Peptide delivery systems

Efficient delivery of peptide drugs to the desired site is very important. There are anumber of barriers that may limit using peptides as potential drugs, some of theseobstacles include poor biomembrane permeability, enzymatic degradation and lowpH. To improve peptide drug efficiency a selective drug delivery system is required.Here we review some of the delivery systems available for peptides and we will alsobriefly discuss peptides that have been used as delivery systems.     

蛋白质和多肽药物长效性研究进展

基于分子生物学和重组技术的发展,蛋白质和多肽已经成为一类重要的药物,但是其稳定性差,生物利用率低,半衰期短等问题也日益受到关注。本文重点介绍了一些新的给药途径和给药系统,例如鼻腔、颊等给药途径以及黏膜给药系统、透皮给药系统、缓控释技术等给药系统的进展。综述了对于蛋白质和多肽药物进行定点突变和化学修饰,以达到增加其长效性的一些新方法。     

Investigation of archaeosomes as carriers for oral delivery of peptides

Oral administration of peptide and protein drugs faces a big challenge partly due to the hostile gastrointestinal (GI) environment. Lipid-based delivery systems are attractive because they offer some protection for peptides and proteins. In this context, we prepared a special lipid-based oral delivery system: archaeosomes, made of the polar lipid fraction E (PLFE) extracted from Sulfolobus acidocaldarius, and explored its potential as an oral drug delivery vehicle. Our study demonstrates that archaeosomes have superior stability in simulated GI fluids, and enable fluorescent labeled peptides to reside for longer periods in the GI tract after oral administration. Although archaeosomes have little effect on the transport of insulin across the Caco-2 cell monolayers, the in vivo experiments indicated that archaeosomes containing insulin induced lower levels of blood glucose than a conventional liposome formulation. These data indicate that archaeosomes could be a potential carrier for effective oral delivery of peptide drugs.     

'IntraCell' plugin for assessment of intracellular localization of nano-delivery systems and their targeting to the individual organelles

Efficient intracellular targeting of drugs and drug delivery systems (DDSs) is a major challenge that should be overcome to enhance the therapeutic efficiency of biopharmaceuticals and other intracellularly-acting drugs. Studies that quantitatively assess the mechanisms, barriers, and efficiency of intracellular drug delivery are required to determine the therapeutic potential of intracellular targeting of nano-delivery systems. In this study we report development and application of a novel ‘IntraCell’ plugin for ImageJ that is useful for quantitative assessment of uptake and intracellular localization of the drug/DDS and estimation of targeting efficiency. The developed plugin is based on threshold-based identification of borders of cell and of the individual organelles on confocal images and pixel-by-pixel analysis of fluorescence intensities.We applied the developed ‘IntraCell’ plugin to investigate uptake and intracellular targeting of novel endoplasmic reticulum (ER)-targeted delivery system based on PLGA nanoparticles decorated with ER-targeting or control peptides and encapsulating antigenic peptide and fluorescent marker. Decoration of the nanoparticles with peptidic residues affected their uptake and intracellular trafficking in HeLa cells, indicating that the targeting peptide was identified as ER-targeting signal by the intracellular trafficking mechanisms in HeLa cells and that these mechanisms can handle nano-DDS of the size comparable to some intracellular vesicles (hundreds of nanometers in diameter).We conclude that decoration of nanoparticles with peptidic residues affects their intracellular localization and trafficking and can be potentially used for intracellularly-targeted drug delivery. ‘IntraCell’ plugin is an useful tool for quantitative assessment of efficiency of uptake and intracellular drug targeting. In combination with other experimental approaches, it will be useful for the development of intracellularly-targeted formulations with enhanced and controlled drug pharmacological activities, such as delivery of antigenic peptides for anticancer vaccination and for other applications.     

Lymphatic transport of orally administered drugs

Several therapeutic molecules such as lipophilic drugs and peptides suffer from the problems of low oral bioavailability. Improvement of their bioavailability and simultaneous prevention of the oral degradation of the prone molecules appears to be a challenge. Lymphatic system, which is responsible for the maintenance of fluid balance, immunity and metastatic spread of cancers, is also found to play a major role in the oral absorption of lipids and lipophilic drugs from intestine. The specialized structure of gut associated lymphoid tissue can be utilized as a gateway for the delivery of particulate systems containing drugs. Even though a large gap has existed in the field of lymphatic drug delivery, the introduction of a large number of lipophilic drugs and peptides has brought a renewed interest of research in this area. In this review, the mechanisms of intestinal lymphatic drug transport, approaches taken for the delivery of macromolecules, lipophilic and peptide drugs, biochemical barriers involved in intestinal drug absorption, and animal models used in the studies of intestinal lymphatic drug transport has been discussed.     

