Polyphosphoinositides are present in plasma membranes isolated from fusogenic carrot cells

Fusogenic carrot cells grown in suspension culture were labeled 12 hours with myo-[2-³H]inositol. Plasma membranes were isolated from the prelabeled fusogenic carrot cells by both aqueous polymer two-phase partitioning and Renografin density gradients. With both methods, the plasma membrane-enriched fractions, as identified by marker enzymes, were enriched in [³H]inositol-labeled phosphatidylinositol monophosphate (PIP) and phosphatidylinositol bisphosphate (PIP₂). An additional [³H]inositol-labeled lipid, lysophosphatidylinositol monophosphate, which migrated between PIP and PIP₂ on thin layer plates, was found primarily in the plasma membrane-rich fraction of the fusogenic cells. This was in contrast to lysophosphatidylinositol which is found primarily in the lower phase, microsomal/mitochrondrial-rich fraction.     

Epigenetics in plant tissue culture

Plants produced vegetatively in tissue culture may differ from the plants from which they have been derived. Two major classes of off-types occur: genetic ones and epigenetic ones. This review is about epigenetic aberrations. We discuss recent studies that have uncovered epigenetic modifications at the molecular level, viz., changes in DNA methylation and alterations of histone methylation or acetylation. Various studies have been carried out with animals, and with plant cells or tissues that have grown in tissue culture but only little work has been done with shoots generated by axillary branching. We present various molecular methods that are being used to measure epigenetic variation. In micropropagated plants mostly differences in DNA methylation have been examined. Epigenetic changes are thought to underlie various well-known tissue-culture phenomena including rejuvenation, habituation, and morphological changes such as flower abnormalities, bushiness, and tumorous outgrowths in, among others, oil palm, gerbera, Zantedeschia and rhododendron.     

Phloroglucinol in plant tissue culture

In plant tissue culture research, there is a constant need to search for novel substances that could result in better or more efficient growth in vitro. A relatively unknown compound, phloroglucinol (1,3,5-trihydroxybenzene), which is a degradation product of phloridzin, has growth-promoting properties. Phloroglucinol increases shoot formation and somatic embryogenesis in several horticultural and grain crops. When added to rooting media together with auxin, phloroglucinol further stimulates rooting, most likely because phloroglucinol and its homologues act as auxin synergists or auxin protectors. Of particular interest is the ability of phloroglucinol—a precursor in the lignin biosynthesis pathway—to effectively control hyperhydricity through the process of lignification, thus maximizing the multiplication rate of woody species and other species that are difficult to propagate. Phloroglucinol has also been used to improve the recovery of cryopreserved Dendrobium protocorms, increasing the potential of cryopreservation for application in ornamental biotechnology. Phloroglucinol demonstrates both cytokinin-like and auxin-like activity, much like thidiazuron, and thus has considerable potential for application in a wide range of plant tissue culture studies.     

History of plant tissue culture

Plant tissue culture, or the aseptic culture of cells, tissues, organs, and their components under defined physical and chemical conditions in vitro, is an important tool in both basic and applied studies as well as in commercial application. It owes its origin to the ideas of the German scientist, Haberlandt, at the begining of the 20th century. The early studies led to root cultures, embryo cultures, and the first true callus/tissue cultures. The period between the 1940s and the 1960s was marked by the development of new techniques and the improvement of those that were already in use. It was the availability of these techniques that led to the application of tissue culture to five broad areas, namely, cell behavior (including cytology, nutrition, metabolism, morphogenesis, embryogenesis, and pathology), plant modification and improvement, pathogen-free plants and germplasm storage, clonal propagation, and product (mainly secondary metabolite) formation, starting in the mid-1960s. The 1990s saw continued expansion in the application of the in vitro technologies to an increasing number of plant species. Cell cultures have remained an important tool in the study of basic areas of plant biology and biochemistry and have assumed major significance in studies in molecular biology and agricultural biotechnology. The historical development of these in vitro technologies and their applications are the focus of this chapter.     

