Border sequences of Medicago truncatula CLE36 are specifically cleaved by endoproteases common to the extracellular fluids of Medicago and soybean

CLE (CLAVATA3/ESR-related) peptides are developmental regulators that are secreted into the apoplast. Little is known about the role of the sequences that flank CLE peptides in terms of their biological activity or how they are targeted by proteases that are known to liberate the final active CLE peptides from their precursor sequences. The biological activity of Medicago truncatula CLE36, which possesses broadly conserved border sequences flanking the putative final active CLE36 peptide product, was assessed. Using in vitro root growth assays and an in vitro root and callus formation assay it is shown that CLE36 peptides of different lengths possess differential biological activities. Using mass spectrometry, Glycine max and Medicago extracellular fluids were each shown to possess an endoproteolytic activity that recognizes and cleaves at border sequences in a synthetic 31 amino acid CLE36 'propeptide bait' to liberate biologically active peptide products. Inhibitor studies suggest that a subtilisin, in combination with a carboxypeptidase, liberated and trimmed CLE36, respectively, to form biologically relevant 11-15 amino acid cleavage products. The 15 amino acid cleavage product is more biologically potent on Arabidopsis than shorter or longer CLE peptides. In situ hybridization shows that the soybean orthologue of CLE36 (GmCLE34) is expressed in the provascular tissue. The results suggest that secreted subtilisins can specifically recognize the border sequences of CLE36 propeptides and liberate biologically active cleavage products. These secreted proteases may affect the stability and biological activity of CLE peptides in the apoplast or be involved in CLE36 processing.     

Structural features and biological activities of the cathelicidin-derived antimicrobial peptides

Cathelicidins are a numerous group of mammalian proteins that carry diverse antimicrobial peptides at the C-terminus of a highly conserved preproregion. These peptides, which become active when released from the proregion, display a remarkable variety of sizes, sequences, and structures, and in fact comprise representatives of all the structural groups in which the known antimicrobial peptides have been classified. Most of the cathelicidin-derived peptides exert a broad spectrum and potent antimicrobial activity and also bind to lipopolysaccharide and neutralize its effects. In addition, some of them have recently been shown to exert other activities and might participate in host defense also by virtue of their ability to induce expression of molecules involved in a variety of biological processes. This review is aimed at providing a general overview of the cathelicidins and of the peptides derived therefrom, with emphasis on aspects such as structure, biological activities in vitro and in vivo, and structure/activity relationship studies.     

Antimicrobial fragments of the pro-region of cathelicidins and other immune peptides

In addition to the numerous cathelicidin peptides that are associated with the antimicrobial activity exhibited by a crude extract from ovine blood, a further three peptides with antimicrobial activity have been identified. These were part of the precursor cathelin domain of cathelicidins, a large fragment of platelet factor 4 and a small peptide similar to signal peptide of the T-cell glycoprotein CD4 precursor. Fragments of proteins that are involved in protecting the host from infection may have a secondary purpose as antimicrobial agents once they have carried out their primary purpose and are cleaved the main protein.     

Localization and genomic organization of sheep antimicrobial peptide genes

Antimicrobial peptides are an abundant and diverse component of animal innate immunity. Within mammalian species, defensins and cathelicidins are the two principal antimicrobial peptide families. We identified and sequenced ten new sheep genes which encode potential antimicrobial peptides including two β-defensins and eight cathelicidins. We mapped the two-exon β-defensin genes to sheep chromosome 26 and the four-exon cathelicidin genes to sheep chromosome 19 using sheep–hamster somatic cell hybrids in conjunction with flow-sorted sheep chromosomes. These assignments confirm homology between sheep, cattle, mouse, and human antimicrobial peptide gene families. Contig construction for the sheep cathelicidin gene family demonstrates that three genes, OaDodeA, OaDodeB, and OaMAP-34, are present head-to-tail in a 14.5 kb region, and that four proline/arginine-rich genes, OaBac5, OaBac7.5, OaBac11, and OaBac6, are arranged head-to-tail in a region covering 30.5 kb. This richly diverse family of sheep cathelicidin peptides is encoded in a gene array which may reflect the mechanism of its evolution.     

