door to rapid, iterative vaccinology in a model that can produce Tier-2 neutralizing antibodies, enabling development of more advanced HIV vaccine concepts,” said Daniel Kulp, Ph.D., associate professor in the Vaccine & Immunotherapy Center at The Wistar Institute and corresponding author on the paper.

The researchers encoded the native-like trimer into DNA for delivery into the mice. This has the practical advantage of turning the host bodies into “antigen factories” instead of requiring what would otherwise be a complex vaccine manufacturing process. The researchers then compared the results from the mice who received the DNA-encoded native-like trimer to results from mice who received a standard protein immunization. Only those mice that received the DNA-encoded native-like trimer developed Tier-2 neutralizing antibodies.

“We were able to generate strong immune responses with both platforms, but the DNA platform uniquely drove this neutralizing response,” said Kulp.

Once they’d verified their immunization regime was producing Tier-2 antibodies, Kulp and his colleagues isolated monoclonal antibodies from the mice and used cryo-electron microscopy to determine the atomic structure of one Tier-2 neutralizing monoclonal antibody. They found that the antibody binds to an epitope (a segment of a protein that sticks out of the antigen, which prompts an immune response) called C3V5. In the gold standard HIV vaccine model (non-human primates), prior research has shown that antibodies binding to C3V5 protect animals from a SHIV infection, which is a close relative of HIV that infects non-human primates.

“The structure gives us incredible insight into how this antibody is able to neutralize the virus,” said Kulp. “For the first time, we can strategize about how to design new vaccines that can generate broadly neutralizing antibody responses to the C3V5 epitope.”

Coauthor David B. Weiner, Ph.D., executive vice president and director of the Vaccine & Immunotherapy Center and the W.W. Smith Charitable Trust Professor in Cancer Research at The Wistar Institute, emphasized the utility of their findings.

“What we’ve done is enable direct in vivo self-assembly of structurally designed immunogens, which are engineered and delivered using nucleic acid technology, inside the vaccinated animal. Our data demonstrating induction of autologous Tier 2 neutralization illustrate the value of this approach as a tool to create surgically tailored immunity against a difficult pathogen’s vulnerable sites, in this case for HIV.”

Co-authors: Ziyang Xu, Susanne Walker, Neethu Chokkalingam, Mansi Purwar, Edgar Tello-Ruiz, Yuanhan Wu, Sonali Majumdar, Kylie M. Konrath, Abhijeet Kulkarni, Nicholas J. Tursi, Faraz I. Zaidi, Emma L. Reuschel, Ishaan Patel, April Obeirne, David B. Weiner, and Daniel W. Kulp from The Wistar Institute; Megan C. Wise, Katherine Schultheis, Lauren Gites, Trevor Smith, Janess Mendoza, Kate E. Broderick, and Laurent Humeau from Inovio Pharmaceuticals; Alan Moore, Jianqiu Du, and Jesper Pallesen from Indiana University.

Work supported by: National Health Institutes (NIH) IPCAVD Grant U19 Al109646-04; W. W. Smith Charitable Trust; and Wistar Monica H.M. Shander Memorial Fellowship.

Publication information: Induction of Tier-2 Neutralizing Antibodies in Mice with a DNA-encoded HIV Envelope Native Like Trimer, Nature Communications, 2022. Online publication.

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The Wistar Institute is an international leader in biomedical research with special expertise in cancer research and vaccine development. Founded in 1892 as the first independent nonprofit biomedical research institute in the United States, Wistar has held the prestigious Cancer Center designation from the National Cancer Institute since 1972. The Institute works actively to ensure that research advances move from the laboratory to the clinic as quickly as possible. wistar.org.

Wistar Scientists Behind the Next Wave of COVID-19 Vaccines

Current COVID-19 vaccines were created in record time, but scientists are working to make better, longer lasting vaccines that could be used around the world.

The first generation of COVID-19 vaccines have been highly effective, but also have limitations: their efficacy can wane without a booster shot, and they may be less effective against some variants. Now scientists at The Wistar Institute have developed a more targeted vaccine that, in animal studies, shows stronger, broader, and more durable protection in a single, lower dose.

