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- Andersson, Anna-Maria, 1990-
(författare)
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Mycobacterium tuberculosis and HIV coinfection : Effects on innate immunity and strategies to boost the immune response
- 2019
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Tuberculosis (TB) still remains a big threat today, being the leading cause of death by a single infectious agent. The TB epidemic is fueled by HIV along with the increasing drug-resistance which prolongs the already long treatment duration and decreases the success rate for curing TB. In most cases an infection results in latency but HIV patients have a 20-30 times higher risk of developing active TB. There are around 36.9 million people living with HIV globally, with the highest burden in Africa. Although there are effective treatments against the disease, there is no cure for AIDS and the availability of the lifelong treatment is limited in low-income countries were the burden is highest. HIV infection causes an immunodeficiency characterized by the progressive loss of CD4 T cells which increases the risk of opportunistic infections, and infection by Mycobacterium tuberculosis (Mtb), the causative agent of TB. Mtb spreads through aerosols from one person with active tuberculosis to a healthy person. Upon inhalation the bacteria are phagocytosed by alveolar macrophages that secrete cytokines and chemokines to recruit more cells, such as dendritic cells, macrophages and lymphocytes, leading to the formation of a granuloma. During a single TB infection the bacteria are usually contained within the granuloma, but HIV can disrupt the stable granuloma, causing a rupture and dissemination of Mtb. This inflammatory site is also beneficial to HIV since it promotes replication of the virus within infected cells. HIV and Mtb are two successful intracellular pathogens able to avoid immune defense mechanisms both of the innate and adaptive immunity in order to persist and replicate. Their virulence factors can manipulate or inhibit cell signaling, phagosome maturation, autophagy, ROS production, apoptosis and antigen presentation, to promote survival. Boosting of immune defenses with host-directed therapies (HDT) has been proposed as a treatment strategy against TB, either alone or adjunctive to the current regimen.In this thesis, ways to boost the innate immune responses in Mtb and HIV coinfected macrophages were investigated, along with studies of the effect of HIV on Mtb antigen presentation in coinfected dendritic cells. The initial hypothesis was that autophagy induction through inhibition of mammalian target of rapamycin (mTOR) could suppress Mtb growth in HIV coinfected macrophages. However, during a low grade infection, autophagy induction increased Mtb replication due to a decreased autophagic flux and acidification of Mtb phagosomes. A general autophagic flux was induced, although not localized to the Mtb phagosomes, thus not inducing a xenophagy (autophagy of intracellular pathogens). Other ways of inducing autophagy or boosting the response in coinfected macrophages might be more beneficial and therefore the effect of efferocytosis was investigated. Uptake of apoptotic neutrophils by coinfected macrophages did not induce autophagy but enhanced the control of Mtb by other means. Upon efferocytosis, the macrophages acquired active myeloperoxidase (MPO) from the neutrophils that suppressed Mtb growth. The coinfected macrophages also produced more ROS after efferocytosis. The inhibition of Mtb growth could thus be mediated by MPO and the increased ROS production either directly or indirectly.The possibility to boost the innate immunity could prove to be important during an HIV coinfection, when the adaptive immunity is deficient. In addition to the well-known decline in CD4 T cells during the course of HIV progression, we found that HIV infection of dendritic cells inhibited antigen presentation by suppressing the expression of HLA-DR and co-stimulatory molecules on coinfected dendritic cells. Furthermore, HIV reduced secretion of pro-inflammatory cytokines and suppressed antigen processing through inhibition of autophagy. This impaired antigen presentation in coinfected dendritic cells resulted in a decreased activation and response of Mtb-specific CD4 T cells.In conclusion, this thesis shows how HIV can manipulate antigen presentation in Mtb coinfected dendritic cells and subsequently inhibit the adaptive immune response. It also contributes to insights on how efferocytosis of apoptotic neutrophils can boost the innate immune responses during coinfection. Lastly, autophagy induction through mTOR inhibition does not enhance protection against TB. Induction of autophagy should therefore be handled with care, particularly during HIV coinfection.
