Distinct Influences of Carboxyl Terminal Segment Structure on Function in the Two Isoforms of Prostaglandin H Synthase

Static retention of the lumenal monotopic membrane protein torsinA in the endoplasmic reticulum

TorsinA is a membrane-associated enzyme in the endoplasmic reticulum (ER) lumen that is mutated in DYT1 dystonia. How it remains in the ER has been unclear. We report that a hydrophobic N-terminal domain (NTD) directs static retention of torsinA within the ER by excluding it from ER exit sites, as has been previously reported for short transmembrane domains (TMDs). We show that despite the NTD's physicochemical similarity to TMDs, it does not traverse the membrane, defining torsinA as a lumenal monotopic membrane protein and requiring a new paradigm to explain retention. ER retention and membrane association are perturbed by a subset of nonconservative mutations to the NTD, suggesting that a helical structure with defined orientation in the membrane is required. TorsinA preferentially enriches in ER sheets, as might be expected for a lumenal monotopic membrane protein. We propose that the principle of membrane-based protein sorting extends to monotopic membrane proteins, and identify other proteins including the monotopic lumenal enzyme cyclooxygenase 1 (prostaglandin H synthase 1) that share this mechanism of retention with torsinA.

Antiplatelet drug therapy: role of pharmacodynamic and genetic testing

Antiplatelet therapy represents the cornerstone of treatment for the short- and long-term prevention of atherothrombotic disease processes, in particular in high-risk settings such as in patients with acute coronary syndrome and those undergoing percutaneous coronary intervention. Currently, dual antiplatelet therapy with aspirin and clopidogrel represents the most commonly used treatment regimen in these settings. However, a considerable number of patients continue to experience adverse outcomes, including both bleeding and recurrent ischemic events. Numerous investigations have demonstrated that this phenomenon may be, in part, attributed to the broad variability in individual response profiles to this standard antiplatelet treatment regimen, as identified by various assays of platelet function testing. In addition, recent studies have demonstrated that genetic polymorphisms may also have an important role in determining levels of platelet inhibition and may be considered as a tool to identify patients at risk of adverse events. This article provides an overview on antiplatelet drug response variability, an update on definitions, including the role of pharmacodynamic testing, underlying mechanisms – with emphasis on recent understandings on pharmacogenetics and drug–drug interactions – and current and future perspectives on individualized antiplatelet therapy.

Impact of genetic polymorphisms on platelet function and aspirin resistance

Genetic polymorphisms may affect platelets' responses to the antiplatelet therapy. Our aim was to determine the role of genetic polymorphisms on aspirin resistance in patients with coronary heart disease (CHD). A total of 126 consecutive patients (35-85 years old, 32% women) with chronic stable CHD was enrolled in the study. Platelet function assays were realized by the platelet function analyzer (PFA)-100 with collagen and epinephrine (Col/Epi) and collagen and adenosine diphosphate (Col/ADP) cartridges. Aspirin resistance was defined as having a closure time of less than 186 s with Col/Epi cartridges despite regular aspirin therapy. Factor V, prothrombin, factor XIII, beta-fibrinogen, plasminogen activator inhibitor I (PAI-1), glycoprotein IIIa, methylene tetrahydrofolate reductase, ACE and ApoB gene polymorphisms were determined by three consecutive steps: isolation and amplification of DNA and reverse hybridization. We determined that 30 patients (23.8%) had aspirin resistance by the PFA-100. Mean closure time measured with the Col/ADP cartridges was 74 +/- 12 s (51-104 s). Ten of the 30 patients with aspirin resistance were women (33.3%). Genetic polymorphisms were determined in 30 aspirin-resistant and 17 aspirin-sensitive patients. No statistically significant relationship was determined between aspirin resistance and the genetic panel. In our study we did not determine a significant relationship between the aspirin resistance and factor V, prothrombin, factor XIII, beta-fibrinogen, PAI-1, glycoprotein IIIa, methylene tetrahydrofolate reductase, ACE and ApoB gene polymorphisms.

Direct evidence of the cyclooxygenase pathway of prostaglandin synthesis in arthropods: genetic and biochemical characterization of two crustacean cyclooxygenases