“This is among the first second-generation vaccines that will have more advanced features and broader protection,” said Daniel Kulp, Ph.D., associate professor in the Vaccine & Immunotherapy Center and corresponding author of the study.

The vaccine combines three technologies — immune focusing, self-assembling nanoparticles, and DNA delivery — into a single platform for the first time.

Immune focusing means that researchers engineered an immunogen that targets specific areas of COVID’s famous “spike” protein to generate protective antibodies. Instead of replicating the whole structure, this immunogen blocks specific sites that produce non-neutralizing antibodies. This stimulates higher production of neutralizing antibodies — the kind of antibodies that help the immune system fight the virus.

Having higher levels of these important antibodies can reduce the chance that the vaccine’s effectiveness will wane over time.

Studies in mice found that 100% of animals who received a single dose of the new vaccine were protected from death after virus challenge, whereas only 20% of animals receiving the first-generation vaccine were protected.

Nanovaccines consist of extremely small (nano) particles—similar in size to bacteria and viruses—used to display multiple copies of an antigen and able to elicit strong immune responses. The new vaccine also uses DNA to instruct cells to make these vaccines. Kulp noted that DNA vaccines can be stored at room temperature, making it potentially easier to transport to remote or developing locations than existing approved vaccines (such as mRNA vaccines), which require specialized cold storage. DNA vaccines historically also have an excellent safety profile, with a very low chance of eliciting severe adverse effects amongst clinical trial participants.

“Current vaccine effects on reducing transmission of SARS-CoV-2 variants of concern including Delta and Omicron could be improved for their breadth of protection as well as their immune potency,” said co-author David B. Weiner, Ph.D., executive vice president, director of the Vaccine & Immunotherapy Center and the W.W. Smith Charitable Trust Professor in Cancer Research, at The Wistar Institute.

The scientists are seeking funding and partnership to begin human trials of the new vaccine.

Dr. Kulp’s research was made possible through the generous support of Wistar donors who contributed to this project through the Wistar Coronavirus Discovery Fund.

Novel Nanoparticle SARS-CoV-2 Vaccine Combines Immune Focusing and Self-assembling Nanoparticles to Elicit More Potent Protection

PHILADELPHIA — (Feb. 1, 2022) — The first generation of COVID-19 vaccines have been highly effective, but also have limitations: their efficacy can wane without a booster shot, and they may be less effective against some variants. Now scientists at The Wistar Institute have developed a more targeted vaccine that, in animal studies, shows stronger, broader, and more durable protection in a single, low dose.

The vaccine combines three technologies – immune focusing, self-assembling nanoparticles, and DNA delivery – into a single platform for the first time. In addition to its other advantages, the vaccine could be stored at room temperature, making it potentially easier to transport to remote or developing locations than existing mRNA vaccines, which require specialized cold storage.

“This is among the first next-generation vaccines that will have more advanced features and broader protection,” said Daniel Kulp, Ph.D., associate professor in the Vaccine & Immunotherapy Center at The Wistar Institute and corresponding author of the study.

The paper, “Nucleic acid delivery of immune-focused SARS-CoV-2 nanoparticles drive rapid and potent immunogenicity capable of single-dose protection,” was published in the journal Cell Reports.

Existing vaccines include an unmodifided receptor binding domain of SARS-CoV-2 spike protein. The new vaccine includes a rationally engineered receptor binding domain using computational and structure-based design methodologies. The engineered receptor binding domain blocks ‘immune distracting’ sites and can therefore elicit stronger levels of protective, neutralizing antibodies.

Researchers then used naturally self-assembling proteins to form nanoparticles which display these highly engineered immunogens. By arranging themselves into structures that resemble an actual virus, the nanoparticles are more easily recognized by the immune system and transported to the germinal centers, where they activate B cells which produce protective antibodies.

Using nucleic acid vaccine delivery technology similar to mRNA, the nanoparticle vaccine is encoded in DNA and delivered into cells thereby giving genetic instructions for the body to build the immunogen internally. This is an advance over traditional vaccines that must be manufactured in specialized factories through complex vaccine production processes. In contrast to other vaccines, Dr. Kulp noted that one advantage of the DNA platform is that it doesn’t require refrigeration and it can also be quickly reformulated to target new variants.

