Arginine-rich intracellular delivery peptides noncovalently transport protein into living cells

Plasma membranes of plant or animal cells are generally impermeable to peptides or proteins. Many basic peptides have previously been investigated and covalently cross-linked with cargoes for cellular internalization. In the current study, we demonstrate that arginine-rich intracellular delivery (AID) peptides are able to deliver fluorescent proteins or beta-galactosidase enzyme into animal and plant cells, as well as animal tissue. Cellular internalization and transdermal delivery of protein could be mediated by effective and nontoxic AID peptides in a neither fusion protein nor conjugation fashion. Therefore, noncovalent AID peptides may provide a useful strategy to have active proteins function in living cells and tissues in vivo.     

Noncovalent protein transduction in plant cells by macropinocytosis

* 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 beta-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.     

Biological applications of protein transduction technology

The impermeable nature of the cell membrane to peptides, proteins, DNA and oligonucleotides limits the therapeutic potential of these biological agents. However, the recent discovery of short cationic peptides that cross the plasma membrane efficiently is opening up new possibilities for the intracellular delivery of such agents. These peptides are commonly referred to as protein transduction domains (PTDs) and are successfully used to transport heterologous proteins, peptides and other types of cargo into cells. Several recent reports have used the membrane transducing technology in vivo to deliver biologically active cargo into various tissues. This review discusses the structure of the most commonly used PTDs and how their ability to transduce membranes is used to regulate biological functions. It also considers future directions and the potential of this technology to move from the laboratory into the clinic.     

A peptide carrier for the delivery of biologically active proteins into mammalian cells.

The development of peptide drugs and therapeutic proteins is limited by the poor permeability and the selectivity of the cell membrane. There is a growing effort to circumvent these problems by designing strategies to deliver full-length proteins into a large number of cells. A series of small protein domains, termed protein transduction domains (PTDs), have been shown to cross biological membranes efficiently and independently of transporters or specific receptors, and to promote the delivery of peptides and proteins into cells. TAT protein from human immunodeficiency virus (HIV-1) is able to deliver biologically active proteins in vivo and has been shown to be of considerable interest for protein therapeutics. Similarly, the third alpha-helix of Antennapedia homeodomain, and VP22 protein from herpes simplex virus promote the delivery of covalently linked peptides or proteins into cells. However, these PTD vectors display a certain number of limitations in that they all require crosslinking to the target peptide or protein. Moreover, protein transduction using PTD-TAT fusion protein systems may require denaturation of the protein before delivery to increase the accessibility of the TAT-PTD domain. This requirement introduces an additional delay between the time of delivery and intracellular activation of the protein. In this report, we propose a new strategy for protein delivery based on a short amphipathic peptide carrier, Pep-1. This peptide carrier is able to efficiently deliver a variety of peptides and proteins into several cell lines in a fully biologically active form, without the need for prior chemical covalent coupling or denaturation steps. In addition, this peptide carrier presents several advantages for protein therapy, including stability in physiological buffer, lack of toxicity, and lack of sensitivity to serum. Pep-1 technology should be extremely useful for targeting specific protein-protein interactions in living cells and for screening novel therapeutic proteins.     

Cell Membrane Diversity in Noncovalent Protein Transduction

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.     

蛋白质转导及其内在化机制

蛋白质转导是新近发展起来的向细胞内快速输送外源性大分子或高极性分子的有效途径。它实质上是一些蛋白质,尤其是病毒蛋白上被称为蛋白质转导区(PTD)的小片段,蛋白质和其他物质,如DNA、脂质体、纳米颗粒、环孢素A等与之结合后,即能够被携带进入细胞或穿过血脑屏障。蛋白质转导的内在化机制目前尚不清楚,可能与带正电荷(富Arg)的PTD肽与细胞膜上带负电荷的硫酸乙酰肝素有关,但不排除其他内在化机制。     

PEP and CADY-mediated delivery of fluorescent peptides and proteins into living cells

