PLASTID DEVELOPMENT IN IOJAP- AND CHLOROPLAST MUTATOR-AFFECTED MAIZE PLANTS

Plastids affected by either iojap or chloroplast mutator fail to green, and altered plastids are maternally transmitted to subsequent generations. The ultrastructure of iojap-affected plastids indicates that these plastids contain no ribosomes and are capable of supporting little internal membrane organization in either light or dark-grown plants. Chloroplast mutator-affected plastids of light-grown plants contain some organized internal membrane structures. In dark-grown plants, chloroplast mutator-aftected plastids contain a crystalline prolamellar body, numerous vesicles, and osmiophilic granules. The chloroplast mutator-affecled etioplasts display an abnormal distribution of lamellar membranes; these membranes, rather than radiating in a spokelike pattern from the prolamellar body, are condensed into a portion of the organelle. Light causes disruption of the prolamellar body in chloroplast mutator-affected plastids without promoting the organization of a normal thylakoid membrane system. The effects of iojap and chloroplast mutator are cell autonomous and apparently influence the individual plastid, as evidenced by the persistence of heteroplastidic cells containing normal and affected plastids.     

Effects of nalidixic acid, chloramphenicol, cycloheximide, and anisomycin on structure and development of plastids and mitochondria in greening Euglena gracilis

The substructure of plastids and mitochondria and the alterations caused by the addition of antibiotics were investigated during light-induced proplastid-to-chloroplast transformation in Euglena gracilis. The organisms were grown in presence of the inhibitors up to 3 days (5 generations). Both 40 μg/ml nalidixic acid and 1–1.5 mg/ml chloramphenicol prevent the formation of chloroplasts of normal size and structure by blocking development during early stages. Under our conditions 2 to 5 straight thylakoids are formed beside 1 to 2 girdle-like thylakoids. The former rarely fuse into bands. Non-crystalline prolamellar bodies of considerable size are formed at the distended ends of the plastids in the presence of both drugs. Chloramphenicol also influences mitochondrial size, shape and internal structure. Giant mitochondria can be observed. Nalidixic acid does not change the size and shape of mitochondria, but the matrix frequently appears highly osmiophilic. Cycloheximide in sublethal doses (2–5 μg/ml) or 50 μg/ml anisomycin inhibits plastid development only in the early period after addition. In later culture periods chloroplasts are found enlarged in size with an increased number of thylakoids and bands per organelle. Insertions of new bands are noted at the inner membrane of the chloroplast envelope. The electronmicroscopic observations agree with the results of chloroplast-specific biochemical activities such as light-induced increase in chlorophyll synthesis and of two chloroplast-bound enzyme activities. The results are discussed with respect to metabolic and biogenetic correlations between the two types of organelles in E. gracilis cells.     

Changes of the plastid system of Euglena gracilis induced with streptomycin and dihydrostreptomycin

Summary Streptomycin-like antibiotics cause hereditary and irreversible aplastidity of Euglena gracilis by inhibiting the replication of plastids, while normal cell division is maintained.Therefore, a gradual dilution of plastids takes place in a multiplying culture. Streptomycin was found to be more effective as bleaching agent than dihydrostreptomycin. The cells of Euglena gracilis are totally deprived of plastids by streptomycin treatment after 4.5 cell divisions, while 9 cell divisions are required with dihydrostreptomycin. In addition to the inhibition of plastid replication both antibiotics bring about formation of pathological plastids, both in growing and in stationary cultures. In this latter case pathological plastids are released from cells only after further cell division has taken place.     

Transport of proteins from cytoplasm into plastids in chloramphenicol-treated bean leaf discs

Leaf discs from etiolated bean plants were found to incorporate [³H]lysine into 80 S ribosomesynthesized proteins in the presence of chloramphenicol (100 mg l^–1) when exposed to light. After a 7 min pulse of [³H]lysine, the discs were transferred to the same medium but with nonradioactive lysine, and postincubation was carried out for 24 h. The number of silver grains over the plastids, after the first period of a lag phase, indicates a large increase between 12 and 24 h of postincubation. Simultaneously, the labeling of the cytoplasm becomes reduced during that period. The results show that during inhibition of the protein formation within plastids, the synthesis of plastid-destined proteins in cytoplasm, as well as their transport into plastids, can still proceed.     

