A promiscuous T cell epitope-based HIV vaccine providing redundant population coverage of the HLA class II elicits broad, polyfunctional T cell responses in nonhuman primates.

Over the last few decades, several emerging or reemerging viral diseases with no readily available vaccines have ravaged the world. A platform to fastly generate vaccines inducing potent and durable neutralizing antibody and T cell responses is sorely needed. Bioinformatically identified epitope-based vaccines can focus on immunodominant T cell epitopes and induce more potent immune responses than a whole antigen vaccine and may be deployed more rapidly and less costly than whole-gene vaccines. Increasing evidence has shown the importance of the CD4+ T cell response in protection against HIV and other viral infections. The previously described DNA vaccine HIVBr18 encodes 18 conserved, promiscuous epitopes binding to multiple HLA-DR-binding HIV epitopes amply recognized by HIV-1-infected patients. HIVBr18 elicited broad, polyfunctional, and durable CD4+and CD8+ T cell responses in BALB/c and mice transgenic to HLA class II alleles, showing cross-species promiscuity. To fully delineate the promiscuity of the HLA class II vaccine epitopes, we assessed their binding to 34 human class II (HLA-DR, DQ, and -DP) molecules, and immunized nonhuman primates. Results ascertained redundant 100% coverage of the human population for multiple peptides. We then immunized Rhesus macaques with HIVBr18 under in vivo electroporation. The immunization induced strong, predominantly polyfunctional CD4+ T cell responses in all animals to 13 out of the 18 epitopes; T cells from each animal recognized 7-11 epitopes. Our results provide a preliminary proof of concept that immunization with a vaccine encoding epitopes with high and redundant coverage of the human population can elicit potent T cell responses to multiple epitopes, across species and MHC barriers. This approach may facilitate the rapid deployment of immunogens eliciting cellular immunity against emerging infectious diseases, such as COVID-19.

First-year students' perceptions of team-based learning in a new medical genetics course / Percepção dos alunos do primeiro ano sobre a aprendizagem baseada em equipes em um novo curso de genética médica

ABSTRACT Background Medical education has evolved considerably over the last few years, especially through adoption of new technologies and active methodologies. These methodologies aim to improve learning and engage students deeply in the process. TBL is a methodology widely used in health schools, including Medical Schools. We can use it to work with large groups, divided into small teams. The students first work individually, then within teams, and finally the groups cooperate to solve applied problems. Objectives To describe students' perceptions and satisfaction about a Medical Genetics course organized into blocks of subject in which we used TBL sessions with first-year medical students. Methods A Medical Genetics course were organized into subject blocks in which a TBL session was conducted in each of these blocks to improve the learning process. At the end of the course, the students answered a questionnaire on satisfaction and perceptions. Results By the first time we described a Medical Genetics course organized into 5 blocks of subject matter on a total of 25 genetic diseases in which a TBL session was conducted in each of these blocks. We enrolled a total of 290 participants and 96% of the students were satisfied with TBL. Furthermore, 97% of students believe that TBL helped them to learn, and 87% approved of use of TBL in the future at other stages of their medical course. Conclusion Application of the TBL method during a medical genetics course was well-received by students and proved an important tool in the structures of curricula for medical education at this university.

RESUMO Introdução A educação médica evoluiu consideravelmente nos últimos anos, especialmente através da adoção de novas tecnologias e metodologias ativas. Essas metodologias visam melhorar a aprendizagem e envolver os alunos profundamente no processo. O TBL é uma metodologia amplamente utilizada em escolas de saúde, incluindo escolas médicas. Podemos usá-lo para trabalhar com grandes grupos, divididos em pequenas equipes. Primeiro, os alunos trabalham individualmente, depois dentro das equipes e, finalmente, os grupos cooperam para resolver os problemas aplicados. Objetivos Descrever as percepções e a satisfação dos alunos em relação a um curso de Genética Médica organizado em blocos de assuntos em que utilizamos sessões de TBL com estudantes de medicina do primeiro ano. Métodos Um curso de Genética Médica foi organizado em blocos de assuntos em que uma sessão de TBL foi realizada em cada um desses blocos para melhorar o processo de aprendizagem. No final do curso, os alunos responderam a um questionário sobre satisfação e percepções. Resultados Pela primeira vez nós descrevemos um curso de Genética Médica organizado em 5 blocos de assuntos, compreendendo 25 doenças genéticas, nos quais, uma sessão de TBL foi conduzida em cada um desses blocos. Participaram um total de 290 alunos, dos quais 96% estavam satisfeitos com o método de TBL. Além disso, 97% dos estudantes acreditam que o TBL os ajudou a aprender, e 87% aprovaram o uso do TBL no futuro, em outras etapas de seu curso de medicina. Conclusão A aplicação do método TBL durante um curso de genética médica foi bem recebida pelos estudantes e se mostrou uma ferramenta importante na estruturação curricular para a educação médica nesta universidade.

