CHLOROPLAST DEVELOPMENT IN NICOTIANA TABACUM ‘MARYLAND MAMMOTH’

The development of chloroplasts in light-grown and in previously etiolated tissues of tobacco has been studied. A single membrane-bound body is found in the developing plastids of both light- and dark-grown tissue. The contents of the body appear homogeneous, becoming progressively granular as the chloroplast develops. In the mature chloroplast the body contains a fibrillar network resembling strands shown to be DNA by other workers. The prolamellar body persists even in moderately well developed chloroplasts in light-grown plants. Frequently the prolamellar body is connected to the membrane-bound body as well as to the grana. Relatively mature chloroplasts are seen to divide in this tissue. The membrane-bound body may have a role in the formation of lamellae, but the nature of its contents is yet to be determined.     

Chlorophyll Formation and Photosynthetic Competence in Euglena During Light-Induced Chloroplast Development in the Presence of 3, (3,4-dichlorophenyl) 1,1-Dimethyl Urea (DCMU)

The possibility that photosynthetic competence is gratuitous for light-induced chloroplast development in Euglena gracilis var. bacillaris was examined by incubating dark-grown resting cells in the light with DCMU, an inhibitor of photosynthesis. Under these conditions photosynthetic carbon dioxide fixation was inhibited essentially completely at all times during chloroplast development, but about 70% of the chlorophyll was formed with essentially the same pattern of accumulation found for cells incubated in the absence of the inhibitor. Electron microscopy of cells incubated with DCMU in the light revealed the formation of morphologically recognizable chloroplasts having comparable overall dimensions and structural elements to those found in normally developed chloroplasts, but frequently lacking a readily detectable pyrenoid with paramylum sheaths, and often containing increased numbers of discs per lamella. Such abnormalities are considered minor since upon removal of DCMU by centrifugation, the cells usually regained almost full photosynthetic competence on a chlorophyll basis.

It is concluded that photosynthetic competence is not necessary for chloroplast development in Euglena and supports the hypothesis, already suggested from other evidence, that light induction results in activation of synthetic machinery external to the developing chloroplast.

     

A comparison of light-dependent RNA metabolism in wild-type Euglena with that of mutants impaired for chloroplast development

Summary The possibility that ³²PO ₄ ^3- (³²P_i) labeling of both chloroplast and non-chloroplast RNAs during light-induced chloroplast development in Euglena is due, in part, to the break-down of existing RNAs and their resynthesis into labeled RNAs has been examined by comparing the RNA content of dark-grown, non-dividing cells after completion of light-induced chloroplast development with that of identical cells maintained in darkness for the same period of time. The involvement of the photo-conversion of protochlorophyll to chlorophyll and other photoreceptor systems in the labeling of RNA during chloroplast development has been considered by comparing the labeling pattern obtained with wild-type cells with the patterns obtained with mutants of Euglena which either lack detectable amounts of protochlorophyll and chlorophyll or form only rudimentary chloroplasts upon light induction.No significant difference in RNA content between dark-grown, non-dividing cells containing fully developed chloroplasts and the same cells maintained in darkness for the development period can be detected. This observation is interpreted to mean that in non-dividing cells precursors for chloroplast-associated RNAs are derived from pools and pre-existing RNAs, including non-chloroplast RNAs, and that the matebolic entrapment of ³²P_i involves a light-dependent turnover and DNA-directed RNA synthesis in wild-type cells.The RNA profiles on sucrose gradients of mutants of Euglena show no remarkable deviation from the profile established for wild-type cells. The labeling patterns obtained after 24 hours of incubation in light and in darkness differ from that obtained for wild-type cells in that all mutants show less of a light-minus-dark difference than wild-type and that mutants lacking plastid-associated DNA and detectable amounts of chlorophyll incorporate considerably more ³²P_i into RNA in darkness than wild-type. One such mutant shows no significant difference in its light-dark labeling pattern.These observations indicate that cells possessing normal proplastids capable of forming functional chloroplasts regulate metabolism of RNA in darkness in a different manner than with either rudimentary chloroplasts or containing no detectable plastids structures. The possible involvement of more than one photoreceptor system in metabolic control is discussed.Supported by a grant from the National Institutes of Health, GM 14595     

