Current Pharmaceutical Design - Volume 19, Issue 17, 2013

Dyslipidemia is one of the main risk factors leading to cardiovascular disease (CVD). The standard of therapy, administration of statins, in conjunction with lifestyle and habit changes, can improve high cholesterol levels in the majority of patients. However, some patients with familial hypercholesterolemia (FH) need low-density-lipoprotein cholesterol (LDL-C) apheresis, as the available medications fail to reduce LDL-C levels sufficiently even at maximum doses. Intense research on cholesterol reducing agents and rapid progress in drug design have yielded many approaches that reduce cholesterol absorption or inhibit its synthesis. Antisense oligonucleotides (ASOs) targeting the production of apolipoprotein B-100 (apoB-100), inhibitors of proprotein convertase subtilisin/kexin type 9, microsomal triglyceride transfer protein inhibitors, squalene synthase inhibitors, peroxisome proliferator-activated receptor agonists, and thyroid hormone receptor agonists are some of the evolving approaches for lipid-lowering therapies. We provide an overview of the apoB ASO approach and its potential role in the management of dyslipidemia. Mipomersen (ISIS- 301012, KYNAMRO™) is a synthetic ASO targeting the mRNA of apoB-100, which is an essential component of LDL particles and related atherogenic lipoproteins. ASOs bind to target mRNAs and induce their degradation thereby resulting in reduced levels of the corresponding protein levels. Mipomersen has been investigated in different indications including homozygous and heterozygous FH, as well as in high-risk hypercholesterolemic patients. Recent phase II and III clinical studies have shown a 25-47$percnt; reduction in LDL-C levels in mipomersen-treated patients. If future studies continue to show such promising results, mipomersen would likely be a viable additional lipid-lowering therapy for high-risk populations.

There is a strong need to reduce the risk of cardiovascular disease (CVD) beyond the use of statins that lower low-density lipoprotein cholesterol (LDL-C). The inverse relationship of high-density lipoprotein cholesterol (HDL-C) with cardiovascular disease suggests HDL-C raising therapy as a novel target. This review discusses the role of HDL-C in atherogenesis as well as the promise of cholesteryl ester transfer protein (CETP) inhibition in CVD prevention. While genetic studies show conflicting results on correlations between HDL-C and CVD, experimental studies have yielded sufficient encouraging data to proceed with the development of HDL-C raising strategies. CETP inhibition has been shown to successfully increase HDL-C levels in man. However, the first CETP inhibitor tested in phase III trials increased mortality possibly due to torcetrapib-specific vasopressor effects. More recently, dalcetrapib did not show an effect on CVD outcome while raising HDL-C by 30%, thereby refuting the HDL-C hypothesis. Anacetrapib and evacetrapib are currently tested in phase III clinical trials and have not shown adverse effects thus far. Both compounds not only increase HDL-C by 129-151%, they also decrease LDL-C (36-41%) and anacetrapib lowers Lp(a) (17%). Combined, these effects are anticipated to decrease CVD risk and the results will be revealed in 2017.

Current lipid-lowering drugs are often unable to achieve low density lipoprotein cholesterol (LDL-C) goals. Moreover, despite LDL-C lowering mostly by statins, a considerable residual vascular risk remains. This is partly associated with atherogenic dyslipidemia where apolipoprotein (apo) B-containing lipoproteins predominate. Mitochondrial Triglyceride (TG) transfer protein (MTP) is a key enzyme for apoB-containing lipoprotein assembly and secretion. This is mostly attributed to its capacity to transfer lipid components (TGs, cholesterol esters and phospholipids) to the endoplasmic reticulum lumen, where these lipoproteins are assembled. Several agents were developed to inhibit MTP wherever it is expressed, namely the liver and/or the intestine. Liver-specific MTP inhibitors reduce secretion of very low density lipoproteins (VLDL) mostly containing apoB100, while the intestine-specific ones reduce secretion of chylomicrons containing apoB48. These drugs can significantly reduce total cholesterol, LDL-C, TGs, VLDL cholesterol, as well as apoB levels in vivo. They may also exert anti-atherosclerotic and insulin-sensitizing effects. Limited clinical data suggest that these compounds can also improve the serum lipid profile in patients with homozygous familial hypercholesterolemia (HoFH). The accumulation of unsecreted fat in the liver and intestinal lumen is associated with elevation of aminotransferases and steatorrhea. Liver steatosis can be avoided by the use of intestine-specific MTP inhibitors, while steatorrhea by low-fat diet. Future indications for these developing drugs may include dyslipidemia associated with insulin resistant states, familial combined hyperlipidemia and HoFH. Future clinical trials are warranted to assess the efficacy and safety of MTP inhibitors in various clinical states.

The discovery of PCSK9 in 2003 and its identification as the third protagonist responsible for ADH opened many new avenues of research in the cardiovascular field. Liver PCSK9 binds the LDLR and promotes its degradation in the endosomal/lysosomal pathway. A higher activity of PCSK9 leads to lower liver LDLR levels, resulting in a reduction in LDL-uptake from circulation, and thus in hypercholesterolemia and associated atherosclerosis. Although PCSK9 mutations are rare, their associated phenotypes can be devastating. The most powerful PCSK9 gain-of-function mutation, D374Y, is responsible for LDL cholesterol (LDLc) levels of ~10 mmol/L versus ~3 mmol/L in normal subjects. The aim of this manuscript is to review the available literature on the identification and pharmacological applications of potent inhibitors of PCSK9 function and/or activity, and to present the latest data on the ongoing clinical trials, mostly related to the use of monoclonal antibodies (mAb) that interfere with PCSK9 function on the LDLR, resulting in a significant drop in circulating LDLc. The clinical data, so far, are very encouraging with Phase-2 trials from various pharmaceutical companies showing a drop of >60% in LDLc for at least 2 weeks after a single injection of a humanized PCSK9 mAb in the presence or absence of adjunct statin therapy. In view of the absence of overt toxicity associated with this treatment Phase-3 clinical trials have started with >20,000 individuals being tested and anticipated primary outcomes results should be forthcoming by 2016. Other approaches including the use of recombinant adnectins, antisense RNAi or small molecule inhibitors are also undergoing early pre-clinical testing or are already in Phase-1 clinical trials. Very recent data revealed that absence of PCSK9 can be protective against melanoma invasion in mouse liver, and that this is due to lower circulating LDLc. This opens the door to novel applications of PCSK9 inhibitors/silencers in cancer/metastasis.