Co-administration of plasmid-encoded granulocyte-macrophage colony-stimulating factor increases human immunodeficiency virus-1 DNA vaccine-induced polyfunctional CD4+ T-cell responses

T-cell based vaccines against human immunodeficiency virus (HIV) generate specific responses that may limit both transmission and disease progression by controlling viral load. Broad, polyfunctional, and cytotoxic CD4+T-cell responses have been associated with control of simian immunodeficiency virus/HIV-1 replication, supporting the inclusion of CD4+ T-cell epitopes in vaccine formulations. Plasmid-encoded granulocyte-macrophage colony-stimulating factor (pGM-CSF) co-administration has been shown to induce potent CD4+ T-cell responses and to promote accelerated priming and increased migration of antigen-specific CD4+ T-cells. However, no study has shown whether co-immunisation with pGM-CSF enhances the number of vaccine-induced polyfunctional CD4+ T-cells. Our group has previously developed a DNA vaccine encoding conserved, multiple human leukocyte antigen (HLA)-DR binding HIV-1 subtype B peptides, which elicited broad, polyfunctional and long-lived CD4+ T-cell responses. Here, we show that pGM-CSF co-immunisation improved both magnitude and quality of vaccine-induced T-cell responses, particularly by increasing proliferating CD4+ T-cells that produce simultaneously interferon-γ, tumour necrosis factor-α and interleukin-2. Thus, we believe that the use of pGM-CSF may be helpful for vaccine strategies focused on the activation of anti-HIV CD4+ T-cell immunity.

Co-administration of plasmid-encoded granulocyte-macrophage colony-stimulating factor increases human immunodeficiency virus-1 DNA vaccine-induced polyfunctional CD4+ T-cell responses.

T-cell based vaccines against human immunodeficiency virus (HIV) generate specific responses that may limit both transmission and disease progression by controlling viral load. Broad, polyfunctional, and cytotoxic CD4+T-cell responses have been associated with control of simian immunodeficiency virus/HIV-1 replication, supporting the inclusion of CD4+ T-cell epitopes in vaccine formulations. Plasmid-encoded granulocyte-macrophage colony-stimulating factor (pGM-CSF) co-administration has been shown to induce potent CD4+ T-cell responses and to promote accelerated priming and increased migration of antigen-specific CD4+ T-cells. However, no study has shown whether co-immunisation with pGM-CSF enhances the number of vaccine-induced polyfunctional CD4+ T-cells. Our group has previously developed a DNA vaccine encoding conserved, multiple human leukocyte antigen (HLA)-DR binding HIV-1 subtype B peptides, which elicited broad, polyfunctional and long-lived CD4+ T-cell responses. Here, we show that pGM-CSF co-immunisation improved both magnitude and quality of vaccine-induced T-cell responses, particularly by increasing proliferating CD4+ T-cells that produce simultaneously interferon-γ, tumour necrosis factor-α and interleukin-2. Thus, we believe that the use of pGM-CSF may be helpful for vaccine strategies focused on the activation of anti-HIV CD4+ T-cell immunity.

Multiple Approaches for Increasing the Immunogenicity of an Epitope-Based Anti-HIV Vaccine.

The development of a highly effective vaccine against the human immunodeficiency virus (HIV) will likely be based on rational vaccine design, since traditional vaccine approaches have failed so far. In recent years, an understanding of what type of immune response is protective against infection and/or disease facilitated vaccine design. T cell-based vaccines against HIV have the goal of limiting both transmission and disease progression by inducing broad and functionally relevant T cell responses. In this context, CD4(+) T cells play a direct cytotoxic role and are also important for the generation and maintenance of functional CD8(+) T and B cell responses. The use of MHC-binding algorithms has allowed the identification of novel CD4(+) T cell epitopes that could be used in vaccine design, the so-called epitope-driven vaccine design. Epitope-based vaccines have the ability to focus the immune response on highly antigenic, conserved epitopes that are fully recognized by the target population. We have recently mapped a set of conserved multiple HLA-DR-binding HIV-1 CD4 epitopes and observed interferon (IFN)-γ-producing CD4(+) T cells when we tested these peptides in peripheral blood mononuclear cells (PBMCs) from HIV-infected individuals. We then designed multiepitopic DNA vaccines that induced broad and polyfunctional T cell responses in immunized mice. In this review we will focus on alternative strategies to increase the immunogenicity of an epitope-based vaccine against HIV infection.