In animal models, researchers found that the DNA delivered immune-focused nanoparticle vaccine produced much higher levels of neutralizing antibodies than the vaccine that wasn’t immune-focused.

“A difficulty with current vaccines is that neutralizing antibodies decline over time,” Kulp said. The nanoparticle vaccine produced durable responses after a single immunization out to six months in mice, unlike what we are seeing with current SARS-CoV-2 vaccines in people.

The ultimate test for SARS-CoV-2 vaccine candidates is protection from death in SARS-CoV-2 challenge experiments. The researchers found that in a lethal challenge model 100% of mice who received the immune-focused nanoparticle vaccine were protected from death with a single low dose. Most mice who received the standard, non-immune focused vaccine died within 10 days of challenge.

The vaccine assessment was conducted in both wild-type mice and mice that were genetically engineered to mimic human immune systems, he noted.

Even without being updated, the immune-focused vaccine showed a comparable level of antibody production to Delta, and other variants, Kulp said. That’s partly because of the immune focusing approach itself, he noted; in blocking parts of the receptive binding domain for the purpose of inhibiting non-neutralizing antibodies, it also blocks many of the areas affected by spike protein mutations. Studies on the Omicron variant are underway.

Researchers are seeking funding to begin human trials of the vaccine.

Co-author David B. Weiner, Ph.D., executive vice president, director of the Vaccine & Immunotherapy Center and the W.W. Smith Charitable Trust Professor in Cancer Research, at The Wistar Institute, said the vaccine could provide a needed step forward to improve protection against COVID-19.

“Current vaccine effects on reducing transmission of SARS-CoV-2 variants of concern including Delta and Omicron could be improved for their breadth of protection as well as their immune potency,” Weiner said. “This study demonstrates that using a nucleic acid approach combined with in vivo structural assembly of a glycan immune-focused nanoparticle drives single protection and neutralization against diverse variants of concern in a dose-sparing formulation. Additional studies of this vaccine approach for SARS-CoV-2 appear timely and important.”

Co-authors: Kylie M. Konrath, Kevin Liaw, Yuanhan Wu, Xizhou Zhu, Susanne N. Walker, Ziyang Xu, Neethu Chokkalingam, Nicholas J. Tursi, Mansi Purwar, Emma Reuschel, Drew Frase, Benjamin Fry, and Ami Patel from Wistar; Katherine Schultheis, Igor Maricic, Viviane M. Andrade, Kate E. Broderick, Laurent M.P.F. Humeau, and Trevor R.F. Smith from Inovio Pharmaceuticals; Himanshi Chawla and Max Crispin from the University of Southhampton; Jianqiu Du and Alan Moore from Indiana University; Jared Adolf-Bryfogle and Jesper Pallesen from the Institute for Protein Innovation; Matthew Sullivan from the University of Pennsylvania; and Christel Iffland from Ligand Pharmaceuticals.

Work supported by: Wistar Coronavirus Discovery Fund, CURE/PA Department of Health grant SAP# 4100083104, COVID/PA Department of Human Services grant SAP# 4100089371, NIH/NIAID CIVICs grant 75N93019C00051, Wistar SRA 16-4 / Inovio Pharmaceuticals, Indiana University.

Publication information: Nucleic acid delivery of immune-focused SARS-CoV-2 nanoparticles drive rapid and potent immunogenicity capable of single-dose protection, Cell Reports, 2022.

Scientists Engineer DNA-based Nanotechnology to Stimulate Potent Antitumor Immune Responses in Preclinical Models

PHILADELPHIA — (Sept. 10, 2020) — Combining their expertise in protein engineering and synthetic DNA technology, scientists at The Wistar Institute successfully delivered nanoparticle antitumor vaccines that stimulated robust CD8 T cell immunity and controlled melanoma growth in preclinical models. Study results were published online in Cancer Immunology Research, a journal of the American Association for Cancer Research, and support exploration of this immunotherapy approach for additional cancer types.

