Frank Sætre

Effects of the diarrhetic shellfish toxin, okadaic acid, on cytoskeletal elements, viability and functionality of rat liver and intestinal cells

The diarrhetic shellfish toxin, okadaic acid, administered to rats by intragastric intubation, caused intestinal damage, diarrhea and death, but had no detectable effect on the liver. In contrast, okadaic acid administered intravenously had little effect on intestinal function, but caused a rapid dissolution of hepatic bile canalicular actin sheaths, congestion of blood in the liver, hypotension and death at high doses. In isolated rat hepatocytes, okadaic acid induced disruption of the canalicular sheaths as well as of the keratin intermediate filament network. Both of these cytoskeletal changes could be prevented by addition of a cytoprotective flavonoid, naringin, to the isolated hepatocytes, whereas intravenously or intragastrically administered naringin failed to protect against the effects of okadaic acid in vivo. Freshly isolated colonocytes already had fragmented keratin and tubulin cytoskeletons, died rapidly and were not further afflicted by okadaic acid. Naringin had no protective effect on isolated colonocytes or on intestinal function in vivo, but the nonspecific protein kinase inhibitor, K-252a, and the protein-tyrosine-phosphatase inhibitor, vanadate, significantly reduced the extent of colonocytic keratin fragmentation, and an inhibitor of apoptotic caspases, zVAD.fmk, was strongly protective. Further studies of hepatic and intestinal cytoprotectants should focus on conditions that limit their effectiveness in vivo.

Modulation of intracellular calcium homeostasis blocks autophagosome formation

Cellular stress responses often involve elevation of cytosolic calcium levels, and this has been suggested to stimulate autophagy. Here, however, we demonstrated that agents that alter intracellular calcium ion homeostasis and induce ER stress—the calcium ionophore A23187 and the sarco/endoplasmic reticulum Ca2+-ATPase inhibitor thapsigargin (TG)—potently inhibit autophagy. This anti-autophagic effect occurred under both nutrient-rich and amino acid starvation conditions, and was reflected by a strong reduction in autophagic degradation of long-lived proteins. Furthermore, we found that the calcium-modulating agents inhibited autophagosome biogenesis at a step after the acquisition of WIPI1, but prior to the closure of the autophagosome. The latter was evident from the virtually complete inability of A23187- or TG-treated cells to sequester cytosolic lactate dehydrogenase. Moreover, we observed a decrease in both the number and size of starvation-induced EGFP-LC3 puncta as well as reduced numbers of mRFP-LC3 puncta in a tandem fluorescent mRFP-EGFP-LC3 cell line. The anti-autophagic effect of A23187 and TG was independent of ER stress, as chemical or siRNA-mediated inhibition of the unfolded protein response did not alter the ability of the calcium modulators to block autophagy. Finally, and remarkably, we found that the anti-autophagic activity of the calcium modulators did not require sustained or bulk changes in cytosolic calcium levels. In conclusion, we propose that local perturbations in intracellular calcium levels can exert inhibitory effects on autophagy at the stage of autophagosome expansion and closure.

Autophagic bulk sequestration of cytosolic cargo is independent of LC3, but requires GABARAPs

LC3, a mammalian homologue of yeast Atg8, is assumed to play an important part in bulk sequestration and degradation of cytoplasm (macroautophagy), and is widely used as an indicator of this process. To critically examine its role, we followed the autophagic flux of LC3 in rat hepatocytes during conditions of maximal macroautophagic activity (amino acid depletion), combined with analyses of macroautophagic cargo sequestration, measured as transfer of the cytosolic protein lactate dehydrogenase (LDH) to sedimentable organelles. To accurately determine LC3 turnover we developed a quantitative immunoblotting procedure that corrects for differential immunoreactivity of cytosolic and membrane-associated LC3 forms, and we included cycloheximide to block influx of newly synthesized LC3. As expected, LC3 was initially degraded by the autophagic-lysosomal pathway, but, surprisingly, autophagic LC3-flux ceased after ~2h. In contrast, macroautophagic cargo flux was well maintained, and density gradient analysis showed that sequestered LDH partly accumulated in LC3-free autophagic vacuoles. Hepatocytic macroautophagy could thus proceed independently of LC3. Silencing of either of the two mammalian Atg8 subfamilies in LNCaP prostate cancer cells exposed to macroautophagy-inducing conditions (starvation or the mTOR-inhibitor Torin1) confirmed that macroautophagic sequestration did not require the LC3 subfamily, but, intriguingly, we found the GABARAP subfamily to be essential.

