GPCR Compound Library

Until recently, the rat model lacked genetic engineering tools for introducing targeted genetic mutations. But in the last years, we and others have used in rats sequence-specific nucleases, such as meganucleases, zinc-finger nucleases, TALENs and CRISPRs/Cas9, to efficiently generate precise gene mutations. To generate dystrophin-deficient rats, we generated TALENs for Dmd that were microinjected in rat zygotes allowing generation of two Dmdmdx rat lines. The muscles of both lines displayed undetectable levels of dystrophin as evaluated by western blot analysis and less than 5% of dystrophin positive fibers by immunohistochemistry. At 3 months of age, forelimb, hindlimb and diaphragm muscles showed severe fiber necrosis and a strong regeneration activity. At 7 months of age, regeneration activity was decreased and muscle showed abundant peri- and endomysial fibrosis with some adipose tissue infiltration. Muscle strength and spontaneous activity were decreased and fatigue was a prominent finding of muscle function analysis. Cardiac muscle was also affected with necrosis and fibrosis and showed signs of progressive dilated cardiomyopathy. Echocardiography showed significant concentric remodeling and alteration of diastolic function. These lesions in skeletal muscle and heart closely mimic those observed in DMD patients. These results indicate that Dmdmdx rats represent a new invaluable small animal model for pre-clinical research on DMD. DMD is the most common neuromuscular disorder, accounting for approximately 30% of muscular dystrophy patients. The liver carries out a diverse range of necessary functions, such as homeostasis, metabolism and detoxification. As much of the research on the liver is human-centric, whether for the elucidation of GS-5734 mechanisms, translational research or cell-based therapy, isolated human liver cells remain an important in vitro model for basic and translational research. The usage of human hepatocytes comes with the additional advantage of following the 3R ethical framework to replace the use of research animals when possible. This is as the liver tissue used in this study was obtained from human elective liver resections. After resection, the tissue was immediately brought to a pathologist, who would take what was required for histopathological evaluation. The rest of the tissue, which is not needed, was designated as surgical waste. If a patient had signed an informed consent, this discarded tissue could then be collected for hepatocyte isolation. In order to successfully use human hepatocytes as an in vitro model or for cell-based therapy, hepatocytes must be obtained with good viability and hence quality.

It is a fact that a large proportion of HF R428 patients would trade increased length of life for increased quality of life, which in HF patients is directly linked to exercise capacity. Surprisingly, exercise dysfunction in HF patients is not directly related to severity of left ventricular dysfunction, intra-cardiac hemodynamics at rest or during exercise, or inadequate skeletal muscle blood flow. Instead, exercise dysfunction is directly related to abnormalities of the skeletal muscles themselves; in fact a skeletal myopathy has been described which includes a fiber shift from type I aerobic fibers to type II anaerobic fibers and decreased mitochondrial volume and metabolic function. Skeletal muscle function depends critically on both intact energy metabolism and on the robustness of the sequence of events linking the electrical with the mechanical activation of the muscle fibers. The role of metabolic deficiencies in skeletal muscle function in HF patients on optimal medical therapy has recently been questioned. We have recently reported marked abnormalities of several key proteins participating in the ECC process in humans with HF. Tacrolimus is the backbone of immunosuppressive drug used worldwide in organ transplantation and characterized by a narrow therapeutic range and high inter-individual variability in its pharmacokinetics. To achieve the desired target blood concentrations is of critical importance to avoid rejection and dose-related adverse effects after transplantation. The variability makes it difficult to establish an empirical dose regimen for this drug, especially in pediatric patients, in whom 100-fold variability in pharmacokinetic parameters and blood concentration after a fixed dose is routinely observed. Underexposure to TAC may result in immunosuppression failure and acute rejection in recipients. On the other hand, overexposure to it may put patients at risk for its considerable toxicity. Therefore, maintaining the drug exposure within this narrow safe therapeutic window becomes a critical aspect in patient management. Concerning the concept that young children need a higher TAC dose than adult patients, the blood TAC concentration should be monitored regularly to maintain a therapeutic range, when the risk of rejection is the highest. Although various factors, such as age, sex, body weight, drug interactions and other factors lead to the wide range of interpatient variability ineffective dosage of TAC, among them genetic factors play a critical role in the pharmacokinetic properties and therapeutic levels of TAC. Therapeutic drug monitoring of TAC in blood is necessary to provide an effective immunosuppression and avoid adverse effects after organ transplantation.

