Simon Skjøde Jensen

Triggered Activation and Release of Liposomal Prodrugs and Drugs in Cancer Tissue by Secretory Phospholipase A2

The selectivity of anticancer drugs in targeting the tumour tissue presents a major problem in cancer treatment. In this article we review a new generation of smart liposomal nanocarriers that can be used for enhanced anticancer drug and prodrug delivery to tumours. The liposomes are engineered to be particularly degradable to secretory phospholipase A2 (sPLA2), which is a lipid hydrolyzing enzyme that is significantly upregulated in the extracellular microenvironment of cancer tumours. Thus, when the long circulatory liposomal nanocarriers extravasate and accumulate in the interstitial tumour space, sPLA2 will act as an active trigger resulting in the release of cytotoxic drugs in close vicinity of the target cancer cells. The sPLA2 generated lysolipid and fatty acid hydrolysis products will furthermore be locally released and function as membrane permeability promoters facilitating the intracellular drug uptake. In addition, the liposomal membrane can be composed of a novel class of prodrug lipids that can be converted selectively to active anticancer agents by sPLA2 in the tumour. The integrated drug discovery and delivery technology offers a promising way to rationally design novel tumour activated liposomal nanocarriers for better cancer treatment.

Regulation of the IL-10/IL-12 axis in human dendritic cells with probiotic bacteria.

In this study, we have used monocyte-derived dendritic cells (DCs) to design a screening model for the selection of microorganisms with the ability to suppress DC-secreted IL-12p70, a critical cytokine for the induction of T-helper cell type 1 immune responses under inflammatory conditions. By the treatment of DCs with cocktails containing TLR agonists and proinflammatory cytokines, the cells increased the secretion of the Th1-promoting cytokine IL-12p70. Clinically used probiotics were tested for their IL-10- and IL-12p70-stimulating properties in immature DCs, and showed a dose-dependent change in the IL-10/IL-12p70 balance. Lactobacillus acidophilus NCFM(™) and the probiotic mixture VSL#3 showed a strong induction of IL-12p70, whereas Lactobacillus salivarius Ls-33 and Bifidobacterium infantis 35624 preferentially induced IL-10. Escherichia coli Nissle 1917 induced both IL-10 and IL-12p70, whereas the probiotic yeast Saccharomyces boulardii induced low levels of cytokines. When combining these microorganisms with the Th1-promoting cocktails, E. coli Nissle 1917 and B. infantis 35624 were potent suppressors of IL-12p70 secretion in an IL-10-independent manner, indicating a suppressive effect on Th1-inducing antigen-presenting cells. The present model, using cocktail-stimulated DCs with potent IL-12p70-stimulating capacity, may be used as an efficient tool to assess the anti-inflammatory properties of microorganisms for potential clinical use.

Differential induction of inflammatory cytokines by dendritic cells treated with novel TLR-agonist and cytokine based cocktails: targeting dendritic cells in autoimmunity

BackgroundDendritic cells (DC) are main gate-keepers of the immune system, bridging the innate and adaptive immune system. DCs are able to mature into inflammatory DCs at sites of inflammation in both autoimmune and allergic disease, thereby sustaining a continuous activation of the adaptive immune system at sites of inflammation. This function of DCs makes them attractive target cells for therapeutic intervention in inflammatory diseases. We have designed a DC-based screening model by which drug candidates can be evaluated for their ability to suppress DC maturation into an inflammatory and disease promoting phenotype.MethodsHuman monocyte derived DCs were differentiated using IL-4 and GM-CSF to immature DCs (imDCs). The imDCs were treated with various combinations of TLR-agonists and pro-inflammatory cytokines to identify cocktails with ability to mature imDCs into inflammatory DCs. The effect of the cocktails on DC maturation was evaluated using ELISA and cytokine arrays to measure secreted cytokines and chemokines. FACS analysis was used to assess expression of maturation markers, and functional studies were carried out using naïve allogeneic T-cells to assay for a Th1-promoting DC phenotype.ResultsNine cocktails were designed with potent ability to induce secretion of the Th1-promoting cytokines IL-12p70 and TNFα from imDCs, and three were able to induce the Th17-promoting cytokine IL-23. The cocktails were further characterized using cytokine arrays, showing induction of inflammation related cytokines and chemokines like CXCL10, CCL2, CCL4, CCL8, CCL15, CCL20 and IL-8, of which some are present in a range of autoimmune pathologies. Prostaglandin E2 secretion was identified from DCs treated with TLR agonists poly I:C and peptidoglycan, but not LPS. The cocktails were able to induce DC maturation markers like HLA-DR, CD40, CD80, CD83 and CD86, except the TLR7/8 agonist R848. Functional end-points made by co-culture of allogeneic CD4+ T cells with the cocktail treated DCs, showed that five cocktails in particular could induce a classical Th1-phenotype with ability to secrete high amounts of the hall-mark cytokine IFNγ. The model was validated using dexamethasone and two COX-inhibitors, which were able to suppress the cocktail driven pro-inflammatory DC maturation.ConclusionsThe identification of novel Th1-promoting cocktails allows screening of anti-inflammatory drug candidates by assessing the ability to suppress the activation and differentiation of imDCs into inflammatory DCs with a specific Th1-promoting phenotype. The model thus provides a screening tool, which can identify potential anti-inflammatory effects on the natural regulator of the immune response, the dendritic cell.

