Opposite effects of Vaccinia and modified Vaccinia Ankara on trained immunity.

Vaccines such as Vaccinia or BCG have non-specific effects conferring protection against other diseases than their target infection, which are likely partly mediated through induction of innate immune memory (trained immunity). MVA85A, a recombinant strain of modified Vaccinia Ankara (MVA), has been suggested as an alternative vaccine against tuberculosis, but its capacity to induce positive or negative non-specific immune effects has not been studied. This study assesses whether Vaccinia and MVA are able to induce trained innate immunity in monocytes. Human primary monocytes were primed in an in vitro model with Vaccinia or MVA for 1 day, after which the stimulus was washed off and the cells were rechallenged with unrelated microbial ligands after 1 week. Heterologous cytokine responses were assessed and the capacity of MVA to induce epigenetic changes at the level of cytokine genes was investigated using chromatin immunoprecipitation and pharmacological inhibitors. Monocytes trained with Vaccinia showed significantly increased IL-6 and TNF-α production to stimulation with non-related stimuli, compared to non-trained monocytes. In contrast, monocytes primed with MVA showed significant decreased heterologous IL-6 and TNF-α responses, an effect which was abrogated by the addition of a histone methyltransferase inhibitor. No effects on H3K4me3 were observed after priming with MVA. It can be thus concluded that Vaccinia induces trained immunity in vitro, whereas MVA induces innate immune tolerance. This suggests the induction of trained immunity as an immunological mechanism involved in the non-specific effects of Vaccinia vaccination and points to a possible explanation for the lack of effect of MVA85A against tuberculosis.

Ready to benefit from training: heterologous effects of early life immunization.

Trained immunity reflects the ability of the innate immune system to adapt via epigenetic changes in monocytes, enhancing responses to a range of microbes, thereby potentially reducing infection in high-risk populations. Examples of trained immunity at birth include enhanced resistance to infection in TLR-simulated newborn mice, reduced risk of late onset sepsis with histologic chorioamnionitis and beneficial heterologous effects of neonatal bacille Calmette-Guérin administration in reducing diverse infections during infancy. Future efforts will assess leveraging trained immunity in early life by administering 'stand-alone' innate immune stimuli or (self-)adjuvanted vaccines to protect against a broad range of infections.

The heterologous (non-specific) effects of vaccines: implications for policy in high-mortality countries.

There are important interactions between vaccines, and between vaccines and unrelated (heterologous) infections. In high-mortality regions, until the next vaccine is given, live vaccines such as bacillus Calmette-Guérin (BCG) and measles vaccines reduce mortality from infections such as pneumonia and sepsis. However, non-live vaccines such as diphtheria, tetanus and whole-cell pertussis vaccine (DTP) may increase mortality from infections other than diphtheria, tetanus and pertussis. All-cause mortality might be reduced if an extra dose of Edmonston-Zagreb measles vaccine were given at 20 weeks of age, 4-6 weeks after the third dose of DTP, with no subsequent doses of DTP in girls, and no vitamin A in girls or boys before the second dose of measles vaccine at 9 months of age. Policy should change to increase the proportion of babies given BCG and oral polio vaccine at birth, and should recognize the important differences between BCG, DTP and measles vaccines produced by different manufacturers.

Trained immunity: consequences for the heterologous effects of BCG vaccination.

A growing body of evidence from epidemiologic and immunologic studies have shown that in addition to target disease-specific effects, vaccines have heterologous effects towards unrelated pathogens. Like some other vaccines, bacille Calmette-Guerin (BCG) has shown in observational studies and randomized clinical trials to increase survival beyond the disease burden of the target disease. The immunologic substrate for these non-specific protective effects have been ascertained to heterologous T cell effects on the one hand, and to priming of innate immunity on the other hand. The term 'trained immunity' has been proposed to describe these potentiating effects of vaccines on innate immune responses. This process can explain the rapid effects of BCG vaccination and has been suggested to be mediated by epigenetic programming of monocytes or macrophages. This novel concept has important implications for the possible use of vaccines, for vaccination policy and even for the design of novel immunotherapeutic approaches.

