Intermediate filament antigens of 60 and 65 kDa in the nuclear matrix of plants: their detection and localization.

Although the presence of a matrix in plant nuclei has been reported, major questions remain about its structural and biochemical features. We have used an intermediate filament antibody of broad specificity to explore whether Daucus carota (carrot) nuclei and nuclear matrices contain intermediate filament/lamin antigens and, if so, where specifically they are localized. SDS-PAGE and Western blotting revealed two bands, at 60 and 65 kDa, that were highly immunoreactive with the intermediate filament antibody (IFA) of Pruss et al. (1981, Cell 27, 419-428). This pattern was observed consistently, not only with carrot cell-free nuclei and nuclear matrices, but also with nuclear preparations from Vicia faba (broad bean) and Pisum sativum (pea). Immunofluorescence studies with whole carrot nuclei localized the IFA antigens to the nucleoplasm and disclosed no accentuated peripheral labeling. Agarose-embedded nuclear matrices showed not only fluorescence throughout the nucleoplasm but also heavy labeling surrounding the nucleoli and suggestions of peripheral labeling. At the ultrastructural level, immunogold results from pre- and postembedment treatments supported the conclusion that IFA antigens occur throughout the nucleoplasm, with possibly a slight concentration at the periphery. These combined results provide substantial evidence that plant nuclei and their matrices possess at least two major intermediate filament antigens with molecular weights characteristic of animal lamins. Whether or not these antigens represent plant lamins, their nonperipheral localization hints at significant differences among the eukaryotic kingdoms in nuclear organization.

Central Somatostatin Inhibits Cholecystokinin-lnduced Oxytocin Secretion in Conscious Rats.

Recent studies have demonstrated the presence of fibres immunoreactive for somatostatin-28 (SS-28), which originate in the brainstem and selectively innervate the magnocellular oxytocin (OT) cells of the supraoptic nucleus. The potential physiological relevance of this pathway was investigated in the present study by measuring plasma OT levels in response to intraperitoneal administration of cholecystokinin in conscious male rats pretreated with intracerebroventricular injections of either SS-28 or artificial cerebrospinal fluid. Cholecystokinin treatment produced the expected marked rise in plasma OT levels in control rats pretreated intracerebroventricularly with artificial cerebrospinal fluid. However, this response was markedly blunted by prior intracerebroventricular administration of SS-28, even though SS-28 itself had no effect on basal plasma OT levels, nor did it impair OT release in response to hypertonic saline injection. These results demonstrate that centrally injected SS-28 can selectively block cholecystokinin-stimulated release of OT in rats, and support an inhibitory role for this peptide in brainstem-mediated neurohypophysial hormone secretion. Central SS-28 administration also elicited up to 3-fold increases in the amount of food ingested in 1 h by previously sated rats. These observations suggest the possibility that endogenous SS-28 may be involved in stimulating food intake in rats, and establish the basis for future studies to clarify the role of this neuropeptide in controlling ingestive behaviours.

Growth of an ocular strain of Chlamydia trachomatis on Chang conjunctival cells.

The most widely used cell lines for in vitro studies of Chlamydia trachomatis infections are McCoy and HeLa cells. Our understanding of the intracellular events that occur during ocular C. trachomatis infections may well be improved if such infections could be studied in a host cell that more closely approximates the natural host conjunctival cell. We report here that Chang conjunctival cells, which have been derived from human conjunctival cells, can be infected with C. trachomatis, serovar B. The optimal times for exposure of the host cells to infectious material and to cycloheximide are about 24 and 48 h, respectively. Under these conditions, the maximum number of inclusions is observed at 72 h after centrifugation.

The detection of fucose residues in plant nuclear envelopes.

Protoplasts from suspension-culturedDaucus carota L. cells, when fixed and incubated with fluorescein conjugates of the fucosyl-specific lectinUlex europaeus agglutinin I, exhibited the following pattern of labeling: plasma membranes were not marked, but striking halos of fluorescence appeared around the periphery of all nucleic. Identical observations were made with protoplasts fromVicia faba L. leaves,Pisum sativum L. epicotyls,Zea mays L. roots andGlycine max L. cell suspensions, as well as with nucleic in cell-free preparations from the same sources. These results indicate that in a broad spectrum of angiosperm cells, fucose residues are associated with the nuclear envelope. The relationship of this finding in plant cells to recent discoveries regarding nuclear glycoconjugates in animal cells remains to be explored.

An ultrastructural search for lectin-binding sites on surfaces of spinach leaf organelles.

