Physicochemical properties and development of wheat large and small starch granules during endosperm development

Wheat mature seeds have large, lenticular A-type starch granules, and small, spherical B-type and irregular C-type starch granules. During endosperm development, large amyloplasts came from proplastid, divided and increased in number through binary fission from 4 to 12 days after flowering (DAF). Large starch granules formed and developed in the large amyloplast. One large amyloplast had only one large starch granule. Small amyloplasts came from the protrusion of large amyloplast envelope, divided and increased in number through envelope protrusion after 12 DAF. B-type starch granules formed and developed in small amyloplast from 12 to 18 DAF, C-type starch granules formed and developed in small amyloplast after 18 DAF. Many B- and C-type starch granules might form and develop in one small amyloplast. The amyloplast envelopes were asynchronously degraded and starch granules released into cell matrix when amyloplasts were full of starch granules. Apparent amylose contents of large starch granules were higher than that of small starch granules, and increased with endosperm development. The swelling powers and crystallinity of large starch granule were lower than that of small starch granules, and decreased with endosperm development. Small starch granules displayed broader gelatinization temperature ranges than did large starch granules.     

绞股蓝正常茎转变为根状茎的形态结构和内源激素含量变化

绞股蓝(Gynostemma pentaphyllum)茎端具有在秋季钻入土中发育为根状茎以越冬和增殖的现象。观察绞股蓝根状茎的形成过程及其组织结构特点,并检测根状茎不同发育阶段和不同节段的内源激素含量。结果表明,正常茎端首先发育为膨大的变态茎并钻入土中,在土中发育成根状茎并进行增殖,腋芽或侧枝的增殖倍数为2.28,来春可萌发出多株新苗。正常芽、变态茎和根状茎的基本结构相似,但后两个阶段的淀粉鞘细胞、髓和髓射线细胞中含有丰富的淀粉粒。生长素、赤霉素和茉莉酸的含量在正常茎端中最高,变态茎端次之,根状茎最低。三种激素在各茎端从芽尖段、弯曲段、膨大段至稳定段的含量总体表现为先升后降趋势。三种激素在变态茎的弯曲段含量明显升高,并在膨大段达到最高值,而生长素在根状茎的弯曲段含量最高,反映它们对相应节段发育的促进作用。     

Amyloplast Size and Number in Gravity-compensated Oat Seedlings

Gravity compensation by the horizontal clinostat increases the diameter of amyloplast starch grains of oat (Avena sativa cv. Victory) coleoptile parenchyma cells, as compared to vertically rotated and stationary controls. In dark-grown coleoptile tip parenchyma cells, measured starch grain sizes exhibit a wide distribution of diameters, from approximately 1.5 to approximately 8.0 mum, but fall into three prominent diameter classes. The compensated tissues from both the tip and the subapical region have more starch grains in the larger, and fewer in the smaller size classes, compared to controls. The total number of starch grains per cell, the total plastid number per cell, and cell volume are unaffected by gravity compensation. Amyloplasts with large starch grains are denser, as well as larger in diameter, than those with smaller starch grains. The amyloplast is considered as a geosensor with an active metabolic role in the geotropic transduction mechanism.     

Identification of the maize amyloplast stromal 112-kD protein as a plastidic starch phosphorylase

Amyloplast is the site of starch synthesis in the storage tissue of maize (Zea mays). The amyloplast stroma contains an enriched group of proteins when compared with the whole endosperm. Proteins with molecular masses of 76 and 85 kD have been identified as starch synthase I and starch branching enzyme IIb, respectively. A 112-kD protein was isolated from the stromal fraction by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and subjected to tryptic digestion and amino acid sequence analysis. Three peptide sequences showed high identity to plastidic forms of starch phosphorylase (SP) from sweet potato, potato, and spinach. SP activity was identified in the amyloplast stromal fraction and was enriched 4-fold when compared with the activity in the whole endosperm fraction. Native and sodium dodecyl sulfate-polyacrylamide gel electrophoresis analyses showed that SP activity was associated with the amyloplast stromal 112-kD protein. In addition, antibodies raised against the potato plastidic SP recognized the amyloplast stromal 112-kD protein. The amyloplast stromal 112-kD SP was expressed in whole endosperm isolated from maize harvested 9 to 24 d after pollination. Results of affinity electrophoresis and enzyme kinetic analyses showed that the amyloplast stromal 112-kD SP preferred amylopectin over glycogen as a substrate in the synthetic reaction. The maize shrunken-4 mutant had reduced SP activity due to a decrease of the amyloplast stromal 112-kD enzyme.     