CHANGES IN PLASTID AND MITOCHONDRION CONTENT DURING MATURATION OF GENERATIVE CELLS OF SOLANUM (SOLANACEAE)

A study was made of the number of plastids and mitochondria present in generative cells of Solanum immediately after microspore mitosis, and the fate of these organelles during development of the pollen was determined. Changes were followed via electron microscopy of anthers of S. chacoense and S. tuberosum Group Phureja × S. chacoense. In earliest stages the generative cells were oval and had one surface along the intine and other surfaces in contact with the vegetative cell. As the pollen matured the generative cells elongated, became spindle-shaped, and were completely engulfed in the vegetative cells. At the earliest stages studied, both mitochondria and plastids were present in the generative cell. Plastids of the generative cell were, in contrast to those of the vegetative cells, fewer, smaller, and lacking in starch. Through the maturation stages the content of these organelles in the vegetative cells remained unchanged. While the generative cells retained mitochondria until anthesis, their plastids disappeared completely during maturation. This selective loss during generative cell maturation could lead to transmission of those characteristics encoded in plastid DNA through the pistillate parent only. The mechanism could explain earlier genetic evidence that plastid characters of Solanum were transmitted uniparentally.     

Aspects of the biochemistry and ultrastructure of a cytoplasmically inherited plastid defect (Dp1) of tobacco

Dpl, a cytoplasmically inherited plastid defect of Nicotiana tabacum L., has been further characterized by pigment and ribulose diphosphate carboxylase (RuDPCase) assays and electron microscopy. RuDPCase activity was reduced in defective plastids to 20–67% of that in normal chloroplasts. The chlorophyll content was reduced to 5% or less of that in normal chloroplasts. Leaf areas with only defective plastids were very light green for several days after the leaf began to expand but eventually turned white. This loss of chlorophyll was correlated with a reduction in internal plastid lamellae, but there was much less reduction in RuDPCase activity. The presence of cells with both mutant and normal plastids indicate that the plastid and not some other cytoplasmic factor was the site of the controlling unit.Scientific Paper No. 3812, College of Agriculture, Washington State University, Pullman, Projects 1916 and 1920. Supported in part by funds provided for medical and biological research by Washington State Initiative Measure 171.     

Mutagenic DNA repair in Escherichia coli

Summary The photoreversibility of UV-induced mutations to Trp⁺ in strain Escherichia coli WP2 uvrA trp (unable to excise pyrimidine dimers) was lost at different rates during incubation in different media. In Casamino acids medium after a short initial lag, photoreversibility was lost over about one generation time; in minimal medium with tryptophan, photoreversibility persisted for more than two generations; in Casamino acids medium with pantoyl lactone photoreversibility was lost extremely slowly. The rate of loss of photoreversibility was unaffected by UV dose in either Casamino acids medium or in minimal medium. The same eventual number of induced mutants was obtained when cells were incubated for two generations in any of the three media before being transferred to selective plates supplemented with Casamino acids. Thus in each the proportion of cells capable of giving rise to a mutant was the same and only the rate at which these cells did so during post-irradiation growth varied, suggesting that there might be a specific fraction of pyrimidine dimers at a given site capable of initiating a mutagenic repair event, and that the size of this fraction is dose dependent. Segregation experiments have shown that error-prone repair appears to occur once only and is not repeated in subsequent replication cycles, in contrast to (presumed error-free) recombination repair.The results are discussed in the light of current models of UV mutagenesis.     