Cell-penetrating peptides (CPPs) constitute a family of peptides with the characteristic ability to cross biological membranes and deliver cargo into the intracellular milieu. Several CPPs have been proposed for delivery of polypeptides and proteins into cells through either of two strategies: covalent or complexed in a non-covalent fashion. Members of the PEP family are primary amphipathic peptides which have been shown to deliver peptides and proteins into a wide variety of cells through formation of non-covalent complexes. CADY is a secondary amphipathic peptide which has been demonstrated to deliver short nucleic acids, in particular siRNA with high efficiency. Here we review the characteristics of the PEP and CADY carriers and describe a novel derivative of CADY termed CADY2, which also presents sequence similarities to Pep1. We have compared Pep1, CADY and CADY2 in their efficiency to interact with and internalize short fluorogenic peptides and proteins into cultured cells, and provide evidence that CADY2 can interact with proteins and peptides and deliver them efficiently into living cells, similar to Pep1, but in contrast to CADY which is unable to deliver any peptide, even short negatively charged peptides. This is the first study to investigate the influence of the cargo on the interactions between PEP and CADY carriers, thereby providing novel insights into the physicochemical parameters underlying interactions and cellular uptake of peptides and proteins by these non-covalent CPPs.     

Pathway for polyarginine entry into mammalian cells

Cationic peptides known as protein transduction domains (PTDs) provide a means to deliver molecules into mammalian cells. Here, nonaarginine (R(9)), the most efficacious of known PTDs, is used to elucidate the pathway for PTD internalization. Although R(9) is found in the cytosol as well as the nucleolus when cells are fixed, this peptide is observed only in the endocytic vesicles of live cells. Colocalization studies with vesicular markers confirm that PTDs are internalized by endocytosis rather than by crossing the plasma membrane. The inability of R(9) to enter living cells deficient in heparan sulfate (HS) suggests that binding to HS is necessary for PTD internalization. This finding is consistent with the high affinity of R(9) for heparin (K(d) = 109 nM). Finally, R(9) is shown to promote the leakage of liposomes but only at high peptide:lipid ratios. These and other data indicate that the PTD-mediated delivery of molecules into live mammalian cells involves (1) binding to cell surface HS, (2) uptake by endocytosis, (3) release upon HS degradation, and (4) leakage from endocytic vesicles.     

MALDI-TOF mass spectrometry: A powerful tool to study the internalization of cell-penetrating peptides

This review summarizes the contribution of MALDI-TOF mass spectrometry in the study of cell-penetrating peptide (CPP) internalization in eukaryote cells. This technique was used to measure the efficiency of cell-penetrating peptide cellular uptake and cargo delivery and to analyze carrier and cargo intracellular degradation. The impact of thiol-containing membrane proteins on the internalization of CPP–cargo disulfide conjugates was also evaluated by combining MALDI-TOF MS with simple thiol-specific reactions. This highlighted the formation of cross-linked species to cell-surface proteins that either remained trapped in the cell membrane or led to intracellular delivery. MALDI-TOF MS is thus a powerful tool to dissect CPP internalization mechanisms.     

Intracellular delivery of glutathione S-transferase into mammalian cells

Protein transduction domains (PTDs) derived from human immunodeficiency virus Tat protein and herpes simplex virus VP22 protein are useful for the delivery of non-membrane-permeating polar or large molecules into living cells. In the course of our study aiming at evaluating PTD, we unexpectedly found that the fluorescent-dye-labeled glutathione S-transferase (GST) from Schistosoma japonicum without known PTDs was delivered into COS7 cells. The intracellular transduction of GST was also observed in HeLa, NIH3T3, and PC12 cells, as well as in hippocampal primary neurons, indicating that a wide range of cell types is permissive for GST transduction. Furthermore, we showed that the immunosuppressive peptide VIVIT fused with GST successfully inhibits NFAT activation. These results suggest that GST is a novel PTD which may be useful in the intracellular delivery of biologically active molecules, such as small-molecule drugs, bioactive peptides, or proteins.     

