Human dendritic cells in blood and airways during respiratory viral infection
Author: Baharom, Faezzah
Date: 2016-10-21
Location: Rolf Luft Auditorium, L1:00, Karolinska University Hospital, Solna
Time: 14:00
Department: Inst för medicin, Solna / Dept of Medicine, Solna
View/ Open:
Thesis (2.766Mb)
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 there is tissue-specific regulation of immune cells due to factors present in the local microenvironment. Hence, we performed bronchoscopies on healthy subjects and hantavirus-infected patients to characterise DCs residing in the airways and bronchial mucosal tissue. We identified several subsets of respiratory DCs at steady state, alongside alveolar macrophages and monocyte-derived cells. During acute hantavirus disease, DCs and monocytes were depleted from circulation, whereas the lungs were infiltrated with monocytes and DCs.
Collectively, our findings reveal the heterogeneity of human DCs in their response to respiratory viruses, depending on their origin and anatomical location. A deeper understanding of the complex interplay between respiratory viruses and human DCs reveals how DCs contribute to immunity or pathogenesis. This knowledge may help us develop better preventive and therapeutic strategies by targeting or modulating DCs to achieve favourable immune responses.
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 there is tissue-specific regulation of immune cells due to factors present in the local microenvironment. Hence, we performed bronchoscopies on healthy subjects and hantavirus-infected patients to characterise DCs residing in the airways and bronchial mucosal tissue. We identified several subsets of respiratory DCs at steady state, alongside alveolar macrophages and monocyte-derived cells. During acute hantavirus disease, DCs and monocytes were depleted from circulation, whereas the lungs were infiltrated with monocytes and DCs.
Collectively, our findings reveal the heterogeneity of human DCs in their response to respiratory viruses, depending on their origin and anatomical location. A deeper understanding of the complex interplay between respiratory viruses and human DCs reveals how DCs contribute to immunity or pathogenesis. This knowledge may help us develop better preventive and therapeutic strategies by targeting or modulating DCs to achieve favourable immune responses.
List of papers:
I. Faezzah Baharom, Oliver S Thomas, Rico Lepzien, Ira Mellman, Cécile Chalouni and Anna Smed Sörensen. Visualization of early influenza A virus trafficking in human dendritic cells using STED microscopy. [Manuscript]
II. Faezzah Baharom, Saskia Thomas, Andrea Bieder, Maria Hellmér, Julia Volz, Kerrie J Sandgren, Gerald McInerney, Gunilla B Karlsson Hedestam, Ira Mellman and Anna Smed Sörensen. Protection of human myeloid dendritic cell subsets against influenza A virus infection is differentially regulated upon TLR stimulation. J Immunol, 2015 May, 194(9):4422-30.
Fulltext (DOI)
Pubmed
View record in Web of Science®
III. Faezzah Baharom, Saskia Thomas, Gregory Rankin, Rico Lepzien, Jamshid Pourazar, Annelie F Behndig, Clas Ahlm, Anders Blomberg and Anna Smed Sörensen. Dendritic cells and monocytes with distinct inflammatory responses reside in lung mucosa of healthy humans. J Immunol, 2016 June, 196(11):4498-509.
Fulltext (DOI)
Pubmed
View record in Web of Science®
IV. Saskia Scholz, Faezzah Baharom, Gregory Rankin, Kimia T Maleki, Shawon Gupta, Sindhu Vangeti, Magnus Evander, Jamshid Pourazar, Andrea Discacciati, Jonas Höijer, Matteo Bottai, Niklas Björkström, Johan Rasmuson, Hans-Gustaf Ljunggren, Anders Blomberg, Jonas Klingström, Clas Ahlm and Anna Smed Sörensen. Massive depletion of monocytes and dendritic cells in human peripheral blood during acute hantavirus infection. [Manuscript]
I. Faezzah Baharom, Oliver S Thomas, Rico Lepzien, Ira Mellman, Cécile Chalouni and Anna Smed Sörensen. Visualization of early influenza A virus trafficking in human dendritic cells using STED microscopy. [Manuscript]
II. Faezzah Baharom, Saskia Thomas, Andrea Bieder, Maria Hellmér, Julia Volz, Kerrie J Sandgren, Gerald McInerney, Gunilla B Karlsson Hedestam, Ira Mellman and Anna Smed Sörensen. Protection of human myeloid dendritic cell subsets against influenza A virus infection is differentially regulated upon TLR stimulation. J Immunol, 2015 May, 194(9):4422-30.
Fulltext (DOI)
Pubmed
View record in Web of Science®
III. Faezzah Baharom, Saskia Thomas, Gregory Rankin, Rico Lepzien, Jamshid Pourazar, Annelie F Behndig, Clas Ahlm, Anders Blomberg and Anna Smed Sörensen. Dendritic cells and monocytes with distinct inflammatory responses reside in lung mucosa of healthy humans. J Immunol, 2016 June, 196(11):4498-509.
Fulltext (DOI)
Pubmed
View record in Web of Science®
IV. Saskia Scholz, Faezzah Baharom, Gregory Rankin, Kimia T Maleki, Shawon Gupta, Sindhu Vangeti, Magnus Evander, Jamshid Pourazar, Andrea Discacciati, Jonas Höijer, Matteo Bottai, Niklas Björkström, Johan Rasmuson, Hans-Gustaf Ljunggren, Anders Blomberg, Jonas Klingström, Clas Ahlm and Anna Smed Sörensen. Massive depletion of monocytes and dendritic cells in human peripheral blood during acute hantavirus infection. [Manuscript]
Institution: Karolinska Institutet
Supervisor: Smed Sörensen, Anna
Issue date: 2016-09-26
Rights:
Publication year: 2016
ISBN: 978-91-7676-373-5
Statistics
Total Visits
Views | |
---|---|
Human ...(legacy) | 964 |
Human ... | 570 |
Total Visits Per Month
September 2023 | October 2023 | November 2023 | December 2023 | January 2024 | February 2024 | March 2024 | |
---|---|---|---|---|---|---|---|
Human ... | 7 | 4 | 4 | 4 | 5 | 2 | 8 |
File Visits
Views | |
---|---|
Thesis_Faezzah_Baharom.pdf | 1899 |
Thesis_Faezzah_Baharom.pdf(legacy) | 287 |
Top country views
Views | |
---|---|
United States | 477 |
Sweden | 287 |
Germany | 160 |
Singapore | 136 |
China | 61 |
Ireland | 37 |
South Korea | 19 |
United Kingdom | 18 |
Australia | 13 |
Spain | 12 |
Top cities views
Views | |
---|---|
Singapore | 94 |
Ashburn | 44 |
Stockholm | 35 |
Wilmington | 25 |
Kiez | 22 |
Seoul | 19 |
Shenzhen | 19 |
Bethesda | 16 |
Mount Laurel | 15 |
Solna | 10 |