A preliminary analysis of Fatty Acid synthesis in pea roots

Subcellular fractions from pea (Pisum sativum L.) roots have been prepared by differential centrifugation techniques. Greater than 50% of the recovered plastids can be isolated by centrifugation at 500g for 5 minutes. Plastids of this fraction are largely free from mitochondrial and microsomal contamination as judged by marker enzyme analysis. De novo fatty acid biosynthesis in pea roots occurs in the plastids. Isolated pea root plastids are capable of fatty acid synthesis from acetate at rates up to 4.3 nanomoles per hour per milligram protein. ATP, bicarbonate, and either Mg²⁺ or Mn²⁺ are all absolutely required for activity. Coenzyme A at 0.5 millimolar improved activity by 60%. Reduced nucleotides were not essential but activity was greatest in the presence of 0.5 millimolar of both NADH and NADPH. The addition of 0.5 millimolar glycerol-3-phosphate increased activity by 25%. The in vitro and in vivo products of fatty acid synthesis from acetate were primarily palmitate, stearate, and oleate, the proportions of which were dependent on experimental treatments. Fatty acids synthesized by pea root plastids were recovered in primarily phosphatidic acid and diacylglycerol or as water soluble derivatives and the free acids. Lesser amounts were found in phosphatidylcholine, phosphatidylethanolamine, phosphatidylglycerol, and monogalactosyldiacylglycerol.     

Effects of Indoleacetic Acid on the Quantity of Mitochondria, Microbodies, and Plastids in the Apical and Expanding Cells of Dark-grown Oat Coleoptiles

We determined the number of mitochondria, microbodies, and plastids in dark-grown oat (Avena sativa) coleoptiles following incubation in indoleacetic acid (IAA) for a period of 60 minutes at 6-minute intervals. In the apical outer epidermis of coleoptiles, the mitochondria increased from 31.4 to 35 per cell section with a 6-minute incubation in IAA, and this trend persisted over the 60-minute incubation. Neither the microbodies, plastids, nor the dicytosomes (Gawlik and Miller 1974 Plant Physiol 54:217-221) responded to the hormone. The apical parenchyma showed no change in quantity of any of the organelles including the dictyosomes during IAA incubation. The quick response of mitochondria in the coleoptile tip could be interpreted as an association of this organelle with hormone transport, growth, or perhaps with gravity perception. In the subapical expansion region, IAA caused significant reductions of mitochondria, microbodies, and dictyosomes in the outer epidermis compared to the control, the timing of which preceded the IAA-induced elongation and of geotropism. The fast response of organelles in the various cells is probably a change in organelle volume rather than number. That microbodies show a response to the plant hormone in the permanently achlorophyllous epidermis indicates that these organelles, in addition to their peroxisomal functions in green leaves, also may have a growth regulation function. IAA treatment was without effect on the quantity of the various types of plastids (including the amyloplasts) in the different oat coleoptile cells.     

Photosynthetic carbon metabolism of isolated corn chloroplasts

Chloroplasts have been isolated from 4- to 6-day-old corn (Zea mays) leaves capable of assimilating 45 micromoles CO₂ per milligram chlorophyll per hour. The effects of various factors such as inorganic phosphate, reducing agents, inhibitors, intermediates of the photosynthetic carbon reduction cycle, organic acids, and oxygen on the photosynthetic rate and on the distribution of ¹⁴C within the products by these chloroplasts were determined. The photosynthetic carbon metabolism of the corn plastids appeared to be similar to that already observed in spinach and pea chloroplasts. It was concluded that the corn plastids can fix CO₂ at meaningful rates via the photosynthetic carbon reduction cycle of Calvin without the operation of a cycle involving the C-4 compounds, malate and aspartate.     

The Distribution of Gibberellins in Vegetative Tissues of Pisum sativum L. : I. Biological and Biochemical Consequences of the le Mutation

The concentrations of endogenous gibberellin (GA) 1, 5, 8, 19, 20, and 29 in the component tissues of maturing tall (Le) and dwarf (le) pea (Pisum sativum) plants have been determined. The following conclusions were drawn from the data obtained: (a) GA₂₀ and its metabolites accumulate only in the growing regions of Le and le plants; (b) the le mutation is biochemically expressed in all immature tissues of the dwarf plants; (c) the quantitative composition of the GA metabolites in the various immature tissues is variable; (d) the total GA concentration in apical buds, unexpanded leaves, and tendrils is considerably higher than in GA₁-responsive stem tissue; and (e) there is very little GA accumulation of the inactive 2β-hydroxylated GAs (GA₈ and GA₂₉) in either the mature vegetative tissues or the roots of pea plants.     

