Assessing T cell responses in respiratory syncytial virus infection and vaccination

Schmidt, Megan Elizabeth

01 May 2019

Respiratory syncytial virus (RSV) is the leading cause of lower respiratory tract infection and hospitalization in infants and young children, but no vaccine is currently available. CD4 and CD8 T cells are critical for mediating viral clearance but also contribute to immunopathology following an acute RSV infection. However, few RSV-derived CD4 and CD8 T cell epitopes in the commonly used C57BL/6 mouse strain have been described. I utilized an overlapping peptide library spanning the entire RSV proteome and intracellular cytokine staining for interferon-gamma (IFN-γ) to identify novel CD4 and CD8 T cell epitopes in C57BL/6 mice. I discovered and characterized two novel CD4 T cell epitopes and three novel CD8 T cell epitopes located within multiple RSV proteins. Overall, the novel RSV-derived CD4 and CD8 T cell epitopes identified in C57BL/6 mice will aid in future studies of RSV-specific T cell responses. While CD8 T cells are important for viral clearance following an acute RSV infection, the contribution of memory CD8 T cells in providing protection against reinfection with RSV remains unclear. I used a prime-boost immunization approach to induce robust, systemic memory CD8 T cell responses in the absence of RSV-specific CD4 T cells and antibodies. I determined that high magnitude, systemic memory CD8 T cell responses efficiently reduced lung viral titers following RSV infection, but unexpectedly did so at the expense of severe and fatal immunopathology. The exacerbated disease was mediated by the rapid and excessive production of IFN-γ by memory CD8 T cells in the lung and airways. In contrast, I found that local immunization generated a large population of tissue-resident memory CD8 T cells in the lung that efficiently reduced lung viral titers in the absence of exacerbated disease. Additionally, I observed that pre-existing RSV-specific neutralizing antibodies prevented the immunopathology induced by high magnitude, systemic memory CD8 T cell responses following RSV infection. Prophylactic treatment with neutralizing antibodies against RSV efficiently restricted early virus replication, which resulted in a significant decrease in lung IFN-γ levels, memory CD8 T cell activation, and the frequency of IFN-γ producing CD8 T cells. Thus, my results demonstrate that high magnitude, systemic memory CD8 T cells induce lethal immunopathology following RSV infection, which can be prevented by pre-existing RSV-specific neutralizing antibodies. Overall, my results have important implications for the development of future RSV vaccines. The development of a live-attenuated vaccine for RSV has been prevented by the inability to properly balance attenuation with immunogenicity and efficacy. Recently, a recombinant RSV strain lacking the gene that encodes the matrix (M) protein (RSV M-null) was developed. As the M protein is required for virion assembly following infection of a host cell, RSV M-null induces a single-cycle infection. I evaluated RSV M-null as a potential live-attenuated vaccine candidate by determining its pathogenicity, immunogenicity, and protective capacity in BALB/c mice compared to its recombinant wild-type control virus (RSV recWT). RSV M-null was sufficiently attenuated, as significantly reduced lung viral titers, weight loss, and pulmonary dysfunction were observed compared to mice infected with RSV recWT. Surprisingly, despite its attenuation, I found that RSV M-null infection induced effector T cell, germinal center B cell, serum antibody, and memory T cell responses of similar magnitude to that elicited by infection with RSV recWT. Importantly, RSV M-null immunization provided protection against secondary viral challenge by reducing lung viral titers as efficiently as immunization with RSV recWT. Overall, my results indicate that RSV M-null combines attenuation with high immunogenicity and efficacy and represents a promising novel live-attenuated RSV vaccine candidate.