Structure formation in short designed peptides probed by proteolytic cleavage

The formation of local structure, in short peptides has been probed by examining cleavage patterns and rates of proteolysis of designed sequences with a high tendency to form beta-hairpin structures. Three model sequences which bear fluorescence donor and acceptor groups have been investigated: [see text]. Fluorescence resonance energy transfer (FRET) provides a convenient probe for peptide cleavage. MALDI mass spectrometry has been used to probe sites of cleavage and CD spectroscopy to access the overall backbone conformation using analog sequences, which lack strongly absorbing donor and acceptor groups. The proteases trypsin, subtilisin, collagenase, elastase, proteinase K and thermolysin were used for proteolysis and the rates of cleavage determined. Peptide 3 is the most susceptible to cleavage by all the enzymes except thermolysin, which cleaves all three peptides at comparable rates. Peptides 1 and 2 are completely resistant to the action of trypsin, suggesting that beta-turn formation acts as a deterrent to proteolytic cleavage.     

Antimicrobial activity and stability to proteolysis of small linear cationic peptides with D-amino acid substitutions

Antimicrobial peptides contribute to innate host defense against a number of bacteria and fungal pathogens. Some of antimicrobial synthetic peptides were systemically administered in vivo; however, effective protection has so far not been obtained because the effective dose of peptides in vivo seems to be very high, often close to the toxic level against the host. Alternatively, peptides administered in vivo may be degraded by certain proteases present in serum. In this study, D-amino acids were substituted for the L-amino acids of antimicrobial peptides to circumvent these problems. Initially a peptide (L-peptide) rich in five arginine residues and consisting of an 11-amino acid peptide (residues 32-42) of human granulysin was synthesized. Subsequently, the L-amino acids of the 11-amino acid peptide were replaced partially (D-peptide) or wholly (AD-peptide) with D-amino acids. Activity and stability to proteolysis, in particular, in the serum of antimicrobial peptides with D-amino acid substitutions were examined. Peptides with D-amino acid substitutions were found to lyse bacteria as efficiently as their all-L-amino acid parent, L-peptide. In addition, the peptide composed of L-amino acids was susceptible to trypsin, whereas peptides containing D-amino acid substitutions were highly stable to trypsin treatment. Similarly, the peptide consisting of L-amino acids alone was also susceptible to fetal calf serum (FCS), however, protease inhibitors restored the lowered antimicrobial activity of the FCS-incubated peptide. Thus, D-amino acid substitutions can make antimicrobial peptides resistant to proteolysis, suggesting that the antimicrobial peptides consisting of D-amino acids are potential candidates for clinical therapeutic use.     

抗菌肽在大肠杆菌中的融合表达

抗菌肽作为新一代抗生素的潜在应用价值使其备受关注,大量高纯度的抗菌肽是开展基础及临床实验的关键。天然来源的抗菌肽资源有限、纯化困难,化学合成抗菌肽成本高、活性不稳定,因此通过基因重组表达得到大量抗菌肽是低成本、高效益的方法。目前采用大肠杆菌表达系统获得抗菌肽已成为研究者的首选,通常以形成融合蛋白的方式表达,这不仅可避免抗菌肽对宿主的杀伤作用,也保护了抗菌肽免受蛋白酶降解。文章结合课题组的研究工作,综述了近年来抗菌肽在大肠杆菌中表达的融合载体、融合蛋白的裂解方法及表达条件优化的研究进展。     

Cleavage Specificity Analysis of Six Type II Transmembrane Serine Proteases (TTSPs) Using PICS with Proteome-Derived Peptide Libraries

Background

Type II transmembrane serine proteases (TTSPs) are a family of cell membrane tethered serine proteases with unclear roles as their cleavage site specificities and substrate degradomes have not been fully elucidated. Indeed just 52 cleavage sites are annotated in MEROPS, the database of proteases, their substrates and inhibitors.