Subcellular distribution of enzymes of the oxidative pentose phosphate pathway in root and leaf tissues

The subcellular distribution of enzymes of the oxidative pentose phosphate pathway was studied in plants. Root and leaf tissues from several species were separated by differential centrifugation into plastidic and cytosolic fractions. In all tissues studied, glucose 6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase were found in both plastidic and cytosolic compartments. In maize and pea root, and spinach and pea leaf, the non-oxidative enzymes of the pentose phosphate pathway (transaldolase, transketolase, ribose 5-phosphate isomerase, ribulose 5-phosphate 3-epimerase) appear to be restricted to the plastid. In tobacco leaf and root, however, the non-oxidative enzymes were found in the cytosolic as well as the plastidic compartments. In the absence of ribose 5-phosphate isomerase and ribulose 5-phosphate 3-epimerase in the cytosol, the product of the oxidative limb of the pathway (ribulose 5-phosphate) must be transported into a compartment capable of utilizing it. Ribulose 5-phosphate was supplied to isolated intact pea root plastids and was shown to be capable of supporting nitrite reduction. The kinetics of ribulose 5-phosphate-driven nitrite reduction in isolated pea root plastids suggested that the metabolite was translocated across the plastid envelope in a carrier-mediated transport process, indicating the presence of a translocator capable of transporting pentose phosphates.Keywords: Pentose phosphate, subcellular, plastid, ribulose 5-phosphate, compartmentation      

Analysis of the state of posttranslational calmodulin methylation in developing pea plants

A specific calmodulin-N-methyltransferase was used in a radiometric assay to analyze the degree of methylation of lysine-115 in pea (Pisum sativum) plants. Calmodulin was isolated from dissected segments of developing roots of young etiolated and green pea plants and was tested for its ability to be methylated by incubation with the calmodulin methyltransferase in the presence of [³H]methyl-S-adenosylmethionine. By this approach, the presence of unmethylated calmodulins were demonstrated in pea tissues, and the levels of methylation varied depending on the developmental state of the tissue tested. Calmodulin methylation levels were lower in apical root segments of both etiolated and green plants, and in the young lateral roots compared with the mature, differentiated root tissues. The incorporation of methyl groups into these calmodulin samples appears to be specific for position 115 since site-directed mutants of calmodulin with substitutions at this position competitively inhibited methyl group incorporation. The present findings, combined with previous data showing differences in the ability of methylated and unmethylated calmodulins to activate pea NAD kinase (DM Roberts et al. [1986] J Biol Chem 261: 1491-1494) raise the possibility that posttranslational methylation of calmodulin could be another mechanism for regulating calmodulin activity.     

THE DEVELOPMENT OF MICROBODIES AND PEROXISOMAL ENZYMES IN GREENING BEAN LEAVES

The ontogeny of leaf microbodies (peroxisomes) has been followed by (a) fixing primary bean leaves at various stages of greening and examining them ultrastructurally, and (b) homogenizing leaves at the same stages and assaying them for three peroxisomal enzymes. A study employing light-grown seedlings showed that when the leaves are still below ground and achlorophyllous, microbodies are present as small organelles (e.g., 0.3 µm in diameter) associated with endoplasmic reticulum, and that after the leaves have turned green and expanded fully, the microbodies occur as much larger organelles (e.g., 1.5 µm in diameter) associated with chloroplasts. Specific activities of the peroxisomal enzymes increase 3- to 10-fold during this period. A second study showed that when etiolated seedlings are transferred to light, the microbodies do not appear to undergo any immediate morphological change, but that by 72 h they have attained approximately the size and enzymatic activity possessed by microbodies in the mature primary leaves of light-grown plants. It is concluded from the ultrastructural observations that leaf microbodies form as small particles and gradually develop into larger ones through contributions from smooth portions of endoplasmic reticulum. In certain aspects, the development of peroxisomes appears analogous to that of chloroplasts. The possibility is examined that microbodies in green leaves may be relatively long-lived organelles.     

