Cytochemical studies on GERL, provacuoles, and vacuoles in root meristematic cells of Euphorbia

AtATG Genes, Homologs of Yeast Autophagy Genes, are Involved in Constitutive Autophagy in Arabidopsis Root Tip Cells

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.

Starvation-induced expression of autophagy-related genes in Arabidopsis

BACKGROUND INFORMATION

Autophagy is a catabolic process for degradation of cytoplasmic components in the vacuolar apparatus. A genome-wide survey recently showed evolutionary conservation among autophagy genes in yeast, mammals and plants. To elucidate the molecular and subcellular machinery responsible for the sequestration and subsequent digestion of intracellular material in plants, we utilized a combination of morphological and molecular methods (confocal laser-scanning microscopy, transmission electron microscopy and real-time PCR respectively).

RESULTS

Autophagy in Arabidopsis thaliana suspension-cultured cells was induced by carbon starvation, which triggered an immediate arrest of cell growth together with a rapid degradation of cellular proteins. We followed the onset of these responses and, in this report, provide a clear functional classification for the highly polymorphic autophagosomes by which the cell sequesters and degrades a portion of its own cytoplasm. Quantification of autophagy-related structures shows that cells respond to the stress signal by a rapid and massive, but transient burst of autophagic activity, which adapts to the stress signal. We also monitored the real-time expressions of AtATG3, AtATG4a, AtATG4b, AtATG7 and AtATG8a-AtATG8i genes, which are orthologues of yeast genes involved in the Atg8 ubiquitination-like conjugation pathway and are linked to autophagosome formation. We show that these autophagy-related genes are transiently up-regulated in a co-ordinated manner at the onset of starvation.

CONCLUSIONS

Sucrose starvation induces autophagy and up-regulates orthologues of the yeast Atg8 conjugation pathway genes in Arabidopsis cultured cells. The AtATG3, AtATG4a, AtATG4b, AtATG7 and AtATG8a-AtATG8i genes are expressed in successive waves that parallel the biochemical and cytological remodelling that takes place. These genes thus serve as early markers for autophagy in plants.

Light-induced morphological alteration in anthocyanin-accumulating vacuoles of maize cells

BACKGROUND

Plant pigmentation is affected by a variety of factors. Light, an important plant developmental signal, influences the accumulation of anthocyanins primarily through the activation of the transcription factors that regulate the flavonoid biosynthetic pathway. In this study, we utilized maize Black Mexican Sweet (BMS) cells expressing the R and C1 regulators of anthocyanin biosynthesis from a light-insensitive promoter as a means to investigate the existence of additional levels of control of pigmentation by light.

RESULTS

BMS cells expressing the R and C1 regulators from the CaMV 35S constitutive promoter accumulate anthocyanins when grown in complete darkness, suggesting that the transcription factors R and C1 are sufficient for the transcription of the genes corresponding to the structural enzymes of the pathway, with no requirement for additional light-induced regulators. Interestingly, light induces a "darkening" in the color of the purple anthocyanin pigmentation of transgenic BMS cells expressing R and C1. This change in the pigment hue is not associated with a variation in the levels or types of anthocyanins present, or with an alteration of the transcript levels of several flavonoid biosynthetic genes. However, cytological observations show that light drives unexpected changes in the morphology and distribution of the anthocyanins-containing vacuolar compartments.

CONCLUSION

By uncoupling the effect of light on anthocyanin accumulation, we have found light to induce the fusion of anthocyanin-containing vacuoles, the coalescence of anthocyanic vacuolar inclusion (AVI)-like structures contained, and the spread of anthocyanins from the inclusions into the vacuolar sap. Similar light-induced alterations in vacuolar morphology are also evident in the epidermal cells of maize floral whorls accumulating anthocyanins. Our findings suggest a novel mechanism for the action of light on the vacuolar storage of anthocyanin.

Alpha tonoplast intrinsic protein is specifically associated with vacuole membrane involved in an autophagic process

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.

