Your search keyword '"Baharom, Faezzah"' showing total 40 results

1. Vax-Innate: improving therapeutic cancer vaccines by modulating T cells and the tumour microenvironment

Author

Baharom, Faezzah, Hermans, Dalton, Delamarre, Lélia, and Seder, Robert A.

Published

2024

2. Intravenous heterologous prime-boost vaccination activates innate and adaptive immunity to promote tumor regression

Author

Ramirez-Valdez, Ramiro A., Baharom, Faezzah, Khalilnezhad, Ahad, Fussell, Sloane C., Hermans, Dalton J., Schrager, Alexander M., Tobin, Kennedy K.S., Lynn, Geoffrey M., Khalilnezhad, Shabnam, Ginhoux, Florent, Van den Eynde, Benoit J., Leung, Carol Sze Ki, Ishizuka, Andrew S., and Seder, Robert A.

Published

2023

3. Supplementary Figure 4 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

4. Supplementary Figure 6 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

5. Supplementary Table 2 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

6. Data from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

7. Supplementary Figure 5 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

8. Supplementary Figure 3 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

9. Supplementary Table 1 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

10. Supplementary Figure 1 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

11. Supplementary Figure 2 from The Exonuclease TREX1 Constitutes an Innate Immune Checkpoint Limiting cGAS/STING-Mediated Antitumor Immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, primary, Williams, Katherine, primary, Silva, John, primary, Gutierrez, Alan G., primary, Tyler, Paul, primary, Baharom, Faezzah, primary, Sun, Tao, primary, Lin, Eva, primary, Martin, Scott, primary, Kayser, Brandon D., primary, Johnston, Robert J., primary, Mellman, Ira, primary, Delamarre, Lélia, primary, West, Nathaniel R., primary, Müller, Sören, primary, Qu, Yan, primary, and Heger, Klaus, primary

Published

2024

12. The exonuclease TREX1 constitutes an innate immune checkpoint limiting cGAS/STING-mediated antitumor immunity

Author

Lim, Junghyun, primary, Rodriguez, Ryan, additional, Williams, Katherine, additional, Silva, John, additional, Gutierrez, Alan G., additional, Tyler, Paul, additional, Baharom, Faezzah, additional, Sun, Tao, additional, Lin, Eva, additional, Martin, Scott, additional, Kayser, Brandon D., additional, Johnston, Robert J., additional, Mellman, Ira, additional, Delamarre, Lélia, additional, West, Nathaniel R., additional, Müller, Sören, additional, Qu, Yan, additional, and Heger, Klaus, additional

Published

2024

13. Intravenous nanoparticle vaccination generates stem-like TCF1+ neoantigen-specific CD8+ T cells

Author

Baharom, Faezzah, Ramirez-Valdez, Ramiro A., Tobin, Kennedy K. S., Yamane, Hidehiro, Dutertre, Charles-Antoine, Khalilnezhad, Ahad, Reynoso, Glennys V., Coble, Vincent L., Lynn, Geoffrey M., Mulè, Matthew P., Martins, Andrew J., Finnigan, John P., Zhang, Xiao Meng, Hamerman, Jessica A., Bhardwaj, Nina, Tsang, John S., Hickman, Heather D., Ginhoux, Florent, Ishizuka, Andrew S., and Seder, Robert A.

Published

2021

14. Peptide–TLR-7/8a conjugate vaccines chemically programmed for nanoparticle self-assembly enhance CD8 T-cell immunity to tumor antigens

Author

Lynn, Geoffrey M., Sedlik, Christine, Baharom, Faezzah, Zhu, Yaling, Ramirez-Valdez, Ramiro A., Coble, Vincent L., Tobin, Kennedy, Nichols, Sarah R., Itzkowitz, Yaakov, Zaidi, Neeha, Gammon, Joshua M., Blobel, Nicolas J., Denizeau, Jordan, de la Rochere, Philippe, Francica, Brian J., Decker, Brennan, Maciejewski, Mateusz, Cheung, Justin, Yamane, Hidehiro, Smelkinson, Margery G., Francica, Joseph R., Laga, Richard, Bernstock, Joshua D., Seymour, Leonard W., Drake, Charles G., Jewell, Christopher M., Lantz, Olivier, Piaggio, Eliane, Ishizuka, Andrew S., and Seder, Robert A.