Subcellular distribution, multiple forms and development of glutamate-pyruvate (glyoxylate) aminotransferase in plant tissues

According to a sucrose density gradient analysis of cell organelles from homogenates of green leaves of rye, wheat and pea seedlings glutamate-pyruvate aminotransferase was predominantly localized in the leaf microbodies (peroxisomes; 90%) and to a minor extent in the mitochondria (10%) but completely absent from chloroplasts. In etiolated rye leaves the distribution of the enzyme was similar. In other non-green tissues glutamate-pyruvate aminotransferase was predominantly associated with the mitochondria but also present in the microbodies of dark-grown pea roots and in the glyoxysomes of Ricinus endosperm. In the microbodies isolated from potato tubers the enzyme was not detectable. Glutamate-pyruvate aminotransferase activity was not associated with the proplastid fractions of the non-green tissues. The distribution of glutamate-oxaloacetate aminotransferase was different from that of glutamate-pyruvate aminotransferase. Glutamate-oxaloacetate aminotransferase was found in chloroplasts, proplastids, mitochondria, microbodies and in the supernatant. Evidence is presented that glutamate-pyruvate and glutamate-glyoxylate aminotransferase activities were catalyzed by the same enzyme. Both activities showed the same organelle distribution on sucrose gradients and both were eluted at the same salt concentration from DEAE-cellulose. By chromatography of preparations from rye leaf extracts on DEAE-cellulose two forms of glutamate-pyruvate (glyoxylate) aminotransferase were separated. The major fraction eluting at a low salt concentration was identified as peroxisomal form and the minor fraction eluting at a higher salt concentration was identified as a mitochondrial form. Both the glutamate-glyoxylate and the glutamate-pyruvate aminotransferase activities of the peroxisomal as well as of the mitochondrial forms of the enzyme were strongly (about 80%) inhibited by the presence of 10 mM glycidate, previously described as an inhibitor of glutamate-glyoxylate aminotransferase in tobacco tissue. Pig heart glutamate-pyruvate aminotransferase exhibited no glutamate-glyoxylate aminotransferase activity and was only slightly inhibited by glycidate. The development of glutamate-pyruvate aminotransferase activity in the leaves of rye seedlings was strongly increased in the light, relative to dark-grown seedlings, and very similar to that of catalase activity while the development of glutamate-oxaloacetate aminotransferase was, in close coincidence with the behavior of leaf growth, only slightly enhanced by light. It is discussed that in green leaves an extrachloroplastic synthesis of alanine is of considerable advantage for the metabolic flow during photosynthesis.     

The capacity of plastids from developing pea cotyledons to synthesise acetyl CoA

In order to determine whether the enzymes required to convert triose phosphate to acetyl CoA were present in pea (Pisum sativum L.) seed plastids, a rapid, mechanical technique was used to isolate plastids from developing cotyledons. The plastids were intact and the extraplastidial contamination was low. The following glycolytic enzymes, though predominantly cytosolic, were found to be present in plastids: glyceraldehyde 3-phosphate dehydrogenase (EC 1.2.1.12), phosphoglycerate kinase (EC 2.7.2.3), and pyruvate kinase(EC 2.7.1.40). Evidence is presented which indicates that plastids also contained low activities of enolase (EC 4.2.1.11) and phosphoglycerate mutase (EC 2.7.5.3). Pyruvate dehydrogenase, although predominantly mitochondrial, was also present in plastids. The plastidial activities of the above enzymes were high enough to account for the rate of lipid synthesis observed in vivo.Abbreviations FPLC fast protein liquid chromatography - PPi pyrophosphate     

Synthesis of the phytoalexin pisatin by a methyltransferase from pea

Previous labeling studies in vivo suggest that the terminal step of (+)pisatin biosynthesis in Pisum sativum L. is methylation of the phenol (+)6a-hydroxymaackiain (HMK). We have found that extracts from pea seedlings perform this reaction, using S-adenosylmethionine as the methyl donor. The enzyme activity was induced by microbial infection or treatment with CuCl₂, which elicit pisatin synthesis, though some activity was also present in healthy tissues. It has been reported that CuCl₂-treated pea tissue provided with (−)HMK or (−)maackiain can synthesize (−)pisatin. Our extract showed no methyltransferase activity dependent on either of these substrates. Methylation of (+)maackiain was detectable, but much slower than that of (+)HMK.     

