Antibacterial and immunoregulatory activity of an antimicrobial peptide hepcidin in loach (Misgurnus anguillicaudatus)

Evaluating the Antimicrobial Efficacy of TroLEAP2 like-27 peptide in golden pompano (Trachinotus ovatus) against Bacterial Pathogens

Amicrobial peptides are crucial components of immune system, acting as the first line of defense against microbial invasion. This study investigated the antimicrobial activity of TroLEAP2 like-27, a novel 27-amino acid peptide derived from golden pompano (Trachinotus ovatus), against Gram-positive Lactococcus garvieae and Staphylococcus epidermidis, and Gram-negative Vibrio alginolyticus and Vibrio harveyi. The 3D structure and helical wheel presentation of TroLEAP2 like-27 were consistent with typical AMP features. The hydrophobic ratio of TroLEAP2 like-27 was 47 %, and its α-helical structure suggested strong antimicrobial potential. The expression levels of the TroLEAP2 like gene in the liver and intestines tissues of T. ovatus were significantly upregulated following infection with L. garvieae and V. harveyi. The peptide induced bacterial agglutination in the presence of Ca2+ and exhibited bactericidal activity with a MIC50 of 60 μM. Transmission electron microscopy (TEM) revealed structural damage to bacterial membranes, while membrane permeability assays showed dose-dependent disruption and depolarization in all tested strains. Additionally, TroLEAP2 like-27 exhibited a potent capacity to interact with and degrade genomic DNA of all tested bacteria. The peptide treatment significantly reduced bacterial loads in the gill, liver, and intestinal tissues of the fish, with histological analysis revealing a remarkable protective effect on the tissues. Furthermore, fish treated with TroLEAP2 like-27 exhibited improved survival rates following bacterial infection. These findings suggest that TroLEAP2 like-27 is a promising antimicrobial peptide with potential therapeutic applications.

Unveiling the Modes of Action of a Recombinant Antimicrobial Peptide, Hepcidin (rGf-Hep), from Gerres filamentosus Against Pathogenic Vibrios: Membrane Disintegration and Reactive Oxygen Species Generation Leading to Cell Death

Antimicrobial peptides (AMPs) are essential components of the innate immune response, which play a significant role in combating pathogenic infections. Hepcidin, a peptide hormone predominantly synthesized in the liver, has been identified to exhibit dual functions in iron metabolism and antimicrobial activity across various organisms. In this study, we describe the molecular characteristics, anti-vibrio activity, and mechanisms of action of a novel hepcidin isoform from the commercially important estuarine fish, Whipfin silver-biddy (Gerres filamentosus). The open reading frame of hepcidin cDNA sequence was 273 base pairs in length, encoding a peptide of 90 amino acids. The active region Gf-Hep contains eight well-conserved cysteine residues which form disulfide bridges stabilizing the antiparallel beta sheet conformation of the peptide. Featuring a C-terminal furin cleavage site (RXXR) within the prodomain and an N-terminal 'QSHI/LS' motif in the mature region, Gf-Hep is classified with the HAMP1 group of fish hepcidins. Recombinantly expressed Gf-Hep exhibited robust antimicrobial activity against Vibrio parahaemolyticus, Vibrio fluvialis, Vibrio cholerae, and Vibrio alginolyticus. The modes of action of rGf-Hep included membrane depolarization, membrane permeabilization, and ROS production. With its potent antibacterial properties, direct killing mechanisms, and non-cytotoxic effects on normal cells, rGf-Hep holds promise to be developed as an effective anti-vibrio agent for aquaculture applications.

Complement-activated fragment Ba functions as an antibacterial protein and mediates immune responses in lower vertebrates

The complement system plays an important role in antibacterial infection and immune regulation. Ba, an important complement component, is produced and released by the cleavage of complement factor B during complement activation. However, the immune functions of Ba are unclear. In this study, we reported that recombinant Ba exerted direct bactericidal and immune regulatory effects. Recombinant Paralichthys olivaceus Ba (rPoBa) bound bacteria via interaction with the bacterial wall component lipopolysaccharide, resulting in bacterial membrane permeabilization and bacterial death. Furthermore, rPoBa exhibited bactericidal activity against Gram-negative bacteria in a manner that depended on concentration, time, temperature, pH, and metal ions. Structure prediction analysis showed that PoBa contained three distinct complement control protein (CCP) domains. CCP1 was mainly responsible for binding to lipopolysaccharide, and both CCP1 and CCP3 might be required for bacterial membranous permeabilization. The bactericidal effects of Ba were observed only in lower vertebrates, with no such effects observed in mammals. In addition, rPoBa could protect P. olivaceus against Vibrio harveyi infection both in vitro and in vivo by significantly improving the immune activity of peripheral blood leukocytes and reducing tissue bacterial loads. Consistently, when PoCFB expression in P. olivaceus was knocked down, the PoBa production and complement activity were decreased, and bacterial replication was significantly enhanced. In conclusion, this study revealed that the complement-activated recombinant Ba fragment improved the immune defense against bacterial infection and provided a potential strategy to control disease in lower vertebrates.

