Current Molecular Medicine - Volume 11, Issue 7, 2011

The prostacyclin receptor (IP - International Union of Pharmacology nomenclature) is a member of the seven transmembrane G-protein coupled receptor (GPCR) superfamily. Recent concerns with selective and non-selective COX-1/COX-2 inhibition have exposed an important cardioprotective role for IP in preventing atherothrombosis. Receptor dysfunction (genetic variants) or reduced signaling (COX-2 inhibition) in high cardiovascular risk patients leads to increased cardiovascular events. These clinical observations have also been confirmed genetically by mouse knockout studies. Thus, receptor regulation is paramount in ensuring correct function in the prevention of atherothrombosis. This review summarizes recent literature on how this important receptor is regulated, from transcription to transport (to and from the membrane surface). These regulatory processes are critical in ensuring that IP receptors are adequately expressed and functional on the cell surface.

Glaucoma is a major cause of irreversible blindness, affecting more than 70 million individuals worldwide. Elevated intraocular pressure (IOP) is a major risk factor in the development of glaucoma and in the progression of glaucomatous damage. High IOP usually occurs as a result of an increase in aqueous humor outflow resistance in trabecular meshwork (TM). Primary open angle glaucoma (POAG) is characterized by quantifiable parameters including the IOP, the aqueous outflow facility, and geometric measurements of the optic disc and visual defects. Morphological and biochemical analyses of the TM of POAG patients revealed loss of cells, increased accumulation of extracellular matrix (ECM), changes in the cytoskeleton, cellular senescence and the process of subclinical inflammation. Various biochemical and molecular biology biomarkers of TM cells senescence are considered in the article. Oxidative stress is becoming an important factor more likely to be involved in the pathogenesis of POAG. Treatment of TM cells with oxidative stress induced POAG-typical changes like ECM accumulation, cell death, disarrangement of the cytoskeleton, advanced senescence and the release of inflammatory markers. Oxidative stress is able to induce characteristic glaucomatous TM changes and these oxidative stress-induced TM changes can be minimized by the use of antioxidants, such as carnosine -related analogues and IOP-lowering substances. There is evidence demonstrating that carnosine related analogues may have antioxidative capacities, can prevent cellular senescence and the attrition of telomeres during the action of oxidative stress. Prevention of oxidative stress exposure to the TM with N-acetylcarnosine ophthalmic prodrug of carnosine and oral formulation of non-hydrolized carnosine may help to reduce the progression of POAG. The previous work has demonstrated that carnosine is able to reach the TM directly via the transcorneal and systemic pathways of administration with N-acetylcarnosine ophthalmic prodrug and oral formulation of non-hydrolized carnosine. We suggest in this article that dual therapy with N-acetylcarnosine lubricant eye drops, oral formulation of nonhydrolized carnosine combined with anti-glaucoma adrenergic drug may become the first-line therapy in glaucoma due to their efficiency in reducing IOP, prevention and reversal of oxidative stress-induced damages in TM and the low rate of severe side effects during combined treatment.

Metastatic melanoma is one of the most intractable tumors, with all current regimens showing limited survival impact. Failure of most agents is attributed to development of therapy resistance. Accumulated evidence points to the apoptotic defect of melanoma cells and the surge of survival signals stimulated by cytotoxic drugs, as a way that tumors circumvent cytotoxic chemotherapy. An overview of inhibitors developed against these growth/survival factors, which are potential partners to be combined with systemic chemotherapy, will be discussed. The escape mechanism from molecular inhibitors also suggests a “vertical” or “horizontal” combination of molecularly targeted therapies. A better understanding of the interactions between simultaneously used regimens and of the rationale for combination therapy will provide new insights to improve survival and quality of life in patients with advanced melanoma.

Hepatocellular carcinoma (HCC) is the fifth most common cancer worldwide, with a poor prognosis and limited therapeutic options. Due to its overexpression in the majority of HCCs, alpha-fetoprotein (AFP) represents one of the most useful markers for hepatocarcinomas and for monitoring patients' response to therapy. Although it was earlier reported that AFP has immunosuppressive properties, it has been recently demonstrated that AFP induces spontaneous T and B cells responses in HCC patients. The characterization of AFP-immunogenic epitopes gives the opportunity to design AFP-based cancer vaccines for human HCC. The activity of AFP-based vaccines has been investigated in HCC mouse models in order to develop novel strategies to treat patients with HCC. This review will discuss the rationale for using the AFP-based vaccination strategy and recent results corroborating the usefulness of AFP vaccines as a potential tool for cancer therapy.

Many cellular processes depend on the establishment of selective stable or transient interactions between proteins. Therefore, the ability to identify and characterize these contacts in physiologically relevant environments is crucial to understanding the networks of contacts that allow the transmission and integration of biological information in living cells. Protein-fragment complementation assays (PCA) have emerged as approaches that report on the proximity of two given proteins in the cell at a given location and time. In particular, bimolecular fluorescence complementation (BIFC) allows noninvasive imaging of protein binding in living cells at high spatial resolution and without the requirement for exogenous substrates. In the present review, we discuss PCA and BIFC fundamentals, the implementation of BIFC assays and selected applications of BIFC in drug discovery, developmental studies or neurological disorders.

The prevalence of asthma and costs of its care have been continuously increasing, but novel therapeutic options to treat this inflammatory disease have not been brought to the US market. Current therapies such as inhaled steroids, long-acting beta-agonist bronchodilators, antihistamines and immunomodulators may control the symptoms of allergic asthma but fail to modify the underlying disease. Excessive use of steroids and other immunosuppresents alter the patient's quality of life, produce undesirable toxicities, and increase the risk of other pathologies such as diabetes. Hence novel therapeutic options to manage asthma are desirable. In the present review, we have discussed the role of the polyol pathway enzyme aldose reductase (AR) in the amplification of allergic airway inflammation. Recent studies have indicated that AR inhibition prevents the NF-κB-dependent generation of pro-inflammatory cytokines and chemokines in mouse models of allergic airway inflammation indicating the potential use of AR inhibition as a novel tool to control allergic responses. Since orally available AR inhibitors have already undergone phase III clinical trials for diabetic neuropathy and appear to have a manageable side effects profile, they could be readily developed as potential new drugs for the treatment of asthma and related complications.