Role of Lysosomal Vesicles in the Digestive Process of Armillaria mellea by the Large Cells of Gastrodia elata

The hyphae of Armillaria mellea Fr. invade the large ceils of Gastrodia elata BI. Through the wall pits of cortical cells. During early stage the plasmalemma of large cell invaginates and the cell wall forms papillary thickenings to restrain the hyphae from invading. When a hypha enters a large cell, it is encircled tightly by the invaginated plasmalemma which is surrounded by a large number of vesicles coated by a unit membrane. As these vesicles fusing with their membranes to the plasmalemma and discharging their contents into the space around the hypha, the space lined by the invaginated plasmalemma enlarges gradually and becomes a digestive vacuole in which a hypha is completely digested. Reaction product form acid phosphatase activities in the vesicles and digestive vacuoles testifies that the vesicles and digestive vacuoles are identical with primary and secondary lysosomes of plant lysosomal system respectively.     

蜜环菌侵染天麻皮层过程中酸性磷酸酶的细胞化学研究

被蜜环菌(Armillaria mellea)侵染的天麻(Gastrodia elata B1.)皮层中,由外至内形成三种类型的染菌细胞:菌丝结细胞、空腔细胞和消化细胞。外部两类细胞中的酸性磷酸酶定位显示,一些位于空腔细胞或衰老的菌丝结细胞中的菌丝内部逐渐产生大量酸性磷酸酶,随后菌丝发生自溶。这两类细胞中未发现明显的释放水解酶消化菌丝的现象。当菌丝进入消化细胞以后,情况与此不同,大量包含酸性磷酸酶的微小颗粒出现在菌丝周围,随后这些酶颗粒相互融合,形成包围菌丝的消化泡,菌丝被溶酶体水解酶所消化。最后消化泡变为包含代谢废物的残体。     

天麻大型细胞消化蜜环菌过程中溶酶体小泡的作用

蜜环菌(Armillaria mellea Fr.)菌丝由天麻(Gastrodia elata Bl.)皮层细胞经纹孔侵入大型细胞。初期大型细胞的原生质膜凹陷,同时细胞壁产生乳突状加厚阻止菌丝侵入。当菌丝侵入大型细胞以后,凹陷的质膜将菌丝紧密包围,大量由单位膜围成的小泡聚集在其周围。随后这些小泡的膜与质膜融合并将其内含物释放到菌丝周围的空间中,凹陷质膜逐渐膨大成为一个包围菌丝的消化泡。小泡和消化泡中均具酸性磷酸酶活性反应产物,证实其分别相当于植物溶酶体系统中的初级和次级溶酶体。菌丝在消化泡中被彻底消化。     

墨兰菌根的结构及酸性磷酸酶定位研究

利用光学显微镜、电子显微镜及细胞化学方法,对墨兰菌根的结构和酸性磷酸酶定位进行了初步研究。结果表明墨兰具有典型的兰科植物根结构,发现该兰花的根的外皮层不具薄壁通道细胞,菌根真菌通过破坏部分根被和外皮层细胞而侵入根的皮层细胞并在细胞内形成菌丝结,侵入的菌丝被染菌皮层细胞质膜和电子透明物质包围,进一步被消化并聚集成衰败菌丝团块。酸性磷酸酶在染菌皮层细胞及包围菌丝的皮层细胞质膜和衰败菌丝细胞壁上有强烈的酶反应,衰败菌丝周围分布有许多单层膜的含酶小泡,它们可相互愈合形成大的含酶泡或与包围菌丝的质膜融合,类似于兰科植物共生原球茎中观察到的现象。说明皮层细胞可主动释放水解酶参与对菌丝的消化     

Study on Structure and Localization of Acid Phosphatase of Mycorrhizal Root of Cymbidium sinense (Orchidaceae)

