Separation and Ultrastructure of Proplastids from Dark-grown Euglena Cells

A procedure for the separation of proplastids free of mitochondria from dark-grown Euglena cells has been developed. A fraction enriched in proplastids was used for freeze-etching study of proplastid structure. The prolamellar body in freeze-etched replicas appeared sponge-like, with thylakoids, often vesicular, emerging from it. The prolamellar body and the thylakoids were covered by particles of about 100Å in diameter. No larger particles, typical of light-grown chloroplasts, were observed.     

CHLOROPLAST DEVELOPMENT IN THE GERMINATING SAFFLOWER (CARTHAMUS TINCTORIUS) COTYLEDON

Proplastids in the mesophyll cells of the cotyledons of mature seeds of safflower are irregular in shape and compressed in narrow corners between the large inclusion bodies, oil vacuoles and protein bodies. The proplastids contain a few irregular internal membranes. During dark germination, sheets or sac-like membranes are produced by the activity of the inner component of the proplastid envelope. These continuous membranes become reticulate and aggregate to the center of the proplastid to form after seven days' germination a quasicrystalline prolamellar body. The membranes are at first irregularly arranged and are of two sorts: those found in the interior of the developing prolamellar body, composed of laterally connected spherical profiles, and those on the periphery of the prolamellar body, which are continuous smooth sheets. The prolamellar body in these dark-germinated proplastids reverts after 3 hr of illumination to the irregularly arranged membranous structure of the 5-day dark germination stage. After 6 hr of illumination membranes grow from the prolamellar body forming concentric loops which, in cross section, appear as concentric circles. These membranes must be nested semi-spheroids. Small grana appear immediately on these looped membranes close to the prolamellar body. With further illumination additional grana develop along the looped membranes in close proximity to the slowly disappearing prolamellar body. Grana increase in size and number along the looped intergranal membranes. The prolamellar body disappears after 15 hr of illumination. The interconnecting fret membranes, sparse at the 15-hr stage, increase and after 24-hr illumination result in the typical grana fretwork system of the mature chloroplast. Membranes are continuously being produced by the invagination of the inner member of the plastid envelope.     

A Comparison between Prolamellar Bodies and Prothylakoid Membranes of Etioplasts of Dark-Grown Wheat Concerning Lipid and Polypeptide Composition

The aim of the present investigation was to find factors critical for the co-existence of prolamellar bodies and prothylakoids in etioplasts of wheat (Triticum aestivum L. cv Starke II). The lipid composition of the prolamellar body and prothylakoid fractions was qualitatively similar. However, the molar ratio of monogalactosyl diacylglycerol to digalactosyl diacylglycerol was higher in the prolamellar body fraction (1.6 ± 0.1), as was the lipid content on a protein basis. Protochlorophyllide was present in both fractions. The dominating protein of the prolamellar body fraction was protochlorophyllide oxidoreductase. This protein was present also in prothylakoid fractions. The other major protein of the prothylakoid fraction was the coupling factor 1, subunit of the chloroplast ATPase. From the lipid and protein data, we conclude that prolamellar bodies are formed when monogalactosyl diacylglycerol is present in larger amounts than can be stabilized into planar bilayer prothylakoid membranes by lamellar lipids or proteins.     

Entwicklung und Struktur der Proplastiden

In this study the proplastid development in embryonic cells is described for the apical meristem of Elodea canadensis, embryo sacs from Lilies, and Begonia leaf buds. The formation of these cell organelles originates with submicroscopical particles which consist of a homogeneous stroma with a surrounding double membrane. When these proplastids reach an average size of 1 µ, the inner layer of the membrane begins to invaginate into the stroma. This process is comparable to tubuli formation in mitochondria. Under growth conditions with sufficient exposure to light, the development of the grana and stroma lamellae proceeds without interruption. If the plants are kept in the dark, small vesicles are formed which accumulate in the prolamellar body of the proplastids. After illumination these elementary vesicles merge to form membranes which evolve into grana and stroma lamellae. The structural similarity of the early proplastid stages with the mitochondria seems to indicate that there exists some phylogenetic relationship between the two cell organelles.     