Published

2020

15. Dynamic Changes in Resident and Infiltrating Epidermal Dendritic Cells in Active and Resolved Psoriasis

Author

Martini, Elisa, Wikén, Maria, Cheuk, Stanley, Gallais Sérézal, Irène, Baharom, Faezzah, Ståhle, Mona, Smed-Sörensen, Anna, and Eidsmo, Liv

Published

2017

16. Systemic vaccination induces CD8+ T cells and remodels the tumor microenvironment

Author

Baharom, Faezzah, primary, Ramirez-Valdez, Ramiro A., additional, Khalilnezhad, Ahad, additional, Khalilnezhad, Shabnam, additional, Dillon, Marlon, additional, Hermans, Dalton, additional, Fussell, Sloane, additional, Tobin, Kennedy K.S., additional, Dutertre, Charles-Antoine, additional, Lynn, Geoffrey M., additional, Müller, Sören, additional, Ginhoux, Florent, additional, Ishizuka, Andrew S., additional, and Seder, Robert A., additional

Published

2022

17. Intravenous Vaccination Induces CD8 + T Cells and Type I IFN-Dependent Remodeling of the Tumor Microenvironment

Author

Baharom, Faezzah, primary, Ramirez-Valdez, Ramiro Andrei, additional, Khalilnezhad, Ahad, additional, Khalilnezhad, Shabnam, additional, Dillon, Marlon, additional, Hermans, Dalton, additional, Fussell, Sloane, additional, Tobin, Kennedy K.S., additional, Dutertre, Charles-Antoine, additional, Lynn, Geoffrey M., additional, Ginhoux, Florent, additional, Ishizuka, Andrew, additional, and Seder, Robert A., additional

Published

2022

18. Monocytes in sarcoidosis are potent tumour necrosis factor producers and predict disease outcome

Author

Lepzien, Rico, Liu, Sang, Czarnewski, Paulo, Nie, Mu, Österberg, Björn, Baharom, Faezzah, Pourazar, Jamshid, Rankin, Gregory, Eklund, Anders, Bottai, Matteo, Kullberg, Susanna, Blomberg, Anders, Grunewald, Johan, and Smed-Sörensen, Anna

Subjects

Sarcoidosis, Sarcoidosis, Pulmonary, Tumor Necrosis Factor-alpha, Respiratory Medicine and Allergy, Original Research Articles, Humans, Interstitial Lung Disease, Bronchoalveolar Lavage Fluid, Monocytes, Lungmedicin och allergi

Abstract

Background Pulmonary sarcoidosis is an inflammatory disease characterised by granuloma formation and heterogeneous clinical outcome. Tumour necrosis factor (TNF) is a pro-inflammatory cytokine contributing to granuloma formation and high levels of TNF have been shown to associate with progressive disease. Mononuclear phagocytes (MNPs) are potent producers of TNF and highly responsive to inflammation. In sarcoidosis, alveolar macrophages have been well studied. However, MNPs also include monocytes/monocyte-derived cells and dendritic cells, which are poorly studied in sarcoidosis, despite their central role in inflammation. Objective To determine the role of pulmonary monocyte-derived cells and dendritic cells during sarcoidosis. Methods We performed in-depth phenotypic, functional and transcriptomic analysis of MNP subsets from blood and bronchoalveolar lavage (BAL) fluid from 108 sarcoidosis patients and 30 healthy controls. We followed the clinical development of patients and assessed how the repertoire and function of MNP subsets at diagnosis correlated with 2-year disease outcome. Results Monocytes/monocyte-derived cells were increased in blood and BAL of sarcoidosis patients compared to healthy controls. Interestingly, high frequencies of blood intermediate monocytes at time of diagnosis associated with chronic disease development. RNA sequencing analysis showed highly inflammatory MNPs in BAL of sarcoidosis patients. Furthermore, frequencies of BAL monocytes/monocyte-derived cells producing TNF without exogenous stimulation at time of diagnosis increased in patients that were followed longitudinally. In contrast to alveolar macrophages, the frequency of TNF-producing BAL monocytes/monocyte-derived cells at time of diagnosis was highest in sarcoidosis patients that developed progressive disease. Conclusion Our data show that pulmonary monocytes/monocyte-derived cells are highly inflammatory and can be used as a predictor of disease outcome in sarcoidosis patients., Phenotypic, transcriptomic and functional mapping of blood and pulmonary mononuclear phagocytes in sarcoidosis patients found that frequency and function of pulmonary monocytes at time of diagnosis predict 2-year outcome in sarcoidosis https://bit.ly/2JX8fhr

