Dynamics of the Glycogen ß-Particle Number in Rat Hepatocytes during Glucose Refeeding.

Glycogen is an easily accessible source of energy for various processes. In hepatocytes, it can be found in the form of individual molecules (ß-particles) and their agglomerates (α-particles). The glycogen content in hepatocytes depends on the physiological state and can vary due to the size and number of the particles. Using biochemical, cytofluorometric, interferometric and morphometric methods, the number of ß-particles in rat hepatocytes was determined after 48 h of fasting at different time intervals after glucose refeeding. It has been shown that after starvation, hepatocytes contain ~1.6 × 108 ß-particles. During refeeding, their number of hepatocytes gradually increases and reaches a maximum (~5.9 × 108) at 45 min after glucose administration, but then quickly decreases. The data obtained suggest that in cells there is a continuous synthesis and degradation of particles, and at different stages of life, one or another process predominates. It has been suggested that in the course of glycogenesis, pre-existing ß-particles are replaced by those formed de novo. The main contribution to the deposition of glycogen is made by an increase in the glucose residue number in its molecules. The average diameter of ß-particles of glycogen during glycogenesis increases from ~11 nm to 21 nm.

The upregulation of Ulk1-dependent autophagy does not require the p53 activity in mouse embryonic stem cells.

Autophagy is known to play a critical role in the early stages of embryogenesis including the formation of blastocyst. The existence of p53 protein-deficient mice may identify that p53 is not indispensable for the activation of autophagy in pluripotent cells derived from the inner cell mass of the blastocyst. We utilized a p53-knockout (KO) mouse embryonic stem cell (mESC) line to investigate the contribution of p53 in autophagy. We showed that lack of p53 has no effect on cell pluripotency but significantly hinders the differentiation process induced by retinoic acid. Using MRT68921, we revealed that Ulk1-dependent autophagy is activated in response to serum deprivation despite the deletion of p53 in mESCs. However, under retinoic acid-induced differentiation, the accumulation of autophagosomes and lysosomes is impaired in p53 KO mESCs, indicating a critical role of p53 in the regulation of autophagy upon differentiation.

Inducible Ulk1 expression activates the p53 protein in mouse embryonic stem cells.

Defective pluripotent cells are removed from embryos prior to differentiation, presumably due to upregulation of the p53 pathway. However, the mechanism underlying p53 protein activation is still unknown. Embryonic stem cells (ESCs), corresponding to cells of the preimplantation blastocyst, likely have similar mechanisms for abnormal cell elimination. Using a mouse ESC cell line with inducible ulk1 gene expression, we showed that Ulk1 upregulation is accompanied by p53 phosphorylation on Ser15. ESCs tolerated the activated p53 and did not undergo apoptosis or cell cycle blockade upon Ulk1 overexpression. However, massive cell death was observed after retinoic acid treatment, suggesting a role of Ulk1-induced p53 activation in the elimination of defective pluripotent cells prior to differentiation.

Rat Left Ventricular Cardiomyocytes Characterization in the Process of Postinfarction Myocardial Remodeling.

Ischemic lesions of the heart, including myocardial infarction, are the most common pathologies of human cardiovascular system. Despite all the research and achievements of medicine in this field, the mortality from this disease remains heavy. Therefore, studying of processes occurring in the myocardium in the early and late postinfarction periods remains important. Rat left ventricular cardiomyocyte (CMC) ploidy, hypertrophy, hyperplasia, and ultrastructure were investigated in 2, 6, and 26 weeks after experimental myocardial infarction, caused by permanent ligation of left coronary artery. Cytofluorimetric study of CMC ploidy revealed no difference between normal, sham-operated, and infarcted animals for all the tested stages. However, interference microscopy indicated significant changes in cells size. CMC dry mass of infarcted rats in 2 weeks after surgery was 1.5 times lower than in control and sham operated groups. Electron microscopy analysis of CMC revealed disruption of sarcomere structure. However, in 6 weeks after surgery CMC dry mass was 1.6 times higher than in control. In 26 weeks after myocardial infarction CMC dry mass exceeded control only in peri-infarction zone. Cell counting showed that the number of left ventricular CMC, reduced as a result of myocardial infarction, was not restored during myocardial remodeling. © 2019 International Society for Advancement of Cytometry.

Glycogen content in hepatocytes is related with their size in normal rat liver but not in cirrhotic one.

BACKGROUND & AIMS: Hepatocytes differ from one another by the degree of the ploidy, size, position in the liver lobule, and level of the DNA-synthetic processes. It is believed, that the cell size exerts substantial influence on the metabolism of the hepatocytes and the glycogen content in them. The aim of the present study was to test this hypothesis. METHODS: Dry weight of hepatocytes, their ploidy and glycogen content were determined in the normal and the cirrhotic rat liver. Liver cirrhosis in rats was produced by chronic inhalation of CCl4 vapours in the course of 6 months. A combined cytophotometric method was used. Dry weight of the cell, its glycogen and DNA content were successively measured on a mapped preparation. RESULT: Hepatocytes of each ploidy class in the normal and the cirrhotic rat liver accumulated glycogen at the same rate. In the normal liver, there was a distinct correlation between the size of hepatocytes and glycogen content in them. This correlation was observed in each ploidy class, and was especially pronounced in the class of mononucleate tetraploid hepatocytes. In the cirrhotic liver, there was no correlation between the size of the cells and their glycogen content. CONCLUSIONS: The impairment of liver lobular structure probably explains the observed lack of correlation between hepatocyte size and their glycogen content in the cirrhotic liver. © 2016 International Society for Advancement of Cytometry.

mTOR pathway occupies a central role in the emergence of latent cancer cells.

The current focus in oncology research is the translational control of cancer cells as a major mechanism of cellular plasticity. Recent evidence has prompted a reevaluation of the role of the mTOR pathway in cancer development leading to new conclusions. The mechanistic mTOR inhibition is well known to be a tool for generating quiescent stem cells and cancer cells. In response to mTOR suppression, quiescent cancer cells dynamically change their proteome, triggering alternative non-canonical translation mechanisms. The shift to selective translation may have clinical relevance, since quiescent tumor cells can acquire new phenotypical features. This review provides new insights into the patterns of mTOR functioning in quiescent cancer cells, enhancing our current understanding of the biology of latent metastasis.