细胞穿透肽:一种新型非病毒载体

细胞膜的选择通透性对维持细胞内环境的稳定起着非常重要的作用,但细胞膜的这种特性限制了一些生物大分子和药物进入细胞内,不利于对一些细胞内疾病的诊断和药物靶向治疗的应用。如何将一些具有诊断和治疗潜力的生物大分子、药物通过细胞膜进入细胞内一直是医学界研究的热点和难点。细胞穿透肽是一类能够携带多肽、蛋白质、核酸、纳米颗粒、病毒颗粒及药物等穿过细胞膜进入细胞,导致完整载物内化的短肽,为生物大分子和药物进入细胞内部提供了有力的运载工具,其作为载体具有的高转导效率和低毒性特点,已经得到了广泛关注和大量研究。目前,细胞穿透肽作为生物分子和药物细胞内化的运载体已经在荧光成像,肿瘤治疗,抗炎治疗及药物靶向治疗中发挥了潜在的诊断和治疗作用,显示出其诱人的应用前景。     

Arginine carrier peptide bearing Ni(II) chelator to promote cellular uptake of histidine-tagged proteins

Arginine-rich peptide-mediated protein delivery into living cells is a novel technology for controlling cell functions with therapeutic potential. In this report, a novel approach for the intracellular delivery of histidine-tagged proteins was introduced where a Ni(II) chelate of octaarginine peptide bearing nitrilotriacetic acid [R8-NTA-Ni(II)] was used as a membrane-permeable carrier molecule. Significant internalization of histidine-tagged enhanced green fluorescent protein (EGFP) into HeLa cells was observed by confocal microscopic observation in the presence of R8-NTA-Ni(II). Nuclear condensation characteristic in apoptotic cell death was also induced in the cells treated with a histidine-tagged apoptosis-inducing peptide [pro-apoptotic domain peptide (PAD)], indicating that the cargo molecules really went through the membrane to reach the cytosol. The apoptosis-inducing activity of the peptide thus delivered was compared with that of the PAD peptide covalently connected with the octaarginine peptide.     

The importance of valency in enhancing the import and cell routing potential of protein transduction domain-containing molecules

Protein transduction domains (PTDs) are peptides that afford the internalization of cargo macromolecules (including plasmid DNA, proteins, liposomes, and nanoparticles). In the case of polycationic peptides, the efficiency of PTDs to promote cellular uptake is directly related to their molecular mass or their polyvalent presentation. Similarly, the efficiency of routing to the nucleus increases with the number of nuclear localization signals (NLS) associated with a cargo. The quantitative enhancement, however, depends on the identity of the PTD sequence as well as the targeted cell type. Thus the choice and multivalent presentation of PTD and NLS sequences are important criteria guiding the design of macromolecules intended for specific intracellular localization. This review outlines synthetic and recombinant strategies whereby PTDs and signal sequences can be assembled into multivalent peptide dendrimers and promote the uptake and routing of their cargoes. In particular, the tetramerization domain of the tumour suppressor p53 (p53^tet) is emerging as a useful scaffold to present multiple routing and targeting moieties. Short cationic peptides fused to the 31-residue long p53^tet sequence resulted in tetramers displaying a significant enhancement (up to 1000 fold) in terms of their ability to be imported into cells and delivered to the cell nucleus in relation to their monomeric analogues. The design of future polycationic peptide dendrimers as effective delivering vehicles will need to incorporate selective cell targeting functions and provide solutions to the issue of endosomal entrapment.     

The importance of valency in enhancing the import and cell routing potential of protein transduction domain-containing molecules

Protein transduction domains (PTDs) are peptides that afford the internalization of cargo macromolecules (including plasmid DNA, proteins, liposomes, and nanoparticles). In the case of polycationic peptides, the efficiency of PTDs to promote cellular uptake is directly related to their molecular mass or their polyvalent presentation. Similarly, the efficiency of routing to the nucleus increases with the number of nuclear localization signals (NLS) associated with a cargo. The quantitative enhancement, however, depends on the identity of the PTD sequence as well as the targeted cell type. Thus the choice and multivalent presentation of PTD and NLS sequences are important criteria guiding the design of macromolecules intended for specific intracellular localization. This review outlines synthetic and recombinant strategies whereby PTDs and signal sequences can be assembled into multivalent peptide dendrimers and promote the uptake and routing of their cargoes. In particular, the tetramerization domain of the tumour suppressor p53 (p53tet) is emerging as a useful scaffold to present multiple routing and targeting moieties. Short cationic peptides fused to the 31-residue long p53tet sequence resulted in tetramers displaying a significant enhancement (up to 1000 fold) in terms of their ability to be imported into cells and delivered to the cell nucleus in relation to their monomeric analogues. The design of future polycationic peptide dendrimers as effective delivering vehicles will need to incorporate selective cell targeting functions and provide solutions to the issue of endosomal entrapment.     