Heat-shock proteins are associated with hnRNA in Drosophila melanogaster tissue culture cells

Ribonucleoprotein complexes of Drosophila melanogaster Kc tissue culture cells grown at 24°C or heat-shocked at 37°C were cross-linked in vivo by u.v. irradiation. Cross-linked heterogeneous nuclear ribonucleoprotein (hnRNP) complexes were fractionated by oligo(dT)-cellulose chromatography and CsCI density centrifugation. The hnRNP complexes of both 24°C and 37°C culture cells possess buoyant densities in CsCI between = 1.38 g/cm^-3 and 1.43 g/cm^-3. The ³⁵S-labelled proteins bound to the hnRNA of 37°C culture cells correspond in mol. wt. to the so-called heat-shock proteins of 70 K, 68 K, 27 K, 26 K, 23 K and 22 K. The 70 K and 68 K proteins are also present in hnRNP complexes of 24°C culture cells. In addition, several other Drosophila hnRNPs of 140 K, 56 K, 45 K, 43 K, 38 K, 37 K and 34 K, whose synthesis is strongly repressed under heat-shock conditions, could be identified. The results demonstrate that the so-called heat-shock proteins possess a function as RNPs.     

Commercialization of plant tissue culture in India

Commercial application of plant tissue culture started in USA with micropropagation of orchids in 1970s. It has seen tremendous expansion globally from 1985 to 1990 in the number of production units as well as the number of plants produced. With an estimated global market of 15 billion US dollars per annum for tissue cultured products, even with exponential expansion in the industry, the demand far exceeds production, leaving enough scope for expansion. This industry appears to be undergoing a pause in growth presently in developed countries as it is finding difficult to remain cost–effective. In US, only half the production capacity is being utilized currently due to high labour costs. In developing countries, with lower wage scales, plants are being produced at much cheaper rates. Indian micropropagation industry, though a late starter by almost a decade, compared to its western counterparts, has expanded exponentially from 5 million annual capacity in 1988 to 190 million in 1996. The facilities now created are at par with the best in leading countries like the Netherlands and USA. To remain in profitable business and to earn the much needed foreign exchange, Indian units need to judiciously mix steady revenue generating items with unique speciality items based on demand in domestic and international markets. This revised version was published online in June 2006 with corrections to the Cover Date.     

Bacterial growth in plant tissue culture media

C. LEIFERT AND W.M. WAITES. 1992. When Murashige and Skoog's liquid plant medium was inoculated with 10 different bacterial species in the absence of plants only Bacillus subtilis showed significant growth. The numbers of Lactobacillus plantarum, Pseudomonas maltophilia, Erwinia carotovora and Staphylococcus saprophyticus decreased rapidly and were not detected at 28 d.
Bacillus subtilis, Lact. plantarum, Ps. maltophilia, Erw. carotovora and Staph. saprophyticus grew and persisted in the same medium in the presence of Delphinium plants, while only Lact. plantarum and Erw. carotovora grew and persisted in the presence of Hemerocallis plants.
Hemerocallis plants lowered the pH of media from 5.6 to about 3.9 while Delphinium plants increased it to about 5.9 within 7 d after subculturing on fresh media. The pH drop in Hemerocallis media is thought to prevent the growth and persistence of bacteria such as B. subtilis, Staph. saprophyticus and Ps. maltophilia , which were found to be more sensitive to low pH than Lact. plantarum and Erw. carotovora. Bacterial growth in the medium altered the pH, reduced the plant growth and/or resulted in plant death.     

Use of fungicides in plant tissue culture

We have examined a number of antifungal agents which might prove useful in plant tissue culture. We find that carbendazim, fenbendazole and imazalil can be used relatively safely and also have a broad spectrum of antifungal activity. Fungicides in clinical use do not prove to be as effective.Abbreviations YEPD yeast potato dextrose, MS medium is Murashige and Skoog medium purchased from Flow Laboratories - 2,4 D 2,4 dichlorophenoxyacetic acid - BAP 6-Benzylamino purine. Benomyl is methyl-(butylcarbamoyl)-2-benzimidazole carbamate - MBC is Carbendazim (methyl benzimidazole -2-yl-carbamate) - TBZ is Thiabendazole; 2-(Thiazol-4-y-l) benzimidazole - FBZ is Fenbendazole [5-(Phenylthio)-1 H-benzimidazole-2-yl] carbamic acid methyl ester     