Lung

Memory CD8 T cell

Respiratory syncytial virus

T cell

Vaccine

Immunology of Infectious Disease

Regulation of memory CD8 T cell differentiation

Pham, Nhat-Long Lam

01 May 2011

Antigen-specific CD8 T cells play a critical role in protecting the host from infection by intracellular pathogens including viruses, bacteria and parasites. During the course of an infection, antigen-specific CD8 T cells undergo proliferative expansion to increase in number, which is followed by contraction and generation of a stable pool of long-lived memory cells. Importantly, memory CD8 T cells provide enhanced resistance to re-infection by the same pathogen. Moreover, the number of memory CD8 T cells correlates strongly with the level of protection against re-infection. Therefore, vaccines designed to promote cellular immunity should logically focus on achieving sufficiently high number of these memory cells for protection. Most current vaccines have relied on inducing antibodies to protect the host by neutralizing pathogens or blocking pathogen entry into the cells. However, there is a recognized need to design vaccines that also stimulate a strong CD8 T cell component of the adaptive immune response in addition to antibodies. Importantly, inflammatory cytokines induced by infection or vaccination with adjuvant act directly or indirectly on CD8 T cells to modulate their expansion, contraction and acquisition of memory characteristics. Thus, an understanding of how inflammatory cytokines regulate CD8 T cell memory differentiation may help guide the strategies for rational vaccine design. My studies examine the roles of inflammatory cytokines in regulating CD8 T cell memory differentiation. Specifically, my studies investigate the timing of inflammatory cytokine exposure and the role of type I IFNs and IL-12 in regulating effector/memory CD8 T cell differentiation, and exploiting the cross-presentation pathway to rapidly generate protective CD8 T cell immunity. Specifically, my results indicate that (i) encounter with inflammatory cytokines during the rapid proliferative phase deflects CD8 T cell differentiation away from memory towards a sustained effector program, (ii) that direct signaling by either type I IFN or IL-12 to the responding CD8 T cells promotes maximal expansion, but neither of these cytokines is essential to regulate the effector/memory differentiation program, and (iii) cross-priming with both cell-associated antigen and antigen-coated, biodegradable microspheres, accelerates CD8 T cell memory development that can be exploited to rapidly generate protective CD8 T cell immunity.

DIFFERENTIATION

INFLAMMATORY CYTOKINES

MEMORY CD8 T CELL

PLGA microspheres

VACCINES

Immunology of Infectious Disease

Induction de réponses mémoires lymphocytaires T CD8 et protection vaccinale après transfert de gènes par le vecteur AAV recombinant / Induction of lymphocytic memory CD8 T cell responses and vaccinal protection following genes transfer by recombinant Adeno-Associated Virus (rAAV) vector

Ghenassia, Alexandre

30 October 2015

La mémoire immunologique est le mécanisme biologique fondamental à la base du développement de la vaccination. La compréhension de ce mécanisme ainsi que de ses interactions avec les différents acteurs du système immunitaire a permis l’élaboration de vaccins qui sont aujourd’hui les garants d’une protection accrue face à l’émergence de maladies infectieuses potentiellement mortelles. La voie d’injection et le mode de transfert de ces vaccins sont des paramètres majeurs à prendre en considération car ils définissent une modulation des réponses immunitaires et de leurs spécificités d’action. De nos jours, seule la voie intramusculaire demeure la voie majoritaire d’administration de vaccins lors de la prophylaxie primaire en santé humaine. Au cours de notre étude, nous nous sommes intéressés à comparer l’injection d’un antigène (l’ovalbumine) selon deux voies d’administration : la voie intramusculaire et la voie intradermique. Nous nous sommes également appuyés sur une technologie du laboratoire qui consiste à transférer des gènes par des vecteurs AAV2/1 recombinants. Nous disposions de deux constructions de ces vecteurs ayant une spécificité pour cibler les cellules musculaires et permettant l’apport d’un effet auxiliaire par les lymphocytes T CD4+ lors d’injections dans des souris femelles. De plus, une de ces constructions nous permettait d’éviter la voie de présentation directe de l’antigène par les cellules dendritiques (DCs) aux lymphocytes T CD8+. Les capacités modulatrices de ces vecteurs nous permirent de montrer pour la première fois que le vecteur AAV2/1 recombinant était capable de faire exprimer un transgène au sein de la peau et d’y générer une réponse cellulaire forte. Nous avons également montré qu’il existait une synergie d’action entre l’effet auxiliaire et la voie intradermique qui améliorait considérablement les réponses cellulaires issues de la présentation croisée d’antigène. Enfin, nous avons pu démontrer que les lymphocytes T CD8+ générés suite à cette synergie d’action présentaient un profil phénotypique de cellules mémoires polyfonctionnelles et capables de protéger l’hôte face à un challenge pathogénique. / Immunological memory is the fundamental biological mechanism at the beginning of the development of vaccination. Understanding this mechanism and its interactions with the various players of the immune system has allowed the development of vaccines that are today the most effective barrier against the emergence of life-threatening infectious diseases. Route of injection and the nature of carriers of these vaccines are key parameters to be taken into consideration because they define a modulation of immune responses and their specific features. Nowadays, only the intramuscular injection route remains the major route of vaccines injection in the context of primary prophylaxis in human health. During our study, we were interested in comparing the injection of antigen (ovalbumin) following two routes of administration: intramuscular and intradermal routes. We also relied on a technology in the laboratory that involves the transfer of genes by rAAV2/1 vectors. We had two constructs of these vectors having specificity to target skeletal muscle cells and allowing us to provide a helper effect from CD4+ T cells during injections into female mice recipients. Moreover, one of these constructs enabled us to avoid the direct presentation of antigens by dendritic cells (DCs) to CD8+ T cells. The capacity of modulation of these vectors allowed us to show for the first time that the rAAV2/1 vector was able to trigger the expression of a transgene in the skin, and there to generate a strong cellular response. We have also shown that CD4+ T cell help and the intradermal route of immunization synergize to improve greatly cellular responses from the cross-presentation of antigens. Finally, we have demonstrated that CD8+ T cells generated following this synergism exhibited a phenotypic profile of polyfunctional memory cells and able to protect the host against a pathogenic challenge.

