Quantification of the anti-murine PD-1 monoclonal antibody RMP1-14 in BALB/c mouse plasma by liquid chromatography-tandem mass spectrometry and application to a pharmacokinetic study.

RMP1-14 is a monoclonal antibody that targets the murine PD-1 protein, and has been used extensively to probe the effects of PD-1 inhibition in preclinical murine models. However, to date, no quantitative analytical methods have been published for RMP1-14. To evaluate its anti-tumor activity in BALB/c mice inoculated with CT26.WT murine colon cancer cells, a liquid chromatography-tandem mass spectrometry (LC-MS/MS) method to quantify RMP1-14 in BALB/c mouse K3EDTA plasma was developed and validated. The methodology used a signature peptide (GFYPPDIYTEWK) as a surrogate for RMP1-14 quantitation and an isotopically labeled analog of the signature peptide as the internal standard. Initial method development focused on a hybrid LC-MS/MS assay involving Protein G immunoprecipitation, but this strategy was abandoned due to lack of selectivity. The final validated method consisted of dilution with Tris-buffered saline, trypsin digestion, and desalting using micro solid-phase extraction. Analytical run time was 3.50 min, and the method demonstrated linearity between 0.500 and 50.0 µg/mL of intact RMP1-14. Accuracy, precision, and robustness were all acceptable, and the method was demonstrated to be comparable to a commercially available fit-for-purpose enzyme-linked immunosorbent assay (ELISA) capable of measuring RMP1-14. The validated method was used to generate pharmacokinetic parameters from tumor-bearing BALB/c mice dosed with RMP1-14 at either 2.50 or 7.50 mg/kg. Overall, the validated method represents a novel tool that can be used to evaluate RMP1-14 activity in future immuno-oncology studies.

Cellular biology of fracture healing.

The biology of bone healing is a rapidly developing science. Advances in transgenic and gene-targeted mice have enabled tissue and cell-specific investigations of skeletal regeneration. As an example, only recently has it been recognized that chondrocytes convert to osteoblasts during healing bone, and only several years prior, seminal publications reported definitively that the primary tissues contributing bone forming cells during regeneration were the periosteum and endosteum. While genetically modified animals offer incredible insights into the temporal and spatial importance of various gene products, the complexity and rapidity of healing-coupled with the heterogeneity of animal models-renders studies of regenerative biology challenging. Herein, cells that play a key role in bone healing will be reviewed and extracellular mediators regulating their behavior discussed. We will focus on recent studies that explore novel roles of inflammation in bone healing, and the origins and fates of various cells in the fracture environment. © 2018 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res.

BMP2 rescues deficient cell migration in Tgfbr3(-/-) epicardial cells and requires Src kinase.

During embryogenesis, the epicardium undergoes proliferation, migration, and differentiation into several cardiac cell types which contribute to the coronary vessels. The type III transforming growth factor-ß receptor (TGFßR3) is required for epicardial cell invasion and development of coronary vasculature in vivo. Bone Morphogenic Protein-2 (BMP2) is a driver of epicardial cell migration. Utilizing a primary epicardial cell line derived from Tgfbr3(+/+) and Tgfbr3(-/-) mouse embryos, we show that Tgfbr3(-/-) epicardial cells are deficient in BMP2 mRNA expression. Tgfbr3(-/-) epicardial cells are deficient in 2-dimensional migration relative to Tgfbr3(+/+) cells; BMP2 induces cellular migration to Tgfbr3(+/+) levels without affecting proliferation. We further demonstrate that Src kinase activity is required for BMP2 driven Tgfbr3(-/-) migration. BMP2 also requires Src for filamentous actin polymerization in Tgfbr3(-/-) epicardial cells. Taken together, our data identifies a novel pathway in epicardial cell migration required for development of the coronary vessels.

Type III TGFß receptor and Src direct hyaluronan-mediated invasive cell motility.