Plastid development in seedlings of Echinochloa crus-galli var. oryzicola under anoxic germination conditions

Plastid development in the primary leaf of Echinochloa crus-galli (L.) Beauv. var. oryzicola (Vasing.) Ohwi was followed during 5 d of anoxic germination and growth. Plastids develop slowly from simple spheroidal proplastids into larger pleomorphic plastids with several stromal membranes and many peripheral membrane vesicles. A small prolamellar body is present at 96 h with perforated (pro)thylakoids extending into the stroma. Changes in starch grains and plastoglobuli are evidence of carbohydrate and lipid metabolism. Plastid division is indicated by dumbbell plastid profiles after 4 d of anoxia. These results demonstrate that plastids not only maintain their integrity during anaerobic germination but also show developmental changes involving an increase in internal membrane complexity, although to a lesser extent than in etiolated shoots.Abbreviation PLB prolamellar body Scientific paper No. 6167. College of Agriculture, Washington State University, Pullman     

Developmental Physiology of Bean Leaf Plastids II. Negative Contrast Electron Microscopy of Tubular Membranes in Prolamellar Bodies

Proplastids and prolamellar bodies with tubular membranes were isolated from the dark grown primary leaves of bean seedlings (Phaseolus vulgaris L.). The combination of fluorescence microscopy and negative contrast electron microscopy provided the tentative identification of protochlorophyll holochrome as a constituent of prolamellar body membranes and new evidence for solution-filled channels within the tubular membrane systems of prolamellar bodies.     

Steroidal Saponins are not Main Building Units of the Prolamellar Body in Etioplasts

Sugar-containing lipids were analyzed by thin layer chromatographyin various cell fractions of etiolated Aoena leaves, Auena intactetioplasts and prolamellar bodies isolated from Cucurbita etioplasts.We confirmed the presence of steroidal saponins, avenacosidesA and B in etiolated leaves and crude etioplast fraction ofAvena, but scarcely detected them in Avena intact etioplastspurified by Percoll density gradient centrifugation. Saponinswere hardly detected in the paracrystalline prolamellar bodiesfrom Cucurbita etioplasts. We concluded that steroidal saponinsare not main building units of the prolamellar body in the etioplasts. (Received August 5, 1982; Accepted February 15, 1983)     

Osservazioni Citologiche Su Peschi Clorotici E Rinverditi in Seguito A Trattamenti Con Soluzioni Minerali

Abstract

A Cytological study of peach leaves, chlorotic or regreening after treatment with salt solutions. — Whitening and regreening (for treatment with solutions containing Fe) leaves of chlorotic (Fe deficient) peaches were examined both at the optical and the electron microscope. The nuclei, as seen at the optical microscope, and the plastids infrastructures of chlorotic leaves sharply differ from the same structure of the leaves of virused plants. The differentiation of plastids of peach chlorotic leaves is arrested at a very early stage comparable to that of proplastids in etiolated plants before a vescicolar body is formed. In peach plastids a prolamellar body is never formed, not even during the greening of plastids. This is a further confirmation that such a structure, although normal in etiolated and genetically variegated plants, does not represent a fixed stage during differentiation of the lamellar system.

The present observations put into evidence that, even when the formation of lamellae is not immediate, the formation of the prolamellar body is not a necessary condition for the further development of the lamellar apparatus.     