Characterization of ADP-glucose transport across the cereal endosperm amyloplast envelope

Most of the carbon used for starch biosynthesis in cereal endosperms is derived from ADP-glucose (ADP-Glc) synthesized by extra-plastidial AGPase activity, and imported directly across the amyloplast envelope. The properties of the wheat endosperm amyloplast ADP-Glc transporter were analysed with respect to substrate kinetics and specificities using reconstituted amyloplast envelope proteins in a proteoliposome-based assay system, as well as with isolated intact organelles. Experiments with liposomes showed that ADP-Glc transport was dependent on counter-exchange with other adenylates. Rates of ADP-Glc transport were highest with ADP and AMP as counter-exchange substrates, and kinetic analysis revealed that the transport system has a similar affinity for ADP and AMP. Measurement of ADP and AMP efflux from intact amyloplasts showed that, under conditions of ADP-Glc-dependent starch biosynthesis, ADP is exported from the plastid at a rate equal to that of ADP-Glc utilization by starch synthases. Photo-affinity labelling of amyloplast membranes with the substrate analogue 8-azido-[alpha-32P]ADP-Glc showed that the polypeptide involved in substrate binding is an integral membrane protein of 38 kDa. This study shows that the ADP-Glc transporter in cereal endosperm amyloplasts imports ADP-Glc in exchange for ADP which is produced as a by-product of the starch synthase reaction inside the plastid.     

Amyloplast formation in cultured tobacco cells; effects of plant hormones on multiplication, size, and starch content

In BY-2 cultured tobacco cells (Nicotiana tabacum L.), depletion of 2,4-dichlorophenoxyacetic acid (2,4-D) and addition of benzyladenine (BA) caused amyloplast formation, a decrease in cell multiplication, and an increase in cell size. These changes were primarily triggered by the depletion of 2,4-D, and facilitated by the addition of BA. An increase in the starch content of BY-2 cells was always accompanied by a reduction in cell multiplication. However, when hormonal conditions were unsuitable for amyloplast formation, the starch content of the cells did not increase, even if cell multiplication was forcibly terminated by the addition of aphidicolin. This result indicates that the hormonal conditions themselves, and not the decrease in cell multiplication, induce amyloplast formation in BY-2 cultured tobacco cells.Abbreviations BA benzyladenine - 2,4-D 2,4-dichlorophenoxyacetic acid - DAPI 4,6-diamidino-2-phenylindole - DMSO dimethyl sulfoxide - NAA 1-naphthylacetic acid - PMSF phenyl methyl sulfonyl fluoride     

Molecular analysis of SCARECROW function reveals a radial patterning mechanism common to root and shoot

Mutation of the SCARECROW (SCR) gene results in a radial pattern defect, loss of a ground tissue layer, in the root. Analysis of the shoot phenotype of scr mutants revealed that both hypocotyl and shoot inflorescence also have a radial pattern defect, loss of a normal starch sheath layer, and consequently are unable to sense gravity in the shoot. Analogous to its expression in the endodermis of the root, SCR is expressed in the starch sheath of the hypocotyl and inflorescence stem. The SCR expression pattern in leaf bundle sheath cells and root quiescent center cells led to the identification of additional phenotypic defects in these tissues. SCR expression in a pin-formed mutant background suggested the possible origins of the starch sheath in the shoot inflorescence. Analysis of SCR expression and the mutant phenotype from the earliest stages of embryogenesis revealed a tight correlation between defective cell divisions and SCR expression in cells that contribute to ground tissue radial patterning in both embryonic root and shoot. Our data provides evidence that the same molecular mechanism regulates the radial patterning of ground tissue in both root and shoot during embryogenesis as well as postembryonically.     

