TY - JOUR
T1 - In vivo antigen expression regulates CD4 T cell differentiation and vaccine efficacy against mycobacterium tuberculosis infection
AU - Clemmensen, Helena Strand
AU - Dube, Jean Yves
AU - McIntosh, Fiona
AU - Rosenkrands, Ida
AU - Jungersen, Gregers
AU - Aagaard, Claus
AU - Andersen, Peter
AU - Behr, Marcel A.
AU - Mortensen, Rasmus
N1 - Publisher Copyright:
© 2021 Clemmensen et al.
PY - 2021
Y1 - 2021
N2 - New vaccines are urgently needed against Mycobacterium tuberculosis (Mtb), which kills more than 1.4 million people each year. CD4 T cell differentiation is a key determinant of protective immunity against Mtb, but it is not fully understood how host-pathogen interactions shape individual antigen-specific T cell populations and their protective capacity. Here, we investigated the immunodominant Mtb anti-gen, MPT70, which is upregulated in response to gamma interferon (IFN-γ) or nutrient/ oxygen deprivation of in vitro-infected macrophages. Using a murine aerosol infection model, we compared the in vivo expression kinetics of MPT70 to a constitutively expressed antigen, ESAT-6, and analyzed their corresponding CD4 T cell phenotype and vaccine protection. For wild-type Mtb, we found that in vivo expression of MPT70 was delayed compared to ESAT-6. This delayed expression was associated with induction of less differentiated MPT70-specific CD4 T cells but, compared to ESAT-6, also reduced protection after vaccination. In contrast, infection with an MPT70-overexpress-ing Mtb strain promoted highly differentiated KLRG1+CX3CR1+ CD4 T cells with lim-ited lung-homing capacity. Importantly, this differentiated phenotype could be pre-vented by vaccination, and against the overexpressing strain, vaccination with MPT70 conferred protection similar to vaccination with ESAT-6. Together, our data indicate that high in vivo antigen expression drives T cells toward terminal differentiation and that targeted vaccination with adjuvanted protein can counteract this phenomenon by maintaining T cells in a protective less differentiated state. These observations shed new light on host-pathogen interactions and provide guidance on how future Mtb vaccines can be designed to tip the immune balance in favor of the host. IMPORTANCE Tuberculosis, caused by Mtb, constitutes a global health crisis of mas-sive proportions and the impact of the current coronavirus disease 2019 (COVID-19) pandemic is expected to cause a rise in tuberculosis-related deaths. Improved vaccines are therefore needed more than ever, but a lack of knowledge on protective immunity hampers their development. The present study shows that constitutively expressed antigens with high availability drive highly differentiated CD4 T cells with diminished protective capacity, which could be a survival strategy by Mtb to evade T cell immunity against key antigens. We demonstrate that immunization with such antigens can counteract this phenomenon by maintaining antigen-specific T cells in a state of low differentiation. Future vaccine strategies should therefore explore combinations of multiple highly expressed antigens and we suggest that T cell differentiation could be used as a readily measurable parameter to identify these in both preclinical and clinical studies.
AB - New vaccines are urgently needed against Mycobacterium tuberculosis (Mtb), which kills more than 1.4 million people each year. CD4 T cell differentiation is a key determinant of protective immunity against Mtb, but it is not fully understood how host-pathogen interactions shape individual antigen-specific T cell populations and their protective capacity. Here, we investigated the immunodominant Mtb anti-gen, MPT70, which is upregulated in response to gamma interferon (IFN-γ) or nutrient/ oxygen deprivation of in vitro-infected macrophages. Using a murine aerosol infection model, we compared the in vivo expression kinetics of MPT70 to a constitutively expressed antigen, ESAT-6, and analyzed their corresponding CD4 T cell phenotype and vaccine protection. For wild-type Mtb, we found that in vivo expression of MPT70 was delayed compared to ESAT-6. This delayed expression was associated with induction of less differentiated MPT70-specific CD4 T cells but, compared to ESAT-6, also reduced protection after vaccination. In contrast, infection with an MPT70-overexpress-ing Mtb strain promoted highly differentiated KLRG1+CX3CR1+ CD4 T cells with lim-ited lung-homing capacity. Importantly, this differentiated phenotype could be pre-vented by vaccination, and against the overexpressing strain, vaccination with MPT70 conferred protection similar to vaccination with ESAT-6. Together, our data indicate that high in vivo antigen expression drives T cells toward terminal differentiation and that targeted vaccination with adjuvanted protein can counteract this phenomenon by maintaining T cells in a protective less differentiated state. These observations shed new light on host-pathogen interactions and provide guidance on how future Mtb vaccines can be designed to tip the immune balance in favor of the host. IMPORTANCE Tuberculosis, caused by Mtb, constitutes a global health crisis of mas-sive proportions and the impact of the current coronavirus disease 2019 (COVID-19) pandemic is expected to cause a rise in tuberculosis-related deaths. Improved vaccines are therefore needed more than ever, but a lack of knowledge on protective immunity hampers their development. The present study shows that constitutively expressed antigens with high availability drive highly differentiated CD4 T cells with diminished protective capacity, which could be a survival strategy by Mtb to evade T cell immunity against key antigens. We demonstrate that immunization with such antigens can counteract this phenomenon by maintaining antigen-specific T cells in a state of low differentiation. Future vaccine strategies should therefore explore combinations of multiple highly expressed antigens and we suggest that T cell differentiation could be used as a readily measurable parameter to identify these in both preclinical and clinical studies.
KW - ESAT-6
KW - Immunization
KW - In vivo expression
KW - MPT70
KW - Mycobacterium tuberculosis
KW - T cell differentiation
KW - Vaccination
U2 - 10.1128/mBio.00226-21
DO - 10.1128/mBio.00226-21
M3 - Journal article
C2 - 33879592
AN - SCOPUS:85104422303
SN - 2150-7511
VL - 12
JO - mBio (Online)
JF - mBio (Online)
IS - 2
M1 - e00226-21
ER -