Leaf senescence and starvation-induced chlorosis are accelerated by the disruption of an Arabidopsis autophagy gene

Autophagy is an intracellular process for vacuolar bulk degradation of cytoplasmic components. The molecular machinery responsible for yeast and mammalian autophagy has recently begun to be elucidated at the cellular level, but the role that autophagy plays at the organismal level has yet to be determined. In this study, a genome-wide search revealed significant conservation between yeast and plant autophagy genes. Twenty-five plant genes that are homologous to 12 yeast genes essential for autophagy were discovered. We identified an Arabidopsis mutant carrying a T-DNA insertion within AtAPG9, which is the only ortholog of yeast Apg9 in Arabidopsis (atapg9-1). AtAPG9 is transcribed in every wild-type organ tested but not in the atapg9-1 mutant. Under nitrogen or carbon-starvation conditions, chlorosis was observed earlier in atapg9-1 cotyledons and rosette leaves compared with wild-type plants. Furthermore, atapg9-1 exhibited a reduction in seed set when nitrogen starved. Even under nutrient growth conditions, bolting and natural leaf senescence were accelerated in atapg9-1 plants. Senescence-associated genes SEN1 and YSL4 were up-regulated in atapg9-1 before induction of senescence, unlike in wild type. All of these phenotypes were complemented by the expression of wild-type AtAPG9 in atapg9-1 plants. These results imply that autophagy is required for maintenance of the cellular viability under nutrient-limited conditions and for efficient nutrient use as a whole plant.

Histochemical and ultrastructural characterization of vacuoles and spherosomes as components of the lytic system in hyphae of the fungus Botrytis cinerea

An integrated approach to acid phosphatase (EC 3.1.3.2) histochemistry by the azo-dye and lead-capture ('Gomori') methods in phosphate-starved hyphae of the fungus Botrytis cinerea revealed strikingly different patterns of localization of activity staining. Reaction product formed with the azo-dye method was found in numerous small organelles (<0.5 microm diameter), which also accumulated the lipophilic dye Nile Red and mislocalized the formazan indicating mitochondrial succinate dehydrogenase activity. Such small organelles were stained only weakly and sporadically with the lead-capture method; instead, lead phosphate deposits were produced mainly in large vacuoles (up to 2.5 microm diam.), similar to those accumulating the vital dye Neutral Red. Additionally, acid phosphatase activity was detected in apical secretory vesicles with the lead-capture method but not with the azo-dye method. Ultrastructural studies by transmission electron microscopy confirmed the presence of large vacuoles which showed evidence of autophagic activity, and of small moderately osmiophilic organelles. The latter are considered to be spherosomes rather than lysosomes because of their weak reaction with the lead-capture method and their high lipid content. It is suggested that their apparently strong reaction with the azo-dye method is caused partly by false localization due to the lipophilic nature of the reaction product.

Sorting of proteins to vacuoles in plant cells

An individual plant cell may contain at least two functionally and structurally distinct types of vacuoles: protein storage vacuoles and lytic vacuoles. Presumably a cell that stores proteins in vacuoles must maintain these separate compartments to prevent exposure of the storage proteins to an acidified environment with active hydrolytic enzymes where they would be degraded. Thus, the organization of the secretory pathway in plant cells, which includes the vacuoles, has a fascinating complexity not anticipated from the extensive genetic and biochemical studies of the secretory pathway in yeast. Plant cells must generate the membranes to form two separate types of tonoplast, maintain them as separate organelles, and direct soluble proteins from the secretory flow specifically to one or the other via separate vesicular pathways. Individual soluble and membrane proteins must be recognized and sorted into one or the other pathway by distinct, specific mechanisms. Here we review the emerging picture of how separate plant vacuoles are organized structurally and how proteins are recognized and sorted to each type.