Published

2021

19. Monocytes in sarcoidosis are potent TNF producers and predict disease outcome

Author

Lepzien, Rico, primary, Liu, Sang, additional, Czarnewski, Paulo, additional, Nie, Mu, additional, Österberg, Björn, additional, Baharom, Faezzah, additional, Pourazar, Jamshid, additional, Rankin, Gregory, additional, Eklund, Anders, additional, Bottai, Matteo, additional, Kullberg, Susanna, additional, Blomberg, Anders, additional, Grunewald, Johan, additional, and Smed-Sörensen, Anna, additional

Published

2021

20. Intravenous nanoparticle vaccination generates stem-like TCF1+ neoantigen-specific CD8+ T cells

Author

Baharom, Faezzah, primary, Ramirez-Valdez, Ramiro A., additional, Tobin, Kennedy K. S., additional, Yamane, Hidehiro, additional, Dutertre, Charles-Antoine, additional, Khalilnezhad, Ahad, additional, Reynoso, Glennys V., additional, Coble, Vincent L., additional, Lynn, Geoffrey M., additional, Mulè, Matthew P., additional, Martins, Andrew J., additional, Finnigan, John P., additional, Zhang, Xiao Meng, additional, Hamerman, Jessica A., additional, Bhardwaj, Nina, additional, Tsang, John S., additional, Hickman, Heather D., additional, Ginhoux, Florent, additional, Ishizuka, Andrew S., additional, and Seder, Robert A., additional

Published

2020

21. Human Blood and Tonsil Plasmacytoid Dendritic Cells Display Similar Gene Expression Profiles but Exhibit Differential Type I IFN Responses to Influenza A Virus Infection

Author

Vangeti, Sindhu, Gertow, Jens, Yu, Meng, Liu, Sang, Baharom, Faezzah, Scholz, Saskia, Friberg, Danielle, Starkhammar, Magnus, Ahlberg, Alexander, Smed-Sörensen, Anna, Vangeti, Sindhu, Gertow, Jens, Yu, Meng, Liu, Sang, Baharom, Faezzah, Scholz, Saskia, Friberg, Danielle, Starkhammar, Magnus, Ahlberg, Alexander, and Smed-Sörensen, Anna

Abstract

Influenza A virus (IAV) infection constitutes an annual health burden across the globe. Plasmacytoid dendritic cells (PDCs) are central in antiviral defense because of their superior capacity to produce type I IFNs in response to viruses. Dendritic cells (DCs) differ depending on their anatomical location. However, only limited host-pathogen data are available from the initial site of infection in humans. In this study, we investigated how human tonsil PDCs, likely exposed to virus because of their location, responded to IAV infection compared with peripheral blood PDCs. In tonsils, unlike in blood, PDCs are the most frequent DC subset. Both tonsil and blood PDCs expressed several genes necessary for pathogen recognition and immune response, generally in a similar pattern. MxA, a protein that renders cells resistant to IAV infection, was detected in both tonsil and blood PDCs. However, despite steady-state MxA expression and contrary to previous reports, at high IAV concentrations (typically cytopathic to other immune cells), both tonsil and blood PDCs supported IAV infection. IAV exposure resulted in PDC maturation by upregulation of CD86 expression and IFN-alpha secretion. Interestingly, blood PDCs secreted 10-fold more IFN-alpha in response to IAV compared with tonsil PDCs. Tonsil PDCs also had a dampened cytokine response to purified TLR ligands compared with blood PDCs. Our findings suggest that tonsil PDCs may be less responsive to IAV than blood PDCs, highlighting the importance of studying immune cells at their proposed site of function.

