Glucocorticoids delivered by inorganic-organic hybrid nanoparticles mitigate acute graft-versus-host disease and sustain graft-versus-leukemia activity.

Glucocorticoids (GCs) are widely used to treat acute graft-versus-host disease (aGvHD) due to their immunosuppressive activity, but they also reduce the beneficial graft-versus-leukemia (GvL) effect of the allogeneic T cells contained in the graft. Here, we tested whether aGvHD therapy could be improved by delivering GCs with the help of inorganic-organic hybrid nanoparticles (IOH-NPs) that preferentially target myeloid cells. IOH-NPs containing the GC betamethasone (BMP-NPs) efficiently reduced morbidity, mortality, and tissue damage in a totally MHC mismatched mouse model of aGvHD. Therapeutic activity was lost in mice lacking the GC receptor (GR) in myeloid cells, confirming the cell type specificity of our approach. BMP-NPs had no relevant systemic activity but suppressed cytokine and chemokine gene expression locally in the small intestine, which presumably explains their mode of action. Most importantly, BMP-NPs delayed the development of an adoptively transferred B cell lymphoma better than the free drug, although the overall incidence was unaffected. Our findings thus suggest that employing IOH-NPs could diminish the risk of relapse associated with GC therapy of aGvHD patients while still allowing to efficiently ameliorate the disease.

Highly selective organ distribution and cellular uptake of inorganic-organic hybrid nanoparticles customized for the targeted delivery of glucocorticoids.

We previously reported that inorganic-organic hybrid nanoparticles (IOH-NPs) containing the synthetic glucocorticoid (GC) betamethasone show efficient anti-inflammatory activity in mice. Here, we employed IOH-NPs with the chemical composition Gd3+2[AMP]2-3 (AMP: adenosine monophosphate) to determine their in vivo distribution by magnetic resonance imaging after intraperitoneal injection. We show that IOH-NPs distribute throughout the peritoneal cavity from where they get rapidly cleared and then localize to abdominal organs. Our findings were confirmed by analyzing individual mouse organs ex vivo following injection of IOH-NPs with the chemical composition [ZrO]2+[(BMP)0.9(FMN)0.1]2- (BMP: betamethasone phosphate, FMN: flavin mononucleotide) or [ZrO]2+[(HPO4)0.9(FMN)0.1]2- using inductively coupled plasma mass spectrometry and flow cytometry. To characterize the mechanism of cellular uptake in vitro, we tested different cell lines for their ability to engulf IOH-NPs by flow cytometric analysis taking advantage of the incorporated fluorescent dye FMN. We found that IOH-NPs were efficiently taken up by macrophages, to a lesser extent by fibroblasts, epithelial cells, and myoblasts, and hardly at all by both T and B lymphocytes. Characterization of the endocytic pathway further suggested that IOH-NPs were internalized by macropinocytosis, and imaging flow cytometry revealed a strong colocalization of the engulfed IOH-NPs with the lysosomal compartment. Intracellular release of the functional anions from IOH-NPs was confirmed by the ability of the GC betamethasone to downregulate the expression of surface receptors on bone marrow-derived macrophages. Taken together, our findings unveil the mechanistic basis of an anti-inflammatory GC therapy with IOH-NPs, which may entail translational approaches in the future.

Glucocorticoid resistance of allogeneic T cells alters the gene expression profile in the inflamed small intestine of mice suffering from acute graft-versus-host disease.

Glucocorticoids (GCs) play an important role in controlling acute graft-versus-host disease (aGvHD), a frequent complication of allogeneic hematopoietic stem cell transplantation. The anti-inflammatory activity of GCs is mainly ascribed to the modulation of T cells and macrophages, for which reason a genetically induced GC resistance of either of these cell types causes aggravated aGvHD. Since only a few genes are currently known that are differentially regulated under these conditions, we analyzed the expression of 54 candidate genes in the inflamed small intestine of mice suffering from aGvHD when either allogeneic T cells or host myeloid cells were GC resistant using a microfluidic dynamic array platform for high-throughput quantitative PCR. The majority of genes categorized as cytokines (e.g. Il2, Il6), chemokines (e.g. Ccl2, Cxcl1), cell surface receptors (e.g. Fasl, Ctla4) and intracellular molecules (e.g. Dusp1, Arg1) were upregulated in mice transplanted with GC resistant allogeneic T cells. Moreover, the expression of several genes linked to energy metabolism (e.g. Glut1) was altered. Surprisingly, mice harboring GC resistant myeloid cells showed almost no changes in gene expression despite their fatal disease course after aGvHD induction. To identify additional genes in the inflamed small intestine that were affected by a GC resistance of allogeneic T cells, we performed an RNAseq analysis, which uncovered more than 500 differentially expressed transcripts (e.g. Cxcr6, Glut3, Otc, Aoc1, Il1r1, Sphk1) that were enriched for biological processes associated with inflammation and tissue disassembly. The changes in gene expression could be confirmed during full-blown disease but hardly any of them in the preclinical phase using high-throughput quantitative PCR. Further analysis of some of these genes revealed a highly selective expression pattern in T cells, intestinal epithelial cells and macrophages, which correlated with their regulation during disease progression. Collectively, we identified an altered gene expression profile caused by GC resistance of transplanted allogeneic T cells, which could help to define new targets for aGvHD therapy.