Genetic analysis of aMicroseris douglasii (Asteraceae) population polymorphic for an alien chloroplast type

Recent evidence suggests chloroplast introgression fromMicroseris bigelovii intoM. douglasii. We have examined 23 plants from a population ofM. douglasii polymorphic forM. douglasii andM. bigelovii chloroplast types. All 23 plants were completely homozygous for morphological and RAPD markers, and inbred lines derived by selfing have been used for DNA analysis. Chloroplast RFLP analysis identified 16 plants withM. bigelovii chloroplasts and seven withM. douglasii chloroplasts. The nuclear genomes of the 16 plants withM. bigelovii chloroplasts were examined with 22 primers for RAPD amplification products shared exclusively withM. bigelovii. Five of 268 markers appeared to be shared betweenM. bigelovii and one or more of these 16 plants on the basis of their position in gels. Detailed examination of these five amplification products showed that none of them are nuclear DNA fromM. bigelovii. Very little, if any, nuclear DNA fromM. bigelovii can be present inM. douglasii plants with chloroplasts typical ofM. bigelovii. The study demonstrates the usefulness of the RAPD technique for screening large numbers of markers to select a few potentially informative ones for rigorous examination.Dedicated to emer. Univ.-Prof. DrFriedrich Ehrendorfer on the occasion of his 70th birthday     

Über die Phycobionten der SektionCystophora vonChaenotheca,insbesondereDictyochloropsis splendida undTrebouxia simplex,spec. nova

Chaenotheca brunneola is lichenized withDictyochloropsis splendida. Until now this member of theChlorococcales has been observed only twice and free-living. It reproduces by motionless daughter cells in the lichen thallus, but mainly by zoospores in the free-living state and under favourable conditions. Zoospore development has not been observed before and apparently depends on storage of starch which is repressed in the lichenized state. During zoospore activity this storage material is consumed. Zoospores possess two flagella which are inserted rather far apart from each other, one pulsating vacuole and a cup-shaped, not latticed chloroplast.Chaenotheca phaeocephala var.alpina, Ch. melanophaea andCh. chrysocephala are lichenized withTrebouxia. The phycobiont ofCh. chrysocephala, Trebouxia simplex, sp. n., differs from other sibs of the genus by the relative small size of the cells, the less marked differentiation of the chloroplast and certain details of cell division.

     

Cell size and chloroplast size in relation to chloroplast replication in light-grown wheat leaves

As part of an investigation into the control of chloroplast replication the number and size of chloroplasts in mesophyll cells was examined in relation to the size of the cells. In first leaves of Triticum aestivum L. and T. monococcum L. the number of chloroplasts in fully expanded mesophyll cells is positively correlated with the plan area of the cells. The linear relationship between chloroplast number per cell and cell plan area is also consistent over a fivefold range of cell size in isogenic diploid and tetraploid T. monococcum. In T. aestivum the chloroplast number per unit cell plan area varies among cells in relation to the size of the chloroplasts. Those cells containing chloroplasts with a relatively small face area have a correspondingly higher density of chloroplasts, and consequently, the total chloroplast area per unit cell plan area is very similar in all the cells. The results indicate that the proportion of the cell surface area covered by chloroplasts is precisely regulated, and that this is achieved during cell development by growth and replication of the chloroplasts.     

Comparison of chloroplast and nuclear phylogeny in the autogamous annualMicroseris douglasii (Asteraceae: Lactuceae)

Morphology suggests that the Californian annualMicroseris douglasii is a monophyletic sister group to the other three diploid annuals ofMicroseris. Phylogenetic analysis of 44 inbred strains ofM. douglasii derived from 23 populations with 72 RAPD markers in the nuclear DNA strongly supports this phylogeny. However, 13 chloroplast RFLPs divideM. douglasii into four distinct groups. Two of these each share one or more cpRFLPs withM. bigelovii andM. pygmaea. Several hypotheses can explain the incongruence between nuclear and chloroplast phylogeny: (1) random sorting out of chloroplasts during phylogeny from a polymorphic pool, (2) cytoplasmic introgression from the related annualM. bigelovii intoM. douglasii after hybridization followed by elimination of theM. bigelovii nuclear genome. We suggest cytoplasmic introgression as the most likely origin. Possible remnants of nuclear introgression have been found in two populations ofM. douglasii that are polymorphic for chloroplast types. In these populationsM. bigelovii type chloroplast DNA seems to be accompanied by nuclear genes for flower color and leaf shape.     