Published

2019

22. Star nanoparticles delivering HIV-1 peptide minimal immunogens elicit near-native envelope antibody responses in nonhuman primates

Author

Francica, Joseph R., primary, Laga, Richard, additional, Lynn, Geoffrey M., additional, Mužíková, Gabriela, additional, Androvič, Ladislav, additional, Aussedat, Baptiste, additional, Walkowicz, William E., additional, Padhan, Kartika, additional, Ramirez-Valdez, Ramiro Andrei, additional, Parks, Robert, additional, Schmidt, Stephen D., additional, Flynn, Barbara J., additional, Tsybovsky, Yaroslav, additional, Stewart-Jones, Guillaume B. E., additional, Saunders, Kevin O., additional, Baharom, Faezzah, additional, Petrovas, Constantinos, additional, Haynes, Barton F., additional, and Seder, Robert A., additional

Published

2019

23. Human Blood and Tonsil Plasmacytoid Dendritic Cells Display Similar Gene Expression Profiles but Exhibit Differential Type I IFN Responses to Influenza A Virus Infection

Author

Vangeti, Sindhu, primary, Gertow, Jens, additional, Yu, Meng, additional, Liu, Sang, additional, Baharom, Faezzah, additional, Scholz, Saskia, additional, Friberg, Danielle, additional, Starkhammar, Magnus, additional, Ahlberg, Alexander, additional, and Smed-Sörensen, Anna, additional

Published

2019

24. Abstract IA29: Peptide-TLR-7/8 agonist conjugate vaccines chemically programmed for nanoparticle self-assembly to enhance the magnitude and breadth of anticancer neoantigen CD8 T cell immunity

Author

Lynn, Geoffrey M., primary, Baharom, Faezzah, additional, Zhu, Yaling, additional, Coble, Vincent, additional, Ramirez-Valdez, Andrei, additional, Yamane, Hide, additional, Tobin, Kennedy, additional, Decker, Brennan, additional, Ishizuka, Andrew, additional, and Seder, Robert, additional

Published

2019

25. Impact of Polymer-TLR-7/8 Agonist (Adjuvant) Morphology on the Potency and Mechanism of CD8 T Cell Induction

Author

Lynn, Geoffrey M., primary, Chytil, Petr, additional, Francica, Joseph R., additional, Lagová, Anna, additional, Kueberuwa, Gray, additional, Ishizuka, Andrew S., additional, Zaidi, Neeha, additional, Ramirez-Valdez, Ramiro A., additional, Blobel, Nicolas J., additional, Baharom, Faezzah, additional, Leal, Joseph, additional, Wang, Amy Q., additional, Gerner, Michael Y., additional, Etrych, Tomáš, additional, Ulbrich, Karel, additional, Seymour, Leonard W., additional, Seder, Robert A., additional, and Laga, Richard, additional

Published

2019

26. Dynamic changes in resident and infiltrating epidermal dendritic cells in active and resolved psoriasis

Author

Martini, Elisa, Wiken, Maria, Cheuk, Stanley, Gallais Sérézal, Irène, Baharom, Faezzah, Ståhle, Mona, Smed-Sörensen, Anna, and Eidsmo, Liv

Subjects

Cell Biology, Dermatology, Biochemistry, Molecular Biology

Published

2016

27. Human Lung Mononuclear Phagocytes in Health and Disease

Author

Baharom, Faezzah, Rankin, Gregory, Blomberg, Anders, Smed-Sorensen, Anna, Baharom, Faezzah, Rankin, Gregory, Blomberg, Anders, and Smed-Sorensen, Anna

Abstract

The lungs are vulnerable to attack by respiratory insults such as toxins, allergens, and pathogens, given their continuous exposure to the air we breathe. Our immune system has evolved to provide protection against an array of potential threats without causing collateral damage to the lung tissue. In order to swiftly detect invading pathogens, monocytes, macrophages, and dendritic cells (DCs)-together termed mononuclear phagocytes (MNPs)-line the respiratory tract with the key task of surveying the lung microenvironment in order to discriminate between harmless and harmful antigens and initiate immune responses when necessary. Each cell type excels at specific tasks: monocytes produce large amounts of cytokines, macrophages are highly phagocytic, whereas DCs excel at activating naive T cells. Extensive studies in murine models have established a division of labor between the different populations of MNPs at steady state and during infection or inflammation. However, a translation of important findings in mice is only beginning to be explored in humans, given the challenge of working with rare cells in inaccessible human tissues. Important progress has been made in recent years on the phenotype and function of human lung MNPs. In addition to a substantial population of alveolar macrophages, three subsets of DCs have been identified in the human airways at steady state. More recently, monocyte-derived cells have also been described in healthy human lungs. Depending on the source of samples, such as lung tissue resections or bronchoalveolar lavage, the specific subsets of MNPs recovered may differ. This review provides an update on existing studies investigating human respiratory MNP populations during health and disease. Often, inflammatory MNPs are found to accumulate in the lungs of patients with pulmonary conditions. In respiratory infections or inflammatory diseases, this may contribute to disease severity, but in cancer patients this may improve clinical outcomes

