Yuji Moriyasu

The uptake and degradation of cytoplasmic material by vacuolar autophagy in plants has been studied extensively by electron microscopy and shown to be involved in developmental processes such as vacuole formation, deposition of seed storage proteins and senescence, and in the response of plants to nutrient starvation and to pathogens. The isolation of genes required for autophagy in yeast has allowed the identification of many of the corresponding Arabidopsis genes based on sequence similarity. Knockout mutations in some of these Arabidopsis genes have revealed physiological roles for autophagy in nutrient recycling during nitrogen deficiency and in senescence. Recently, markers for monitoring autophagy in whole plants have been developed, opening the way for future studies to decipher the mechanisms and pathways of autophagy, and the function of these pathways in plant development and stress responses.

The response of tobacco (Nicotiana tabacum) suspension-cultured cells (BY-2) to nutrient starvation was investigated. When the cells that were grown in Murashige-Skoog medium containing 3% (w/v) sucrose were transferred to the same medium without sucrose, 30 to 45% of the intracellular proteins were degraded in 2 d. An analysis with sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that proteins were degraded nonselectively. With the same treatment, protease activity in the cell, which was measured at pH 5.0 using fluorescein thiocarbamoyl-casein as a substrate, increased 3- to 7-fold after 1 d. When the cysteine protease inhibitor (2S,3S)-trans-epoxysuccinyl-L-leucylamido-3-methyl-butane (10 [mu]M) was present in the starvation medium, both the protein degradation and the increase in the protease activity were effectively inhibited. Light microscopy analysis showed that many small spherical bodies accumulated in the perinuclear region of the cytosol 8 h after the start of the inhibitor treatment. These bodies were shown to be membrane-bound vesicles of 1 to 6 [mu]m in diameter that contained several particles. Quinacrine stained these vesicles and the central vacuole; thus, both organelles are acidic compartments. Cytochemical enzyme analysis using 1-naphthylphosphate and [beta]-glycerophosphate as substrates showed that these vesicles contained an acid phosphatase(s). We suggest that these vesicles contribute to cellular protein degradation stimulated under sucrose starvation conditions.

In Arabidopsis root tips cultured in medium containing sufficient nutrients and the membrane-permeable protease inhibitor E-64d, parts of the cytoplasm accumulated in the vacuoles of the cells from the meristematic zone to the elongation zone. Also in barley root tips treated with E-64, parts of the cytoplasm accumulated in autolysosomes and pre-existing central vacuoles. These results suggest that vacuolar and/or lysosomal autophagy occurs constitutively in these regions of cells. 3-Methyladenine, an inhibitor of autophagy, inhibited the accumulation of such inclusions in Arabidopsis root tip cells. Such inclusions were also not observed in root tips prepared from Arabidopsis T-DNA mutants in which AtATG2 or AtATG5, an Arabidopsis homolog of yeast ATG genes essential for autophagy, is disrupted. In contrast, an atatg9 mutant, in which another homolog of ATG is disrupted, accumulated a significant number of vacuolar inclusions in the presence of E-64d. These results suggest that both AtAtg2 and AtAtg5 proteins are essential for autophagy whereas AtAtg9 protein contributes to, but is not essential for, autophagy in Arabidopsis root tip cells. Autophagy that is sensitive to 3-methyladenine and dependent on Atg proteins constitutively occurs in the root tip cells of Arabidopsis.

Tobacco (Nicotiana tabacum) culture cells perform autophagy and degrade cellular proteins in response to sucrose starvation. When protein degradation is blocked by the cysteine protease inhibitor E-64c, lysosomes containing particles of cytoplasm (autolysosomes) accumulate in the cells. Therefore, using light microscopy, we can determine whether cells have performed autophagy. In this study, we investigated whether or not 3-methyladenine (3-MA), which is a known inhibitor of autophagy in mammalian cells, blocks autophagy in tobacco culture cells. The accumulation of autolysosomes was blocked by the addition to the culture media of 5 mM 3-MA together with E-64c. We did not detect autolysosomes or structures thought to be involved with autophagy, such as autophagosomes, accumulating in these cells, as observed by electron microscopy. 3-MA blocked cellular protein degradation without any effect on cellular protease activity. In mammalian cells, phosphatidylinositol 3-kinase (PtdIns 3-kinase) is a putative target of 3-MA. The PtdIns 3-kinase inhibitors wortmannin and LY294002 also inhibited the accumulation of autolysosomes in tobacco culture cells. These results suggest that (1) 3-MA inhibits autophagy by blocking the formation of autophagosomes in tobacco culture cells, and (2) PtdIns 3-kinase is essential for autophagy in tobacco cells.

When a fusion protein of cytochrome b5 (Cyt b5) and the red fluorescent protein (RFP) are expressed in tobacco BY-2 cells, the expressed protein forms intracellular aggregates that emit red fluorescence. When such cells are grown to the stationary phase or incubated in nutrient limited medium, RFP fluorescence can be detected in the vacuolar lumen. We investigated this transport mechanism using a limited-nitrogen model. E-64 and 3-methyladenine, which inhibit autophagic processes, blocked the transport of the RFP signal to the vacuole. We next traced the autophagic process in tobacco cells using YFP fused with the tobacco Atg8 homologue (YFP-NtAtg8) and analyzed the contribution of autophagy to the vacuolar transport of the aggregates. Under limited-nitrogen conditions, the aggregates were degraded in preference to other organelles, and the autophagosomes colocalized with the aggregates at a higher frequency than with mitochondria. This is the first demonstration that selective macroautophagic degradation can occur in plant cells.

Highly luminescent ultrasmall carbon nanodots (CDs) have been prepared by one-step microwave-assisted pyrolysis and functionalized with fluorescein photosensitizer by a diazo-bond. The absorption edge of such prepared fluorescein–N═N–CDs was red-shifted in comparison with the bare one. Nevertheless, the emission signal induced by the nanoparticle quantum-sized graphite structure was quenched due to photoisomerization of the diazo group at the photoexcited state. In order to restrict the photoisomerization, i.e., rotation around the nitrogen–nitrogen bond, the diazo group was fixed by a metal cation to form a complex compound or chelate. The obtained metal complex of fluorescein–N═N–CDs shows an absorbance maximum the same as bare CDs but a recovered emission signal from the nanoparticle moiety, which was bathochromically shifted. They exhibit lower quantum yield in comparison with the bare CDs but better photostability toward emission quenching in nutrition cell culture. The formed photosensitizer-conjugated nanoprobes were proposed as multifunctional fluorophores for intracellular in vivo imaging due to their attractive photophysical attributes and tunable and excitation-dependent emission. The bioapplication of photosensitizer-conjugated CDs was demonstrated as fluorescent tracers for endocytosis pathways in cultured Tobacco cells. Their successful staining and lower toxicity to the plant cells were compared with conventional quantum dots (CdSe/ZnS core–shell type, which caused an acute toxicological in vivo effect).

