Mitochondrial DNA variation in maize plants regenerated during tissue culture selection

Summary Plants resistant to Helminthosporium maydis race T were obtained following selection for H. maydis pathotoxin resistance in tissue cultures of susceptible, Texas male-sterile (T) cytoplasm maize. The selected lines transmitted H. maydis resistance to their sexual progeny as an extranuclear trait. Of 167 resistant, regenerated plants, 97 were male fertile and 70 were classified male sterile for reasons that included abnormal plant, tassel, anther or pollen development. No progeny were obtained from these male-sterile, resistant plants. Male fertility and resistance to the Phyllosticta maydis pathotoxin that specifically affects T cytoplasm maize were co-transmitted with H. maydis resistance to progeny of male-fertile, resistant plants. These three traits previously were associated only with the normal (N) male-fertile cytoplasm condition in maize. Three generations of progeny testing provided no indication that the cytoplasmic association of male sterility and toxin susceptibility had been broken by this selection and regeneration procedure. Restriction endonuclease analysis of mitochondrial DNA (mtDNA) revealed that three selected, resistant lines had distinct mtDNA organization that distinguished them from each other, from T and from N cytoplasm maize. Restriction patterns of the selected resistant lines were similar to those from T cytoplasm mtDNA; these patterns had not been observed in any previous analyses of various sources of T cytoplasm. The mtDNA analyses indicated that the male-fertile, toxin-resistant lines did not originate from selection of N mitochondrial genomes coexisting previously with T genomes in the T cytoplasm line used for selection.Scientific Journal Series Article no. 11,185 of the Minnesota Agricultural Experiment Station and no. 2295 of the Florida Agricultural Experiment Station. Mention of a trademark, proprietary product, or vendor does not constitute a guarantee of warrantly of the product by the U.S. Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable     

Mixing of maize and wheat genomic DNA by somatic hybridization in regenerated sterile maize plants

Intergeneric somatic hybridization was performed between albino maize (Zea mays L.) protoplasts and mesophyll protoplasts of wheat (Triticum aestivum L.) by polyethylene glycol (PEG) treatments. None of the parental protoplasts were able to produce green plants without fusion. The maize cells regenerated only rudimentary albino plantlets of limited viability, and the wheat mesophyll protoplasts were unable to divide. PEG-mediated fusion treatments resulted in hybrid cells with mixed cytoplasm. Six months after fusion green embryogenic calli were selected as putative hybrids. The first-regenerates were discovered as aborted embryos. Regeneration of intact, green, maize-like plants needed 6 months of further subcultures on hormone-free medium. These plants were sterile, although had both male and female flowers. The cytological analysis of cells from callus tissues and root tips revealed 56 chromosomes, but intact wheat chromosomes were not observed. Using total DNA from hybrid plants, three RAPD primer combinations produced bands resembling the wheat profile. Genomic in situ hybridization (GISH) using total wheat DNA as a probe revealed the presence of wheat DNA islands in the maize chromosomal background. The increased viability and the restored green color were the most-significant new traits as compared to the original maize parent. Other intermediate morphological traits of plants with hybrid origin were not found.     

Ploidy levels of plants regenerated from mixed ploidy maize callus cultures

Summary Haploid and diploid anther-derivedZea mays callus lines were treated with the antimicrotubule herbicide pronamide to produce mixed ploidy callus as determined by flow cytometry. The ploidy levels of the plants regenerated from the callus were determined by counting the leaf epidermal guard cell chloroplast numbers. The proportion of diploid regenerated plants was somewhat lower than the proportion of diploid cells of the callus. The diploid plants regenerated somewhat faster than the haploids. The proportion of tetraploids regenerated from the pronamide treated diploid callus, which originated by spontaneous chromosome doubling, was much lower than the proportion of cells indicating that tetraploid cells survive or regenerate plants at a lower frequency than diploid cells.     