Published

2017

28. Human lung dendritic cells : spatial distribution and phenotypic identification in endobronchial biopsies using immunohistochemistry and flow cytometry

Author

Baharom, Faezzah, Rankin, Gregory, Scholz, Saskia, Pourazar, Jamshid, Ahlm, Clas, Blomberg, Anders, Smed-Sörensen, Anna, Baharom, Faezzah, Rankin, Gregory, Scholz, Saskia, Pourazar, Jamshid, Ahlm, Clas, Blomberg, Anders, and Smed-Sörensen, Anna

Abstract

The lungs are constantly exposed to the external environment, which in addition to harmless particles, also contains pathogens, allergens, and toxins. In order to maintain tolerance or to induce an immune response, the immune system must appropriately handle inhaled antigens. Lung dendritic cells (DCs) are essential in maintaining a delicate balance to initiate immunity when required without causing collateral damage to the lungs due to an exaggerated inflammatory response. While there is a detailed understanding of the phenotype and function of immune cells such as DCs in human blood, the knowledge of these cells in less accessible tissues, such as the lungs, is much more limited, since studies of human lung tissue samples, especially from healthy individuals, are scarce. This work presents a strategy to generate detailed spatial and phenotypic characterization of lung tissue resident DCs in healthy humans that undergo a bronchoscopy for the sampling of endobronchial biopsies. Several small biopsies can be collected from each individual and can be subsequently embedded for ultrafine sectioning or enzymatically digested for advanced flow cytometric analysis. The outlined protocols have been optimized to yield maximum information from small tissue samples that, under steady-state conditions, contain only a low frequency of DCs. While the present work focuses on DCs, the methods described can directly be expanded to include other (immune) cells of interest found in mucosal lung tissue. Furthermore, the protocols are also directly applicable to samples obtained from patients suffering from pulmonary diseases where bronchoscopy is part of establishing the diagnosis, such as chronic obstructive pulmonary disease (COPD), sarcoidosis, or lung cancer.

Published

2017

29. Human hantavirus infection elicits pronounced redistribution of mononuclear phagocytes in peripheral blood and airways

Author

Scholz, Saskia, Baharom, Faezzah, Rankin, Gregory, Maleki, Kimia T., Gupta, Shawon, Vangeti, Sindhu, Pourazar, Jamshid, Discacciati, Andrea, Höijer, Jonas, Bottai, Matteo, Björkström, Niklas K., Rasmuson, Johan, Evander, Magnus, Blomberg, Anders, Ljunggren, Hans-Gustaf, Klingström, Jonas, Ahlm, Clas, Smed-Sörensen, Anna, Scholz, Saskia, Baharom, Faezzah, Rankin, Gregory, Maleki, Kimia T., Gupta, Shawon, Vangeti, Sindhu, Pourazar, Jamshid, Discacciati, Andrea, Höijer, Jonas, Bottai, Matteo, Björkström, Niklas K., Rasmuson, Johan, Evander, Magnus, Blomberg, Anders, Ljunggren, Hans-Gustaf, Klingström, Jonas, Ahlm, Clas, and Smed-Sörensen, Anna