Autophagy in plant cells is induced by nutrient starvation. Initially, double membrane-bound organelles, termed autophagosomes, enclose a portion of cytoplasm, and then fuse with a vacuole or lysosome to give an autolysosome. Autolysosomes can be visualized by incubating cells in the presence of a membrane-permeable cysteine protease inhibitor. The inhibitor presumably decreases proteolytic degradation of the autolysosome contents that are composed of portions of cytoplasm enclosed by the membrane originating from the inner membrane of autophagosomes, and allows them to accumulate. The origin of membranes that give rise to autophagosomes and autolysosomes is unknown. Here we use an acidotropic fluorescent dye, LysoTracker Red, to label autolysosomes specifically. We demonstrate that autolysosome membranes are marked by the presence of alpha-tonoplast intrinsic protein (alpha-TIP) but not by gamma-TIP or delta-TIP. The identification of a TIP specifically associated with membranes derived from an autophagic process may help our understanding of how plant cells generate and maintain functionally distinct types of vacuoles.

The genotoxicity of nanoparticles is a major concern for nano-safety appraisal in the bryophytes as they are the primary colonizers of bare land, indicators of atmospheric pollution and excellent accumulators of trace metals. The present study for the first time evince the in planta genotoxicity of MnONP in Physcomitrella patens a model plant system utilized for evolutionary developmental genetics. The induction of DNA strand breaks was confirmed by comet assay at all tested concentrations corroborated with the enhanced generation of ROS, increase in Mn dissolution, uptake and internalization. Genotoxicity is often coupled with epigenetic alterations. In the present study, global DNA methylation pattern at the level of single cells was studied by the methylation sensitive comet assay using the isochizomeric restriction endonucleases HpaII (digests unmethylated and hemimethylated DNA) and MspI (digests methylated DNA at 5′-CmCGG-3′). MnONP incited DNA hypomethylation in P. patens gametophores treated with the highest concentration of MnONP (20 μg/mL). The DNA hypomethylation incurred upon MnONP exposure was comparable with that of the DNA methylation blocker 5-azacytidine. This can be ascribed to its clastogenic potential mediated by the formation of H2O2, OH and O2¯. There are no reports on the epigenotoxicity of nanomaterials in plants utilizing the detection of DNA damage and DNA methylation. This can open up new avenues of research on the assessment of the epigenotoxic impact of environmentally relevant nanoparticles using bryophytes as model indicator plant system.

Synergistic interaction of nitric oxide (NO) and reactive oxygen species (ROS) is essential to initiate cell death mechanisms in plants. Though autophagy is salient in either restricting or promoting hypersensitivity response (HR)-related cell death, the crosstalk between the reactive intermediates and autophagy during hypersensitivity response is paradoxical. In this investigation, the consequences of Alternaria alternata toxin (AaT) in tobacco BY-2 cells were examined. At 3 h, AaT perturbed intracellular ROS homeostasis, altered antioxidant enzyme activities, triggered mitochondrial depolarization and induced autophagy. Suppression of autophagy by 3-Methyladenine caused a decline in cell viability in AaT treated cells, which indicated the vital role of autophagy in cell survival. After 24 h, AaT facilitated Ca2+ influx with an accumulation of reactive oxidant intermediates and NO, to manifest necrotic cell death. Inhibition of NO accumulation by 2-(4-Carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (cPTIO) decreased the level of necrotic cell death, and induced autophagy, which suggests NO accumulation represses autophagy and facilitates necrotic cell death at 24 h. Application of N-acetyl-L-cysteine at 3 h, confirmed ROS to be the key initiator of autophagy, and together with cPTIO for 24 h, revealed the combined effects of NO and ROS is required for necrotic HR cell death.

The effect of cerium oxide nanoparticle (CeNP) in plants has elicited substantial controversy. While some investigators have reported that CeNP possesses antioxidant properties, others observed CeNP to induce reactive oxygen species (ROS). In spite of considerable research carried out on the effects of CeNP in metazoans, fundamental studies that can unveil its intracellular consequences linking ROS production, autophagy and DNA damage are lacking in plants. To elucidate the impact of CeNP within plant cells, tobacco BY-2 cells were treated with 10, 50 and 250 µg ml−1 CeNP (Ce10, Ce50 and Ce250), for 24 h. Results demonstrated concentration-dependent accumulation of Ca2+ and ROS at all CeNP treatment sets. However, significant DNA damage and alteration in antioxidant defence systems were noted prominently at Ce50 and Ce250. Moreover, Ce50 and Ce250 induced DNA damage, analysed by comet assay and DNA diffusion experiments, complied with the concomitant increase in ROS. Furthermore, to evaluate the antioxidant property of CeNP, treated cells were washed after 24 h (to minimise CeNP interference) and challenged with H2O2 for 3 h. Ce10 did not induce genotoxicity and H2O2 exposure to Ce10-treated cells showed lesser DNA breakage than cells treated with H2O2 only. Interestingly, Ce10 provided better protection over N-acetyl-L-cysteine against exogenous H2O2 in BY-2 cells. CeNP exposure to transgenic BY-2 cells expressing GFP-Atg8 fusion protein exhibited formation of autophagosomes at Ce10. Application of vacuolar protease inhibitor E-64c and fluorescent basic dye acridine orange, further demonstrated accumulation of particulate matters in the vacuole and occurrence of acidic compartments, the autophagolysosomes, respectively. BY-2 cells co-treated with CeNP and autophagy inhibitor 3-methyladenine exhibited increased DNA damage in Ce10 and cell death at all assessed treatment sets. Thus, current results substantiate an alternative autophagy-mediated, antioxidant and geno-protective role of CeNP, which will aid in deciphering novel phenomena of plant–nanoparticle interaction at cellular level.

In previous studies, using a membrane-permeable protease inhibitor, E-64d, we showed that autophagy occurs constitutively in the root cells of barley and Arabidopsis. In the present study, a fusion protein composed of the autophagy-related protein AtAtg8 and green fluorescent protein (GFP) was expressed in Arabidopsis to visualize autophagosomes. We first confirmed the presence of autophagosomes with GFP fluorescence in the root cells of seedlings grown on a nutrient-sufficient medium. The number of autophagosomes changed as the root cells grew and differentiated. In cells near the apical meristem, autophagosomes were scarcely found. However, a small but significant number of autophagosomes existed in the elongation zone. More autophagosomes were found in the differentiation zone where cell growth ceases but the cells start to form root hair. In addition, we confirmed that autophagy is activated under starvation conditions in Arabidopsis root cells. When the root tips were cultured in a sucrose-free medium, the number of autophagosomes increased in the elongation and differentiation zones, and a significant number of autophagosomes appeared in cells near the apical meristem. The results suggest that autophagy in plant root cells is involved not only in nutrient recycling under nutrient-limiting conditions but also in cell growth and root hair formation.