Starch content and distribution in excised watermelon cotyledons treated with benzyladenine

We have examined the effect of benzyladenine (BA) on amyloplast number and distribution in semithin cross-sections of excised watermelon ( Citrullus vulgaris Schrad ., cv. Fairfax) cotyledons grown in the dark. The sections were stained with Lugol solution and observed with an immersion objective. In control cotyledons, amyloplasts were always more abundant and contain more starch grains than in BA-treated cotyledons. The higher starch content was correlated with a higher ratio between starch synthetase (EC 2.4.1.21) and amylase (EC 3.2.1.1) activities in the controls. In the central zone of the mesophyll, the amyloplasts contained more starch grains than in the abaxial and adaxial (palisade) zones. The average number of amyloplasts per cell was different in the three zones, and followed a different time course in control and treated cotyledons. BA decreased this number, particularly in the adaxial zones. Our data seem to indicate a different function of starch in the central and in adaxial zone of the mesophyll. In the central zone starch is probably used as a source of carbohydrates for export to the embryo axis, while in the adaxial zone, where the transformation from amyloplast to etioplast is particularly pronounced, starch may be a reserve for organelle differentiation. BA stimulates the utilization of starch for both functions.     

STARCH GRANULE (AMYLOPLAST) DEVELOPMENT IN ENDOSPERM OF SEVERAL ZEA MAYS L. GENOTYPES AFFECTING KERNEL POLYSACCHARIDES

Endosperm cell and starch granule (amyloplast) development of six maize (Zea mays L.) genotypes, normal, amylose-extender (ae), sugary (su), waxy (wx), amylose-extender sugary (ae su), and amylose-extender waxy (ae wx), was compared. Endosperms of all genotypes were indistinguishable at 14 days after pollination. Cells were highly vacuolated and those in the central crown area of the kernel contained small starch granules in close association with the nucleus. Cellular and nuclear enlargement occurred during endosperm development in all genotypes, and major and minor gradients in physiological age of endosperm cells were observed in all kernels. Amyloplast development varied with genotype. Plastid development in normal and wx cells was characterized by an initial starch granule formation followed by granule enlargement to cell maturity. Endosperms homozygous for ae (ae, ae su, and ae wx) developed abnormal plastid-granules. Secondary granule formations preceded development of abnormality in ae and ae su, but not in ae wx endosperms. In contrast to ae and ae su starch granules, ae wx granules were highly birefringent indicating a high degree of crystallinity. In all three ae genotypes, abnormality increased as a function of kernel and physiological cell age. The su mutant had two distinct effects on amyloplast development. First, a mobilization of the initially formed starch, and second a synthesis and accumulation of phytoglycogen and the formation of large rounded plastids. In ae su plastid development, there was a mobilization of the starch initially formed (resulting in irregularly shaped, nonbirefringent granules) but only small amounts of phytoglycogen were produced.     

Amyloplast development in etiolated and ethylene-treated pea epicotyls

The amyloplasts found in the apical hook cells of etiolated pea (Pisum sativum L.) epicotyls were randomly distributed. Sedimentation of endodermal amyloplasts in the direction of gravity became apparent in the transition from the hook to the top of the main axis of the epicotyl. Cortical amyloplasts in this region were not, however, sedimented. These patterns of sedimentation could not be related to changes in amyloplast size, and it is proposed that cytoplasmic properties determine amyloplast behaviour.The differentiation of plastids in the hook differed between the amyloplast-containing endodermal cells and the cortical cells, in which amoeboid plastids predominated over amyloplasts. Amyloplasts disappeared from the cortical cells in the main axis of the epicotyl, but in the endodermal cells sedimented amyloplasts were found throughout the upper epicotyl.Etiolated epicotyls induced to grow horizontally by treatment with ethylene had a normal content of amyloplasts, sedimented in the direction of gravity.     