DEVELOPMENT OF THE DIMORPHIC CHLOROPLASTS OF SUGAR CANE

The vascular bundle sheath cells of sugar cane contain starch-storing chloroplasts lacking grana, whereas the adjacent mesophyll cells contain chloroplasts which store very little starch and possess abundant grana. This study was undertaken to determine the ontogeny of these dimorphic chloroplasts. Proplastids in the two cell types in the meristematic region of light-grown leaves cannot be distinguished morphologically. Bundle sheath cell chloroplasts in tissue with 50% of its future chlorophyll possess grana consisting of 2-8 thylakoids/granum. Mesophyll cell chloroplasts of the same age have better developed grana and large, well structured prolamellar bodies. A few grana are still present in bundle sheath cell chloroplasts when the leaf tissue has 75% of its eventual chlorophyll, and prolamellar bodies are also found in mesophyll cell chloroplasts at this stage. The two cell layers in mature dark-grown leaves contain morphologically distinct etio-plasts. The response of these two plastids to light treatment also differs. Plastids in tissue treated with light for short periods exhibit protrusions resembling mitochondria. Plastids in bundle sheath cells of dark-grown leaves do not go through a grana-forming stage. It is concluded that the structure of the specialized chloroplasts in bundle sheath cells of sugar cane is a result of reduction, and that the development of chloroplast dimorphism is related in some way to leaf cell differentiation.     

Effect of 4-Thiouridine on Photosystems of a Higher Plant

Effect of 4-thiouridine, which was proved to inhibit selectively and “light-reversibly” the synthesis of chloroplast ribosomal RNAs in radish cotyledons, on the photo-induced development of photosystem I, II and a complete electron transport chain was investigated with plastids obtained from 4-thiouridine treated dark-grown radish cotyledons after various times of development in the light. It was demonstrated that the 4-thioridine treated chloroplasts showed a higher activity of photoreduction than the control untreated chloroplasts in every system on a chlorophyll basis during the development after 24 hr illumination. This specific activity decreased in both chloroplasts, as the chloroplasts matured with the time of illumination. The activity per g of fresh cotyledons treated with 4-thiouridine, especially in the early stage of development, was lower than that of ones untreated with the drug because total chlorophyll content was poor, but the activity of the former was enhanced with the increase of total chlorophyll content upon illumination while the activity of the latter decreased on 24 hr illumination. Moreover, Hill reaction measurements showed that 4-thiouridine treated chloroplasts were saturated at lower light intensity than untreated ones inspite of the same content of chlorophyll in both the chloroplasts: photoreduction of NADP⁺ was saturated at 3000 lux for the former and at 5000 lux for the latter. Based upon these results, specific development of the chloroplast is discussed.     

Light regulated translational activators: identification of chloroplast gene specific mRNA binding proteins.

Genetic analysis has revealed a set of nuclear-encoded factors that regulate chloroplast mRNA translation by interacting with the 5' leaders of chloroplastic mRNAs. We have identified and isolated proteins that bind specifically to the 5' leader of the chloroplastic psbA mRNA, encoding the photosystem II reaction center protein D1. Binding of these proteins protects a 36 base RNA fragment containing a stem-loop located upstream of the ribosome binding site. Binding of these proteins to the psbA mRNA correlates with the level of translation of psbA mRNA observed in light- and dark-grown wild type cells and in a mutant that lacks D1 synthesis in the dark. The accumulation of at least one of these psbA mRNA-binding proteins is dependent upon chloroplast development, while its mRNA-binding activity appears to be light modulated in developed chloroplasts. These nuclear encoded proteins are prime candidates for regulators of chloroplast protein synthesis and may play an important role in coordinating nuclear-chloroplast gene expression as well as provide a mechanism for regulating chloroplast gene expression during development in higher plants.     