Tobacco culture cells carry out a large-scale degradation of intracellular proteins in order to survive under sucrose starvation conditions. We have previously suggested that this bulk degradation of cellular proteins is performed by autophagy, where autolysosomes formed de novo act as the major lytic compartments. The digestion process in autolysosomes can be retarded by addition of the cysteine protease inhibitor E-64c to the culture medium, resulting in the accumulation of autolysosomes. In the present study, we have investigated several properties of autolysosomes in tobacco cells. Electron microscopy showed that the autolysosomes contain osmiophilic particles, some of which resemble partially degraded mitochondria. It also revealed the presence of two kinds of autolysosome precursor structures; one resembled the isolation membrane and the other the autophagosome of mammalian cells. Immunofluorescence microscopy showed that autolysosomes contain acid phosphatase, in accordance with cytochemical enzyme analyses by light and electron microscopy in a previous study. Autolysosomes isolated by cell fractionation on Percoll gradients showed the localization of acid phosphatase, vacuolar H+-ATPase and cysteine protease. These results show that starvation-induced autophagy in tobacco cells follows a macroautophagic-type response similar to that described for other eukaryotes. However, our results indicate that, although the plant vacuole is often described as being equivalent to the lysosome of the animal cell, a new low pH lytic compartment—the autolysosome—also contributes to proteolytic degradation when tobacco cells are subjected to sucrose deprivation.

Autolysosomes accumulate in tobacco cells cultured under sucrose starvation conditions in the presence of a cysteine protease inhibitor. We characterized these plant autolysosomes using fluorescent dyes and green fluorescent protein (GFP). Observation using the endocytosis markers, FM4-64 and Lucifer Yellow CH, suggested that there is a membrane flow from the plasma membrane to autolysosomes. Using these dyes as well as GFP-AtVam3p, sporamin-GFP and gamma-VM23-GFP fusion proteins as markers of the central vacuole, we found transport of components of the central vacuole to autolysosomes. Thus endocytosis and the supply from the central vacuole may contribute to the formation of autolysosomes.

The vacuolar pH (pHv) was modified by vacuolar perfusion of internodal cells of Chara australis. After perfusion, the cell was incubated in artificial pond water. The cell sap was isolated after various incubation periods and its pH was measured with a glass pH microelectrode. The time course of pHv change also was measured in situ with an intracellular pH-sensitive antimony electrode. When the natural cell sap (pH 5) was replaced with artificial cell sap of pH 6.0, the pH gradually returned to 5. This recovery process was inhibited by DCCD, an inhibitor of H+-ATPase. When the natural cell sap was replaced with an artificial cell sap of pH 4.2, the pH quickly shifted to the alkaline direction (reaching a pH of 6, after which it returned to the original value, pH 5), or it returned directly to the original value. This process was not inhibited by DCCD. Our results indicate that the pHv is regulated by the balance between the active influx of H+ into the vacuole provided by the H+-pump of the tonoplast and the passive efflux of H+ from the vacuole.

We investigated the leaf tissue and cellular morphology of tea (Camellia sinensis). Osmiophilic material, presumably catechins, was present in mesophyll cells, but not in epidermal cells. Electron microscopy showed that catechins were localized to restricted regions within the central vacuoles. In addition, two kinds of small vacuoles of 0.5-3 microm were present in mesophyll cells. One vacuole had catechins within its whole lumen, while the other had an electron-lucent lumen. We found fusion profiles between a large central vacuole and these small vacuoles. We propose that after catechins are synthesized, they are incorporated into small vacuoles and transported to the large central vacuoles.

Tobacco BY-2 cells undergo autophagy in sucrose-free culture medium, which is the process mostly responsible for intracellular protein degradation under these conditions. Autophagy was inhibited by the vacuolar H(+)-ATPase inhibitors concanamycin A and bafilomycin A1, which caused the accumulation of autophagic bodies in the central vacuoles. Such accumulation did not occur in the presence of the autophagy inhibitor 3-methyladenine, and concanamycin in turn inhibited the accumulation of autolysosomes in the presence of the cysteine protease inhibitor E-64c. Electron microscopy revealed not only that the autophagic bodies were accumulated in the central vacuole, but also that autophagosome-like structures were more frequently observed in the cytoplasm in treatments with concanamycin, suggesting that concanamycin affects the morphology of autophagosomes in addition to raising the pH of the central vacuole. Using BY-2 cells that constitutively express a fusion protein of autophagosome marker protein Atg8 and green fluorescent protein (GFP), we observed the appearance of autophagosomes by fluorescence microscopy, which is a reliable morphological marker of autophagy, and the processing of the fusion protein to GFP, which is a biochemical marker of autophagy. Together, these results suggest the involvement of vacuole type H(+)-ATPase in the maturation step of autophagosomes to autolysosomes in the autophagic process of BY-2 cells. The accumulation of autophagic bodies in the central vacuole by concanamycin is a marker of the occurrence of autophagy; however, it does not necessarily mean that the central vacuole is the site of cytoplasm degradation.

Autophagy is a pathway in which a cell degrades part of its cytoplasm in vacuoles or lysosomes. To identify the physiological functions of autophagy in plants, we disrupted ATG5, an autophagy-related gene, in Physcomitrella, and confirmed that atg5 mutants are deficient in the process of autophagy. On carbon or nitrogen starvation medium, atg5 colonies turned yellow earlier than the wild-type (WT) colonies, showing that Physcomitrella atg5 mutants, like yeast and Arabidopsis, are sensitive to nutrient starvation. In the dark, even under nutrient-sufficient conditions, colonies turned yellow and the net degradation of chlorophyll and Rubisco protein occurred together with the upregulation of several senescence-associated genes. Yellowing reactions were inhibited by the protein synthesis inhibitor cycloheximide, suggesting that protonemal colonies undergo dark-induced senescence like the green leaves of higher plants. Such senescence responses in the dark occurred earlier in atg5 colonies than WT colonies. The sugar content was almost the same between WT and atg5 colonies, indicating that the early-senescence phenotype of atg5 is not explained by sugar deficiency. However, the levels of 7 amino acids showed significantly different alteration between atg5 and WT in the dark: 6 amino acids, particularly arginine and alanine, were much more deficient in the atg5 mutants, irrespective of the early degradation of Rubisco protein. On nutrient-sufficient medium supplemented with casamino acids, the early-senescence phenotype was slightly moderated. We propose that the early-senescence phenotype in atg5 mutants is partly explained by amino acid imbalance because of the lack of cytoplasmic degradation by autophagy in Physcomitrella.

Autophagy is the process responsible for degrading cytoplasmic components in lysosomes and vacuoles. Autophagy-deficient mutants are generally more sensitive to environmental stress than their wild-type (WT) plants. In this study, however, we found that autophagy-deficient (atg) mutants of Physcomitrium, in which an autophagy-related gene, either ATG5 or ATG7, is disrupted, are more tolerant to extreme desiccation stress than WT plants. The colonies were treated with the phytohormone abscisic acid, desiccated using silica gel, and hydrated on a nutrient-sufficient medium. atg mutant colonies survived this stress program and produced green colonies whereas the WT colonies did not. Evans Blue staining revealed obvious cell death in both colonies, but the rate was higher in WT than in atg5 colonies. atg cells had a higher protein content, accumulated more sucrose, and had greater water-holding capacity than WT cells. These factors likely reduce the rate of cell death with less damage during the stress program. On the other hand, inhibition of autophagy during the hydration step with the inhibitor 3-methyladenine increased survival, suggesting that autophagy occurring during the hydration step is involved in cell death. We conclude that Physcomitrium autophagy-deficient cells are more tolerant to extreme desiccation stress than WT cells due to higher water-holding capacity and the promotion of cell death by autophagy through an unknown mechanism. These findings challenge the conventional understanding of the role of autophagy in cell survival against stress and highlight the importance of further research in this area.