Changes in structure of isolated chloroplasts ofCodium fragile andCaulerpa filiformis in response to osmotic shock and detergent treatment

Summary The ultrastructure of chloroplasts from two genera of coenocytic green algae,Codium andCaulerpa, were examined after suspension in hypotonic solution and in detergent at various concentrations. The capacity of the suspensions to carry out CO₂-dependent and ferricyanide-dependent O₂ evolution was measured under the same conditions of osmotic strength and detergent concentration.The chloroplasts in the preparations were in the form of cytoplasts and gave rates of O₂ evolution comparable with those expected from undamaged chloroplasts. Suspension in hypotonic solution depressed the rate of CO₂-dependent O₂ evolution in both species, but this was partially restored in theCodium chloroplasts when these were re-suspended in iso-osmotic solutions. Major structural changes were observed only after suspension in buffer when theCodium chloroplasts lost their outer envelope, most of their stroma, and the thylakoids became swollen.Caulerpa chloroplasts were more variable in their response and, even when suspended in buffer only, the proportion of the plastids which had lost all of their stroma and thylakoid swelling was never as common as inCodium chloroplasts. However, once suspended in hyper-osmotic medium below 700 mosmolar,Caulerpa chloroplasts could not regain their capacity for CO₂-dependent O₂ evolution.Detergent treatment removed the cytoplast membrane but not the cytoplasmic material adhering to the chloroplast envelope. High concentrations of detergent were needed to cause loss of the chloroplast envelope, loss of stromal contents and unstacking of the thylakoids.Caulerpa chloroplasts were less sensitive to detergent than those ofCodium. There was no indication that specific structures such as the thylakoid organizing body were resistant to detergent action. The results show that exposure to hypotonic solutions and to detergent results in less damage to these chloroplasts than it would to those of higher plants. It is proposed that the basis of this unusual resistance is not due to the properties of the chloroplast membranes but to the presence of material which coats the organelles during isolation. This material is likely to be identical with the sulphated xylo-mannogalactan isolated from the vacuole contents of these algae and which has the visco-elastic properties essential to allow the organelles to resist disruption by osmotic forces and disintegration by detergents.     

C4 syndrome of the species in theDichotomiflora group of the genusPanicum (Gramineae)

Leaf anatomy, pattern of post-illumination CO₂ burst (PIB) and activity of three C₄-acid decarboxylating enzymes in C₄ photosynthesis were investigated with the leaves of five species in theDichotomiflora group of the genusPanicum. All species had mestome sheaths, exhibited the sharp pattern of PIB in less than 30 sec of darkness and were classified as NAD-malie enzyme species biochemically. However, they clearly fell into two groups according to the difference in chloroplast location in bundle sheath cells (BSC).P. coloratum var.makarikariense, P. lanipes andP. stapfianum had centripetal chloroplasts, whereasP. laevifolium andP. longijubatum had centrifugal chloroplasts, whereas cv. Kabulabula and cv. Solai had centrifugal chlorplasts. The results indicate that theDichotomiflora group had the two leaf anatomical variations of NAD-malic enzyme species. In addition, the results onP. coloratum suggest that this species may be divided into two separate species by chloroplast location in BSC. The ultrastructural features of leaves ofP. dichtomiflorum, NAD-malic enzyme species with centrifugal chloroplasts, were also investigated. Chloroplasts in BSC had well-developed grana, and numerous large mitochondria with extensively developed internal membrane structure were restricted to the area between the chloroplsts and the vacuole in BSC.     

Über Plastidenstapel beiBotrydiopsis alpina sowie Anlage und Vermehrung der Stigmen bei dieser undHeterococcus (Xanthophyceae)

Under certain conditions inBotrydiopsis alpina stacks of chloroplasts are formed. They consist of up to 8 elements. In contrast to what is known from other algae in zoosporangia of this species and ofHeterococcus caespitosus, stigmata are formed in early developmental stages. They are reproduced together with the chloroplasts, in which they occupy a position at the edge and near the existing or future incision. At the side of the old stigma a new one is formed, and partitioning of the chloroplast between these two leads to their distribution to the daughter chloroplasts. Young daughter cells in the zoosporangia ofBotrydiopsis alpina contain one chloroplast which undergoes a last unequal division giving rise to one astigmate and usually somewhat smaller and to one stigmate chloroplast. In both species the capacity for locomotion may be suppressed, the presumptive zoospores thereby becoming aplanospores. Autospores in the proper sense were not observed. Their development quite generally is different from that of aplanospores (and zoospores), and both types of spores should be distinguished.

