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

Arcalís, Elsa; Ibl, Verena; Peters, Jenny; Melnik, Stanislav; Stöger, Eva

doi:10.3389/fpls.2014.00439

Cited by 40 publications

(28 citation statements)

References 143 publications

(227 reference statements)

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“…Our results further stress the advantages of rice endosperm as a production platform and efficient mucosal delivery vehicle for therapeutic peptides and proteins (Arcalis et al 2014;Takagi et al 2010;Takaiwa 2013;Yang et al 2012). In light of future clinical applications, un-powdered and cooked rice might be a suitable formulation for human consumption.…”

supporting

confidence: 59%

Efficacy of transgenic rice containing human interleukin-10 in experimental mouse models of colitis and pollen allergy

Takagi

Watanabe

Hiroi

et al. 2015

Plant Biotechnology

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Recombinant human interleukin-10 (hIL-10) is highly expressed in transgenic rice endosperm and forms active homodimers in the ER-derived hIL-10 body. In this study, we examined the preclinical efficacy of transgenic rice accumulating hIL-10 (hIL-10 rice) in in vivo experimental mouse models of colitis and pollen allergy. In the group of mice orally fed hIL-10 rice, the development of Japanese cedar pollen allergen-specific IgE and splenic T cell responses were significantly inhibited. In addition, oral feeding of hIL-10 rice showed therapeutic as well as prophylactic efficacy against experimental colitis developed in IL-10-deficient mice. These results indicate the clinical potentiality of hIL-10 rice for the control of inflammatory and allergic disorders through efficient delivery of hIL-10 to the gut-associated lymphoid tissue.

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supporting

confidence: 59%

Efficacy of transgenic rice containing human interleukin-10 in experimental mouse models of colitis and pollen allergy

Takagi

Watanabe

Hiroi

et al. 2015

Plant Biotechnology

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“…The genetic background of the production host is an important factor that can be influenced by crossing, breeding and selection [24], but targeted engineering of the host genome can also be used to reduce the accumulation of endogenous storage proteins, thus providing further capacity for the storage of recombinant proteins [25]. A deeper understanding of recombinant protein storage and protein quality control in the endomembrane system will promote strategies such as the induction of ectopic storage organelles [26–29]. …”

Section: Improving Product Quality and Quantity By Host Cell Engineermentioning

confidence: 99%

The increasing value of plant-made proteins

Sack

Hofbauer

Fischer

et al. 2015

Current Opinion in Biotechnology

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126

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The production of high-value proteins in plants is maturing, as shown by the recent approval of innovative products and the latest studies that showcase plant-based production systems using technologies and approaches that are well established in other fields. These include host cell engineering, medium optimization, scalable unit operations for downstream processing (DSP), bioprocess optimization and detailed cost analysis. Product-specific benefits of plant-based systems have also been exploited, including bioencapsulation and the mucosal delivery of minimally processed topical and oral products with a lower entry barrier than pharmaceuticals for injection. Success stories spearheaded by the FDA approval of Elelyso developed by Protalix have revitalized the field and further interest has been fueled by the production of experimental Ebola treatments in plants.

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“…20 Platforms based on seed storage also combine perfectly with strategies that facilitate downstream processing and make it more cost-effective by using protein domains that form high-molecularweight or nanomaterial structures, such as elastin-like peptides, hydrophobins, or peptides that promote the formation of protein bodies. 3,4,[89][90][91][92] However, in reality, the reluctance of big industry players to invest in a relatively untested (and unsupported) new technology, and public hostility to the open-field cultivation of GM crops in Europe, has slowed down the fulfillment of these promises. But the development of transient gene expression systems 56,[93][94][95] has added speed to the panel of advantages offered by molecular farming in plants and the promises seem to be within reach once again.…”

Section: Why Make Antibodies In Plants?mentioning

confidence: 99%

Antibodies from plants for bionanomaterials

Edgue

Twyman²,

Beiss

et al. 2017

WIREs Nanomed Nanobiotechnol

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Antibodies are produced as part of the vertebrate adaptive immune response and are not naturally made by plants. However, antibody DNA sequences can be introduced into plants, and together with laboratory technologies that allow the design of antibodies recognizing any conceivable molecular structure, plants can be used as 'green factories' to produce any antibody at all. The advent of plant-based transient expression systems in particular allows the rapid, convenient, and safe production of antibodies, ranging from laboratory-scale expression to industrial-scale manufacturing. The key features of plant-based production include safety, speed, low cost, and convenience, allowing newcomers to rapidly master the technology and use it to its full advantage. Manufacturing in plants has recently achieved significant milestones and offers more than just an alternative to established microbial and mammalian cell platforms. The use of plants for product development in particular offers the power and flexibility to easily coexpress many different genes, allowing the plug-and-play construction of novel bionanomaterials, perfectly complementing existing approaches based on plant virus-like particles. As well as producing single antibodies for applications in medicine, agriculture, and industry, plants can be used to produce antibody-based supramolecular structures and scaffolds as a new generation of green bionanomaterials that promise a bright future based on clean and renewable nanotechnology applications. © 2017 The Authors. WIREs Nanomedicine and Nanobiotechnology published by Wiley Periodicals, Inc. How to cite this article:WIREs Nanomed Nanobiotechnol 2017, 9:e1462. doi: 10.1002/wnan.1462 INTRODUCTIONA ntibodies are glycoproteins produced by the adaptive immune system in humans and other vertebrates. They recognize and bind particular target antigens with great affinity and specificity, allowing them to clear pathogens and other unwanted material from the body. Although plants do not naturally produce antibodies, they can be engineered to do so by introducing the corresponding immunoglobulin genes. 1,2 In this manner, plants can be instructed to make antibodies that target any antigen of choice, and they can make them efficiently and in all kinds of different formats. 3,4 Most people picture antibodies as the typical mammalian serum-type immunoglobulin G (IgG), which comprises two identical heavy chains and two identical light chains joined by disulfide bonds (Figure 1). The chains fold and assemble into a multimeric Y-shaped structure. Below the hinge, in what is known as the Fc region (fragment crystallizable), all IgG molecules are largely the same, and this region is responsible for the general effector functions of antibodies, such as immune cell recognition and complement fixation. This part of the antibody is also glycosylated. The hinge and the region above, where the antibody branches into its characteristic Y-shape, is known as the F(ab 0 ) 2 or Fab (fragment for antigen This is an open access article under ...

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

Cited by 40 publications

References 143 publications

Efficacy of transgenic rice containing human interleukin-10 in experimental mouse models of colitis and pollen allergy

Efficacy of transgenic rice containing human interleukin-10 in experimental mouse models of colitis and pollen allergy

The increasing value of plant-made proteins

Antibodies from plants for bionanomaterials

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