Mature plant cells have large vacuoles. But how these vacuoles are formed has not been fully understood. It has been reported that autophagy is involved in the genesis of plant vacuoles. Thus we examined whether autophagy occurs in the vacuole genesis of a plant cell model called miniprotoplasts, in which preexisting large vacuoles have been removed. We prepared miniprotoplasts from tobacco culture cells (BY-2) and observed the formation of vacuoles by light and electron microscopy. The miniprotoplasts had few vacuoles immediately after preparation, but had large vacuoles after 1 to 2 d. When the cysteine protease inhibitor E-64c or E-64d was added to culture media, almost all vacuoles formed contained materials of cytoplasmic origin. This result suggests that autophagy occurs together with the genesis of the vacuoles in miniprotoplasts. 3-Methyladenine and phosphatidylinositol 3-kinase inhibitors such as wortmannin and LY294002, all of which block starvation?induced autophagy in tobacco culture cells and constitutive autophagy in Arabidopsis root cells, did not affect the autophagy in miniprotoplasts. Thus the form of autophagy in miniprotoplasts is probably different from the form of autophagy that arises as a result of sucrose starvation and constitutive autophagy in root tip cells. The causal connection between autophagy and vacuole genesis in miniprotoplasts was not clarified in this study.

Net degradation of cellular components occurs in plant cells cultured under starvation conditions, and autophagy contributes to the degradation of intracellular proteins. In this study, we investigated the degradation of membrane phospholipids by autophagy in cultured tobacco (Nicotiana tabacum) cells. The amounts of total phospholipids and a major phospholipid, phosphatidylcholine (PC), decreased, whereas phosphorylcholine, a degradation product of PC, increased in response to deprivation of sucrose. The addition of glycerol to the culture medium inhibited both the degradation of phospholipids and the concomitant increase of phosphorylcholine. Glycerol, however, did not block autophagy, which was assessed by the accumulation of autolysosomes in the presence of a cysteine protease inhibitor. On the other hand, 3-methyladenine, an inhibitor of autophagy, did not affect the net degradation of PC. We labeled intracellular phospholipids by loading cells with a fluorochrome-labeled fatty acid and chased it under sucrose-free conditions. Glycerol slowed down the decrease in the amount of fluorochrome-labeled PC, suggesting that it inhibits the degradation process of PC. These results show that phospholipids are degraded by mechanisms different from autophagy in tobacco cells cultured under sucrose-free conditions.

In cultured tobacco (BY-2) cells, autophagy seems to be induced under nutrient-starvation conditions, whereas in root cells from Arabidopsis and barley, it occurs constitutively though is activated under nutrient starvation conditions. In both cases, protease inhibitors such as E-64, E-64c, antipain, and leupeptin block autophagy at the step of degradation of the cytoplasm enclosed in lysosomes/vacuoles, and cause the accumulation of autolysosomes (lysosomes containing parts of the cytoplasm) and/or of many cytoplasmic inclusions in the central vacuoles. Both types of autophagy are inhibited by 3-methyladenine, which is known as a potent inhibitor of autophagy in mammalian cells. Thus, using protease inhibitors and 3-methyladenine provides us with a method useful for analyzing autophagy in plant cells. This chapter describes protocols for detecting autophagic compartments in BY-2 cells and in the root-tip cells of Arabidopsis and barley by microscopy.

Autophagy is the process by which cells degrade their own components in lysosomes or vacuoles. Autophagy in tobacco BY-2 cells cultured in sucrose-free medium takes place in formed, autolysosomes in the presence of a cysteine protease inhibitor. The autolysosomes in BY-2 cells are located in the endocytotic pathway and thus can be stained with fluorescent endocytosis marker FM4–64. In the present study, in order to detect autophagy in the root cells of Arabidopsis, we incubated root tips from Arabidopsis seedlings in culture medium containing the membrane-permeable cysteine protease inhibitor E-64d and FM4–64, and examined whether autolysosomes stained with FM4–64 are accumulated. The results suggest that autophagy accompanying the formation of autolysosomes also occurs in Arabidopsis root cells. Such autophagy appeared to occur constitutively in the root cells in nutrient-sufficient culture medium. Even in atg5 mutants in which an autophagy-related gene is disrupted, accumulation of the structures stained with FM4–64, which likely correspond to autolysosomes, was seen although at lower level than in wild type roots.

The contribution of proteases in the central vacuole of Chara corallina internodal cells to overall cellular protein degradation was examined. I measured the decrease in the trichloroacetic acid (TCA)-precipitable radioactivity in the cell for a 6-d chase period after labeling cellular proteins with [3H]leucine. The kinetics of [3H]leucine-labeled protein disappearance showed that the half-life of the cellular soluble proteins was 4 to 5 d. This value did not change when cells were treated with (2S,3S)-trans-epoxysuccinyl-L-leucylamido- 3-methyl-butane ethyl ester, a permeant inhibitor of cysteine proteases. This inhibitor mostly inhibited bovine serum albumin-degrading activity in the vacuole. I also measured the release of TCA-soluble radioactivity from the TCA-insoluble fraction in the cell. This experiment showed that 13% of [3H]leucine-labeled cellular proteins were degraded in 1 d. This value agreed well with the half-life obtained for soluble proteins in the above experiment. This value did not change even when both trans-epoxysuccinyl-L-leucylamido-(4-guanidino)butane, a cysteine protease inhibitor, and pepstatin A, an aspartic protease inhibitor, were introduced into the vacuole. With this operation, bovine serum albumin-degrading activity in the vacuole was almost completely inhibited. These data suggest that the cytoplasmic but not the vacuolar proteases contribute to cellular protein turnover in Chara internodal cells.

