Zeolin. A New Recombinant Storage Protein Constructed Using Maize <i>γ</i>-Zein and Bean Phaseolin

Mainieri, Davide; Rossi, Marika; Archinti, Marco; Bellucci, Michele; Marchis, Francesca De; Vavassori, Stefano; Pompa, Andrea; Arcioni, Sergio; Vitale, Alessandro

doi:10.1104/pp.104.046409

Cited by 113 publications

(209 citation statements)

References 42 publications

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“…These protein bodies sequester a proportion of BiP, which can be released by ATP in vitro treatment, indicating that BiP is not trapped but is acting as a chaperone (heat shock-70 chaperones are ATPases and use ATP hydrolysis to perform their function). Zeolin protein bodies are insoluble and can be solubilized and disassembled by reducing agents (Mainieri et al, 2004). These results indicate that disulfide bonds are a key factor in zeolin protein body assembly and that the process is extensively assisted by BiP.…”

Section: Protein Bodiesmentioning

confidence: 80%

“…Consistently, when the repeat and linker regions of g-zein are appended to the trimeric vacuolar protein phaseolin, the fusion protein, termed zeolin, is retained in the ER and stably deposited in protein body-like structures ( Fig. 2B; see Mainieri et al, 2004). These protein bodies sequester a proportion of BiP, which can be released by ATP in vitro treatment, indicating that BiP is not trapped but is acting as a chaperone (heat shock-70 chaperones are ATPases and use ATP hydrolysis to perform their function).…”

Section: Protein Bodiesmentioning

confidence: 89%

“…However, some native or artificial storage proteins accumulated as protein bodies in the ER also associate for a long time after synthesis with the plant homologue of the immunoglobulin heavy chain binding protein (BiP), which is the ER member of the heat shock 70 chaperone family (Li et al, 1993; and in this issue Mainieri et al, 2004). Persistent interactions with the ER helpers are therefore not sufficient per se for degradation, and this seems to constitute a second paradox, at least in the cells that accumulate storage proteins in the ER.…”

Section: Protein Quality Controlmentioning

confidence: 99%

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Protein Quality Control Mechanisms and Protein Storage in the Endoplasmic Reticulum. A Conflict of Interests?

Vitale

Ceriotti

2004

Plant Physiology

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Section: Protein Bodiesmentioning

confidence: 80%

Section: Protein Bodiesmentioning

confidence: 89%

Section: Protein Quality Controlmentioning

confidence: 99%

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Protein Quality Control Mechanisms and Protein Storage in the Endoplasmic Reticulum. A Conflict of Interests?

Vitale

Ceriotti

2004

Plant Physiology

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“…Previous evidence of a role for disulfide bonds in Zera polymerization came from zeolin expression studies in tobacco (4). Zeolin, a fusion of phaseolin and a ␥-zein sequence equivalent to Zera, was insoluble and formed PBs in the ER when expressed in tobacco (26). When protoplasts expressing zeolin were treated with 2-ME or when a zeolin devoid of the six Cys residues was expressed in the protoplasts, the solubility of the protein was enhanced, allowing its trafficking along the secretory pathway (4).…”

Section: Discussionmentioning

confidence: 99%

“…The proline-rich N-terminal sequence of ␥-zein comprising the first 112 amino acids (the Zera sequence) (23) fused to a variety of reporter and therapeutic proteins, was shown to induce the stable accumulation of the fusion proteins in ER-derived PB-like structures in plant vegetative tissues (24,25). The ability of a similar sequence to redirect phaseolin, a vacuolar storage protein, to the ER compartment of transformed tobacco leaves in which the fusion protein, named zeolin, is retained and accumulated in PBs, has also been demonstrated (26). Interestingly, the PBinducing capacity of Zera was also demonstrated in a variety of other (non-plant) eukaryotic cells, including mammalian, insect, and fungal cells (24).…”

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Relevant Elements of a Maize γ-Zein Domain Involved in Protein Body Biogenesis