During embryogenesis, the epicardium undergoes proliferation, migration, and differentiation into several cardiac cell types which contribute to the coronary vessels. This process requires epithelial to mesenchymal transition (EMT) and directed cellular invasion. The Type III Transforming Growth Factor-beta Receptor (TGFßR3) is required for epicardial cell invasion and coronary vessel development. Using primary epicardial cells derived from Tgfbr3(+/+) and Tgfbr3(-/-) mouse embryos, high-molecular weight hyaluronan (HMWHA) stimulated cellular invasion and filamentous (f-actin) polymerization are detected in Tgfbr3(+/+) cells, but not in Tgfbr3(-/-) cells. Furthermore, HMWHA-stimulated cellular invasion and f-actin polymerization in Tgfbr3(+/+) epicardial cells are dependent on Src kinase. Src activation in HMWHA-stimulated Tgfbr3(-/-) epicardial cells is not detected in response to HMWHA. RhoA and Rac1 also fail to activate in response to HMWHA in Tgfbr3(-/-) cells. These events coincide with defective f-actin formation and deficient cellular invasion. Finally, a T841A activating substitution in TGFßR3 drives ligand-independent Src activation. Collectively, these data define a TGFßR3-Src-RhoA/Rac1 pathway that is essential for hyaluronan-directed cell invasion in epicardial cells.

Disruption of canonical TGFß-signaling in murine coronary progenitor cells by low level arsenic.

Exposure to arsenic results in several types of cancers as well as heart disease. A major contributor to ischemic heart pathologies is coronary artery disease, however the influences by environmental arsenic in this disease process are not known. Similarly, the impact of toxicants on blood vessel formation and function during development has not been studied. During embryogenesis, the epicardium undergoes proliferation, migration, and differentiation into several cardiac cell types including smooth muscle cells which contribute to the coronary vessels. The TGFß family of ligands and receptors is essential for developmental cardiac epithelial to mesenchymal transition (EMT) and differentiation into coronary smooth muscle cells. In this in vitro study, 18hour exposure to 1.34µM arsenite disrupted developmental EMT programming in murine epicardial cells causing a deficit in cardiac mesenchyme. The expression of EMT genes including TGFß2, TGFß receptor-3, Snail, and Has-2 are decreased in a dose-dependent manner following exposure to arsenite. TGFß2 cell signaling is abrogated as detected by decreases in phosphorylated Smad2/3 when cells are exposed to 1.34µM arsenite. There is also loss of nuclear accumulation pSmad due to arsenite exposure. These observations coincide with a decrease in vimentin positive mesenchymal cells invading three-dimensional collagen gels. However, arsenite does not block TGFß2 mediated smooth muscle cell differentiation by epicardial cells. Overall these results show that arsenic exposure blocks developmental EMT gene programming in murine coronary progenitor cells by disrupting TGFß2 signals and Smad activation, and that smooth muscle cell differentiation is refractory to this arsenic toxicity.

Mechanism of anti-glioma activity and in vivo efficacy of the cannabinoid ligand KM-233.

Glioblastoma multiforme (GBM) is the most common and devastating form of primary central nervous system malignancy. The prognosis for patients diagnosed with GBM is poor, having a median survival rate of 12-15 months. Despite modern advances in the development of antineoplastic agents, the efficacy of newer anti-cancer agents in the treatment of GBM is yet to be determined. Thus, there remains a significant unmet need for new therapeutic strategies against GBM. A promising chemotherapeutic intervention has emerged from studies of cannabinoid receptor agonists wherein tetrahydrocannabinol has been the most extensively studied. The novel cannabinoid ligand KM-233 was developed as a lead platform for future optimization of biopharmaceutical properties of classical based cannabinoid ligands. Treatment of U87MG human GBM cells with KM-233 caused a time dependent change in the phosphorylation profiles of MEK, ERK1/2, Akt, BAD, STAT3, and p70S6K. Almost complete mitochondrial depolarization was observed 6 h post-treatment followed by a rapid increase in cleaved caspase 3 and significant cytoskeletal contractions. Treatment with KM-233 also resulted in a redistribution of the Golgi-endoplasmic reticulum structures. Dose escalation studies in the orthotopic model using U87MG cells revealed an 80 % reduction in tumor size after 12 mg/kg daily dosing for 20 days. The evaluation of KM-233 against primary tumor tissue in the side flank model revealed a significant decrease in the rate of tumor growth. These findings indicate that structural refinement of KM-233 to improve its biopharmaceutical properties may lead to a novel and efficacious treatment for GBM.

Open fractures of the femur in children: analysis of various treatment methods.

