Molecular Morphology and Function of Stromal Cells

The term “stromal cells” refers to a highly heterogeneous class of connective tissue cells that build the infrastructure of any organ and fulfill a variety of fundamental roles in health and disease [...]

THE RESULTS OF THE SEARCH FOR LABORATORY SIGNS OF AUTOIMMUNE REACTIONS TO CEREBRAL AND EXTRACEREBRAL AUTOANTIGENS IN CHILDREN WITH AUTISM SPECTRUM DISORDERS ASSOCIATED WITH GENETIC DEFICIENCY OF THE FOLATE CYCLE

Relevance. The results of five meta-analyzes of randomized controlled clinical trials indicate an association between genetic deficiency of the folate cycle (GDFC) and autism spectrum disorders (ASD) in children. Autoimmune mechanisms play a special role in the pathogenesis of encephalopathy in children with ASD associated with GDFC. Objective: to study the structure of autoimmune reactions in children with ASD associated with GDFC, according to the accumulated evidence base and to identify associations of laboratory signs of autoimmunity and microorganisms to improve understanding of encephalopathy pathogenesis and diagnostic, monitoring and treatment algorithms. Materials and methods. The medical data of 225 children aged 2 to 9 years with GDFC, who had clinical manifestations of ASD (183 boys and 42 girls) were retrospectively analyzed. The diagnosis of ASD was made by child psychiatrists according to the criteria DSM-IV-TR (Diagnostic and Statistical Manual of mental disorders) and ICD-10 (The International Statistical Classification of Diseases and Related Health Problems) (study group; SG). The control group (CG) included 51 clinically healthy children (37 boys and 14 girls) of similar age and gender distribution who did not suffer from GDFC and ASD. Pathogenic polymorphic variants of folate cycle genes were determined by PCR with restriction (Sinevo, Ukraine). Autoantibodies to autoantigens of CNS subcortical ganglion neurons in blood serum were determined using a Cunningham panel (Moleculera Labs, Inc, USA). Serum autoantibodies to neurons of the mesolimbic system of the brain were identified by ELISA (MDI Limbach Berlin GmbH, Germany). Autoimmunization to myelin was assessed by serum autoantibody titer to basic myelin protein (ELISA) and signs of neutrophil and CD8+ T-lymphocyte sensitization to hemispheric white matter autoantigens (cell-based assay; department of neuroimmunology at the Neurosurgery Institute; Ukraine). Serum autoantibodies to nuclei of connective tissue cells and striated muscle proteins were determined by western blot analysis (Sinevo, Ukraine). To determine the significance of the differences between the indicators in the observation groups, we used the Student's parametric T-test with the confidence probability p and the nonparametric criterion – the number of signs Z according to Urbach Yu.V. The odds ratio (OR) and the 95% confidence interval (95% CI) were used to study the associations between the studied indicators. The study was performed as a fragment of research work commissioned by the Ministry of Health of Ukraine (№ state registration 0121U107940). Research. Positive results of the Cunningham panel occurred in 32%, laboratory signs of autoimmunization to neurons of the mesolimbic system – 36%, myelin of white matter of the hemispheres – 43%, nuclei autoantigens of connective tissue cells – 53%, proteins of striated muscles – 48% of cases among children SG (in general – 68% of cases; p < 0.05; Z < Z0.05). Serological signs of autoimmunization to autoantigens of the subcortical ganglia of the cerebral hemispheres were associated with Streptococcus pyogenes and Borrelia, to neurons of the mesolimbic system – EBV, HHV-6, HHV-7, Toxoplasma and TTV, to CNS myelin – EBV, HHV-6, HHV-7, Borrelia and TTV, to the nuclei of connective tissue cells and striated muscles – EBV, HHV-6, HHV-7, Borrelia and TTV. Conclusions. In children with ASD associated with GDFC laboratory sings of microbial-induced autoimmunity to a number of cerebral and extracerebral autoantigens has been evaluated, which affects the mental and physical health of patients and is a potential target for effective therapeutic interventions.

Single-cell adhesion strength and contact density drops in the M phase of cancer cells

The high throughput, cost effective and sensitive quantification of cell adhesion strength at the single-cell level is still a challenging task. The adhesion force between tissue cells and their environment is crucial in all multicellular organisms. Integrins transmit force between the intracellular cytoskeleton and the extracellular matrix. This force is not only a mechanical interaction but a way of signal transduction as well. For instance, adhesion-dependent cells switch to an apoptotic mode in the lack of adhesion forces. Adhesion of tumor cells is a potential therapeutic target, as it is actively modulated during tissue invasion and cell release to the bloodstream resulting in metastasis. We investigated the integrin-mediated adhesion between cancer cells and their RGD (Arg-Gly-Asp) motif displaying biomimetic substratum using the HeLa cell line transfected by the Fucci fluorescent cell cycle reporter construct. We employed a computer-controlled micropipette and a high spatial resolution label-free resonant waveguide grating-based optical sensor calibrated to adhesion force and energy at the single-cell level. We found that the overall adhesion strength of single cancer cells is approximately constant in all phases except the mitotic (M) phase with a significantly lower adhesion. Single-cell evanescent field based biosensor measurements revealed that at the mitotic phase the cell material mass per unit area inside the cell-substratum contact zone is significantly less, too. Importantly, the weaker mitotic adhesion is not simply a direct consequence of the measured smaller contact area. Our results highlight these differences in the mitotic reticular adhesions and confirm that cell adhesion is a promising target of selective cancer drugs as the vast majority of normal, differentiated tissue cells do not enter the M phase and do not divide.