The microstructure and ultrastructure of mycorrhizal root of Cymbidum sinenese (Andr.) Wild were studied. The results showed that this species possesses the typical root structure of orchids. There is no passage cells in the exodermis of root. Mycorrhizal fungi invade into the cortex by destroying the velamen and exodermal cells, and form pelotons in cortical cells. The hyphae colonizing cortical cells were separated from the cortical cells by electron- lucent material and cortical cell plasma membrane and digested. They often gathered to form clumps. Localization of acid phosphatase revealed that this enzyme possessed higher activity in the cortical cells containing hyphae. Many products of it also occurred on cortical cell plasma membrane surrounding hyphae and degenerated hyphae cell wall. Higher acid phosphatase activity was observed in many vesicles in the cortical cells infected by fimgi. These enzyme vesicles gathered around the invaded hy-phae and often fused with each other, or with cortical cell plasma membrane surrounding hyphae to digest these hyphae. It means cortical cells were able to release hydrolytic enzyme to digest the invaded hyphae.     

Two vacuole-mediated defense strategies in plants

As plants lack immune cells, each cell has to defend itself against invading pathogens. Plant cells have a large central vacuole that accumulates a variety of hydrolytic enzymes and antimicrobial compounds, raising the possibility that vacuoles play a role in plant defense. However, how plants use vacuoles to protect against invading pathogens is poorly understood. Recently, we characterized two vacuole-mediated defense strategies associated with programmed cell death (PCD). In one strategy, vacuolar processing enzyme (VPE) mediated the disruption of the vacuolar membrane, resulting in the release of vacuolar contents into the cytoplasm in response to viral infection. In the other strategy, proteasome-dependent fusion of the central vacuole with the plasma membrane caused the discharge of vacuolar antibacterial protease and cell death-promoting contents from the cell in response to bacterial infection. Intriguingly, both strategies relied on enzymes with caspase-like activities: the vacuolar membrane-collapse system required VPE, which has caspase-1-like activity and the membrane-fusion system required a proteasome that has caspase-3-like activity. Thus, plants may have evolved a cellular immune system that involves vacuolar membrane collapse to prevent the systemic spread of viral pathogens and membrane fusion to inhibit the proliferation of bacterial pathogens.Key words: plant-pathogen interaction, vacuole, hypersensitive cell death, caspase activity, vacuolar processing enzyme, proteasome     

SEQUENTIAL DEGRANULATION OF THE TWO TYPES OF POLYMORPHONUCLEAR LEUKOCYTE GRANULES DURING PHAGOCYTOSIS OF MICROORGANISMS

The sequential discharge of neutrophilic polymorphonuclear leukocyte (PMN) granules—azurophils and specifics—was investigated by electron microscopy and cytochemistry. Thus the enzyme content of PMN phagocytic vacuoles was determined at brief intervals after phagocytosis of bacteria, utilizing peroxidase as a marker enzyme for azurophil granules, and alkaline phosphatase for specifics. At 30 s, approximately half the phagocytic vacuoles were reactive for alkaline phosphatase, whereas none contained peroxidase. Peroxidase-containing vacuoles were rarely seen at 1 min, but by 3 min, vacuoles containing both enzymes were consistently present. Alkaline phosphatase was found in both small and large vacuoles, whereas peroxidase was visible only in large ones. By 10 min, very big phagocytic vacuoles containing considerable amounts of reaction product for both enzymes were evident. These observations indicate that the two types of PMN granules discharge in a sequential manner, specific granules fusing with the vacuole before azurophils. In an earlier paper, we reported that the pH of phagocytic vacuoles drops to 6.5 within 3 min and to ~4 within 7–15 min. Substances known to be present in specific granules (alkaline phosphatase, lysozyme, and lactoferrin) function best at neutral or alkaline pH, whereas most of those contained in azurophil granules (i.e., peroxidase and the lysosomal enzymes) have pH optima in the acid range. Hence the sequence of granule discharge roughly parallels the change in pH, thereby providing optimal conditions for coordinated activity of granule contents.     