Isolation of microbodies from plant tissues

Specialized microbodies have previously been isolated and characterized from fatty seedling tissues (glyoxysomes) and leaves (leaf peroxisomes). We have now examined 11 other plant tissues, including tubers, fruits, roots, shoots, and petals, and find that all contain particulate catalase, a distinctive common enzyme component of microbodies. On linear sucrose gradients the catalase activity peaks sharply at a higher equilibrium density (1.20 to 1.25 gram per cm³ in the various tissues) than the mitochondria (1.17 to 1.20). Only small amounts of protein are recovered in the fractions containing catalase, although a definite band is visible in preparations from some tissues, e.g., potato. As in the preparations from castor bean endosperm and spinach leaves for which comparable data are provided, the distribution of glycolate oxidase and uricase follows closely that of catalase on the gradients. The preparations from potato lack glyoxylate reductase and the transaminases, typical enzymes of leaf peroxisomes, and the distinctive enzymes of glyoxysomes are missing. Nonspecialized microbodies with limited enzyme composition can thus be isolated from a variety of plant tissues.     

Stress-Induced Legume Root Nodule Senescence. Physiological, Biochemical, and Structural Alterations

Nitrate-fed and dark-stressed bean (Phaseolus vulgaris) and pea (Pisum sativum) plants were used to study nodule senescence. In bean, 1 d of nitrate treatment caused a partially reversible decline in nitrogenase activity and an increase in O₂ diffusion resistance, but minimal changes in carbon metabolites, antioxidants, and other biochemical parameters, indicating that the initial decrease in nitrogenase activity was due to O₂ limitation. In pea, 1 d of dark treatment led to a 96% decline in nitrogenase activity and sucrose, indicating sugar deprivation as the primary cause of activity loss. In later stages of senescence (4 d of nitrate or 2–4 d of dark treatment), nodules showed accumulation of oxidized proteins and general ultrastructural deterioration. The major thiol tripeptides of untreated nodules were homoglutathione (72%) in bean and glutathione (89%) in pea. These predominant thiols declined by approximately 93% after 4 d of nitrate or dark treatment, but the loss of thiol content can be only ascribed in part to limited synthesis by γ-glutamylcysteinyl, homoglutathione, and glutathione synthetases. Ascorbate peroxidase was immunolocalized primarily in the infected and parenchyma (inner cortex) nodule cells, with large decreases in senescent tissue. Ferritin was almost undetectable in untreated bean nodules, but accumulated in the plastids and amyloplasts of uninfected interstitial and parenchyma cells following 2 or 4 d of nitrate treatment, probably as a response to oxidative stress.     

Studies on seeds. II. Origin and degradation of lipid vesicles in pea and bean cotyledons

At least two kinds of lipid vesicles are present in pea and bean cotyledons which can be recognized at seed maturity on the basis of whether they do or do not interassociate into lipid vesicle sheets. Those that do interassociate into sheets are also characterized by (a) their association with plastids or plasma membranes during dormancy, and (b) the unique transformation into flattened saccules that they undergo during the first few days of seed germination. These interassociated (or composite) lipid vesicles have been found in only a few seeds and may be restricted to certain classes of plants and/or certain states of cellular development. Lipid vesicle-to-saccule transformation is predominantly confined to the germinating seed. However, some lipid vesicle-derived saccules are already present in some cells even before the seed reaches maturity. These partially transformed vesicles and saccules remain unchanged over dormancy, and then resume their transformation when the seed is germinated. This suggests that some stages of seed germination are already underway before the seed reaches maturity and are only resumed at seed germination. The lipid vesicles that do not interassociate into sheets (i.e., the simple lipid vesicles) are present in all tissues at all states of cellular development. These vesicles do not undergo any conspicuous structural changes during development.     

