New Genomic Research Shows Why Testing Malaria Vaccines in the Clinic is as Rigorous as Natural Exposure in the Field

UMSOM Research Could Guide Future Vaccine Development

Malaria is the deadliest mosquito-borne parasitic infection of humans. In 2021, after a century of research, the World Health Organization (WHO) approved the world’s first malaria vaccine. That vaccine reduces the incidence of malaria infections in young children aged 5-17 months by only 30 percent, meaning that it remains critical to continue developing and testing more effective vaccines.

WHO’s goal is to find a vaccine that prevents infection as well as cases of severe malaria.  However, testing vaccines in the field is challenging and requires large number of volunteers and long periods of follow-up. This process increases the expense and reduces the number of trials that researchers can perform.

Now, scientists at the University of Maryland School of Medicine’s (UMSOM) Institute for Genome Sciences (IGS) and the UMSOM Center for Vaccine Development and Global Health (CVD), and their collaborators report a new way to test vaccines that may be as rigorous and stringent as exposure to field strains of malaria.  Their study was published in the June issue of Nature Communications.

Their method has two key aspects. First, they expose vaccinated volunteers to malaria in a controlled clinical environment. Secondly, for this testing, they use a strain of malaria that is genetically very different from the one used in the vaccine, as well as from strains in the geographic region to which the vaccine is intended.

This technique allows scientists to test how well the vaccine works in small numbers of volunteers under controlled settings and in a rapid fashion and predicts how well the vaccine may perform in the field. This lets researchers select the best vaccines for larger studies in the field. This method will increase the efficiency of vaccine testing and should accelerate malaria vaccine development. 

“The standard for many investigators has been to test vaccines with a strain similar to the one used in the vaccine’s development,” explained the study’s lead author, Joana Carneiro da Silva, PhD, Professor of Microbiology and Immunology at UMSOM and IGS. “Using a strain that is both genetically distant from the one in the vaccine -- as well as from the strains circulating in the area where malaria is rampant and the vaccine will be used– is a more stringent way to test vaccine effectiveness.”

Researchers are studying the effectiveness of a vaccine (PfSPZ Vaccine) made by the company Sanaria, Inc, based in Rockville, Maryland. This vaccine uses the West African parasite strain known as PfNF54. One objective is to use this vaccine to protect individuals with little or no previous exposure to malaria, including those living or traveling in Africa. The long-term goal is to use the vaccine in mass vaccination programs to eliminate malaria from specific regions in Africa.

For the study, researchers infected mosquitoes with a Brazilian malarial strain and then exposed U.S. volunteers who had been vaccinated with the Sanaria vaccine (as well as those who received a placebo) to the bites of infected mosquitos in a controlled clinical setting. They also vaccinated research participants in Mali with the same dose of the vaccine to compare observed vaccine efficacy in the field with that in the clinic. Through genomic sequencing, researchers had shown that the Brazilian strain differed greatly from 700 strains previously collected from across Africa, including the one used to make the vaccine.

The researchers looked at about 200 volunteers in four trials – two in the United States and two in Mali. In all four, they observed how many people became infected with malaria, as well as how long it took for them to become infected, comparing clinic to field. At the end of six months, they found the vaccine was just as effective in both populations.

In addition, previous comparisons had shown that those volunteers who had never been exposed to malaria developed more antibodies than those in the field, proving that it would work well in first-time travelers to the area.

The research team included scientists from Sanaria Inc.; the Naval Medical Research Center; University of Tübingen in Germany; the Malaria Research and Training Center in Bamako, Mali; and the Laboratory of Malaria Immunology and Vaccinology at NIAID, NIH.

The World Health Organization estimates that in 2020, 241 million cases and 627,000 deaths worldwide were due to malaria, including 2,000 cases diagnosed in the United States from travelers and immigrants who were exposed elsewhere. The variety of malarial strains globally makes vaccine development particularly difficult.

“Given the diversity of malaria strains worldwide, this research demonstrates that the Brazilian strain is as diverse as any strain detected in Africa,” said Kirsten E. Lyke, MD, Professor of Medicine and Director of the Malaria Vaccine and Challenge Unit at the CVD and an author of the paper.