Two different modes of early development and nitrogen assimilation in gymnosperm seedlings†

Light-independent chloroplast development and expression of genes encoding chloroplast proteins occur in many but not all species of gymnosperms. Early development in maritime pine (Pinus pinaster) seedlings was strongly light-independent, whereas Ginkgo biloba seedlings exhibited a typical angiosperm-like morphogenesis with differentiated patterns in light and dark. In pine, chloroplast polypeptides were undetectable in the seed embryo and accumulated in cotyledons of both light- and dark-grown plants in good correlation with light-independent chlorophyll synthesis. In contrast, chlorophyll and chloroplast proteins were only detected in light-grown ginkgo. Pine cytosolic glutamine synthetase (GS) and ferredoxin glutamate synthase (Fd-GOGAT) were present at low levels in the seeds and accumulated at comparable amounts in light- and dark-grown seedlings. Fd-GOGAT was also barely detectable in the seeds of ginkgo and only accumulated in green plants with mature chloroplasts. In G. biloba seeds and etiolated plants only cytosolic GS was identified, while in light-grown seedlings this molecular form was present at low abundance and choroplastic GS was the predominant isoenzyme. The above results have been confirmed by immunolocalization of GS protein in pine and ginkgo plantlets. In pine, GS was present in the peripheral cytoplasm of mesophyll cells and also in the phloem region of the vascular bundle. Immunocytochemical analysis showed that the labelling of mesophyll and phloem cells was only cytoplasmic. In developing ginkgo, GS antigens were present in the chloroplasts of mesophyll parenchyma cells of leaflets and green cotyledons. In contrast, a weak labelling of GS was observed in the parenchyma and phloem cells of non-green cotyledons enclosed in the seed coat. Taking all this into account, our data indicate the existence of two different modes of GS and GOGAT regulation in gymnosperms in close correlation with the differential response of plants to light. Furthermore, the results suggest that glutamine and glutamate biosynthesis is confined to the chloroplast of mesophyll cells in species with light-dependent chloroplast, development whereas compartmentation would be required in species with light-independent plastid development.     

CHLOROPLAST DEVELOPMENT IN OCHROMONAS DANICA

When dark-grown cells of Ochromonas danica are placed in the light, the amount of chlorophyll a per cell increases 82-fold; the content of carotenoid pigment, 24-fold. Concomitantly with this increase in chlorophyll and carotenoid pigment, the small proplastid of dark-grown cells develops into a large lamellate chloroplast. During the first 12 hours in the light, vesicles appear within the loose clusters of dense chloroplast granules, enlarge, align themselves into rows (plates in three dimensions), and fuse into discs. Double discs may form from the more or less simultaneous fusion of two adjacent plates of vesicles or by the addition of vesicles to an already formed single disc. Three-disc bands arise by the addition of a disc to an already formed two-disc band through the approach and fusion of more vesicles. After 24 hours in the light, most of the chloroplast bands contain three discs, but the chloroplasts are still small. After 48 hours in the light, almost all the cells contain full-sized chloroplasts with a full complement of three-disc bands. However, at this time the amount of chlorophyll a and carotenoid pigment is only one-half of maximum. During the next 3 days in the light, as the number of chlorophyll and carotenoid molecules per chloroplast approximately doubles, there is a compression of the discs in each band (from 180 to 130 A) and a precise alignment of their membranes. Changes also occur in the nucleus when dark-grown cells are placed in the light. There is an increase in the number of small nucleolar bodies, many of which lie directly against the nuclear envelope, and in a few cells a dense mass of granules is seen between the two membranes of the nuclear envelope.     

DAG, a gene required for chloroplast differentiation and palisade development in Antirrhinum majus.

We have identified a mutation at the DAG locus of Antirrhinum majus which blocks the development of chloroplasts to give white leaves with green revertant sectors. The green areas contain normal chloroplasts whereas the white areas have small plastids that resemble proplastids. The cotyledons of dark-grown dag mutant seedlings have plastids which also resemble proplastids. The palisade cells in the white areas of dag mutant leaves also lack their characteristic columnar shape. The DAG locus was cloned by transposon tagging: DAG encodes a novel protein with a predicted Mr of 26k, which is targeted to the plastids. Cleavage of its predicted transit peptide gives a mature protein of Mr 20k. Screening of databases and analysis of Southern blots gave evidence that DAG belongs to a protein family with homology to several proteins of unknown function from plants. Expression of DAG is required for expression of nuclear genes affecting the chloroplasts, such as CAB and RBCS, and also for expression of the plastidial gene RPOB encoding the plastidial RNA polymerase beta subunit, indicating that it functions very early in chloroplast development.     

