Brittle-1, an Adenylate Translocator, Facilitates Transfer of Extraplastidial Synthesized ADP-Glucose into Amyloplasts of Maize Endosperms

Amyloplasts of starchy tissues such as those of maize (Zea mays L.) function in the synthesis and accumulation of starch during kernel development. ADP-glucose pyrophosphorylase (AGPase) is known to be located in chloroplasts, and for many years it was generally accepted that AGPase was also localized in amyloplasts of starchy tissues. Recent aqueous fractionation of young maize endosperm led to the conclusion that 95% of the cellular AGPase was extraplastidial, but immunolocalization studies at the electron- and light-microscopic levels supported the conclusion that maize endosperm AGPase was localized in the amyloplasts. We report the results of two nonaqueous procedures that provide evidence that in maize endosperms in the linear phase of starch accumulation, 90% or more of the cellular AGPase is extraplastidial. We also provide evidence that the brittle-1 protein (BT1), an adenylate translocator with a KTGGL motif common to the ADP-glucose-binding site of starch synthases and bacterial glycogen synthases, functions in the transfer of ADP-glucose into the amyloplast stroma. The importance of the BT1 translocator in starch accumulation in maize endosperms is demonstrated by the severely reduced starch content in bt1 mutant kernels.     

Btl, a structural gene for the major 39–44 kDa amyloplast membrane polypeptides

The aim of the present work was to investigate the relationship between the Btl gene (Btl) and the major 39–44 kDa amyloplast membrane polypeptides which were deficient in amyloplast membranes of brittlel (btl) kernels of maize (Zea mays L.). A rapid yet gentle procedure for the isolation of amyloplasts from immature kernels is described. These amyloplasts were relatively free of contamination by other cellular components, and immunological studies showed that they contained polypeptides which reacted with antibodies to maize starch branching enzyme and ADP-Gle pyrophosphorylase. Purified membranes isolated from the amyloplast contained a poly-peptide which reacted with antibodies to the P_i-translocator from spinach chloroplasts. However, a cluster of 39–44 kDa polypeptides accounted for about 40% of the total amyloplast membrane protein from W64A kernels. These polypeptides were specifically recognized by antibodies raised against a fusion protein consisting of 56 amino acids of the carboxyl terminus of the BTI protein and glutathione S-transferase. The BT1 antibodies also reacted with the abundant polypeptides in amyloplast membranes from hybrid kernels (Doebler 66XP and Pioneer 3780), and the shrunkenl and shrunken2 mutant genotypes, but no BTl reacting polypeptides were present in amyloplast membranes from btl mutant kernels. We were unable to detect BTl by the immunoblot procedure in microsomal membranes from embryo and pericarp tissues from the kernel, from seedling roots and shoots, or in membranes from mitochondria and chloroplasts. The same BTl immunoblot pattern was obtained for proteins extracted from microsomal membranes from developing endosperm and from purified amyloplast membranes. A linear relationship between the number of copies of Btl alleles and the levels of BTl in endosperm microsomal membranes was demonstrated in a gene dosage series. BTl was not extracted from amyloplast membranes by chloroform/methanol or by alkaline buffer at pH 11.5, but was partially extracted by 0.1 M NaOH. These lines of evidence support the conclusion that Btl is the structural gene for the major 39–44 kDa amyloplast membrane polypeptides and that these polypeptides are integral proteins specific to amyloplast membranes from the endosperm.     

Molecular and biochemical analysis of the plastidic ADP-glucose transporter (ZmBT1) from Zea mays

Physiological studies on the Brittle1 maize mutant have provided circumstantial evidence that ZmBT1 (Zea mays Brittle1 protein) is involved in the ADP-Glc transport into maize endosperm plastids, but up to now, no direct ADP-Glc transport mediated by ZmBT1 has ever been shown. The heterologous synthesis of ZmBT1 in Escherichia coli cells leads to the functional integration of ZmBT1 into the bacterial cytoplasmic membrane. ZmBT1 transports ADP-Glc in counterexchange with ADP with apparent affinities of about 850 and 465 mum, respectively. Recently, a complete ferredoxin/thioredoxin system has been identified in cereal amyloplasts and BT1 has been proposed as a potential Trx target protein (Balmer, Y., Vensel, W. H., Cai, N., Manieri, W., Schurmann, P., Hurkman, W. J., and Buchanan, B. B. (2006) Proc. Natl. Acad. Sci. U. S. A. 103, 2988-2993). Interestingly, we revealed that the transport activity of ZmBT1 is reversibly regulated by redox reagents such as diamide and dithiothreitol. The expression of ZmBT1 is restricted to endosperm tissues during starch synthesis, whereas a recently identified BT1 maize homologue, the ZmBT1-2, exhibits a ubiquitous expression pattern in hetero- and autotrophic tissues indicating different physiological roles for both maize BT1 isoforms. BT1 homologues are present in both mono- and dicotyledonous plants. Phylogenetic analyses classify the BT1 family into two phylogenetically and biochemically distinct groups. The first group comprises BT1 orthologues restricted to cereals where they mediate the ADP-Glc transport into cereal endosperm storage plastids during starch synthesis. The second group occurs in mono- and dicotyledonous plants and is most probably involved in the export of adenine nucleotides synthesized inside plastids.     

