Development of functionalized hollow microporous organic capsules encapsulating morphine - an in vitro and in vivo study.

Microporous organic capsules with hollow interiors have received enormous attention due to their unusual encapsulation efficiency to confine chemicals within their hollow cavities and prompted controlled release by circumventing their ripening or poisoning. To this end, herein, we report the design and synthesis of carboxylic group functionalized hollow microporous organic capsules (HMOCs) using a facile emulsion polymerization technique that show extraordinary high encapsulation efficiency (up to 98%) of morphine·HCl and its promising prolonged release. The functionalized HMOCs are found to release the drug at a rate which is proportional to the amount of drug remaining in its interior. Due to the presence of hollow and porous morphologies, they possess high BET surface areas, i.e. up to 974 m2 g-1. Moreover, the in vivo results showed that functionalized HMOCs can offer slow release of active drug molecules and attenuate the level of writhing response over 72 h of intraperitoneal injection. The functionalized HMOCs, therefore, present a new class of potential drug delivery systems that can maintain the slow and prolonged release of analgesics by lowering the dosage and avoid frequent administration.

Inherited cardiomyopathies caused by troponin mutations.

Genetic investigations of cardiomyopathy in the recent two decades have revealed a large number of mutations in the genes encoding sarcomeric proteins as a cause of inherited hypertrophic cardiomyopathy (HCM), dilated cardiomyopathy (DCM), or restrictive cardiomyopathy (RCM). Most functional analyses of the effects of mutations on cardiac muscle contraction have revealed significant changes in the Ca(2+)-regulatory mechanism, in which cardiac troponin (cTn) plays important structural and functional roles as a key regulatory protein. Over a hundred mutations have been identified in all three subunits of cTn, i.e., cardiac troponins T, I, and C. Recent studies on cTn mutations have provided plenty of evidence that HCM- and RCM-linked mutations increase cardiac myofilament Ca(2+) sensitivity, while DCM-linked mutations decrease it. This review focuses on the functional consequences of mutations found in cTn in terms of cardiac myofilament Ca(2+) sensitivity, ATPase activity, force generation, and cardiac troponin I phosphorylation, to understand potential molecular and cellular pathogenic mechanisms of the three types of inherited cardiomyopathy.

A large-scale meta-analysis of the association between the ANKK1/DRD2 Taq1A polymorphism and alcohol dependence.

Alcohol dependence (AD) is a common neuropsychiatric disorder with high heritability. A number of studies have analyzed the association between the Taq1A polymorphism (located in the gene cluster ANKK1/DRD2) and AD. In the present study, we conducted a large-scale meta-analysis to confirm the association between the Taq1A polymorphism and the risk for AD in over 18,000 subjects included in 61 case-control studies that were published up to August 2012. Our meta-analysis demonstrated both allelic and genotypic association between the Taq1A polymorphism and AD susceptibility [allelic: P(Z) = 1.1 × 10(-5), OR = 1.19; genotypic: P(Z) = 3.2 × 10(-5), OR = 1.24]. The association remained significant after adjustment for publication bias using the trim and fill method. Sensitivity analysis showed that the effect size of the Taq1A polymorphism on AD risk was moderate and not influenced by any individual study. The pooled odds ratio from published studies decreased with the year of publication, but stabilized after the year 2001. Subgroup analysis indicated that publication bias could be influenced by racial ancestry. In summary, this large-scale meta-analysis confirmed the association between the Taq1A polymorphism and AD. Future studies are required to investigate the functional significance of the ANKK1/DRD2 Taq1A polymorphism in AD.

[Physiology and pathophysiology of Na⁺/HCO3⁻ cotransporter NBCe1].

Na⁺/HCO3⁻ cotransporter NBCe1 is an electrogenic member of the solute carrier 4 (SLC4) family and plays important roles in intracellular pH regulation as well as transepithelial HCO3⁻ movement. The physiological and pathological significance of NBCe1 has been well established by genetic studies with humans as well as knock-out study with mouse. NBCe1 is expressed in diverse tissues in mammals. The transporter plays an essential role in the maintenance of acid-base homeostasis in our body, being responsible for more ~80% of HCO3⁻ reabsorption in the proximal renal tubule. In humans, a number of SLC4A4 mutations have been associated with proximal renal tubule acidosis that is often accompanied with short stature, ocular abnormalities (including cataract, glaucoma, and band keratopathy), migraine, and/or defects in dental enamel development. In the present article, we review the molecular physiology, the structure/function relationship, the mechanisms underlying the functional regulation of NBCe1, as well as the physiological and pathological roles of the transporter.