Autophagic activity measured in whole rat hepatocytes as the accumulation of a novel BHMT fragment (p10), generated in amphisomes by the asparaginyl proteinase, legumain

To investigate the stepwise autophagic-lysosomal processing of hepatocellular proteins, the abundant cytosolic enzyme, betaine:homocysteine methyltransferase (BHMT) was used as a probe. Full-length (45 kDa) endogenous BHMT was found to be cleaved in an autophagy-dependent (3-methyladenine-sensitive) manner in isolated rat hepatocytes to generate a novel N-terminal 10-kDa fragment (p10) identified and characterized by mass spectrometry. The cleavage site was consistent with cleavage by the asparaginyl proteinase, legumain and indeed a specific inhibitor of this enzyme (AJN-230) was able to completely suppress p10 formation in intact cells, causing instead accumulation of a 42-kDa intermediate. To prevent further degradation of p10 or p42 by the cysteine proteinases present in autophagic vacuoles, the proteinase inhibitor leupeptin had to be present. Asparagine, an inhibitor of amphisome-lysosome fusion, did not detectably impede either p42 or p10 formation, indicating that BHMT processing primarily takes place in amphisomes rather than in lysosomes. Lactate dehydrogenase (LDH) was similarly degraded primarily in amphisomes by leupeptin-sensitive proteolysis, but some additional leupeptin-resistant LDH degradation in lysosomes was also indicated. The autophagic sequestration of BHMT appeared to be nonselective, as the accumulation of p10 (in the presence of leupeptin) or of its precursors (in the additional presence of AJN-230) proceeded at approximately the same rate as the model autophagic cargo, LDH. The complete lack of a cytosolic background makes p10 suitable for use in a “fragment assay” of autophagic activity in whole cells. Incubation of hepatocytes with ammonium chloride, which neutralizes amphisomes as well as lysosomes, caused rapid, irreversible inhibition of legumain activity and stopped all p10 formation. The availability of several methods for selective targeting of legumain in intact cells may facilitate functional studies of this enigmatic enzyme, and perhaps suggest novel ways to reduce its contribution to cancer cell metastasis or autoimmune disease.

Dynamic Escherichia coli SeqA complexes organize the newly replicated DNA at a considerable distance from the replisome.

The Escherichia coli SeqA protein binds to newly replicated, hemimethylated DNA behind replication forks and forms structures consisting of several hundred SeqA molecules bound to about 100 kb of DNA. It has been suggested that SeqA structures either direct the new sister DNA molecules away from each other or constitute a spacer that keeps the sisters together. We have developed an image analysis script that automatically measures the distance between neighboring foci in cells. Using this tool as well as direct stochastic optical reconstruction microscopy (dSTORM) we find that in cells with fluorescently tagged SeqA and replisome the sister SeqA structures were situated close together (less than about 30 nm apart) and relatively far from the replisome (on average 200–300 nm). The results support the idea that newly replicated sister molecules are kept together behind the fork and suggest the existence of a stretch of DNA between the replisome and SeqA which enjoys added stabilization. This could be important in facilitating DNA transactions such as recombination, mismatch repair and topoisomerase activity. In slowly growing cells without ongoing replication forks the SeqA protein was found to reside at the fully methylated origins prior to initiation of replication.