Dr. da Silva noted this new model can be used in the future in selecting challenge strains to test the efficacy of vaccines against other parasitic diseases, using carefully controlled clinical settings to compare against field studies.

Albert Reece, MD, PhD, MBA, Executive Vice President for Medical Affairs, UM, Baltimore, the John Z. and Akiko K. Bowers Distinguished Professor, and Dean at the University of Maryland School of Medicine, said, “The world has waited decades for effective malaria vaccines. Dr. Silva and her colleagues have found a way to greatly expedite our ability to examine potential vaccine formulations in clinic to identify the most promising candidates. This study also shows how important genomics are to help establish the efficacy of new vaccine formulations and to guide vaccine development.”

Funding

This study was funded the National Institutes of Health’s National Institute of Allergy and Infectious Diseases intramural program and grants (U19AI110820, R01AI141900, 5R44AI058375-10, and 5R44AI055229-11) , and the Department of Defense (W81XWH1420011).

Authors from the University of Maryland School of Medicine

Joana C. da Silva, PhD, Professor, Microbiology and Immunology; Associate Professor, Institute for Genome Sciences

Ankit Dwivedi, PhD, Bioinformatics Analyst, Institute for Genome Sciences

Kara A. Moser, PhD, previous doctoral student, Institute for Genome Sciences

Kirsten E. Lyke, MD, Professor of Medicine and Director, Malaria Vaccine and Challenge Unit Center for Vaccine Development and Global Health

Author Conflicts of Interest

Competing interests Thomas L. Richie, Tooba Murshedkar B. Kim Lee Sim, and Stephen L. Hoffman are salaried employees of Sanaria Inc., the developer, and owner of PfSPZ Vaccine and PfSPZ Challenge (7G8). In addition, Hoffman and Sim. have a financial interest in Sanaria Inc. No other authors declare competing interests.

About the University of Maryland School of Medicine

Now in its third century, the University of Maryland School of Medicine was chartered in 1807 as the first public medical school in the United States. It continues today as one of the fastest growing, top-tier biomedical research enterprises in the world -- with 46 academic departments, centers, institutes, and programs, and a faculty of more than 3,000 physicians, scientists, and allied health professionals, including members of the National Academy of Medicine and the National Academy of Sciences, and a distinguished two-time winner of the Albert E. Lasker Award in Medical Research.  With an operating budget of more than $1.3 billion, the School of Medicine works closely in partnership with the University of Maryland Medical Center and Medical System to provide research-intensive, academic and clinically based care for nearly 2 million patients each year. The School of Medicine has nearly $600 million in extramural funding, with most of its academic departments highly ranked among all medical schools in the nation in research funding.  As one of the seven professional schools that make up the University of Maryland, Baltimore campus, the School of Medicine has a total population of nearly 9,000 faculty and staff, including 2,500 students, trainees, residents, and fellows. The combined School of Medicine and Medical System (“University of Maryland Medicine”) has an annual budget of over $6 billion and an economic impact of nearly $20 billion on the state and local community. The School of Medicine, which ranks as the 8th highest among public medical schools in research productivity (according to the Association of American Medical Colleges profile) is an innovator in translational medicine, with 606 active patents and 52 start-up companies.  In the latest U.S. News & World Report ranking of the Best Medical Schools, published in 2021, the UM School of Medicine is ranked #9 among the 92 public medical schools in the U.S., and in the top 15 percent (#27) of all 192 public and private U.S. medical schools.  The School of Medicine works locally, nationally, and globally, with research and treatment facilities in 36 countries around the world. Visit medschool.umaryland.edu

About the Institute for Genome Sciences

The Institute for Genome Sciences (IGS) at the University of Maryland School of Medicine has revolutionized genomic discoveries in medicine, agriculture, environmental science, and biodefense since its founding in 2007. IGS investigators research areas of genomics and the microbiome to better understand health and disease, including treatments, cures, and prevention. IGS investigators also lead the development of the new field of microbial forensics. IGS is a leading center for major biological initiatives currently underway including the NIH-funded Human Microbiome Project (HMP) and the NIAID-sponsored Genomic Sequencing Center for Infectious Diseases (GSCID). Follow us on Twitter @GenomeScience.