George N. Pavlakis, M.D., Ph.D.

George N. Pavlakis, M.D., Ph.D.
Senior Investigator
Head, Human Retrovirus Section

The Human Retrovirus Section designs, develops and tests vaccines and immunotherapies for AIDS and cancer. We develop and test new technologies including nucleic acid delivery methods in vivo, prophylactic and therapeutic vaccines and immunotherapies. We study the role and application of cytokines in vaccines and cancer immunotherapy.

The Human Retrovirus Section focuses on the development of innovative vaccines and immunotherapies for AIDS and cancer based on the understanding of basic mechanisms, and by combining our expertise in molecular biology, virology and immunology.

A major focus is presently directed towards DNA vaccine development. We aim to improve DNA vaccine platform technology and develop immunogens able to prevent HIV infection or progression to AIDS. This is achieved by optimizing DNA vaccine expression, delivery, immunogenicity as well as synergy with other vaccine modalities. The strong and effective cellular immunity achieved by optimized DNA is also an important consideration for the expanding field of cancer vaccines. A related focus area is the study of the biology and clinical applications of cytokines in vaccines and immunotherapies for cancer.

This work is a direct extension of our previous studies and represents a translational component of our basic science accomplishments.

Areas of Expertise

1) HIV-1/AIDS, 2) vaccines, 3) cytokines, 4) cancer immunotherapy

Contact Info

George N. Pavlakis, M.D., Ph.D.
Center for Cancer Research
National Cancer Institute
Building 535, Room 210
Frederick, MD 21702-1201
Ph: 301-846-1474

New Vaccine Approaches, DNA Vaccine Optimization

Our overall goal is to improve DNA and nucleic acid vaccination  technologies so that they becomes rapid, safe, and effective vaccine platforms for AIDS, cancer and other indications. DNA vaccination has distinct advantages, including that it provides a broad priming of the immune system that may result in a robust and effective immune response. The strong and effective cellular immunity achieved by optimized DNA is an important consideration for the expanding field of cancer vaccines.

Rapid advances in the efficiency of DNA vaccination make this approach very promising for the development of safe and effective vaccines with distinct advantages for many indications including AIDS and cancer. Yet, further research and development is needed for the DNA vaccine field to fulfill this promise. Our goal is to further improve this technology and contribute to its translation to the clinic. We use molecular biology and animal models to test new vectors, new technologies and new combinations for DNA vaccination. We have successfully applied the increased understanding in basic knowledge of gene expression regulation to the improvement of DNA vaccines. We have shown in the past that DNA vaccine expression in the tissues is a major limiting step for meaningful immunogenicity and we developed general methods for efficient plasmid expression. The methods (RNA or codon optimization to increase mRNA stability transport and expression) have applications in both DNA and viral vaccine vectors and also gene therapy protocols. These patented technologies have contributed to overcoming a critical barrier for clinical application of DNA vaccines. An additional advancement in DNA vaccines is the development of more efficient delivery methods such as in vivo DNA electroporation. These advancements form the basis for the accelerated development of DNA vaccines for AIDS, other infectious diseases and also cancer. We are presently optimizing the formulations and delivery of DNA vaccines using molecular adjuvants, liposomes, nanoparticle formulations and electroporation. A novel potential application for cancer is DNA-delivered immunotherapies, based on the development of efficient expression vectors for cytokines and other immunomodulators. We are testing the hypothesis that DNA-delivered immunotherapies are beneficial in cancer models.

We have used different DNA vaccine delivery procedures to discover optimal methods of DNA vaccination. This work has led to the conclusion that both the form and the method of delivery of specific antigens affect strongly the produced immune response. We have tested different adjuvants for their compatibility with DNA vaccine protocols and have developed shortened protocols able to produce strong humoral immune response. We have compared the humoral and cellular immune responses obtained after DNA vaccination to other vaccine modalities. These studies are important in understanding strengths and weaknesses of different vectors and protocols and provide guidance for further development of improved vaccine protocols.

A new type of DNA vaccine comprising Conserved Elements of HIV Gag protein is currently developed for a clinical trial on the basis of mouse and macaque immunogenicity. Inclusion of a Conserved Element immunogen provides a novel and effective strategy to broaden responses against highly diverse pathogens by avoiding decoy epitopes, while focusing responses to critical viral elements for which few escape pathways exist.

Cytokines and Immunomodulatory Molecules in Immunotherapy and Vaccines
The overall goal of this project is to study gene expression and function of selected cytokines and other immunomodulatory molecules relevant for cancer and AIDS immunotherapy. This goal is important for the development of more efficient interventions to alleviate, delay or prevent disease through immunotherapy, gene therapy and DNA vaccine technologies. Such novel interventions require a more thorough understanding of all aspects of cellular processes. One goal is to develop efficient expression vectors by identifying key elements and factors associated with the pathways of posttranscriptional control of gene expression used by many genes, including cytokines. The validity of this approach is demonstrated by the development of efficient vectors for the expression of important cytokines, especially IL-15 and IL-12..

In the case of IL-15, the understanding of the cellular mechanisms controlling expression has led to methods of preparation and purification of the heterodimeric form of this cytokine and the demonstration that the heterodimer is the bioactive form circulating in human blood. This has now being recognized as an important development in our understanding of IL-15 function. Pharmacokinetic studies in animals show that the heterodimeric IL-15 has favorable properties for clinical applications.