Bacteria in the plant tissue culture environment

Bacteria and plants are joined in various symbiotic relationships that have developed over millennia and have influenced the evolution of both groups. Bacteria inhabit the surfaces of most plants and are also present inside many plant organs. These bacteria may have positive, neutral or negative impacts on their plant hosts. Probiotic effects may improve plant nutrition or increase resistance to biotic and abiotic stresses. Conversely pathogenic bacteria may kill or reduce the vigor of plant hosts. In addition some bacteria inhabit plants and profit from excess metabolites or shelter while not injuring the plant. Micropropagation of plants is based on the stimulation of organogenesis or embryogenesis from explants that are superficially decontaminated and placed into a sterile environment. If successful, this process removes bacteria from surfaces, but those inhabiting inner tissues and organs are usually not affected by these steriliants. In vitro conditions are designed for optimal plant growth and development, however these conditions are also often ideal for bacterial multiplication. The presence of bacteria in the in vitro environment was almost universally considered negative for plant culture, but more recently this view has been questioned. Certain bacteria appear to have a beneficial effect on the explants in culture; increasing multiplication and rooting, increasing explant quality, and organo- and embryogenesis of recalcitrant genotypes. The most important role of beneficial bacteria for micropropagated plants is likely to be during acclimatization, when growth is resumed under natural conditions. This review includes the role of bacterial interactions in plants, especially those grown in vitro.     

Epithelial cells in tissue culture

In this review the characteristics of established renal and intestinal epithelial cell lines are described by summarizing the accumulated literature about specific properties retained by the cells in tissue culture. Furthermore, brief examples are given for the use of cultured epithelia as model systems to study epithelial transport and metabolic functions, epithelial cell polarity, and aspects of the differentiation and maturation of epithelia by physiological, biochemical and genetic, or cell and molecular biological approaches.     

Plant hormones and plant growth regulators in plant tissue culture

Summary This is a short review of the classical and new, natural and synthetic plant hormones and growth regulators (phytohormones) and highlights some of their uses in plant tissue culture. Plant hormones rarely act alone, and for most processes— at least those that are observed at the organ level—many of these regulators have interacted in order to produce the final effect. The following substances are discussed: (a) Classical plant hormones (auxins, cytokinins, gibberellins, abscisic acid, ethylene and growth regulatory substances with similar biological effects. New, naturally occurring substances in these categories are still being discovered. At the same time, novel structurally related compounds are constantly being synthesized. There are also many new but chemically unrelated compounds with similar hormone-like activity being produced. A better knowledge of the uptake, transport, metabolism, and mode of action of phytohormones and the appearance of chemicals that inhibit synthesis, transport, and action of the native plant hormones has increased our knowledge of the role of these hormones in growth and development. (b) More recently discovered natural growth substances that have phytohormonal-like regulatory roles (polyamines, oligosaccharins, salicylates, jasmonates, sterols, brassinosteroids, dehydrodiconiferyl alcohol glucosides, turgorins, systemin, unrelated natural stimulators and inhibitors), as well as myoinositol. Many of these growth active substances have not yet been examined in relation to growth and organized developmentin vitro.     

Ependymal cells in tissue culture

Summary Ciliated ependymal cells from various locations of the ventricular system of mammals showed outgrowth either in the form of epithelial sheets or in the form of pools and elongated double rows, dependant on the site from which the ependyma was taken and on the original orientation of the cells in respect to the cover slip.The ependymal cilia in such cultures were shown to be moving at a rate of 51/2 to 6 times per second. The movement of the cilia of adjacent cells was apparently well coordinated causing the surrounding fluid to flow in a particular direction.The effect of physiological saline, morphine sulfate, ethyl and methyl alcohol on the ciliary motility has been studied in living cells with phase contrast cinematography.Grateful acknowledgement is made to Messers G. Lefeber, E. Pitsinger and J. Carnes for indispensible aid with photographic work. Mrs. J. Finerty and Mrs. W. Hild contributed generously in the management of the tissue cultures and in executing staining procedures.This investigation was supported by a research grant [PHS B-364 (C3)] from the National Institute of Neurological Diseases and Blindness, of the National Institutes of Health, Public Health Service, administered by C. M. Pomerat.     

Acetylcholine receptor channels are present in undifferentiated satellite cells but not in embryonic myoblasts in culture

The expression and the physiological properties of acetylcholine receptors (AChRs) of mononucleated myogenic cells, isolated from either embryonic or adult muscle of the mouse, have been investigated using the gigaohm seal patch-clamp technique in combination with immunocytochemistry (with an anti-myosin antibody) and alpha-bungarotoxin binding techniques. Undifferentiated (myosin-negative) embryonic myoblasts, grown either in mass culture or under clonal conditions, were found to be unresponsive to ACh and did not bind alpha-bungarotoxin. On the contrary, undifferentiated satellite cells (from adult muscle) exhibited channels activated by ACh and alpha-bungarotoxin binding sites similar to those observed in differentiated (myosin-positive) embryonic myoblasts and myotubes. Two classes of ACh-activated channels with different opening frequencies were identified. The major class of channels had a conductance of about 42 pS and mean open time of 3.1-8.2 msec. The minor class of channels had smaller conductance (about 17 pS) and similar open time. During differentiation, the conductance of the two channels did not change significantly, while channel lifetime became shorter in myotubes derived from satellite cells but not in myotubes derived from embryonic myoblasts. The relative proportion of small over large channels was significantly larger in embryonic than in adult myogenic cells.     