Abstract

Hantaviruses infect humans via inhalation of virus-contaminated rodent excreta. Infection can cause severe disease with up to 40% mortality depending on the viral strain. The virus primarily targets the vascular endothelium without direct cytopathic effects. Instead, exaggerated immune responses may inadvertently contribute to disease development. Mononuclear phagocytes (MNPs), including monocytes and dendritic cells (DCs), orchestrate the adaptive immune responses. Since hantaviruses are transmitted via inhalation, studying immunological events in the airways is of importance to understand the processes leading to immunopathogenesis. Here, we studied 17 patients infected with Puumala virus that causes a mild form of hemorrhagic fever with renal syndrome (HFRS). Bronchial biopsies as well as longitudinal blood draws were obtained from the patients. During the acute stage of disease, a significant influx of MNPs expressing HLA-DR, CD11c or CD123 was detected in the patients' bronchial tissue. In parallel, absolute numbers of MNPs were dramatically reduced in peripheral blood, coinciding with viremia. Expression of CCR7 on the remaining MNPs in blood suggested migration to peripheral and/or lymphoid tissues. Numbers of MNPs in blood subsequently normalized during the convalescent phase of the disease when viral RNA was no longer detectable in plasma. Finally, we exposed blood MNPs in vitro to Puumala virus, and demonstrated an induction of CCR7 expression on MNPs. In conclusion, the present study shows a marked redistribution of blood MNPs to the airways during acute hantavirus disease, a process that may underlie the local immune activation and contribute to immunopathogenesis in hantavirus-infected patients.

Published

2017

30. Intravenous nanoparticle vaccination generates stem-like TCF1+neoantigen-specific CD8+T cells

Author

Baharom, Faezzah, Ramirez-Valdez, Ramiro A., Tobin, Kennedy K. S., Yamane, Hidehiro, Dutertre, Charles-Antoine, Khalilnezhad, Ahad, Reynoso, Glennys V., Coble, Vincent L., Lynn, Geoffrey M., Mulè, Matthew P., Martins, Andrew J., Finnigan, John P., Zhang, Xiao Meng, Hamerman, Jessica A., Bhardwaj, Nina, Tsang, John S., Hickman, Heather D., Ginhoux, Florent, Ishizuka, Andrew S., and Seder, Robert A.

Abstract

Personalized cancer vaccines are a promising approach for inducing T cell immunity to tumor neoantigens. Using a self-assembling nanoparticle vaccine that links neoantigen peptides to a Toll-like receptor 7/8 agonist (SNP-7/8a), we show how the route and dose alter the magnitude and quality of neoantigen-specific CD8+T cells. Intravenous vaccination (SNP-IV) induced a higher proportion of TCF1+PD-1+CD8+T cells as compared to subcutaneous immunization (SNP-SC). Single-cell RNA sequencing showed that SNP-IV induced stem-like genes (Tcf7, Slamf6, Xcl1) whereas SNP-SC enriched for effector genes (Gzmb, Klrg1, Cx3cr1). Stem-like cells generated by SNP-IV proliferated and differentiated into effector cells upon checkpoint blockade, leading to superior antitumor response as compared to SNP-SC in a therapeutic model. The duration of antigen presentation by dendritic cells controlled the magnitude and quality of CD8+T cells. These data demonstrate how to optimize antitumor immunity by modulating vaccine parameters for specific generation of effector or stem-like CD8+T cells.

Published

2021

31. Human hantavirus infection elicits pronounced redistribution of mononuclear phagocytes in peripheral blood and airways

Author

Scholz, Saskia, primary, Baharom, Faezzah, additional, Rankin, Gregory, additional, Maleki, Kimia T., additional, Gupta, Shawon, additional, Vangeti, Sindhu, additional, Pourazar, Jamshid, additional, Discacciati, Andrea, additional, Höijer, Jonas, additional, Bottai, Matteo, additional, Björkström, Niklas K., additional, Rasmuson, Johan, additional, Evander, Magnus, additional, Blomberg, Anders, additional, Ljunggren, Hans-Gustaf, additional, Klingström, Jonas, additional, Ahlm, Clas, additional, and Smed-Sörensen, Anna, additional

Published

2017

32. Visualization of early influenza A virus trafficking in human dendritic cells using STED microscopy

Author

Baharom, Faezzah, primary, Thomas, Oliver S., additional, Lepzien, Rico, additional, Mellman, Ira, additional, Chalouni, Cécile, additional, and Smed-Sörensen, Anna, additional

Published

2017

33. Human Lung Mononuclear Phagocytes in Health and Disease

Author

Baharom, Faezzah, primary, Rankin, Gregory, additional, Blomberg, Anders, additional, and Smed-Sörensen, Anna, additional