Early responses to gibberellic acid in a dwarf maize mutant (Zea mays L. d 1)

Early effects of gibberellic acid (GA₃) (1–4 h treatment) on the ion ratios in a dwarf maize mutant (Zea mays L. d ₁) showing normal growth after hormone treatment, have been investigated by electron microprobe analysis. GA₃ exerts a different effect on the ion ratios in plastids, cytoplasm and vacuoles in short term experiments. The Cl content of chloroplasts and cytoplasm increases without a lag phase after GA₃ treatment. The K content of plastids increases after a lag phase of 2 h, whereas in the cytoplasm an increase can be observed immediately after GA₃ addition. The hormone has only little influence on the Ca content of the cell compartments investigated. Control experiments with water and the physiologically inactive GA₃ methylester confirm the specifity of the short-term actions of GA₃ on the ion ratios. The primary action of GA₃ at the membrane level is discussed.     

Temperature dependency of induction of sexual agglutinability by α pheromone in the yeast Saccharomyces cerevisiae

When pheromone-pretreated cells of an inducible a strain of Saccharomyces cerevisiae carrying the inducible gene saa1 were incubated in a growth medium at 28°C, induction of sexual agglutinability began after a 10 min lag period. If the cells were incubated at 38°C during the lag period, no induction occurred even after incubation at 28°C. Contrary to this, if the cells were incubated at 28°C during the lag period, almost complete induction occurred, even after transfer to 38°C. Temperature shift experiments revealed that 5 min incubation at 28°C was necessary for the initiation of the temperature-sensitive period and further 5 min incubation for the completion of the period. The temperature-sensitive period was sensitive to phenylmethylsulfonyl fluoride.Non-common abbreviations PBS 10^-2 M phosphate buffer solution, pH 5.5 - PMSF phenylmethylsulfonyl fluoride     

Structural and chemical study of callus formation from leaves of <Emphasis Type="Italic">Rubia tinctorum</Emphasis>

Dedifferentiation was monitored in Rubia tinctorum L. leaves over a 14-d period after callus induction using transmission electron microscope (TEM), high performance liquid chromatography (HPLC), spectroscopy and thin layer chromatography (TLC). Photosynthetic pigment loss of leaves took 3–5 d coinciding with the first period of anthraquinone accumulation. Callus cells were discernible in the region of the vascular bundles and wounded edges of leaves after 10–14 d. Characteristic ultrastructural alterations were manifested in vacuolization, appearance of mitochondria, amount of smooth endoplasmatic reticulum and cytoplasm, caryolympha density of nuclei and cytoplasm content of cells. There were special events in the transfer cells: unequal divisions of dedifferentiated plastids and lytic activity in the cell wall. Our results show that mesophyll cells seem to be stopped at a particular level of dedifferentiation, while transfer cells embodied in veins of leaves pass through further alterations and lead to callus formation. Findings suggest that a sort of dedifferentiation drift manifests in the various cells of R. tinctorum leaves during callus induction and depending on their specialized status they achieve different levels of dedifferentiation. Approximately 4 weeks after callus induction, root growth has started from the young calli.     

Development of 0-methylhydroxylamine induced mutations causing resistance to 8-azaguanine in Chinese hamster cells]

The dependence of the yield of mutations of the resistance to 8-azaguanine induced with 0-methylhydroxylamine on the number of cell generations that have passed by the time of the creation of selective conditions and the existence of a phenotypic lag period is established. The highest rate of mutations is found after 8-azaguanine treatment in two generations. As the number of generations increased, the number of detectable mutations decreased. A dependence is observed between the induced mutation frequency and death of cells as the latter are transferred to selective conditions after two generations. In experiments on induced mutagenesis, one can obtain more exact quantitative characteristics by introducing a selective agent into the cell suspension but not by treating growing cells in colonies.     

Plastids in sieve elements and their companion cells

Summary Plastids have been identified in the sieve elements and/or companion cells of 14 monocotyledon species. In contrast to earlier reports, plastids are present in the sieve elements of Smilax and the companion cells of Tradescantia. The development and fine structure of the sieve-element plastids in Smilax do not differ from the type found in all of the 230 angiosperm species we have studied so far contain prominent plastids. The companion cells are easily identified by their specialized plasmatic connections with the sieve elements. The leucoplasts in the companion cells of Tradescantia are identical with those reported for many angiosperms.     