Induction of a carbon-starvation-related proteolysis in whole maize plants submitted to Light/Dark cycles and to extended darkness

Three-week-old maize (Zea mays L.) plants were submitted to light/dark cycles and to prolonged darkness to investigate the occurrence of sugar-limitation effects in different parts of the whole plant. Soluble sugars fluctuated with light/dark cycles and dropped sharply during extended darkness. Significant decreases in protein level were observed after prolonged darkness in mature roots, root tips, and young leaves. Glutamine and asparagine (Asn) changed in opposite ways, with Asn increasing in the dark. After prolonged darkness the increase in Asn accounted for most of the nitrogen released by protein breakdown. Using polyclonal antibodies against a vacuolar root protease previously described (F. James, R. Brouquisse, C. Suire, A. Pradet, P. Raymond [1996] Biochem J 320: 283-292) or the 20S proteasome, we showed that the increase in proteolytic activities was related to an enrichment of roots in the vacuolar protease, with no change in the amount of 20S proteasome in either roots or leaves. Our results show that no significant net proteolysis is induced in any part of the plant during normal light/dark cycles, although changes in metabolism and growth appear soon after the beginning of the dark period, and starvation-related proteolysis probably appears in prolonged darkness earlier in sink than in mature tissues.

A Vacuole-Associated Annexin Protein, VCaB42, Correlates with the Expansion of Tobacco Cells

A Ca-dependent membrane-binding protein of the annexin family, VCaB42, has previously been shown to associate with vacuolar vesicles at physiological levels of Ca. In this study we used suspension-cultured cells of tobacco (Nicotiana tabacum BY-2) to show that VCaB42 is enriched 4.5-fold in intact vacuoles, whereas evacuolated protoplasts show a 12-fold reduction in VCaB42. VCaB42 distribution is thus comparable to that of the vacuole-associated H+-ATPase but is distinct from the endoplasmic reticulum-localized protein calnexin. Because VCaB42 is a vacuole-associated annexin, and given the putative function of annexins in vesicle fusion, we hypothesize a role for this protein in the vacuolation process of expanding cells. Consistent with this hypothesis, we show that VCaB42 levels correlate with age-associated and hormonally induced changes in cell volume in tobacco suspension cultures. The association of VCaB42 with vacuoles and its correlative pattern of expression relative to the expansion of cells is consistent with a possible role for VCaB42 in the early events of vacuole biogenesis.

Autophagy in Tobacco Suspension-Cultured Cells in Response to Sucrose Starvation

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.

Ultrastructural and biochemical characterization of autophagy in higher plant cells subjected to carbon deprivation: control by the supply of mitochondria with respiratory substrates

Autophagy triggered by carbohydrate starvation was characterized at both biochemical and structural levels, with the aim to identify reliable and easily detectable marker(s) and to investigate the factors controlling this process. Incubation of suspension cells in sucrose-free culture medium triggered a marked degradation of the membrane polar lipids, including phospholipids and galactolipids. In contrast, the total amounts of sterols, which are mainly associated with plasmalemma and tonoplast membranes, remained constant. In particular, phosphatidylcholine decreased, whereas phosphodiesters including glycerylphosphorylcholine transiently increased, and phosphorylcholine (P-Cho) steadily accumulated. P-Cho exhibits a remarkable metabolic inertness and therefore can be used as a reliable biochemical marker reflecting the extent of plant cell autophagy. Indeed, whenever P-Cho accumulated, a massive regression of cytoplasm was noticed using EM. Double membrane-bounded vacuoles were formed in the peripheral cytoplasm during sucrose starvation and were eventually expelled into the central vacuole, which increased in volume and squeezed the thin layer of cytoplasm spared by autophagy. The biochemical marker P-Cho was used to investigate the factors controlling autophagy. P-Cho did not accumulate when sucrose was replaced by glycerol or by pyruvate as carbon sources. Both compounds entered the cells and sustained normal rates of respiration. No recycling back to the hexose phosphates was observed, and cells were rapidly depleted in sugars and hexose phosphates, without any sign of autophagy. On the contrary, when pyruvate (or glycerol) was removed from the culture medium, P-Cho accumulated without a lag phase, in correlation with the formation of autophagic vacuoles. These results strongly suggest that the supply of mitochondria with respiratory substrates, and not the decrease of sucrose and hexose phosphates, controls the induction of autophagy in plant cells starved in carbohydrates.

Examination of the contribution of vacuolar proteases to intracellular protein degradation in Chara corallina

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.