Chloroplast Development in Rye Coleoptiles

In the parenchyma cells of 1-d-old dark-grown rye coleoptiles (Secale cereale) proplastids occurred which sometimes contained starch grains. During coleoptile growth in darkness starch-filled amyloplasts are formed from the preexisting proplastids. No prolamellar bodies were observed in the stroma of the plastids of the etiolated coleoptile. After irradiation of 3-d-old etiolated coleoptiles with continuous white light three different types of plastids occurred. In the epidermal cells proplastids were observed. The parenchyma cells below the stomata of the outer epidermis (above the two vascular bundles) contained mature, spindle-shaped chloroplasts with a well-developed thylakoid system. In the parenchyma cells that surround the vascular bundles amyloplasts with some thylakoid membranes (chloroamyloplasts) occurred. The mesophyll cells of the primary leaves of dark-grown seedlings contained etioplasts with large prolamellar bodies. In the primary leaves of irradiated plants chloroplasts similar to those of the parenchyma cells of the coleoptile were observed. Our results show that the rye coleoptile, which grows underground as a heterotrophic organ, is capable of developing mature chloroplasts upon reaching the light above the soil surface. The significance of this expression of photosynthetic capacity for the carbon economy of the developing seedling is discussed.     

The ultrastructural development of plastids in leaves of maize plants exposed to continuous illumination

Summary Chloroplast differentiation in relation to increasing leaf age has been investigated in maize plants exposed to continuous illumination. In the young leaves the proplastids differentiate into chloroplasts containing well organized grana as well as prolamellar bodies. In the older leaves, while plastids differentiate, the prolamellar bodies are no longer detectable. Chloroplast ability to build up prolamellar bodies does not seems so much a light dependent process as it is affected by cell differentiation rate.Supported by a grant of C.N.R.     

A comparison of prolamellar bodies from wheat, Scots pine and Jeffrey pine. Pigment spectra and properties of protochlorophyllide oxidoreductase

Inner etioplast membrane fractions were isolated from wheat ( Triticum aestivum L. cv. Starkell), Scots pine ( Pinus sylvestris L.) and Jeffrey pine ( Pinus jeffreyi Murr), in order to investigate whether cotyledons of dark-grown conifers have protochlorophyllide associated to protochlorophyllide oxidoreductase (EC 1.6.99.–) in the pro-lamellar body in the same way as angiosperms. Protochlorophyllide was found to be present in dark-grown seedlings of Scots pine and Jeffrey pine to the same extent as in dark-grown wheat, 10–15.8 nmol (g fresh weight)⁻¹. Fluorescence emission spectra at 77 K showed accumulation of protochlorophyllide with emission maximum at 657 nm in the prolamellar body fractions of the three species studied. Also the light- and NADPH-dependent activity of protochlorophyllide oxidoreductase was consistently localized in the prolamellar body fractions. The three prolamellar body fractions were dominated by the same polypeptide. Its molecular weight was estimated to be 38 000 by sodium dodecylsulphate polyacrylamide gel electrophoresis.     

Localization of Galactolipid Biosynthesis in Etioplasts Isolated from Dark-Grown Wheat (Triticum aestivum L.)

Etioplasts were isolated from leaves of dark-grown wheat (Triticum aestivum L. var Starke II). Galactolipid biosynthesis was assayed in an envelope-rich fraction and in the fraction containing the rest of the etioplast membranes by measuring incorporation of ¹⁴C from uridine-diphospho[¹⁴C]galactose into monogalactosyl diacylglycerol and digalactosyl diacylglycerol. More than half of the galactolipid biosynthetic capability was found in the fraction of inner etioplast membranes. This fraction was subfractioned into fractions enriched in prolamellar bodies and membrane vesicles (prothylakoids), respectively. All membrane fractions obtained from etioplasts were able to carry out galactolipid biosynthesis, although the activity was very low in prolamellar body-enriched fractions. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed markedly different polypeptide patterns between the different fractions. It is concluded that the capability of galactolipid biosynthesis of etioplasts probably is not restricted to the envelope, but is also present in the inner membranes of this plastid.     