Herrn Professor Dr.Lothar Geitler zum 80. Geburtstag in Verehrung gewidmet.     

Chloroplast proliferation based on their distribution and arrangement inAdiantum protonemata growing under red light

Chloroplast proliferation was investigated inAdiantum protonemata growing under continuous red light. Cell division is absent when cells are grown under red light. The chloroplast number increases as the cell length increases, therefore the chloroplasts divide in the absence of cell division. Chloroplasts in the basal part of the filamentous protonemal cell migrate gradually toward the cell apex, but there is no large net migration from the tip to the base or vice versa, indicating that chloroplast division takes place in the apical part of the protonemata. Chloroplast number in the apical 100 μm was maintained at about 200 during cell growth at least over eight days. The chloroplasts were either dumbbell- or ellipsoid-shaped. Dumbbell-shaped chloroplasts are abundant everywhere in a protonema, ranging from 30 to 50% of the total chloroplasts. The dumbbell-shaped chloroplasts attached to or very close to the plasma membrane seem to be the ones that are dividing but the dumbbell-shaped ones in the other regions do not divide. These data support the hypothesis that a signal from the plasma membrane induces the dumbbell-shaped chloroplasts to divide.     

Lupinus species differ in their requirements for iron

The effect of iron supply on the growth and nodulation ofLupinus angustifolius L. (Gungurru),Lupinus luteus L. (R-1171) andLupinus pilosus Murr. (P20957) was studied in acid solutions. Plants of the three species were grown together in the same solution and inoculated withBradyrhizobium (Lupinus) WU 425. Plants were then grown with or without applied NH₄NO₃. The lupin species differed greatly in their sensitivity to low iron concentrations in solution withL. pilosus being most tolerant andL. luteus most sensitive.L. pilosus had the highest iron concentration in tissues and had a higher ratio of iron concentration in the youngest fully expanded leaf blades (YEB) to that in roots than the other two species.L. luteus had higher iron concentrations in roots but lower iron concentration in YEB and shoots than didL. angustifolius. The requirements of internal iron for the maximal chlorophyll synthesis in YEB were 65 μg g^-1 forL. angustifolius andL. luteus, and 52 μg g^-1 forL. pilosus. In contrast to effects on growth, the three species had similar external iron requirements for nodule formation in roots and for maximal nitrogen concentrations in shoots. The results indicate that iron tolerant lupin species require lower internal and external iron supply and have a greater ability than sensitive species to translocate iron from roots to shoots.     

A rapid method for isolation of purified,physiologically active chloroplasts,used to study the intracellular distribution of amino acids in pea leaves

A procedure is described for the rapid (<5 min) isolation of purified, physiologically active chloroplasts from Pisum sativum L. Mitochondrial and microbody contamination is substantially reduced and broken chloroplasts are excluded by washing through a layer containing a treated silica sol. On average the preparations contain 93% intact chloroplasts and show high rates of ¹⁴CO₂ fixation and CO₂-dependent O₂ evolution (over 100 mol/mg chlorophyll(chl)/h); they are also able to carry out light-driven incorporation of leucine into protein (4 nmol/mg chl/h). The amino-acid contents of chloroplasts prepared from leaves and from leaf protoplasts have been determined. Asparagine is the most abundant amino acid in the pea chloroplast (>240 nmol/mg chl), even thought it is proportionately lower in the chloroplast relative to the rest of the cell. The chloroplasts contain about 20% of many of the amino acids of the cell, but for individual amino acids the percentage in the chloroplast ranges from 8 to 40% of the cell total. Glutamic acid, glutamine and aspartic acid are enriched in the chloroplasts, while asparagine, homoserine and -(isoxazolin-5-one-2-yl)-alanine are relatively lower. Leakage of amino acids from the chloroplast during preparation or repeated washing was ca. 20%. Some differences exist between the amino-acid composition of chloroplasts isolated from intact leaves and from protoplasts. In particular, -aminobutyric acid accumulates to high levels, while homoserine and glutamic acid decrease, during protoplast formation and breakage.     