Prostaglandins, well-known lipid mediators in vertebrate animals, have also shown to play certain regulatory roles in insects and other arthropods acting on reproduction, immune system and ion transport. However, knowledge of their biosynthetic pathways in arthropods is lacking. In the present study, we report the cloning and expression of cyclooxygenase (COX) from amphipod crustaceans Gammarus spp and Caprella spp. The amphipod COX proteins contain key residues shown to be important for cyclooxygenase and peroxidase activities. Differently from all other known cyclooxygenases the N-terminal signal sequence of amphipod enzymes is not cleaved during protein expression in mammalian cells. The C-terminus of amphipod COX is shorter than that of mammalian isoforms and lacks the KDEL(STEL)-type endoplasmic reticulum retention/retrieval signal. Despite that, amphipod COX proteins are N-glycosylated and locate similarly to the vertebrate COX on the endoplasmic reticulum and nuclear envelope. Both amphipod COX mRNAs encode functional cyclooxygenases that catalyze the transformation of arachidonic acid into prostaglandins. Using bioinformatic analysis we identified a COX-like gene from the human body louse Pediculus humanus corporis genome that encodes a protein with about 30% sequence identity with human COX-1 and COX-2. Although the COX gene is known to be absent from genomes of Drosophila sp., Aedes aegypti, Bombyx mori, and other insects, our studies establish the existence of the COX gene in certain lineages within the insect world.

Pharmacogenetics in cardiovascular antithrombotic therapy

Thrombosis is the most important underlying mechanism of coronary artery disease and embolic stroke. Hence, antithrombotic therapy is widely used in these scenarios. However, not all patients achieve the same degree of benefit from antithrombotic agents, and a considerable number of treated patients will continue to experience a new thrombotic event. Such lack of clinical benefit may be related to a wide variability of responses to antithrombotic treatment among individuals (i.e., interindividual heterogeneity). Several factors have been identified in this interindividual heterogeneity in response to antithrombotic treatment. Pharmacogenetics has emerged as a field that identifies specific gene variants able to explain the variability in patient response to a given drug. Polymorphisms affecting the disposition, metabolism, transporters, or targets of a drug all can be implicated in the modification of an individual's antithrombotic drug response and therefore the safety and efficacy of the aforementioned drug. The present paper reviews the modulating role of different polymorphisms on individuals' responses to antithrombotic drugs commonly used in clinical practice.

An active triple-catalytic hybrid enzyme engineered by linking cyclo-oxygenase isoform-1 to prostacyclin synthase that can constantly biosynthesize prostacyclin, the vascular protector

It remains a challenge to achieve the stable and long-term expression (in human cell lines) of a previously engineered hybrid enzyme [triple-catalytic (Trip-cat) enzyme-2; Ruan KH, Deng H & So SP (2006) Biochemistry45, 14003-14011], which links cyclo-oxygenase isoform-2 (COX-2) to prostacyclin (PGI(2)) synthase (PGIS) for the direct conversion of arachidonic acid into PGI(2) through the enzyme's Trip-cat functions. The stable upregulation of the biosynthesis of the vascular protector, PGI(2), in cells is an ideal model for the prevention and treatment of thromboxane A(2) (TXA(2))-mediated thrombosis and vasoconstriction, both of which cause stroke, myocardial infarction, and hypertension. Here, we report another case of engineering of the Trip-cat enzyme, in which human cyclo-oxygenase isoform-1, which has a different C-terminal sequence from COX-2, was linked to PGI(2) synthase and called Trip-cat enzyme-1. Transient expression of recombinant Trip-cat enzyme-1 in HEK293 cells led to 3-5-fold higher expression capacity and better PGI(2)-synthesizing activity as compared to that of the previously engineered Trip-cat enzyme-2. Furthermore, an HEK293 cell line that can stably express the active new Trip-cat enzyme-1 and constantly synthesize the bioactive PGI(2) was established by a screening approach. In addition, the stable HEK293 cell line, with constant production of PGI(2), revealed strong antiplatelet aggregation properties through its unique dual functions (increasing PGI(2) production while decreasing TXA(2) production) in TXA(2) synthase-rich plasma. This study has optimized engineering of the active Trip-cat enzyme, allowing it to become the first to stably upregulate PGI(2) biosynthesis in a human cell line, which provides a basis for developing a PGI(2)-producing therapeutic cell line for use against vascular diseases.

Site-specific proteolysis of cyclooxygenase-2: A putative step in inflammatory prostaglandin E2 biosynthesis

Cyclooxygenase-2 (COX-2) catalyzes the rate-limiting step in inflammatory prostanoid biosynthesis. Transcriptional, post-transcriptional, and post-translational covalent modifications have been defined as important levels of regulation for COX-2 gene expression. Here, we describe a novel regulatory mechanism in primary human cells involving regulated, sequence-specific proteolysis of COX-2 that correlates with its catalytic activity and ultimately, the biosynthesis of prostaglandin E(2) (PGE(2)). Proinflammatory cytokines induced COX-2 expression and its proteolysis into stable immunoreactive fragments of 66, 42-44, 34-36, and 28 kDa. Increased COX-2 activity (PGE(2) release) was observed coincident with the timing and degree of COX-2 proteolysis with correlation analysis confirming a linear relationship (R(2) = 0.941). Inhibition of induced COX-2 activity with non-steroidal anti-inflammatory drugs (NSAIDs) and COX-2 selective inhibitors also abrogated cleavage. To determine if NSAID inhibition of proteolysis was related to drug-binding-induced conformational changes in COX-2, we assayed COX-inactive NSAID derivatives that fail to bind COX-2. Interestingly, these compounds suppressed COX-2 activity and cleavage in a correlated manner, thus suggesting that the observed NSAID-induced inhibition of COX-2 cleavage occurred through COX-independent mechanisms, presumably through the inhibition of proteases involved in COX-2 processing. Corroborating this observation, COX-2 cleavage and activity were mutually suppressed by calpain/cathepsin protease inhibitors. Our data suggest that the nascent intracellular form of COX-2 may undergo limited proteolysis to attain full catalytic capacity.