Isolation of Plastids from Sunflower Cotyledons during Germination

Plastids from cotyledons of sunflower (Helianthus annus L.) seedlings, germinated in the dark or in the light, were isolated by isopycnic sucrose density gradient centrifugation. At all stages of development the whole plastids contained triose phosphate isomerase, NADPH-glyoxylate reductase, and l-dihydroxyphenylalanine oxidase, which were used as marker enzymes. At the beginning of germination the isopycnic density of whole plastids (proplastids) was about 1.22 g cm⁻³. During development of proplastids into etioplasts in the dark, their isopycnic density increased to 1.26 g cm⁻³. During exposure of germinating seedlings to white light for 2 days, the isopycnic density of whole plastids decreased from 1.26 to 1.22 g cm⁻³. These changes in isopycnic density of plastids on sucrose density gradients are consistent with changes in the plastid ultrastructure caused by the protein-rich prolamellar body or by the lipid-rich thylakoids. Broken plastids (thylakoids), determined by the main peak of chlorophyll, increased in isopycnic density from less than 1.14 to about 1.17 g cm⁻³ during illumination. During germination no major changes occurred in the isopycnic density of mitochondria. Microbodies had an isopycnic density of 1.24 g cm⁻³ in very early stages of germination, and their density increased to 1.265 g cm⁻³, when glyoxysomal enzymes reached maximum development.     

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.     

CHANGES INDUCED BY LOW LIGHT INTENSITIES ON THE PROLAMELLAR BODY OF 8-DAY,DARK-GROWN SEEDLINGS

Etioplasts of 8-day-old, dark-grown seedlings of Phaseolus vulgaris contain large, crystalline prolamellar bodies. The basic structural unit within the prolamellar body is a six-pointed star (star module) with four tubules fusing at each of the nodes. With sufficient illumination some of the tubules are withdrawn and the crystalline prolamellar body transforms to a complex tangle of tubules, the reacted prolamellar body. In vivo spectrophotometry and electron microscopic observations were carried out on portions of the same leaves after varying periods of illumination with low light intensity. Protochlorophyllide transformation was normal. However, the structural changes are not closely tied to protochlorophyllide conversion. The pigment conversion is complete after 20 sec of illumination, but 80% of the prolamellar bodies are still in the crystalline form after 20 min of illumination. After 1 and 2 hr of illumination all prolamellar bodies are reacted. After 4 hr of continuous illumination 35%, and by 12 hr 60%, of the prolamellar bodies returned to the crystalline form. Spectrophotometric evidence and presence of grana show chlorophyll synthesis during this period. The coexistence of grana and the crystalline prolamellar body indicates that when insufficient photosynthetic membrane constituents are provided by the photo-reactions, under low light intensity, the membranes of the reacted prolamellar body will be forced to reform a crystalline prolamellar body.     

Prolamellar body transformation with increasing cell age in the maize leaf

Summary The fine structure of the plastids in the leaf's basal meristem and in the leaf tissues 2 cm immediately above has been studied in maize leaves of different ages. In the young leaves the proplastids of the basal meristem differentiate, in the tissues within 2 cm above the meristem, into chloroplasts containing two or more prolamellar bodies, indipendently whether the tissues have been fixed 11 hours after a period of illumination or of darkness. In the oldest leaves, in the tissues immediately above the basal meristem, no prolamellar body is present in the plastids, and the proplastids differentiate directly into chloroplasts, without passing through an etio-chloroplast stage.Supported by a grant of C.N.R.     

