Hormonal Regulation of the Lectin Biosynthesis in Callus Culture of the Phaseolus vulgaris Plant

Callus cultures established from Phaseolus vulgaris seedlings were used to investigate hormonal influence on lectin biosynthesis. The plant tissue cultures were initiated using defined levels of both a cytokinin (kinetin) and an auxin (2,4-dichlorophenoxyacetic acid) and were then transferred to media containing different amounts of these hormones. The lectin content of each callus culture was determined using an enzyme immunoassay specific for the seed lectin of the P. vulgaris plant. The lectin biosynthesis was directly affected by the levels of auxin and cytokinin in the culture media and no lectin was detected in hormone-free medium. This enabled us to compose culture media yielding a maximal or minimal lectin content of the callus cultures, illustrating the ability to induce an enhancement or suppression of the in vitro lectin biosynthesis. The lectin level of callus tissue during the growth cycle of a culture was, furthermore, related to the cellular growth rate which might indicate an involvement of the lectin in cellular events during rapid cell division.     

The production of callus capable of plant regeneration from immature embryos of numerous Zea mays genotypes

In the summer of 1983, immature embryos from 101 selfed inbred lines and germplasm stocks of Zea mays L. were examined for their ability to produce callus cultures capable of plant regeneration (regenerable cultures) using a medium with which some limited success had previously been obtained. Forty-nine of the genotypes (49%) produced callus which visually appeared similar to callus previously cultured and shown to be capable of plant regeneration. After five months, 38 of these genotypes were alive in culture and plants were subsequently regenerated from 35 (92%) of them. No correlation was observed between plant regeneration and callus growth rate, the vivipary mutation (genes vp1, 2, 5, 7, 8 and 9), or published vigor ratings based on K⁺ uptake by roots. When F₁ hybrid embryos were cultured, 97% of the hybrids having at least one regenerable parent also produced callus capable of plant regeneration. No regenerable cultures were obtained from any hybrid lacking a parent capable of producing a regenerable callus culture.In the summer of 1984, immature embryos from 218 additional inbred lines and germplasm stocks were plated and examined for their ability to produce regenerable callus cultures on media containing altered micronutrient concentrations, 3,6-dichloro-o-anisic acid (dicamba), glucose, and elevated levels of vitamin-free casamino acids and thiamine. Of these genotypes 199 (91%) produced callus that was regenerable in appearance. In the 1984 study, plant regeneration was noted in many commercially important inbreds, including B73, Mo17, B84, A632, A634, Ms71, W117, H99³H95 and Cm105. Thus tissue-culture techniques are now available to obtain callus cultures capable of plant regeneration from immature embryos of most maize genotypes.Abbreviations trade names 2,4-D 2,4-dichlorophenoxyacetic acid - dicamba 3,6-dichloro-o-anisic acid     

Biochemistry and physiology of nitrogen fixation with particular emphasis on nitrogen-fixing phototrophs

Summary This paper presents an overview of aspects of N₂-fixation in phototrophic N₂-fixers. Nitrogenase is little different in phototrophs from other organisms. Evidence suggests that fixed carbon dissimilation rather than direct photoreduction from oxidised inorganic compounds or exogenous photosynthetic electron donors is the major route of reductant supply to nitrogenase in phototrophs; inRhodospirillum rubrum pyruvate is a possible electron donor to nitrogenase; in cyanobacteria the oxidative pentose phosphate pathway is important, although some recent evidence implicates glycolysis and the tricarboxylic acid cycle in reductant supply in heterocystous cyanobacteria. In photosynthetic organisms light modulation of various enzymes occurs-some Calvin cycle enzymes are light activated, some oxidative pentose phosphate pathway and glycolytic enzymes are deactivated and some tricarboxylic acid cycle enzymes are activated. Reduced levels of thioredoxin in heterocysts may contribute to the sustained functioning of the oxidative pentose phosphate pathway in heterocysts in the light and dark. In photosynthetic bacteria such asRhodospirillum rubrum an activating enzyme which removes a modifying group from inactive Fe protein can activate nitrogenase. O₂ and NH ₄ ⁺ both inhibit N₂-fixation and there is some evidence in cyanobacteria that O₂ stability of whole cell nitrogenase can be achieved by prolonged incubation of cultures at high O₂.     

