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The outburst of microbial resistance to antibiotics creates the need for new sources of active compounds for the treatment of pathogenic microorganisms. Marine microalgae are of particular interest in this context because they have developed tolerance and defense strategies to resist the exposure to pathogenic bacteria, viruses, and fungi in the aquatic environment. Although antimicrobial activities have been reported for some microalgae, natural algal bioactive peptides have not been described yet. In this work, acid extracts from the microalga Tetraselmis suecica with antibacterial activity were analyzed, and de novo sequences of peptides were determined. Synthetic peptides and their alanine and lysine analogs allowed identifying key residues and increasing their antibacterial activity. Additionally, it was determined that the localization of positive charges within the peptide sequence influences the secondary structure with tendency to form an alpha helical structure.

Marine invertebrates are a prime source of biologically active peptides due to their role in humoral immunity. These peptides typically exhibit broad-spectrum functions, including antibacterial, antifungal, anticancer, and immunomodulatory activities. In this report, we describe the identification and biological characterization of five novel bioactive peptides from the marine mollusk Pisania pusio. An extract of P. pusio was analyzed using nanoLC-ESI-MS-MS, and five peptides (PP1–5) were selected via bioinformatic screening as potential antimicrobial and anticancer peptides and subsequently validated experimentally. Among these, PP1, PP2, and PP4 were identified as cryptides derived from the proteolytic cleavage of actin, while PP3 and PP5 are novel peptides with no known protein precursors. All peptides exhibited moderate activity against Pseudomonas aeruginosa, Escherichia coli, Staphylococcus aureus, and Klebsiella pneumoniae with minimum inhibitory concentrations (MICs) predominantly at 100 µM. In contrast, only PP1 and PP5 were active against cancer cells, with PP1 being the most effective against A375 melanoma cells (IC50 = 17.08 µM). This experimental validation confirmed the utility of the integrated in silico/peptidomic pipeline for lead identification. None of these peptides showed significant hemolytic activity or toxicity on fetal lung fibroblasts over 800 μM, demonstrating promising in vitro selectivity. These results highlight the multifunctional nature of P. pusio-derived peptides and their potential as lead compounds for further optimization and development into therapeutic agents against microbial infections and cancer, subject to more comprehensive safety evaluations in relevant models

Cancer is one of the leading causes of death in the world, and antineoplastic drug research continues to be a major field in medicine development. The marine milieu has thousands of biological species that are a valuable source of novel functional proteins and peptides, which have been used in the treatment of many diseases, including cancer. In contrast with proteins and polypeptides, small peptides (with a molecular weight of less than 1000 Da) have overwhelming advantages, such as preferential and fast absorption, which can decrease the burden on human gastrointestinal function. Besides, these peptides are only connected by a few peptide bonds, and their small molecular weight makes it easy to modify and synthesize them. Specifically, small peptides can deliver nutrients and drugs to cells and tissues in the body. These characteristics make them stand out in relation to targeted drug therapy. Nowadays, the anticancer mechanisms of the small marine peptides are still largely not well understood; however, several marine peptides have been applied in preclinical treatment. This paper highlights the anticancer linear and cyclic small peptides in marine resources and presents a review of peptides and the derivatives and their mechanisms.

Spirulina platensis, a blue-green alga rich in nutritional value and the beneficial pigment phycocyanin, is a source of bioactive peptides with antioxidant properties. This study aimed to evaluate the effects of bioactive peptides extracted from spirulina on wound healing and inflammation after periodontal surgery. In this double-blind, split-mouth randomized controlled trial study, twenty patients with periodontitis were assigned to either an experimental group (receiving spirulina peptide gel) or a control group (receiving placebo). Before surgery, all patients underwent scaling and root planning to eliminate pre-existing plaque. The surgical procedure involved a modified Widman flap technique. Wound healing was assessed at 1, 4, and 8 weeks post-surgery using parameters including soft tissue swelling, gingival color, probing depth, bleeding index, and plaque index. followed by a saline wash. Statistical analysis using SPSS 20 software employing non-parametric tests (Wilcoxon and Kruskal-Wallis) were carried out. The spirulina group showed a significant reduction in plaque and bleeding indices at weeks 4 and 8, as well as less gingival redness and lower pain scores at week 1, compared to controls. In addition, the need for pain medication was significantly lower in the spirulina group. These findings indicate that spirulina bioactive peptide gel can significantly improve wound healing, reduce inflammation, and alleviate post-surgical pain in periodontal procedures. These findings suggest its potential as a valuable adjunct therapy in periodontal surgery, enhancing patient recovery and improving overall periodontal health. However considering the limitation of the study, further studies are warranted to confirm and generalize the results.