Proteomic Analysis of Vibrio parahaemolyticus-Stimulated Pinctada martensii Proteins for Antimicrobial Activity, Potential Mechanisms, and Key Components

Background: Bacterial infections are a major challenge in food processing and public health, and there is an urgent need to develop novel antimicrobial agents. Objectives: The purpose of this study is to investigate the potential mechanism and key components of Pinctada martensii antimicrobial proteins (Pm-Aps) to provide a theoretical basis for the development of novel antimicrobial agents. Methods: The researchers used Vibrio parahaemolyticus (VP) to stimulate Pinctada martensii, extracted the antimicrobial proteins, and analyzed their antimicrobial activities, potential mechanisms of action, and key components using proteomics. Results: The results showed that the antimicrobial activity of Pm-Aps, with broad-spectrum antimicrobial effects, was significantly enhanced after VP stimulation. This was associated with the upregulation of LAAO, CHDH, TLR2, ATG16L1, BAK, CLCA4, and CASP8 and the downregulation of MCM3, MCM5, DTYMK, PLK1, FBXO6, LPCAT3, GST, LAMTOR5, CYP17A, CTSA, and RRM1. It is hypothesized that these proteins may inhibit bacterial growth and multiplication by activating immune-related signaling pathways, inhibiting DNA replication and repair, and inducing apoptosis and autophagy. Furthermore, it was found that LAAO may be a key component of the antimicrobial action of Pm-Aps, killing bacteria by catalyzing the oxidation of amino acids to produce hydrogen peroxide (H2O2). Conclusions: These results strongly suggest that Pm-Aps is an effective antimicrobial protein, and it is expected that new LAAO can be obtained from Pm-Aps.

Three hepcidins from the spotted knifejaw (Oplegnathus punctatus) promote antimicrobial activity via TLR/NFκB pathway

Hepcidin belongs to a class of small cationic antimicrobial peptides rich in cysteine. It is synthesized by liver and is widely involved in host antimicrobial, antiviral and other immune responses. We identified and characterized three hepcidin genes (OpHep1, OpHep2 and OpHep3) in spotted knifejaw. All the OpHeps shared high identities with hepcidins in other teleost, containing alpha helix and β-sheets. Three OpHeps were all detected in healthy tissues, with the abundant expression in liver. They were significantly increased after Vibrio harveyi infection in the six immune-relevant tissues (liver, kidney, spleen, gill, skin and intestine). OpHeps knockdown in spotted knifejaw liver cells affected the mRNA levels of inflammation-related genes, including il1β, il6, il8, and nfκb. Further, the recombinant hepcidin proteins were effective in suppressing the growth of both Gram-negative and Gram-positive bacteria. To identify the function of OpHeps in vivo, we performed the overexpression of three OpHeps in zebrafish, and found OpHeps could significantly induce immune-related genes expression in transgenic zebrafish, including myd88, il10, il21, il16, tlr1, tlr3 and lysozyme. When infected with V. harveyi, OpHeps transgenic zebrafishes had a higher survival rate than wild-type zebrafishes. The expression of myd88, il10, il8, il1β, nfκb and lysozyme were all significantly up-regulated in transgenic fishes during bacterial infection. In summary, these results indicated that hepcidin could protect fish fight against pathogen through TLR/NFκB signaling cascade and Lysozyme. Three OpHeps would be potential targets for prevention of bacterial infections in aquaculture industry of spotted knifejaw, which provided a new idea for the molecular breeding of fish disease resistance.

Nanopore-based full-length transcriptome sequencing of the skin in Pseudopleuronectes yokohamae identifies novel antimicrobial peptide genes