Organelles isolated from leaves of spinach (Spinacia oleracea L.) were prefixed in glutaraldehyde and then incubated with ferritin conjugates of four lectins - Concanavalin A (Con A), Ricinus communis L. agglutinin, MW 120,000 (RCA), soybean agglutinin (SBA), and wheat germ agglutinin (WGA) - in order to probe their cytoplasmic surfaces for saccharide residues. In each case the major leaf organelles, including microbodies, mitochondria and chloroplast derivatives, failed to exhibit labeling when examined with the electron microscope. Tobacco (Nicotiana tabacum L.) leaf protoplasts, incubated simultaneously with and under identical conditions to the spinach organelles, showed specific labeling of their plasma membranes with all four lectin conjugates, thus establishing the efficacy of the procedure for demonstrating the presence of binding sites when they exist. Further attempts to show binding of one of the lectins, Con A, by labeling with fluorescein-Con A and by organelle agglutination, yielded results consistent with the absence of ultrastructural labeling. It is concluded that no saccharide residues recognized by the four lectins are present on the cytoplasmic surfaces of organelles and that those residues reported to be constituents of intracellular membranes, therefore, are most likely exposed on the luminal (extracytoplasmic) surfaces.

Cytochemical localization of glycolate oxidase in microbodies of Klebsormidium.

The filamentous green alga Klebsormidium flaccidum A.Br. was fixed with glutaraldehyde, incubated in a cytochemical medium designed to detect glycolate-oxidase activity, and prepared for electron microscopy. Heavy deposits of stain were observed in microbodies following incubation with either glycolate or L-lactate as substrate, but not after incubation with D-lactate or H2O. When Chlamydomanas reinhardi Dangeared cells were treated in the same way, their microbodies did not appear stained. The results establish that in Klebsormidium glycolate-oxidase occurs in microbodies (peroxisomes), as it does in angiosperms; also, they emphasize the dichotomy between those green algae which contain glycolate-oxidase and those, such as Chlamydomonas, which possess the mitochondrial enzyme glycolate dehydrogenase.

Cytochemical localization of glycolate dehydrogenase in mitochondria of chlamydomonas.

Mildly disrupted cells of Chlamydomonas reinhardi Dangeard were incubated in a reaction medium containing glycolate, ferricyanide, and cupric ions, and then processed for electron microscopy. As a result of the cytochemical treatment, an electron opaque product was deposited specifically in the outer compartment of mitochondria; other cellular components, including microbodies, did not accumulate stain. Incubation with d-lactate yielded similar results, while treatment with l-lactate produced only a weak reaction. Oxamate, which inhibits glycolate dehydrogenase activity in cell-free extracts, also inhibited the cytochemical reaction. These findings demonstrate in situ that glycolate dehydrogenase is localized in mitochondria, and thus corroborate similar conclusions reached on the basis of enzymic studies of isolated algal organelles.

Enzymes related to lactate metabolism in green algae and lower land plants.

Cell-free extracts of Chlorella pyrenoidosa contained two enzymes capable of oxidizing d-lactate; these were glycolate dehydrogenase and NAD(+)-dependent d-lactate dehydrogenase. The two enzymes could be distinguished by differential centrifugation, glycolate dehydrogenase being largely particulate and NAD(+)-d-lactate dehydrogenase being soluble. The reduction of pyruvate by NADH proceeded more rapidly than the reverse reaction, and the apparent Michaelis constants for pyruvate and NADH were lower than for d-lactate and NAD(+). These data indicated that under physiological conditions, the NAD(+)-linked d-lactate dehydrogenase probably functions to produce d-lactate from pyruvate.Lactate dehydrogenase activity dependent on NAD(+) was found in a number of other green algae and in the green tissues of a few lower land plants. When present in species which contain glycolate oxidase rather than glycolate dehydrogenase, the enzyme was specific for l-lactate rather than d-lactate. A cyclic system revolving around the production and utilization of d-lactate in some species and l-lactate in certain others is proposed.

The occurrence of glycolate dehydrogenase and glycolate oxidase in green plants: an evolutionary survey.

Homogenates of various lower land plants, aquatic angiosperms, and green algae were assayed for glycolate oxidase, a peroxisomal enzyme present in green leaves of higher plants, and for glycolate dehydrogenase, a functionally analogous enzyme characteristic of certain green algae. Green tissues of all lower land plants examined (including mosses, liverworts, ferns, and fern allies), as well as three freshwater aquatic angiosperms, contained an enzyme resembling glycolate oxidase, in that it oxidized l- but not d-lactate in addition to glycolate, and was insensitive to 2 mm cyanide. Many of the green algae (including Chlorella vulgaris, previously claimed to have glycolate oxidase) contained an enzyme resembling glycolate dehydrogenase, in that it oxidized d- but not l-lactate, and was inhibited by 2 mm cyanide. Other green algae had activity characteristic of glycolate oxidase and, accordingly, showed a substantial glycolate-dependent O(2) uptake. It is pointed out that this distribution pattern of glycolate oxidase and glycolate dehydrogenase among the green plants may have phylogenetic significance.Activities of catalase, a marker enzyme for peroxisomes, were also determined and were generally lower in the algae than in the land plants or aquatic angiosperms. Among the algae, however, there were no consistent correlations between levels of catalase and the type of enzyme which oxidized glycolate.

Ultrastructure and distribution of microbodies in leaves of grasses with and without CO2-photorespiration.