Biochemistry and molecular biology of chromoplast development

Plant cells contain a unique class of organelles, designated the plastids, which distinguish them from animal cells. According to the largely accepted endosymbiotic theory of evolution, plastids are descendants of prokaryotes. This process requires several adaptative changes which involve the maintenance and the expression of part of the plastid genome, as well as the integration of the plastid activity to the cellular metabolism. This is illustrated by the diversity of plastids encountered in plant cells. For instance, in tissues undergoing color changes, i.e., flowers and fruits, the chromoplasts produce and accumulate excess carotenoids. In this paper we attempt to review the basic aspects of chromoplast development.

Three-dimensional structure of cytidine monophosphatase reactive trans-Golgi elements in spinal ganglion cells of the rat

In order to analyse, at the electron microscope level, the three-dimensional configuration of the trans compartment of the Golgi apparatus rat dorsal root ganglia were treated to demonstrate cytidine monophosphatase (CMPase) activity. The localization of enzymatic activity in the Golgi apparatus varied according to cell types. In type A and C cells, CMPase was exclusively located in the transmost sacculotubular element, whereas in type B cells all the saccules of the stacks forming the Golgi ribbon and the trans-Golgi networks were impregnated. Numerous dense bodies seen at proximity were also CMPase positive. In 3 microns thick sections of type A cells examined at low magnification, the impregnated element was scattered throughout the cytoplasm and never formed a continuous structure. In type B cells, the strongly reactive trans-Golgi networks did not follow the entire length of the impregnated Golgi ribbon but were preferentially located in the concavity of its arched portions. At higher magnification and in all cell types some tubular portions of the trans-Golgi networks took the appearance of spheroidal cage-like structures, the CMPase positive anastomotic tubules forming the bars of the cage. Anastomotic tubules separated from the trans-Golgi networks formed fenestrated spheres, while nearby CMPase-reactive dense bodies exhibited a paler hilus. These observations were taken to indicate that in ganglion cells, some CMPase positive dense bodies, presumably lysosomes, formed by fragmentation of the trans-Golgi networks.

Comparisons of Golgi structure and dynamics in plant and animal cells

The Golgi apparatus of both higher plant and animal cells sorts and packages macromolecules which are in transit to and from the cell surface and to the lysosome (vacuole). It is also the site of oligosaccharide and polysaccharide synthesis and modification. The underlying similarity of function of plant and animal Golgi is reflected in similar morphological features, such as cisternal stacking. There are, however, several fundamental differences between the Golgi of plant and animal cells, reflecting, in large part, the fact that the extracellular matrices and lysosomal systems differ between these kingdoms. These include 1) the form and replication of the Golgi during cell division; 2) the disposition of the Golgi in the interphase cell; 3) the nature of "anchoring" the Golgi in the cytoplasm; 4) the genesis, extent, and nature of membranes at the trans side of the stack; 5) targeting signals to the lysosome (vacuole); and 6) physiological regulation of secretion events (constitutive vs. regulated secretion). The degree of participation of the Golgi in endocytosis and membrane recycling is becoming clear for animal cells, but has yet to be explored in detail for plant cells.

THE SAP OF PLANT CELLS

Recent advances in the understanding of the functional relevance of sap of mature plant cells are reviewed. The emphasis is placed on roles of vacuoles played in the temporary storage of saccharides and organic acids, in the accumulation of water soluble products of secondary metabolism and in the intracellular digestion of protein. Contents Summary 1 I. Introduction 1 II. Functions of vacuoles 2 III. Vacuoles as pools of saccharides 3 IV. Organic acids 7 V. (Potentially) toxic cell saps 9 VI. Pools of protein 14 VII. Digestive cell saps 15 VIII. Tonoplast, cell sap and cytoplasm 18 IX. Cellular homeostasis 19 Acknowledgement 20 References 20.

