Types Of Amino Acids Research Articles

IR Fingerprint of the Intermolecular Hydrogen Bond on Amino Acids and Its Relevance to Chaperone Activity of αB-Crystallin.

Intermolecular hydrogen bonds between carboxyl (COO-) and amino groups are a common weak interaction in proteins. Infrared (IR) spectral assignment of such an intermolecular hydrogen bond provides a fingerprint for studying protein-protein interactions as its absorption frequency is affected by the molecular electrostatic environment. Temperature-dependent FTIR and temperature-jump time-resolved IR absorbance difference spectra of several typical amino acids and those of wild type and single-site mutated αB-crystallin were performed. It was found that the antisymmetric vibrational frequency of the COO- groups in amino acids decreases from approximately 1626 to 1610 cm-1 upon the formation of intermolecular hydrogen bonds, which was further supported by DFT calculations, while the IR frequency of the intermolecular hydrogen bonds on the formation of intermolecular hydrogen bonds, which was further supported by DFT calculations, while the IR frequency of the intermolecular hydrogen bonded COO- groups at the αB-crystallin dimeric interface was also observed around 1610 cm-1. With this spectral label, the active site of αB-crystallin, a heat shock molecular chaperone against the UV-light-damaged γD-crystallin was investigated. The active site was found to be localized at an arch loop structure connecting the two β-strands locked by intermolecular hydrogen bonds at the dimeric interface. It is the liberated arch loop after breaking of the intermolecular hydrogen bond locks that binds the damaged γD-crystallin, leading to the observed chaperone-like activity of αB-crystallin.

Glutamine, Serine and Glycine at Increasing Concentrations Regulate Cisplatin Sensitivity in Gastric Cancer by Posttranslational Modifications of KDM4A.

Gastric cancer is a common digestive system tumor with a high resistance rate that reduces the sensitivity to chemotherapy. Nutrition therapy is an important adjuvant approach to favor the prognosis of gastric cancer. Dietary amino acids contribute greatly to gastric cancer progression by mediating tumor gene expressions, epigenetics, signal transduction, and metabolic remodeling. In the present study, 20 types of amino acids were screened and glutamine, glycine and serine were identified as the critical regulators of cisplatin (DDP) sensitivity in gastric cancer cells. Moreover, KDM4A acetylation drove the reduced chemotherapy sensitivity in gastric cancer cells by maintaining protein stability and activating DNA repair ability when the concentrations of glutamine (Gln), serine (Ser), and glycine (Gly) decreased. Conversely, Gln/Ser/Gly at increasing concentrations stimulated ubiquitination degradation of KDM4A, which in turn elevated the sensitivity of gastric cancer cells to chemotherapy. Our findings unveiled the role of amino acid nutrition in regulating chemotherapy sensitivity of gastric cancer and the underlying mechanism, thus providing a scientific basis for expanding the clinical significance of nutrition therapy for gastric cancer patients.

Nitrogen@Carbon Quantum Dots for Fluorescence Detection of L-alanine, L-methionine and L-cysteine.

Nitrogen@Carbon quantum dots (N@CQDs) are prepared using microwave hydrothermal method, and polyvinylpyrrolidone (PVP) and melamine are used as mixed C source and N source. Microwave reaction conditions of preparing the N@CQDs are 170 ℃ and 3h. This N@CQDs are are used as fluorescence probe for detection of amino acids. The N@CQDs can recognize L-alanine in water solution, and simultaneously recognize both L-methionine and L-cysteine in dimethyl sulfoxide (DMSO) solution. The linear ranges for L-alanine, L-methionine and L-cysteine are 0-15 µM, 2-50 µM and 0-17 µM, respectively. While limits of detection (LOD) for them are 11.092 nM, 7.8067 nM and 0.67476 nM, respectively. Compared to presently available detection methods, as-prepared N@CQDs have the advantage of high sensitivity and selectivity. Furthermore, coexistence of other amino acids has minimal interference in the detection of L-alanine, L-methionine and L-cysteine. For the as-prepared N@CQDs, solvent plays important roles in influencing the identification of amino acid types and detection sensitivity.