Methodology/Principal Finding

To profile the active site specificities of the TTSPs, we applied Proteomic Identification of protease Cleavage Sites (PICS). Human proteome-derived database searchable peptide libraries were assayed with six human TTSPs (matriptase, matriptase-2, matriptase-3, HAT, DESC and hepsin) to simultaneously determine sequence preferences on the N-terminal non-prime (P) and C-terminal prime (P’) sides of the scissile bond. Prime-side cleavage products were isolated following biotinylation and identified by tandem mass spectrometry. The corresponding non-prime side sequences were derived from human proteome databases using bioinformatics. Sequencing of 2,405 individual cleaved peptides allowed for the development of the family consensus protease cleavage site specificity revealing a strong specificity for arginine in the P1 position and surprisingly a lysine in P1′ position. TTSP cleavage between R↓K was confirmed using synthetic peptides. By parsing through known substrates and known structures of TTSP catalytic domains, and by modeling the remainder, structural explanations for this strong specificity were derived.

Conclusions

Degradomics analysis of 2,405 cleavage sites revealed a similar and characteristic TTSP family specificity at the P1 and P1′ positions for arginine and lysine in unfolded peptides. The prime side is important for cleavage specificity, thus making these proteases unusual within the tryptic-enzyme class that generally has overriding non-prime side specificity.     

How do bacteria resist human antimicrobial peptides?

Cationic antimicrobial peptides (CAMPs), such as defensins, cathelicidins and thrombocidins, are an important human defense mechanism, protecting skin and epithelia against invading microorganisms and assisting neutrophils and platelets. Staphylococcus aureus, Salmonella enterica and other bacterial pathogens have evolved countermeasures to limit the effectiveness of CAMPs, including the repulsion of CAMPs by reducing the net negative charge of the bacterial cell envelope through covalent modification of anionic molecules (e.g. teichoic acids, phospholipids and lipid A); expelling CAMPs through energy-dependent pumps; altering membrane fluidity; and cleaving CAMPs with proteases. Mutants susceptible to CAMPs are more efficiently inactivated by phagocytes and are virulence-attenuated, indicating that CAMP resistance plays a key role in bacterial infections.     

The unconventional antimicrobial peptides of the classical propionibacteria

The classical propionibacteria produce genetically unique antimicrobial peptides, whose biological activities are without equivalents, and to which there are no homologous sequences in public databases. In this review, we summarize the genetics, biochemistry, biosynthesis, and biological activities of three extensively studied antimicrobial peptides from propionibacteria. The propionicin T1 peptide constitutes a bona fide example of an unmodified general secretory pathway (sec)-dependent bacteriocin, which is bactericidal towards all tested species of propionibacteria except Propionibacterium freudenreichii. The PAMP antimicrobial peptide represents a novel concept within bacterial antagonism, where an inactive precursor protein is secreted in large amounts, and which activation appears to rely on subsequent processing by proteases in its resident milieu. Propionicin F is a negatively charged bacteriocin that displays an intraspecies bactericidal inhibition spectrum. The biosynthesis of propionicin F appears to proceed through a series of unusual events requiring both N- and C-terminal processing of a precursor protein, which probably requires the radical SAM superfamily enzyme PcfB.     

Identification and functional characterization of three chicken cathelicidins with potent antimicrobial activity

Cathelicidins comprise a family of antimicrobial peptides sharing a highly conserved cathelin domain. Here we report that the entire chicken genome encodes three cathelicidins, namely fowlicidin-1 to -3, which are densely clustered within a 7.5-kb distance at the proximal end of chromosome 2p. Each fowlicidin gene adopts a fourexon, three-intron structure, typical for a mammalian cathelicidin. Phylogenetic analysis revealed that fowlicidins and a group of distantly related mammalian cathelicidins known as neutrophilic granule proteins are likely to originate from a common ancestral gene prior to the separation of birds from mammals, whereas other classic mammalian cathelicidins may have been duplicated from the primordial gene for neutrophilic granule proteins after mammals and birds are diverged. Similar to ovine cathelicidin SMAP-29, putatively mature fowlicidins displayed potent and salt-independent activities against a range of Gram-negative and Gram-positive bacteria, including antibiotic-resistant strains, with minimum inhibitory concentrations in the range of 0.4-2.0 microm for most strains. Fowlicidin-1 and -2 also showed cytotoxicity, with 50% killing of mammalian erythrocytes or epithelial cells in the range of 6-40 microm. In addition, two fowlicidins demonstrated a strong positive cooperativity in binding lipopolysaccharide (LPS), resulting in nearly complete blockage of LPS-mediated proinflammatory gene expression in RAW264.7 cells. Taken together, fowlicidin-1 and -2 are clearly among the most potent cathelicidins that have been reported. Their broad spectrum and salt-insensitive antibacterial activities, coupled with their potent LPS-neutralizing activity, make fowlicidins excellent candidates for novel antimicrobial and anti-sepsis agents.     