Chapter 5 Sequestration Assays for Mammalian Autophagy

Macroautophagic activity is most directly and precisely measured by a cargo sequestration assay. Long-lived, cytosolic proteins that are degraded exclusively by the autophagic-lysosomal pathway, such as lactate dehydrogenase (LDH) are suitable as endogenous sequestration probes. Autophagic sequestration is measured as transfer of the protein from the soluble (cytosolic) to the sedimentable (organelle-containing) cell fraction, using leupeptin or other proteinase inhibitors to block inactivation and degradation of the protein inside autophagic vacuoles. A convenient separation method is electrodisruption of the cells, followed by sedimentation of the organelle fraction through a Nycodenz density cushion. A promising variant of the cargo assay is to use a protein probe that is processed by the autophagic-lysosomal pathway so as to generate an intravacuolar fragment. Because there is no cytosolic background, subcellular fractionation is unnecessary, allowing the use of the autophagic fragment assay to measure autophagic activity in whole cells. In hepatocytes, a small fragment, p10(BHMT), made by autophagic processing of the enzyme betaine:homocysteine methyltransferase, thus accumulates in an autophagy-dependent manner in the presence of leupeptin. Autophagic sequestration can also be measured by using exogenous cargo probes, such as radiolabeled di- and trisaccharides, which can be loaded into the cytosol of hepatocytes by reversible electrodisruption or mechanical stress. Raffinose is the preferable probe for measurement of autophagic activity, whereas sucrose (which can be hydrolyzed in amphisomes and lysosomes by added endocytosed invertase) and lactose (which is hydrolyzed in lysosomes by the endogenous beta-galactosidase) are useful for dissection of the various steps in the autophagic-lysosomal pathway and for studying autophagic-endocytic interactions. Furthermore, the intralysosomal hydrolysis of autophagocytosed lactose can be measured in whole cells (as formation of the hydrolysis product, galactose), thus providing a background-free assay (autophagic lactolysis) of the overall autophagic-lysosomal pathway.

Novel steps in the autophagic-lysosomal pathway

Autophagy is the process by which portions of cytoplasm are enclosed by membranous organelles, phagophores, which deliver the sequestered cytoplasm to degradative autophagic vacuoles. Genes and proteins involved in phagophore manufacture have been extensively studied, but little is known about how mature phagophores proceed through the subsequent steps of expansion, closure and fusion. Here we have addressed these issues by combining our unique autophagic cargo sequestration assay (using the cytosolic enzyme lactate dehydrogenase as a cargo marker) with quantitative measurements of the lipidation‐dependent anchorage and turnover of the phagophore‐associated protein LC3. In isolated rat hepatocytes, amino acid starved to induce maximal autophagic activity, the two unrelated reversible autophagy inhibitors 3‐methyladenine (3MA) and thapsigargin (TG) both blocked cargo sequestration completely. However, whereas 3MA inhibited LC3 lipidation, TG did not, thus apparently acting at a post‐lipidation step to prevent phagophore closure. Intriguingly, the resumption of cargo sequestration seen upon release from a reversible TG block was completely suppressed by 3MA, revealing that 3MA not only inhibits LC3 lipidation but also (like TG) blocks phagophore closure at a post‐lipidation step. 3MA did not, however, prevent the resumption of lysosomal LC3 degradation, indicating that phagophores could fuse directly with degradative autophagic vacuoles without carrying cytosolic cargo. This fusion step was clearly blocked by TG. Furthermore, density gradient centrifugation revealed that a fraction of the LC3‐marked phagophores retained by TG could be density‐shifted by the acidotropic drug propylamine along with the lysosomal marker cathepsin B, suggesting physical association of some phagophores with lysosomes prior to cargo sequestration.

Rab7b modulates autophagic flux by interacting with Atg4B

Autophagy (macroautophagy) is a highly conserved eukaryotic degradation pathway in which cytosolic components and organelles are sequestered by specialized autophagic membranes and degraded through the lysosomal system. The autophagic pathway maintains basal cellular homeostasis and helps cells adapt during stress; thus, defects in autophagy can cause detrimental effects. It is therefore crucial that autophagy is properly regulated. In this study, we show that the cysteine protease Atg4B, a key enzyme in autophagy that cleaves LC3, is an interactor of the small GTPase Rab7b. Indeed, Atg4B interacts and co‐localizes with Rab7b on vesicles. Depletion of Rab7b increases autophagic flux as indicated by the increased size of autophagic structures as well as the magnitude of macroautophagic sequestration and degradation. Importantly, we demonstrate that Rab7b regulates LC3 processing by modulating Atg4B activity. Taken together, our findings reveal Rab7b as a novel negative regulator of autophagy through its interaction with Atg4B.