Cellular internalization of fluorescent proteins via arginine-rich intracellular delivery peptide in plant cells

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.     

细胞穿膜肽研究应用的新进展

细胞穿膜肽(Cell-penetrating peptides,CPPs)是一类能够穿过细胞膜或组织屏障的短肽。CPPs可通过内吞和直接穿透等机制运载蛋白质、RNA、DNA等生物大分子进入细胞内发挥其效应功能。相比于其他非天然的化学分子,CPPs具有生物相容性佳、对细胞造成的毒性小、完成入胞转运后可降解、并能与生物活性蛋白直接融合重组表达等优点,因此成为以胞内分子为靶标的药物递送技术发展的重要工具,并在生物医学研究领域具有良好的应用前景。文中针对CPPs的分类特点、入胞转运机制及其治疗应用的新近研究进展进行综述和讨论。     

Identification and characterization of a novel cell-penetrating peptide of 30Kc19 protein derived from Bombyx mori

Cell-penetrating peptides (CPPs) or protein transduction domains (PTDs) have attracted increasing attention due to their high potential to deliver various, otherwise impermeable, bioactive agents, such as drugs and proteins across cell membranes. A number of CPPs have been discovered since then. Recently, 30Kc19 protein has attracted attention because it was the first cell-penetrating protein that has been found in insect hemolymph. Here, we report a cell-penetrating peptide derived from 30Kc19 protein, VVNKLIRNNKMNC, which efficiently penetrates cells when supplemented to medium for mammalian cell culture. Moreover, like other CPPs, this “Pep-c19” also efficiently delivered cell-impermeable cargo proteins, such as green fluorescent protein (GFP) into cells. In addition to the in vitro system, Pep-c19 exhibited the cell-penetrating property in vivo. When Pep-c19 was intraperitoneally injected into mice, Pep-c19 successfully delivered cargo proteins into various organ tissues with higher efficiency than the 30Kc19 protein itself, and without toxicity. Our data demonstrates that Pep-c19 has a great potential as a cell-penetrating peptide that can be used as a therapeutic tool to efficiently deliver different cell-impermeable cargo molecules into the tissues of various organs.     

Heparan sulfate proteoglycan as a plasma membrane carrier

The plasma membrane defines the border of living cells and provides a barrier to extracellular components. Advances in molecular biology have resulted in the development of novel therapeutic strategies (e.g. gene therapy and cellular protein delivery) which rely on the entry of charged macromolecules into the intracellular compartment. Recent reports demonstrate an intriguing role for heparan sulfate proteoglycans in cellular internalization of viruses, basic peptides and polycation-nucleic-acid complexes and the possibility that they have important implications for gene transfer and protein delivery to mammalian cells. This review focuses on heparan sulfate proteoglycan as a plasma membrane carrier.     

Organelle-targeted delivery of biological macromolecules using the protein transduction domain: potential applications for Peptide aptamer delivery into the nucleus

Extensive effort is currently being expended on the innovative design and engineering of new molecular carrier systems for the organelle-targeted delivery of biological cargoes (e.g., peptide aptamers or biological proteins) as tools in cell biology and for developing novel therapeutic approaches. Although cell-permeable Tat peptides are useful carriers for delivering biological molecules into the cell, much internalized Tat-fused cargo is trapped within macropinosomes and thus not delivered into organelles. Here, we devised a novel intracellular targeting technique to deliver Tat-fused cargo into the nucleus using an endosome-disruptive peptide (hemagglutinin-2 subunit) and a nuclear localization signal peptide. We show for the first time that Tat-conjugated peptide aptamers can be selectively delivered to the nucleus by using combined hemagglutinin-2 subunit and nuclear localization signal peptides. This nuclear targeting technique resulted in marked enhancement of the cytostatic activity of a Tat-fused p53-derived peptide aptamer against human MDM2 (mouse double minute 2) that inhibits p53-MDM2 binding. Thus, our technique provides a unique methodology for the development of novel therapeutic approaches based on intracellular targeting.