PURPOSE: To describe the demographic and clinical characteristics of children who presented with open femur fractures. METHODS: A retrospective chart review of all children treated for open femur fractures at the McGill University Health Center between 1980 and 2009 was conducted. Thirty-seven patients (28 males and 9 females) were identified. Union was determined clinically by the absence of pain, tenderness to palpation and crepitus with motion. Complications were reported. RESULTS: The mean age of the patients was 11.5 years (range 2.8-18.1 years). The mechanism of injury involved motor vehicle-related injuries in 70% of cases. There were 13 Grade I, 15 Grade II and 9 Grade III fractures. The treatment involved traction and hip spica in 11 patients, external fixator in nine patients, intramedullary nailing in seven patients, open reduction and internal fixation in six patients, and traction and an ischial weight bearing brace in four patients. Average time to union was 5.1 months (range 1.5-14.4 months). Infections occurred in ten patients, nine had delayed unions, two developed malunions, four had a refracture and four patients developed a limb length discrepancy >2 cm. CONCLUSIONS: Open fractures of the femur are often accompanied by associated injuries, indicating the importance of early and comprehensive treatment. Treatment may include hip spica application in school-age children and solid intramedullary nails in adolescents. In children with multiple injuries, specifically those with higher fracture grades, treatment with an external fixator provides immediate stability of the fracture and allows early mobilization and ease of management of associated injuries.

Evaluation of novel vanilloid-based hemostatic agents in rats.

BACKGROUND: : Hemostatic dressings containing clotting factors, biodegradable matrices, and recombinant proteins have been developed to control bleeding for battlefield trauma and trauma in clinical settings. Our present study evaluates the use of a vanilloid compound in biodegradable hemostatic dressings in a rat model of trauma. METHODS: : Male Sprague-Dawley rats (n = 180) were randomly divided into treatment groups and control groups and subjected to a lethal groin injury at 30 degrees C and 37 degrees C. Treatment groups included hemostatic matrices consisting of Protosan and graded doses of 2.5%, 5%, 10%, 15%, and 20% of the vanilloid agonist CAP-305. Powder or bilayer patch formulations were applied to the injury site. The seal integrity was assessed by reperfusion of the animal to a minimum mean-arterial pressure (MAP) of 80 mm Hg and monitoring for 60 minutes postinjury. RESULTS: : Powder and patch formulations loaded with varying concentrations of CAP-305 were evaluated. Powders containing 2.5% to 20% drug by weight showed 40% to 80% seal rates at 37 degrees C (p < 0.0001), whereas no significant results were obtained at 30 degrees C compared with the control animals. Conversely, bilayer patches loaded with 5% to 20% drug exhibited a consistent 70% seal rate (p < 0.0001) at 37 degrees C and 70% to 90% seal rates (p < 0.0001) in hypothermic animals when compared with controls. CONCLUSIONS: : Our study demonstrates the efficacy of CAP-305 loaded hemostatic dressings in the rat model of lethal groin injury. This study provides relevant proof of concept for the development of vanilloid agonists as hemostatic agents.

Different residues mediate recognition of 1-O-oleyllysophosphatidic acid and rosiglitazone in the ligand binding domain of peroxisome proliferator-activated receptor gamma.

Here we showed that a naturally occurring ether analog of lysophosphatidic acid, 1-O-octadecenyl-2-hydroxy-sn-glycero-3-phosphate (AGP), is a high affinity partial agonist of the peroxisome proliferator-activated receptor gamma (PPARgamma). Binding studies using the PPARgamma ligand binding domain showed that [32P]AGP and [3H]rosiglitazone (Rosi) both specifically bind to PPARgamma and compete with each other. [32P]AGP bound PPARgamma with an affinity (Kdapp 60 nm) similar to that of Rosi. However, AGP displaced approximately 40% of bound [3H]Rosi even when applied at a 2000-fold excess. Activation of PPARgamma reporter gene expression by AGP and Rosi showed similar potency, yet AGP-mediated activation was approximately 40% that of Rosi. A complex between AGP and PPARgamma was generated using molecular modeling based on a PPARgamma crystal structure. AGP-interacting residues were compared with Rosi-interacting residues identified within the Rosi-PPARgamma co-crystal complex. These comparisons showed that the two ligands occupy partially overlapping positions but make different hydrogen bonding and ion pairing interactions. Site-specific mutants of PPARgamma were prepared to examine individual ligand binding. H323A and H449A mutants showed reduced binding of Rosi but maintained binding of AGP. In contrast, the R288A showed reduced AGP binding but maintained Rosi binding. Finally, alanine replacement of Tyr-473 abolished binding and activation by Rosi and AGP. These observations indicate that the endogenous lipid mediator AGP is a high affinity ligand of PPARgamma but that it binds via interactions distinct from those involved in Rosi binding. These distinct interactions are likely responsible for the partial PPARgamma agonism of AGP.