Disease lesion mimics of maize: A model for cell death in plants

A class of maize mutants, collectively known as disease lesion mimics, display discrete disease-like symptoms in the absence of pathogens. It is intriguing that a majority of these lesion mimics behave as dominant gain-of-function mutations. The production of lesions is strongly influenced by light, temperature, developmental state and genetic background. Presently, the biological significance of this lesion mimicry is not clear, although suggestions have been made that they may represent defects in the plants' recognition of, or response to, pathogens. One feature that is common to all lesion mimics is their association with cell death. In plants, as in animals, a number of developmental and pathological processes exist where controlled cell death, whether programmed or triggered in response to physiological or environmental stimuli, constitutes the normal aspect of life. Might disease lesion mimic mutations represent variants where regulation of desirable cell death has gone awry? In this paper we argue that this might be the case, and further conjecture that these mutants offer a unique opportunity for studying the genetic and cellular mechanisms of cell death in plants.     

Multiple patterns of mtDNA reorganization in plants regenerated from different in vitro cultured explants of a single wheat variety

Summary We have previously shown that tissue cultures derived from various explants of the wheat variety Chinese Spring exhibit organ/tissue-specific changes in the organization of their mitochondrial genome. The aim of this work was to study the influence of passage out of in-vitro culture, and subsequent plant regeneration, on the in vitro induced reorganization of this genome. In all cases but one, subgenomic configurations present in both the donor parent and the tissue culture were evident, in corresponding regenerated plants. The presence, in regenerated plants, of subgenomic configurations found in tissue culture but undetectable in the donor parent appeared to be both timeand organ/tissue-dependent. Moreover, when present, these novel organizations were not systematically found in all regenerated plants. Finally, novel subgenomic configurations were specifically detected after passage out of in-vitro culture. As these results were obtained from a single plant variety, they clearly confirm the extreme plasticity of mitochondrial genome structure in response to in-vitro culture.Accepted by D. R. Pring     

Accumulation of vismione A in regenerated plants ofVismia guianensis DC

Summary The accumulation and tissue localization of antitumoral vismione A in the in vitro regenerated plants ofVismia guianensis DC. were investigated. Chemical and light and electron-microscope analyses revealed that vismione A, detected as phenolic black globules in the vacuoles, was accumulated in the leaf, mainly in the palisade, and in small amounts in the primary body of the stem (epidermis and first cortical layer). Vismione A is neither present in the secretory cavities and ducts of the leaf nor in the secretory ducts of the stem. In the leaves of the regenerated plants, the amount of vismione A reached 0.5% FW, compared to 0.1% in the leaves of the parent plant. The optimization of the in vitro regeneration of plants was obtained in MS medium enriched with BAP (1 ppm). The best results for the rooting of regenerated plants were achieved with MS medium containing half-strength salts and 10^–5 MIBA.Abbreviations APT attached proton test - BAP 6-benzyl-aminopurine - CC column chromatography - 2,4-D 2,4-dichlorophenoxyacetic acid - EtOAc ethyl acetate - IBA indole-3-butyric acid - MeOH methanol - MS Murashige and Skoog - NAA -naphthaleneacetic acid - NMR nuclear magnetic resonance - TEM transmission electron microscopy - TLC thin layer chromatography - UV ultraviolet     

A model for sucrose transport in the maize scutellum

A model originally developed for transport of neutral substrates in bacterial systems was tested for its suitability for depicting sucrose transport across the plasmalemma of the maize scutellum cell. The model contains a sucrose—proton symporter, a negatively-charged free carrier and a neutral sucrose—proton—carrier complex. Sucrose transport is driven by the sucrose gradient and by a proton electrochemical gradient set up by a proton-translocating ATPase. The results of experiments on sucrose uptake in scutellum slices are in accord with predictions based on the model. Evidence was obtained for an electrogenic proton pump in the plasmalemma, for sucrose—proton symport and for a sucrose transport mechanism driven by both electrical potential and pH gradients. It was found that treatments (dinitrophenol, N-ethylmaleimide or HCl) causing a net proton influx into the slices also caused an efflux of sucrose. Interpretations of these results compatible with the model are given.     

Genome rearrangements by nonlinear transposons in maize.