Origin and development of protein bodies in cotyledons of Vicia faba : Proposal for an uniform mechanism

Storage proteins of the field bean (Vicia faba L., var. minor, cv. "Fribo") are synthesized and accumulated in the cotyledons during stage 2 of seed development. Deposition of protein reserves takes place in the protein bodies. The generation of protein bodies was investigated electronmicroscopically using ultra-thin sections as well as the freeze-fracturing technique. During the initial period of storage protein formation, globulins are deposited in large vacuoles which later are transformed to give increasing numbers of small vacuoles with decreasing size. The vacuoles disappear early during the stage of storage protein formation and generate the first protein bodies. During the subsequent period of maximum storage protein formation, which takes place at the rough endoplasmic reticulum (rER), swollen ER strands appear which seem to be entirely filled with protein, and these generate ER-produced protein vacuoles (ERPVAC). The vesicles are transformed in a manner comparable to the vacuoles in the initial period of developmental stage 2 and thus generate the major quantity of protein bodies. Both processes seem to represent only two variants of an uniform mechanism of protein body generation.

The Golgi apparatus in developing endosperm of wheat (Triticum aestivum L.)

The ultrastructure and distribution of the Golgi apparatus in developing wheat endosperm was investigated using a zinc iodide-osmium tetroxide staining complex in conjunction with low and high voltage electron microscopy. Dictyosomes were numerous in starchy endosperm and aleurone at 15 days after anthesis, and during the period of rapid storage protein deposition 25 d after anthesis. Fewer dictyosomes were seen in maturing endosperm. Two types of vesicles were associated with the dictyosomes; small, heavily-stained vesicles were sited at the ends of fine tubules which extend from the cisternae, and larger less-stained vesicles were associated with the periphery of the cisternae. Stereo-pairs of micrographs up to 1 μm thick were taken to demonstrate the interconnections between cisternal and tubular endoplasmic reticulum. Elements of tubular ER were closely associated with dictyosomes, but connections were not observed. These results are discussed in relation to the transport of endosperm storage proteins from their site of synthesis on the cisternal ER to their site of storage, the protein bodies.

A cytochemical study of the Golgi apparatus of the spermatid during spermiogenesis in the rat

The reactivity of the various components of the Golgi apparatus of rat spermatids for three phosphatase activities (nicotinamide adenine dinucleotide phosphatase, NADPase; thiamine pyrophosphatase, TPPase; cytidine monophosphatase, CMPase) and the incorporation of 3H-fucose by the spermatids was analyzed at the 19 steps of spermiogenesis, i.e., during and after this organelle elaborated the glycoprotein-rich acrosomic system. During steps 1-3, the Golgi apparatus produced, in addition to the proacrosomic granules, multivesicular bodies that became associated with the chromatoid body. NADPase was located within the four of five intermediate saccules of Golgi stacks, and TPPase was found in the last one or two saccules on the trans aspect of the stacks from steps 1 to 17 of spermiogenesis. CMPase was located within the thick saccular GERL elements found in the trans region of the Golgi apparatus from steps 1 to 7 of spermiogenesis, but the CMPase-positive GERL disappeared from the Golgi apparatus after its detachment from the acrosomic system at step 8. Th acrosomic system itself was reactive from CMPase and TPPase but was negative for NADPase, while the multivesicular bodies were CMPase and NADPase positive but unreactive for TPPase. Tritiated-fucose was readily incorporated within the Golgi apparatus of steps 1-17 spermatids; in steps 1-7 it was subsequently incorporated within the acrosomic system and multivesicular bodies. These various data indicated (1) that the Golgi apparatus of spermatids, although it loses its CMPase-positive GERL element in step 8, retains evidence of functional capacity until it degenerates in step 17; (2) that in early spermatids the various saccular components of the Golgi are specialized with respect to enzymatic activities; and (3) that each Golgi region may contribute in a coordinated fashion to the formation of the acrosomic system and multivesicular bodies.

Epifluorescence and Video Analysis of Vacuole Motility and Development in Stomatal Cells of Allium

The vacuole in stomatal cells of Allium undergoes major changes in shape during differentiation, switching from a globular form in new guard mother cells to a network of interconnected tubules and chambers, and then back to a globular form as guard cells mature. In addition, vacuolar network elements exhibit characteristic movements and rearrangements.