Roles of isoamylase and ADP-glucose pyrophosphorylase in starch granule synthesis in rice endosperm

Amyloplast-targeted green fluorescent protein (GFP) was used to monitor amyloplast division and starch granule synthesis in the developing endosperm of transgenic rice. Two classical starch mutants, sugary and shrunken, contain reduced activities of isoamylase1 (ISA1) and cytosolic ADP-glucose pyrophosphorylase, respectively. Dividing amyloplasts in the wild-type and shrunken endosperms contained starch granules, whereas those in sugary endosperm did not contain detectable granules, suggesting that ISA1 plays a role in granule synthesis at the initiation step. The transition from phytoglycogen to sugary-amylopectin was gradual in the boundary region between the inner and outer endosperms of sugary. These results suggest that the synthesis of sugary-amylopectin and phytoglycogen involved a stochastic process and that ISA1 activity plays a critical role in the stochastic process in starch synthesis in rice endosperm. The reduction of cytosolic ADP-glucose pyrophosphorylase activity in shrunken endosperm did not inhibit granule initiation but severely restrained the subsequent enlargement of granules. The shrunken endosperm often developed pleomorphic amyloplasts containing a large number of underdeveloped granules or a large cluster of small grains of amyloplasts, each containing a simple-type starch granule. Although constriction-type divisions of amyloplasts were much more frequent, budding-type divisions were also found in the shrunken endosperm. We show that monitoring GFP in developing amyloplasts was an effective means of evaluating the roles of enzymes involved in starch granule synthesis in the rice endosperm.     

Distinct isoforms of ADPglucose pyrophosphorylase occur inside and outside the amyloplasts in barley endosperm

This paper addresses the controversial idea that ADPglucose pyrophosphorylase may be located in the cytosol in some non-photosynthetic plant organs. The intracellular location of the enzyme in developing barley endosperm has been investigated by isolation of intact amyloplasts. Amyloplast preparations contained 13–17% of the total endosperm activity of two plastidial marker enzymes, and less than 0.5% of the total endosperm activity of two cytosolic marker enzymes. Amyloplast preparations contained about 2.5% of the ADPglucose pyrophosphorylase activity, indicating that approximately 15% of the ADPglucose pyrophosphorylase activity in young endosperms is plastidial. Immunoblotting of gels of endosperm and amyloplast extracts also indicated that the enzyme is both inside and outside the amyloplast. Antibodies to the small subunits of the enzyme from barley and maize revealed two bands of protein of different sizes, one of which was located inside and the other outside the amyloplast. The plastidial protein was of the same size as a protein in the chloroplasts of barley leaves which was also recognized by these antibodies. It is suggested that the barley plant contains two distinct isoforms of ADPglucose pyrophosphorylase: one located in plastids (chloroplasts and amyloplasts) and the other in the cytosol of the endosperm. The role of the cytosolic ADPglucose pyrophosphorylase is unknown. Although it may contribute ADPglucose to starch synthesis, the total activity of ADPglucose pyrophosphorylase in the endosperm is far in excess of the rate of starch synthesis and the plastidial isoform is probably capable of catalysing the entire flux of carbon to starch.     

Digestion of Barley, Maize, and Wheat by Selected Species of Ruminal Bacteria

Differences in the digestion of barley, maize, and wheat by three major ruminal starch-digesting bacterial species, Streptococcus bovis 26, Ruminobacter amylophilus 50, and Butyrivibrio fibrisolvens A38, were characterized. The rate of starch digestion in all cereal species was greater for S. bovis 26 than for R. amylophilus 50 or B. fibrisolvens A38. Starch digestion by S. bovis 26 was greater in wheat than in barley or maize, whereas starch digestion by R. amylophilus 50 was greater in barley than in maize or wheat. B. fibrisolvens A38 digested the starch in barley and maize to a similar extent but was virtually unable to digest the starch in wheat. The higher ammonia concentration in cultures of B. fibrisolvens A38 when grown on wheat than when grown on barley or maize suggests that B. fibrisolvens A38 utilized wheat protein rather than starch. Scanning electron microscopy revealed that B. fibrisolvens A38 initially colonized cell wall material, while S. bovis 26 randomly colonized the endosperm and R. amylophilus 50 preferentially colonized starch granules. There was subsequent colonization but only superficial digestion of wheat starch granules by B. fibrisolvens A38. Variation in the association between starch and protein within the endosperm of cereal grains contributes to the differential effectiveness with which amylolytic species can utilize cereal starch.     

