Malaria continues to wreak havoc in tropical regions, due largely to the lack of an effective vaccine. Vaccine candidates based on whole parasites have shown promising results in malaria-naïve... Show moreMalaria continues to wreak havoc in tropical regions, due largely to the lack of an effective vaccine. Vaccine candidates based on whole parasites have shown promising results in malaria-naïve individuals, but their potency in malaria-exposed individuals is considerably lower. This dissertation described the development of a chemical strategy for boosting such parasites’ potency in pursuit of more efficacious malaria vaccines for use in endemic areas.Chapter 2 outlined the adaptation of a method for chemically modifying microbial cell surfaces.Chapter 3 showed the chemistry underlying this modification system to be stably compatible with in vivo usage.Chapter 4 demonstrated that when the chemical modification system was used to introduce immune-potentiating agents onto bacteria, better immune responses ensued.Chapter 5 tied it all together by using the chemical modification system to potentiate malaria parasites, and showed that doing so markedly improved immune responses in an in vivo immunization model.Chapter 6 summarized these findings in the context of malaria vaccine development and posited next steps forward. Show less
Duszenko, N.; Schuijlenburg, R. van; Chevalley-Maurel, S.; Willigen, D.M. van; Bes-Roeleveld, L. de; Wees, S. van der; ... ; Roestenberg, M. 2023
Despite promising results in malaria-naïve individuals, whole sporozoite (SPZ) vaccine efficacy in malaria-endemic settings has been suboptimal. Vaccine hypo-responsiveness due to previous malaria... Show moreDespite promising results in malaria-naïve individuals, whole sporozoite (SPZ) vaccine efficacy in malaria-endemic settings has been suboptimal. Vaccine hypo-responsiveness due to previous malaria exposure has been posited as responsible, indicating the need for SPZ vaccines of increased immunogenicity. To this end, we here demonstrate a proof-of-concept for altering SPZ immunogenicity, where supramolecular chemistry enables chemical augmentation of the parasite surface with a TLR7 agonist-based adjuvant (SPZ-SAS(CL307)). In vitro, SPZ-SAS(CL307) remained well recognized by immune cells and induced a 35-fold increase in the production of pro-inflammatory IL-6 (p < 0.001). More promisingly, immunization of mice with SPZ-SAS(CL307) yielded improved SPZ-specific IFN-γ production in liver-derived NK cells (percentage IFN-γ+ cells 11.1 ± 1.8 vs. 9.4 ± 1.5%, p < 0.05), CD4+ T cells (4.7 ± 4.3 vs. 1.8 ± 0.7%, p < 0.05) and CD8+ T cells (3.6 ± 1.4 vs. 2.5 ± 0.9%, p < 0.05). These findings demonstrate the potential of using chemical augmentation strategies to enhance the immunogenicity of SPZ-based malaria vaccines. Show less
Duszenko, N.; Willigen, D.M. van; Bunschoten, A.; Velders, A.H.; Roestenberg, M.; Leeuwen, F.W.B. van 2022
Many pathogens blunt immune responses because they lack immunogenic structural features, which typically results in disease. Here, we show evidence suggesting that pathogen immunogenicity can be... Show moreMany pathogens blunt immune responses because they lack immunogenic structural features, which typically results in disease. Here, we show evidence suggesting that pathogen immunogenicity can be chemically enhanced. Using supramolecular host-guest chemistry, we complexed onto the surface of a poorly immunogenic bacterium (Staphylococcus aureus) a TLR7 agonist-based adjuvant. "Adjuvanted" bacteria were readily recognized by macrophages and induced a more pro-inflammatory immunophenotype. Future applications of this concept could yield treatment modalities that bolster the immune system's response to pathogenic microbes. Show less
Welling, M.M.; Duszenko, N.; Willigen, D.M. van; Smits, W.K.; Buckle, T.; Roestenberg, M.; Leeuwen, F.W.B. van 2021
