Efficient delivery of short interfering RNAs reflects a prerequisite for the development of RNA interference therapeutics. Here, we describe highly specific nanoparticles, based on near infrared fluorescent polymethine dye-derived targeting moieties coupled to biodegradable polymers. The fluorescent dye, even when coupled to a nanoparticle, mimics a ligand for hepatic parenchymal uptake transporters resulting in hepatobiliary clearance of approximately 95% of the dye within 45 min. Body distribution, hepatocyte uptake and excretion into bile of the dye itself, or dye-coupled nanoparticles can be tracked by intravital microscopy or even non-invasively by multispectral optoacoustic tomography. Efficacy of delivery is demonstrated in vivo using 3-hydroxy-3-methyl-glutaryl-CoA reductase siRNA as an active payload resulting in a reduction of plasma cholesterol levels if siRNA was formulated into dye-functionalised nanoparticles. This suggests that organ-selective uptake of a near infrared dye can be efficiently transferred to theranostic nanoparticles allowing novel possibilities for personalised silencing of disease-associated genes.
The molecular mechanisms of maladaptive response in liver tissue with respect to the acute and post-acute phase of sepsis are not yet fully understood. Long-term sepsis survivors might develop hepatocellular/hepatobiliary injury and fibrosis. Here, we demonstrate that acid sphingomyelinase, an important regulator of hepatocyte apoptosis and hepatic stellate cell (HSC) activation, is linked to the promotion of liver dysfunction in the acute phase of sepsis as well as to fibrogenesis in the long-term. In both phases, we observed a beneficial effect of partial genetic sphingomyelinase deficiency in heterozygous animals (smpd1+/−) on oxidative stress levels, hepatobiliary function, macrophage infiltration and on HSC activation. Strikingly, similar to heterozygote expression of SMPD1, either preventative (p-smpd1+/+) or therapeutic (t-smpd1+/+) pharmacological treatment strategies with desipramine – a functional inhibitor of acid sphingomyelinase (FIASMA) – significantly improved liver function and survival. The inhibition of sphingomyelinase exhibited a protective effect on liver function in the acute-phase, and the reduction of HSC activation diminished development of sepsis-associated liver fibrosis in the post-acute phase of sepsis. In summary, targeting sphingomyelinase with FDA-approved drugs is a novel promising strategy to overcome sepsis-induced liver dysfunction.
Plasma secretion of acid sphingomyelinase is a hallmark of cellular stress
response resulting in the formation of membrane embedded ceramide-enriched lipid
rafts and the reorganization of receptor complexes. Consistently,
decompartmentalization of ceramide formation from inert sphingomyelin has been
associated with signaling events and regulation of the cellular phenotype.
Herein, we addressed the question of whether the secretion of acid
sphingomyelinase is involved in host response during sepsis. We found an
exaggerated clinical course in mice genetically deficient in acid
sphingomyelinase characterized by an increased bacterial burden, an increased
phagocytotic activity, and a more pronounced cytokine storm. Moreover, on a
functional level, leukocyte-endothelial interaction was found diminished in
sphingomyelinase-deficient animals corresponding to a distinct leukocytes’
phenotype with respect to rolling and sticking as well as expression of cellular
surface proteins. We conclude that hydrolysis of membrane-embedded
sphingomyelin, triggered by circulating sphingomyelinase, plays a pivotal role
in the first line of defense against invading microorganisms. This function
might be essential during the early phase of infection leading to an adaptive
response of remote cells and tissues.
Polymicrobial sepsis produces profound hepatocellular dysfunction in the absence of traditional cytokine-mediated mechanisms of cellular injury. This questions the central role of cytokines and the ensuing oxidative stress as key molecular events in mediating liver dysfunction.
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