Changes in plastid proteome and structure in arbuscular mycorrhizal roots display a nutrient starvation signature

During arbuscular mycorrhizal symbiosis, arbuscule‐containing root cortex cells display a proliferation of plastids, a feature usually ascribed to an increased plant anabolism despite the lack of studies focusing on purified root plastids. In this study, we investigated mycorrhiza‐induced changes in plastidic pathways by performing a label‐free comparative subcellular quantitative proteomic analysis targeted on plastid‐enriched fractions isolated from Medicago truncatula roots, coupled to a cytological analysis of plastid structure. We identified 490 root plastid protein candidates, among which 79 changed in abundance upon mycorrhization, as inferred from spectral counting. According to cross‐species sequence homology searches, the mycorrhiza‐responsive proteome was enriched in proteins experimentally localized in thylakoids, whereas it was depleted of proteins ascribed predominantly to amyloplasts. Consistently, the analysis of plastid morphology using transmission electron microscopy indicated that starch depletion associated with the proliferation of membrane‐free and tubular membrane‐containing plastids was a feature specific to arbusculated cells. The loss of enzymes involved in carbon/nitrogen assimilation and provision of reducing power, coupled to macromolecule degradation events in the plastid‐enriched fraction of mycorrhizal roots that paralleled lack of starch accumulation in arbusculated cells, lead us to propose that arbuscule functioning elicits a nutrient starvation and an oxidative stress signature that may prime arbuscule breakdown.     

CORRELATED BIOCHEMICAL AND ULTRASTRUCTURAL CHANGES IN NITROGEN-STARVED EUGLENA GRACILIS1

Growth of Euglena gracilis Z Pringsheim under photoheterotrophic conditions in a nitrogen-deprived medium resulted in progressive loss of chloroplastic material until total bleaching of the cells occurred. Biochemical analysis and ultrastructural observation of the first stages of the starvation process demonstrated an early lag phase (from 0 to 9 h) in which cells increased in size, followed by a period of cell division, apparently supported by the mobilization of some chloroplastic proteins such as the photosynthetic CO₂-fixing enzyme ribulose-1,5-bisphosphate carboxylase/oxygenase. The degradation of the enzyme started after 9 h of starvation and was preceded by a transient concentration of this protein in pyrenoidal structures. Protein nitrogen and photosynthetic pigments as well as number of chloroplasts per cell decreased during proliferation through mere distribution among daughter cells. However, after 24 h, when cell division had almost ceased, there was a slow but steady decline of photosynthetic pigments. This was paralleled by observable ultrastructural changes including progressive loss of chloroplast structure and accumulation of paramylon granules and lipid globules in the cytoplasm. These findings reinforce the role of chloroplastic materials as a nitrogen source during starvation of E. gracilis in a carbon-rich medium. The excess of ribulose-1,5-bisphosphate carboxylase/oxygenase acts as a first reservoir that, once exhausted, is superseded by the generalized disassembly of the photosynthetic structures, if the adverse environment persists more than 24 h.     

The use of the immobilization of whole living cells to increase stability of recombinant plasmids in escherichia coli

Immobilization of whole living cells was used as an experimental approach to enhance plasmid stability in cultured recombinant micro-organisms. pTG201 plasmid which is very unstable in continuous cultures with free cells, was found to be extremely stable in continuous cultures with immobilized cells.To elucidate the mechanism by which immobilization increases the plasmid stability, we analyzed the growth of pTG201-containing E. coli W3101 cells within the gel beads. We found that in immobilized continuous culture, plasmid-free segregants were not detected even after 240 generations. This appears to be due to the mechanical properties of the gel-bead system that allow only a limited number of cell divisions (10–16) to occur in each clone of cells before the clone escapes from the gel bead. This number of generations is not sufficient for the plasmid-free cells to appear within the cavities compared to what was observed in a free-system (plasmid-free segregants were detected after a lag period of approximately 25–30 generations). Even when they appear, they cannot overcome the culture. From the data described in this paper we conclude that cells released from the gel beads at any time during continuous culture are cells which are issued from cells grown in the cavities for only 10–16 generations.     