Peptide Nanovesicles Formed by the Self-Assembly of Branched Amphiphilic Peptides

Peptide-based packaging systems show great potential as safer drug delivery systems. They overcome problems associated with lipid-based or viral delivery systems, vis-a-vis stability, specificity, inflammation, antigenicity, and tune-ability. Here, we describe a set of 15 & 23-residue branched, amphiphilic peptides that mimic phosphoglycerides in molecular architecture. These peptides undergo supramolecular self-assembly and form solvent-filled, bilayer delimited spheres with 50–200 nm diameters as confirmed by TEM, STEM and DLS. Whereas weak hydrophobic forces drive and sustain lipid bilayer assemblies, these all-peptide structures are stabilized potentially by both hydrophobic interactions and hydrogen bonds and remain intact at low micromolar concentrations and higher temperatures. A linear peptide lacking the branch point showed no self-assembly properties. We have observed that these peptide vesicles can trap fluorescent dye molecules within their interior and are taken up by N/N 1003A rabbit lens epithelial cells grown in culture. These assemblies are thus potential drug delivery systems that can overcome some of the key limitations of the current packaging systems.     

细胞穿膜肽介导蛋白/多肽类药物输送的研究进展

在当前药物研发中,蛋白/多肽类药物占据着重要地位。然而,此类药物大多需进入细胞内才能发挥作用,故细胞摄取率低的问 题成为制约其发展的关键因素。细胞穿膜肽是一类富含精氨酸的短肽,自身具有较强的生物膜穿透能力,可携带多种大分子甚至是纳米 粒入胞。因此,穿膜肽被广泛应用于药物输送,且基于穿膜肽介导药物胞内输送,成为解决蛋白/多肽类药物入胞问题的优选策略。主 要综述穿膜肽介导蛋白/多肽类药物输送用于不同疾病治疗的研究进展。     

Peptide-based biomaterials for protease-enhanced drug delivery

Controlled delivery of drugs in response to environments has the potential of targeting therapies and personalized treatments. Here, we described self-assembled peptide sequences that release therapeutic payloads upon specific interaction with disease-associated proteases. The core peptide sequence consists of a protease cleavable region flanked by two self-assembly motifs. In aqueous solution, the peptides self-assemble as a gel scaffold. With treatment of the model preparations with the appropriate protease, the matrix can be degraded in a controlled fashion, where the degradation rate is fine-tuned by varying the peptide compositions. Protease-mediated drug release was demonstrated by enzymatic treatment of a model therapeutic peptide incorporated into the optimized matrix. Our results suggest that this type of material may have far-reaching applications for functionally targeted drug delivery.     

An unexpected cell‐penetrating peptide from Bothrops jararaca venom identified through a novel size exclusion chromatography screening

Efficient drug delivery systems are currently one of the greatest challenges in pharmacokinetics, and the transposition of the gap between in vitro candidate molecule and in vivo test drug is, sometimes, poles apart. In this sense, the cell‐penetrating peptides (CPP) may be the bridge uniting these worlds. Here, we describe a technique to rapidly identify unlabeled CPPs after incubation with liposomes, based on commercial desalting (size exclusion) columns and liquid chromatography‐MS/MS, for peptide de novo sequencing. Using this approach, we found it possible to identify one new CPP – interestingly, a classical bradykinin‐potentiating peptide – in the peptide‐rich low molecular mass fraction of the Bothrops jararaca venom, which was also able to penetrate live cell membranes, as confirmed by classical approaches employing fluorescence‐labeled analogues of this CPP. Moreover, both the labeled and unlabeled CPPs caused no metabolic, cell‐cycle or morphologic alterations, proving to be unmistakably cargo deliverers and not drugs themselves. In sum, we have developed and validated a method for screening label‐free peptides for CPP activity, regardless of their biological origin, which could lead to the identification of new and more efficient drug delivery systems. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

环糊精及其衍生物在多肽/蛋白质类药物非注射给药体系中的应用

目前,多肽/蛋白质类药物多数需要采用注射剂型给药以确保其生物利用度。开发易于给药、病人顺应性高以及治疗费用更低的非注射剂型是非常有意义的。然而,多肽/蛋白质类药物直接进行非注射给药的生物利用度通常非常低,需要制备具有设计功能的载药系统,例如加入不同比例的酶抑制剂、吸收促进剂等以提高生物利用度。环糊精及其衍生物由于其能与客体分子形成包合物的特性,以及对粘膜的促渗透作用等,在多肽/蛋白质药物的非注射给药系统中获得了日益广泛的应用。综述了近年来环糊精及其衍生物在多肽/蛋白质类药物非注射给药体系中的应用情况。     