The control of chloroplast number in wheat mesophyll cells

Chloroplast number per cell and mesophyll cell plan area were determined in populations of separated cells from the primary leaves of different wheat species representing three levels of ploidy. Mean chloroplast number per cell increases with ploidy level as mean cell size increases. But in addition the analysis of individual cells clearly shows that cells of a similar size but from species of different ploidies have similar numbers of chloroplasts. We conclude that the number of chloroplasts within a cell is closely correlated (P<0.001) with the size of the cell and this relationship is consistent for species of different ploidies over a wide range of cell sizes. These results are discussed in relation to the hypothesis that chloroplast number in leaf mesophyll cells is determined by the size of the cell.     

Analysis and characterization of DCMU-resistant Euglena gracilis

Dark-grown, DCMU-adapted Euglena gracilis Z (ZR) are able to undergo light-induced chloroplast development in the presence or absence of DCMU. The differentiated chloroplasts are photosynthetically active and are resistant not only to DCMU, but also to an analog, o-phenanthrolene. When DCMU overdoses are added to ZR cells or to chloroplasts isolated from these cells, photosynthesis is partially inhibited. A brief period of darkness removes this inhibition. This recovery phenomenon is related to DCMU resistance, since it is not exhibited by non-resistant control cells. The chloroplast protein synthesis apparatus is not involved in DCMU resistance. Rather, this phenomenon is apparently related to new characteristics of thylakoids. It is shown that photosynthetic recovery by ZR cells depends on the accessibility and fluid properties of membranes. The analysis of fluorescence induction kinetics shows that changes in the environmental conformation of photosystem II units occur during recovery.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - ZR DCMU-adapted Euglena gracilis Z I and II=Calvayrac et al., in press (a, b)     

Chloroplast ultrastructure and fluorescence response of oilseed rape containing male-sterile radish cytoplasm

Summary The production of hybrid seed is facilitated if one parent possesses a male-sterile cytoplasm. Introduction of the cytoplasm of male-sterile radish (Raphanus sativus L.) into rapeseed (Brassica napus L.) results not only in transfer of the desirable male-sterile trait but induces a chlorophyll defect in the backcrossed male-sterile plants. In this study we show that the defect manifests itself in two different ways in the alloplasmic plants: a) smaller and fewer chloroplasts with an impaired ultrastructure and b) an increase in chlorophyll fluorescence. Defective chloroplasts were characterized by a reduction in both the number and size of grana, the latter due to poor stacking of thylakoids and with frequent discontinuity in the intergranal thylakoid systems. The changed chloroplast morphology and the increase in chlorophyll fluorescence are probably the cause of the lowered photosynthetic efficiency associated with the alloplasmic plants. We propose that the deficiency is the result of incompatibility between the genomes of the radish chloroplast and the rapeseed nucleus. Supporting this hypothesis are studies of male-sterile rapeseed plants in which, by protoplast fusion, the radish chloroplasts were substituted by those of normal male-fertile rapeseed. Such plants showed complete restoration of their photosynthetic potential and displayed both normal chloroplast ultrastructure and normal levels of chlorophyll fluorescence.     

Cytoplasmic reorganization accompanies the deposition of a bipolar cell wall in the large-celled red alga Anotrichium tenue

