Formation mechanism of the internal structure of type I protein bodies in rice endosperm: relationship between the localization of prolamin species and the expression of individual genes

Saito, Yuhi; Shigemitsu, Takanari; Yamasaki, Ryuichi; Sasou, Ai; Goto, Futami; Kishida, Koichi; Kuroda, Masaharu; Tanaka, Kunisuke; Morita, Shigeto; Satoh, Shigeru; Masumura, Takehiro

doi:10.1111/j.1365-313x.2012.04947.x

Cited by 80 publications

(90 citation statements)

References 45 publications

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Section: Resultssupporting

confidence: 75%

“…Cys-poor prolamins are accumulated at late stages of grain filling [43], and their expression is increased during suppression of glutelins, which are the most abundant storage protein in rice [44]. Both the present data and previous reports suggest that the expression of Cys-poor prolamin is controlled at the mRNA level, and effectively stores excess nitrogen during additional fertilization [43], [44]. This may be because Cys-poor prolamin has the simple primary structure with the absence of cysteine residues, and is directly accumulated in the endoplasmic reticulum where protein synthesis occurs.…”

Section: Resultsmentioning

confidence: 99%

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Additional Nitrogen Fertilization at Heading Time of Rice Down-Regulates Cellulose Synthesis in Seed Endosperm

et al. 2014

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The balance between carbon and nitrogen is a key determinant of seed storage components, and thus, is of great importance to rice and other seed-based food crops. To clarify the influence of the rhizosphere carbon/nitrogen balance during the maturation stage of several seed components, transcriptome analysis was performed on the seeds from rice plants that were provided additional nitrogen fertilization at heading time. As a result, it was assessed that genes associated with molecular processes such as photosynthesis, trehalose metabolism, carbon fixation, amino acid metabolism, and cell wall metabolism were differentially expressed. Moreover, cellulose and sucrose synthases, which are involved in cellulose synthesis, were down-regulated. Therefore, we compared cellulose content of mature seeds that were treated with additional nitrogen fertilization with those from control plants using calcofluor staining. In these experiments, cellulose content in endosperm from plants receiving additional nitrogen fertilization was less than that in control endosperm. Other starch synthesis-related genes such as starch synthase 1, starch phosphorylase 2, and branching enzyme 3 were also down-regulated, whereas some α-amylase and β-amylase genes were up-regulated. On the other hand, mRNA expression of amino acid biosynthesis-related molecules was up-regulated. Moreover, additional nitrogen fertilization caused accumulation of storage proteins and up-regulated Cys-poor prolamin mRNA expression. These data suggest that additional nitrogen fertilization at heading time changes the expression of some storage substance-related genes and reduces cellulose levels in endosperm.

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Section: Resultssupporting

confidence: 75%

Section: Resultsmentioning

confidence: 99%

Additional Nitrogen Fertilization at Heading Time of Rice Down-Regulates Cellulose Synthesis in Seed Endosperm

et al. 2014

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“…Protein trafficking and organelle reshaping can also be investigated by looking at the behavior of recombinant proteins, including storage proteins fused to fluorescent tags (Tosi et al, 2009; Saito et al, 2012; Shigemitsu et al, 2013; Wakasa and Takaiwa, 2013) or foreign proteins that have been produced in the context of molecular farming. Endogenous glycoproteins are rarely found in the endosperm (Woo et al, 2001) and are difficult to follow due to the lack of appropriate detection antibodies, so recombinant glycoproteins are particularly useful because they can be traced through intracellular pathways by immunolocalization and by characterizing their glycan modifications (Drakakaki et al, 2006; Arcalis et al, 2010).…”

Section: Recombinant Protein Production In Cereal Endospermmentioning

confidence: 99%

The dynamic behavior of storage organelles in developing cereal seeds and its impact on the production of recombinant proteins

et al. 2014

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Cereal endosperm is a highly differentiated tissue containing specialized organelles for the accumulation of storage proteins, which are ultimately deposited either within protein bodies derived from the endoplasmic reticulum, or in protein storage vacuoles (PSVs). During seed maturation endosperm cells undergo a rapid sequence of developmental changes, including extensive reorganization and rearrangement of the endomembrane system and protein transport via several developmentally regulated trafficking routes. Storage organelles have been characterized in great detail by the histochemical analysis of fixed immature tissue samples. More recently, in vivo imaging and the use of tonoplast markers and fluorescent organelle tracers have provided further insight into the dynamic morphology of PSVs in different cell layers of the developing endosperm. This is relevant for biotechnological applications in the area of molecular farming because seed storage organelles in different cereal crops offer alternative subcellular destinations for the deposition of recombinant proteins that can reduce proteolytic degradation, allow control over glycan structures and increase the efficacy of oral delivery. We discuss how the specialized architecture and developmental changes of the endomembrane system in endosperm cells may influence the subcellular fate and post-translational modification of recombinant glycoproteins in different cereal species.

