Turnover of Antigen Specific Lymphocytes and Monocytes After Immunization With the 17D Yellow Fever Vaccine

Yellow fever is a viral disease caused by the yellow fever virus (YFV). It is transmitted to humans through the bite of an infected mosquito and can result in a life-threatening infection with hepatitis, renal failure and coagulation abnormalities, and in severe cases, death. Yellow fever can be prevented by vaccination with the yellow fever vaccine (YFV-17D). Currently, the Centers for Disease Control and Prevention (CDC) and the World Health Organization (WHO) recommend vaccination for persons ≥ 9 months of age who are traveling to or living in a yellow fever endemic area.

A very interesting, but unexplained aspect of flavivirus biology is how infection with different members of the same virus family can lead to such diverse types of host-virus interactions and variable disease outcomes. For example, YFV infection can be fatal, but if the infected host survives, long-term protective immunity is seen. Alternatively, dengue virus causes an acute infection with associated acute disease manifestations; however, even more severe disease outcomes are observed following secondary infection with a distinct serologic type of dengue virus. Understanding why the human immune system can successfully contain one flavivirus infection, but not another is both a fascinating scientific enigma in human immunology and a topic with substantial practical importance to public health. Given the great global public health threats posed by epidemic and emerging flavivirus infections, and the need to define the biological basis of successful induction and maintenance of protective immunity by vaccination, elucidation of the immunologic mechanisms underlying the generation and maintenance of protective immunity to YFV vaccine should be extremely useful. Furthermore, definition of the attributes of such a highly effective vaccine should help expedite the development and evaluation of new and/or improved vaccines to prevent important prevalent and emerging infectious diseases.

The goal of this study is to use the live attenuated yellow fever vaccine, YFV-17D (YF-VAX®, Sanofi Pasteur) as a safe and effective model to study a primary, acute viral infection in humans. Yellow fever virus vaccine is the viral infection model that the researchers have chosen for the following reasons:

• The 17D attenuated yellow fever vaccine strain is one of the most efficacious vaccines available and has been in use since the 1930s.
• YFV vaccination leads to limited infection without causing the disease.
• Since most of the US population is not exposed to yellow fever virus, immunization of adult participants with the 17D vaccine strain allows for examination of the innate immunity and the naïve T and B cell response in humans during primary infection and the subsequent development of memory T cells after resolution of the primary infection.
• The YFV-17D vaccine induces long-term immunity that lasts for decades. By studying how the human immune system responds to an effective vaccine such as the YFV-17D vaccine, the researchers hope to learn more about the normal functioning of the immune system so that it might be possible to design new, more effective vaccines to prevent important infectious diseases. Therefore, this vaccine can serve as an ideal model to help decipher the properties that make a vaccine effective.

YFV-17D is known to stimulate broad-spectrum immune responses, including cytotoxic T cells and Th1 and Th2 responses, as well as neutralizing antibody titers that can persist for up to 30 years, after a single vaccination. Despite the great success of this empiric vaccine, there has been relatively little understanding of the mechanisms by which YFV-17D induces such robust protective immune responses.

This study seeks to understand the lifespan and decay curve of effector CD8+ T cells and the rate of homeostatic turnover of memory CD8+ T cells after YFV-17D immunization using an innovative method developed by Dr. Marc Hellerstein's group (at the University of California, Berkeley) for measuring DNA replication and cell proliferation in humans using a naturally occurring stable isotope called deuterium (2H). This technique has been used to track the turnover of a number of human cell types in vivo. The researchers plan to use 2H labeling to track YFV specific CD8+ T cells in human vaccinees (HLA-A2 positive participants only). The availability of a T cell epitope (A2-NS4B^214), a major component of the human YFV specific CD8+ T cell response, allows for the longitudinal analysis of virus specific CD8+ T cells. The unique feature of this study is that it allows for tracking of differentiation of YFV specific CD8+ T cells in humans. Thus, the researchers can overcome the inherent limitations due to heterogeneity in cross sectional studies that involve bulk CD8+ T cells.

In addition, the researchers are proposing to study the life span and decay curve of monocytes after YFV vaccination. The mononuclear phagocytes comprise three types of cells: monocytes, macrophages, and dendritic cells (DCs). Mononuclear phagocytes play key functions in maintaining tissue homeostasis during steady state as well as orchestrating the genesis and resolution of the immune response. The kinetics underlying their generation, differentiation, and disappearance are critical to understanding both steady-state homeostasis and inflammatory responses. Using human in vivo deuterium labeling, it has been shown that classical monocytes emerge first from marrow, after a postmitotic interval of 1.6 days, and circulate for a day. Subsequent labeling of intermediate and nonclassical monocytes is consistent with a model of sequential transition. Intermediate and nonclassical monocytes have longer circulating lifespans (∼4 and ∼7 days, respectively). It is of great interest to determine the lifespan and decay of monocytes post-viral infection as modeled by administration of a live, attenuated yellow fever vaccination.

Deuterium labeled water (2H2O) or heavy water is chemically nearly the same as normal water but the hydrogen atoms are of the heavy isotope deuterium, in which the nucleus of the hydrogen atom contains a neutron in addition to the proton. When a person drinks 2H2O, it mixes with the body water. Proteins, DNA, RNA, lipids, and other biomolecules become "labeled"; the faster the biomolecules are being synthesized, the more they become labeled with deuterium. The deuterium labeled molecules can be measured by sampling blood and body fluids such as plasma, cerebrospinal fluid, sputum, urine, etc.

Participants will enroll into one of 8 study arms and will be given repeated small doses of 2H2O to drink and may receive the yellow fever vaccine, depending on the study arm they are in.