BCG-associated heterologous immunity, a historical perspective: experimental models and immunological mechanisms.

Randomized controlled trials indicate that bacille Calmette-Guerin (BCG) has beneficial heterologous ('non-specific') effects on mortality in high mortality settings. These findings have stimulated interest in understanding the immunological mechanisms underlying these effects in the hope of harnessing them to reduce all-cause mortality. This line of investigation is especially important in light of BCG being discontinued in some countries as the prevalence of TB falls. Stopping routine BCG in this situation may have the unintended consequence of depriving children of the beneficial immune modulating effects of this vaccine. BCG has been recognized as a potent immunomodulator for decades. This review details experimental studies involving BCG and any heterologous antigen that aimed to interrogate potential immunological mechanisms. To provide a historical perspective, the evidence is presented chronologically. The lines of immunological enquiry can be seen to mirror the evolution of our understanding of cell-mediated immunity and its components. As new clinical trials to investigate the heterologous effects of BCG are undertaken, an understanding of the history of BCG-induced immunity against heterologous antigens may provide information on immunological pathways worthy of further interrogation using modern immunological methods.

BCG-associated heterologous immunity, a historical perspective: intervention studies in animal models of infectious diseases.

The WHO Special Advisory Group of Experts (SAGE) review of the available epidemiological and trial evidence in humans concluded that bacillus Calmette-Guérin (BCG) vaccination leads to beneficial heterologous ('non-specific') effects, specifically on all-cause mortality. Randomized controlled trials showing this beneficial effect suggest improved survival is the result of enhanced protection against infection. This paper reviews the available evidence for the attenuating effects of BCG vaccine on experimental infections in animal models, including protection from bacteria, viruses, parasites and fungi. The reviewed studies suggest that BCG activates multiple immune pathways and that the basis for BCG-associated heterologous immunity may vary by pathogen. Modern immunological and molecular methods, exemplified by 'vaccinomics', are well placed to further investigate the basis of BCG's heterologous effects using a systems biology approach.

Vaccination and heterologous immunity: educating the immune system.

This review discusses three inter-related topics: (1) the immaturity of the neonatal and infant immune response; (2) heterologous immunity, where prior infection history with unrelated pathogens alters disease outcome resulting in either enhanced protective immunity or increased immunopathology to new infections, and (3) epidemiological human vaccine studies that demonstrate vaccines can have beneficial or detrimental effects on subsequent unrelated infections. The results from the epidemiological and heterologous immunity studies suggest that the immune system has tremendous plasticity and that each new infection or vaccine that an individual is exposed to during a lifetime will potentially alter the dynamics of their immune system. It also suggests that each new infection or vaccine that an infant receives is not only perturbing the immune system but is educating the immune system and laying down the foundation for all subsequent responses. This leads to the question, is there an optimum way to educate the immune system? Should this be taken into consideration in our vaccination protocols?

Heterologous and sex differential effects of administering vitamin A supplementation with vaccines.

WHO recommends high-dose vitamin A supplementation (VAS) to children from 6 months to 5 years of age in low-income countries, in order to prevent and treat vitamin A deficiency-associated morbidity and mortality. The current policy does not discriminate this recommendation either by sex or vaccination status of the child. There is accumulating evidence that the effects of VAS on morbidity, mortality and immunological parameters depend on concomitant vaccination status. Moreover, these interactions may manifest differently in males and females. Certain vaccines administered through the Expanded Program on Immunization have been shown to alter all-cause mortality from infections other than the vaccine-targeted disease. This review summarizes the evidence from observational studies and randomized-controlled trials of the effects of VAS on these so-called heterologous or non-specific effects of vaccines, with a focus on sex differences. In general, VAS seems to enhance the heterologous effects of vaccines, particularly for diphtheria-tetanus-pertussis and live measles vaccines, where some studies, although not unanimously, show a stronger interaction between VAS and vaccination in females. We suggest that vaccination status and sex should be considered when evaluating the effects of VAS in early life.