Delivery of TLR7 agonist to monocytes and dendritic cells by DCIR targeted liposomes induces robust production of anti-cancer cytokines

Tumor immune escape is today recognized as an important cancer hallmark and is therefore a major focus area in cancer therapy. Monocytes and dendritic cells (DCs), which are central to creating a robust anti-tumor immune response and establishing an anti-tumorigenic microenvironment, are directly targeted by the tumor escape mechanisms to develop immunosuppressive phenotypes. Providing activated monocytes and DCs to the tumor tissue is therefore an attractive way to break the tumor-derived immune suppression and reinstate cancer immune surveillance. To activate monocytes and DCs with high efficiency, we have investigated an immunotherapeutic Toll-like receptor (TLR) agonist delivery system comprising liposomes targeted to the dendritic cell immunoreceptor (DCIR). We formulated the immune stimulating TLR7 agonist TMX-202 in the liposomes and examined the targeting of the liposomes as well as their immune activating potential in blood-derived monocytes, myeloid DCs (mDCs), and plasmacytoid DCs (pDCs). Monocytes and mDCs were targeted with high specificity over lymphocytes, and exhibited potent TLR7-specific secretion of the anti-cancer cytokines IL-12p70, IFN-α 2a, and IFN-γ. This delivery system could be a way to improve cancer treatment either in the form of a vaccine with co-formulated antigen or as an immunotherapeutic vector to boost monocyte and DC activity in combination with other treatment protocols such as chemotherapy or radiotherapy. STATEMENT OF SIGNIFICANCE Cancer immunotherapy is a powerful new tool in the oncologists therapeutic arsenal, with our increased knowledge of anti-tumor immunity providing many new targets for intervention. Monocytes and dendritic cells (DCs) are attractive targets for enhancing the anti-tumor immune response, but systemic delivery of immunomodulators has proven to be associated with a high risk of fatal adverse events due to the systemic activation of the immune system. We address this important obstacle by targeting the delivery of an immunomodulator, a Toll-like receptor agonist, to DCs and monocytes in the bloodstream. We thus focus the activation, potentially avoiding the above-mentioned adverse effects, and demonstrate greatly increased ability of the agonist to induce secretion of anti-cancer cytokines.

Monocyte targeting and activation by cationic liposomes formulated with a TLR7 agonist

Objectives: Monocytes are one of the major phagocytic cells that patrol for invading pathogens, and upon activation, differentiate into macrophages or antigen-presenting dendritic cells (DCs) capable of migrating to lymph nodes eliciting an adaptive immune response. The key role in regulating adaptive immune responses has drawn attention to modulate monocyte responses therapeutically within cancer, inflammation and infectious diseases. We present a technology for targeting of monocytes and delivery of a toll-like receptor (TLR) agonist in fresh blood using liposomes with a positively charged surface chemistry. Methods: Liposomes were extruded at 100 nm, incubated with fresh blood, followed by leukocyte analyses by FACS. Liposomes with and without the TLR7 agonist TMX-202 were incubated with fresh blood, and monocyte activation measured by cytokine secretion by ELISA and CD14 and DC-SIGN expression. Results: The liposomes target monocytes specifically over lymphocytes and granulocytes in human whole blood, and show association with 75 – 95% of the monocytes after 1 h incubation. Formulations of TMX-202 in cationic liposomes were potent in targeting and activation of monocytes, with strong induction of IL-6 and IL-12p40, and differentiation into CD14+ and DC-SIGN+ DCs. Conclusion: Our present liposomes selectively target monocytes in fresh blood, enabling delivery of TLR7 agonists to the intracellular TLR7 receptor, with subsequent monocyte activation and boost in secretion of proinflammatory cytokines. We envision this technology as a promising tool in future cancer immunotherapy.