The hypocotyl chloroplast plays a role in phototropic bending of Arabidopsis seedlings: developmental and genetic evidence

Chloroplasts of guard cells and coleoptiles have been implicated in the sensory transduction of blue light. The present study was aimed at establishing whether the chloroplast of the hypocotyl from Arabidopsis, another blue light-responding organ, has similar characteristics to that of sensory-transducing guard cell and coleoptile chloroplasts. Results showed that the phototropic curvature and arch length induced by blue light in Arabidopsis seedlings matched the distribution of mature chloroplasts in the bending hypocotyl. The bending arch consistently included the region of the hypocotyl containing mature chloroplasts, and never extended beyond that region. Manipulation of the extent of greening of dark-grown hypocotyls by varying red light pretreatments elicited blue light-stimulated curvatures and arch lengths that depended on the duration of the red light pretreatment and on the distribution of mature chloroplasts in the hypocotyl. Albino psd2 mutants of Arabidopsis, which lack mature chloroplasts, are devoid of phototropic sensitivity under conditions in which wild-type seedlings show large curvatures. The star mutant of Arabidopsis has a delayed greening and a delayed phototropic response as compared with wild type. Measurements of photosynthetic oxygen evolution and carbon fixation, dark respiration, and light-dependent zeaxanthin formation in the hypocotyl showed features similar to those of guard cells and coleoptiles, and distinctly different from those of mesophyll tissue. These results indicate that the hypocotyl chloroplast has characteristics similar to those associated with guard cell and coleoptile chloroplasts, and that phototropic bending of Arabidopsis hypocotyls appears to require mature chloroplasts.     

Events Surrounding the Early Development of Euglena Chloroplasts: 14. Biosynthesis of Cytochrome c-552 in Wild Type and Mutant Cells

Lack of a suitable assay has thwarted attempts to measure cytochrome c-552 in dark-grown wild type cells of Euglena gracilis var. bacillaris in mutants and in other situations where the concentrations are low. Purification methods are described based on electrofocusing which provide a cytochrome c-552 preparation homogeneous enough to elicit a single reactive antibody in rabbits; this antibody is then used as a specific and sensitive assay for cytochrome c-552. Dark-grown cells of wild type and of mutants O₁BS, O₂BX, G₁BU and P₁BXL (which make normal sized chloroplasts with abnormal internal structure in the light) have 0.02 to 0.1 × 10⁻¹¹ micromoles of cytochrome c-552 per cell, 10 to 150 times less than light-grown cells. Light-grown cells of these mutants and of wild type show a ratio of chlorophyll to cytochrome of about 300 (mole to mole). Cytochrome c-552 is undetectable in dark-grown Y₁BXD, Y₃BUD, and W₃₄ZUD which cannot carry plastid development beyond the proplastid in light; the light-grown cells of these mutants have levels of cytochrome similar to or lower than dark-grown wild type cells. Cytochrome c-552 is undetectable in light- and dark-grown mutants in which plastid DNA is undetectable (such as Y₂BUL, W₃BUL, W₈BHL, and W₁₀BSmL) consistent with the view, but not proving, that this molecule may be coded, at least in part, in plastid DNA. During light-induced chloroplast development in resting cells, cytochrome c-552 formation behaves in all respects like chlorophyll except that the dark-grown cells contain low amounts of the cytochrome c-552 but lack chlorophyll. Thus, both cytochrome c-552 and chlorophyll show the same lag period even when the length is changed by nutritional manipulation; preillumination largely eliminates the lag in the formation of both molecules, cycloheximide and streptomycin both inhibit the biosynthesis of chlorophyll and cytochrome c-552 in the same manner, and the formation of both during chloroplast development is strictly light-dependent. It is shown that chloroplasts isolated from Euglena by methods thought to give intact organelles, lack 95% of the cytochrome c-552; this and the loss of similar molecules may explain why these isolated chloroplasts are not photosynthetically active.     