Cyclodextrin (CD)-based host-guest interactions with adamantane (Ad) have demonstrated use for functionalizing living cells in vitro. The next step in this supramolecular functionalization approach... Show moreCyclodextrin (CD)-based host-guest interactions with adamantane (Ad) have demonstrated use for functionalizing living cells in vitro. The next step in this supramolecular functionalization approach is to explore the concept to deliver chemical cargo to living cells in vivo, e.g., inoculated bacteria, in order to study their dissemination. We validated this concept in two rodent Staphylococcus aureus models. Bacteria (1 X 10(8) viable S. aureus) were inoculated by (1) intramuscular injection or (2) intrasplenic injection followed by dissemination throughout the liver. The bacteria were prefunctionalized with Tc-99m-UBI29-41-Ad(2) (primary vector), which allowed us to both determine the bacterial load and create an in vivo target for the secondary host-vector (24 h post-inoculation). The secondary vector, i.e., chemical cargo delivery system, made use of a In-111-Cy5(0)(.5)CD(9)PIBMA(39 )polymer that was administered intravenously. Bacteria-specific cargo delivery as a result of vector complexation was evaluated by dual-isotope SPECT imaging and biodistribution studies (In-111), and by fluorescence (Cy5); these evaluations were performed 4 h post-injection of the secondary vector. Mice inoculated with nonfunctionalized S. aureus and mice without an infection served as controls. Dual-isotope SPECT imaging demonstrated that In-111-Cy5(0)(.5)CD(9)PIBMA(3)(9) colocalized with Tc-99m-UBI29-41-Ad(2)-labeled bacteria in both muscle and liver. In inoculated muscle, a 2-fold higher uptake level (3.2 +/- 1.0%ID/g) was noted compared to inoculation with nonfunctionalized bacteria (1.9 +/- 0.4%ID/g), and a 16-fold higher uptake level compared to noninfected muscle (0.2 +/- 0.1%ID/g). The hepatic accumulation of the host-vector was nearly 10-fold higher (27.1 +/- 11.1%ID/g) compared to the noninfected control (2.7 +/- 0.3%ID/g; p < 0.05). Fluorescence imaging of the secondary vector corroborated SPECT-imaging and biodistribution findings. We have demonstrated that supramolecular host-guest complexation can be harnessed to achieve an in vivo cargo delivery strategy, using two different bacterial models in soft tissue and liver. This proof-of-principle study paves a path toward developing innovative drug delivery concepts via cell functionalization techniques. Show less
Aim: Pre-targeting is a proven strategy for in vivo delivery of a diagnostic or therapeutic payload. The pre-targeting concept can be realized through various conjugation strategies, one of which... Show moreAim: Pre-targeting is a proven strategy for in vivo delivery of a diagnostic or therapeutic payload. The pre-targeting concept can be realized through various conjugation strategies, one of which is based on copper-free "click" chemistry. Copper-free click reactions have shown in vivo potential for imaging and radionuclide therapy, but this conjugation strategy has not yet been explored in combination with microspheres or unicellular organisms. This study aims to evaluate the in vivo efficacy of strain-promoted azide-alkyne cycloaddition (SPAAC) reactions to achieve imaging and targeting of azide-functionalized macro-aggregated albumin (MAA) microspheres and Staphylococcus aureus bacteria. Methods: MAA microspheres (diameter 10-90 mu m) were functionalized with a biorthogonal Cy5 fluorophore, bearing an azide functionality (N-3), to generate MAA-Cy5-N-3. S. aureus (diameter similar to 1 mu m) were functionalized with Tc-99m-UBI29-41-Cy5-N-3, generating S. aureus-Tc-99m-UBI29-41-Cy5-N-3. In situ and in vitro click conjugation on the -N-3 moieties was studied for 20 h using a radioactivity-based assay and fluorescence microscopy. For in vivo validation, both primary entities, radiolabeled with Tc-99m, were deposited into the microvasculature of the liver via intrasplenic injections. Secondary targeting was realized following the intravenous administration of indium-111-radiolabeled diethylenetriaminepentaacetic acid-dibenzocyclooctyne (In-111-DTPA-DBCO). To assess click reaction efficiency in vivo, Tc-99m and In-111-biodistributions were measured (SPECT and %ID g(-1)). Use of In-111-DTPA-DBCO in mice without MAA deposits or mice infected with non-functionalized S. aureus served as controls. Ex vivo confocal fluorescence imaging was carried out in excised tissues to confirm the presence of functionalized MAA and bacteria. Results: In vitro data confirmed effective click reactions on both the MAA particles and the bacterial membrane. SPECT imaging and biodistribution studies revealed significantly (p < 0.05) increased accumulation of In-111-DTPA-DBCO at the sites where MAA-Cy5-N-3 (7.5 +/- 1.5%ID g(-1)vs. 3.5 +/- 0.5%ID g(-1) in control mice) and S. aureus-Tc-99m-UBI29-41-Cy5-N-3 (9.3 +/- 1.3%ID g(-1)vs. 6.0 +/- 0.5%ID g(-1) in control mice) resided. Ex vivo fluorescence imaging confirmed the presence of either functionalized MAA or S. aureus in excised spleens and livers of mice. Conclusion: Copper-free click chemistry between a DBCO moiety and Cy5-N-3-functionalized microspheres or bacterial entities in the liver can be used to realize in vivo imaging and targeting. Show less