Peroxidase activity in calluses and cell suspension cultures of radishRaphanus sativus var. Cherry Bell

Calluses ofRaphanus sativus var. Cherry Bell were induced in a medium containing 2,4-dichlorophenoxyacetic acid and benzyladenine. The biomass and peroxidase activities were determined, both in agar cultures and cell suspension cultures. Different growth-regulator concentrations induced different responses measured as peroxidase activity in callus. The suspended-cell cultures showed the importance of selecting the cell line, in order to obtain an optimal response in extracellular peroxidase activity. The commercial production of this enzyme by utilizing plant cell tissue cultures is discussed.     

Methyl jasmonate differentially affects tocopherol content and tyrosine amino transferase activity in cultured cells of Amaranthus caudatus and Chenopodium quinoa

Tocopherols are lipid-soluble compounds synthesised exclusively by photosynthetic organisms. In this study, in vitro callus cultures were established from two plants that are naturally rich in tocopherols, Amaranthus caudatus and Chenopodium quinoa, in order to examine whether callus cultures were able to produce these compounds at levels comparable to those observed in planta . In both species, cotyledon explants produced the best callus induction and, once established, callus cultures were grown under two different hormonal treatments to check for effects of growth and to induce chloroplast differentiation in the cells. A rapid differentiation of chloroplasts occurred only in C. quinoa cell aggregates grown in the presence of benzyladenine, leading to the production of a homogeneous green callus. In both species, only α-tocopherol was produced by callus cultures, although levels were much lower than in planta, and the production was not influenced by the hormonal conditions. Interestingly, cell cultures of the two species responded in different ways to methyl jasmonate (MJ). In A. caudatus cultures, treatment with 100 μ m MJ increased the production of α-tocopherol up to fivefold, and the inductive effect was influenced by the hormonal composition of the medium. This increase in α-tocopherol was associated with a proportional increase in tyrosine aminotransferase (TAT) activity, one of the key enzymes involved in tocopherol biosynthesis. By contrast, in C. quinoa cultures, elicitation with MJ did not have any effect, neither on tocopherol production, nor on TAT activity. These results are discussed in relation to chloroplast differentiation and the interplay between jasmonates and phytohormones.     

Biochemical features of maize tissues with different capacities to regenerate plants

Metabolic profiling using GC–MS and LC–MS analyses of soluble metabolites and cell wall bound phenolic compounds from maize calluses of different morphogenic competence revealed a number of biochemical characteristics that distinguish tissues with high plant regeneration ability from tissues that cannot efficiently regenerate plants in vitro. Maize cultures of different ages from H99 (compact type I callus) and HiII (friable type II callus) were divided into two different samples: regenerable (R) and non-regenerable (NR) based on known morphologies. Tissues from both genotypes with high morphogenic potential had higher asparagine and aspartate and indole-3-butenol concentrations, decreased sugar and DIMBOA (2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one) concentrations, low levels of 4-aminobutyric acid (GABA) and chlorogenic acid and lower levels of feruloyl- and sinapoyl glucosides compared to NR tissues. The ether bound cell wall phenolics of tissues with high regeneration potential had higher levels of the predominant G (guaiacyl) units and lower levels of H (p-hydroxyphenyl) and S (syringyl) units and higher ferulic acid/coumaric acid and ferulic acid/diferulic acid ratios. The same trends were found with the ester-bound phenolics of HiII, however, there were only small differences between the H99 R and NR tissues. Concentrations of the major sugars, organic acids, amino acids and soluble aromatic compounds tended to increase as the time after culture initiation increased. The results show that there are differences in general metabolism, phenolic secondary compounds and cell wall composition between R and NR cell types.     

Artificial associations between Daucus and nitrogen-fixing Azotobacter cells in vitro

Symbiotic associations were established between nitrogen-fixing Azotobacter zettuovii (CRS-H6) cells and carrot ( Daucus carota L. cv. 'Rother' Half Long) tissues based on the induced carbon and energy dependency of diazotrophs on plant metabolic activity. Symbiotic associations were grown on nitrogen-free media for four years. Plant regeneration was achieved from callus-bacterium associations on nitrogen-containing media. Light and electron micrographs are used to show the localization of bacteria in intercellular spaces of callus and regenerated plant tissues. The nitrogen-fixing ability of the partnership was proved on nitrogen-free media.     