Formulação vacinal trivalente voltada para o controle profilático/terapêutico de tumores induzidos pelo vírus do papiloma humano tipo 16 (HPV-16) e infecções pelos vírus da imunodeficiência adquirida (HIV) e herpes vírus humano (HSV) / Trivalent vaccine formulation focused on the prophylactic / therapeutic control of tumors induced by human papillomavirus type 16 (HPV-16) and infection by human immunodeficiency virus (HIV) and human herpes virus (HSV)

As proteínas E7 (HPV), p24 (HIV) e gD (HSV) são exclusivamente expressas por células infectadas ou tumorais e, por isso, são utilizadas como alvos para vacinas com características terapêuticas. Foram desenvolvidas duas vacinas de DNA capazes de expressar as três proteínas virais por meio de um vetor de expressão bicistrônico baseado na sequência IRES. As vacinas, denominadas pIRES I e pIRES II, diferem entre si por transportarem os genes que codificam as proteínas E7 do HPV-16 e p24 do HIV fusionadas à proteína gD do HSV-1 em ordem inversa. Células COS-7 transfectadas com os plasmídeos vacinais expressaram as proteínas alvo, como determinado por imunofluorecência com anticorpos específicos para as proteínas gD, p24 e E7. As vacinas foram testadas em modelo murino quanto à capacidade de gerar anticorpos e células T CD8+ específicas. Observamos que animais vacinados desenvolveram baixas taxas de anticorpos contra gD, p24 e E7. Em contrapartida, demonstramos a indução de células T CD8+ específicas para os três antígenos testados. Os plasmídeos vacinais foram capazes de proteger camundongos inoculados com células tumorais TC-1 (que expressam a proteína E7 do HPV-16), embora apresentando diferentes níveis de proteção em ensaios profiláticos e terapêuticos. As formulações foram testadas em relação à capacidade de proteger animais frente a desafio com o HSV-1 sendo que apenas um deles gerou efeito protetor. Em conclusão, os resultados demonstram que vacinas voltadas para o controle terapêutico de infecções ou processos tumorais associados aos vírus HPV, HIV e HSV representam uma meta viável e promissora

The proteins E7 (HPV), p24 (HIV) and gD (HSV) are exclusively expressed by infected cells or tumors and therefore are used as targets for vaccines with therapeutic characteristics. We developed two DNA vaccines capable of expressing these three viral proteins using a bicistronic expression vector based on IRES sequence. The plasmid vaccines, named pIRES I and pIRES II, differ by carrying the genes that encode proteins of HPV-16 E7 and p24 fused to the HIV protein gD of HSV-1 in reverse order. Transfected COS-7 cells expressed the target proteins, as determined by immunofluorescence with specific antibodies for gD, p24 and E7. The vaccines were tested in mice for their ability to generate antibodies and specific CD8+ T cells. We observed that vaccinated animals developed low levels of antibodies against gD, E7 and p24. In contrast, we demonstrate the induction of specific CD8+ T cells for the three antigens. The plasmid vaccines were able to protect mice inoculated with TC-1 tumor cells (which express the E7 protein of HPV-16), although with different levels of protection in prophylactic and therapeutic trials. The formulations were tested for ability to protect animals against challenge with HSV-1 and only one of them generated a protective effect. In conclusion, the results show that vaccines directed to therapeutic control of infections or tumor process associated with HPV, HSV or HIV represents a promising and viable goal

Broad and cross-clade CD4+ T-cell responses elicited by a DNA vaccine encoding highly conserved and promiscuous HIV-1 M-group consensus peptides.

T-cell based vaccine approaches have emerged to counteract HIV-1/AIDS. Broad, polyfunctional and cytotoxic CD4(+) T-cell responses have been associated with control of HIV-1 replication, which supports the inclusion of CD4(+) T-cell epitopes in vaccines. A successful HIV-1 vaccine should also be designed to overcome viral genetic diversity and be able to confer immunity in a high proportion of immunized individuals from a diverse HLA-bearing population. In this study, we rationally designed a multiepitopic DNA vaccine in order to elicit broad and cross-clade CD4(+) T-cell responses against highly conserved and promiscuous peptides from the HIV-1 M-group consensus sequence. We identified 27 conserved, multiple HLA-DR-binding peptides in the HIV-1 M-group consensus sequences of Gag, Pol, Nef, Vif, Vpr, Rev and Vpu using the TEPITOPE algorithm. The peptides bound in vitro to an average of 12 out of the 17 tested HLA-DR molecules and also to several molecules such as HLA-DP, -DQ and murine IA(b) and IA(d). Sixteen out of the 27 peptides were recognized by PBMC from patients infected with different HIV-1 variants and 72% of such patients recognized at least 1 peptide. Immunization with a DNA vaccine (HIVBr27) encoding the identified peptides elicited IFN-γ secretion against 11 out of the 27 peptides in BALB/c mice; CD4(+) and CD8(+) T-cell proliferation was observed against 8 and 6 peptides, respectively. HIVBr27 immunization elicited cross-clade T-cell responses against several HIV-1 peptide variants. Polyfunctional CD4(+) and CD8(+) T cells, able to simultaneously proliferate and produce IFN-γ and TNF-α, were also observed. This vaccine concept may cope with HIV-1 genetic diversity as well as provide increased population coverage, which are desirable features for an efficacious strategy against HIV-1/AIDS.