The vacuolar pH of Chara internodal cells was modified by vacuolar perfusion, and changes in membrane potential and membrane resistance of the tonoplast in response to the vacuolar pH (pHv) change were studied by anesthetizing the cell with 110 mM KC1 in the external medium. Under this condition the responses of the vacuolar potential (Evo) and re-sistance (Rvo) are assumed to reflect the responses of the tonoplast. Evo showed scarcely any sensitivity to the pH, when the KC1 concentration of the vacuole ([KCl]v) was high (100 mM), but it changed by 30 mV in response to changes in the pHv from 5.5 to 7.5 when the [KCl]v was as low as 0.1 mM. This pHv sensitivity of Evo was suppressed by DCCD, an inhibitor of H+-ATPase.Tonoplast vesicles were prepared from an internodal cell, and the effect of MgATP on their internal pHs was studied by estimating the accumulation of neutral red. A high accumulation of the pigment was found when MgATP was present in the external medium, but the color faded away when ATP was absent. These results together with the effect of DCCD on the Evo indicate that there is an ATP-dependent electrogenic H+-pump in the tonoplasts of Chara internodal cells and that this electrogenicity is very small under normal conditions in which the natural cell sap contains about 100 mM KC1.Membrane characteristics of the tonoplast were compared with those of the plasmalemma with respect to their passive permeabilities to K+ and H+ and to the pump conductance.

We have synthesized optically active α-phenylpyridylmethanols by reduction or hydrolysis with cell cultures of Nicotiana tabacum or immobilized cells of N. tabacum.

EDITORIAL article Front. Plant Sci., 30 September 2019Sec. Plant Cell Biology Volume 10 - 2019 | https://doi.org/10.3389/fpls.2019.01190

Multiple meristematic nodules were induced on leaf segments from the Japanese persimmon (Diospyros kaki Thunb.) ‘Fuyu’ that were cultured on a solidified half-strength Murashige and Skoog's medium containing 2% (w/v) sucrose and 1 μM thidiazuron (TDZ). The nodules 1 to 3 mm in diameter were formed in the cut ends and abaxial side of the leaf segments two weeks after inoculation. The nodule changed from pale green to dense green and multiplied to form many daughter nodules. Adventitious buds were thereafter formed on the nodules, suggesting that the meristematic nodule is an intermediate structure for bud differentiation. The adventitious buds grew poorly on the medium with TDZ, but resumed growth and developed into shoots after transfer to the medium containing 2% (w/v) sucrose and 10 μM zeatin. The meristematic nodules survived more than one year on the medium containing 2% (w/v) sucrose and 1 μM TDZ without transfer, and did not lose their ability to form adventitious buds for more than 5 years when transferred regularly to a fresh medium. These results suggest that the meristematic nodule is a promising material for propagation and long-term conservation of this plant.

Autophagy is a self-protection process against reactive oxygen species (ROS). The intracellular level of ROS increased when cells were cultured under nutrient starvation. Antioxidants such as glutathione and ascorbic acid play an important role in ROS removal. However, the cellular redox state in the autophagic pathway is still unclear. Herein, we developed a new redox-sensitive probe with a disulfide-linked silica scaffold to enable the sensing of the reduction environment in cell organelles. This redox-responsive silica nanoprobe (ReSiN) could penetrate the plant cell wall and release fluorescent molecules in response to redox states. By applying the ReSiN to tobacco BY-2 cells and tracing the distribution of fluorescence, we found a higher reducing potential in the central vacuole than in the autolysosomes. Upon cysteine protease inhibitor (E64-c) treatment in sucrose-free medium, the disulfide-silica structures of the ReSiNs were broken down in the vacuoles but were not degraded and were accumulated in the autolysosomes. These results reveal the feasibility of our nanoprobe for monitoring the endocytic and macroautophagic pathways. These pathways merge upstream of the central vacuole, which is the final destination of both pathways. In addition, different redox potentials were observed in the autophagic pathway. Finally, the expression of the autophagy-related protein (Atg8) fused with green fluorescence protein confirmed that the ReSiN treatment itself did not induce the autophagic pathway under normal physiological conditions, indicating the versatility of this nanoprobe in studying stimuli-triggered autophagy-related trafficking.

Autolysosomes are organelles that sequester and degrade a portion of the cytoplasm during autophagy. Although autophagosomes are short lived compared to other organelles such as mitochondria, plastids, and peroxisomes, many autolysosomes accumulate in tobacco BY-2 cells cultured under sucrose starvation conditions in the presence of a cysteine protease inhibitor. We here describe our methodology for isolating autolysosomes from BY-2 cells by conventional cell fractionation using a Percoll gradient. The autolysosome fraction separates clearly from fractions containing mitochondria and peroxisomes. It contains acid phosphatase, vacuolar H+-ATPase, and protease activity. Electron micrographs show that the fraction contains partially degraded cytoplasm seen in autolysosomes before isolation although an autolysosome structure is only partially preserved.

The presence of two major aminopeptidases (aminopeptidases I and II) in the giant alga Chara australis was shown using polyacrylamide gel electrophoresis. Partially purified aminopeptidase I had a molecular weight of about 120,000, hydrolyzed both leucine-beta-naphthylamide (pH optimum 6.0) and alanine-beta-naphthylamide (pH optimum 7.5), and was located both inside and outside the vacuole. Aminopeptidase I was inhibited by p-chloromercuribenzoic acid, iodoacetic acid, 1,10-phenanthroline, and N-tosyl-l-phenylalanine chloromethyl ketone. Aminopeptidase II hydrolyzed alanine-beta-naphthylamide but not leucine-beta-naphthylamide and was located only outside the vacuole.

We purified the 20S proteasome from the alga Chara corallina Willd with DEAE–ion‐exchange column chromatography and preparative nondenaturing PAGE. The analysis of the purified enzyme bynondenaturing PAGE gave a single band whose molecular mass was estimated to be about 600,000 Da by gel permeation chromatography and whose isoelectric point was at pH 5.5. Two‐dimensional gel electrophoresis gave at least 12 spots with molecular masses from 26,000 to 32,000 Da in a wide range of isoelectric points. The 20S proteasome hydrolyzed three types of artificial substrates used to differentiate chymotrypsin‐like, trypsin‐like, and peptidyl glutamyl peptidase activities. Both the chymotrypsin‐like and the peptidyl glutamyl peptidase activities were enhanced by SDS. In the presence of 0.03% SDS, the optimal pH for both activities was 8.5. Trypsin‐like activity of the 20S proteasome had a broad pH optimum in an alkaline region and was not activated but inhibited by SDS. Its chymotrypsin‐like activity was inhibited by N ‐ethylmaleimide, p ‐chloromercuribenzoic acid, and chymostatin. In contrast, its peptidyl glutamyl peptidase activity was not inhibited by chymostatin. Moreover, proteasome inhibitors MG 115 and MG 135 were effective against the chymotrypsin‐like activity and less so against the peptidyl glutamyl peptidase activity. These properties were very similar to those of the proteasomes of mammalian, yeast, and spinach cells. The large size of Chara cells will make in vivo manipulations and investigations of the proteasome proteolytic system possible.