The filamentous red alga Anotrichium tenue C. Aghard (Naegeli) (formerly Griffithsia tenuis C. Aghard; Baldock, 1976, Aust. T. Bot. 24, 509–593) has large (1–2 mm long), cylindrical, multinucleate cells that exhibit a daily, cyclic redistribution of chloroplasts. Chloroplasts accumulate in the mid-region of each growing cell during the day; consequently, filaments appear banded with a light apical end-band, a dark mid-band and a light basal end-band in each growing cell. Chloroplasts disperse at night so that the bands are no longer visible and the cells appear evenly pigmented. Anotrichium tenue also has a type of cell elongation, known as bipolar band growth, in which new material is added to the microfibrillar part of the wall in bands located at the apical and basal poles of elongating cells. This site of wall growth corresponds to the position of the light-colored end-bands present during the day. Here we examine the structural relationship between the cytoplasmic bands and the wall-growth bands. Our results show that, in addition to the previously described bipolar wall bands, there is a non-microfibrillar wall band in the mid-region of the cell. This wall component apparently branches from near the top of the microfibrillar outer wall and terminates near but not at the bottom of the cell. It contains nodules of sulphated polysaccharide material secreted from a band of vesicles, which co-localize with the chloroplasts in the mid-band. The outer wall appears to enclose the entire cell. Nuclei do not redistribute with the chloroplasts or wall vesicles into the mid-band but remain evenly distributed throughout the cytoplasm. Each wall component grows by a different mechanism. We show that two types of wall growth, diffuse and the bipolar-type of tip growth, occur in the same cell and we propose that the observed segregation of the cytoplasm supports localized growth of the unique inner wall component. Additionally, we show that A. tenue is an excellent model for study of the role and mechanism of cytoplasmic compartmentalization and cell polarity during plant cell growth.We wish to thank Dr. Richard Cloney (University of Washington and Dr. Tom Schroeder (Friday Harbor Laboratories, Friday Harbor, Wash.) for helpful discussions and critical review of this work. We also thank Dr. Susan Waaland (University of Washington) for sharing her original observations on the chloroplast banding phenomenon in Anotrichium tenue. We are grateful to the Friday Harbor Laboratories for the use of their space and facilities. This research was supported by funds from the Washington Sea Grant Program (awarded to J.R.W.) and by the Developmental Biology Training Grant, predoctoral fellowship, National Institutes of Health, No. HD07183 to A.W.S.     

Comparative study of chloroplast morphology and ontogeny in <Emphasis Type="Italic">Asterochloris</Emphasis> (Trebouxiophyceae,Chlorophyta)

Confocal laser scanning microscopy was utilized to compare the chloroplast morphology and ontogeny among five strains of the green alga Asterochloris. Parsimony analysis inferred from the rDNA ITS sequences confirmed their placement in three distinct lineages: Asterochloris phycobiontica, Trebouxia pyriformis and Asterochloris sp. Examination by confocal microscopy revealed the existence of interspecific differences in the chloroplast ontogeny of Asterochloris; this was based upon either specific chloroplast structures observed in a single species, or on the differential timing of particular ontogenetic sequences. The occurrence of flat parietal chloroplasts prior to cell division, considered as a basic morphological discriminative character of Asterochloris, was clearly associated with the process of aplanosporogenesis. By contrast, chloroplast transformation prior to the formation of autospores proceeded simply by the multiple fission of the chloroplast matrix in the cell lumen. Presented at the International Symposium Biology and Taxonomy of Green Algae V, Smolenice, June 26–29, 2007, Slovakia.     

Chloroplast DNA of Acetabularia mediterranea: Cell cycle related changes in distribution

Chloroplast DNA (cpDNA) distribution in the giant unicellular, uninucleate alga Acetabularia mediterranea was analyzed with the DNA-specific fluorochrome 4'6-diamidino-2-phenylindole (DAPI) at various stages of the cell cycle. The number of chloroplasts exhibiting DNA/DAPI fluorescence changes during the cell's developmental cycle: (1) all chloroplasts in germlings contain DNA; (2) the number of plastids with DNA declines during polar growth of the vegetative cell; (3) it increases again prior to the transition from the vegetative to the generative phase; (4) several nucleoids of low fluorescence intensity are present in the chloroplasts of the gametes. The temporal distribution of the number of chloroplasts with DNA appears to be linked to the different mode of chloroplast division and growth during the various stages of development. The chloroplast cycle in relation to the cell cycle is discussed.Abbreviations cpDNA chloroplast DNA - DAPI 4,6-diamidino-2-phenylindole     

Giant chloroplast development in ethylene response1-1 is caused by a second mutation in ACCUMULATION AND REPLICATION OF CHLOROPLAST3 in Arabidopsis