Rapid progress in the IL-15 clinical development project has led to the production of a GMP lot of heterodimeric IL-15, which we named hetIL-15 for clinical trials projected to start in 2015. Our hypothesis is that IL-15 will activate Natural Killer cells and tumor infiltrating T cells. As a result, hetIL-15 may find important applications in cancer immunotherapy.

This project complements our efforts to improve DNA vaccines (see above) and DNA-delivered immunotherapies. An additional goal of this project is to explore function of key cytokine genes in order to establish their role in normal homeostasis and disease processes.

Our collaborators include Genoveffa Franchini, Marjorie Robert-Guroff, David J. Venzon, Jay A. Berzofsky, Thomas Waldmann, Steven A. Rosenberg (NCI); Barbara K. Felber (NCI-Frederick); Jeffrey D. Lifson, Elena N. Chertova (Leidos Biomedical Research, Inc./FNLCR); James I. Mullins (Univ. of Wash.); Georgia D. Tomaras, David C. Montefiori (Duke Human Vaccine Institute); Timothy Fouts (Profectus BioSciences); Niranjan Y. Sardesai (Inovio); George K. Lewis (Institute of Human Virology/Univ. of MD); and David B. Weiner (Univ. of Penn.).

NIH Scientific Focus Areas:
Clinical Research, Immunology, Molecular Biology and Biochemistry, Virology
View Dr. Pavlakis' PubMed Summary/

Selected Key Publications

  1. Bergamaschi, C.a, Pandit, H.b, Nagy, B.A.b, Stellas, D.b, Jensen, S.M.c, Bear, J.a, Cam, M.d, Valentin, A.b, Fox, B.A.c, Felber, B.K.a, Pavlakis, G.N.
    Full-Text Article [ Journal Article ]
  2. Felber BK, Lu Z, Hu X, Valentin A, Rosati M, Remmel CAL, Weiner JA, Carpenter MC, Faircloth K, Stanfield-Oakley S, Williams WB, Shen X, Tomaras GD, LaBranche CC, Montefiori D, Trinh HV, Rao M, Alam MS, Vandergrift NA, Saunders KO, Wang Y, Rountree W, Das J, Alter G, Reed SG, Aye PP, Schiro F, Pahar B, Dufour JP, Veazey RS, Marx PA, Venzon DJ, Shaw GM, Ferrari G, Ackerman ME, Haynes BF, Pavlakis GN.
    Cell Rep. 31(6): 107624, 2020. [ Journal Article ]
  3. Felber BK, Pavlakis GN.
    Lancet HIV. 6(11): e724-e725, 2019. [ Journal Article ]
  4. Watson DC, Moysi E, Valentin A, Bergamaschi C, Devasundaram S, Fortis SP, Bear J, Chertova E, Bess J Jr, Sowder R, Venzon DJ, Deleage C, Estes JD, Lifson JD, Petrovas C, Felber BK, Pavlakis GN.
    PLoS Pathog. 14(2): e1006902, 2018. [ Journal Article ]
  5. Ng SSM, Nagy BA, Jensen SM, Hu X, Alicea C, Fox BA, Felber BK, Bergamaschi C, Pavlakis GN.
    Clin Cancer Res. 23(11): 2817-30, 2017. [ Journal Article ]

Dr. Pavlakis received his M.D. from the University of Athens, Greece, and his Ph.D. from Syracuse University. He has been associated with the National Cancer Institute since 1980 and is currently Chief of the Human Retrovirus Section. He has directed both basic research and clinical development projects based on his pioneering research achievements. Dr. Pavlakis has extensive research and development experience in molecular biology, virology, and immunology. He is credited with the first production of mature human hormones in mammalian cells by recombinant DNA technologies. This methodology is still in commercial production (human Growth Hormone). He continues this work by the development of new production methods and clinical application of heterodimeric IL-15 (hetIL-15), a cytokine essential for NK and T lymphocyte development and function.

Dr. Pavlakis co-developed codon/RNA optimization methods that have found wide applications in biotechnology, gene therapy protocols and DNA vaccines. He developed DNA vaccines for HIV and showed they provide strong and long lasting immunity. He developed strong fluorescent GFP mutants that are in wide use in biology. He studied the molecular biology, genetic organization and expression strategy of HIV and discovered important functions of its regulatory factors Tat and Rev. He described the first transcriptional activator on oncoretroviruses, the Tax protein of HTLV-I and the first posttranscriptional regulatory factor controlling mRNA export from the nucleus, the Rev protein of HIV-1. His studies have provided new insights on the biology of several viruses, and have aided the development of diagnostic and therapeutic procedures. His work has also led to the development of innovative biotechnology drugs and gene therapy procedures.

Dr. Pavlakis is member of several professional societies, including the American Society for Clinical Investigation and the American Association of Physicians. He is a highly cited researcher, has authored more than 200 publications and is inventor of more than 50 US and International patents.

Name Position
Bhabadeb Chowdhury Ph.D. Biologist
Terry Jones Program Specialist
Sevasti Karaliota Ph.D. Scientist I (Leidos)
Breana Myers Research Associate I (Contr.)
Hrishikesh Shrinivas Pandit Ph.D. Postdoctoral Fellow (Visiting)
Demetrios Papademetriou M.D. Postdoctoral Fellow (CRTA)
Margherita Rosati Ph.D. Biologist
Dimitrios Stellas Ph.D. Research Fellow
Vasiliki Stravokefalou Predoctoral Fellow (Graduate Student)
Antonio L. Valentin M.D., Ph.D. Associate Scientist
Dionysios Watson M.D. Special Volunteer
Shadan Yarandi Ph.D. Postdoctoral Fellow (CRTA)