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| 2. |
- Nelson, Maria, 1979-
(författare)
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Host responses to malaria and bacterial co-infections
- 2015
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- The two main causes of child mortality and morbidity in Africa are malaria and invasive bacterial diseases. In addition, co-infections in sub-Saharan Africa are the rule rather than the exception. However, not much is known about the host-pathogen interaction during a concomitant infection or how it affects the outcome of disease.In order to study the immunological responses during malaria and bacterial co-infections, we established a co-infection mouse model. In these studies we used two pathogenic bacteria found in malaria co-infected patients: Streptococcus pneumoniae and Relapsing fever Borrelia duttonii.Hosts co-infected with malaria and Borrelia showed greatly increased spirochetal growth but low parasite densities. In addition, the co-infected hosts presented symptoms of experimental-cerebral malaria, in an otherwise unsusceptible mouse model. This was found to be a consequence of a dysregulated immune response due to loss of timing and control over regulatory mechanisms in antigen presenting cells thus locking the host in an inflammatory response. This results in inflammation, severe anemia, internal organ damage and pathology of experimental cerebral malaria.On the other hand, in the malaria - S. pneumoniae co-infection model we found that co-infected hosts cleared the bacterium much more efficiently than the single infected counterpart. This efficiency of clearance showed to be neutrophil dependent. Furthermore, in vitro studies revealed that neutrophils isolated from malaria-infected hosts present an altered migratory effect together with a significantly increased capacity to kill S. pneumoniae. This suggests that a malaria infection primes neutrophils to kill S. pneumoniae more efficiently.Furthermore, a study was carried out on plasma samples from Rwandan children under the age of five, on which a full metabolomics profile was performed. We showed that these children could be divided in different disease categories based on their metabolomics profile and independent of clinical information. Additionally, the mild malaria group could further be divided in two sub-groups, in which one had a metabolomic profile resembling that of severe malaria infected patients. Based on this, metabolite profiling could be used as a diagnostic tool to determine the distinct phase, or severity of a malaria infection, identify risk patients and provide helpful and correct therapy.
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| 3. |
- Raffetseder, Johanna
(författare)
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Interplay of human macrophages and Mycobacterium tuberculosis phenotypes
- 2016
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Mycobacterium tuberculosis (Mtb) is the pathogen causing tuberculosis (TB), a disease most often affecting the lung. 1.5 million people die annually due to TB, mainly in low-income countries. Usually considered a disease of the poor, also developed nations recently put TB back on their agenda, fueled by the HIV epidemic and the global emergence of drug-resistant Mtb strains. HIV-coinfection is a predisposing factor for TB, and infection with multi-drug resistant and extremely drug resistant strains significantly impedes and lengthens antibiotic treatment, and increases fatality. Mtb is transmitted from a sick individual via coughing, and resident macrophages are the first cells to encounter the bacterium upon inhalation. These cells phagocytose intruders and subject them to a range of destructive mechanisms, aiming at killing pathogens and protecting the host. Mtb, however, has evolved to cope with host pressures, and has developed mechanisms to submerge macrophage defenses. Among these, inhibition of phagosomal maturation and adaptation to the intracellular environment are important features. Mtb profoundly alters its phenotype inside host cells, characterized by altered metabolism and slower growth. These adaptations contribute to the ability of Mtb to remain dormant inside a host during latent TB infection, a state that can last for decades. According to recent estimates, one third of the world’s population is latently infected with Mtb, which represents a huge reservoir for active TB disease. Mtb is also intrinsically tolerant to many antibiotics, and adaptation to host pressures enhances tolerance to first-line TB drugs. Therefore, TB antibiotic therapy takes 6 to 9 months, and current treatment regimens involve a combination of several antibiotics. Patient noncompliance due to therapeutic side effects as well as insufficient penetration of drugs into TB lesions are reasons for treatment failure and can lead to the rise of drug-resistant populations. In view of the global spread of drug-resistant strains, new antibiotics and treatment strategies are urgently needed.In this thesis, we studied the interplay of the primary host cell of Mtb, human macrophages, and different Mtb phenotypes. A low-burden infection resulted in restriction of Mtb replication via phagolysosomal effectors and the maintenance of an inactive Mtb phenotype reminiscent of dormant bacteria. Macrophages remained viable for up to 14 days, and profiling of secreted cytokines mirrored a silent infection. On the contrary, higher bacterial numbers inside macrophages could not be controlled by phagolysosomal functions, and intracellular Mtb shifted their phenotype towards active replication. Although slowed mycobacterial replication is believed to render Mtb tolerant to antibiotics, we did not observe such an effect. Mtb-induced macrophage cell death is dependent on ESAT6, a small mycobacterial virulence factor involved in host cell necrosis and the spread of the pathogen. Although well-studied, the fate of ESAT6 inside infected macrophages has been enigmatic. Cultivation of Mtb is commonly carried out in broth containing detergent to avoid aggregation of bacilli due to their waxy cell wall. Altering cultivation conditions revealed the presence of a mycobacterial capsule, and ESAT6 situated on the mycobacterial surface. Infection of macrophages with this encapsulated Mtb phenotype resulted in rapid ESAT6-dependent host cell death, and ESAT6 staining was lost as bacilli were ingested by macrophages. These observations could reflect the earlier reported integration of ESAT6 into membranes followed by membrane rupture and host cell death.In conclusion, the work presented in this thesis shows that the phenotype of Mtb has a significant impact on the struggle between the pathogen and human macrophages. Taking the bacterial phenotype into account can lead to the development of drugs active against altered bacterial populations that are not targeted by conventional antibiotics. Furthermore, deeper knowledge on Mtb virulence factors can inform the development of virulence blockers, a new class of antibiotics with great therapeutic potential.