Biological actions of green tea catechins on cardiac troponin C.

BACKGROUND AND PURPOSE: Catechins, biologically active polyphenols in green tea, are known to have a protective effect against cardiovascular diseases. In this study, we investigated direct actions of green tea catechins on cardiac muscle function to explore their uses as potential drugs for cardiac muscle disease. EXPERIMENTAL APPROACH: The effects of catechins were systematically investigated on the force-pCa relationship in skinned cardiac muscle fibres to determine their direct effects on cardiac myofilament contractility. The mechanisms of action of effective catechins were investigated using troponin exchange techniques, quartz crystal microbalance, nuclear magnetic resonance and a transgenic mouse model. KEY RESULTS: (-)-Epicatechin-3-gallate (ECg) and (-)-epigallocatechin-3-gallate (EGCg), but not their stereoismers (-)-catechin-3-gallate and (-)-gallocatechin-3-gallate, decreased cardiac myofilament Ca(2+) sensitivity probably through its interaction with cardiac troponin C. EGCg restored cardiac output in isolated working hearts by improving diastolic dysfunction caused by increased myofilament Ca(2+) sensitivity in a mouse model of hypertrophic cardiomyopathy. CONCLUSIONS AND IMPLICATIONS: The green tea catechins, ECg and EGCg, are Ca(2+) desensitizers acting through binding to cardiac troponin C. These compounds might be useful compounds for the development of therapeutic agents to treat the hypertrophic cardiomyopathy caused by increased Ca(2+) sensitivity of cardiac myofilaments.

Up-regulation of type 2 iodothyronine deiodinase in dilated cardiomyopathy.

AIMS: Thyroid hormone (TH) has prominent effects on the heart, and hyperthyroidism is occasionally found to be a cause of dilated cardiomyopathy (DCM). We aim to explore the potential role of TH in the pathogenesis of DCM. METHODS AND RESULTS: The pathophysiological role of TH in the heart was investigated using a knock-in mouse model of inherited DCM with a deletion mutation DeltaK210 in the cardiac troponin T gene. Serum tri-iodothyronine (T(3)) levels showed no significant difference between wild-type (WT) and DCM mice, whereas cardiac T(3) levels in DCM mice were significantly higher than those in WT mice. Type 2 iodothyronine deiodinase (Dio2), which produces T(3) from thyroxin, was up-regulated in the DCM mice hearts. The cAMP levels were increased in DCM mice hearts, suggesting that transcriptional up-regulation of Dio2 gene is mediated through the evolutionarily conserved cAMP-response element site in its promoter. Propylthiouracil (PTU), an anti-thyroid drug, prevented the hypertrophic remodelling of the heart in DCM mice and improved their cardiac function and life expectancy. Akt and p38 mitogen-activated protein kinase (p38 MAPK) phosphorylation increased in the DCM mice hearts and PTU treatment significantly reduced the phosphorylation levels, strongly suggesting that Dio2 up-regulation is involved in cardiac remodelling in DCM through activating the TH-signalling pathways involving Akt and p38 MAPK. Dio2 gene expression was also markedly up-regulated in the mice hearts developing similar eccentric hypertrophy after myocardial infarction. CONCLUSION: Local hyperthyroidism via transcriptional up-regulation of the Dio2 gene may be an important underlying mechanism for the hypertrophic cardiac remodelling in DCM.

Phosphorylation of cardiac troponin I at protein kinase C site threonine 144 depresses cooperative activation of thin filaments.

