Gábor Réz

Morphological aspects of ionizing radiation response of small intestine

Knowledge of the acute and late ionizing radiation exposure damage to the gastrointestinal tract, particularly injury of the small intestine, is of great significance in radiotherapy, as is management of accidental radiation exposure. Irradiation (X-ray, neutron, cobalt gamma) induces a series of events in this rapidly renewing tissue resulting in the well-known symptoms of the gastrointestinal (GI) radiation syndrome, such as GI haemorrhage, endotoxemia, bacterial infection, anorexia, nausea, vomiting, diarrhoea, and loss of electrolytes and fluid. In spite of the significant advances that have occurred in research on underlying mechanisms over the last two decades, the overall etiology and pathogenesis of the GI-syndrome still remains unclear. Currently, to our knowledge, these symptoms are probably due to a rapid modification of the intestinal motility and to the structural alteration of the intestinal mucosa (cell loss and altered crypt integrity). Several evidences suggest that radiation-induced dysfunctions and structural changes of this organ (either changes in subcellular, cellular, and histological structure) are mediated by concerted and interrelated changes of a plethora of various extracellular mediators and their intracellular messengers. The aim of this review is to summarize our current knowledge about the pathomorphology and cell biology of the ionizing radiation response of the GI tract with a focus on the small intestine.

Sequestration revisited: Integrating traditional electron microscopy, de novo assembly and new results

Electron microscopy analysis of the autophagic sequestration membrane (SM) in various metazoan cell types after different fixation methods shows that: (1) the growing SM cannot derive from preformed rough surfaced endoplasmic reticulum (RER) membranes by transformation; (2) the empty cleft between the two layers of the SM after aldehyde fixation is an artifact of sample preparation; (3) the SM emerges from and grows de novo in cytoplasmic areas where membranous precursors cannot be identified by traditional electron microscopy; (4) the growing SM consists of two tightly packed membrane layers with a sharp bend at the edge; (5) changes in the environment of the growing SM participate in the determination of the size and shape of the autophagosome.

Morphometric evaluation of the turnover of autophagic vacuoles after treatment with triton X-100 and vinblastine in murine pancreatic acinar and seminal vesicle epithelial cells

SummaryLarge numbers of autophagic vacuoles were found in murine pancreatic acinar and seminal vesicle epithelial cells following the administration of Triton X-100 or vinblastine for 4 h. The autophagic vacuoles disappeared rapidly from the cells after the administration of cycloheximide to animals pretreated with Triton X-100. The decay in seminal vesicle cells appeared to follow firstorder kinetics with an estimated t1/2 of 8.7 min. The regression in pancreatic cells was equally rapid and less than half the initial volume of autophagic vacuoles was found at the 12th min after cycloheximide injection. This time, the decay curve appeared to be linear rather than exponential. Our data, together with the work of others, support the view that the average half-life of autophagic vacuoles is a fairly constant parameter kept within the range of 6–9 min in various types of mouse and rat cell when the late steps of autophagocytosis (i.e. the fusion of autophagosomes and lysosomes and the degradation within lysosomes) are not affected.The regression of autophagic vacuoles was slow in mice pretreated with vinblastine t1/2 of about 27–30 min) suggesting that this drug slows down the turnover of autophagic vacuoles.Morphometric evaluation of the regression of the autophagic vacuole compartment after cycloheximide treatment can be used as a tool to distinguish between treatments which elevate the amount of autophagic vacuoles within the cells by increasing the rate of sequestration from those which expand the autophagic vacuole compartment by causing accumulation of autophagic vacuoles as a result of blockade of the late steps of the autophagic process.

Prevention by cycloheximide of neutral red-induced formation of autophagic vacuoles and krinom granules in mouse pancreatic acinar cells

SummaryThe effect of cycloheximide on neutral red-induced autophagocytosis in pancreatic acinar cells of the mousein vivo was investigated. Administration of the dye resulted in an appearance of basophilic granules (Chlopin’s krinom granules) in the cytoplasm. The cells containing krinom granules were always found to contain a great number of autophagic vacuoles in various stages of degradation. It was concluded, that the krinom granules are light microscopic indicators of autophagy in this cell type. Cycloheximide in doses of 0.1 mg/g body weight and 0.05 mg/g b.w. given simultaneously with or prior to neutral red was found to prevent the dye-induced formation of autophagic vacuoles and krinom granules as well. Evidence was obtained that it was not due to an inhibition of the cellular uptake of neutral red. The protective effect of the drug might be related to its capability for preserving the ultrastructural integrity of the endoplasmic reticulum.