Methods for mapping protease specificity

The study of protease specificity provides information on active-site structure and function, protein-protein interaction, regulation of intracellular and extracellular pathways, and evolution of protease and substrate genes. Peptide libraries that include fluorogenic and binding tags are often generated by solid-phase synthesis. Even larger explorations of cleavage site preferences employ positional scanning libraries or phage display. Microarrays enable presentation of individual peptides to proteases, DNA sequences for capture of peptide nucleic acid encoded peptides, or nanodroplets containing soluble peptide sequences. These new methods continue to inform the design of chemical inhibitors and the identification of substrates of proteases.     

Role of Cathelicidin Peptides in Bovine Host Defense and Healing

The in vitro antimicrobial activities and biological effects on host cells were compared for the bovine cathelicidins BMAP-28, an alpha-helical AMP, and Bac5 and Bac7, proline-rich AMPs. Our results confirm that the broad-spectrum activity of BMAP-28 correlates with a high capacity to interact with and permeabilize bacterial membranes, whereas the proline-rich AMPs selectively internalize into the cytoplasm of susceptible Gram-negative bacteria with a non-lytic mechanism. All peptides efficiently translocated into mammalian fibroblastic cells, but while Bac5 and Bac7(1–35) localized to nuclear structures and induced cellular proliferation, BMAP-28 associated with mitochondria and did not induce proliferation. Moreover, BMAP-28 was considerably more cytotoxic than the proline-rich peptides due to cytolytic and pro-apoptotic effects. Our results highlight important functional differences among the bovine cathelicidins and suggest that they contribute to an integrated response of the host to infection, with distinct but complementary activities.     

Identification and characterization of novel reptile cathelicidins from elapid snakes

Three cDNA sequences coding for elapid cathelicidins were cloned from constructed venom gland cDNA libraries of Naja atra, Bungarus fasciatus and Ophiophagus hannah. The open reading frames of the cloned elapid cathelicidins were all composed of 576bp and coded for 191 amino acid residue protein precursors. Each of the deduced elapid cathelicidin has a 22 amino acid residue signal peptide, a conserved cathelin domain of 135 amino acid residues and a mature antimicrobial peptide of 34 amino acid residues. Unlike the highly divergent cathelicidins in mammals, the nucleotide and deduced protein sequences of the three cloned elapid cathelicidins were remarkably conserved. All the elapid mature cathelicidins were predicted to be cleaved at Valine157 by elastase. OH-CATH, the deduced mature cathelicidin from king cobra, was chemically synthesized and it showed strong antibacterial activity against various bacteria with minimal inhibitory concentration of 1-20microg/ml in the presence of 1% NaCl. Meanwhile, the synthetic peptide showed no haemolytic activity toward human red blood cells even at a high dose of 200microg/ml. Phylogenetic analysis of cathelicidins from vertebrate suggested that elapid and viperid cathelicidins were grouped together in the tree. Snake cathelicidins were evolutionary closely related to the neutrophilic granule proteins (NGPs) from mouse, rat and rabbit. Snake cathelicidins also showed a close relationship with avian fowlicidins (1-3) and chicken myeloid antimicrobial peptide 27. Elapid cathelicidins might be used as models for the development of novel therapeutic drugs.     

Antimicrobial peptides important in innate immunity

Antimicrobial peptides are present in all walks of life, from plants to animals, and they are considered to be endogenous antibiotics. In general, antimicrobial peptides are determinants of the composition of the microbiota and they function to fend off microbes and prevent infections. Antimicrobial peptides eliminate micro-organisms through disruption of their cell membranes. Their importance in human immunity, and in health as well as disease, has only recently been appreciated. The present review provides an introduction to the field of antimicrobial peptides in general and discusses two of the major classes of mammalian antimicrobial peptides: the defensins and the cathelicidins. The review focuses on their structures, their main modes of action and their regulation.     