Polyphosphoinositides are derived from ether-linked inositol glycerophospholipids in rat brain

Membrane inositol glycerophospholipid (IGP) is metabolized to phosphatidylinositol-4-phosphate (PIP), phosphatidylinositol-4, 5-bisphosphate (PIP2), and inositol triphosphate (IP3) in signaling transduction. This study was carried out to determine the subclasses of IGP involved in signaling pathway. The acyl chain moieties of the phospholipids are easily modulated by dietary fatty acids. We analyzed acyl chain composition of IGP 3-subclasses, PIP and PIP2 from rat brain after feeding sunflower seed oil enriched with linoleic acid or fish oil high in eicosapentaenoic acid and docosahexaenoic acid. Long chain polyunsaturated fatty acids (LCPUFA) as eicosapentaenoic acid and docosahexaenoic acid were not incorporated into ether-linked IGP (alkenylacylglycerophosphoinositol and alkylacyl-glycerophosphoinositol), PIP and PIP2, while diacyl-glycerophosphoinositol (GPI) contained high LCPUFA. These results suggest that PIP might be phosphorylated from only the ether-linked IGP (alkenylacyl- and alkylacyl species) but not from diacyl subclass for signals to intracellular responses in the plasma membrane of rat brain.     

Analysing treatment means in plant tissue culture research

Many researchers set up an experiment, make measurements, do an analysis of variance, calculate the mean response for each treatment, and then try to decide if the treatment means are significantly different and why. Much too frequently, Duncan's multiple range test is used to test differences among means. It is only one of a number of techniques that can be used to examine treatment means. Some researchers are unaware of the different techniques and that the interpretation of the results of an experiment is strongly influenced by the technique used i.e. using two different techniques might produce two different interpretations of the results. Selection of the appropriate technique to use for a particular experiment depends upon the nature of the treatments and the objectives of the research. This paper discusses four techniques (ranking treatment means, multiple comparison procedures, fitting response models, and using contrasts to make planned comparisons) that can be used to examine treatment means and presents examples of the use of each one for plant tissue culture research.Abbreviations (IAA) indole-3-acetic acid - (IBA) indole-3-butyric acid - (NAA) naphthalene-acetic acid - (2,4-D) 2, 4-dichlorophenoxyacetic acid - (BA) benzyladenine - (PBA) tetrahydropyranylbenzyladenine - (2iP) 2 isopentenyl adenine - (2iPA) 2 isopentenyl adenosine Journal Paper J-12661 of the Iowa Agriculture and Home Economics Experiment Station, Ames. Project 2210.     

The influence of ethylene in plant tissue culture

Ethylene produced by plant tissues grown in vitro may accumulate in large quantities in the culture vessels, particularly from rapidly growing non-differentiated callus or suspension cultures, and hence is likely to influence growth and development in such systems. Research into this aspect of tissue culture has been sparse, although it has grown recently with the increasing importance of in vitro regeneration. This review deals with the measurement and relevance of the accumulated ethylene, and the influence of both exogenous and endogenous ethylene in the different types of tissue culture systems. The relationships between ethylene and other growth regulators in tissue culture growth and development are also discussed. Although in some cases its influence seems negligible, in many types of tissue culture ethylene may act either as a promoter or inhibitor depending on the species used. Thus ethylene has an important influence on many aspects of in vitro regeneration, but it is also clear that we cannot at present describe a specific role or roles for ethylene in tissue culture which can be applied at a general, species-wide level. If its effects are to be enhanced or diminished in order to improve the efficiency and range of plant tissue culture, then more research is needed to clarify what its fundamental role might be in in vitro growth and development.Abbreviations ABA abscisic acid - ACC 1-aminocyclopropane-1-carboxylic acid - AOA aminooxyacetic acid - ASA acetylsalicyclic acid - AVG aminoethoxyvinylglycine - BA N⁶ benzylaminopurine; 2,4-D, 2,4-dichlorophenoxyacetic acid - DNP 2,4-dinitrophenol - GA gibberellin - IAA indole-3-acetic acid - IBA indole-3-butyric acid - NAA naphthaleneacetic acid - SAM S-adenosylmethionine - STS silver thiosulphate - TIBA 2,3,5-triidobenzoic acid