Significance of NOTCH1 Expression in the Progression of Human Lung and Colorectal Cancers.

Lung and colorectal cancers are the most common types of cancer characterized by a poor prognosis and a high mortality rate. Mutations in the genes encoding components of the main intra- and extracellular signaling pathways, in particular the NOTCH1 gene (Notch1, a member of the Notch family of receptors), play one of the key roles in progression of these malignancies. Notch signaling is involved in maintaining homeostasis of the intestinal epithelium and structural and functional lung elements. Therefore, it is not surprising that the constitutive activity and hyperactivity of Notch signaling due to somatic mutations in genes coding for the products directly involved into its activation, could lead to the progression of these cancer types. The aim of our study was to investigate how the NOTCH1 downregulation via RNA interference (RNAi) affects the phenotype, characteristics, and Notch-dependent signaling of human A549 lung and HCT116 colorectal carcinoma cells. Several small harpin RNAs (shRNAs) were selected using the bioinformatic analysis and tested for their ability to suppress the NOTCH1 expression. The most efficient one was used to produce the A549 and HCT116 cells with NOTCH1 knockdown. The obtained cell lines demonstrated decreased proliferation rates, reduced colony-forming capacity under adhesive conditions, and decreased migration activity in a Boyden chamber. The NOTCH1 knockdown also significantly decreased expression of some Notch signaling target genes potentially involved in the acquisition and maintenance of more invasive and malignant cell phenotype. In vivo experiments in immunodeficient athymic female Balb/c nu/nu mice confirmed the results obtained in vitro: the NOTCH1 inhibition decreased the growth rates of the subcutaneous xenografts formed by A549 and HCT116 tumor cells. Therefore, downregulation of the gene encoding the Notch1 receptor potentially reduces malignant characteristics of human lung and colorectal carcinoma cells.

LMNA Mutations G232E and R482L Cause Dysregulation of Skeletal Muscle Differentiation, Bioenergetics, and Metabolic Gene Expression Profile.

Laminopathies are a family of monogenic multi-system diseases resulting from mutations in the LMNA gene which include a wide range of neuromuscular disorders. Although lamins are expressed in most types of differentiated cells, LMNA mutations selectively affect only specific tissues by mechanisms that remain largely unknown. We have employed the combination of functional in vitro experiments and transcriptome analysis in order to determine how two LMNA mutations associated with different phenotypes affect skeletal muscle development and metabolism. We used a muscle differentiation model based on C2C12 mouse myoblasts genetically modified with lentivirus constructs bearing wild-type human LMNA (WT-LMNA) or R482L-LMNA/G232E-LMNA mutations, linked to familial partial lipodystrophy of the Dunnigan type and muscular dystrophy phenotype accordingly. We have shown that both G232E/R482L-LMNA mutations cause dysregulation in coordination of pathways that control cell cycle dynamics and muscle differentiation. We have also found that R482/G232E-LMNA mutations induce mitochondrial uncoupling and a decrease in glycolytic activity in differentiated myotubes. Both types of alterations may contribute to mutation-induced muscle tissue pathology.

Clinical Response to Personalized Exercise Therapy in Heart Failure Patients with Reduced Ejection Fraction is Accompanied by Skeletal Muscle Histological Alterations.

Abstract: Heart failure (HF) is associated with skeletal muscle wasting and exercise intolerance. This study aimed to evaluate the exercise-induced clinical response and histological alterations. One hundred and forty-four HF patients were enrolled. The individual training program was determined as a workload at or close to the lactate threshold (LT1); clinical data were collected before and after 12 weeks/6 months of training. The muscle biopsies from eight patients were taken before and after 12 weeks of training: histology analysis was used to evaluate muscle morphology. Most of the patients demonstrated a positive response after 12 weeks of the physical rehabilitation program in one or several parameters tested, and 30% of those showed improvement in all four of the following parameters: oxygen uptake (VO2) peak, left ventricular ejection fraction (LVEF), exercise tolerance (ET), and quality of life (QOL); the walking speed at LT1 after six months of training showed a significant rise. Along with clinical response, the histological analysis detected a small but significant decrease in both fiber and endomysium thickness after the exercise training course indicating the stabilization of muscle mechanotransduction system. Together, our data show that the beneficial effect of personalized exercise therapy in HF patients depends, at least in part, on the improvement in skeletal muscle physiological and biochemical performance.

Myogenic potential of human alveolar mucosa derived cells.

Difficulties related to the obtainment of stem/progenitor cells from skeletal muscle tissue make the search for new sources of myogenic cells highly relevant. Alveolar mucosa might be considered as a perspective candidate due to availability and high proliferative capacity of its cells. Human alveolar mucosa cells (AMC) were obtained from gingival biopsy samples collected from 10 healthy donors and cultured up to 10 passages. AMC matched the generally accepted multipotent mesenchymal stromal cells criteria and possess population doubling time, caryotype and immunophenotype stability during long-term cultivation. The single myogenic induction of primary cell cultures resulted in differentiation of AMC into multinucleated myotubes. The myogenic differentiation was associated with expression of skeletal muscle markers: skeletal myosin, skeletal actin, myogenin and MyoD1. Efficiency of myogenic differentiation in AMC cultures was similar to that in skeletal muscle cells. Furthermore, some of differentiated myotubes exhibited contractions in vitro. Our data confirms the sufficiently high myogenic potential and proliferative capacity of AMC and their ability to maintain in vitro proliferation-competent myogenic precursor cells regardless of the passage number.

Bioceramics composed of octacalcium phosphate demonstrate enhanced biological behavior.

Bioceramics are used to treat bone defects but in general do not induce formation of new bone, which is essential for regeneration process. Many aspects related to bioceramics synthesis, properties and biological response that are still unknown and, there is a great need for further development. In the most recent research efforts were aimed on creation of materials from biological precursors of apatite formation in humans. One possible precursor is octacalcium phosphate (OCP), which is believed to not only exhibit osteoconductivity but possess osteoinductive quality, the ability to induce bone formation. Here we propose a relatively simple route for OCP ceramics preparation with a specifically designed microstructure. Comprehensive study for OCP ceramics including biodegradation, osteogenic properties in ortopic and heterotopic models and limited clinical trials were performed that demonstrated enhanced biological behavior. Our results provide a possible new concept for the clinical applications of OCP ceramics.

Octacalcium phosphate ceramics combined with gingiva-derived stromal cells for engineered functional bone grafts.

Biocompatible ceramic fillers are capable of sustaining bone formation in the proper environment. The major drawback of these scaffolding materials is the absence of osteoinductivity. To overcome this limitation, bioengineered scaffolds combine osteoconductive components (biomaterials) with osteogenic features such as cells and growth factors. The bone marrow mesenchymal stromal cells (BMMSCs) and the ß-tricalcium phosphate (ß-TCP) are well-known and characterized in this regard. The present study was conducted to compare the properties of novel octacalcium phosphate ceramic (OCP) granules with ß-TCP (Cerasorb(®)), gingiva-derived mesenchymal stromal cells (GMSCs) properties with the BMMSCs and osteogenic and angiogenic properties of a bioengineered composite based on OCP granules and the GMSCs. This study demonstrates that GMSCs and BMMSСs have a similar osteogenic capacity. The usage of OCP ceramic granules in combination with BMMSCs/GMSCs significantly affects the osteo- and angiogenesis in bone grafts of ectopic models.