The higher plants of today array a large number of small chloroplasts in their photosynthetic cells. This array of small chloroplasts results from organelle division via prokaryotic binary fission in a eukaryotic plant cell environment. Functional abnormalities of the tightly coordinated biochemical event of chloroplast division lead to abnormal chloroplast development in plants. Here, we described an abnormal chloroplast phenotype in an ethylene insensitive ethylene response1-1 (etr1-1) of Arabidopsis thaliana. Extensive transgenic and genetic analyses revealed that this organelle abnormality was not linked to etr1-1 or ethylene signaling, but linked to a second mutation in ACCUMULATION AND REPLICATION3 (ARC3), which was further verified by genetic complementation analysis. Despite the normal expression of other plastid division-related genes, the loss of ARC3 caused the enlargement of chloroplasts as well as the diminution of a photosynthetic protein Rubisco in etr1-1. Our study has suggested that the increased size of the abnormal chloroplasts may not be able to fully compensate for the loss of a greater array of small chloroplasts in higher plants.     

Response of ectomycorrhizalPinus banksiana andPicea glauca to heavy metals in soil

Pinus banksiana andPicea glauca inoculated or not with the ectomycorrhizal fungusSuillus luteus were grown in a sandy loam soil containing a range of Cd, Cu, Ni, Pb and Zn concentrations. Ectomycorrhizal colonization rates were significantly reduced on Pinus and Picea seedlings by the heavy metals, particularly Cd and Ni. Needle tissue metal concentrations were lower in ectomycorrhizal seedlings at low soil metal concentrations. However, at higher soil concentrations, heavy metal concentrations of needle tissue were similar in ectomycorrhizal and nonmycorrhizal plants. The growth of nonmycorrhizal seedlings exposed to heavy metals was reduced compared to those inoculated withSuillus luteus. Apparently ectomycorrhizal colonization can protect Pinus and Picea seedlings from heavy metal toxicity at low or intermediate soil concentrations of Cd, Cu, Ni, Pb and Zn.     

Analysis of nuclear and organellar DNA of somatic hybrid calli and plants between Lycopersicon spp. and Nicotiana spp.

Protoplast fusion experiments between Lycopersicon esculentum or L. peruvianum and Nicotiana tabacum or N. plumbaginifolia were performed to investigate the possibility of producing symmetric and asymmetric somatic hybrids between these genera. These fusions, which involved 1.7 × 10⁸ protoplasts, yielded 35 viable hybrid calli. Plant regeneration was successful with two calli. One of these regenerants flowered, but developed no fruits. Analysis of the nuclear DNA by means of dot blot hybridization with species-specific repetitive DNA probes combined with flow cytometry, revealed that the nuclei of most hybrid calli contained the same absolute amount of Nicotiana DNA as the Nicotiana parent or (much) less, whereas the amount of Lycopersicon DNA per nucleus was 2–5 times that of the parental genotype. Eighteen of the 34 hybrids analyzed possessed Lycopersicon chloroplast DNA (cpDNA), whereas the other 16 had DNA from Nicotiana chloroplasts. The cpDNA type was correlated with the nuclear DNA composition; hybrids with more than 2C Nicotiana nuclear DNA possessed Nicotiana chloroplasts, whereas hybrids with 2C or less Nicotiana nuclear DNA contained Lycopersicon chloroplasts. Mitochondrial DNA (mtDNA) composition was correlated with both nuclear DNA constitution and chloroplast type. Hybrids possessed only or mainly species-specific mtDNA fragments from the parent predominating in the nucleus and often providing the chloroplasts. The data are discussed in relation to somatic incompatibility which could explain the low frequency at which hybrids between Lycopersicon and Nicotiana species are obtained and the limited morphogenetic potential of such hybrids.     

Changes in chloroplast number during pea leaf development

Protoplasts were prepared from pea (Pisum sativum L.) leaves throughout development and their contents spread in a monolayer to determine the number of chloroplasts per cell. This approach permitted the rapid analysis of more than 100 cells at each stage of development. The average number of chloroplasts per cell increased from 24±10 to 64±20 during greening and expansion of the first true foliage leaves; all cells containing chloroplasts apparently increase their chloroplast number. A parallel increase in the amount of DNA per nucleus was not observed. As the leaves senesced the chloroplast number gradually decreased to 44±12. We have correlated these changes with our previous results on the percentage of chloroplast DNA per cell. Chloroplast multiplication resulted in a 2.7-fold dilution (from 272 to 102) of the number of copies of the chloroplast DNA molecule per plastid.