The physiological implications of autophagy in plant cells have not been fully elucidated. Therefore, we investigated the consequences of autophagy in the moss Physcomitrella by measuring biochemical parameters (fresh and dry weights; starch, amino acid, carbohydrate, and NH3 content) in wild-type (WT) and autophagy-deficient atg5 Physcomitrella cells. We found higher starch levels and a higher net starch synthesis rate in WT cells than in atg5 cells cultured in a glucose-containing culture medium, whereas net starch degradation was similar in the two strains cultured in a glucose-deficient culture medium. Additionally, the treatment of cells with the autophagy inhibitor 3-methyladenine suppressed starch synthesis. Loading bovine serum albumin into atg5 cells through endocytosis, i.e., supplying proteins to vacuoles in the same way as through autophagy, accelerated starch synthesis, whereas loading glutamine through the plasma membrane had no such effect, suggesting that Physcomitrella cells distinguish between different amino acid supply pathways. After net starch synthesis, NH3 levels increased in WT cells, although the change in total amino acid content did not differ between WT and atg5 cells, indicating that autophagy-produced amino acids are oxidized rapidly. We conclude that autophagy promotes starch synthesis in Physcomitrella by supplying the energy obtained by oxidizing autophagy-produced amino acids.

Leaf senescence accompanied by yellowing and Rubisco degradation occurs prematurely in response to various stresses. However, signaling pathways between stress perception and senescence responses are not understood fully, although previous studies suggest the involvement of reactive oxygen species (ROS). While investigating the physiological functions of autophagy in Physcomitrium patens using wild-type (WT) and autophagy-deficient atg5 strains, we found that Physcomitrium colonies senesce prematurely under dark or nitrogen-deficient conditions, with atg5 senescing earlier than WT. In the present study, we measured cellular H2O2, and examined whether H2O2 mediates premature senescence in Physcomitrium colonies. Methyl viologen, an ROS generator, increased cellular H2O2 levels and caused senescence-like symptoms. H2O2 levels were also elevated to the same plateau levels in WT and atg5 under dark or nitrogen-deficient conditions. The ROS scavenger N-acetylcysteine and the ROS source inhibitor carbonyl cyanide m-chlorophenylhydrazone inhibited the increase in H2O2 levels as well as senescence. Upon transfer to a nitrogen-deficient medium, H2O2 levels increased earlier in atg5 than in WT by ~18 h, whereas atg5 yellowed earlier by >2 days. We conclude that the increased H2O2 levels under dark or nitrogen-deficient conditions mediate premature senescence in Physcomitrium but do not explain the different senescence responses of WT and atg5 cells.

It has been generally accepted that autophagy contributes to the degradation of cellular components under nutrient starvation conditions. In a previous study, however, we showed that the degradation of membrane phospholipids occurs mainly by mechanisms distinct from autophagy in suspension-cultured tobacco (Nicotiana tabacum) BY-2 cells. In response to deprivation of sucrose, the amounts of total phospholipids and a major phospholipid, phosphatidylcholine (PC), decreased. 3-Methyladenine, which inhibits autophagy, did not affect the degradation of total phospholipids or PC. On the other hand, glycerol inhibited PC degradation although it did not block autophagy. In the present study, we labeled intracellular phospholipids by loading cells with a fluorochrome-labeled fatty acid and observed cellular morphology by fluorescence microscopy. Most cellular membrane structures were stained at the start of starvation; but 12 h after starvation treatment, concomitant with PC degradation, fluorescence on membranes disappeared and instead the central vacuole became fluorescent. 3-Methyladenine did not inhibit this process, whereas glycerol did. These results suggest that the degradation of membrane phospholipids can be traced by light microscopy and support the notion that autophagy is not a main contributor to the degradation of membrane phospholipids in tobacco cells cultured in sucrose-free medium.

When an exogenous protein, bovine serum albumin, was introduced into the vacuole of a Chara australis internodal cell, it was degraded with time. This degradation proceeded only in the vacuole as far as could be observed by sodium dodecylsulfate-polyacrylamide gel electrophoresis. Degradation was inhibited by protease inhibitors such as antipain and leupeptin. Endogenous proteins introduced into the vacuole were also degraded there. Furthermore, intravacuolar cytoplasmic drops, which were often formed by cell ligation, seemed to be degraded in the vacuole. However, bovine serum albumin degradation did not proceed when mixed with isolated vacuolar sap. These results show that the vacuole in the Chara internodal cell has the capacity to degrade cellular proteins, but that cytoplasmic support is needed for this degrading activity to be maintained.

A protease that is activated by Ca2+ has been discovered in the alga Chara corallina. The activity of the protease was measured using the substrates succinyl-bovine serum albumin (BSA) and [14C]methyl-BSA. In the absence of CaCl2, the optimal activity of the homogenate was found to be in the acidic range. However, in the presence of CaCl2, the activity in the alkaline range increased. The concentration of CaCl2 that gave half-maximal activation of the enzyme was 100 – 500 μM at pH 7.5. The effect of Ca2+ could be partially replaced by Sr2+, but not by Mg2+. The molecular mass of the Ca2+-activated protease was estimated by gel permeation chromatography to be about 40 kD. Cell fractionation, using the vacuolar perfusion technique, showed that the enzyme is localized in the cytoplasm. The Ca2+-activation at pH 7.5 was inhibited by p-chloromercuribenzoic acid. The partially purified enzyme had negligible activity in the absence of Ca2+, showing that this enzyme has an absolute requirement for Ca2+ for its activity. This protease could be separated into two protein isoforms by activity-staining on polyacrylamide gels containing gelatin as the substrate.

The autophagy-defective mutants (atg5 and atg7) of Physcomitrium patens exhibit strong desiccation tolerance. Here, we examined the effects of H2O2 on wild-type (WT) and autophagy-defective mutants of P. patens, considering that desiccation induces reactive oxygen species (ROS). We found that atg mutants can survive a 30-min treatment with 100 mM H2O2, whereas WT cannot, implying that autophagy promotes cell death induced by H2O2. Concomitant with cell death, vacuole collapse occurred. Intracellular H2O2 levels in both WT and atg5 increased immediately after H2O2 treatment and subsequently reached plateaus, which were higher in WT than in atg5. The ROS scavenger N-acetylcysteine lowered the plateau levels in WT and blocked cell death, suggesting that higher H2O2 plateau caused cell death. The uncoupler of electron transport chain (ETC) carbonyl cyanide m-chlorophenylhydrazone also lowered the H2O2 plateaus, showing that ROS produced in the ETC in mitochondria and/or chloroplasts elevated the H2O2 plateau. The autophagy inhibitor 3-methyladenine lowered the H2O2 plateau and the cell death rate in WT, suggesting that autophagy occurring after H2O2 treatment is involved in the production of ROS. Conversely, the addition of bovine serum albumin, which is endocytosed and supplies amino acids instead of autophagy, elevated the H2O2 plateau in atg5 cells, suggesting that amino acids produced through autophagy promote H2O2 generation. These results clearly show that autophagy causes cell death under certain stress conditions. We propose that autophagy-derived amino acids are catabolized using ETCs in mitochondria and/or chloroplasts and produce H2O2, which in turn promotes the cell death accompanying vacuole collapse.