For instance HSA has been used as a model protein for numerous studies investigating protein/drug binding and protein/nano-particle interactions. Lot-to-lot variability may make any conclusions drawn from these or future studies using OsrHSA difficult to interpret. Furthermore, altered drug binding could be significant for the future consideration of heavily glycated OsrHSA with regards to individuals receiving large doses of recombinant albumin expressed in O. sativa. We also demonstrated that Sigma-Aldrich sourced OsrHSAs have dramatically improved thermal stability, due to the presence of FAs, when compared to other OsrHSAs, which could impact their function as biotherapeutics. However, the source and composition of these FAs or the potential for lot-to-lot variability in their composition have yet to be determined. These channels are composed by a multigene family of integral membrane proteins called connexins. So far, at least 20 Cx genes were identified in the mouse and human genome. Notably, communication through GJ channels has been recognized as an important mechanism for synchronizing neuronal networks in both physiological and pathological conditions. In fact, several evidences from animal models and human slices from epileptic patients indicate the participation of GJ channels in the generation and maintenance of epileptic seizures. Moreover, specific alterations of Cx expression have been described in tissue from epileptic patients and in experimental models. The aim of this study was to determine the involvement of GJ channels in the Talazoparib epileptiform activity induced by pilocarpine by examining the changes in electrophysiological patterns produced by uncoupling of these channels with carbenoxolone. After we established the participation of GJ in the ictal discharges, we thoroughly analyzed the regulation of gene expression, changes in protein levels, phosphorylation profile and distribution of the neuronal Cx36 and Cx45 and the glial Cx43, three of the most highly expressed Cxs in the rat hippocampus, during acute seizures and the epileptogenic process. We observed that pharmacological blockade of GJ channels decreases the epileptiform activity, which in turn regulates Cx gene expression, protein levels and phosphorylation. Thus, our results revealed a reciprocal, mutual regulation of Cx-mediated communication and the epileptiform phenomenon. The main purposes of this work were to demonstrate the involvement of GJ communication in the epileptiform activity and the possible alterations in Cx gene expression, protein levels, phosphorylation profile and distribution in the hippocampus triggered by pilocarpine. Indeed, our results showed that blockade of Cx channels produced antiepileptiform effects, indisputably correlating the GJ coupling with the epileptiform activity induced by pilocarpine. In spite of previous evidences in the literature regarding the anticonvulsant effects of GJ blockers, based on both in vitro and in vivo models, this is the first report addressing this issue in the pilocarpine model, which reproduces most of the characteristics of human temporal lobe epilepsy.