There is evidence for PKC-dependent multisite phosphorylation of cardiac troponin I (cTnI) at Ser-23 and Ser-24 (also PKA sites) in the cardiac-specific N-terminal extension and at Thr-144, a unique residue in the inhibitory region. The functional effect of these phosphorylations in combination is of interest in view of data indicating intramolecular interaction between the N-terminal extension and the inhibitory region of cTnI. To determine the role of PKC-dependent phosphorylation of cTnI on sarcomeric function, we measured contractile regulation at multiple levels of complexity. Ca(2+) binding to thin filaments reconstituted with either cTnI(wild-type) or pseudo-phosphorylated cTnI(S23D/S24D), cTnI(T144E), and cTnI(S23D/S24D/T144E) was determined. Compared with controls regulated by cTnI(wild-type), thin filaments with cTnI(S23D/S24D) and cTnI(S23D/S24D/T144E) exhibited decreased Ca(2+) sensitivity. In contrast, there was no significant difference between Ca(2+) binding to thin filaments with cTnI(wild-type) and with cTnI(T144E). Studies of the pCa-force relations in skinned papillary fibers regulated by these forms of cTnI yielded similar results. However, in both the Ca(2+) binding measurements and the skinned fiber tension measurements, the presence of cTnI(S23D/S24D/T144E) induced a much lower Hill coefficient than either wild type, S23D/S24D, or T144E. These data highlight the importance of thin filament-based cooperative mechanisms in cardiac regulation, with implications for mechanisms of control of function in normal and pathological hearts.

Therapeutic effect of {beta}-adrenoceptor blockers using a mouse model of dilated cardiomyopathy with a troponin mutation.

AIMS: Extensive clinical studies have demonstrated that beta-adrenoceptor blocking agents (beta-blockers) are beneficial in the treatment of chronic heart failure, which is due to various aetiologies, including idiopathic dilated cardiomyopathy (DCM) and ischaemic heart disease. However, little is known about the therapeutic efficacy of beta-blockers in the treatment of the inherited form of DCM, of which causative mutations have recently been identified in various genes, including those encoding cardiac sarcomeric proteins. Using a mouse model of inherited DCM with a troponin mutation, we aim to study the treatment benefits of beta-blockers. METHODS AND RESULTS: Three different types of beta-blockers, carvedilol, metoprolol, and atenolol, were orally administered to a knock-in mouse model of inherited DCM with a deletion mutation DeltaK210 in the cardiac troponin T gene (TNNT2). Therapeutic effects were examined on the basis of survival and myocardial remodelling. The lipophilic beta(1)-selective beta-blocker metoprolol was found to prevent cardiac dysfunction and remodelling and extend the survival of knock-in mice. Conversely, both the non-selective beta-blocker carvedilol and the hydrophilic beta(1)-selective beta-blocker atenolol had no beneficial effects on survival and myocardial remodelling in this mouse model of inherited DCM. CONCLUSION: The highly lipophilic beta(1)-selective beta-blocker metoprolol, known to prevent ventricular fibrillation via central nervous system-mediated vagal activation, may be especially beneficial to DCM patients showing a family history of frequent sudden cardiac death, such as those with a deletion mutation DeltaK210 in the TNNT2 gene.

Targeted disruption of the cardiac troponin T gene causes sarcomere disassembly and defects in heartbeat within the early mouse embryo.

Cardiac troponin T (cTnT) is a component of the troponin (Tn) complex in cardiac myocytes, and plays a regulatory role in cardiac muscle contraction by anchoring two other Tn components, troponin I (TnI) and troponin C, to tropomyosin (Tm) on the thin filaments. In order to determine the in vivo function of cTnT, we created a null cTnT allele in the mouse TNNT2 locus. In cTnT-deficient (cTnT(-/-)) cardiac myocytes, the thick and thin filaments and alpha-actinin-positive Z-disk-like structures were not assembled into sarcomere, causing early embryonic lethality due to a lack of heartbeats. TnI was dissociated from Tm in the thin filaments without cTnT. In spite of loss of Tn on the thin filaments, the cTnT(-/-) cardiac myocytes showed regular Ca(2+)-transients. These findings indicate that cTnT plays a critical role in sarcomere assembly during myofibrillogenesis in the embryonic heart, and also indicate that the membrane excitation and intracellular Ca(2+) handling systems develop independently of the contractile system. In contrast, heterozygous cTnT(+/-) mice had a normal life span with no structural and functional abnormalities in their hearts, suggesting that haploinsufficiency could not be a potential cause of cardiomyopathies, known to be associated with a variety of mutations in the TNNT2 locus.

Knock-in mouse model of dilated cardiomyopathy caused by troponin mutation.