Dynamics of vinblastine-induced autophagocytosis in murine pancreatic acinar cells: Influence of cycloheximide post-treatments

Accumulation of autophagic vacuoles (AVs) was monitored by electron microscopic morphometry in murine pancreatic acinar cells during the 5-hr period after a single injection of vinblastine (VBL). The expansion of the autophagic compartment (AC) occurred in two waves. AVs accumulated in the first 90 min and regressed in the next hour, but thereafter AC expanded again, and 5 hr following the VBL injection, as much as 5.3% of the cytoplasmic volume was found sequestered into the AC. The high rates of accumulation of AVs indicated that VBL stimulated AV formation (segregation) during both expansion phases. To have a deeper insight into the dynamics of the process segregational inhibitor cycloheximide (CHI) was given 1 and 3 hr after VBL and the subsequent regression of the AC and its subcompartments (i.e., early, advanced, and late AVs) were measured during the next 90 min. We found that regression of AVs was fast in the first expansion and slowed down in the second expansion phase during which only early AVs regressed. CHI proved to be a fast and effective inhibitor of autophagic segregation, whether it was given before, simultaneously, or after the VBL injection. The aforementioned results argue for a dual mode of action of VBL (i.e., a prompt stimulation of segregation and a delayed retardation of AV maturation). The two effects of the alkaloid prevail differently along the time course. A further analysis of the behavior of the AC subcompartments showed that CHI perhaps inhibits segregational step(s) occurring prior to the actual formation of the autolysosomes.

Time course of the quantitative changes in the autophagic-lysosomal and secretory granule compartments of murine liver cells under the influence of vinblastine

SummaryThe dynamics of the transient expansion of the autophagic-lysosomal (ALC) and secretory granule (SGC) compartments in mouse liver cells were monitored by electron microscopic morphometry after a single injection of 10 mg/kg b.w. vinblastine sulfate (VBL). Initially (first phase) the cytoplasmic volume fractions of the total ALC and its subcompartments, as well as of the SGC increased by an order of magnitude and peaked at the second h. In thesecond phase, all the aformentioned compartments regressed gradually, approaching their normal size between 12 and 36 h after VBL injection. Analysis of the dynamic changes in fractional volumes of subcompartments of the ALC showed that early autophagic vacuoles (AV1) were the first to enlarge. Advanced AVs (AV2) reacted 30 min later and a further 30 min time lag was required before late autolysosomes, appearing as dense bodies (DB), started to expand. We regard these data as kinetic proof that the bodies of the later reacting subcompartments developed from the earlier reacting ones. The time lag between the expansion of AV1 and AV2 subcompartments may be explained by a period of retardation of conversion of nascent autophagosomes (AV1) to autolysosomes (AV2) which is known to occur normally by fusion of AV1 with enzymecarrying lysosomes. However, transformation of AV1 to AV2 and later to DB resumed after the respective time lags. Moreover, our quantitative data lend support to the view that segregation of cytoplasmic portions into newly-formed autophagosomes was stimulated by VBL, at least in the first 2 h of treatment. The expansion of ALC accelerated during this period and led to an obvious overload of the lysosomal apparatus. DNA-based specific activity of the lysosomal marker enzyme acid phosphatase did not alter significantly during the 36 h period. The volume fraction of the SGC reacted to VBL in essentially the same way as the ALC. The possible mechanisms underlying the time course of the volume changes of ALC and SGC are briefly discussed.

Combined effects of fasting and vinblastine treatment on serum insulin level, the size of autophagic-lysosomal compartment, protein content and lysosomal enzyme activities of liver and exocrine pancreatic cells of the mouse

1. The volume fraction of autophagic vacuoles in liver parenchymal and exocrine pancreatic cells was smallest and the serum insulin level highest in the 24 hr prestarved mouse immediately after 3 hr feeding period. 2. The size of the autophagic vacuole and lysosome (dense body) compartments increased in both types of cells during 2-72 hr fasting parallel with decreasing serum insulin levels. 3. The protein content of the cells decreased and the DNA-based activity of acid phosphatase showed little change throughout fasting. The activity of cathepsin D increased during days 2 and 3 of food deprivation. 4. Vinblastine (50 mg/kg body wt) applied for the last 2 hr of different periods (2, 12, 24, 48 and 72 hr) of fasting decreased serum insulin level and increased the fractional cytoplasmic volume of autophagic vacuoles and dense bodies. This increase was smaller when the drug was applied shortly after feeding and much larger after prolonged fasting. The increase was more pronounced in the pancreatic than in the liver cells. 5. Our data show that the effect of vinblastine on the size of the autophagic-lysosomal compartment depends on the feeding status of the animals.

Prevention of induced autophagy by emetine in exocrine cells of mouse pancreas and seminal vesicle.

SummaryThe effect of the translational inhibitor emetine on neutral red-induced autophagocytosis has been investigated in exocrine cells of mouse pancreas and seminal vesicle. Sublethal doses (0.005–00.1 mg/g body weight) of the drug given 30 minutes prior to neutral red prevent dye-induced autophagocytosis. This is a transient protection, since autophagocytosis can be induced by neutral red when it is given 24 hours after the administration of the drug. Emetine given alone causes few morphological alterations in the cytoplasm. Analysis of experimental data and information in the literature shows that protein synthesis inhibitors causing polyribosome breakdown and degranulation of the rough surfaced endoplasmic reticulum induce autophagocytosis, while those stabilizing polyribosomes prevent this reaction. It is concluded that the preventive effect of cycloheximide and emetine may be related to their stabilizing effect on polyribosomes and on the structure of rough surfaced endoplasmic reticulum.