The distribution of some hydrolytic enzymes in the cells of the digestive gland of certain lamellibranchs and gastropods

Five hydrolytic enzymes (acid phosphatase, aryl sulphatase, β-glucuronidase, N-acetyl-β-glucosaminidase, and non-specific esterase) have been studied histochemically in the cells of the digestive gland of Mytilus edulis, Helix aspersa , and certain other lamellibranchs and gastropods. All the enzymes studied have basically similar distributions.
In the digestive cells, the enzymes occur in cytoplasmic granules which are believed to be primary lysosomes; in vacuoles which contain phagocytosed food material; and in vacuoles containing lipofuscin granules, which are the residues of digestive activity.
In the basiphil cells of M. edulis , most of the enzymes are localized in a few cytoplasmic granules; non-specific esterase, however, is found throughout the cytoplasm. In the calcium cells of H. aspersa and the other pulmonate gastropods studied, the enzymes are either in cytoplasmic granules, or distributed diffusely throughout the cytoplasm. Acid phosphatase is also found in the calcium spherules, especially in H. aspersa.
In the excretory cells of H. aspersa and the other pulmonates studied, the enzymes are found in granules in the cytoplasm, and in the lipofuscin granules which lie in the vacuoles of these cells.     

盘基网柄菌细胞分化和凋亡中酸性磷酸酶的定位

利用电镜酶细胞化学方法,观察盘基网柄菌细胞分化和凋亡过程中酸性磷酸酶的变化。在细胞丘阶段,酶反应颗粒出现在线粒体内自噬空泡内,随着内自噬空泡的逐渐增大,线粒体内的酶反应颗粒逐渐增多,线粒体内嵴结构不断破坏,直至遍布整个空泡化的线粒体内;当细胞发育至前孢子细胞时,由于嵴结构被完全破坏,酶反应颗粒主要集中在前孢子细胞空泡的单层膜上,空泡化的线粒体内酶反应颗粒逐渐消失。在凋亡的柄细胞中,自噬泡内酶反应强烈,凋亡中期的前柄细胞的细胞核中出现酶反应颗粒,均匀分布在细胞核中,直至细胞核与自噬泡融合。在孢子细胞外被与质膜间也观察到非溶酶体酸性磷酸酶。所得结果证实:线粒体内自噬小泡具有消化功能;自噬泡内酶活性与细胞器消亡有关;细胞核中的酸性磷酸酶可能作为一种非溶酶体酸性磷酸酶参与细胞核中核蛋白的脱磷酸化过程,与发育相关基因表达有关     

Study on Ultrastructure and Localization of Acid Phosphatase of Gastrodia elata Cortical Cells in Their Digestive Process of Armillaria mellea

In order to study the mechanism of the digestive process of Armillaria mellea in Castrodia data, electron microscopy and cytochemical method for determination of acid phosphatase activity was employed. The provacuoles were formed by means of expanded or convoluted ER under the stimulation of cortical cells and large cells of Gastrodia data by Armillaria mellea. A product of acid phosphatase (lead phosphate deposits) occured on the tonoplast. The papillae were produced in the cell wall of cortex in Gastrodia data when Armillaria mellea penetrated into its cortex. Our results showed that the enzyme was not released from cell of Armillaria mellea. A number of small vacuoles in the cortical cells disappeared. At the same time, lead phosphate deposits on the Armillaria mellea hyphae wall were observed and than Armillaria mellea hyphae wall was going to be digested, and the hyphae lost their structure. The activity of Armillaria mellea hyphae was not observed in the large cell of Gastrodia data. A great deal of small vacuoles and mitochondria were produced, at the same time the renewable nuclei and nuclolar vacuoles etc. appeared in the large cells of Gastrodia data under the stimulation of Armillaria mellea.     