Quantitative relationship between autophagy and proteolysis during graded amino acid deprivation in perfused rat liver

Fractional volumes of lysosomal-vacuolar elements and long lived protein degradation were quantitatively correlated in rat livers perfused in the single pass mode with varying levels of plasma amino acids. Volumes were determined stereologically; degradation was measured in a second stage cyclic perfusion from the linear accumulation of valine in the presence of cycloheximide and was corrected for loss of short lived proteins. Livers exhibited a high degree of amino acid responsiveness; total protein degradation decreased sharply from 4.5 to 1.5%/h (basal) over an amino acid range of 0-10 times (10X) normal plasma concentrations; near basal values were achieved at 1X. Vacuoles containing undegraded cytoplasm (AVi) appeared immediately following stringent deprivation and by 7.5 min were converted to degradative forms (AVd); both autophagic populations attained steady state volumes by 20 min. With amino acid additions, AVi formation virtually ceased and AVd regressed rapidly (0.087 min-1). Cytoplasmic turnover, calculated from this rate constant and the increases over basal in fractional volumes of either AVi or degradative components, agreed quantitatively with corresponding rates of protein turnover. Predictions from these findings, together with evidence for intralysosomal protein pools in both deprived and basal states, account fully for the accelerated proteolysis and suggest that cytoplasm is also internalized by lysosomes under basal conditions.

Low and high voltage electron microscopy of mitosis and cytokinesis in maize roots

The structure and distribution of cytoplasmic membranes during mitosis and cytokinesis in maize root tip meristematic cells was investigated by low and high voltage electron microscopy. The electron opacity of the nuclear envelope and endoplasmic reticulum (ER) was enhanced by staining the tissue in a mixture of zinc iodide and osmium tetroxide. Thin sections show the nuclear envelope to disassemble at prophase and become indistinguishable from the surrounding ER and polar aggregations of ER. In thick sections under the high voltage electron microscope the spindle is seen to be surrounded by a mass of tubular (TER) and cisternal (CER) endoplasmic reticulum derived from both the nuclear envelope and ER, which persists through metaphase and anaphase. At anaphase strands of TER traverse the spindle between the arms of the chromosomes. The octagonal nuclear pore complexes disappear by metaphase, but irregular-shaped pores persist in the membranes during mitosis. It is suggested that these form a template for pore-complex reformation during telophase. Phragmoplast formation is preceded by an aggregation of TER across the spindle at anaphase. Evidence is presented to suggest that the formation of the desmotubule of a plasmodesma is by the squeezing of a strand of endoplasmic reticulum between the vesicles of the cell plate.

Analytical characterization of beetroot vacuole membrane

Vacuoles from beetroot (Beta vulgaris L. var. esculenta Gürke) isolated by a mechanical procedure were osmotically lysed to separate the membrane and sap components for analysis. Approximately 62% of the vacuole proteins, 70% of the nondialyzable carbohydrates and almost all of the phospholipids and sterols were recovered in the membrane fraction. The vacuole membrane had a phospholipid protein ratio of 0.68 and a sterol:phospholipid ratio of 0.21. 17 complex polar lipids including phosphatides and glycolipids have been tentatively identified. Phosphatidylcholine (54%) and phosphatidylethanolamine (24%) were the most prominent phosphoglycerides besides phosphatidylserine, phosphatidylglycerol, phosphatidylinositol, and phosphatidic acid (1, 4, 5, and 12%, respectively). A putative sulfoglycoside and two major ceramide glycoside-like lipids, resembling those of animal lysosomes, were identified by thin-layer chromatography. High-resolution SDS-acrylamide gel electrophoresis of the polypeptides from the vacuole revealed 15 major bands with apparent molecular weights ranging from 91,000 to 12,000. Selective elution experiments delineated those polypeptides that were peripheral membrane proteins or sap proteins adsorbed to the membrane, and those that exhibited hydrophobic interactions with the lipid core. Lectin labeling results indicated that most of the polypeptides from the membrane and from the sap were glycoproteins probably of the high-mannose type characteristic of lysosomal enzymes that have undergone several stages of posttranslational modification.