A comparative study was made of the ultrastructure, distribution and abundance of leaf microbodies in four species of "temperate" grasses with high and four "tropical" grasses with low CO2-photorespiration. The temperate grasses were all festucoid; the tropical grasses included two panicoid species and two chloridoid. Comparisons of relative abundance were made by computing the average numbers of microbody profiles per cell section.Although microbodies were present in the green parenchymatous leaf cells in all grasses examined, their average number per cell was in general severalfold greater in the grasses with high CO2-photorespiration than in those with low. Furthermore, whereas in the grasses with high CO2-photorespiration the microbodies were distributed through the mesophyll, in those with low CO2-photorespiration they were concentrated in the vascular-bundle-sheath cells and were smaller and relatively scarce in the mesophyll cells. The leaf microbodies of the eight grass species resembled one another in general morphology, but differed to some extent in regard to size and type of inclusion. Microbodies of all four festucoid species contained numerous fibrils with a discernible substructure. Those of the two panicoid species contained clusters of round bodies with transparent cores. The equivalence of the microbodies to peroxisomes as biochemically defined was shown cytochemically by employing 3,3'-diaminobenzidine for the localization of catalase, a marker enzyme for the peroxisome. This reaction was blocked by the catalase inhibitor, aminotriazole.The observations on the relative abundance and distribution of peroxisomes in leaves of grasses with high CO2-photorespiration versus those with low are consistent with the published biochemical data on the levels and distribution of peroxisomal enzymes in representatives of plants with high and low CO2-photorespiration, and may help explain the differences in apparent photorespiratory levels between these two groups of plants.

Cytochemical localization of catalase in leaf microbodies (peroxisomes).

Segments of mature tobacco leaves were fixed in glutaraldehyde, incubated in medium containing 3,3'-diaminobenzidine (DAB) and hydrogen peroxide, and postfixed in osmium tetroxide. Electron microscopic observation of treated tissues revealed pronounced deposition of a highly electron-opaque material in microbodies but not in other organelles. The coarsely granular reaction product is presumably osmium black formed by reaction of oxidized DAB with osmium tetroxide. Reaction of the microbodies with DAB was completely inhibited by 0.02 M 3-amino-1,2,4-triazole and was considerably reduced by 0.01 M potassium cyanide. These results, when considered in light of recent biochemical studies, strongly suggest that catalase is responsible for the reaction. Sharp localization of this enzyme in microbodies establishes that they are identical to the catalase-rich "peroxisomes" recently isolated from leaf cell homogenates. A browning reaction that occurred in leaves during the incubation step was inhibited by cyanide but not by aminotriazole and therefore could not have been caused by the same enzyme. This reaction and a slight deposition of dense material within primary and secondary walls are ascribed to oxidation of DAB by soluble and wall-localized peroxidases.

Microbody-like organelles in leaf cells.

An organelle approximately 0.5 to 1.5 microns in diameter, limited by a single membrane, occurs abundantly in the chlorophyllous cells of leaves of several dicotyledonous and monocotyledonous plants. Its finely granular matrix frequently contains crystalline, fibrous, or amorphous inclusions. It is frequently appressed to a chloroplast or squeezed between chloroplasts so that its limiting membrane is in extensive contact with the outer membranes of the chloroplast envelopes. The organelle is probably identical with recently isolated leaf particles that contain enzymes involved in the metabolism of glycolate, a chloroplast product; it is interpreted as a form of plant microbody.

Fine-structural characterization of plant microbodies.

Morphology and distribution of the relatively less well known organelles of plants have been studied with the electron microscope in tissues fixed in glutaraldehyde and postfixed in osmium tetroxide. An organelle comparable morphologically to the animal microbody and similar to the plant microbody isolated by MOLLENHAUER et al. (1966) has been encountered in a variety of plant species and tissues, and has been studied particularly in bean and radish roots, oat coleoptiles, and tobacco roots, stems and callus. The organelle has variable shape and is 0.5 to 1.5 µ in the greatest diameter. It has a single bounding membrane, a granular to fibrillar matrix of variable electron density, and an intimate association with one or two cisternae of rough endoplasmic reticulum (ER). Microbodies are easily the most common and generally distributed of the less well characterized organelles of plant cells. It seems very probable that they contain the enzymes characteristic of animal lysosomes (containing hydrolases) or animal microbodies (containing catalase and certain oxidases). Spherosomes are also possible sites of enzyme activity but are not as common or as widely distributed as microbodies. For this reason it appears likely that the particles designated as "plant lysosomes", "spherosomes", "peroxisomes", etc., in some of the cytochemical and biochemical studies on enzyme localization will prove to be microbodies.Variations in the morphology and ER associations of microbodies in tissues of bean and radish are described and discussed. "Crystal-containing bodies" (CCBs) are interpreted as a specialized type of microbody characteristic of metabolically less active cells. Stages in the formation of CCBs from microbodies of typical appearance are illustrated for Avena.The general occurrence of microbodies in meristematic and differentiating cells and their close association with the ER suggest that they may play active roles in cellular metabolism. The alterations in their morphology and numbers that are observed in certain differentiating cells suggest further that the enzyme complements and metabolic roles of microbodies might change during cellular differentiation. If so, microbodies could be the functional equivalent of both microbodies and lysosomes of animal cells.