Modifiers of heterocyst repression and spacing and formation of heterocysts without nitrogenase in the cyanobacterium Anabaena variabilis.

Twelve amino acid analogs and related compounds were screened for their ability to induce heterocysts in ammonia-repressed, undifferential filaments of Anabaena variabilis. As has been previously described, 1-methionine-dl-sulfoximine induces both heterocysts and nitrogenase. In contrast, dl-7-azatryptophan and beta-2-thienyl-dl-alanine were found to induce heterocysts but not nitrogenase activity (measured as acetylene reduction) even under microaerobic conditions. When the initial ammonium concentration was reduced, dl-7-azatryptophan-treated cultures sequentially produced heterocysts and then nitrogenase activity, but nitrogenase was detected only when a parallel culture without analog also became capable of acetylene reduction. Neither of the two latter analogs affected gamma-glutamyl transferase activity in crude extracts. All three analogs significantly reduced the mean interheterocyst distance in nitrogen-fixing cultures.     

The interaction of Yersinia, Listeria and Salmonella with plant cells

The results of the interaction of bacteria of the genera Yersinia, Listeria and Salmonella, pathogenic for humans and animals, with callus cultures of different plant species are presented. As revealed in this study, complicated interactions developed between bacteria and plant cells. Plant cells were shown to be highly sensitive to the action of bacteria. Yersinia, Listeria and Salmonella were found to be capable of callus damage. The influence of plant cells on bacteria was more complicated: both the stimulation of bacterial growth and its inhibition were noted, depending on the time of cultivation.     

Selection and characterization of ethionine-resistant alfalfa (Medicago sativa L.) cell lines

Summary Diploid alfalfa (HG2), capable of plant regeneration from tissue culture, was used to select variant cell lines resistant to growth inhibition due to ethionine (an analog of methionine). Approximately 10⁷ suspension-cultured cells were mutagenized with methane sulfonic acid ethylester and then plated in solid media containing ethionine. Callus colonies formed on media with 0.02 mM ethionine. Of the 124 cell lines recovered, 91 regenerated plants. After six months growth on media without ethionine, 15 of 110 cell lines of callus grew significantly better than HG2 on 1 mM ethionine. Several ethionine-resistant callus cultures were also resistant to growth inhibition due to the addition of lysine + threonine to the media. High concentrations, relative to unselected HG2 callus, of methionine, cysteine, cystathionine, and glutathione were found in some, but not all, ethionine-resistant callus cultures. Cell line R32, which had a ca. tenfold increase in soluble methionine, had a 43% increase in total free amino acids and a 40% increase in amino acids in protein as compared to unselected HG2 callus. Relative amounts of each amino acid in protein were the same in both.Abbreviation LT lysine + threonine in equimolar concentration     

Metabolic flux analysis of Cyanothece sp. ATCC 51142 under mixotrophic conditions

Cyanobacteria are a group of photosynthetic prokaryotes capable of utilizing solar energy to fix atmospheric carbon dioxide to biomass. Despite several “proof of principle” studies, low product yield is an impediment in commercialization of cyanobacteria-derived biofuels. Estimation of intracellular reaction rates by ¹³C metabolic flux analysis (¹³C-MFA) would be a step toward enhancing biofuel yield via metabolic engineering. We report ¹³C-MFA for Cyanothece sp. ATCC 51142, a unicellular nitrogen-fixing cyanobacterium, known for enhanced hydrogen yield under mixotrophic conditions. Rates of reactions in the central carbon metabolism under nitrogen-fixing and -non-fixing conditions were estimated by monitoring the competitive incorporation of ¹²C and ¹³C from unlabeled CO₂ and uniformly labeled glycerol, respectively, into terminal metabolites such as amino acids. The observed labeling patterns suggest mixotrophic growth under both the conditions, with a larger fraction of unlabeled carbon in nitrate-sufficient cultures asserting a greater contribution of carbon fixation by photosynthesis and an anaplerotic pathway. Indeed, flux analysis complements the higher growth observed under nitrate-sufficient conditions. On the other hand, the flux through the oxidative pentose phosphate pathway and tricarboxylic acid cycle was greater in nitrate-deficient conditions, possibly to supply the precursors and reducing equivalents needed for nitrogen fixation. In addition, an enhanced flux through fructose-6-phosphate phosphoketolase possibly suggests the organism’s preferred mode under nitrogen-fixing conditions. The ¹³C-MFA results complement the reported predictions by flux balance analysis and provide quantitative insight into the organism’s distinct metabolic features under nitrogen-fixing and -non-fixing conditions.     

