Cationic host defence peptides (CHDP), also known as antimicrobial peptides, are naturally-occurring peptides which can combat infections through their direct microbicidal properties and/or by influencing the host's immune responses. The unique ability of CHDP to control infections as well as resolve harmful inflammation has generated interest in harnessing the properties of these peptides to develop new therapies for infectious diseases, chronic inflammatory disorders and wound healing. Various strategies have been employed to design synthetic optimized peptides, with negligible toxicity. Here, we focus on the progress made in understanding the scope of functions of CHDP and the emerging potential clinical applications of CHDP-based therapies. This has led to the adoption of the current name for this family of peptides, Cationic Host Defence Peptides, which encompasses the wide range of described functions. Over the last three decades there has been substantial interest in therapeutically harnessing CHDP, with more than 5000 papers published in this area of research since 2017 alone. These include the examination of potential clinical uses for CHDP ranging from infections including multidrug-resistant bacteria 16-19 , to chronic inflammatory diseases such as arthritis 20 , asthma 21 and colitis 22 , as well as some cancers 23. Peptide-based therapeutics currently in clinical trials are primarily for the treatment of infections such as respiratory, oral and catheter-related infections, and for wound healing (see http://dramp.cpu-bioinfor.org/browse/ClinicalTrialsData.php). This review will provide an overview of current understanding of the scope of functions of CHDP, primarily from eukaryotes. Emerging therapeutic applications of these peptides, current clinical trials and the associated clinical developmental challenges will be discussed. Although there is increasing interest in the development of non-peptide mimics of CHDP for therapeutic application, such as peptoid analogs (reviewed in 24), a comprehensive discussion of these approaches is beyond the scope of this review. [H1] Naturally occurring CHDP The antimicrobial peptide database has catalogued more than 2600 natural antimicrobial peptides, including those annotated as immunomodulatory 25. The major families of CHDP from eukaryotes that are of interest from a drug discovery perspective are summarized below. [H2] Vertebrate CHDP CHDP from vertebrates have an essential role in the first line of defense against microbial pathogens. Upon infection, CHDP can kill pathogens through diverse mechanisms 26-31 (discussed below), acting rapidly and directly on the pathogen when present in high local concentrations, or indirectly to modify components of host defense. These peptides exhibit immunomodulatory activities that can be either pro-or anti-inflammatory depending on the phase of the infection (see below) 12-14,29. CHDP from vertebrates are amphipathic peptides containing amino acids with hydrophilic and hydrophobic side chains at opposite sides of the molec...
Several members of the Rubiaceae and Violaceae families produce a series of cyclotides or macrocyclic peptides of 29 -31 amino acids with an embedded cystine knot. We aim to understand the mechanism of synthesis of cyclic peptides in plants and have isolated a cDNA clone that encodes the cyclotide kalata B1 as well as three other clones for related cyclotides from the African plant Oldenlandia affinis. The cDNA clones encode prepropeptides with a 20-aa signal sequence, an N-terminal prosequence of 46 -68 amino acids and one, two, or three cyclotide domains separated by regions of about 25 aa. The corresponding cyclotides have been isolated from plant material, indicating that the cyclotide domains are excised and cyclized from all four predicted precursor proteins. The exact processing site is likely to lie on the N-terminal side of the strongly conserved GlyLeuPro or SerLeuPro sequence that flanks both sides of the cyclotide domain. Cyclotides have previously been assigned an antimicrobial function; here we describe a potent inhibitory effect on the growth and development of larvae from the Lepidopteran species Helicoverpa punctigera.
Self-incompatibility in flowering plants is often controlled by a single nuclear gene (the S-gene) having several alleles. This gene prevents fertilization by self-pollen or by pollen bearing either of the two S-alleles expressed in the style. Sequence analysis shows that three alleles of the S gene of Nicotiana alata encode style glycoproteins with regions of defined homology. Two of the homologous regions also show precise homology with ribonucleases T2 (ref. 4) and Rh (ref. 5). We report here that glycoproteins corresponding to the S1, S2, S3, S6 and S7 alleles isolated from style extracts of N. alata are ribonucleases. These style S-gene-encoded glycoproteins account for most of the ribonuclease activity recovered from style extracts. The ribonuclease specific activity of style extracts of the self-incompatible species N. alata is 100-1,000-fold higher than that of the related self-compatible species N. tabacum. These observations implicate ribonuclease activity in the mechanism of gametophytic self-incompatibility.
Cyclotides are diverse plant backbone cyclized peptides that have attracted interest as pharmaceutical scaffolds, but fundamentals of their biosynthetic origin remain elusive. Backbone cyclization is a key enzyme-mediated step of cyclotide biosynthesis and confers a measure of stability on the resultant cyclotide. Furthermore, cyclization would be desirable for engineered peptides. Here we report the identification of four asparaginyl endopeptidases (AEPs), proteases implicated in cyclization, from the cyclotide-producing plant Oldenlandia affinis. We recombinantly express OaAEP1b and find it functions preferably as a cyclase by coupling C-terminal cleavage of propeptide substrates with backbone cyclization. Interestingly, OaAEP1b cannot cleave at the N-terminal site of O. affinis cyclotide precursors, implicating additional proteases in cyclotide biosynthesis. Finally, we demonstrate the broad utility of this enzyme by cyclization of peptides unrelated to cyclotides. We propose that recombinant OaAEP1b is a powerful tool for use in peptide engineering applications where increased stability of peptide products is desired.
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.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.