A review of aspirin resistance; definition, possible mechanisms, detection with platelet function tests, and its clinical outcomes

Aspirin (acetylsalicylic acid) is one of the main therapeutics in prevention of thrombo-embolic vascular events. Its efficiency is proved in the prevention of cardiovascular events. However, antiplatelet effect of aspirin is not absolute in all patients and some patients experience thrombo-embolic events despite aspirin. These patients are clinically called as aspirin resistant or aspirin non-responders. Globally, a lot of people are affected by aspirin resistance according to the high prevalence of athero-thrombotic vascular diseases. A prevalence of 5.5-45% in patients with various cardiovascular disease by different laboratory methods has been reported for aspirin resistance. Clinical outcome of aspirin resistance has been demonstrated in patients with different vascular diseases. Detection of platelet function in patients treated with aspirin may be necessary in the prediction of clinical outcome. Point of care methods, which have correlated results with the standard light transmittance aggregometry may be appropriate choices in the detection of platelets' response to antiplatelet therapy. Adequate additional therapies may reduce atherothrombotic risks and major cardiovascular events rate in aspirin resistant subjects. None of the current researches advised the cessation of aspirin therapy. There is need to investigate the efficacy of additional adenosine diphosphate receptor antagonists or newer antiplatelet agents in aspirin resistant subjects. The intent of this paper is to review the literature discussing possible mechanisms, determination techniques, and clinical effects of aspirin resistance.

The structure of mammalian cyclooxygenases

Cyclooxygenases-1 and -2 (COX-1 and COX-2, also known as prostaglandin H2 synthases-1 and -2) catalyze the committed step in prostaglandin synthesis. COX-1 and -2 are of particular interest because they are the major targets of nonsteroidal antiinflammatory drugs (NSAIDs) including aspirin, ibuprofen, and the new COX-2-selective inhibitors. Inhibition of the COXs with NSAIDs acutely reduces inflammation, pain, and fever, and long-term use of these drugs reduces the incidence of fatal thrombotic events, as well as the development of colon cancer and Alzheimer's disease. In this review, we examine how the structures of COXs relate mechanistically to cyclooxygenase and peroxidase catalysis and how alternative fatty acid substrates bind within the COX active site. We further examine how NSAIDs interact with COXs and how differences in the structure of COX-2 result in enhanced selectivity toward COX-2 inhibitors.

Comparison of the properties of prostaglandin H synthase-1 and -2

Biosynthesis of prostanoid lipid signaling agents from arachidonic acid begins with prostaglandin H synthase (PGHS), a hemoprotein in the myeloperoxidase family. Vertebrates from humans to fish have two principal isoforms of PGHS, termed PGHS-1 and-2. These two isoforms are structurally quite similar, but they have very different pathophysiological roles and are regulated very differently at the level of catalysis. The focus of this review is on the structural and biochemical distinctions between PGHS-1 and-2, and how these differences relate to the functional divergence between the two isoforms.

Aspirin resistance and genetic polymorphisms

Differences in genetic makeup or polymorphisms can affect individual drug response. Detecting genetic variation may help predict how a patient will respond to a drug and could be used as a tool to select optimal therapy, tailor dosage regimens, and improve clinical outcomes. The data are replete relative to the therapeutic efficacy of aspirin (ASA) for the prevention of ischemic events. However, there is a paucity of published data on the relationship between polymorphisms and the clinical effects on ASA. Prothrombotic genetic variations that may contribute to ASA resistance, and increased risk of cardiovascular events may involve: (1) a polymorphism on the cyclooxygenase-1 (COX-1) gene affecting Ser529; (2) overexpression of COX-2 mRNA on platelets and endothelial cells; (3) polymorphism PLA1/A2 of the gene encoding glycoprotein IIIa (GPIIIa); and (4) the homozygous 807T (873A) polymorphism allied with increased density of platelet GP Ia/IIa collagen-receptor gene. Because of the possible increased risk of ischemic vascular events, carriers of these genetic polymorphisms may be resistant to the antithrombotic effects of ASA and should be considered for additional or alternative treatment.