Carrier-mediated delivery of peptidic drugs for cancer therapy

Protein and peptide drugs are used for treatment of a variety of ailments. However, their wider use has been hindered by issues such as poor bioavailability in vivo and the cost involved in producing these drugs. This review discusses the various carrier-mediated methods used for delivery of peptide and protein drugs, with emphasis on liposomal and microspherical drug delivery systems. A brief look at the types of peptidic drugs currently in use clinically, and a brief discourse on several novel ideas for better protein delivery systems for cancer therapy is included.     

Use of X-ray scattering to aid the design and delivery of membrane-active drugs

Biological membranes can be targets for compounds that either disrupt their barrier function or affect protein function via membrane-mediated processes. Biophysical studies on membrane-mimetic systems composed of membrane lipids have contributed substantially to our knowledge on the pertaining membrane physics and aid the development of membrane-specific drugs. Moreover, lipid membranes and, in particular, liposomes are convenient systems for drug delivery. We review some of our recent work that demonstrates the applicability of X-ray scattering to understanding the molecular mechanisms of drug–membrane interactions. In particular we focus on effects of anesthetics, sphingomyelinase, and antimicrobial peptides. We further discuss X-ray scattering as a quality-control tool for liposomal drug-delivery systems.     

The role of peptides in blood-brain barrier nanotechnology.

The blood-brain barrier (BBB) regulates the passage of molecules between the bloodstream and the brain. Overcoming the difficulty of delivery drugs to specific areas of the brain is a major challenge. The BBB exerts a neuroprotective function as it hinders the delivery of diagnostic and therapeutic agents to the brain. Here, we provide an overview of the way in which peptides and nanotechnology are being exploited in tandem to address this problem. Peptides can be used as specialised coatings able to transport nanoparticles with specific properties, such as targeting. The nanoparticle can also carry a peptide drug. Furthermore, peptides can be used in less conventional approaches such as all-peptide nanoparticles. In summary, the combined use of peptides and nanotechnology offers tremendous hope in the treatment of brain disorders.     

Physical blends of starch graft copolymers as matrices for colon targeting drug delivery systems

Colon targeting drug delivery systems have attracted many researchers due to the distinct advantages they present such as near neutral pH, longer transit time and reduced enzymatic activity. Moreover, in recent studies, colon specific drug delivery systems are gaining importance for use in the treatment of local pathologies of the colon and also for the systemic delivery of protein and peptide drugs.In previous works, our group has developed different types of hydrophilic matrices with grafted copolymers of starch and acrylic monomers with a wide range of physicochemical properties which have demonstrated their ability in controlled drug release. Since the cost of synthesizing a new polymeric substance and testing for its safety is enormous, polymer physical blends are frequently used as excipients in controlled drug delivery systems due to their versatility. So, the aim of this work is to combine two polymers which offer different properties such as permeability for water and drugs, pH sensitivity and biodegradability in order to further enhance the release performance of various drugs. It was observed that these physical blend matrices offer good controlled release of drugs, as well as of proteins and present suitable properties for use as hydrophilic matrices for colon-specific drug delivery.     

Sequence and length optimization of membrane active coiled coils for triggered liposome release

Defined and tunable peptide-lipid membrane interactions that trigger the release of liposome encapsulated drugs may offer a route to improving the efficiency and specificity of liposome-based drug delivery systems, but this require means to tailor the performance of the membrane active peptides. In this paper, the membrane activity of a de novo designed coiled coil peptide has been optimized with respect to sequence and size to improve release efficiency of liposome encapsulated cargo. The peptides were only membrane active when covalently conjugated to the liposomes. Two amino acid substitutions were made to enhance the amphipathic characteristics of the peptide, which increased the release by a factor of five at 1?μM. Moreover, the effect of peptide length was investigated by varying the number of heptad repeats from 2 to 5, yielding the peptides KVC₂-KVC₅. The shortest peptide (KVC₂) showed the least interaction with the membrane and proved less efficient than the longer peptides in releasing the liposomal cargo. The peptide with three heptads (KVC₃) caused liposome aggregation whereas KVC₄ proved to effectively release the liposomal cargo without causing aggregation. The longest peptide (KVC₅) demonstrated the most defined α-helical secondary structure and the highest liposome surface concentration but showed slower release kinetics than KVC₄. The four heptad peptide KVC₄ consequently displayed optimal properties for triggering the release and is an interesting candidate for further development of bioresponsive and tunable liposomal drug delivery systems.     

