Heterotypic Cell Culture from Mouse Bone Marrow under Simulated Microgravity: Lessons for Stromal Lineage Functions.

Muscle and skeleton structures are considered most susceptible to negative factors of spaceflights, namely microgravity. Three-dimensional clinorotation is a ground-based simulation of microgravity. It provides an opportunity to elucidate the effects of microgravity at the cellular level. The extracellular matrix (ECM) content, transcriptional profiles of genes encoding ECM and remodelling molecules, and secretory profiles were investigated in a heterotypic primary culture of bone marrow cells after 14 days of 3D clinorotation. Simulated microgravity negatively affected stromal lineage cells, responsible for bone tissue formation. This was evidenced by the reduced ECM volume and stromal cell numbers, including multipotent mesenchymal stromal cells (MSCs). ECM genes encoding proteins responsible for matrix stiffness and cell-ECM contacts were downregulated. In a heterotypic population of bone marrow cells, the upregulation of genes encoding ECM degrading molecules and the formation of a paracrine profile that can stimulate ECM degradation, may be mechanisms of osteodegenerative events that develop in real spaceflight.

Regulatory Effects of Senescent Mesenchymal Stem Cells: Endotheliocyte Reaction.

Currently, there is a growing focus on aging and age-related diseases. The processes of aging are based on cell senescence, which results in changes in intercellular communications and pathological alterations in tissues. In the present study, we investigate the influence of senescent mesenchymal stem cells (MSCs) on endothelial cells (ECs). In order to induce senescence in MSCs, we employed a method of stress-induced senescence utilizing mitomycin C (MmC). Subsequent experiments involved the interaction of ECs with MSCs in a coculture or the treatment of ECs with the secretome of senescent MSCs. After 48 h, we assessed the EC state. Our findings revealed that direct interaction led to a decrease in EC proliferation and migratory activity of the coculture. Furthermore, there was an increase in the activity of the lysosomal compartment, as well as an upregulation of the genes P21, IL6, IL8, ITGA1, and ITGB1. Treatment of ECs with the "senescent" secretome resulted in less pronounced effects, although a decrease in proliferation and an increase in ICAM-1 expression were observed. The maintenance of high levels of typical "senescent" cytokines and growth factors after 48 h suggests that the addition of the "senescent" secretome may have a prolonged effect on the cells. It is noteworthy that in samples treated with the "senescent" secretome, the level of PDGF-AA was higher, which may explain some of the pro-regenerative effects of senescent cells. Therefore, the detected changes may underlie both the negative and positive effects of senescence. The findings provide insight into the effects of cell senescence in vitro, where many of the organism's regulatory mechanisms are absent.

Antioxidant mito-TEMPO prevents the increase in tropomyosin oxidation and mitochondrial calcium accumulation under 7-day rat hindlimb suspension.

After the first day of muscle disuse (unloading) mitochondria-derived ROS accumulate in the postural-tonic soleus muscle. It is known that excess of ROS can lead to the accumulation of intramitochondrial calcium and overload of mitochondria with calcium, can negatively affect mitochondrial function and fatigue resistance of soleus muscle. We assumed that the use of mitochondrial ROS scavenger mito-TEMPO will be able to prevent the unloading-induced disruption of mitochondrial functions and will help maintain soleus muscle fatigue resistance. To test this hypothesis, male rats were divided into 3 groups (n = 16 in each): vivarium control with placebo (C), 7-day hindlimb suspension with placebo (7HS) and 7-day hindlimb suspension with intraperitoneal administration of the mimetic superoxide dismutase mito-TEMPO at a dose of 1 mg/kg (7HSM). In the 7HS group, increased fatigue of the soleus muscle was found in the ex vivo test, accompanied with increased activity of ETC complex I and "leak" respiration, as well as a twofold increased content of oxidized tropomyosin (a marker of ROS level in tissues) and increase in intramitochondrial calcium compared to C. In 7HSM, the activity of ETC complex I and "leak" respiration had no significant differences from the control group, and the increase in intramitochondrial calcium and the content of oxidized tropomyosin was partially prevented, however, muscle fatigue was also significantly higher than in the control group. Thus, mitochondrial ROS under 7-day muscle unloading contribute to the accumulation of intramitochondrial calcium and oxidation of tropomyosin, but do not have a significant effect on soleus muscle function.