Jyh-Ching Chou scite author profile

The protein delivery across cellular membranes or compartments is limited by low biomembrane permeability because of the hydrophobic characteristics of cell membranes. Usually the delivery processes utilize passive protein channels or active transporters to overcome the membrane impediment. In this report, we demonstrate that arginine-rich intracellular delivery (AID) peptide is capable of efficiently delivering fused fluorescent proteins unpreferentially into different plant tissues of both tomato (a dicot plant) and onion (a monocot plant) in a fully bioactive form. Thus, cellular internalization via AID peptide can be a powerful tool characterized by its simplicity, non-invasion and high efficiency to express those bioactive proteins in planta or in plant cells in vivo. This novel method may alternatively provide broader applications of AID chimera in plants without the time-consuming transgenic approaches.

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Noncovalent protein transduction in plant cells by macropinocytosis

Chang

et al. 2007

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Research Summary• Protein delivery across cellular membranes or compartments is primarily limited by low biomembrane permeability.• Many protein transduction domains (PTDs) have previously been generated, and covalently cross-linked with cargoes for cellular internalization.• An arginine-rich intracellular delivery (AID) peptide could rapidly deliver fluorescent proteins or β -galactosidase enzyme into plant and animal cells in a noncovalent fashion. The possible mechanism of this noncovalent protein transduction (NPT) may involve macropinocytosis.• The NPT via a nontoxic AID peptide provides a powerful tool characterized by its simplicity and quickness to have active proteins function in living cells in vivo . This should be of broad utility for functional enzyme assays and protein therapies in both plant biology research as well as biomedical applications.

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Transfection and expression of plasmid DNA in plant cells by an arginine‐rich intracellular delivery peptide without protoplast preparation

et al. 2007

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The delivery and expression of exogenous genes in plant cells have been of particular interest for plant research and biotechnology. Here, we present results demonstrating a simple DNA transfection system in plants. Short arginine-rich intracellular delivery peptide, a protein transduction domain, was capable of delivering plasmid DNA into living plant cells non-covalently. This peptide-mediated DNA delivery conferred several advantages, such as nuclear targeting, non-toxic effect, and ease of preparation without protoplast formulation. Thus, this novel technology shall provide a powerful tool to investigate gene function in vivo, and lay the foundation for the production of transgenic plants in future.

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Cell Membrane Diversity in Noncovalent Protein Transduction

2008

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Crossing of the plasma membrane for all macromolecules without energy, receptors or any artificial methods was thought to be difficult. Our previous studies demonstrated that arginine-rich intracellular delivery (AID) peptides are able to deliver macromolecules, such as proteins, RNAs and DNAs, into either animal or plant cells. Cellular internalization could be mediated by effective and nontoxic AID peptides in either a covalent or noncovalent protein transduction (NPT) manner. AID peptides were so versatile that the procedure seemed to replace the current artificial transfection methods. However, the utilization of AID peptides has been limited to animal or plant systems so far. None has proposed that AID peptides could work in other species. Here, we select some representative organisms to screen whether NPT mediated by AID peptides works in them. They include cyanobacteria, bacteria, archaea, algae, fungi and yeasts. The results reveal that not all living beings possess this capability of protein transduction. Interestingly, all species of prokaryotes tested, which were thought to be highly diverse from the animal and plant systems, appear to be capable of NPT. The mechanism of AID-mediated NPT in cyanobacteria is in a classical endocytosis- and energy-independent pathway and may involve macropinocytosis. In contrast, green algae and multicellular fungi of the eukaryotes are impermeable to protein passage. Our results bring an interesting clue to the reexamination of the phylogeny of both algae and fungi.

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Arginine-Rich Intracellular Delivery Peptides Synchronously Deliver Covalently and Noncovalently Linked Proteins into Plant Cells

Liu

et al. 2010

J. Agric. Food Chem.

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Protein transduction domains (PTDs) are small peptides with a high content of basic amino acids, and they are responsible for cellular uptake. Many PTDs, including arginine-rich intracellular delivery (AID) peptides, have been shown to transport macromolecules across membranes and into cells. In this study, we demonstrated for the first time that AID peptides could rapidly and efficiently deliver proteins into plant cells in both covalent and noncovalent protein transductions (CNPT) simultaneously. The optimal molecular ratio between an AID peptide carrier and cargo in CNPT was about 3:1. Fluorescence resonance energy transfer (FRET) analysis revealed protein-protein interactions between AID peptide carriers and cargos after CNPT in cells. The possible mechanisms of AID peptides-mediated cellular entry might involve a combination of multiple internalization pathways. Therefore, applications by AID peptide-mediated CNPT may provide a simple and direct transport strategy for delivering two proteins in agricultural systems.

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Jyh-Ching Chou

Cellular Internalization of Fluorescent Proteins via Arginine-rich Intracellular Delivery Peptide in Plant Cells

Noncovalent protein transduction in plant cells by macropinocytosis

Transfection and expression of plasmid DNA in plant cells by an arginine‐rich intracellular delivery peptide without protoplast preparation

Cell Membrane Diversity in Noncovalent Protein Transduction

Arginine-Rich Intracellular Delivery Peptides Synchronously Deliver Covalently and Noncovalently Linked Proteins into Plant Cells

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