Heart failure is a class of cardiovascular diseases that remains the number one cause of death worldwide with a substantial economic burden of around $18 billion incurred by the healthcare sector in 2017 due to heart failure hospitalization and disease management. Although several laboratory tests have been used for early detection of heart failure, these traditional diagnostic methods still fail to effectively guide clinical decisions, prognosis, and therapy in a timely and cost-effective manner. Recent advances in the design and development of biosensors coupled with the discovery of new clinically relevant cardiac biomarkers are paving the way for breakthroughs in heart failure management. Natriuretic neurohormone peptides, B-type natriuretic peptide (BNP) and N-terminal prohormone of BNP (NT-proBNP), are among the most promising biomarkers for clinical use. Remarkably, they result in an increased diagnostic accuracy of around 80% owing to the strong correlation between their circulating concentrations and different heart failure events. The latter has encouraged research towards developing and optimizing BNP biosensors for rapid and highly sensitive detection in the scope of point-of-care testing. This review sheds light on the advances in BNP and NT-proBNP sensing technologies for point-of-care (POC) applications and highlights the challenges of potential integration of these technologies in the clinic. Optical and electrochemical immunosensors are currently used for BNP sensing. The performance metrics of these biosensors—expressed in terms of sensitivity, selectivity, reproducibility, and other criteria—are compared to those of traditional diagnostic techniques, and the clinical applicability of these biosensors is assessed for their potential integration in point-of-care diagnostic platforms.

Recombinant protein production in Escherichia coli is a fundamental aspect of biotechnology. Fusion tags are commonly used to enhance solubility and facilitate purification. However, these tags can lead to challenges such as low yields, complicated purification processes, and the necessity for tag removal, especially when dealing with peptides. This study introduces a novel fusion tag called SmallTalk, a truncated version of the small metal‐binding protein SmbP. Weighing in at 5 kDa, SmallTalk includes two of the four α‐helices found in SmbP. It retains the ability to bind Ni(II) ions, which enables purification through IMAC. In this work, we assessed the efficiency of SmallTalk in expressing and purifying both a model protein, the green fluorescent protein, and the antimicrobial peptide Bin1b. Both proteins were effectively expressed and purified using IMAC, demonstrating SmallTalk's value as an affinity tag, yielding 7.2 mg·L−1 of cell culture for the green fluorescent protein and up to 9.8 mg·L−1 for Bin1b. Antimicrobial assays conducted with SmallTalk‐tagged Bin1b showed activity against Staphylococcus aureus, Escherichia coli, Klebsiella pneumoniae, and Pseudomonas aeruginosa, with minimum inhibitory concentrations ranging from 7.5 to 22.5 μm. Importantly, SmallTalk enabled the full retention of Bin1b's antimicrobial activity without the need for its removal, significantly simplifying the production process. These findings indicate that SmallTalk provides a promising strategy for the recombinant production of peptides. This tag has the potential to enhance the expression, purification, and functional analysis of antimicrobial peptides, which are increasingly being pursued as alternatives to antibiotics in the fight against antimicrobial resistance. The SmallTalk fusion tag allows for the efficient expression and purification of soluble recombinant proteins or peptides in Escherichia coli. Testing with SmallTalk‐GFP confirmed that the proteins were soluble and folded correctly, while SmallTalk‐Bin1b maintained its antimicrobial activity against various bacterial isolates. This streamlined workflow showcases the versatility of the SmallTalk system in producing functional, biologically active proteins and peptides.

