CyLoP-1 is a cysteine-rich cell-penetrating peptide derived from nuclear localization sequence of snake toxin, crotamine. The peptide has shown cytoplasmic uptake in mammalian cells at lower concentrations. In the present study, the cell-penetrating and antimicrobial activity of the peptide has been studied by employing mammalian cells, plant cells as well as bacterial and fungal pathogens. The study shows that the peptide acts as an effective CPP and a cargo-delivery vector for not only mammalian cells but also for plant cells. Besides this, the peptide also possesses antimicrobial activity against representative pathogens tested. It is shown to be effective in killing methicillin-resistant Staphylococcus aureus. We have observed that the presence of cysteine residues in the peptide play a major role in conferring cell-penetrating as well as antimicrobial activity to the peptide since there is a significant decline in these activities when cysteine residues are replaced with serine residues. Our findings are significant for the proposition that CyLoP-1 is an efficient membrane-active peptide with both cell-penetrating and antimicrobial activity. Hence, it can be further evaluated for its application in the field of drug-delivery, plant biotechnology and as a peptide-antibiotic.
Osmotic behavior of erythrocytes is not only important clinically, but is also significant in understanding of material transport across biological membranes. It is most commonly studied through fragiligrams – plots of the degree of hemolysis as a function of extracellular osmolarity. A fundamental assumption in experimental and theoretical studies on osmolarity driven transport of water across the plasma membranes of all cells is the sigmoidal nature of their osmotic behavior. Sigmoidal data is mathematically monotonic showing either a decreasing only or an increasing only trend, but not both, within certain thresholds; beyond these thresholds the data is asymptotic or flat. Fragiligrams of erythrocytes are usually sigmoidal, with maximal hemolysis in plain solute-free water and often up to a certain extracellular hypotonic environment. In this work, we report a new discovery of non-monotonic osmotic behavior of avian erythrocytes. In contrast to the expected monotonic fragiligrams obtained for mammalian erythrocytes, fragiligrams of avian erythrocytes show non-monotonic curves. Maximal hemolysis of avian erythrocytes was not observed at the most hypotonic conditions – instead, maximal hemolysis was observed at mild hypotonic conditions. Hemolysis of avian erythrocytes first increases then decreases with increasing extracellular osmolarity. We also report that the non-monotonic fragiligrams of chicken erythrocytes are converted to the expected monotonic sigmoids subsequent to controlled extracellular trypsinization. While possibly having profound evolutionary implications for vertebrates, the findings reported in this work have a direct impact on understanding of avian physiology. Our results also compel revisiting of experimental and theoretical models for understanding material transport across biological membranes under different osmotic conditions.
Marine organisms are known to be a rich and unique source of bioactive compounds as they are exposed to extreme conditions in the oceans. The present study is an attempt to briefly describe some of the important membrane-active peptides (MAPs) such as antimicrobial peptides (AMPs), cell-penetrating peptides (CPPs) and peptide toxins from marine organisms. Since both AMPs and CPPs play a role in membrane perturbation and exhibit interchangeable role, they can speculatively fall under the broad umbrella of MAPs. The study focuses on the structural and functional characteristics of different classes of marine MAPs. Further, AMPs are considered as a potential remedy to antibiotic resistance acquired by several pathogens. Peptides from marine organisms show novel post-translational modifications such as cysteine knots, halogenation and histidino-alanine bridge that enable these peptides to withstand harsh marine environmental conditions. These unusual modifications of AMPs from marine organisms are expected to increase their half-life in living systems, contributing to their increased bioavailability and stability when administered as drug in in vivo systems. Apart from AMPs, marine toxins with membrane-perturbing properties could be essentially investigated for their cytotoxic effect on various pathogens and their cell-penetrating activity across various mammalian cells. The current review will help in identifying the MAPs from marine organisms with crucial post-translational modifications that can be used as template for designing novel therapeutic agents and drug-delivery vehicles for treatment of human diseases.
Nanotechnology-based pharmaceutics is a fast emerging field in the diagnosis and therapy of a number of human diseases, including cancer. Nanoparticles offer a stable means to achieve targeted drug delivery to various cells and tissues. They have been investigated for drug delivery to different tumor tissues, to brain where the blood-brain barrier poses a significant problem in the delivery of effective therapeutic molecules, to ocular tissues and also for eliciting immune response via delivery of vaccines. Particularly, the small size of nanoparticles facilitates their easy access to a wide range of cells and tissues. Further, the size of nanoparticles can be controlled and their surface can be modified with desired ligands and receptors to specifically target cells of interest as well as achieve controlled drug release. Research is being carried out on numerous biological and synthetic nanoparticles. Diverse strategies are being developed to improve their stability, specificity and drug delivery efficiency. Nanoparticles have been also used in conjunction with cellpenetrating peptides for efficient drug delivery. Cellpenetrating peptides serve as efficient nanocarriers owing to their inherent ability to cross the plasma membrane barrier and deliver cargo to intracellular targets. Modification of nanoparticles with cell-penetrating peptides further increases their efficacy for increased permeation into varied cells and tissues. The current review focuses on different classes of nanoparticles and their application in the treatment of several types of diseases. Key PointsNanoparticle-based therapeutic drugs are widely used for the treatment of a number of diseases, including cancer.Ease of modulation of size and tuning of the nanoparticles with various ligands make them effective for formulation into specific drugs with increased therapeutic index and reduced toxicity.Successful pre-clinical and early phase clinical trials have promised the emergence of nanocarrier-based drugs.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.