Leaf Abscission in Soybean: Cytochemical and Ultrastructural Changes following Benzylaminopurine Treatment

6-benzylaminopurine (BAP) delays leaf abscission of soybeanGlycine max (L.) Merr. Abscission of the distal pulvinus ofprimary leaves was induced in 12-d-old seedlings or explantsby removal of the leaf blade. BAP applied to the cut end ofthe pulvinus following leaf blade removal delayed abscission.Discoloration of the pulvinus occurred before abscission commencedand the number of grana in chloroplasts within cortical parenchymacells of the pulvinus decreased over time following leaf bladeremoval. BAP prevented discoloration of pulvinus tissues anda decrease in grana number. Starch grains within amyloplastsof cells of the starch sheath in the pulvinus disappeared followingleaf blade removal, whereas starch accumulated within the abscissionzone prior to abscission. BAP prevented this apparent redistributionof starch and instead promoted an increase in starch withinplastids of cortical parenchyma cells of the pulvinus. Duringthe abscission process, cells within the separation layer enlargedand their nuclei and nucleoli became more evident prior to theirseparation from one another. Cell separation resulted from breakdownof middle lamellae and partial degradation of primary cell walls.Cycloheximide applied directly to the external surface of theabscission zone inhibited abscission in a similar way to theBAP treatment. These results suggest that BAP prevents abscissionby altering patterns of starch distribution in the pulvinusand abscission zone and by inhibiting the synthesis of proteinsthat typically appear de novo in induced abscission zone tissues. Key words: Benzylaminopurine, BAP, Soybean, Pulvinus, Abscission, amyloplast.     

The amyloplast proteome of potato tuber

Potato (Solanum tuberosum) is the fourth largest crop worldwide in yield, and cv. Kuras is the major starch potato of northern Europe. Storage starch is packed densely in tuber amyloplasts, which become starch granules. Amyloplasts of soil-grown mini-tubers and agar-grown micro-tubers of cv. Kuras were purified. The mini-tuber amyloplast preparation was enriched 10-20-fold and the micro-tuber amyloplast approximately fivefold over comparative total protein extracts. Proteins separated by SDS-PAGE were digested with trypsin, analysed by mass spectrometry and identified by mascot software searches against an in-house potato protein database and the NCBI non-redundant plant database. The differential growth conditions for mini- and micro-tubers gave rise to rather different protein profiles, but the major starch granule-bound proteins were identical for both and dominated by granule-bound starch synthase I, starch synthase II and alpha-glucan water dikinase. Soluble proteins were dominated by starch phosphorylase L-1, other large proteins of the classes 'starch and sucrose metabolism', 'pentose phosphate pathway', 'glycolysis', 'amino acid metabolism', and other proteins such as plastid chaperonins. The majority of the identified proteins had a predicted plastid transit peptide, supporting their presence in the amyloplast. However, several highly expressed proteins had no transit peptide, such as starch phosphorylase H, or had a predicted mitochondrial location. Intriguingly, all polyphenol oxidases, a family of enolases, one transketolase, sulfite reductase, deoxynucleoside kinase-like and dihydroxy-acid dehydrase had twin-arginine translocation motifs, and a homologue to dihydrolipoamide dehydrogenase had a Sec (secretory) motif; these motifs usually target thylakoid-like structures.     

Cytoplasmic pH dynamics in maize pulvinal cells induced by gravity vector changes

In maize (Zea mays) and other grasses, changes in orientation of stems are perceived by pulvinal tissue, which responds to the stimulus by differential growth resulting in upward bending of the stem. The amyloplast-containing bundle sheath cells are the sites of gravity perception, although the initial steps of gravity perception and transmission remain unclear. In columella cells of Arabidopsis roots, we previously found that cytoplasmic pH (pH(c)) is a mediator in early gravitropic signaling (A.C. Scott, N.S. Allen [1999] Plant Physiol 121: 1291-1298). The question arises whether pH(c) has a more general role in signaling gravity vector changes. Using confocal ratiometric imaging and the fluorescent pH indicator carboxy seminaphtorhodafluor acetoxymethyl ester acetate, we measured pH(c) in the cells composing the maize pulvinus. When stem slices were gravistimulated and imaged on a horizontally mounted confocal microscope, pH(c) changes were only apparent within the bundle sheath cells, and not in the parenchyma cells. After turning, cytoplasmic acidification was observed at the sides of the cells, whereas the cytoplasm at the base of the cells where plastids slowly accumulated became more basic. These changes were most apparent in cells exhibiting net amyloplast sedimentation. Parenchyma cells and isolated bundle sheath cells did not show any gravity-induced pH(c) changes although all cell types responded to external stimuli in the predicted way: Propionic acid and auxin treatments induced acidification, whereas raising the external pH caused alkalinization. The results suggest that pH(c) has an important role in the early signaling pathways of maize stem gravitropism.     

