Modulating reconstituted high density lipoprotein functionality to target the Pseudomonas aeruginosa quorum sensing system.

AIMS: The synthetic counterparts of serum high density lipoproteins (HDL; reconstituted HDL, reHDL) are assuming increasing importance as a therapeutic vector. They circulate not only in blood, but also outside the vascular compartment giving access to all body tissues. Presently, the therapeutic use of reHDL exploits inherent HDL functions. Our aim was to determine if HDL functionality could be modulated by attaching peptides not normally associated with the complex. MAIN METHODS: A peptide chimera was designed by linking the signal peptide of the HDL-associated enzyme paraoxonase-1 (PON1) to the coding region for the intracellular enzyme paraoxonase-2 (PON2). KEY FINDINGS: The signal peptide modified the properties of PON2, promoting its secretion from cells and binding to HDL. Enzyme activity of the chimera protein was highly stable. Conditioned HDL showed the functions of PON2 in its ability to hydrolyse typical PON2 substrates, namely homoserine lactones. Further in vitro studies showed that conditioned HDL was able to reduce the virulence of Pseudomonas aeruginosa. Both biofilm formation and the activation of the quorum sensing systems las and rhl, responsible for bacterial virulence, were significantly reduced. SIGNIFICANCE: The study provides proof of principal that the signal peptide of PON1 can be used to attach peptides to HDL and thus modulate HDL function. They may provide a vector that is ubiquitously distributed in extracellular body fluids for designing therapeutic strategies to address different pathophysiological states.

HDL-associated paraoxonase-1 can redistribute to cell membranes and influence sensitivity to oxidative stress.

Paraoxonase-1 (PON1) is a high-density lipoprotein (HDL)-associated serum enzyme thought to make a major contribution to the antioxidant capacity of the lipoprotein. In previous studies, we proposed that HDL promoted PON1 secretion by transfer of the enzyme from its plasma membrane location to HDL transiently anchored to the hepatocyte. This study examined whether PON1 can be transferred into cell membranes and retain its enzymatic activities and functions. Using Chinese hamster ovary and human endothelial cells, we found that recombinant PON1 as well as PON1 associated with purified human HDL was freely exchanged between the external medium and the cell membranes. Transferred PON1 was located in the external face of the plasma membrane of the cells in an enzymatically active form. The transfer of PON1 led to a gain of function by the target cells, as revealed by significantly reduced susceptibility to oxidative stress and significantly increased ability to neutralize the bacterial virulence agent 3-oxo-C(12)-homoserine lactone. The data demonstrate that PON1 is not a fixed component of HDL and suggest that the enzyme could also exert its protective functions outside the lipoprotein environment. The observations may be of relevance to tissues exposed to oxidative stress and/or bacterial infection.

Expression of the hepatic Niemann-Pick C1 like 1 protein gene is sensitive to rosuvastatin treatment of primary human hepatocytes.

Statins act by reducing hepatic cholesterol synthesis, thus stimulating uptake of serum cholesterol. Statin therapy modulates a number of genes involved in hepatic cholesterol homeostasis. These have rarely been analyzed simultaneously in the same experimental setting, with virtually no studies of primary human hepatocytes. This study analyzed the efficacy of rosuvastatin in the coordinated regulation of a number of genes implicated in cholesterol metabolism in primary human hepatocytes. Expression of five cholesterol-related genes were significantly upregulated, notably the Niemann-Pick C1 like 1 protein, for whom functional studies have been essentially limited to the intestine. Two genes were significantly downregulated, including sterol recognition element binding protein-1 gene that is implicated in control of hepatic lipogenesis. The results show the coordinated regulation of several genes implicated in hepatic cholesterol homeostasis and suggest therapeutic targets that could complement that clinical action of statins.

The contribution of high density lipoprotein apolipoproteins and derivatives to serum paraoxonase-1 activity and function.

High density lipoproteins (HDL) not only provide a serum transport vector for paraoxonase-1 (PON1) but also contribute to enzyme activity, stability and, consequently, function. The contribution of the apolipoprotein (apo) components of HDL to overall PON1 activity and function is not clearly established. ApoAI appears of major importance in defining serum PON1 activity and stability, but in the context of an interaction with the phospholipid fraction of HDL. This may involve a role in establishing the architecture of the HDL particle that optimally integrates the PON1 peptide. As the second, major structural peptide of HDL, apoAII may accomplish a similar role. These apolipoproteins, together with others associated with HDL, may also exert a more indirect influence on PON1 function by sequestering oxidised lipids that could compromise enzyme activity. The latter has been exploited therapeutically to give rise to apolipoprotein mimetic peptides that may be useful in limiting oxidative stress within the lipoprotein system, thus permitting PON1 activity to be maximally expressed.

The importance of high-density lipoproteins for paraoxonase-1 secretion, stability, and activity.

The association of paraoxonase-1 (PON1) with high-density lipoproteins (HDL) is a prerequisite for maintaining normal serum activity of the enzyme. The lipoprotein furnishes an amphipathic environment to shield the hydrophobic, N-terminal region of the enzyme, and such an environment may also be necessary for interaction of PON1 with its substrates. HDL provides the optimal physiological acceptor complex, in terms of both stimulating PON1 secretion and stabilizing the secreted peptide. Lipid and peptide components of HDL contribute to these effects, such that modulating HDL composition influences PON1 activity and function. In this context, understanding how PON1 associates with HDL, what governs the association, and the mechanism by which the PON1-HDL complex exerts its antioxidant function is of particular physiological relevance. Moreover, HDL is subject to substantial compositional variations under both normal and pathological metabolic conditions. It has implications for the influence of the enzyme on cardiovascular risk, as normal enzyme activity may not correlate with optimal functional (antioxidant) efficiency. We review evidence that HDL lipid and protein components interact to promote PON1 secretion and maintain serum enzyme activity. Emerging data on how the enzyme associates with HDL are discussed, and the consequences for PON1 function of modifications to HDL are outlined. Finally, we highlight questions concerning the HDL-PON1 association that remain unanswered but are of particular importance in defining PON1 efficiency.

Genetic and environmental factors modulating serum concentrations and activities of the antioxidant enzyme paraoxonase-1.

PON1 (paraoxonase-1) is an HDL (high-density lipoprotein)-associated enzyme capable of hydrolysing diverse substrates from OP (organophosphate) toxins to oxidized phospholipids. As such, it has been linked with both the prevention of OP poisoning and inhibition of atherosclerosis initiated by oxidatively modified LDL (low-density lipoprotein). Mice deficient in PON1 are more susceptible to OP poisoning and oxidative stress and more prone to develop atherosclerosis than their wild-type siblings. There are a number of polymorphisms in the PON1 gene which affect serum PON1 activity and concentration. Many (but not all) studies in human populations have suggested that these polymorphisms may be a risk factor for atherosclerosis. The serum concentration of PON1 across the general population is highly variable and there is some debate as to whether genotype or phenotype (i.e. the quantity or quality of the enzyme) is most accurately associated with risk of disease development. What is clear is that factors influencing serum levels of PON1, be they genetic or environmental, will, in turn, affect the capacity of HDL to protect LDL from oxidation and, consequently, may be linked to atherosclerosis. This review will focus on mechanisms which determine the serum concentration of PON1, including gene expression and genetic polymorphisms, protein secretion and association with HDL, pharmacological and environmental factors.