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“…In the case of rice proteins, Bradbury et al (16) reported that the decreased protein digestibility due to cooking does not result from the formation of isopeptide linkages between the e-amino group of lysine (which would make it resistant to trypsin degradation) and the g-carboxyl group of glutamic acid residues, but may instead be due to the formation of a cystine-rich core that is resistant to proteases. In addition, Saito et al (17) reported that the localization of prolamin species in PB-Is was different and 16 and 10 kDa prolamin, sulfur-containing amino acids rich in proteins, were mainly located in the core and in the middle layer of PB-Is, respectively. Based on these reports and our results, we hypothesize that hydrophobic interactions and disulfide linkages in the PB-Is contribute to the decrease in prolamin digestibility that occurs with cooking.…”

Section: Excretion Of Rice Proteins In the Fecesmentioning

confidence: 99%

In Vivo Digestibility of Rice Prolamin/Protein Body-I Particle Is Decreased by Cooking

Kubota

Saito

Masumura

et al. 2014

J Nutr Sci Vitaminol

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Rice is a staple cereal and a major source of both protein and energy in most Asian countries. Thus, the true digestibility of cooked rice protein is very important for human nutrition. The proteins in rice endosperm consist mainly of storage proteins, e.g., glutelin, prolamin and globulin. Two major proteins, glutelin and prolamin, can be separated into several protein bands by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). Glutelin separates into three bands: proglutelin (57 kDa), an acidic subunit (37-39 kDa), and a basic subunit (22-23 kDa) (1). Prolamin also separates into three bands: 16, 13 and 10 kDa prolamin (2). These storage proteins accumulate in organelles called protein bodies (PBs). Rice endosperm has two different types of PBs; prolamin accumulates in type-I protein bodies (PB-I), while glutelin and globulin accumulate in type-II protein bodies (PB-II) (3). Tanaka et al. (4) reported that fecal protein particles (FPP), such as PBs, were excreted in the feces of humans who had ingested cooked rice (CR). Ogawa et al. (2) demonstrated that the 13 kDa prolamin band in raw rice (RR) remained after pepsin digestion, although the glutelin subunit bands (37-39 and 22-23 kDa) disappeared. These results imply that prolamin is an indigestible protein. However, we recently reported that structural changes induced by alkali extraction can improve the in vivo digestibility of prolamin (5, 6). A study by Eggum et al. showed that cooking decreased the true protein digestibility (TD) of rice from 99.7 to 88.6% (7). However, no reports have directly demonstrated whether rice prolamin is rendered indigestible in vivo by cooking.In the present study, we monitored the gastrointestinal (GI) transit and fecal excretion of rice glutelin and prolamin in rats by using anti-23 kDa glutelin (23G) and anti-13 kDa prolamin (13P) antibodies to estimate their digestibility in CR and RR. Additionally, morphological observations of PBs in the feces of rats fed the CR or RR diets were conducted using electron microscopy to confirm the effects of cooking on PB structure. Although the digestibility of 23G was not affected by cooking, the digestibility of 13P was clearly reduced. Almost intact PB-Is were observed in the feces of rats fed the CR diet. Our results clearly indicate that rice prolamin is not indigestible in its raw form, but is rendered indigestible by cooking. Materials and MethodsMaterials and animal experiment. Rice (Koshihikari, 10% polished fraction) was purchased from Niigata Seifun Co., Ltd. (Tainai, Japan). RR flour was prepared using a jet mill (KV-3-4S, Yakushinkikai Seisakusho, Japan). CR flour was prepared by rinsing the rice first and then cooking it in twice its volume of water in an electric rice cooker (JAG-A100 TM, Tiger Co., Ltd., Osaka, Japan). Summary Rice has storage proteins, e.g., glutelin, globulin and prolamin, in the seeds, which are used as nitrogen sources during germination. Rice prolamin has been reported to be an indigestible protein that decreases the nutritional ...

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Formation mechanism of the internal structure of type I protein bodies in rice endosperm: relationship between the localization of prolamin species and the expression of individual genes

Cited by 80 publications

References 45 publications

Additional Nitrogen Fertilization at Heading Time of Rice Down-Regulates Cellulose Synthesis in Seed Endosperm

Additional Nitrogen Fertilization at Heading Time of Rice Down-Regulates Cellulose Synthesis in Seed Endosperm

The dynamic behavior of storage organelles in developing cereal seeds and its impact on the production of recombinant proteins

In Vivo Digestibility of Rice Prolamin/Protein Body-I Particle Is Decreased by Cooking

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