On the other end, our results showed also that TLQP peptides in the pituitary and hypothalamus could be up-regulated by the oestradiol/progesterone. These hormones regulate also somatostatin, and being TLQP peptides present in such neurones, it is possible that steroid hormones could modulate both TLQP and somatostatin by the same mechanisms. Regarding the role of TLQP peptides in the median eminence, in view of their close relation to somatostatin seen also in pancreas and stomach, we tried to elucidate a possible bioactivity of TLQP-21 on somatostatin and on its GHRH neurone targets. We found that TLQP-21 up-regulated the GHRH production suggesting that such peptide could act promoting the growth at the hypothalamic level. When adult male mice were chronically treated with TLQP-21, physiological, molecular and behavioral parameters related to the GH axis were investigated, however, TLQP-21 did not modulate the GH axis. One could hypothesize that TLQP-21 may regulate GHRH through somatostatin neurones selectively at the median eminence level, instead when the same peptide is injected, only a little part could reach the median eminence. Further experiments are needed to ascertain the precise role of TLQP-21 on the growth mechanisms and the possible connections with the cycle. Regarding the other VGF peptides, also C-and N-terminus peptides changed in the hypothalamus, pituitary and plasma. However, for these peptides is more difficult to hypothesize mechanisms of action in view of the rare information regarding their involvement on reproduction. It could be only suggested that these peptides could have a neuroendocrine and/or endocrine activity on the estrous cycle, and their presence into kisspeptin neurones is intriguing because of the importance of this hormone in PI-103 reproductive mechanisms. Furthermore, also the presence of PGH peptides in gonadotrophs, GnRH neurones, plasma and especially within the oocyte, needs more investigation. In conclusion, various VGF peptides may regulate the hypothalamus-pituitary complex via specific neuroendocrine mechanisms. In particular, for TLQP peptides we may hypothesize different possible interacting ways of action on the reproduction including endocrine pathways largely involving the ovary as well as paracrine/autocrine mechanisms at both the pituitary and ovary levels. In addition, we also found evidence for an involvement of TLQP-21 on neuroendocrine mechanisms acting on promoting growth at the median eminence level. To achieve their native structure, secretory and membrane proteins exploit the vast array of chaperones and enzymes that reside in the endoplasmic reticulum, the port of entry into the secretory compartment. Here, they undergo stringent quality control : only properly folded and assembled proteins are given the green light and proceed along the secretory pathway. Proteins that fail to attain their native state are eventually retrotranslocated to the cytosol for proteasomal degradation. Not all proteins entering the ER are secreted or directed to the plasma membrane. Even if in some conditions the flux of cargo can become intense, resident proteins stop at the desired stations to maintain organelle identity and guarantee function.

On the other side, the observed decrease in catalase activity after LEE011 molecular weight cisplatin administration could account for the disability of kidney to eliminate and scavenge toxic H2O2 and lipid peroxides. The inhibition of mitochondrial and postmitochondrial antioxidant enzyme activities may occur due to direct binding of cisplatin to essential sulfhydryl groups at the active sites of these enzymes and depletion of copper and manganese which are essential for SOD activity. Meanwhile, the oxidative stress demonstrated in the current study may target multiple molecules in the cells and damage cell structural components such as lipids, proteins and other organelles where mitochondria are among the most affected ones. Cisplatin exposure induces a mitochondria-dependent ROS generation that significantly contributes to cisplatin-induced nephrotoxicity. Mitochondrial dysfunction has been reported to occur in rats following the depletion of cytosolic GSH with subsequent increase in lipid peroxidation in cisplatin-treated renal cortical slices. Disturbances of the respiratory electron flow or the antioxidant defense mechanisms, can lead to an overproduction of superoxide anions in the respiratory chain of mitochondria by reaction of oxygen with iron-sulfur centers in complex I and by partially reduced ubiquinone and cytochrome b in complex III. A previous study using cultured mouse proximal tubular cells demonstrated cisplatin-induced mitochondrial injury, as revealed by a decrease in mitochondrial succinate dehydrogenase activity, an induction of cytochrome c release, mitochondrial fragmentation and a reduction of complex IV protein. In the present study, cisplatin-induced mitochondrial dysfunction was demonstrated by inhibition of complexes I and III of the respiratory chain. This result is in agreement with previous studies describing the inhibition of the mitochondrial respiratory chain complexes in vitro and the decline in mitochondrial respiratory activity in vivo by cisplatin. The inhibition of complexes I and III activities demonstrated in the current study was accompanied by deterioration of mitochondrial oxidative phosphorylation capacity, resulting in disruption of renal cellular energy production. The decrease in oxidative phosphorylation might be explained by the observed induction of mNOS in the present study which would increase NO production. Increased mitochondrial NO production possibly inhibits cytochrome c oxidase activity by competing with oxygen and also inhibits the electron transport chain at complexes I and III favoring superoxide formation. This in turn would increase peroxynitrite level, alter energy production by increased oxidation of mitochondrial proteins and induce macromolecular damage and cell death. Partial ATP depletion as observed in the present study may constitute a common biochemical pathway that initiates a cascade of events leading to further cellular dysfunctions and activation of programmed cell death. This in turn may accelerate ROS formation by the damaged cells, which may contribute to an amplification of ROS-mediated cell death of the same cell or even the neighboring cells.