The impact of zearalenone and thidiazuron on indirect plant regeneration of oilseed rape and wheat

The aim of the study was to test the synergistic activity of zearalenone and thidiazuron with commonly used regulators (6-benzylaminopurine, 2,4-dichlorophenoxyacetic acid) in callus tissue growth and the regeneration processes of winter oilseed rape and winter wheat. Oilseed rape callus was obtained from the upper fragments of seedling hypocotyls. Wheat callus tissue was obtained from immature embryos. Zearalenone, in combination with 6-benzylaminopurine, stimulated the regeneration of oilseed rape and, in combination with 2,4-dichlorophenoxyacetic acid, the regeneration of wheat. An additional application of thidiazuron to these media increased the percentage of shoot regeneration from callus in both species tested. Zearalenone is proposed as a new regulator in in vitro plant cultures for use in protocols of plant regeneration.     

Biosynthesis of levorin and activity of several enzyme systems of Streptomyces levoris depending on culture conditions

The regularities of changes in the main oxidation-reduction enzymes of the tricarboxylic acid cycle (TAC) and the pentose cycle were studied under different cultivation conditions: with the use of the control soybean-corn-hydrol medium and the medium with addition of a biostimulant produced by C. tropicalis. It was shown that the activity levels of the dehydrogenase systems of the TAC and the pentose cycle of S. levoris grown in the presence of the biostimulant were higher. The increase in the production levels of levorin due to addition of the biostimulant was connected with the activity of the systems responsible for regeneration of NADP.H2.     

GROWTH OF EDIBLE CHLOROPHYLLOUS PLANT TISSUES IN VITRO

Hildebrandt, A. C, J. C. Wilmar, H. Johns, and A. J. Riker. (U. Wisconsin, Madison.) Growth of edible chlorophyllous plant tissues in vitro, Amer. Jour. Bot. 50(3): 248–254. Illus. 1963.—Plant callus cultures were attempted from roots, stems, leaves or excised embryos of 32 species of plants on a basal mineral salts–sucrose agar medium (T-medium), on T-medium + coconut milk + α-naphthaleneacetic acid + calcium pantothenate (C-medium) and on C-medium + 2,4-dichlorophenoxyacetic acid (D-medium). Embryos on T- or C-medium generally produced normal plants, while on D-medium, they often produced callus only. Fresh isolates of carrot, endive, lettuce, parsley, red kidney bean, and navy bean gave moderate to excellent callus on C-medium. Parsley and navy bean also produced excellent callus on D-medium. Strains of callus from potato, tomato, grape and rose also grew well on C- or D-medium. In the light, red pigmentation developed on rose, parsley, and grape callus. Chlorophyll formation was inhibited on D-medium, but on C-medium more or less chlorophyll was initiated in callus from carrot, endive, lettuce, pea, potato and certain rose varieties. Chlorophyll formation was also strong in endive callus on T-medium supplemented with casein hydrolysate, i-inositol and NAA. The amount and type of sugar used in C-medium influenced the amount of growth and were critical in relation to chlorophyll formation. Carrot tissues in constant light produced abundant chlorophyll and were still growing on media without added sugar after 6 weeks.     

Physiology and metabolism of pathogenic neisseria: tricarboxylic acid cycle activity in Neisseria gonorrhoeae.