The sections in this article are Introduction Morphological Evidence for Autophagy in Plant Cells Biochemical Characterization of Autophagy in Plant Cells Autophagy in Various Developmental Processes in Plant Cells (Figure 4.1) Autophagy in Various Developmental Processes in Plant Cells (Figure 1) Starvation-Induced Autophagy Does the Cytoplasm to Vacuole Targeting (Cvt) Pathway Exist in Plants? Endocytosis and Autophagy Future Perspective

Vacuolar sap was separated by intracellular perfusion and the distribution of proteases was studied in the giant alga Chara australis. Caseinolytic and hemoglobin-digesting activities were found to be higher at low pH, and about 85 % of total activity was localized in the central vacuole. The optimal pH for carboxypeptidase activity measured using N-carbo-benzoxy-L-phenylalanyl-L-alanineas a substrate was around 5, and about 95 % of total activity was localized in the vacuole. Moreover a substantial portion (40 %) of aminopeptidase activity, measured at pH 5.5 using L-leucine-β-naphthylamide as a substrate, was found in the vacuole.

Aminopeptidase II, one of the two major aminopeptidases in the giant alga Chara australis, was partially purified. Its molecular weight was estimated to be about 80,000 by gel permeation chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis showed that it is composed of a single polypeptide with a molecular weight of about 85,000. Aminopeptidase II hydrolyzed alanine-2-naphthylamide more efficiently than the naphthylamides of lysine and proline, and only weakly hydrolyzed the naphthylamides of arginine, phenylalanine, valine, and leucine. The optimal pH for the hydrolysis of alanine-2-naphthylamide was near 7.0. The activity of aminopeptidase II was inhibited by the SH-reagents p-chloromercuribenzoic acid and N-ethylmaleimide and by the metal chelator 1,10-phenanthroline.

Phytochrome was extracted from both light-grown and dark-grown shoots of Pisum and partially purified by brushite chromatography and ammonium sulfate fractionation. About 160–270 ng of phytochrome per g green tissue extracted was recovered after the partial purification while about 5.1–8.6 μg of phytochrome per g etiolated tissue was recovered. Only the red-light-absorbing form of phytochrome was detected in extracts prepared from both light- and dark-grown tissue, even though the light-grown tissue was harvested in daylight and purification was done entirely at 0–4°C with only a dim green safe light. No significant differences were found between phytochrome purified from green and etiolated tissues, either in their spectral properties or in their immunochemical reactivity against antietiolated-zucchini-phytochrome serum.

Autophagy is a pathway in which a cell degrades part of its cytoplasm in vacuoles or lysosomes. To identify the physiological functions of autophagy in plants, we disrupted <i>ATG5</i>, an autophagy-related gene, in <i>Physcomitrella</i>, and confirmed that <i>atg5</i> mutants are deficient in the process of autophagy. On carbon or nitrogen starvation medium, <i>atg5</i> colonies turned yellow earlier than the wild-type (WT) colonies, showing that <i>Physcomitrella atg5</i> mutants, like yeast and <i>Arabidopsis</i>, are sensitive to nutrient starvation. In the dark, even under nutrient-sufficient conditions, colonies turned yellow and the net degradation of chlorophyll and Rubisco protein occurred together with the upregulation of several senescence-associated genes. Yellowing reactions were inhibited by the protein synthesis inhibitor cycloheximide, suggesting that protonemal colonies undergo dark-induced senescence like the green leaves of higher plants. Such senescence responses in the dark occurred earlier in <i>atg5</i> colonies than WT colonies. The sugar content was almost the same between WT and <i>atg5</i> colonies, indicating that the early-senescence phenotype of <i>atg5</i> is not explained by sugar deficiency. However, the levels of seven amino acids showed significantly different alteration between <i>atg5</i> and WT in the dark: six amino acids, particularly arginine and alanine, were much more deficient in the <i>atg5</i> mutants, irrespective of the early degradation of Rubisco protein. On nutrient-sufficient medium supplemented with casamino acids, the early-senescence phenotype was slightly moderated. We propose that the early-senescence phenotype in <i>atg5</i> mutants is partly explained by amino acid imbalance because of the lack of cytoplasmic degradation by autophagy in <i>Physcomitrella</i>.

Autophagy is a pathway in which a cell degrades part of its cytoplasm in vacuoles or lysosomes. To identify the physiological functions of autophagy in plants, we disrupted <i>ATG5</i>, an autophagy-related gene, in <i>Physcomitrella</i>, and confirmed that <i>atg5</i> mutants are deficient in the process of autophagy. On carbon or nitrogen starvation medium, <i>atg5</i> colonies turned yellow earlier than the wild-type (WT) colonies, showing that <i>Physcomitrella atg5</i> mutants, like yeast and <i>Arabidopsis</i>, are sensitive to nutrient starvation. In the dark, even under nutrient-sufficient conditions, colonies turned yellow and the net degradation of chlorophyll and Rubisco protein occurred together with the upregulation of several senescence-associated genes. Yellowing reactions were inhibited by the protein synthesis inhibitor cycloheximide, suggesting that protonemal colonies undergo dark-induced senescence like the green leaves of higher plants. Such senescence responses in the dark occurred earlier in <i>atg5</i> colonies than WT colonies. The sugar content was almost the same between WT and <i>atg5</i> colonies, indicating that the early-senescence phenotype of <i>atg5</i> is not explained by sugar deficiency. However, the levels of seven amino acids showed significantly different alteration between <i>atg5</i> and WT in the dark: six amino acids, particularly arginine and alanine, were much more deficient in the <i>atg5</i> mutants, irrespective of the early degradation of Rubisco protein. On nutrient-sufficient medium supplemented with casamino acids, the early-senescence phenotype was slightly moderated. We propose that the early-senescence phenotype in <i>atg5</i> mutants is partly explained by amino acid imbalance because of the lack of cytoplasmic degradation by autophagy in <i>Physcomitrella</i>.

Autophagy is a pathway in which a cell degrades part of its cytoplasm in vacuoles or lysosomes. To identify the physiological functions of autophagy in plants, we disrupted <i>ATG5</i>, an autophagy-related gene, in <i>Physcomitrella</i>, and confirmed that <i>atg5</i> mutants are deficient in the process of autophagy. On carbon or nitrogen starvation medium, <i>atg5</i> colonies turned yellow earlier than the wild-type (WT) colonies, showing that <i>Physcomitrella atg5</i> mutants, like yeast and <i>Arabidopsis</i>, are sensitive to nutrient starvation. In the dark, even under nutrient-sufficient conditions, colonies turned yellow and the net degradation of chlorophyll and Rubisco protein occurred together with the upregulation of several senescence-associated genes. Yellowing reactions were inhibited by the protein synthesis inhibitor cycloheximide, suggesting that protonemal colonies undergo dark-induced senescence like the green leaves of higher plants. Such senescence responses in the dark occurred earlier in <i>atg5</i> colonies than WT colonies. The sugar content was almost the same between WT and <i>atg5</i> colonies, indicating that the early-senescence phenotype of <i>atg5</i> is not explained by sugar deficiency. However, the levels of seven amino acids showed significantly different alteration between <i>atg5</i> and WT in the dark: six amino acids, particularly arginine and alanine, were much more deficient in the <i>atg5</i> mutants, irrespective of the early degradation of Rubisco protein. On nutrient-sufficient medium supplemented with casamino acids, the early-senescence phenotype was slightly moderated. We propose that the early-senescence phenotype in <i>atg5</i> mutants is partly explained by amino acid imbalance because of the lack of cytoplasmic degradation by autophagy in <i>Physcomitrella</i>.