Protein accumulation in aleurone cells,sub-aleurone cells and the center starch endosperm of cereals

There are mainly three endosperm storage tissues in the cereal endosperm: aleurone cells, sub-aleurone cells and the center starch endosperm. The protein accumulation is very different in the three endosperm storage tissues. The aleurone cells accumulate protein in aleurone granules. The sub-aleurone cells and the center starch endosperm accumulate protein in endoplasmic reticulum-derived protein bodies and vacuolar protein bodies. Proteins are deposited in different patterns within different endosperm storage tissues probably because of the special storage properties of these tissues. There are several special genes and other molecular factors to mediate the protein accumulation in these tissues. Different proteins have distinct functions in the protein body formation and the protein interactions determine protein body assembly. There are both cooperation and competition relationships between protein, starch and lipid in the cereal endosperm. This paper reviews the latest investigations on protein accumulation in aleurone cells, sub-aleurone cells and the center starch endosperm. Useful information will be supplied for future investigations on the cereal endosperm development.     

Ultrastructural characterization of maize (Zea mays L.) kernels exposed to high temperature during endosperm cell division

This study reports the ultrastructural changes in maize endosperm that result from exposure to high temperature during cell division. Kernels were grown in vitro at 25 ºC continuously (control) and at 5 d after pollination (DAP) subsamples were transferred to continuous 35 ºC for either 4 or 6 d. The 4 d treatment reduced kernel mass by 40% and increased kernel abortion three-fold. The 6-d high-temperature treatment resulted in a 77% reduction in kernel mass and a 12-fold increase in kernel abortion. Evaluation of the kernels at 11 DAP using scanning and transmission electron microscopy revealed that the reduced kernel mass and/or abortion was associated with the disruption of cell division and amyloplast biogenesis in the periphery of the endosperm. This was further confirmed by the presence of an irregular-shaped nucleus, altered size of the nucleolus, highly dense nucleoplasm, and a decrease in the number of proplastids and amyloplasts. Thus, the endosperm cavity was not filled, the total number of endosperm cells was reduced by 35 and 70%, and the number of starch granules was decreased by 45 and 80% after exposure to 4 and 6 d of high-temperature treatments, respectively. This also resulted in a 35–70% reduction in total starch accumulation. KI/I₂ staining and light microscopy revealed that starch accumulation in the peripheral endosperm cells was reduced more severely than in the central zones. However, the scanning electron micrographs of cells from the central endosperm showed that the number and the size of apparently viable amyloplasts were reduced and isolated granules were smaller and/or showed enhanced pitting. These ultrastructural data support the hypothesis that high temperature during endosperm cell division reduces kernel sink potential and subsequently mature kernel mass, mainly by disrupting cell division and amyloplast biogenesis in the peripheral and central endosperm.     

水稻胚乳发育中淀粉体和蛋白体ATPase活性的动态变化

利用ATPase定位技术,对水稻品种(Oryza sativa L.cv．Minghui 63)胚乳细胞发育中后期淀粉体和蛋白体的ATPase活性进行了超微细胞化学定位。结果表明,在淀粉体内外膜上、淀粉粒间的通道上和淀粉体四周的无定形物上呈现显著的ATPase活性。蛋白体Ⅰ和蛋白体Ⅱ的膜上和四周的囊泡、小泡上均出现ATPase活性产物。另外,胚乳细胞的胞壁和质膜,糊粉层和亚糊粉层细胞的胞壁、质膜、细胞核和胞间连丝上也有定位的ATPase活性产物分布。根据ATPase活性产物分布特点,推测淀粉体内的网状通道是便于养分进入淀粉体内部的转运通道。淀粉体膜和蛋白体膜上的ATPase主要是为养分进入内部提供跨膜动力。     

B-type granule containing protrusions and interconnections between amyloplasts in developing wheat endosperm revealed by transmission electron microscopy and GFP expression

Starch granules in mature wheat endosperm show a bimodal size distribution. The formation of small starch granules in wheat endosperm cells was studied by transmission electron microscopy (TEM) and confocal laser scanning microscopy (CLSM) after expression and targeting of fluorescent protein into amyloplasts. Both techniques demonstrated the presence of protrusions emanating from A-type granules-containing amyloplasts and the presence of B-type starch granules in these evaginations. Moreover, CLSM recordings demonstrated the interconnection of the amyloplasts by these protrusions, suggesting a possible role of these protrusions in interplastid communication.     