Nanovaccines consist of extremely small (nano) particles — similar in size to bacteria and viruses — used to display multiple copies of an antigen and able to elicit strong immune responses. The team previously reported on using DNA instructions to launch in vivo production of nanoparticle vaccines (DLnano-vaccines).

DLnano-vaccines assembled in the body produced stronger immune responses than protein based nanoparticle vaccines in an infectious disease setting, especially inducing CD8 T cell responses.

“We wanted to test DLnano-vaccines for cancer immunotherapy and obtain proof of concept that this platform could be successfully applied in the cancer field, thanks to its effectiveness at prompting CD8 T cells responses,” said Daniel Kulp, Ph.D., associate professor in Wistar’s Vaccine & Immunotherapy Center and co-corresponding author of the study, who specializes in nanotechnology and protein engineering for vaccine development.

Due to their ability to specifically kill malignant cells, CD8 T cells play a pivotal role in anticancer immunity, therefore engagement of these cells represents a necessary step for the success of anticancer vaccine approaches, although this type of immune response is typically difficult to achieve by vaccination with proteins or inactivated virus.

Researchers designed DLnano-vaccines displaying 60 copies of protein parts derived from the melanoma-specific antigens Trp2 and Gp100 and tested these in mouse models of melanoma, observing prolonged survival that depended on CD8 T cell activation both in therapeutic and prophylactic settings.

“One of the advantages of synthetic DNA technologies over other methods is the versatility of the platforms,” said Ziyang Xu, Ph.D., a recent doctoral graduate working at Wistar and the first author of the study. “DLnano-vaccines may be designed for various cancer targets and our study shows this is a promising strategy for cancer immunotherapy that may warrant further testing.”

To elucidate the mechanism through which DLnano-vaccines activate CD8 T cells, the team studied the effects of the DNA-launched version of a previously described HIV nanoparticle vaccine (eOD-GT8-60mer). They observed that DLnano-vaccines administered via electroporation resulted in transient muscle cell apoptosis that attracted macrophage infiltration at the injection site, which in turn was instrumental to activate CD8 T cells.

DLnano-vaccines were developed using synthetic DNA technology in collaboration with the lab of David B. Weiner, Ph.D., Wistar executive vice president, director of the Vaccine & Immunotherapy Center, and the W.W. Smith Charitable Trust Professor in Cancer Research and also a co-senior author on the study.

Co-authors: Neethu Chokkalingam, Edgar Tello-Ruiz, Mamadou A. Bah, Susanne Walker, and Nicholas J. Tursi from Wistar; Megan C. Wise, Paul D. Fisher, Katherine Schultheis, Kate E. Broderick, and Laurent Humeau from Inovio Pharmaceuticals, Inc.

Work supported by: National Institutes of Health (NIH) grants U19 Al109646 and Collaborative Influenza Vaccine Innovation Centers (CIVICs) contract 75N93019C00051; additional support was provided by Inovio Pharmaceuticals, Inc., a grant from the W.W. Smith Charitable Trust, and the Monica H.M. Shander Memorial Fellowship.

Publication information: A DNA-launched nanoparticle vaccine elicits CD8+ T-cell immunity to promote in vivo tumor control, Cancer Immunology Research, 2020. Online publication.

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The Wistar Institute is an international leader in biomedical research with special expertise in cancer, immunology, infectious disease research, and vaccine development. Founded in 1892 as the first independent nonprofit biomedical research institute in the United States, Wistar has held the prestigious Cancer Center designation from the National Cancer Institute since 1972. The Institute works actively to ensure that research advances move from the laboratory to the clinic as quickly as possible. Wistar’s Business Development team is dedicated to accelerating the translation of Wistar discoveries into innovative medicines and healthcare solutions through licensing, start-ups and creative collaborations. wistar.org.