Isolation and partial characterization of vacuoles from tobacco protoplasts

Protoplasts from suspension-cultured cells of Nicotiana glutinosa L. were lysed in 0.3 molar sorbitol in 2 millimolar ethylenediaminetetraacetate-tris(hydroxymethyl) aminomethane (pH 7.5) to release intact vacuoles. The vacuoles were purified by centrifugation in a Ficoll step gradient. About 11% of the vacuoles and 13% of the acid phosphatase activity was recovered in the purified vacuole fraction, suggesting that the vacuole is the major site for acid phosphatase in these cells. NADH-cytochrome c reductase, malate dehydrogenase, and cytochrome c oxidase activities were reduced during vacuole purification. The majority of the adenosine 5′-triphosphate (ATP) hydrolytic activity of purified vacuoles was associated with nonspecific acid phosphatase and not with a transport ATPase. As judged by acid phosphatase distribution and electron microscopy, the effective density of vacuoles in a sucrose gradient was low (less than 1.1 grams per cubic centimeter), although an unequivocal estimate of the vacuole or tonoplast density was not possible from the experiments conducted.     

Isolation and characterization of autophagic vacuoles from rat kidney cortex

The number of autophagic vacuoles in the proximal tubule cells of the rat kidney increased considerably after 3 h of vinblastine treatment. This increase was paralleled by stimulated proteolysis in an homogenate prepared from the cortex. We have taken advantage of this expansion in autophagic vacuoles in an effort to isolate these organelles from rat kidney cortex on a discontinuous Metrizamide gradient. Autophagic vacuoles have recently been purified from liver but not from other tissues. The purity of the isolated fraction was 95% of which 55% consisted of typical intact autophagic vacuoles containing sequestered organelles and 45% of other types of secondary lysosome. On plane section many of these displayed one or several intramatrical vesicles or flap like processes forming apparent vesicles at the pole of the organelles, which occasionally contained pinocytosed membranous material. These lysosomes were designated microautophagic vacuoles. It is suggested that the microautophagic vacuoles could be the morphological expression of uptake into lysosomes of small portions of cytosol. The isolated autophagic vacuole fraction was enriched in lysosomal enzymes (acid phosphatase and cathepsin D activities) and displayed high proteolytic rates, especially at acid pH.     

Internal defenses of the snail Biomphalaria glabrata.

We describe three distinct types of cells among Biomphalaria glabrata hemocytes: large cells with a tubulo-vesicular compartment, a component of the endocytic system, and with numerous mitochondria and large aggregates of glycogen particles; medium-size cells poor in organelles and glycogen; and small cells with organelles and few secretory granules. Other small hemocytes can be interpreted as juvenile cells. B. glabrata hemocytes contain few enzymes and do not show specific secretory granules, except for a subpopulation of large cells richer in acid phosphatase vesicles. Hemocytes have different aspects corresponding to different physiological states and their transitions: in quiescent hemocytes, the cell cortex is narrow and organelles are scattered in the cytoplasm, both in circulating cells characterized by thin-folded filopods and large macropinocytic vacuoles and in sedentary cells in which extended filopods connect to the extracellular matrix. In stress-activated hemocytes, the cortical region is thickened by polymerization of actin, and organelles are gathered around the nucleus. Fixed phagocytes are components of the connective tissue; the presence of numerous lysosomes and residual bodies and of acid phosphatase and peroxidase activities suggests a high phagocytic activity.     

Dispersed polyphosphate in fungal vacuoles in Eucalyptus pilularis/Pisolithus tinctorius ectomycorrhizas.

Ectomycorrhizas produced between Pisolithus tinctorius and Eucalyptus pilularis under axenic conditions were rapidly frozen, freeze-substituted in tetrahydrofuran and embedded anhydrously, and dry-sectioned for X-ray microanalysis. The vacuoles of the sheath and Hartig net hyphae were rich in phosphorus and potassium. They also contained sulfur and variable amounts of chlorine. In anhydrously processed freeze-substituted mycorrhizas, dispersed electron-opaque material filled the fungal vacuoles. X-ray maps indicated that P was distributed evenly throughout the entire vacuole profile and was not concentrated in spherical bodies or subregions of the vacuole. There were no electron-opaque granules surrounded by electron-lucent areas, such as are commonly seen in chemically fixed material. The fungal vacuoles were also rich in K, which similarly gave a signal from the entire vacuolar profile. Such P-rich vacuoles occurred in both the mycorrhizal sheath and Hartig net hyphae. Stained sections of ether-acrolein freeze-substituted mycorrhizas also showed only dispersed material in the fungal vacuoles as, in most cases, did acetone-osmium freeze-substituted material. Precipitation of metachromatic granules by ethanol suggested that large amounts of polyphosphate are stored in these regions under the conditions of our experiments, as well as in the tips of actively growing hyphae of the same fungus. The higher plant vacuoles of ectomycorrhizas gave a much lower signal for K, and P was barely detectable. Much more K was located in the vacuoles of the root exodermal cells than in epidermal cells. The analysis of element distribution between the vacuole and cytoplasm in root cells agrees well with that found for other plant species using other techniques. We conclude that polyphosphate is indeed present in the vacuoles of the fungal cells of these ectomycorrhizas, but that in vivo it is in a dispersed form, not in granules.     