There are many examples of biologically active food proteins, with physiological significance beyond the pure nutritional requirements that concern available nitrogen for normal growth and maintenance. Moreover, there are many physiologically active peptides, derived by protease activity from various food protein sources; however, relationships between structural properties and functional activities have not been completely elucidated. Many bioactive peptides have in common structural properties that include a relatively short peptide residue length (e.g. 2-9 amino acids), possessing hydrophobic amino acid residues in addition to proline, lysine or arginine groups. Bioactive peptides are also resistant to the action of digestion peptidases. Antihypertensive peptides, known as Angiotensin I converting enzyme (ACE) inhibitors have been derived from milk, corn and fish protein sources. Peptides with opioid activities are derived from wheat gluten or casein, following digestion with pepsin. Exorphins, or opioid peptides derived from food proteins such as wheat and milk (e.g. exogenous sources) have similar structure to endogenous opioid peptides, with a tyrosine residue located at the amino terminal or bioactive site. Immunomodulatory peptides derived from tryptic hydrolysates of rice and soybean proteins act to stimulate superoxide anions (reactive oxygen species-ROS), which triggers non-specific immune defense systems. Antioxidant properties that prevent peroxidation of essential fatty acids have also been shown for peptides derived from milk proteins. The addition of a Leu or Pro residue to the N-terminus of a His-His, dipeptide will enhance antioxidant activity and facilitate further synergy with non-peptide antioxidants (e.g. BHT). We also show herein, that the tryptic digests of casein yielding caseinophosphopeptides exhibits both hydrophilic and lipophilic antioxidant activity due to both metal ion sequestering and quenching of ROS. The separation and purification of bioactive peptides which will involve development of automated and continuous systems is an important field for Food chemists. Much effort has been given to develop selective column chromatography methods that can replace batch methods of salting out, or using solvent extraction to isolate and purify bioactive peptides. Advances here will enable recovery of bioactive peptides with minimal destruction thus enabling utilization by returning these active peptides to functional food or specific nutraceutical applications.

The hepatopancreas of crustaceans is an important immune organ involved in the secretion of immune effectors such as antimicrobial peptides. Crustacean antimicrobial peptides are very diverse and have a broad spectrum of activity, but are poorly explored. In this work, the activity of antibacterial peptides from the hepatopancreas of red king crab and snow crab was compared. Both peptides were found to be highly effective in inhibiting the growth of gram-positive bacteria. At the same time, the peptide from the red king crab was found to be highly sensitive to the presence of salt and a disulfide bond reducing agent, in contrast to the peptide from the snow crab. An approach for the chromatographic purification of the red king crab peptide from the hepatopancreas was developed. Both peptides are of interest for the development of novel antibacterial drugs.

For the study of amyloid beta (Aβ) associated toxicity which is supposed to be the main pathological agent in Alzheimer’s disease (AD), it is important to secure Aβ peptide with appropriate biological activity. However, commercial and synthetic Aβ often have some pitfalls like less cell toxicity, prompt aggregation and excess price, using recombinant technology, these issues can be resolved though the method also suffered from some problems such as low yield, aggregation and prolong time to purify. Thus, we previously developed an easy, economic and convenient method for Aβ42 purification using highly expressed GroES-Ubiquitin-Aβ42 fusion protein. The method was efficient, but further development was performed to improve the procedure and increase the yield. Focus was on the isolation of the fusion protein (GroES-Ubiquitin) from Aβ42 peptide. After a series of systematic testing with several chemicals, we found that methanol could precipitate efficiently the fusion protein, while the Aβ peptide was recovered in the supernatant. By this method, Aβ peptide was easily purified without tedious chromatographic steps which are main obstacles to purify the peptide in the previous method. This method yielded ~20 mg highly pure Aβ42 peptide from 1-liter bacterial culture. Different biophysical characterizations and bioactivity assays indicate that the peptide purified using this method was competitive with others which have been previously reported whereas considering the simplicity, final yield and time of purification, this method is the optimal solution.

The situation of drug resistance has become more complicated due to the scarcity of plant resistance genes, and overcoming this challenge is imperative. Isatis indigotica has been used for the treatment of wounds, viral infections, and inflammation for centuries. Antimicrobial peptides (AMPs) are found in all classes of life ranging from prokaryotes to eukaryotes. To identify AMPs, I. indigotica was explored using a novel, sensitive, and high-throughput Bacillus subtilis screening system. We found that IiR515 and IiR915 exhibited significant antimicrobial activities against a variety of bacterial (Xanthomonas oryzae, Ralstonia solanacearum, Clavibacter michiganensis, and C. fangii) and fungal (Phytophthora capsici and Botrytis cinerea) pathogens. Scanning electron microscope and cytometric analysis revealed the possible mechanism of these peptides, which was to target and disrupt the bacterial cell membrane. This model was also supported by membrane fluidity and electrical potential analyses. Hemolytic activity assays revealed that these peptides may act as a potential source for clinical medicine development. In conclusion, the plant-derived novel AMPs IiR515 and IiR915 are effective biocontrol agents and can be used as raw materials in the drug discovery field.