We created knock-in mice in which a deletion of 3 base pairs coding for K210 in cardiac troponin (cTn)T found in familial dilated cardiomyopathy patients was introduced into endogenous genes. Membrane-permeabilized cardiac muscle fibers from mutant mice showed significantly lower Ca(2+) sensitivity in force generation than those from wild-type mice. Peak amplitude of Ca(2+) transient in cardiomyocytes was increased in mutant mice, and maximum isometric force produced by intact cardiac muscle fibers of mutant mice was not significantly different from that of wild-type mice, suggesting that Ca(2+) transient was augmented to compensate for decreased myofilament Ca(2+) sensitivity. Nevertheless, mutant mice developed marked cardiac enlargement, heart failure, and frequent sudden death recapitulating the phenotypes of dilated cardiomyopathy patients, indicating that global functional defect of the heart attributable to decreased myofilament Ca(2+) sensitivity could not be fully compensated by only increasing the intracellular Ca(2+) transient. We found that a positive inotropic agent, pimobendan, which directly increases myofilament Ca(2+) sensitivity, had profound effects of preventing cardiac enlargement, heart failure, and sudden death. These results verify the hypothesis that Ca(2+) desensitization of cardiac myofilament is the absolute cause of the pathogenesis of dilated cardiomyopathy associated with this mutation and strongly suggest that Ca(2+) sensitizers are beneficial for the treatment of dilated cardiomyopathy patients affected by sarcomeric regulatory protein mutations.

Drastic Ca2+ sensitization of myofilament associated with a small structural change in troponin I in inherited restrictive cardiomyopathy.

Six missense mutations in human cardiac troponin I (cTnI) were recently found to cause restrictive cardiomyopathy (RCM). We have bacterially expressed and purified these human cTnI mutants and examined their functional and structural consequences. Inserting the human cTnI into skinned cardiac muscle fibers showed that these mutations had much greater Ca2+-sensitizing effects on force generation than the cTnI mutations in hypertrophic cardiomyopathy (HCM). The mutation K178E in the second actin-tropomyosin (Tm) binding region showed a particularly potent Ca2+-sensitizing effect among the six RCM-causing mutations. Circular dichroism and nuclear magnetic resonance spectroscopy revealed that this mutation does not extensively affect the structure of the whole cTnI molecule, but induces an unexpectedly subtle change in the structure of a region around the mutated residue. The results indicate that the K178E mutation has a localized effect on a structure that is critical to the regulatory function of the second actin-Tm binding region of cTnI. The present study also suggests that both HCM and RCM involving cTnI mutations share a common feature of increased Ca2+ sensitivity of cardiac myofilament, but more severe change in Ca2+ sensitivity is associated with the clinical phenotype of RCM.

Cardiac troponin T mutation R141W found in dilated cardiomyopathy stabilizes the troponin T-tropomyosin interaction and causes a Ca2+ desensitization.

A missense mutation R141W in the strong tropomyosin-binding region of cardiac troponin T (cTnT) has recently been reported to cause dilated cardiomyopathy (DCM), following the first report of a DCM-causing deletion mutation DeltaK210. To clarify the molecular mechanism for the pathogenesis of DCM caused by this novel mutation in cTnT gene, functional analyses were made on the recombinant human cTnT mutant proteins. Exchanging human wild-type and mutant cTnTs into rabbit skinned cardiac muscle fibers revealed that R141W mutation resulted in a decrease in the Ca(2+) sensitivity of force generation, as in the case of DeltaK210 mutation lying outside the strong tropomyosin-binding region. In contrast, a missense mutation R94L in the vicinity of the strong tropomyosin-binding region associated with hypertrophic cardiomyopathy (HCM) resulted in an increase in the Ca(2+) sensitivity of force generation, as in the case of the other HCM-causing mutations in cTnT reported previously. An assay using a quartz-crystal microbalance (a very sensitive mass-measuring device) revealed that R141W mutation increased the affinity of cTnT for alpha-tropomyosin by approximately three times, whereas an HCM-causing mutation DeltaE160 in the strong tropomyosin-binding region, as well as DeltaK210 and R94L mutations, had no effects on the interaction between cTnT and alpha-tropomyosin. Since cTnT has an important role in structurally integrating cardiac troponin I (cTnI) into the thin filaments via its two-way interactions with cTnI and tropomyosin, the present results suggest that R141W mutation in the strong tropomyosin-binding region in cTnT strengthens the integrity of cTnI in the thin filament by stabilizing the interaction between cTnT and tropomyosin, which might allow cTnI to inhibit the thin filament more effectively, leading to a Ca(2+) desensitization.