Winkel, B.M.F.; Pelgrom, L.R.; Schuijlenburg, R. van; Baalbergen, E.; Ganesh, M.S.; Gerritsma, H.; ... ; Roestenberg, M. 2020
Author summary Malaria continues to be the deadliest parasitic disease worldwide, and an effective vaccine yielding sterile immunity does not yet exist. Attenuated parasites can induce sterile... Show moreAuthor summary Malaria continues to be the deadliest parasitic disease worldwide, and an effective vaccine yielding sterile immunity does not yet exist. Attenuated parasites can induce sterile protection in both human and rodent models for malaria, but these vaccines need to be administered directly into the bloodstream in order to convey protection; administration via the skin results in a much-reduced efficacy. We hypothesized this is caused by an early immune regulation initiated at the first site of contact with the immune system: the skin. However, the human skin stage of malaria has not been investigated to date. We used human antigen presenting cells as well as whole human skin explants to investigate (dermal) immune responses and found thatPlasmodiumsporozoites are able to suppress immune responses by inducing regulatory macrophages. Our study provides new insights in the mechanism of early immune regulation exploited byPlasmodiumparasites and can help to explain why intradermal vaccination using whole attenuated sporozoites results in reduced protection.Professional antigen-presenting cells (APCs), like macrophages (M phi s) and dendritic cells (DCs), are central players in the induction of natural and vaccine-induced immunity to malaria, yet very little is known about the interaction of SPZ with human APCs. Intradermal delivery of whole-sporozoite vaccines reduces their effectivity, possibly due to dermal immunoregulatory effects. Therefore, understanding these interactions could prove pivotal to malaria vaccination. We investigated human APC responses to recombinant circumsporozoite protein (recCSP), SPZ and anti-CSP opsonized SPZ both in monocyte derived MoDCs and MoM phi s. Both MoDCs and MoM phi s readily took up recCSP but did not change phenotype or function upon doing so. SPZ are preferentially phagocytosed by MoM phi s instead of DCs and phagocytosis greatly increased after opsonization. Subsequently MoM phi s show increased surface marker expression of activation markers as well as tolerogenic markers such as Programmed Death-Ligand 1 (PD-L1). Additionally they show reduced motility, produce interleukin 10 and suppressed interferon gamma (IFN gamma) production by antigen specific CD8(+)T cells. Importantly, we investigated phenotypic responses to SPZ in primary dermal APCs isolated from human skin explants, which respond similarly to their monocyte-derived counterparts. These findings are a first step in enhancing our understanding of pre-erythrocytic natural immunity and the pitfalls of intradermal vaccination-induced immunity. Show less
Duszenko, N.; Willigen, D.M. van; Welling, M.M.; Korne, C.M. de; Schuijlenburg, R. van; Winkel, B.M.F.; ... ; Roestenberg, M. 2020
In an era of antimicrobial resistance, a better understanding of the interaction between bacteria and the sentinel immune system is needed to discover new therapeutic targets for combating... Show moreIn an era of antimicrobial resistance, a better understanding of the interaction between bacteria and the sentinel immune system is needed to discover new therapeutic targets for combating bacterial infectious disease. Sentinel immune cells such as macrophages phagocytose intact bacteria and thereby initiate ensuing immune responses. The bacterial surface composition is a key element that determines the macrophage signaling. To study the role of the bacterial cell surface composition in immune recognition, we developed a platform technology for altering bacterial surfaces in a controlled manner with versatile chemical scaffolds. We show that these scaffolds are efficiently loaded onto both Gram-positive and -negative bacteria and that their presence does not impair the capacity of monocyte-derived macrophages to phagocytose bacteria and subsequently signal to other components of the immune system. We believe this technology thus presents a useful tool to study the role of bacterial cell surface composition in disease etiology and potentially in novel interventions utilizing intact bacteria for vaccination. Show less