Published

2017

34. Human Lung Dendritic Cells: Spatial Distribution and Phenotypic Identification in Endobronchial Biopsies Using Immunohistochemistry and Flow Cytometry

Author

Baharom, Faezzah, primary, Rankin, Gregory, primary, Scholz, Saskia, primary, Pourazar, Jamshid, primary, Ahlm, Clas, primary, Blomberg, Anders, primary, and Smed-Sörensen, Anna, primary

Published

2017

35. Human dendritic cells in blood and airways during respiratory viral infection

Author

Baharom, Faezzah and Baharom, Faezzah

Abstract

The air we inhale contains oxygen necessary for life, but also potentially harmful microorganisms, toxins and allergens. This presents an important immunological dilemma: how can our lungs quickly and selectively eliminate harmful agents without inflicting damage on the delicate tissues of the lungs? We have thus evolved a network of cells involved in immune surveillance, made up of dendritic cells (DCs), monocytes and macrophages. Together, these mononuclear phagocytes sample the lungs and airways for presence of foreign pathogens such as viruses or bacteria. Recognition of pathogenic patterns – for instance the genetic material of viruses or the lipid membrane of bacteria – triggers a cascade of events in these immune cells. They produce inflammatory mediators to signal that a source of danger has been detected, and to contain the infection while awaiting the arrival of other immune cells. DCs migrate to lymphoid organs where they present antigens to naïve T cells, thus shaping the generation of protective and adaptive immunity. Much of what we know of how our immune system functions come from studies in murine models. In this thesis, we focus our attention on human DCs. Using super resolution microscopy, we assessed the early trafficking events that take place upon internalisation of influenza A virus (IAV) by human DCs. We report that IAV trafficked via early and late endosomes in DCs, similar to epithelial cells, but with more delayed kinetics. Next, we investigated whether maturation of monocyte-derived versus bona fide DCs affects their susceptibility to IAV infection. Indeed, the two subsets of DCs are inherently different in their ability to respond to pathogenic signals by producing antiviral mediators, which protect them from IAV infection. The accessibility of human blood has improved our understanding of human DCs. However, immune cells residing at mucosal barriers are our first line of defence against respiratory viruses. Increasing data suggest that t

Published

2016

36. Dendritic Cells and Monocytes with Distinct Inflammatory Responses Reside in Lung Mucosa of Healthy Humans

Author

Baharom, Faezzah, Thomas, Saskia, Rankin, Gregory, Lepzien, Rico, Pourazar, Jamshid, Behndig, Annelie F., Ahlm, Clas, Blomberg, Anders, Smed-Sorensen, Anna, Baharom, Faezzah, Thomas, Saskia, Rankin, Gregory, Lepzien, Rico, Pourazar, Jamshid, Behndig, Annelie F., Ahlm, Clas, Blomberg, Anders, and Smed-Sorensen, Anna

Abstract

Every breath we take contains potentially harmful pathogens or allergens. Dendritic cells (DCs), monocytes, and macrophages are essential in maintaining a delicate balance of initiating immunity without causing collateral damage to the lungs because of an exaggerated inflammatory response. To document the diversity of lung mononuclear phagocytes at steady-state, we performed bronchoscopies on 20 healthy subjects, sampling the proximal and distal airways (bronchial wash and bronchoalveolar lavage, respectively), as well as mucosal tissue (endobronchial biopsies). In addition to a substantial population of alveolar macrophages, we identified subpopulations of monocytes, myeloid DCs (MDCs), and plasmacytoid DCs in the lung mucosa. Intermediate monocytes and MDCs were highly frequent in the airways compared with peripheral blood. Strikingly, the density of mononuclear phagocytes increased upon descending the airways. Monocytes from blood and airways produced 10-fold more proinflammatory cytokines than MDCs upon ex vivo stimulation. However, airway monocytes were less inflammatory than blood monocytes, suggesting a more tolerant nature. The findings of this study establish how to identify human lung mononuclear phagocytes and how they function in normal conditions, so that dysregulations in patients with respiratory diseases can be detected to elucidate their contribution to immunity or pathogenesis.