Simulation study of interaction mechanism between peptide and asymmetric membrane

Cell-penetrating peptides (CPPs) are widely used as drug carriers, owing to their superior ability to cross cell membrane both alone and with cargos, such as genes and other particles. Understanding the translocation mechanism of CPP is significant for many therapeutic purposes, including targeting drug and gene delivery. In this study, we performed a coarse-grained molecular dynamics simulation to investigate the interaction mechanism between polyarginine peptides and asymmetric membranes. Results showed that peptides can penetrate through the lipid bilayer by inducing a hydrophilic hole formation in the asymmetric membrane. Furthermore, the lengthy peptide chain length (R4–R16 peptides) and high membrane asymmetry positively affect peptide penetration. Our study provides insights into the molecular-level interactions between peptides and asymmetric membranes, as well as suggestions for targeted gene and drug delivery.     

Quantitative assessment of peptide-lipid interactions.: Ubiquitous fluorescence methodologies

Peptide-membrane interactions have been gaining increased relevance, mainly in biomedical investigation, as the potential of the natural, nature-based and synthetic peptides as new drugs or drug candidates also expands. These peptides must face the cell membrane when they interfere with or participate in intracellular processes. Additionally, several peptide drugs and drug leads actions occur at the membrane level (e.g., antimicrobial peptides, cell-penetrating peptides and enveloped viruses membrane fusion inhibitors). Here we explore fluorescence spectroscopy methods that can be used to monitor such interactions. Two main approaches are considered, centered either on the peptide or on the membrane. On the first, we consider mainly the methodologies based on the intrinsic fluorescence of the aminoacid residues tryptophan and tyrosine. Regarding membrane-centric approaches, we review methods based on lipophilic probes sensitive to membrane potentials. The use of fluorescence constitutes a simple and sensitive method to measure these events. Unraveling the molecular mechanisms that govern these interactions can unlock the key to understand specific biological processes involving natural peptides or to optimize the action of a peptide drug.     

Cell adhesive peptide screening of the mouse laminin α1 chain G domain

Cell adhesive peptides have been widely applied for therapeutic drugs, drug delivery systems, and biomaterials. Previously, we identified various cell adhesive sequences in the G domains of four laminin α chains (α2-α5) by the systematic soluble peptide screening. We also identified five cell-binding sequences in the laminin α1 chain G domain using synthetic peptide-polystyrene beads. Here, we re-screened cell adhesive peptides in the laminin α1 chain G domain by the systematic soluble peptides screening. The 110 soluble peptides were evaluated for their cell adhesive activities using human fibrosarcoma HT1080 cells and human dermal fibroblasts. Fourteen peptides were newly identified as a cell adhesive. Additionally, four peptides (AG22: SSFHFDGSGYAM, AG42: TFDLLRNSYGVRK, AG76: HQNQMDYATLQLQ, AG86: LGGLPSHYRARNI) promoted integrin-mediated cell adhesion. Further, neurite outgrowth activity with rat pheochromocytoma PC12 cells was evaluated and two peptides (AG20: SIGLWNYIEREGK, AG26: SPNGLLFYLASNG) were newly identified for neurite outgrowth activity. These results suggested that the systematic soluble peptides screening approach is an accurate and powerful strategy for finding biologically active sequences. The active sequences newly identified here could be involved in the biological functions of this domain. The active peptides are useful for evaluating molecular mechanisms of laminin-receptor interactions and for developing cell adhesive biomaterials.     

A novel delivery platform for therapeutic peptides

Although many peptides have therapeutic effects against diverse disease, their short half-lives in vivo hurdle their application as drug candidates. To extend the short elimination half-lives of therapeutic peptides, we developed a novel delivery platform for therapeutic peptides using an anti-hapten antibody and its corresponding hapten. We selected cotinine because it is non-toxic, has a well-studied metabolism, and is physiologically absent. We conjugated WKYMVm-NH₂, an anti-sepsis therapeutic peptide, to cotinine and showed that the conjugated peptide in complex with an anti-cotinine antibody has a significantly improved in vivo half-life while retaining its therapeutic efficacy. We suggest that this novel delivery platform for therapeutic peptides will be very useful to develop effective peptide therapeutics.