Autophagy is a pathway in which a cell degrades part of its cytoplasm in vacuoles or lysosomes. To identify the physiological functions of autophagy in plants, we disrupted <i>ATG5</i>, an autophagy-related gene, in <i>Physcomitrella</i>, and confirmed that <i>atg5</i> mutants are deficient in the process of autophagy. On carbon or nitrogen starvation medium, <i>atg5</i> colonies turned yellow earlier than the wild-type (WT) colonies, showing that <i>Physcomitrella atg5</i> mutants, like yeast and <i>Arabidopsis</i>, are sensitive to nutrient starvation. In the dark, even under nutrient-sufficient conditions, colonies turned yellow and the net degradation of chlorophyll and Rubisco protein occurred together with the upregulation of several senescence-associated genes. Yellowing reactions were inhibited by the protein synthesis inhibitor cycloheximide, suggesting that protonemal colonies undergo dark-induced senescence like the green leaves of higher plants. Such senescence responses in the dark occurred earlier in <i>atg5</i> colonies than WT colonies. The sugar content was almost the same between WT and <i>atg5</i> colonies, indicating that the early-senescence phenotype of <i>atg5</i> is not explained by sugar deficiency. However, the levels of 7 amino acids showed significantly different alteration between <i>atg5</i> and WT in the dark: 6 amino acids, particularly arginine and alanine, were much more deficient in the <i>atg5</i> mutants, irrespective of the early degradation of Rubisco protein. On nutrient-sufficient medium supplemented with casamino acids, the early-senescence phenotype was slightly moderated. We propose that the early-senescence phenotype in <i>atg5</i> mutants is partly explained by amino acid imbalance because of the lack of cytoplasmic degradation by autophagy in <i>Physcomitrella</i>.

Autophagy is a pathway in which a cell degrades part of its cytoplasm in vacuoles or lysosomes. To identify the physiological functions of autophagy in plants, we disrupted <i>ATG5</i>, an autophagy-related gene, in <i>Physcomitrella</i>, and confirmed that <i>atg5</i> mutants are deficient in the process of autophagy. On carbon or nitrogen starvation medium, <i>atg5</i> colonies turned yellow earlier than the wild-type (WT) colonies, showing that <i>Physcomitrella atg5</i> mutants, like yeast and <i>Arabidopsis</i>, are sensitive to nutrient starvation. In the dark, even under nutrient-sufficient conditions, colonies turned yellow and the net degradation of chlorophyll and Rubisco protein occurred together with the upregulation of several senescence-associated genes. Yellowing reactions were inhibited by the protein synthesis inhibitor cycloheximide, suggesting that protonemal colonies undergo dark-induced senescence like the green leaves of higher plants. Such senescence responses in the dark occurred earlier in <i>atg5</i> colonies than WT colonies. The sugar content was almost the same between WT and <i>atg5</i> colonies, indicating that the early-senescence phenotype of <i>atg5</i> is not explained by sugar deficiency. However, the levels of seven amino acids showed significantly different alteration between <i>atg5</i> and WT in the dark: six amino acids, particularly arginine and alanine, were much more deficient in the <i>atg5</i> mutants, irrespective of the early degradation of Rubisco protein. On nutrient-sufficient medium supplemented with casamino acids, the early-senescence phenotype was slightly moderated. We propose that the early-senescence phenotype in <i>atg5</i> mutants is partly explained by amino acid imbalance because of the lack of cytoplasmic degradation by autophagy in <i>Physcomitrella</i>.

Tobacco BY-2 cells undergo autophagy in sucrose-free culture medium, which is the process mostly responsible for intracellular protein degradation under these conditions. Autophagy was inhibited by the vacuolar H⁺-ATPase inhibitors concanamycin A and bafilomycin A₁, which caused the accumulation of autophagic bodies in the central vacuoles. Such accumulation did not occur in the presence of the autophagy inhibitor 3-methyladenine, and concanamycin in turn inhibited the accumulation of autolysosomes in the presence of the cysteine protease inhibitor E-64c. Electron microscopy revealed not only that the autophagic bodies were accumulated in the central vacuole, but also that autophagosome-like structures were more frequently observed in the cytoplasm in treatments with concanamycin, suggesting that concanamycin affects the morphology of autophagosomes in addition to raising the pH of the central vacuole. Using BY-2 cells that constitutively express a fusion protein of autophagosome marker protein Atg8 and green fluorescent protein (GFP), we observed the appearance of autophagosomes by fluorescence microscopy, which is a reliable morphological marker of autophagy, and the processing of the fusion protein to GFP, which is a biochemical marker of autophagy. Together, these results suggest the involvement of vacuole type H⁺-ATPase in the maturation step of autophagosomes to autolysosomes in the autophagic process of BY-2 cells. The accumulation of autophagic bodies in the central vacuole by concanamycin is a marker of the occurrence of autophagy; however, it does not necessarily mean that the central vacuole is the site of cytoplasm degradation.

Abstract The influence of protein‐synthesis inhibitors on the subcellular distribution of free amino acids was studied in internodal cells of Chara corallina . Use of an intracellular perfusion technique allowed separate measurements of amino acids in the vacuole, in the flowing sol endoplasm and in the gel layer. The sol endoplasm predominantly represents the cytosol, while the gel layer is occupied, for the most part, by chloroplasts. When cells were treated with 0.5 mM chloramphenicol (CRP) in the dark, both the total concentration of amino acids and the subcellular distribution were almost the same as in cells without treatment. In the light, however, the subcellular distribution changed dramatically, although the total concentration of amino acids was unchanged. The vacuolar concentration of amino acids was 3 times greater in CRP‐treated cells than in the control. The concentrations of amino acids in the sol endoplasm and in the gel layer were only half of those in the control. Amino acid permeability of the chloroplast envelope, measured using the perfused internodal cells, slightly increased after the CRP treatment in the light. Time‐dependent changes in concentrations of amino acids in the CRP‐treated cells were also measured in the light. The total concentration of amino acids in the cytoplasm gradually decreased, while that in the vacuole increased commensurately. The concentration and/or subcellular distribution of alanine, glutamine, glutamate and glycine changed dramatically. The concentration of alanine increased considerably both in the vacuole and in the cytoplasm. The cytoplasmic concentration of glutamine increased transiently within 1 −2 h after treatment with CRP. The cytoplasmic concentrations of glutamate and glycine decreased. Although the concentrations of some amino acids changed so markedly both in the vacuole and cytoplasm, only small differences in the activities of glutamic‐pyruvic transaminase, glutamic‐oxaloacetic transaminase and glutamine synthetase were detected between the control and the CRP‐treated cells.