Formation of protein storage bodies during embryogenesis in cotyledons of Sinapis alba L

An electron microscopic investigation of fine structural changes in post-meristematic cotyledon mesophyll cells during the period of storage protein accumulation (16-32 d after pollination) showed that the rough ER, the Golgi apparatus and the developing vacuome are intimately involved in the formation of storage protein bodies (aleurone bodies). At the onset of storage protein accumulation (16-18 d after pollination) storage protein-like material appears within Golgi vesicles and preformed vacuoles. At a later stage (24 d after pollination) similar material can also be detected within vesicles formed directly by the rough endoplasmic reticulum (ER). It is concluded that there are two routes for storage protein transport from its site of synthesis at the ER to its site of accumulation in the vacuome. The first route involves the participation of dictyosomes while the second route bypasses the Golgi apparatus. It appears that the normal pathways of membrane flow in the development of central vacuoles in post-meristematic cells are used to deposit the storage protein within the protein bodies. Thus, the protein body can be regarded as a transient stage in the process of vacuome development of these storage cells.

Glucagon-induced autophagy and proteolysis in rat liver: mediation by selective deprivation of intracellular amino acids

Amino acid deprivation and glucagon are both potent inducers of autography and proteolysis in liver. Because glucagon enhanced the metabolic utilization of some amino acids, the catabolic response to both of these stimuli could be achieved by a lowering of intracellular amino acid pools. Alternatively, glucagon could act independently of amino acids. To clarify the mode of hormonal action and also the relationship between the two cellular responses, livers from fed rats were perfused, with and without glucagon, with plasma amino acids over a concentration range of 0 to 10 times normal. Individual amino acids constancy at each level was ensured by perfusion in the single-pass mode. Amino acids alone strongly regulated autophagy and proteolysis in a coordinated fashion; maximal suppression was achieved at twice normal concentration; both effects increased rapidly to maximum at less than normal concentration. Corresponding effects of glucagon, however, could be elicited only at intermediate amino acid levels. None was noted at 4 and 10 times normal; at 0, hormonal stimulation was minimal. The amino acid inhibition was selective because it did not block cyclic AMP production or glycogenolysis. Intracellular pool measurements and systematic alteration of perfusate amino acid composition indicated that the autophagic and proteolytic effects of glucagon are mediated by a hormonally induced depletion of glycine, alanine, glutamate, and glutamine; of these, glutamine alone is the most effective. We conclude that the stimulation of intracellular protein degradation in liver is a manifestation of deprivation-induced autophagy which results from a decrease in certain intracellular glucogenic amino acids, notably glutamine.

Three-dimensional architecture of the golgi apparatus in Sertoli cells of the rat

Glutaraldehyde-fixed testes were stained "en bloc" with the Ur-Pb-Cu technique of Thiéry and Rambourg ('76) or post-fixed and stained with the osmium tetroxide-potassium ferrocyanide method of Karnovsky ('71). Thin or thick (up to 3 micron) sections were examined with the Philips (301 or 400) EM or the high voltage EM. Stereopairs were prepared with photographs of tilted specimens (+/- 7 degrees). At low magnification, in thick sections (0.5-3 micron) stained with Ur-Pb-Cu, the whole Golgi apparatus formed a single network of interconnected wavy ribbon or platelike structures extending from the juxtanuclear region toward the apex of the cell. At higher magnifications, with the two staining techniques, this Golgi network showed two distinct types of regions: the "saccular region" corresponding to the conventional stack of saccules and the "intersaccular connecting region" made up of anastomotic tubules which bridge adjacent stacks. In the saccurlar regions, there was, on the cis-face of the stack, a tight polygonal meshwork of anastomotic tubules (osmiophilic element). Underlying it there were three to seven closely apposed saccules perforated with pores of various diameters, and finally, on the trans-face, a network of tubules was usually connected to the last saccule of the stack, which seemed to peel off" from the pile. The intersaccular connecting regions showed proximal and distal zones with regard to the associated stacks. The proximal zone was made up of superimposed and parallel polygonal networks of membranous tubules which were continuous with corresponding saccules of the stack. In the distal zone they interdigitated, intertwined, anastomosed and bridged adjacent saccular regions; others turned at right angles and established connections with tubular extensions arising at various levels of the same stack. While cisternae of endoplasmic reticulum were contiguous with tubules or saccules located on the transface of the Golgi apparatus, a close association between the ER cisternae and the cis-face of the stacks was not usually observed.