Identification of a homolog of Arabidopsis DSP4 (SEX4) in chestnut: its induction and accumulation in stem amyloplasts during winter or in response to the cold

Oligosaccharide synthesis is an important cryoprotection strategy used by woody plants during winter dormancy. At the onset of autumn, starch stored in the stem and buds is broken down in response to the shorter days and lower temperatures resulting in the buildup of oligosaccharides. Given that the enzyme DSP4 is necessary for diurnal starch degradation in Arabidopsis leaves, this study was designed to address the role of DSP4 in this seasonal process in Castanea sativa Mill. The expression pattern of the CsDSP4 gene in cells of the chestnut stem was found to parallel starch catabolism. In this organ, DSP4 protein levels started to rise at the start of autumn and elevated levels persisted until the onset of spring. In addition, exposure of chestnut plantlets to 4 °C induced the expression of the CsDSP4 gene. In dormant trees or cold-stressed plantlets, the CsDSP4 protein was immunolocalized both in the amyloplast stroma and nucleus of stem cells, whereas in the conditions of vegetative growth, immunofluorescence was only detected in the nucleus. The studies indicate a potential role for DSP4 in starch degradation and cold acclimation following low temperature exposure during activity-dormancy transition.     

Sucrose-Starch Conversion in Heterotrophic Tissues of Plants

The historical progress in recent years pertaining to the sucrose-starch conversion in heterotrophic tissues of plants has been described. Special attention has been focused on the enzymatic breakdown of sucrose to produce hexose units that are transported to the amyloplast compartment by means of specific translocator molecules and act as glucose donors for starch biosynthesis. Although the current prevailing view is that variable mechanisms operate in different plant tissues and organs, it is often argued that the following enzymic steps are essential in the overall step of sucrose to starch conversion: sucrose + UDP -> UDPGlc + Fru(sucrose synthase-SS) (UDPGlc UDPGlc + PPi -» G1P + UTPpyrophosphorylase-UGPase) (ADPGlc GlP + ATP -» ADPGlc + PPipyrophosphorylase-AGPase) (starch ADPGlc -> starchsynthase) The presence of an ADPGlc-specific translocator in the amyloplast envelope has been demonstrated in a number of plant sources, which indicates the potential role of ADPGlc-synthesizing machineries located in the cytosol of starch-storing cells. Although it was initially believed that AGPase is present exclusively in the amyloplast compartment, the presence of a cytosolic enzyme has been shown in some cereals. The SS has a potential to produce ADPGlc, but the general belief is that this is not a dominant reaction in the mechanism of starch biosynthesis. Numerous experimental trials have been reported by many scientists employing transgenic plants transformed with cDNAs either in antisense- or sense- orientation encoding enzymes which are presumably involved in the process of sucrose-starch conversion. Although great caution is needed to interpret the data obtained, the general picture is contradictory to the mechanism presented above. It now appears that serious reconsideration is needed for the possible mechanism of SS-catalyzed ADPGlc formation and its subsequent link to starch formation. In the newly proposed mechanistic scheme, which appears to be consistent with the results by other scientists as well, hexokinase, phosphoglucomutase (PGM), and ADPGlc formation by AGPase are components in the cyclic turnover of starch molecules in the amyloplast compartment.     

Development of Plastids in Pollen and Tapetum of Rye-grass, Lolium perenne L

Proplastids of both tapetal cells and microsporocytes were presentearly in anther development. Tapetal proplastids differentiated—probablyinto elaioplasts—at late microspore stage. The tapetalcytoplasm was completely resorbed by early tricellular pollenstage. Microspore proplastids differentiated into amyloplastsat early bicellular stage, and were present in both vegetativeand generative cells. In the generative cell, the amyloplastswere ephemeral and apparently degenerated within autophagicvacuoles. Plastids were absent from sperm cells. Vegetativecell amyloplasts increased in number apparently by fission suchthat one amyloplast produced one amyloplast and one proplastidper division. Mature pollen grains were estimated to containbetween 550 and 820 amyloplasts with only one starch granuleper plastid. Elaioplasts, amyloplasts, plastid division, plastid differentiation, starch granules, autophagy, Lolium perenne, Poaceae, rye-grass     

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.