Transposable elements have long been considered as potential agents of large-scale genome reorganization by virtue of their ability to induce chromosomal rearrangements such as deletions, duplications, inversions, and reciprocal translocations. Previous researchers have shown that particular configurations of transposon termini can induce chromosome rearrangements at high frequencies. Here, we have analyzed chromosomal rearrangements derived from an unstable allele of the maize P1 (pericarp color) gene. The progenitor allele contains both a full-length Ac (Activator) transposable element and an Ac terminal fragment termed fAc (fractured Ac) inserted in the second intron of the P1-rr gene. Two rearranged alleles were derived from a classical maize ear twinned sector and were found to contain a large inverted duplication and a corresponding deficiency. The sequences at the junctions of the rearrangement breakpoints indicate that the duplication and deletion structures were produced by a single transposition event involving Ac and fAc termini located on sister chromatids. Because the transposition process we describe involves transposon ends located on different DNA molecules, it is termed nonlinear transposition (NLT). NLT can rapidly break and rejoin chromosomes and thus could have played an important role in generating structural heterogeneity during genome evolution.     

Karyotypic changes in potato plants regenerated from protoplasts

Over two hundred plants were regenerated from shoot-culture derived proto-plasts of potato (Solanum tuberosum L. cv. Majestic). Some had grossly aberrant phenotypes but the majority were similar to, or indistinguishable from normal control Majestic. Cytological examination showed that on average, 57% of the regenerants had the normal chromosome number (2n=4x=48). The remainder were aneuploids and fell into two classes in approximately equal numbers. The first class was limited at about the euploid level (ie, 2n=44–49). The second class contained plants with higher chromosome numbers ranging from 2n=73 to the octaploid level (2n=8x=96). The overall results represent an improvement over our earlier studies on chromosome variation in protoplast-derived potato plants. In addition, three cases of structural chromosome variation were observed.     

Putative homozygous mutations in regenerated plants of rice

Summary Both normal and putative homozygous mutant (dwarf mutant) rice plants were regenerated from diploid seed callus, cultured in the presence of 1% NaCl. This trait was transmitted at least through the eighth genration (D₈) of regenerated plants (D₁) by self-pollination, as a homozygous mutation. However, the trait disappeared in the F₁, F₂, F₃ and F₄ obtained by reciprocal crosses of mutant plants with either control plants or with progeny of normal regenerated plants. Chimeric reversion of the homozygous mutant trait was observed and the revertant phenotype was transmitted stably to at least three successive generations. Similar dwarf types of homzygous mutation were observed independently in the two varieties, Norin 8 and Nipponbare, in an experimental series of ca. 3000 D₁ plants. The frequency of mutations among regenerated plants was calculated to be 1.8×10^-2. The mechanism responsible for these phenomena may be heritable gene inactivation induced by in vitro culture.     

Genetic variability in regenerated plants of Ungernia victoris

To determine the suitability of micropropagation techniques developed for conserving rare medicinal herb Ungernia victoris we estimated the genetic fidelity of plants produced through direct regeneration from the bulb scale segments and organogenesis from long-term callus culture. Average value of the Jaccard’s distances between explant-derived regenerants and maternal plants calculated from RAPD data was 0.5 %, while that of estimated between callus-derived regenerants and maternal cell line was 4.2 %; average distances between the objects among the explant-derived and callus-derived regenerants were 0.7 % and 2.5 %, respectively. The data obtained suggest that conditions for in vitro culture applied in this work provide relatively high genetic stability of the species upon the direct regeneration in vitro and regeneration from the long-term cultured callus.     

A biomechanical model for maize root lodging

Plant and Soil - Root lodging is a structural failure of the root-soil anchorage system in a plant that adversely affects its yield. It is a complex phenomenon that depends strongly on both crop...     

Application of luminescence for quality evaluation of in vitro regenerated strawberry plants

The parameters of chlorophyll a fluorescence induction were measured: F_v/F_m, S_c/F_m, Rf_d and coefficient of L_d delayed luminescence decay kinetics, related with a course of primary photosynthesis reactions on leaves of strawberry plants, cultured in vitro by means of the micropropagation methods. Strawberry plants cv. Ananasowa from in vitro cultures in optimal condition show significantly higher values of luminescence parameters indicating better condition of plants of this variety in comparison with the variety Senga Sengana. After temperature lowering, however, these values were more reduced than for plants of Senga Sengana, which can be interpreted as higher susceptibility of this variety to chill. Addition of BAP caused disturbance of primary photosynthesis reactions rate, particularly in lower temperature. Auxin 2,4-D had no effect on the luminescence parameters in comparison with control cultures. Dehydration stress strongly diminished the values of measured parameters for Ananasowa variety what indicates the inhibition of primary photosynthesis reaction in leaves. The old culture of Senga Sengana variety showed higher tolerance on linuron in comparison with the new one.     

