Immunoassay for detection of oligomeric proteins.

The mass concentration of specific proteins is often used as a biomarker and play an important part in diagnostics of inflammatory diseases. Monodisperse proteins are robustly measured in immunoassays, but it is considerably more complicated to measure polydisperse oligomeric proteins. The degree of protein oligomerization is critical for functional aspects. For such proteins, information on both the mass concentration as well as the degree of oligomerization is important. Here, a time-resolved immunofluorometric assay (TRIFMA) with sensitivity for protein structure to detect homo-oligomeric and polydisperse proteins is presented. An established TRIFMA for mannan-binding lectin (MBL) was modified by implementing an additional blocking step prior to coating with capture antibodies, leading to a decrease in coating density. Recombinant human MBL was sorted into small, intermediate, and large complexes, using gel permeation chromatography. Small MBL complexes were poorly detectable by TRIFMA with a sparse antibody coating, while larger complexes produced a strong response. From comparison of molecular dimensions, this difference can be related to the size of oligomers. In conclusion, it is possible to design oligomer-size-sensitive immunoassays by regulating the inter-molecular distance of capture antibodies on a scale comparable to the size of the oligomers.

Effects of particulate matter on atherosclerosis: a link via high-density lipoprotein (HDL) functionality?

BACKGROUND: Exposure to air pollution has been associated with adverse effects on human health, and ultimately increased morbidity and mortality. This is predominantly due to hazardous effects on the cardiovascular system. Exposure to particulate matter (PM) is considered to be responsible for the most severe effects. MAIN BODY: Here we summarize current knowledge from existing epidemiological, clinical and animal studies on the influence of PM exposure on high-density lipoprotein (HDL) functionality and the potential initiation and progression of atherosclerosis. We highlight experimental studies that bring support to the causality and point to possible mechanistic links. Recent studies indicate that the functional properties of HDL are more important than the levels per se. Fine (PM2.5-0.1) and ultrafine (UFP) PM are composed of chemicals as well as biological elements that are redox-active and may trigger pro-inflammatory responses. Experimental studies indicate that these properties and responses may promote HDL dysfunction via oxidative pathways. By affecting protein and lipid components of the HDL particle, its anti-atherosclerotic characteristics including cholesterol efflux capacity, as well as other anti-oxidative and anti-inflammatory features might be impaired. CONCLUSION: Current literature suggests that PM promotes HDL dysfunction via oxidative pathways. However, as relatively few studies so far have evaluated the impact of particulate air pollution on HDL functionality, more human epidemiological as well as experimental studies are needed to strengthen any possible causal relationship and determine any relevance to atherosclerosis.