Llop‐Tous

Madurga

Giralt

et al. 2010

Journal of Biological Chemistry

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The N-terminal proline-rich domain of ␥-zein (Zera) plays an important role in protein body (PB) formation not only in the original host (maize seeds) but in a broad spectrum of eukaryotic cells. However, the elements within the Zera sequence that are involved in the biogenesis of PBs have not been clearly identified. Here, we focused on amino acid sequence motifs that could be involved in Zera oligomerization, leading to PB-like structures in Nicotiana benthamiana leaves. By using fusions of Zera with fluorescent proteins, we found that the lack of the repeat region (PPPVHL) 8 of Zera resulted in the secretion of the fusion protein but that this repeat by itself did not form PBs. Although the repeat region containing eight units was the most efficient for Zera self-assembly, shorter repeats of 4 -6 units still formed small multimers. Based on site-directed mutagenesis of Zera cysteine residues and analysis of multimer formation, we conclude that the two N-terminal Cys residues of Zera (Cys 7 and Cys 9 ) are critical for oligomerization. Immunoelectron microscopy and confocal studies on PB development over time revealed that early, small, Zera-derived oligomers were sequestered in buds along the rough ER and that the mature size of the PBs could be attained by both cross-linking of preformed multimers and the incorporation of new chains of Zera fusions synthesized by active membrane-bound ribosomes. Based on these results and on the behavior of the Zera structure determined by molecular dynamics simulation studies, we propose a model of Zera-induced PB biogenesis.The mechanisms by which prolamins, which lack the ER 3 retention (H/K)DEL motif, are retained and assembled in the ER-derived PBs are only partially understood. Different factors act as determinants of PB biogenesis, some of them derived from cis-cargo properties and others with a cellular trans-origin (1). It has been proposed that the physico-chemical properties of prolamins, such as hydrophobicity and disulfide bond formation, promote specific interactions resulting in the formation of large self-assemblies that are responsible for their retention in the ER and PB formation (2-4). These polymers could be excluded because of their size from being carried by the COP II vesicles that transport cargo proteins to the Golgi complex (5). However, the generic COPII vesicles are flexible enough for large cargo loading, including that of procollagen (more than 300 nm in size) (6) and the collagen VII trimer (900 kDa) (7).In maize, four distinct types of prolamins (␣-, ␤-, ␥-, and ␦-zein) coexist in the PBs (8) and play distinct roles in PB formation. Recently, maize storage protein mutants created through RNAi showed that ␥-RNAi maize mutant lines exhibited slightly altered protein body formation and that a more drastic effect was observed in the ␤-␥ combined mutant, where protein bodies showed an irregular shape, particularly in their periphery (9).Various studies on zein accumulation in heterologous expression systems suggest that ␥-zein and ␤-zein mediate t...

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Cassava Genetic Improvement

Ceballos¹,

Fregene²,

Carlos³

et al. 2007

Breeding Major Food Staples

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PREFACEThis Handbook is the result of a combined effort by several current and previous cassava researchers at CIAT to review and summarize the most important results of cassava research during the past 40 years. Most of the chapters are based on the various presentations during the Regional Cassava Training Course, held in Thailand from October 6 to 17, 2008. This course was organized upon the realization that many people that were actively involved with cassava research in the 1970s and 80s, both at CIAT and in national programs, have now retired or will soon do so, and that a whole new generation of cassava researchers are currently being hired to take their place.As cassava is now becoming a very important, and mostly industrial, crop in Asia, there are many new opportunities, but also a host of new problems and challenges. These include the appearance in Asia of new cassava diseases and pests; the decreasing availability and increasing cost of rural labor, resulting in the need for partial or complete mechanization of cassava production; the rapidly increasing demand for cassava roots for production of food, feed and fuel, and the unavailability in many countries of new land for any expansion of cassava area, thus requiring a rapid increase in cassava yields to increase supplies. This requires a renewed focus on cassava research for the development of new higher-yielding varieties and more sustainable production practices.While many cassava researchers in national programs in Asia received individual or group training at CIAT-Colombia during the 1970s and 80s, this training was greatly reduced during the following two decades due to funding limitations. Thus, the objective of the Regional Cassava Training Course in 2008 was to provide a new training opportunity for young scientists in Asian countries, and to hand over the knowledge and experience of the older cassava researchers, mostly from CIAT, to a new generation that will have to face the new challenges. Thus, the course was taught mostly by current or already retired CIAT cassava researchers, while the 60-plus participants of the course included cassava researchers from Cambodia, China, East Timor, India, Indonesia, Lao PDR, Malaysia, Myanmar, the Philippines, Thailand and Vietnam. The training course not only provided knowledge -from physiology and biotechnology to animal feeding and production of fuelethanol -but also an opportunity for people from different institutions and countries to get to know each other, which will greatly facilitate future collaboration.Course participants returned home with a CD containing the PowerPoint presentations of the course. However, it was felt that a more comprehensive review of all the topics covered was warranted, as this would provide more in-depth knowledge for those working in the various specialized fields. Most of this information is available in many refereed journals, in workshop proceedings and old CIAT annual reports, but many of these are now out of print or otherwise difficult to obtain. Thus, the Cas...

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Zeolin. A New Recombinant Storage Protein Constructed Using Maize γ-Zein and Bean Phaseolin

Cited by 113 publications

References 42 publications

Protein Quality Control Mechanisms and Protein Storage in the Endoplasmic Reticulum. A Conflict of Interests?

Protein Quality Control Mechanisms and Protein Storage in the Endoplasmic Reticulum. A Conflict of Interests?

Relevant Elements of a Maize γ-Zein Domain Involved in Protein Body Biogenesis

Cassava Genetic Improvement

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