Positive Results from Preclinical Testing Support Clinical Development of COVID-19 DNA Vaccine

PHILADELPHIA — (May 20, 2020) — The Wistar Institute, an international biomedical research leader in cancer, immunology and infectious disease, announces a study reporting initial immunogenicity of a synthetic DNA vaccine for SARS-CoV-2 developed in collaboration with Inovio Pharmaceutical, Inc., and other scientists. Published in Nature Communications, the report focuses on immune studies in animals, which show induction of functional antibody responses and T-cell responses following immunization. The vaccine, INO-4800, was advanced to phase 1 clinical testing in 10 weeks (clinicaltrials.gov NCT04336410).

The SARS-CoV-2 coronavirus emerged in December 2019 in the city of Wuhan, China. Infection causes the viral pneumonia disease COVID-19 that has spread quickly around the world. On March 11, 2020, the World Health Organization declared COVID-19 a global pandemic. Currently in the U.S., there are 1.5 million confirmed infections and more than 90,000 deaths occurring in just months, making COVID-19 infection the leading cause of death in the country.

No vaccines or major therapies are available to prevent infection or control the disease and the U.S. government has made development of a vaccine for COVID-19 a top priority. The viral genome became available on January 11, 2020, and the Wistar-Inovio team immediately began working to design and develop a new vaccine, based largely on their previous experience creating a synthetic DNA vaccine against the related coronavirus that causes Middle East respiratory syndrome (MERS).

Working with Inovio, a group led by David B. Weiner, Ph.D., Wistar executive vice president, director of the Vaccine & Immunotherapy Center (VIC) and W.W. Smith Charitable Trust Professor in Cancer Research, focused on rapid development of a synthetic DNA-based vaccine targeting the major surface antigen Spike protein (S) of SARS-CoV-2 into preclinical studies.

“We focused on both assay development and vaccination studies to test if immune responses induced by the vaccine in laboratory animals were functional against the virus. Our focus was the induction of immune responses that could in concept make it difficult for SARS-CoV-2 to have a home in the human body,” said Weiner, co-senior author of the publication. “The vaccine was designed leveraging our synthetic DNA technology, which has a set of conceptual advantages including accelerated clinical development built on a conceptually safe, non-live, simple platform that has scalable manufacturing and temperature stability. The vaccine-induced antibodies in vaccinated animals were of sufficient quantity and quality to block interaction of the virus with its receptor, which is its doorway into infecting the body, and were present in the lungs, a place where immunity is very important. The vaccine also induced T-cell function, which is critical for clearing viral infections from the body. These are indications that the immunity it induced might provide no escape for the SARS-CoV-2 virus. We are looking forward to additional studies and examining data from the ongoing clinical trial.”

The team includes Wistar VIC investigators Daniel Kulp, Ph.D., Kar Muthumani, Ph.D., and Ami Patel, Ph.D., who is a shared first author in the paper.

DNA vaccines work by delivering the genetic information required to make a certain viral protein in the recipient’s body, which stimulates the immune system to recognize that protein as foreign and build a response against it, thus targeting the virus and providing protection from infection.

Expressed in vitro, INO-4800 induced robust expression of the S protein. Within days following a single immunization of mice and guinea pigs, the vaccine induced antigen-specific T cell responses and functional antibodies that neutralize the virus, blocking the ability of the SARS-CoV-2 S protein to bind to the angiotensin-converting enzyme 2 (ACE2) host receptor on human cells.

Importantly, SARS-CoV-2-specific antibodies were detected in the lungs of immunized animals, suggesting they might protect against upper and lower respiratory disease that is associated with severe cases of COVID-19.

“While this candidate continues its journey as a potential vaccine against COVID-19, we are continuing our work in the lab to gather more information on the vaccine’s performance in small and larger animals,” said Patel, who is a research assistant professor at Wistar. “We will further characterize antibody functionality, cellular responses, and the ability of INO-4800 to mediate protection of animals against viral challenge.”