A light and electron microscopy study of the epidermis of Paphiopedilum spp. with emphasis on stomatal ultrastructure

Abstract Light and fluorescence microscopy studies indicated that chlorophyll was absent from the guard cells of the lady slipper orchids, Paphiopedilum insigne (Wall.) Pfitz, P. insigne (hybrid), P. venustum (Wall.) Pfitz and P. harrisseanum Hort. In the guard cells of P. aureum hyeanum Hort., however, very slight red fluorescence suggested that chlorophyll and hence chloroplasts were present. Ultrastructural studies of the lower epidermis of P. insigne (hybrid) confirmed the absence of chloroplasts in guard and epidermal cells although plastids of an unusual structure were found in these cells. In fully developed epidermal cells the plastids contained large amounts of a fibrous, possibly proteinaceous substance, spherical, lightly staining vesicles and an electron-dense material located in reticulate and non-reticulate regions. Additionally, latticed crystalline inclusions and plasto-globuli were occasionally observed in the epidermal cell plastids. In plastids of fully developed guard cells the fibrous material, starch and plastoglobuli were present. From the earliest stages of development of the epidermal tissue starch was present in both epidermal cell and guard cell plastids. At maturity, however, starch had accumulated to greater levels in the guard cell plastids and had entirely disappeared in the epidermal cell plastids. In differentiating epidermal tissue, plasmodesmata were found between neighbouring epidermal cells and between guard and epidermal cells. At maturity, plasmodesmata between guard and epidermal cells were not observed. Mitochondria were particularly abundant in guard cells. Large oil drops developed in guard and epidermal cells, being especially abundant in the former at maturity. Our results confirm the observations of Nelson & Mayo (1975) that certain lady slipper orchids possess functional stomata the guard cells of which do not contain chloroplasts.     

Ultrastructural Aspects of the Glandular Cells from the Secretory Trichomes and from the Cell Suspension Cultures of Achillea millefolium L. ssp. millefolium

The ultrastructure of the glandular cells of the floret secretorytrichomes from Achillea millefolium L. ssp. millefolium (yarrow)was examined before and after anthesis and compared with theultrastructure of the cells from the cell suspension culturesobtained from the same plant. The profuse tubular structuresobserved in the plastids of the glandular cells of the trichomesduring the pre-secretory stage were much reduced in the secretorystage and showed an osmiophilic content. Some endoplasmic reticulumprofiles could be seen adjacent to the plastids. Later in thesecretory stage, the secretion appeared in the periplasmic spacebetween the cells of the upper tiers and in the sub-cuticularspace. Finally the secretion was released by rupture of thecuticle. At the lag phase, the cells from the cell suspensioncultures of yarrow were characterized by the presence or plastidswith tubular structures, similar to those observed in the plastidsof the trichomes in the pre-secretory stage. By the end of thelag phase accumulations of starch were observed inside the plastids.At the beginning of the exponential phase, the tubular structuresof the plastids started to show an osmiophilic content and theaccumulations of starch were still present. At the end of thisphase starch disappeared from the plastids and only osmiophilictubular structures were observed. Rough endoplasmic reticulumas well as smooth endoplasmic reticulum profiles were frequentlyin close association with plastids and mitochondria. At thestationary phase a very large vacuole filled the cells, andin the remaining cytoplasm some endoplasmic reticulum profilesand osmiophilic droplets were observed.Copyright 1994, 1999Academic Press Achillea millefolium L. spp. millefolium, yarrow, ultrastructure, trichomes, glandular cells, plant cell suspension cultures     

Vir-115 gene product is required to stabilize D1 translation intermediates in chloroplasts