On the aggregational states of protochlorophyllide and its protein complexes in wheat etioplasts

The inner membranes from wheat ( Triticum aestivum L. cv. Walde) etioplasts were separated into membrane fractions representative of prolamellar bodies and prothylakoids by differential and gradient centrifugations. The isolated fractions were characterized by absorption-, low-temperature fluorescence-, and circular dichroism (CD) spectroscopy, by high performancy liquid chromatography and by sodium dodecyl sulphate polyacrylamide gel electrophoresis.
The prolamellar body fraction was enriched in NADPH-protochlorophyllide oxidoreductase (E.C. 1.6.99.1), and in protochlorophyllide showing an absorption maximum at 650 nm and a fluorescence emission maximum at 657 nm. Esterified protochlorophyllide was mainly found in the prothylakoid fraction. The carotenoid content was qualitatively the same in the two fractions. On a protein basis the carotenoid content was about three times higher in the prolamellar body fraction than in the prothylakoid fraction. The CD spectra of the membrane fractions showed a CD couplet with a positive band at 655 nm, a zero crossing at 643–644 nm and a negative band at 623–636 nm. These results differ from earlier CD measurements on protochlorophyllide holochrome preparations. The results support the interpretation that protochlorophyllide is present as large aggregates in combination with NADPH and NADPH-protochlorophyllide oxidoreductase in the prolamellar bodies.     

THE EFFECT OF 3-AMINO-1,2,4-TRIAZOLE ON THE ULTRASTRUCTURE OF PLASTIDS OF TRITICUM VULGARE SEEDLINGS

The application of sublethal doses of 3-amino-1,2,4-triazole (AT) to germinating, light-grown wheat grains causes chlorosis of the resulting leaves. An ultrastructural examination of the leaf tissue reveals that the plastids lack normal grana-fret membrane systems and chloroplast ribosomes. A few disorganized membranes are always present in these chloroplasts. However, AT-treated, dark-grown seedlings contain proplastids with non-crystalline prolamellar bodies and ribosomes. When these etiolated, treated plants are exposed to 600 ft-c light for various periods of time, the proplastids fail to develop into normal, grana-containing chloroplasts.     

Characterization of a Membrane Fraction Containing a b-type Cytochrome

The various components obtained from etiolated corn (Zea mays L.) coleoptiles were fractionated by differential or sucrose gradient centrifugation. The endoplasmic reticulum, proplastids, Golgi, and mitochondria were localized by enzymic or other markers in the various fractions. A fifth fraction was also characterized. It contains glucan synthetase II activity, binding sites for N-naphthylphthalamic acid, NADH dehydrogenase activity which is both antimycin A- and cyanide-insensitive, and a b-type cytochrome. It is possible that this fraction is plasma membrane and that it may contain the blue-ultraviolet photoreceptor for phototropism in corn.     

The polypeptide composition of highly purified prolamellar bodies and prothylakoids from wheat (Triticum aestivum) as revealed by silver staining

The inner membranes from wheat ( Triticum aestivum L. cv. Walde, Weibull) etioplasts were separated by density centrifugation. The etioplasts were broken by osmotic shock and the inner membranes were split by the sheering forces when pressed through a syringe needle. Membrane fractions representative of prolamellar bodies and prothylakoids, respectively, were achieved by separation on a 20–50% continuous sucrose density gradient followed by different purification procedures. The membrane contents of the isolated fractions were characterized by low temperature fluorescence spectra, sodium dodecyl sulphate polyacrylamide gel electrophoresis and electron micrographs. The prolamellar body and the prothylakoid fractions had a fluorescence emission ratio 657/633 nm of 18 and 0.9, respectively. The main part of the total amount of PChlide was found in the prolamellar body fraction. The electrophoretograms stained with Coomassie Blue showed the presence of mainly two polypeptides. The NADPH-protochlorophyllide oxidoreductase was the dominating polypeptide in the prolamellar body fraction, and the α and β subunits of the coupling factor 1 of chloroplast ATP synthase the dominating polypeptides in the prothylakoid fraction. Silver staining revealed at least 4 additional prominent bands with molecular weights of 86, 66, 34 and 28 kDa. The polypeptide composition of the prolamellar body is thus more complex than earlier judged after Coomassie Blue staining. The function of these polypeptides is unknown, but the knowledge of their presence is important in understanding the formation and function of the prolamellar body.