Acid phosphatase activity in the wild-type and B-mutant hyphae of Schizophyllum commune.

In the wild-type and B-mutant hyphae of Schizophyllum commune, acid phosphatase activity was found in association with vacuoles, lipid bodies, and endoplasmic reticulum. Small granules containing acid phosphatase also occurred in mitochondria and along the nuclear envelope. Both ultrastructural and biochemical studies indicated greater acid phosphatase activity in the B-mutant than in the wild-type hyphae, which suggests that the mutation in the B incompatibility factor increases the production of the acid phosphatase in the mutant hyphae.     

Kinetics of fusion of the cytoplasmic granules with phagocytic vacuoles in human polymorphonuclear leukocytes. Biochemical and morphological studies

This study on human neutrophils was conducted to measure the kinetics of degranulation of the different cytoplasmic granules into phagocytic vacuoles, and to relate the timing of these events to the burst of respiration that accompanies phagocytosis by these cells. Purified neutrophils were incubated with latex particles opsonized with human immunoglobulin (Ig)G, and phagocytosis was stopped at timed intervals. The cells were examined by electron microscopy to document the sequence of degranulation of the cytoplasmic granules. The azurophil granules and lyosomes were identified by histochemical staining for peroxidase and acid phosphatase, respectively. Phagocytic vacuoles were separated from cell homogenates by floatation on sucrose gradients and assayed for contained lactoferrin, myeloperoxidase, and acid hydrolases. The conclusions drawn from the biochemical and morphological studies were in agreement and indicated: particle uptake and vacuole closure can be completed within 20 s; both the specific and azurophil granules fuse with the phagocytic vacuole much earlier than is generally appreciated, with half-saturation times of 39 s (99% confidence limits, 15-72); oxygen consumption has kinetics similar to those of the fusion of these granules with the phagosome; degranulation of the acid hydrolases beta- glucuronidase, N-acetyl-beta-glucosaminidase (biochemical assays), and acid phosphatase (biochemical assay and electron microscopic cytochemistry) have kinetics of degranulation that are similar to each other but totally different from and much slower than that of myeloperoxidase with half-saturation times of between 354 and 682 s (99% confidence limits, 246-883). This suggests that the acid hydrolases are not co-located with myeloperoxidase in the azurophil granule but are contained in distinct lysosomes, or "tertiary granules".     

木耳菌丝老化过程的微形态学研究

分别从显微和超微结构观察木耳菌种老化过程中菌丝细胞的形态变化。结果显示：接种后30d时,光镜下观察到菌丝结构均匀紧凑,细胞壁光滑;电镜下观察到细胞结构完整,内含物丰富,各种细胞器形态规整,没有老化现象。接种后60d时,光镜下菌丝部分肿胀,色泽加深;电镜下细胞壁疏松,线粒体和液泡肿大,细胞核不规则肿胀,核仁消失,脂肪滴和囊泡增多,并有少量电子致密度高的嗜锇性黑色颗粒状物质出现,表明菌丝开始老化。90d时,光镜下部分菌丝严重肿胀,且色泽更深;电镜下线粒体和液泡肿胀明显,部分细胞核破裂,脂肪滴、囊泡和电子致密度高的嗜锇性黑色颗粒状物质显著增多,细胞壁更加疏松。120d时,光镜下许多菌丝开始断裂,色泽进一步加深;电镜下细胞壁塌陷,膜系统也随之解体,线粒体等细胞器部分溶解消失。150d时,光镜下大部分菌丝完全断裂,并失去菌丝形态;电镜下细胞膜及其内含物已基本消失,只剩部分严重塌陷的细胞壁残骸。由此表明,木耳菌丝的老化是一个由个别向整体逐渐过渡的不可逆的过程。     