Tricarboyxlic acid cycle activity was examined in Neisseria gonorrhoeae CS-7. The catabolism of glucose in N. gonorrheae by a combination of the Entner-Doudoroff and pentose phosphate pathways resulted in the accumulation of acetate, which was not further catabolized until the glucose was depleted or growth became limiting. Radiorespirometric studies revealed that the label in the 1 position of acetate was converted to CO2 at twice the rate of the label in the 2 position, indicating the presence of a tricarboxylic acid cycle. Growth on glucose markedly reduced the levels of all tricarboxylic acid cycle enzymes except citrate synthase (EC 4.1.3.7). Extracts of glucose-grown cells contained detectable levels of all tricarboxylic acid cycle enzymes except aconitase (EC 4.2.1.3), isocitrate dehydrogenase (EC 1.1.1.42), and a pyridine nucleotide-dependent malate dehydrogenase (EC 1.1.1.37). Extracts of cells capable of oxidizing acetate lacked only the pyridine nucleotide-dependent malate dehydrogenase. In lieu of this enzyem, a particulate pyridine nucleotide-independent malate oxidase (EC 1.1.3.3) was present. This enzyme required flavin adenine dinucleotide for activity and appeared to be associated with the electron transport chain. Radiorespirometric studies utilizing labeled glutamate demonstrated that a portion of the tricarboxylic acid cycle functioned during glucose catabolism. In spite of the presence of all tricarboxylic acid cycle enzymes, N. gonorrhoeae CS-7 was unable to grow in medium supplemented with cycle intermediates.     

Antioxidants enhance in vitro plant regeneration by inhibiting the accumulation of peroxidase in Virginia pine (<Emphasis Type="Italic">Pinus virginiana</Emphasis> Mill.)

Plant tissue necrosis and subsequent cell death are usually observed during in vitro regeneration in conifers, especially in plant regeneration via somatic organogenesis in pine species. Cell death is correlated with the elevated levels of peroxides. In this investigation, the effects of antioxidants on in vitro regeneration of Virginia pine (Pinus virginiana Mill.) were evaluated. Antioxidants, polyvinylpolypyrrolidone (PVPP) and 1,4-dithio-dl-threitol (DTT), were found to improve callus formation, shoot differentiation and growth, and shoot rooting by inhibiting tissue necrosis during the initiation of cultures and subculture of shoots. These treatments enabled the recovery and regeneration plants at high frequency through somatic organogenesis. Compared to the control, the frequencies of callus formation, shoot growth, and shoot rooting increased 15, 26, and 19%, respectively, by addition of 5 g/l PVPP and 2 g/l DTT. Higher peroxidase activity of tissue cultures during subculture from callus proliferation medium to shoot differentiation medium and to rooting medium was observed. The addition of antioxidants reduces and inhibits browning by reducing the accumulation of peroxidase.Abbreviations BA 6-Benzylaminopurine - 2,4-D 2,4-Dichlorophenoxyacetic acid - DTT 1,4-Dithio-dl-threitol - IBA Indole butyric acid - NAA -Naphthaleneacetic acid - PVPP Polyvinylpolypyrrolidone     

Metabolism in plant storage tissue slices

The tissue of resting plant storage organs such as carrots, red beets, sugar beets or potato tubers can be activated by slicing into thin disks and incubation of these fragments in a moist atmosphere for different periods of time (“aging”). Activation comprises the turning-on of various genes with subsequent synthesis of transfer-, ribosomal and messenger RNAs and their transport into the cytoplasm. The immediate consequence of all these primary reactions is a vigorous synthesis of various enzymes and structural proteins which enable the cell to greatly enhanced metabolic activities. Thus, degradation of storage polymers and the procession of the resulting products through glycolysis, the pentose phosphate shunt and the shikimateprephenate-pathway and cellulose biosynthesis occur. Deinhibition of the tricarboxylic acid cycle opens the flow of metabolites into fatty acid, phospholipid and steroid biosynthesis, simultaneously providing the respiratory chain with electrons. In spite of functional modifications within the electron transport chain, the enhanced respiration of tissue slices serves as an energy source for the various energy-dependent reactions of the cell such as syntheses and the uptake of solutes. All of these activities accompany a concomitant dedifferentiation process and ultimately lead to renewed redifferentiation of the tissue slice cell.     