Development of the alt Mutant of Pisum sativum L

The alt (albina-terminalis) mutant of Pisum sativum L. germinates normally, produces several nodes, and then above a sharp transition produces 2 to 3 bleached nodes, ceases growth, and eventually dies. Green nodes have normal chlorophyll content, absorption spectra, photosynthetic rates, and ultrastructure. In bleaching tissues, the chloroplasts degenerate rapidly, followed by extensive disruption and loss of the remaining cytoplasm and organelles. Application of tissue extracts of normal genotypes of pea, corn, and bean stimulates apical development of alt. The resulting tissues have essentially normal structure and function. Application of thiamine, thiamine monophosphate, and thiamine pyrophosphate also stimulate normal apical development at concentrations of 1 micromolar and above. Partial characterization of the stimulus from pea seed extracts is consistent with thiamine as the active factor.     

Tissue and Cellular Distribution of Glutamine Synthetase in Roots of Pea (Pisum sativum) Seedlings

The effect of nitrate application on glutamine synthetase activity in roots of pea (Pisum sativum L.) seedlings (2 weeks old) was studied. Separation of organelles from root fragments by sucrose density-gradient centrifugation revealed that both nitrite reductase and glutamine synthetase activities increased in root plastids as a response to nitrate application and that no such response was induced by ammonium application. Glutamine synthetase activity was also found to increase in plastids with distance from apex in nitrate-treated plants, the highest specific activity being located in the fourth 1-centimeter segment. Separation by SDS-PAGE and characterization by Western blotting showed that cytosolic glutamine synthetase contains one subunit polypeptide (28 kilodaltons) and that plastid glutamine synthetase contains both the 38-kilodalton subunit and a heavier subunit. When nitrate was present in the nutrient solution, the heavier subunit increased in abundance in protein fractions obtained from purified root plastids.     

New data about the suspensor of succulent angiosperms: Ultrastructure and cytochemical study of the embryo-suspensor of Sempervivum arachnoideum L. and Jovibarba sobolifera (Sims) Opiz

The development of the suspensor in two species ?? Sempervivum arachnoideum and Jovibarba sobolifera ?? was investigated using cytochemical methods, light and electron microscopy. Cytological processes of differentiation in the embryo-suspensor were compared with the development of embryo-proper. The mature differentiated suspensor consists of a large basal cell and three to four chalazal cells. The basal cell produces haustorial branched invading ovular tissues. The walls of the haustorium and the micropylar part of the basal cell form the wall ingrowths typical for a transfer cells. The ingrowths also partially cover the lateral wall and the chalazal wall separating the basal cell from the other embryo cells. The dense cytoplasm filling the basal cell is rich in: numerous polysomes lying free or covering rough endoplasmic reticulum (RER), active dictyosomes, microtubules, bundles of microfilaments, microbodies, mitochondria, plastids and lipid droplets. Cytochemical tests (including proteins, insoluble polysaccharides and lipids are distributed in the suspensor during different stages of embryo development) showed the presence of high amounts of macromolecules in the suspensor cells, particularly during the globular and heart-shaped phases of embryo development. The protein bodies and lipid droplets are the main storage products in the cells of the embryo-proper. The results of Auramine 0 indicate that a cuticular material is present only on the surface walls of the embryo-proper, but is absent from the suspensor cell wall. The ultrastructural features and cytochemical tests indicate that in the two species ?? S. arachnoideum and J. sobolifera ?? the embryo-suspensor is mainly involved in the absorption and transport of metabolites from the ovular tissues to the developing embryo-proper.     

Cuscuta europaea plastid apparatus in various developmental stages: Localization of THF1 protein