Loss of chloroplastic DNA in a Euglena mutant during growth in darkness

The mutant strain U of Euglena gracilis, different from the wild type strain Z, has lost the ability to form chloroplasts during growth in the dark.Chloroplastic DNA could not be detected by CsCl density analysis in the dark-grown strain U. Chloroplast nucleoids fluoro-stained by DAPI were found in the light-grown cells, but not in the dark-grown U. Target number analysed by UV irradiation on the chloroplast formation ability decreased rapidly during cell-growth in darkness. These results suggest that U has lost plastid DNA during cell-growth in darkness.Abbreviations DAPI 4,6-diamidino-2-phenylindole - PSI and PSII photosystems I and II - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

Development of chloroplast structure and photosynthetic competence in dark-adapted moss protonemata after exposure to light

Summary Sporelings and protonemata ofCeratodon purpureus were grown in darkness for one to two months. On their exposure to light, starch was observed after 30 minutes but only minor changes occurred in the chloroplast structure during the first hours. After one day in light, the chloroplasts had a structure similar to that of the chloroplasts of light-grown material. The dark-grown material evolved oxygen and assimilated CO₂ readily after exposure to light. Nevertheless, maximization of the photosynthetic rate was not achieved until the second day in light, coinciding with the development of light-type chloroplasts. The ultrastructural localization of photosystems I and II revealed much higher activity of PS I in dark-adapted material than in material grown in light, whereas the activity of PS II appeared to be greater in light-grown material.     

Immunogold localization of a transglutaminase related to grana development in different maize cell types

Summary A comparative study of the subcellular localization of a plant transglutaminase (TGase; EC 2.3.2.13) in various in vivo and in vitro maize cell types was carried out with a polyclonal antibody raised against a 58 kDa TGase purified fromHelianthus tuberosus leaves. Immunocytochemical staining, followed by electron microscopy, showed that this enzyme was markedly present in the grana-appressed thylakoids of mature chloroplasts of the lightexposed cells. Moreover, during embryogénie callus chloroplast differentiation, the abundance of TGase in the grana-appressed thylakoids depended on the degree of grana development and was greater than in mature leaf chloroplasts. In addition to the 58 kDa form, two other forms of the protein (of 77 and 34 kDa) were obtained by Western blot. The 77 kDa form might correspond to the inactive form and was immunodetected in dense vesicles observed in dark-grown embryogenie callus cells. In adult leaves, the enzyme was also markedly present in the grana-appressed thylakoids of the mesophyll cell chloroplasts, though very scarce and dispersed in the bundle-sheath cell chloroplasts (which do not contain grana). The concordance of these localizations with those described for the light-harvesting antenna proteins of the photosystem II suggests that it is possible that this TGase has a functional role in photosynthesis, perhaps modulating the photosynthetic efficiency and the absorption of excess light by means of polyamine conjugation to the antenna proteins.     

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.     

A coupling factor for photosynthetic phosphorylation from plastids of light- and dark-grown maize

1. Maize chloroplasts contain a trypsin-, dithiothreitol-, and Ca²⁺-activated ATPase. This enzyme, which can serve as a coupling factor for photosynthetic phosphorylation, differs slightly in a few properties but in general resembles a similar one in spinach plastids which was described earlier by others.

2. Maize etioplasts (immature plastids in dark-grown plants) also contain this ATPase, and it is shown that NaCl-EDTA extracts of etioplasts can restore photosynthetic phosphorylation activity to depleted green membranes of chloroplasts.

3. Electron microscopy of maize etioplast and chloroplast membranes demonstrates the presence of protruding knobs, approx. 90 Å in diameter. Removal and reassociation of knobs with membranes can be correlated with the ability to carry on photosynthetic phosphorylation.

4. Most or possibly all of the coupling factor (measured as ATPase) activity of a chloroplast may be present in the etioplast from which it develops. The photosynthetic membrane of the chloroplast can be formed in stages.

5. The significance of these observations is discussed with regard to membrane formation in general and plastid membrane development in particular.