Previous studies have shown that distal mouse chromosome 1 contains the apolipoprotein All (apoAII) gene, encoding the second most abundant apolipoprotein in high density lipoproteins (HDLs), as well as a gene termed Ath-1 that controls aortic fatty streak development and HDL cholesterol levels in response to a high-fat, high-cholesterol diet. We report genetic studies confirming that the genes are distinct. Using molecular markers for mouse chromosome 1, we have further mapped the two genes, and our results indicate that they are separated by a minimum of 2 cM. We also report evidence that in mice on a low-fat chow diet, the apoAII gene locus influences HDL cholesterol levels. Thus, statistical analysis of two sets of recombinant inbred strains revealed concordant segregation patterns of HDL cholesterol levels and the apoAII gene locus. The effect of apoAII expression on HDL cholesterol levels was further tested by using a congenic strain that exhibits increased apoAII synthesis in comparison to the background strain. The results support the concept that increased synthesis of apoAII results in increased HDL cholesterol levels. Unexpectedly, increased expression of apoAII appeared to promote rather than retard aortic fatty streak are an important risk factor for coronary artery disease.
Heparin can cause an artifactual elevation in the concentration of unbound (free) thyroxine (T4) in the plasma, particularly when measured by equilibrium dialysis. The lipase released into the plasma by heparin acts on substrate (triglycerides; TG) in the plasma in vitro to release nonesterified (free) fatty acids (FFA), which, in high concentrations, inhibit the binding of T4 to its plasma binding proteins. This artifact occurs only in the presence of sufficient substrate (serum TG greater than approximately 180 mg/dL), and is most pronounced in methods requiring long incubation times. We observed this artifact in a patient receiving intralipid and subcutaneous (sc) heparin. Plasma-free T4, when measured by equilibrium dialysis, was elevated, but was normalized when the in vitro generation of FFA during equilibrium dialysis was prevented by prior treatment of the sample with protamine to inhibit lipoprotein lipase and with an antibody to hepatic triglyceride lipase. This observation caused us to investigate formally whether heparin, at standard sc doses or at iv doses even lower than those that are commonly used to flush iv lines (100-300 U), could also cause this artifact. We gave increasing doses of heparin at weekly intervals to each of three normal volunteers and measured FFA generation in their plasma (supplemented with 250 mg/dL triglycerides) under conditions simulating equilibrium dialysis. We found that, indeed, iv doses of heparin as low as 0.08 U/kg (5.6 U in a 70-kg subject) as well as a standard dose of sc heparin (5000 U) could release significant lipase activity into the plasma and, in the setting of sufficient substrate, cause enough in vitro generation of FFA to artifactually increase the serum-free T4 concentration when measured by equilibrium dialysis. These results indicate that equilibrium dialysis may not always be the best method for assessing serum-free T4 concentrations in hospitalized patients, and should be taken into account when interpreting previous studies demonstrating inhibitors of T4-serum protein binding in sera from hospitalized patients.
Mounting evidence suggests that oxidative processes contribute to the pathogenesis of atherosclerosis and that antioxidants may represent a strategy to complement the lowering of lipids in the therapy of this disease. Although multiple molecular events have been identified in vitro and although it is tempting to ascribe multiple atherogenic properties to oxidized LDL, our understanding of this process remains incomplete. Further research is warranted in several areas. First, it will be important to selectively inhibit different aspects of the process to determine the relative contribution of various biological targets. In this regard pharmacological inhibition of 15-lipoxygenase in vivo in relevant animal models is required to address the question of the contribution of this enzyme to significant oxidative events. The lack of specific inhibitors has made this task more difficult. It will also be important to define the biologically active moiety of oxidized LDL to begin to determine the mechanisms through which it exerts its atherogenic effects. It is likely that alternate protein targets can be identified both downstream and upstream of the oxidative process. Research is only now beginning to elucidate the inflammatory mechanisms that account for the cellular response. Further research into adhesion events, cytokine profiles, and downstream effector molecules of the oxidative process are likely to identify alternate targets for therapeutic intervention.
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