It was generally accepted that Cuscuta europaea is mostly adapted to a parasitic lifestyle with no detectable levels of chlorophylls. We found out relatively high level of chlorophylls (Chls a+b) in young developmental stages of dodder. Significant lowering of Chls (a+b) content and increase of carotenoid concentration was typical only for ontogenetically more developed stages. Lower content of photosynthesis-related proteins involved in Chls biosynthesis and in photosystem formation as well as low photochemical activity of PSII indicate that photosynthesis is not the main activity of C. europaea plastids. Previously, it has been shown in other species that the Thylakoid Formation Protein 1 (THF1) is involved in thylakoid membrane differentiation, plant-fungal and plant-bacterial interactions and in sugar signaling with its preferential localization to plastids. Our immunofluorescence localization studies and analyses of haustorial plasma membrane fractions revealed that in addition to plastids, the THF1 protein localizes also to the plasma membrane and plasmodesmata in developing C. europaea haustorium, most abundantly in the digitate cells of the endophyte primordium. These results are supported by western blot analysis, documenting the highest levels of the THF1 protein in “get together” tissues of dodder and tobacco. Based on the fact that photosynthesis is not a typical process in the C. europaea haustorium and on the extra-plastidial localization pattern of the THF1, our data support rather other functions of this protein in the complex relationship between C. europaea and its host.     

Ultrastructure of the vegetative cell ofBrassica napus pollen with particular reference to microbodies

Summary The ultrastructure of the vegetative cell ofBrassica napus tricellular pollen grains, just before anthesis with standard chemical fixation, is reported. The vegetative cell may be regarded as a highly differentiated and metabolically active fat-storage cell. It contains many mitochondria with a well developed internal membrane system, starchless plastids, microbodies, lipid bodies, dictyosomes and numerous vesicles thought to originate from the dictysomes. Rough endoplasmic reticulum organized in stacks of cisternae is also spatially associated with certain organelles, mainly lipid bodies, microbodies and plastids. There are also randomly distributed polyribosome areas. The microbodies are mainly polymorphic in shape and are often observed in contact with lipid bodies. The above spatial relationship implies that the microbodies may have a glyoxysomal function. In the late period of vegetative cell maturation, the microbodies are probably involved in the process of glyconeogenesis in which the conversion of lipid reserves to sugar takes place.Abbreviations VC vegetative cell - VN vegetative nucleus - SC sperm cell - M mitochondria - MB microbodies - L lipid body - P plastid - D dictyosomes     

Structural changes in the innercortex cells of soybean root nodules are induced by short-term exposure to high salt or oxygen concentrations

After a 2 h exposure of intact soybean nodules to high concentrations of NaCl (100mol m_?3) or oxygen (8OkPa O₂), morphometric computations carried out using an image analysis technique on semi-thin sections showed that both treatments induced a decrease in the area of the inner-cortex cells, which were then characterized by a tangential elongation. In contrast, no significant change in area occurred in the middle-cortex cells although their elongation decreased. Electron microscopic observations showed that in the inner-cortex cells changes included the presence of wall infoldings, an enlarged periplasmic space and a lobate nucleus whose chromatin distribution differed from that of the control. Structural changes also occurred in the endoplasmic reticulum, microbodies, mitochondria and plastids. From several of these changes, which are similar to those noted in osmocontractil cells in response to external stimuli, it can be hypothesized that the inner cortex may provide a potential mechanism for the control of oxygen diffusion through the nodules.     

Enzymes of ureide synthesis in pea and soybean

Soybean (Glycine max) and pea (Pisum sativum) differ in the transport of fixed nitrogen from nodules to shoots. The dominant nitrogen transport compounds for soybean are ureides, while amides dominate in pea. A possible enzymic basis for this difference was examined.

The level of enzymes involved in the formation of the ureides allantoin and allantoic acid from inosine 5′-monophosphate (IMP) was compared in different tissues of pea and soybean. Two enzymes, 5′-nucleotidase and uricase, from soybean nodules were found to be 50- and 25-fold higher, respectively, than the level found in pea nodules. Other purine catabolizing enzymes (purine nucleosidase, xanthine dehydrogenase, and allantoinase) were found to be at the same level in the two species. From comparison of enzyme activities in nodules with those from roots, stems, and leaves, two enzymes were found to be nodule specific, namely uricase and xanthine dehydrogenase. The level of enzymes found in the bacteroids indicated no significant contribution of Rhizobium japonicum purine catabolism in the overall formation of ureides in the soybean nodule. The presence in the nodules of purine nucleosidase and ribokinase activities makes a recirculation of the ribose moiety possible. In concert with phosphoribosylpyrophosphate synthetase, ribose becomes available for a new round of purine de novo synthesis, and thereby ureide formation.