Development of assay platforms for in vitro screening of Treg modulating potential of pharmacological compounds

Abstract CD4 + CD25+ regulatory T cells (Tregs) are believed to be pivotal in controlling chronic inflammation as well as in opposing the effect of cancer immunotherapy. Therefore, identification of novel drug compounds that interfere with Treg function is of high priority together with research that investigates Treg modulation by current drugs. For such research as well as for novel cell based therapies based on Treg infusions, rapid in vitro assays as well as functional assays based on inhibitory capacity of Tregs are required. Here, we report on such assays using highly pure fluorescence-activated cell sorting (FACS) sorted CD4 + CD25highCD127dim/−CD45RA+ naïve Treg cells followed by in vitro expansion. We report on the use of these cells in a short-term assay based on Treg mediated inhibition of the early effector T cell activation markers CD69 and CD154. Additionally, we investigate the use of highly pure Tregs in a functional assay based on Treg mediated inhibition of effector T cell proliferation. We report highly reproducible Treg function in assays that test the effect of well-known model compounds such as CpG-A, anti-IL-6R (tocilizumab), anti-TNF-α (adalimumab) or a combination of IL-6 and TNF-α. In conclusion, these assays have the potential for use in pharmacological screening and discovery in relation to drug development in immunology.

Whole blood targeting and activation of monocytes with TLR7 agonist formulated in cationic liposomes

Monocytes are one of the major phagocytic cells in the periphery that patrols the circulation for invading pathogens, and upon activation differentiates into dendritic cells, capable of migration to lymph nodes eliciting an adaptive immune response. Monocytes has for more than a decade been precursor cell for generation of autologous dendritic cell cancer vaccines, but clinical results have shown limiting benefits for the patients. One way of improving dendritic cell vaccines is targeting the monocytes in vivo with a suitable carrier of adjuvant together with tumor antigens, to boost monocyte differentiation towards tumor antigen presenting DCs. Here we report a novel monocyte targeting liposome technology capable of delivering TLR7 agonist to CD14 positive monocytes in fresh whole human blood. Liposomes with a positive surface charge were able to specifically target monocytes over lymphocytes and granulocytes, and showed association with 90-100 % of the monocytes. Formulation of the TLR7 agonist in monocyte targeting liposomes showed strong activation of the monocytes, with potent induction of proinflammatory cytokines, and differentiation into tissue inflammatory DCs, demonstrating that the liposomes are able to deliver compounds to the endosomes where TLR7 is present. The present monocyte targeting technology may be a promising approach for designing cancer vaccines with suitable adjuvants and cancer antigens.

Targeting Monocytes with TLR7 Ligands as a Novel Opportunity in Immuno-Oncology

Cancer immunotherapy has for the last decade been one of the fastest developing therapeutic areas in oncology with promising clinical benefits, supporting a role of immunotherapy as a cornerstone in future cancer treatment in combination with existing treatments. Treatment of early stage cancers today is very efficient due to refined surgery, chemotherapy, radiation and use of therapeutic antibodies, but a large group of patients in particular with late stage and metastatic disease have poor prognosis due to lack of efficient treatment options. Thus, there is an urgent need to develop new technologies to provide more efficient treatment of late stage cancers, focused towards cure of these patients. One approach that may lead to better treatment is utilising the immune system of these patients, in order to generate durable anti-tumor memory immune responses. One strategy to boost the immune system of cancer patients has been administration of Toll Like Receptor ligands to overcome systemic and local immune escape mechanisms. In this commentary we discuss a novel delivery technology for systemic targeting of a Toll Like Receptor 7 ligand to monocytes in relation to current knowledge in cancer immunotherapy with perspectives on challenges and opportunities for clinical use of this technology.