The marbled flounder (Pseudopleuronectes yokohamae) is highly esteemed for its exceptional nutritional value and delicious taste. However, this species has extremely limited transcriptome data, which can offer priceless information for disease protection. In the study, the skin transcriptomic sequencing of P. yokohamae revealed 7.72 GB of clean data using the Nanopore sequencing platform. The results revealed 30,498 transcripts of functional annotations in the P. yokohamae transcriptome. All transcripts were searched in eight functional databases. A total of 10,337 ORFs were obtained, of which 6081 complete ORFs accounted for 58.83% of all predicted CDS. Moreover, 10,195 SSRs were detected. Meanwhile, the non-pecific immunity pathways were investigated for better understanding of the immunological reaction in P. yokohamae, and seven innate immune pathways were identified. The innate-immune related genes were highly expressed in the NOD-like receptor signaling pathway, followed by the C-type lectin receptor signaling pathway, Toll-like receptor signaling pathway, RIG-I-like receptor signaling pathway and Cytosolic DNA-sensing pathway. In this study, four families of antimicrobial peptides (AMPs) in P. yokohamae were analysed for the first time, including piscidins, hepcidins, liver-expressed antimicrobial peptide and defensins. Seven AMPs, including Pypleurocidin-like WF3, Pypleurocidin-like WFX, Pyhepcidin 1, Pyhepcidin-like 1, PyLEAP-2, Pybeta-defensin and Pybeta-defensin-like 1, were further identified. The seven AMPs showed a highly identity in their cDNA and genomic structures and an inducible expression pattern preferable to skin in response to pathogens. The transcriptomic data and investigation of AMPs from P. yokohamae promote a deeper awareness of fish mucosal immunity and provide information in the prevention of fish diseases.

Double-Network Hydrogel with Strengthened Mechanical Property for Controllable Release of Antibacterial Peptide

Developing double-network (DN) hydrogels with high mechanical properties and antibacterial efficacy to combat multidrug-resistant bacterial infections and serve as scaffolds for cell culture still remains an ongoing challenge. In this study, an ion-responsive antibacterial peptide (AMP) (C16-WIIIKKK, termed as IK7) was synergistically combined with a photoresponsive gelatin methacryloyl (GelMA) polymer to fabricate a biocompatible DN hydrogel. The GelMA-IK7 DN hydrogel showed enhanced mechanical properties in contrast to the individual IK7 and GelMA hydrogels and demonstrated substantial antibacterial efficacy. Further investigations revealed that the DN hydrogel effectively inhibited bacterial growth by the controlled and sustained release of the IK7 peptide. In addition, the formation of the DN hydrogel was also found to protect AMP IK7 from rapid degradation by proteinase K. Our findings suggested that the developed GelMA-IK7 DN hydrogel holds great potential for next-generation antibacterial hydrogels for three-dimensional cell culture and tissue regeneration.

Synthetic Antimicrobial Peptides Fail to Induce Leucocyte Innate Immune Functions but Elicit Opposing Transcriptomic Profiles in European Sea Bass and Gilthead Seabream

Antimicrobial peptides (AMPs) are promising molecules in diverse fields, including aquaculture. AMPs possess lytic effects on a wide range of pathogens, resulting in a potential replacement for traditional antimicrobials in aquaculture. In addition, they also have modulatory effects on host immune responses. Thus, the objective of this work was to evaluate the immunomodulatory capability of three known synthetic AMPs derived from European sea bass, NK-lysin (Nkl), hepcidin (Hamp), and dicentracin (Dic), in head-kidney cell suspensions from European sea bass and gilthead seabream. The tested peptides were neither cytotoxic for European sea bass nor gilthead seabream cells and failed to modulate the respiratory burst and phagocytosis activities. However, they modified the pattern of transcription of immune-related genes differently in both species. Peptides were able to promote the expression of marker genes for anti-inflammatory (il10), antiviral (mx, irf3), cell-mediated cytotoxicity (nccrp1, gzmb), and antibody responses (ighm) in European sea bass, with the Nkl peptide being the most effective. Contrary to this, the effects of those peptides on gilthead seabream mainly resulted in the suppression of immune responses. To conclude, European sea bass-derived peptides can be postulated as potential tools for immunostimulation in European sea bass fish farms, but more efforts are required for their universal use in other species.

Advancements of fish-derived peptides for mucormycosis: a novel strategy to treat diabetic compilation

Mucormycosis, an extremely fatal fungal infection, is a major hurdle in the treatment of diabetes consequences. The increasing prevalence and restricted treatment choices urge the investigation of novel therapeutic techniques. Because of their effective antimicrobial characteristics and varied modes of action, fish-derived peptides have lately emerged as viable options in the fight against mucormycosis. This review examines the potential further application of fish-derived peptides in diagnosing and managing mucormycosis in relation to diabetic complications. First, we examine the pathophysiology of mucormycosis and the difficulties in treating it in diabetics. We emphasize the critical need for alternative therapeutic methods for tackling the limitations of currently available antifungal medicines. The possibility of fish-derived peptides as an innovative approach to combat mucormycosis is then investigated. These peptides, derived from several fish species, provide wide antimicrobial properties against a variety of diseases. They also have distinct modes of action, such as rupture of cell membranes, suppression of development, and modification of the host immunological response. Furthermore, we investigate the problems and prospects connected with the clinical application of fish-derived peptides. Ultimately, future advances in fish-derived peptides, offer interesting avenues for the management of mucormycosis in the context of diabetic comorbidities. More research and clinical trials are needed to properly investigate these peptide's therapeutic potential and pave the way for their adoption into future antifungal therapies.