Tool developments for structure-function studies of host defense peptides

Antimicrobial peptides, or host defense peptides, are universal signaling and effector molecules in host defense and innate immunity. This article highlights various tools developed for cathelicidins and defensins, ranging from peptide identification, production, and structural biology, including the eight databases for antimicrobial peptides. Novel peptides can be identified from natural sources at both gene and protein levels. Solid-phase synthesis and bacterial expression are the two important methods for peptide production. Three-dimensional structures of antimicrobial peptides, primarily determined by solution NMR techniques, are essential for an in-depth understanding of the mode of action. The introduction of octanoyl phosphatidylglycerol as a bacterial membrane-mimetic model provides new insights into peptide-lipid interactions. The incorporation of structure and activity data into the antimicrobial peptide database (http://aps.unmc.edu/AP/main.html) will lead to an integrated understanding of these peptides via structural bioinformatics.     

Rational Design of a Carrier Protein for the Production of Recombinant Toxic Peptides in Escherichia coli

Commercial uses of bioactive peptides require low cost, effective methods for their production. We developed a new carrier protein for high yield production of recombinant peptides in Escherichia coli very well suited for the production of toxic peptides like antimicrobial peptides. GKY20, a short antimicrobial peptide derived from the C-terminus of human thrombin, was fused to the C-terminus of Onconase, a small ribonuclease (104 amino acids), which efficiently drove the peptide into inclusion bodies with very high expression levels (about 200–250 mg/L). After purification of the fusion protein by immobilized metal ion affinity chromatography, peptide was obtained by chemical cleavage in diluted acetic acid of an acid labile Asp-Pro sequence with more than 95% efficiency. To improve peptide purification, Onconase was mutated to eliminate all acid labile sequences thus reducing the release of unwanted peptides during the acid cleavage. Mutations were chosen to preserve the differential solubility of Onconase as function of pH, which allows its selective precipitation at neutral pH after the cleavage. The improved carrier allowed the production of 15–18 mg of recombinant peptide per liter of culture with 96–98% purity without the need of further chromatographic steps after the acid cleavage. The antimicrobial activity of the recombinant peptide, with an additional proline at the N-terminus, was tested on Gram-negative and Gram-positive strains and was found to be identical to that measured for synthetic GKY20. This finding suggests that N-terminal proline residue does not change the antimicrobial properties of recombinant (P)GKY20. The improved carrier, which does not contain cysteine and methionine residues, Asp-Pro and Asn-Gly sequences, is well suited for the production of peptides using any of the most popular chemical cleavage methods.     

The role of cathelicidins in the innate host defenses of mammals

The cathelicidin peptides comprise one of several families of antimicrobial peptides that are found in neutrophils and epithelia as components of the early host defenses of mammals against infection. All cathelicidin family members are synthesized and stored in cells as two-domain proteins. These are split on demand to produce a cathelin protein and an antimicrobial peptide. Accumulating evidence indicates that both the cathelin portion and the C-terminal peptide exert biological activities connected with host protection. This review presents an overview of the structure and biology of cathelicidins and discusses recent progress in cathelicidin research with emphasis on the functional properties and role in host defense of the human cathelicidin hCAP18/LL-37. Although investigators initially concentrated their attention on antibiotic activity, it is becoming clear now that LL-37 is a multifunctional molecule that may mediate various host responses, and thus represents an essential component of the innate immune system in humans.     

Peptide Fragments From Plant Vicilins Expressed in <Emphasis Type="Italic">Escherichia Coli</Emphasis> Exhibit Antimicrobial Activity <Emphasis Type="Italic">In Vitro</Emphasis>

Peptide fragments that exhibit antimicrobial activity in vitro have been shown to be produced by cleavage from the hydrophilic region near the N terminus of various vicilin proteins in plant seeds. Three peptide sequences identified in the hydrophilic region of vicilin seed proteins of Macadamia integrifolia and Theobroma cacao were predicted to exhibit antimicrobial activity based on sequence similarity to antimicrobial peptides that had been previously purified from macadamia kernels. Histidine-tagged versions of the putative antimicrobial peptides were expressed in Escherichia coli, purified, and demonstrated to have in vitro antimicrobial activity. There are many vicilin sequences in the growing plant genome sequence databases, and this expression method provides a high-throughput process for functionally testing the potential of internal peptide fragments of vicilins as novel antimicrobial molecules.