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| 4. |
- Eklund, Daniel, 1984-
(författare)
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Mycobacterium tuberculosis and the human macrophage : shifting the balance through inflammasome activation
- 2013
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Mycobacterium tuberculosis is a very successful pathogen and tuberculosis constitutes a major threat to global health worldwide. The World Health Organization (WHO) estimates that almost nine million new cases and 1.5 million deaths occur annually and the situation is worsened by increased antibiotic resistance and an extreme synergism with the HIV pandemic. M. tuberculosis primarily affects the lungs where the infection can lead to either eradication of the bacteria or the initiation of an immune response that culminates in the formation of a large cluster of immune cells termed granulomas. In these granulomas, the bacteria can either replicate and cause disease with the ultimate goal of spreading to new hosts or cause latent tuberculosis, which can persist for decades. The tools available to manage the disease are currently suboptimal and include lengthy antibiotic treatments and an inefficient vaccine resulting in poor protection. On a cellular level, M. tuberculosis primarily infects the cell designed to recognize, ingest and eradicate bacteria, namely the human macrophage. Following recognition, the macrophage phagocytoses the bacterium and tries to kill it using an array of different effector mechanisms including acidification of the bacterium-containing vacuole, different degradative enzymes and the generation of radicals. However, the bacterium is able to circumvent many of these harmful effects, leading to a tug-of-war between the bacterium and host macrophage. This thesis aims at studying the interaction between the human macrophage and M. tuberculosis to identify host factors critical for controlling growth of the bacteria. More specifically, it focuses on the role of an intracellular receptor protein called NLRP3 and its downstream effects. NLRP3 is activated in human macrophages infected by M. tuberculosis and upon activation it forms a multi-protein complex known as the inflammasome. This protein complex is known to induce the production of the proinflammatory cytokine IL-1β and specialized forms of macrophage cell death. We hypothesized that stimulating this pathway would have a beneficial effect for the host macrophage during infection with M. tuberculosis.To allow us to follow interaction between M. tuberculosis and the human macrophage, we first developed a luminometry-based method of measuring bacterial numbers and following bacterial growth over several days in infected cells. With this new assay we showed that low numbers of bacteria induced very low levels of IL-1β and failed to induce any type of cell death in the macrophage. However, when a critical number of bacteria were reached, the infected macrophages underwent necrosis, which was accompanied by high levels of IL-1β. We were also able to show that addition of vitamin D, which has been implicated as an important factor for increased killing capacity of infected macrophages, increased the production of IL-1β, which coincided with increased killing of M. tuberculosis. This effect was seen specifically in cells from patients with active tuberculosis, suggesting that these cells are primed to respond to vitamin D and increased levels of IL-1β. Furthermore, we also showed that increasing production of IL-1β by stimulating infected macrophages with apoptotic neutrophils in turn drives the production of other proinflammatory cytokines. Lastly, we showed that gain-of-function polymorphisms in inflammasome components linked to increased inflammasome activation and IL-1β production promotes bacterial killing in human macrophages. In conclusion, the work presented in this thesis shows that by enhancing the functions of the inflammasome, it is possible to tip the balance between the human macrophage and M. tuberculosis in favor of the host cell.
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