Published

2016

37. Dendritic Cells and Monocytes with Distinct Inflammatory Responses Reside in Lung Mucosa of Healthy Humans

Author

Baharom, Faezzah, primary, Thomas, Saskia, additional, Rankin, Gregory, additional, Lepzien, Rico, additional, Pourazar, Jamshid, additional, Behndig, Annelie F., additional, Ahlm, Clas, additional, Blomberg, Anders, additional, and Smed-Sörensen, Anna, additional

Published

2016

38. Protection of Human Myeloid Dendritic Cell Subsets against Influenza A Virus Infection Is Differentially Regulated upon TLR Stimulation

Author

Baharom, Faezzah, primary, Thomas, Saskia, additional, Bieder, Andrea, additional, Hellmér, Maria, additional, Volz, Julia, additional, Sandgren, Kerrie J., additional, McInerney, Gerald M., additional, Karlsson Hedestam, Gunilla B., additional, Mellman, Ira, additional, and Smed-Sörensen, Anna, additional

Published

2015

39. A genetically engineered therapeutic lectin inhibits human influenza A virus infection and sustains robust virus-specific CD8 T cell expansion.

Author

Yu M, Lin A, Baharom F, Li S, Legendre M, Covés-Datson E, Sohlberg E, Schlisio S, Loré K, Markovitz DM, and Smed-Sörensen A

Abstract

Native banana lectin (BanLec) is antiviral but highly mitogenic, which limits its therapeutic value. In contrast, the genetically engineered H84T BanLec (H84T) is not mitogenic but remains effective against influenza A virus (IAV) infection in mouse models. However, the potency and effect of H84T on human immune cells and IAV-specific immune responses is undetermined. We found that H84T efficiently inhibited IAV replication in human dendritic cells (DCs) from blood and tonsils, which preserved DC viability and allowed acquisition and presentation of viral antigen. Consequently, H84T-treated DCs initiated effective expansion of IAV-specific CD8 T cells. Furthermore, H84T preserved the capacity of IAV-exposed DCs to present a second non-IAV antigen and induce robust CD8 T cell expansion. This supports H84T as a potent antiviral in humans as it effectively inhibits IAV infection without disrupting DC function, and preserves induction of antigen-specific adaptive immune responses against diverse antigens, which likely is clinically beneficial.

Published

2024

40. Systemic vaccination induces CD8 + T cells and remodels the tumor microenvironment.

Author

Baharom F, Ramirez-Valdez RA, Khalilnezhad A, Khalilnezhad S, Dillon M, Hermans D, Fussell S, Tobin KKS, Dutertre CA, Lynn GM, Müller S, Ginhoux F, Ishizuka AS, and Seder RA

Subjects

Humans, Mice, Animals, CD8-Positive T-Lymphocytes, Cell Line, Tumor, Immunotherapy methods, Antigens, Neoplasm, Vaccination methods, Adjuvants, Immunologic, Tumor Microenvironment, Cancer Vaccines

Abstract

Therapeutic cancer vaccines are designed to increase tumor-specific T cell immunity. However, suppressive mechanisms within the tumor microenvironment (TME) may limit T cell function. Here, we assessed how the route of vaccination alters intratumoral myeloid cells. Using a self-assembling nanoparticle vaccine that links tumor antigen peptides to a Toll-like receptor 7/8 agonist (SNP-7/8a), we treated tumor-bearing mice subcutaneously (SNP-SC) or intravenously (SNP-IV). Both routes generated antigen-specific CD8 + T cells that infiltrated tumors. However, only SNP-IV mediated tumor regression, dependent on systemic type I interferon at the time of boost. Single-cell RNA-sequencing revealed that intratumoral monocytes expressing an immunoregulatory gene signature (Chil3, Anxa2, Wfdc17) were reduced after SNP-IV boost. In humans, the Chil3 + monocyte gene signature is enriched in CD16 - monocytes and associated with worse outcomes. Our results show that the generation of tumor-specific CD8 + T cells combined with remodeling of the TME is a promising approach for tumor immunotherapy., Competing Interests: Declaration of interests A.S.I., G.M.L., and R.A.S. are listed as inventors on patents describing polymer-based vaccines. A.S.I. and G.M.L. are employees of Vaccitech North America, which is commercializing polymer-based drug delivery technologies for immunotherapeutic applications. F.B. and S.M. are employees of Genentech, a member of the Roche group, which develops and markets drugs for profit., (Published by Elsevier Inc.)

Published

2022