Mémoire immunologique

Vaccination

Vecteur AAV recombinant

Lymphocyte T CD8+ mémoire

Voies de présentation d’antigène

Voies d’administration

Lymphocyte T CD4+ auxiliaire

Immunological memory

Vaccination

Recombinant AAV vector

Memory CD8+ T cell

Antigen presentation pathways

Routes of administration

CD4+ T helper cell

571.96

Induction de réponses mémoires lymphocytaires T CD8 et protection vaccinale après transfert de gènes par le vecteur AAV recombinant / Induction of lymphocytic memory CD8 T cell responses and vaccinal protection following genes transfer by recombinant Adeno-Associated Virus (rAAV) vector

Ghenassia, Alexandre

30 October 2015

La mémoire immunologique est le mécanisme biologique fondamental à la base du développement de la vaccination. La compréhension de ce mécanisme ainsi que de ses interactions avec les différents acteurs du système immunitaire a permis l’élaboration de vaccins qui sont aujourd’hui les garants d’une protection accrue face à l’émergence de maladies infectieuses potentiellement mortelles. La voie d’injection et le mode de transfert de ces vaccins sont des paramètres majeurs à prendre en considération car ils définissent une modulation des réponses immunitaires et de leurs spécificités d’action. De nos jours, seule la voie intramusculaire demeure la voie majoritaire d’administration de vaccins lors de la prophylaxie primaire en santé humaine. Au cours de notre étude, nous nous sommes intéressés à comparer l’injection d’un antigène (l’ovalbumine) selon deux voies d’administration : la voie intramusculaire et la voie intradermique. Nous nous sommes également appuyés sur une technologie du laboratoire qui consiste à transférer des gènes par des vecteurs AAV2/1 recombinants. Nous disposions de deux constructions de ces vecteurs ayant une spécificité pour cibler les cellules musculaires et permettant l’apport d’un effet auxiliaire par les lymphocytes T CD4+ lors d’injections dans des souris femelles. De plus, une de ces constructions nous permettait d’éviter la voie de présentation directe de l’antigène par les cellules dendritiques (DCs) aux lymphocytes T CD8+. Les capacités modulatrices de ces vecteurs nous permirent de montrer pour la première fois que le vecteur AAV2/1 recombinant était capable de faire exprimer un transgène au sein de la peau et d’y générer une réponse cellulaire forte. Nous avons également montré qu’il existait une synergie d’action entre l’effet auxiliaire et la voie intradermique qui améliorait considérablement les réponses cellulaires issues de la présentation croisée d’antigène. Enfin, nous avons pu démontrer que les lymphocytes T CD8+ générés suite à cette synergie d’action présentaient un profil phénotypique de cellules mémoires polyfonctionnelles et capables de protéger l’hôte face à un challenge pathogénique. / Immunological memory is the fundamental biological mechanism at the beginning of the development of vaccination. Understanding this mechanism and its interactions with the various players of the immune system has allowed the development of vaccines that are today the most effective barrier against the emergence of life-threatening infectious diseases. Route of injection and the nature of carriers of these vaccines are key parameters to be taken into consideration because they define a modulation of immune responses and their specific features. Nowadays, only the intramuscular injection route remains the major route of vaccines injection in the context of primary prophylaxis in human health. During our study, we were interested in comparing the injection of antigen (ovalbumin) following two routes of administration: intramuscular and intradermal routes. We also relied on a technology in the laboratory that involves the transfer of genes by rAAV2/1 vectors. We had two constructs of these vectors having specificity to target skeletal muscle cells and allowing us to provide a helper effect from CD4+ T cells during injections into female mice recipients. Moreover, one of these constructs enabled us to avoid the direct presentation of antigens by dendritic cells (DCs) to CD8+ T cells. The capacity of modulation of these vectors allowed us to show for the first time that the rAAV2/1 vector was able to trigger the expression of a transgene in the skin, and there to generate a strong cellular response. We have also shown that CD4+ T cell help and the intradermal route of immunization synergize to improve greatly cellular responses from the cross-presentation of antigens. Finally, we have demonstrated that CD8+ T cells generated following this synergism exhibited a phenotypic profile of polyfunctional memory cells and able to protect the host against a pathogenic challenge.