A Comprehensive Conceptual and Computational Dynamics Framework for Autonomous Regeneration Systems

Many biological organisms regenerate structure and function after damage. Despite the long history of research on molecular mechanisms, many questions remain about algorithms by which cells can cooperate towards the same invariant morphogenetic outcomes. Therefore, conceptual frameworks are needed not only for motivating hypotheses for advancing the understanding of regeneration processes in living organisms, but also for regenerative medicine and synthetic biology. Inspired by planarian regeneration, this study offers a novel generic conceptual framework that hypothesizes mechanisms and algorithms by which cell collectives may internally represent an anatomical target morphology towards which they build after damage. Further, the framework contributes a novel nature-inspired computing method for self-repair in engineering and robotics. Our framework, based on past in vivo and in silico studies on planaria, hypothesizes efficient novel mechanisms and algorithms to achieve complete and accurate regeneration of a simple in silico flatwormlike organism from any damage, much like the body-wide immortality of planaria, with minimal information and algorithmic complexity. This framework that extends our previous circular tissue repair model integrates two levels of organization: tissue and organism. In Level 1, three individual in silico tissues (head, body, and tail—each with a large number of tissue cells and a single stem cell at the centre) repair themselves through efficient local communications. Here, the contribution extends our circular tissue model to other shapes and invests them with tissue-wide immortality through an information field holding the minimum body plan. In Level 2, individual tissues combine to form a simple organism. Specifically, the three stem cells form a network that coordinates organism-wide regeneration with the help of Level 1. Here we contribute novel concepts for collective decision-making by stem cells for stem cell regeneration and large-scale recovery. Both levels (tissue cells and stem cells) represent networks that perform simple neural computations and form a feedback control system. With simple and limited cellular computations, our framework minimises computation and algorithmic complexity to achieve complete recovery. We report results from computer simulations of the framework to demonstrate its robustness in recovering the organism after any injury. This comprehensive hypothetical framework that significantly extends the existing biological regeneration models offers a new way to conceptualise the information-processing aspects of regeneration, which may also help design living and non-living self-repairing agents.

Apoptotic investigation of brain tissue cells in dogs naturally infected by canine distemper virus

Background Canine distemper caused by canine distemper virus that belongs to the Morbillivirus genus of the Paramyxoviridae family is still a global epidemic significant infectious disease, especially in pet dogs in China and serious harm to the development of the dog industry. It has been known that apoptosis caused by the canine distemper virus can show in culture cells, lymphoid tissues, and the cerebellum. However, its occurrence in brain tissue cells remains unclear. To investigate the relationship among canine distemper infecting brain tissues, apoptosis in brain tissue cells, and demyelinating pathogenesis was investigated. Methods 16 naturally infected dogs that exhibited clinical signs of CD and tested positive for the anti-CDV monoclonal antibody and six healthy dogs that served as the control, were used in the research. Brain specimens were divided into the cerebrum, brain stem, and cerebellum embedded in paraffin and made the sections respectively. Approximately 5 µm-thick sections were stained by hematoxylin–eosin, methyl green pyronin, terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling technique, and immunohistochemistry. CDV nucleocapsid protein was detected by immune streptavidin-biotinylated peroxidase complex. Results Alterations in the brain tissues of CDV-infected dogs involved both various cells and nerve fibers. CDV had varying degrees of cytotropism to all brain tissue cells; apoptosis also occurred in all brain cells, especially in the endothelia of cerebral vessels, astrocytes, oligodendrocytes, and ependymal cells, the more serious infection, the more obvious apoptosis. Serious infections also involved the pyramidal and Purkinje cells. The nervous fibers exhibited demyelinating lesions (showed small multifocal vacuole), and some axonal neuron atrophy gradually disappeared (formed large vacuole). Conclusions Apoptosis in brain tissue cells was mainly related to the propagation path and cytotropism of CDV. The apoptosis of astrocytes, oligodendrocytes, and some neurons may play a significant role in the demyelinating pathogenesis in dogs with acute canine distemper. A lot of diverse nervous signs shown in the clinic may be related to different neuron apoptosis.

Efficacy of Low Molecular Heparin on Preeclampsia by Inhibiting Apoptosis of Trophoblasts via the p38MAPK Signaling Pathway

Objective. To explore the efficacy of low molecular heparin on preeclampsia by inhibiting apoptosis of trophoblasts via the p38MAPK signaling pathway. Methods. A preeclampsia rat model was established, and the effects of low molecular heparin on preeclampsia via the p38MAPK signaling pathway were analyzed based on intervention of the rats with different combinations of low molecular heparin and p38MAPK signaling pathway activator. Furthermore, a hypoxia/reoxygenation model of trophoblasts in vitro was established to explore the effects of low molecular heparin on trophoblasts via the p38MAPK signaling pathway. Results. After treatment with low molecular heparin, pregnant rats in the heparin group showed significantly decreased blood pressure, 24 h proteinuria, and p38MAPK protein levels in placenta tissues and decreased apoptosis rate of placenta tissue cells (all P < 0.05 ) and showed more fetal rats and lowered weight of them (both P < 0.05 ) but showed no significant change in the weight of placenta (all P > 0.05 ). Pregnant rats treated with low molecular heparin and p38MAPK activator showed significantly higher blood pressure, 24 h proteinuria, and p38MAPK protein levels in placenta tissues and apoptosis rate of placenta tissue cells than those of pregnant rats in the heparin group (all P < 0.05 ) and also showed less fetal rats and lighter fetal rats than those in the heparin group (both P < 0.05 ) but showed no difference with them in the weight of placenta ( P > 0.05 ). Further analysis revealed that low molecular heparin could protect the survival and migration of trophoblasts under hypoxia/reoxygenation conditions and reduce apoptosis of them (all P < 0.05 ). Conclusion. Low molecular heparin can alleviate preeclampsia by inhibiting the p38MAPK signaling pathway and can inhibit apoptosis of trophoblasts and promote proliferation and migration of them.