Acetate assimilation by Nitrobacter agilis in relation to its "obligate autotrophy"

Acetate (1 to 10 mm) had no effect on the rate of nitrite oxidation or exponential growth by Nitrobacter agilis. However, acetate-1-(14)C and -2-(14)C were both assimilated by growing cultures, and acetate carbon contributed 33 to 39% of newly synthesized cell carbon. Carbon from acetate was incorporated into all of the major cell constituents, including most of the amino acids of cell protein and poly-beta-hydroxybutyrate (PHB). Cultures grown in the presence of acetate showed a significant increase in turbidity, attributable in part to protein synthesis and the accumulation of PHB in the "post-exponential phase," when the supply of nitrite was completely exhausted. Cell suspensons of N. agilis assimilated acetate in the absence of bicarbonate and even in the absence of nitrite. However, the addition of nitrite increased the rate of acetate assimilation by cell suspensions. The distribution of (14)C-acetate incorporated by cell suspensions was qualitatively similar to that found with growing cultures. Cell suspensions of N. agilis slowly oxidized acetate to CO(2). Addition of nitrite suppressed CO(2) production from acetate but increased the assimilation of acetate carbon into cell material. N. agilis contained all the enzymes of the tricarboxylic acid cycle. Growth of N. agilis in the presence of acetate did not significantly affect the levels of the enzymes of the tricarboxylic acid cycle, but did result in a 100-fold increase in the specific activity of isocitratase. In contrast, carboxydismutase was partially repressed. N. agilis was grown heterotrophically through seven transfers on a medium containing acetate and casein hydrolysate. The addition of nitrite increased the rate of heterotrophic growth. Heterotrophically grown organisms still retained their ability to grow autotrophically with nitrite. However, these organisms oxidized nitrite at a slower rate. Organisms from autotrophic and heterotrophic cultures were analyzed to determine the mean guanine plus cytosine content of their deoxyribonucleic acid; in both cases this mean was 61.2 +/- 1%. We concluded that N. agilis is not an obligate autotroph; it appears to be a facultative autotroph which resembles the novel facultative autotroph, Thiobacillus intermedius, very closely.     

Acid and alkaline invertases in suspension cultures of sugar beet cells

Alkaline invertase was induced during the initiation of suspension cultures of single cells from leaf explants of sugar beets in Murashige-Skoog liquid medium which contained benzyladenine. This activity was barely detectable in the leaves themselves. In suspension cultures, the presence of both acid and alkaline invertases was detected; alkaline invertase was only present in the cytoplasm of the cultured cells, whereas acid invertase was present in the cytoplasm and cell walls, and was also detected in the culture medium. The cell wall contained at least three types of acid invertase; two of these activities were solubilized by saline (saline-released) and EDTA (EDTA-released), respectively, and the third remained tightly associated with the cell wall. Saline-released and EDTA-released invertases from the cell wall showed the significant differences in their properties: the saline-released enzyme had the highest affinity for sucrose among the invertases tested, and was easily bound to cell walls, to DNA, and to a cation exchanger, unlike the EDTA-released enzyme. Sucrose is the source of carbon for plant cells in suspension culture and is probably degraded in the cell wall by the saline-released invertase, which had the highest activity and the highest affinity for sucrose. Hexose products of this degradation would be transported to cytoplasm. Soluble invertase, EDTA-released invertase from the cell wall, and one of two extracellular invertases behaved similarly upon chromatography on DEAE-cellulose. They had similar activity profiles with changing pH, and similar K_m values for sucrose. Thus it appears that they are identical. Two extracellular invertases found in the growth medium of the suspension cultures were probably identical with those in the soluble fraction of callus and seedlings of sugar beets, because they showed similar behaviors during chromatography on DEAE-cellulose, and had similar activity profiles with changing pH and K_m values for sucrose.     

DNA methylation as a key process in regulation of organogenic totipotency and plant neoplastic progression?

Summary Progressive loss of organogenic totipotency appears to be a common event in long-term plant tissue culture. This loss of totipotency, which has been proposed to be a typical trait of plant neoplastic progression, is compared to some mechanisms that occur during the establishment of animal differentiation-resistant cancer lines in vitro. Evidence is presented that alteration in DNA methylation patterns and expression of genes occur during long-term callus culture. An effect of the auxin, 2,4-dichlorophenoxyacetic acid, in the progressive methylation, is moreover suggested. Methylation of genes relevant to cell differentiation and progressive elimination of cells capable of differentiation is proposed as being responsible for this progressive loss of organogenic potential. Finally, the epigenetic alteration (DNA methylation) that occurs during prolonged periods of culture may induce other irreversible genetic alterations that ultimately make the loss of totipotency irreversible.