Mémoire immunologique

Vaccination

Vecteur AAV recombinant

Lymphocyte T CD8+ mémoire

Voies de présentation d’antigène

Voies d’administration

Lymphocyte T CD4+ auxiliaire

Immunological memory

Vaccination

Recombinant AAV vector

Memory CD8+ T cell

Antigen presentation pathways

Routes of administration

CD4+ T helper cell

571.96

Induction de réponses mémoires lymphocytaires T CD8 et protection vaccinale après transfert de gènes par le vecteur AAV recombinant / Induction of lymphocytic memory CD8 T cell responses and vaccinal protection following genes transfer by recombinant Adeno-Associated Virus (rAAV) vector

Ghenassia, Alexandre

30 October 2015

La mémoire immunologique est le mécanisme biologique fondamental à la base du développement de la vaccination. La compréhension de ce mécanisme ainsi que de ses interactions avec les différents acteurs du système immunitaire a permis l’élaboration de vaccins qui sont aujourd’hui les garants d’une protection accrue face à l’émergence de maladies infectieuses potentiellement mortelles. La voie d’injection et le mode de transfert de ces vaccins sont des paramètres majeurs à prendre en considération car ils définissent une modulation des réponses immunitaires et de leurs spécificités d’action. De nos jours, seule la voie intramusculaire demeure la voie majoritaire d’administration de vaccins lors de la prophylaxie primaire en santé humaine. Au cours de notre étude, nous nous sommes intéressés à comparer l’injection d’un antigène (l’ovalbumine) selon deux voies d’administration : la voie intramusculaire et la voie intradermique. Nous nous sommes également appuyés sur une technologie du laboratoire qui consiste à transférer des gènes par des vecteurs AAV2/1 recombinants. Nous disposions de deux constructions de ces vecteurs ayant une spécificité pour cibler les cellules musculaires et permettant l’apport d’un effet auxiliaire par les lymphocytes T CD4+ lors d’injections dans des souris femelles. De plus, une de ces constructions nous permettait d’éviter la voie de présentation directe de l’antigène par les cellules dendritiques (DCs) aux lymphocytes T CD8+. Les capacités modulatrices de ces vecteurs nous permirent de montrer pour la première fois que le vecteur AAV2/1 recombinant était capable de faire exprimer un transgène au sein de la peau et d’y générer une réponse cellulaire forte. Nous avons également montré qu’il existait une synergie d’action entre l’effet auxiliaire et la voie intradermique qui améliorait considérablement les réponses cellulaires issues de la présentation croisée d’antigène. Enfin, nous avons pu démontrer que les lymphocytes T CD8+ générés suite à cette synergie d’action présentaient un profil phénotypique de cellules mémoires polyfonctionnelles et capables de protéger l’hôte face à un challenge pathogénique. / Immunological memory is the fundamental biological mechanism at the beginning of the development of vaccination. Understanding this mechanism and its interactions with the various players of the immune system has allowed the development of vaccines that are today the most effective barrier against the emergence of life-threatening infectious diseases. Route of injection and the nature of carriers of these vaccines are key parameters to be taken into consideration because they define a modulation of immune responses and their specific features. Nowadays, only the intramuscular injection route remains the major route of vaccines injection in the context of primary prophylaxis in human health. During our study, we were interested in comparing the injection of antigen (ovalbumin) following two routes of administration: intramuscular and intradermal routes. We also relied on a technology in the laboratory that involves the transfer of genes by rAAV2/1 vectors. We had two constructs of these vectors having specificity to target skeletal muscle cells and allowing us to provide a helper effect from CD4+ T cells during injections into female mice recipients. Moreover, one of these constructs enabled us to avoid the direct presentation of antigens by dendritic cells (DCs) to CD8+ T cells. The capacity of modulation of these vectors allowed us to show for the first time that the rAAV2/1 vector was able to trigger the expression of a transgene in the skin, and there to generate a strong cellular response. We have also shown that CD4+ T cell help and the intradermal route of immunization synergize to improve greatly cellular responses from the cross-presentation of antigens. Finally, we have demonstrated that CD8+ T cells generated following this synergism exhibited a phenotypic profile of polyfunctional memory cells and able to protect the host against a pathogenic challenge.

Mémoire immunologique

Vaccination

Vecteur AAV recombinant

Lymphocyte T CD8+ mémoire

Voies de présentation d’antigène

Voies d’administration

Lymphocyte T CD4+ auxiliaire

Immunological memory

Vaccination

Recombinant AAV vector

Memory CD8+ T cell

Antigen presentation pathways

Routes of administration

CD4+ T helper cell

571.96