A statistical model for the study of self-fertilization in plants

A model is proposed for the study of plant breeding where the self-fertilization rate is of importance. The model can be used to provide convenient maximum likelihood estimation of the self-fertilization rate and allelic frequencies in a parental population and its pollen pool. The self-fertilization rate can also be allowed to vary with genotype or other characteristics of a plant. A simple example illustrates the methodology.     

A model for starch breakdown in higher plants

An in vitro system for the breakdown of starch granules by mixtures of α- and β-amylase is developed and discussed with reference to information concerning the degradation of starch in vivo. β-Amylase has no action on starch granules and has very little effect on the rate of starch granule digestion by α-amylase. It does, however, affect the product distribution in an α-amylase digest and is considered to attack dextrin intermediates produced by the action of α-amylase on the starch granules.     

Somaclonal variation in soybean plants regenerated from tissue culture

Callus cultures of soybean (Glycine max (L.) Merr.) genotypes PI 88788, PI 438489B, and cultivar Bedford were initiated in vitro from seedling explants consisting of the cotyledonary node plus epicotyl from germinated mature seed. Plants were regenerated from these callus cultures and subsequently evaluated for qualitative variation in three to four subsequent generations. Variant phenotypes observed that have not been previously reported from tissue culture include lanceolate leaves, leaf variegation (chimeral variegated plants), pod variegation on otherwise normal plants, and change in growth habit from indeterminate to determinate. The lanceolate leaf, chimeral variegated plant, and change from indeterminate to determinate growth habit characters were inherited through at least three generations (R₀-R₂), and segregation occurred in each generation. Pod variegation was inherited through the two generations tested thus far and segregation occurred in each generation. No variation was observed in control plants derived from normal seed. Variants appeared more frequently in regenerants from PI 88788 and PI 438489B than from Bedford. These results confirm and extend the finding that certain tissue culture techniques may be used to induce novel plant formation from somatic tissue of soybean.Missouri Agricultural Experiment Station, University of Missouri, Columbia, Missouri, USAMention of tradenames does not constitute a guarantee or warranty of the product by University of Missouri or USDA-ARS and does not imply their approval to the exclusion of other products.     

Variation in plants regenerated from vacuolate and evacuolate protoplasts

Mesophyll protoplasts of Nicotiana tabacum were evacuolated by centrifugation through a percoll gradient. Their viability was comparable to untreated protoplasts, but the time for reformation of the cell wall as well as to the onset of the first division was delayed. Plants were regenerated from both classes of protoplast; those from evacuolate protoplasts showed higher rates of mutation than those from vacuolate protoplasts. The possible basis of this difference is discussed.     

Isozyme variation in leaf-callus regenerated plants of Solanum tuberosum

Electrophoretic patterns of isozymes, allowing the direct study of gene products, represent a valid tool in detecting genetic and epigenetic variations both involved in determining somaclonal variation. In the present work, three isozyme systems, glutamate-oxalacetate transaminase (GOT, EC 2.6.1.1), alcohol dehydrogenase (ADH, EC 1.1.1.1), and esterase (EST, EC 3.1.1.1), were analyzed in different organs of callus-regenerated plants of potato and on the tubers of the first vegetative reproduction. As concerns ADH and GOT, the electrophoretic patterns showed the disappearance of one band in may regenerated plants in respect to the parental cultivar. This loss of allele expression can be determined by a stable (ADH) or by an unstable change (GOT) as suggested by the permanence or not of the variation in the tubers. The electrofocusing of esterase revealed the presence of additional bands in respect of parental cultivar. Taking into account that somaclonal variation might arise as the response of the genome to a shock caused by tissue culture, it is suggested that sequence rearrangements represent likely mechanisms respectively involved in the loss or in the appearance of gene expression.