Trained innate immunity and resistance to Mycobacterium tuberculosis infection.

Some individuals, even when heavily exposed to an infectious tuberculosis patient, develop neither active nor latent tuberculosis infection (LTBI). This 'early clearance' of Mycobacterium tuberculosis is associated with a history of bacillus Calmette-Guérin (BCG) vaccination. As BCG vaccination can boost innate immune responses through a process termed 'trained immunity', we hypothesize that BCG-induced trained innate immunity contributes to early clearance of M. tuberculosis. We describe the epidemiological evidence and biological concepts of early clearance and trained immunity, and the possible relation between these two processes through BCG vaccination. Relevant data from published reports up to November 2018 were examined in the conduct of this review. Several observational studies and one recent randomized trial support the concept that boosting innate immunity contributes to protection against M. tuberculosis infection, with BCG vaccination providing approximately 50% protection. The molecular mechanisms mediating early clearance remain largely unknown, but we propose that trained immunity, characterized by epigenetic and metabolic reprogramming of innate immune cells such as monocytes or macrophages, is at least partially responsible for eliminating the mycobacteria and inducing early clearance. Future studies should examine if BCG revaccination increases early clearance of M. tuberculosis through induction of trained immunity. Epigenetic or metabolic modulation may further boost BCG-induced trained innate immunity to promote tuberculosis prevention. New tuberculosis vaccine candidates should also be examined for their capacity to improve protection against M. tuberculosis infection and induce trained immunity.

Koeken VACM ，Verrall AJ ，Netea MG ，Hill PC ，van Crevel R ... -  《-》

Natural and trained innate immunity against Mycobacterium tuberculosis.

Tuberculosis (TB), caused by Mycobacterium tuberculosis (Mtb) infection, remains a major global health emergency. It is estimated that one third of global population are affected, predominantly with latent granuloma form of the disease. Mtb co-evolved with humans, for its obligatory intra-macrophage phagosome habitat and slow replication, balanced against unique mycobacterial innate immunity, which appears to be highly complex. TB is transmitted via cough aerosol Mtb inhalation. Bovine TB attenuated Bacillus Calmette Guerin (BCG) live vaccine has been in practice for protection of young children from severe disseminated Mtb infection, but not sufficiently for their lungs, as obtained by trials in TB endemic community. To augment BCG vaccine-driven innate and adaptive immunity for neonates and better protection against adult pulmonary TB, a number of BCG pre-vaccination based, subset vaccine candidates have been tested via animal preclinical, followed by safe clinical trials. BCG also enhances innate macrophage trained immunity and memory, through primordial intracellular Toll-like receptors (TLRs) 7 and 9, which recognise distinct mycobacterial molecular pattern signature. This signature is transmitted by TLR signalling via nuclear factor-κB, for activating innate immune transcription and expression of gene profiling in a mycobacterial signature-specific manner. These are epigenetically imprinted in reprogramming of distinct chromatin areas for innate immune memory, to be recalled following lung reinfection. Unique TB innate immunity and its trained memory are considered independent from adaptive immune B and T cells. On the other hand, adaptive immunity is crucial in Mtb containment in granulomatous latency, supported by innate immune cell infiltration. In nearly 5-10 % of susceptible people, latent TB may be activated due to immune evasion by Mtb from intracellular phagosome within macrophage, perpetrating TB. However, BCG and new recombinant BCG vaccines have the capacity, as indicated in pre- and clinical trials, to overcome such Mtb evasion. Various strategies include pro-inflammatory-bactericidal type 1 polarisation (M1) phenotype of the infected macrophage, involving thrombospondin-TLR pathway. Saprophytic M. smegmatis-based recombinant vaccines are also promising candidates against TB. BCG vaccination of neonates/infants in TB endemic countries also reduced their pneumonia caused by various microbes independent of TB immunity. Here, we discuss host immune response against Mtb, its immune evasion strategies, and the important role innate immunity plays in the development of protection against TB.

Ferluga J ，Yasmin H ，Al-Ahdal MN ，Bhakta S ，Kishore U ... -  《-》

BCG-Induced Cross-Protection and Development of Trained Immunity: Implication for Vaccine Design.

The Bacillus Calmette-Guérin (BCG) is a live attenuated tuberculosis vaccine that has the ability to induce non-specific cross-protection against pathogens that might be unrelated to the target disease. Vaccination with BCG reduces mortality in newborns and induces an improved innate immune response against microorganisms other than Mycobacterium tuberculosis, such as Candida albicans and Staphylococcus aureus. Innate immune cells, including monocytes and natural killer (NK) cells, contribute to this non-specific immune protection in a way that is independent of memory T or B cells. This phenomenon associated with a memory-like response in innate immune cells is known as "trained immunity." Epigenetic reprogramming through histone modification in the regulatory elements of particular genes has been reported as one of the mechanisms associated with the induction of trained immunity in both, humans and mice. Indeed, it has been shown that BCG vaccination induces changes in the methylation pattern of histones associated with specific genes in circulating monocytes leading to a "trained" state. Importantly, these modifications can lead to the expression and/or repression of genes that are related to increased protection against secondary infections after vaccination, with improved pathogen recognition and faster inflammatory responses. In this review, we discuss BCG-induced cross-protection and acquisition of trained immunity and potential heterologous effects of recombinant BCG vaccines.

Covián C ，Fernández-Fierro A ，Retamal-Díaz A ，Díaz FE ，Vasquez AE ，Lay MK ，Riedel CA ，González PA ，Bueno SM ，Kalergis AM ... -  《Frontiers in Immunology》

BCG-induced protection: effects on innate immune memory.

The Bacille Calmette-Guerin (BCG) vaccine is the only vaccine proved to be effective against tuberculosis and it remains the most commonly used vaccine worldwide. In addition to its effects on mycobacterial diseases, an increasing body of epidemiological evidence accumulated since its introduction in 1921 shows that BCG also exerts beneficial non-specific effects ranging from protection against non-mycobacterial diseases, decreased incidence of allergic diseases, and treatment of certain malignancies. The biological substrate of these effects is mediated partly by heterologous effects on adaptive immunity, but also on the potentiation of innate immune responses through epigenetic mechanisms, a process termed 'trained immunity'. The process of trained immunity may also play a role in the beneficial effects of BCG against tuberculosis and Mycobacterium tuberculosis infection, and this could have important consequences for our quest for improving vaccination strategies.

Netea MG ，van Crevel R 《-》

Targeting innate immunity for tuberculosis vaccination.

Khader SA ，Divangahi M ，Hanekom W ，Hill PC ，Maeurer M ，Makar KW ，Mayer-Barber KD ，Mhlanga MM ，Nemes E ，Schlesinger LS ，van Crevel R ，Vankayalapati R( ，Xavier RJ ，Netea MG ，Bill and Melinda Gates Foundation Collaboration for TB Vaccine Discovery Innate Immunity Working Group18 ... -  《-》