Nitrogen-induced changes in the growth and metabolism of developing maize kernels grown in vitro

Cereal kernel growth and grain yield are functions of endosperm starch accumulation. The objective of this study was to examine how various metabolic factors in developing maize (Zea mays L.) endosperm influence starch deposition. Kernels were grown in vitro on medium with: (a) zero N (−N), (b) optimum N (+N), or (c) −N from 3 to 20 days after pollination followed by +N until maturity (±N) to produce different degrees of endosperm growth and to promote an enhancement of starch synthesis midway through development. At intervals, kernels were harvested and levels of enzyme activities and carbohydrate and N constituents examined. Endosperm starch and protein accumulation were decreased in −N compared to +N kernels, but relief of N starvation increased both constituents. With greater movement of N into ±N kernels, endosperm sugar concentrations declined suggesting an inverse relationship between C and N transport. Unusually high concentrations of sugar in N stressed kernels did not appear to limit or enhance starch production. Rather, increased accumulation of starch in ±N endosperm was correlated with significant increases in the enzymatic activities of sucrose synthase and PPi-linked phosphofructokinase, and to a lessor extent hexokinase. In addition, the occurrence of specific proteins of the albumin/globulin fraction either increased, decreased, or remained unchanged in relation to starch synthesis. These data suggest that lack of N limits starch deposition in maize endosperm primarily through an influence on synthesis of key proteins.     

Immunohistochemical localization of β-amylase in resting barley seeds

The cellular localization of β-amylase (EC 3.2.1.2) in resting barley seeds was investigated by immunohistochemistry. The monospecificity of the antibodies used was shown by immunoelectrophoresis and western blotting. An adaptation of the immunofluorescence technique allowed the localization of β-amylase. free of autofluorescence, in the different parts of the seed. In endosperm, there was β-amylase protein in aleurone layers, only in the starchy endosperm, where the distribution of the enzyme was not uniform. The β-amylase of starchy endosperm. which can be in a free or a hound form, was mainly localized around starch granules of different sizes. In the embryo. β-amylase was present only in the part of the scutellum in front of the first leaf. By immunoquantitation after separation of the seed parts, its was shown that the ratio between the amounts of enzyme in embryo and endosperm was less than 1/3000.     

Delivery of prolamins to the protein storage vacuole in maize aleurone cells

Zeins, the prolamin storage proteins found in maize (Zea mays), accumulate in accretions called protein bodies inside the endoplasmic reticulum (ER) of starchy endosperm cells. We found that genes encoding zeins, α-globulin, and legumin-1 are transcribed not only in the starchy endosperm but also in aleurone cells. Unlike the starchy endosperm, aleurone cells accumulate these storage proteins inside protein storage vacuoles (PSVs) instead of the ER. Aleurone PSVs contain zein-rich protein inclusions, a matrix, and a large system of intravacuolar membranes. After being assembled in the ER, zeins are delivered to the aleurone PSVs in atypical prevacuolar compartments that seem to arise at least partially by autophagy and consist of multilayered membranes and engulfed cytoplasmic material. The zein-containing prevacuolar compartments are neither surrounded by a double membrane nor decorated by AUTOPHAGY RELATED8 protein, suggesting that they are not typical autophagosomes. The PSV matrix contains glycoproteins that are trafficked through a Golgi-multivesicular body (MVB) pathway. MVBs likely fuse with the multilayered, autophagic compartments before merging with the PSV. The presence of similar PSVs also containing prolamins and large systems of intravacuolar membranes in wheat (Triticum aestivum) and barley (Hordeum vulgare) starchy endosperm suggests that this trafficking mechanism may be common among cereals.     

Analyses of isoamylase gene activity in wild-type barley indicate its involvement in starch synthesis

The notion of debranching enzyme activity as a participant in starch synthesis is gaining acceptance. Inconsistent reports from mutant analyses implicate either isoamylase or pullulanase as a determinant in amylopectin formation and whether wild-type plants utilize one or the other, or both, of these debranching enzymes in starch synthesis is unclear. Recent results on the su1 mutant in maize suggest that both forms of debranching enzymes might be involved in amylopectin formation. We wished to find out if isoamylase takes part in starch synthesis by comparing isoamylase gene activity under three conditions: (1) during starch accumulation in developing sink tissues; (2) during starch degradation in germinating seeds; (3) in ectopic expression after applying sucrose, a starch precursor. We isolated the gene for barley isoamylase, iso1, and analysed its expression and regulation in germinating seeds, developing endosperm and vegetative tissues, and compared the isoamylase gene expression in sink tissues from three different species. Our results indicate that isoamylase gene activity is involved in starch synthesis in wild-type plants and is modulated by sucrose.     

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.