The nuclear gene mutant of barley, vir-115, shows a developmentally induced loss of D1 synthesis that results in inactivation of Photosystem II. Translation in plastids isolated from 1 h illuminated vir-115 seedlings is similar to wild type. In wild-type barley, illumination of plants for 16 to 72 h results in increased radiolabel incorporation into the D1 translation intermediates of 15–24 kDa. In contrast, these D1 translation intermediates were not observed in vir-115 plastids isolated from plants illuminated for 16–72 h. In addition, after 72 h of illumination, radiolabel incorporation into D1 was undetectable in vir-115 plastids. The level and distribution ofpsbA mRNA in membrane-associated polysomes was similar in wild-type and vir-115 mutant plastids isolated from plants illuminated for 16–72 h. Toeprint analysis showed similar levels of translation initiation complexes onpsbA mRNA in vir-115 and wild-type plastids. These results indicate that translation initiation and elongation of D1 is not significantly altered in the mutant plastids. Ribosome pausing onpsbA mRNA was observed in wild-type and vir-115 mutant plastids. Therefore, the absence of D1 translation intermediates in mutant plastids is not due to a lack of ribosome pausing onpsbA mRNA. Based on these results, it is proposed that vir-115 lacks or contains a modified nuclear-encoded gene product which normally stabilizes the D1 translation intermediates. In wild-type plastids, ribosome pausing and stabilization of D1 translation intermediates is proposed to facilitate assembly of cofactors such as chlorophyll will D1 allowing continued D1 synthesis and accumulation in mature chloroplasts.     

In situ plastid and mitochondrial DNA determination: Implication of the observed MINIMAL PLASTID GENOME NUMBER

The total loss of plastid DNA has never been reported for any alga or plant cell line, with the sole exception of the protozoan Euglena, yet plastid distribution at mitosis is apparently stochastric (Birky and Skavaril, Journal of Theoretical Biology, vol. 106, pp. 441–447, 1984) and accidental loss might be expected. It is not obvious how stem cells of photosynthetic eukaryotes avoid this problem. The chrysophyte alga Ochromonas danica, described as having but one or two plastids, can proliferate indefinitely without the benefit of photosynthesis. Under such conditions its plastid genome copy number per cell might drop to the absolute minimum compatible with maintaining its inheritance. In situ quantitation of Ochromonas plastid DNA in both photosynthetic and enriched mixotrophic growth, and in heterotrophic growth in prolonged darkness, suggests that plastids are capable of very wide variation (7 to >;200 genomes/plastid) in their DNA content, and likewise, cells can vary from one to >;8 plastids per cell, with total genomes numbers from 7 to >;1,000 per cell. Among many growth conditions tested, the smallest plastids were found in rapidly dividing cells grown in the dark, many of which contained but one plastid. The inability to find plastids with fewer than seven plastid genome equivalents of DNA, even in these rapidly multiplying cells grown in total darkness for months, suggests that multiple copies of the plastid genome may be very carefully maintained, even in the prolonged absence of photosynthesis. This implies that multiple copies are important for reasons other than photosynthetic capability; two possibilities are the biosynthetic steps necessary for eukaryote cell survival known to occur solely within a plastid, and/or the potential that multiple plastid genome copies provide to escape the effects of Muller's ratchet.     

Hereditary structural alterations of plastids induced by a nuclear mutator gene inArabidopsis

Summary Homozygosity for mutant alleles at thechm locus inArabidopsis induces structural alterations in the plastids. The newly arisen plastid alterations are hereditary, autonomous from the inducer gene, and show maternal transmission only. The mutator action is limited to the plastids but several sites within this organelle become mutable with a very high frequency. The mutations reveal that the plastids have a share in the control of their own structure and function as well as in those of the host cells and organs. The individuality of the plastids was ascertained by genetic and electron microscopic techniques. Within single cells numerous different plastids were revealed. The mutations blocked plastid differentiation at various stages and also produced viable, functional chloroplasts of distinct morphology. Since specific structural alterations can be genetically isolated in homoplastidic forms, one may apply the techniques of the classical cytogenetics to chloroplasts and correlate function with the morphology of this hereditary vehicle in somewhat similar manner as structural alterations of the chromosomes have been correlated with genic expression and pattern of inheritance.Contribution from the Missouri Agricultural Experiment Station. Journal Series Number 6534. Approved by the Director 10/9/72.