Co-authors: Trevor R.F. Smith and Stephanie Ramos from Inovio co-first authors. Other co-authors include Xizhou Zhu, Ebony N. Gary, Susanne N. Walker, Mansi Purwar, Ziyang Xu, Pratik Bhojnagarwala, Neethu Chokkalingam, Elizabeth Parzych, Emma L. Reuschel, Nicholas Tursi, Jihae Choi, Edgar Tello-Ruiz, Mamadou A. Bah, Yuanhan Wu, Daniel Park, Yaya Dia, Ali Raza Ali, Faraz I. Zaidi, Kevin Y. Kim, Sophia Reeder, Makan Khoshnejad, Jacqueline Chu, Kar Muthumani, and Daniel W. Kulp from Wistar; Dustin Elwood, Jian Yan, Katherine Schultheis, Jewell Walters, Maria Yang, Patrick Pezzoli, Arthur Doan, Miguel Vasquez, Igor Maricic, Dinah Amante, Alison Generotti, Timothy A. Herring, Ami Shah Brown, J Joseph Kim, Jean Boyer, Laurent M.P.F. Humeau, and Kate E. Broderick (corresponding author) from Inovio Pharmaceuticals; Nianshuang Wang, Daniel Wrapp, and Jason S McLellan from University of Texas at Austin; and B Wang from Fudan University, China.

Work supported by: Funding from the Coalition for Epidemic Preparedness Innovations (CEPI).

Publication information: Immunogenicity of a DNA vaccine candidate for COVID-19, Nature Communications (2020). Online publication.

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The Wistar Institute is an international leader in biomedical research with special expertise in cancer research and vaccine development. Founded in 1892 as the first independent nonprofit biomedical research institute in the United States, Wistar has held the prestigious Cancer Center designation from the National Cancer Institute since 1972. The Institute works actively to ensure that research advances move from the laboratory to the clinic as quickly as possible. wistar.org.

Philanthropy Powering Science: $1.6M in New Funding for Wistar Coronavirus Research

In mere weeks, philanthropic support of Wistar’s Coronavirus Discovery Fund has exceeded $1.6M in new funding thanks to an extraordinary response from individuals, foundations, and corporate sponsors. As our scientists focused their research to advance vaccines, drugs, and diagnostics targeting the novel coronavirus, SARS-CoV-2, Wistar donors moved with the same speed, committing to put our discovery science into action in a variety of important ways. This pace of investment in research now underway at Wistar will allow us to accelerate and potentiate progress against SARS-CoV-2 and future viral threats the world may confront.

Under the leadership of Dr. David Weiner, executive vice president, director of the Vaccine & Immunotherapy Center (VIC), and W.W. Smith Charitable Trust Professor in Cancer Research, our team continues to carry out pivotal laboratory testing of its synthetic DNA vaccine. Funding support has enabled us to expand that research through the purchase of critical equipment that allows for real-time, high-throughput assays required for vaccine development, and will hasten the Institute’s ability to respond to future pandemic threats as they arise.

Dr. Daniel Kulp, associate professor in the VIC, is engineering nanoparticle-based immunotherapies that target SARs-CoV-2. He and his team use extremely small (nano) particles to display multiple copies of critical parts of the virus in order to stimulate immunity against COVID-19.  Donor support for his project is allowing the lab to design molecular simulations of the SARS-CoV-2 spike protein — the surface protein that lets the virus invade healthy cells.

Not only did individual donors make a strong commitment to Wistar Science; so did foundations, including The G. Harold and Leila Y. Mathers Charitable Foundation. Dr. Hildegund Ertl, vaccine expert and a professor in the VIC, is creating a SARS-CoV-2 vaccine based on safe viral delivery technologies. Genetically modified adenoviruses are great delivery vehicles for vaccines because they induce neutralizing antibodies and killer T-cell responses. Dr. Ertl’s goal is to apply innovative technologies created in her lab to develop a vaccine that will produce strong and sustained protection to COVID-19. The Mathers Foundation and steadfast Wistar supporters quickly mobilized to provide critical support for this project.

This is not Wistar’s first pandemic. We are uniquely prepared for this moment by a near-century’s worth of Wistar achievement in developing vaccines that have saved countless lives. Wistar’s community of supporters has provided the resources and tools our scientists need to work efficiently and effectively to address this pandemic. For that, we thank you deeply. We’re all in this for science. Because Wistar Science saves lives.

If you would like to play a role in advancing Wistar’s research fighting COVID-19, your donation will keep the momentum going and inspire our scientists to continue tackling the world’s biggest threats.