Cytochemical demonstration of amine-storing vacuoles and lysosomes in the chicken thrombocytes

A combined electron microscopic and cytochemical study of the thrombocytes of the chicken has clearly identified the amine-storing organelles and lysosomes. A chromaffin positive-reaction product was observed on the inner surface and the granules of the large electron-lucent vacuoles. No acid phosphatase activity was localized in these amine-storing vacuoles. However, the acid phosphatase activity was observed in the small vesicles, the primary lysosomes, and in the large electron dense inclusions with myelin which may be secondary lysosomes. The results of this study suggest that the large empty vacuoles, with one or two very dense osmiophilic peripherally-situated granules, in the chicken thrombocytes are comparable to the vesicles with electron dense materials called "dense bodies" in mammalian thrombocytes.     

DIFFERENCES IN ENZYME CONTENT OF AZUROPHIL AND SPECIFIC GRANULES OF POLYMORPHONUCLEAR LEUKOCYTES : I. Histochemical Staining of Bone Marrow Smears

Histochemical procedures for PMN granule enzymes were carried out on smears prepared from normal rabbit bone marrow, and the smears were examined by light microscopy. For each of the enzymes tested, azo dye and heavy metal techniques were utilized when possible. The distribution and intensity of each reaction were compared to the distribution of azurophil and specific granules in developing PMN. The distribution of peroxidase and six lysosomal enzymes (acid phosphatase, arylsulfatase, β-galactosidase, β-glucuronidase, esterase, and 5'-nucleotidase) corresponded to that of azurophil granules. Progranulocytes contained numerous reactive granules, and later stages contained only a few. The distribution of one enzyme, alkaline phosphatase, corresponded to that of specific granules. Reaction product first appeared in myelocytes, and later stages contained numerous reactive granules. The results of tests for lipase and thiolacetic acid esterase were negative at all developmental stages. Both types of granules stained for basic protein and arginine. It is concluded that azurophil and specific granules differ in their enzyme content. Moreover, a given enzyme appears to be restricted to one of the granules. The findings further indicate that azurophil granules are primary lysosomes, since they contain numerous lysosomal, hydrolytic enzymes, but the nature of specific granules is uncertain since, except for alkaline phosphatase, their contents remain unknown.     

Concanavalin A and the in vitro induction in macrophages of vacuolation and lysosomal enzyme synthesis

Concanavalin A (ConA) induced extensive vacuolation in mouse peritoneal macrophages. Electron microscopic observations on thin sections reveal that the vacuoles are essentially empty except for minute vesicles attached to their inner periphery. The vacuoles consist of irregular structures and are heterogeneous in size distribution. ConA-induced vacuoles exhibit high acid phosphatase activity, suggesting fusion between vacuoles and lysosomes. Induction of acid phosphatase in ConA-treated macrophages was studied under several cultivation conditions. ConA-treated macrophage cultures responded in increase in acid phosphatase activity early after exposure to the lectin, a significant increase recorded already after 1 h. When cultivated in 1% serum medium for 48 h, ConA-treated macrophages exhibit twice the activity of acid phosphatase at zero time as well as that of non-treated control cultures. The effect of ConA on thioglycolate-stimulated mouse peritoneal macrophages was also studied. Vacuole formation resulting from lectin binding and internalization is discussed in terms of possible lectin effects on membrane fluidity, fusion capacity, surface to volume conservation during vacuole formation, fusion of vacuoles with lysosomes and intravacuolar lysosomal enzyme activities. The phenomenon of lysosomal enzyme induction as a result of ConA treatment is being correlated with enzyme induction due to other stimuli.