Benefits of Bambara Groundnut (Vigna subterranea) as a Source of Protein on Reproductive Function Related to Ghrelin-leptin in Female Mice Fed a Low Protein Diet

Background: Low protein intake during pregnancy increases maternal mortality and blood levels of leptin and ghrelin, the hormones that regulate energy balance, affecting energy intake and body weight. The benefits of protein depend on the amount and type of amino acids that make up the protein. The need for L-lysine amino acids in pregnant women is reported to increase, especially at the end of pregnancy. Bambara beans contain high levels of the amino acid L-lysine, so they can be used as a source of protein that contains high levels of L-lysine. Objective: This study evaluated the Bambara groundnuts (Vigna subterranea) supplementation effects on reproductive function related to ghrelin-leptin in female mice fed a low protein diet. Methods: Quasi-experimental study with a control group employing 50 female mice divided into five groups: normal protein diet (N), low protein diet (LP), low protein diet with 100 g (LP+100); 200 g (LP+200), and 300 g (LP+300) Bambara groundnut supplementation. After 2 months of intervention, half of the mice in each group (n=25) were terminated, and blood samples were collected to determine albumin, ghrelin, and leptin levels. The other half mice were mated to assess gestational age. Results: Supplementation with Bambara groundnuts at 200 and 300 g/kg of feed increases protein intake and ghrelin and leptin levels. The leptin/ ghrelin ratio in the group of mice supplemented with Bambara groundnut at a dose of 300 g/kg feed shows a similar ratio to the normal group. Although there were no significant changes in albumin levels in all groups, protein intake, ghrelin and leptin levels were positively correlated with gestational age. Conclusion: Bambara groundnuts can reduce the negative effect of a low protein diet in female mice. It is an excellent protein source that increases the leptin/ghrelin ratio to improve gestational age.

The potential role of amino acids in myopia: inspiration from metabolomics.

Due to the high prevalence of myopia, there is a growing need for the identification of myopia intervention mechanisms and targets. Metabolomics has been gradually used to investigate changes in myopia tissue metabolites over the last few years, but the potential physiological and pathological roles of amino acids and their downstream metabolites discovered by metabolomics in myopia are not fully understood. Aim to explore the possible relationship between amino acid metabolism and the occurrence and development of myopia, we collected a total of 21 experimental studies related to myopia metabolomics. Perform pathway analysis using MetaboAnalyst online software. We have identified over 20 amino acids that may be associated with the development of myopia. Among them, 19 types of amino acids are common amino acids. We discussed their possible mechanisms affecting myopia and proposed future prospects for treating myopia. Our analysis results show that metabolomics research on myopia involves many important amino acids. We have collected literature and found that research on amino acid metabolism in myopia mainly focuses on downstream small molecule substances. Amino acids and their downstream metabolites affect the development of myopia by participating in important biochemical processes such as oxidative stress, glucose metabolism, and lipid metabolism. Enzymes, receptors, and cytokines that regulate amino acid metabolism may become potential targets for myopia treatment.

Formation and snake-eating like solubilization mechanisms of rhamnolipid vesicles for oil components and amino acids

Rhamnolipid vesicles hold significant potential across a wide range of applications, yet their formation mechanisms and selective solubilization of organic molecules remain elusive. Employing dissipative particle dynamics (DPD) simulations, this study delves deeply into these aspects, uncovering a stepwise formation pathway from dispersed monomers to complex multi-layer vesicle structures. The fusion and growth of three-layer structures were identified as crucial steps in the development of stacked vesicles. Notably, double-chain rhamnolipids (Rh-C10-C10) exhibited enhanced stability in self-assembled structures compared to their single-chain counterparts (Rh-C10). Through a detailed analysis of parameters such as relative concentration distribution, radial distribution function, and density fields, the solubilization process of rhamnolipid vesicles was found to resemble a “snake-eating” mechanism. We also analyzed the solubilization sites, amounts, and vesicle sizes, elucidating the selective solubilization mechanisms of rhamnolipids for representative polar and non-polar compounds in crude oil, anisole and 1-hexene. The selectivity of rhamnolipid vesicles in solubilizing organic molecules was primarily influenced by polar attraction and steric hindrance, which together determined their solubilization sites within the vesicles. Additionally, the solubilization behavior and properties of five types of amino acids within rhamnolipid vesicles were explored, demonstrating analogous solubilization patterns that correlated with amino acid polarity. These results provide a foundation for optimizing the application of rhamnolipid vesicles, paving the way for potential advancements in drug delivery, environmental remediation, and oil recovery processes.

Analysis of free amino acids and evaluation of the quality of gallnut honeys from different geographical areas

AbstractGallnut honey, a typical Chinese medicinal commodity, is produced from the nectar of Rhus chinensis Mill. Gallnut honey is very popular with consumers because of its health effects and nutritional value, but its specific nutritional composition and medicinal components are not clear. Free amino acids are important nutritional components of honey, and can provide relevant information about the honey, such as geographical and botanical origin, as well as adulterations. The aim of this paper was to explore the free amino acid characteristics of gallnut honeys in different areas. 18 free amino acids from 17 places in China were determined by automatic amino acid analyser analysis, and the geographical characteristics were studied by principal component analysis and cluster analysis. Results showed that gallnut honey is rich in free amino acids. A total of 12 types of free amino acids were detected in all honey-producing areas, and the total amino acid content was 0.132–0.292 g/100 g. Due to its free amino acid content gallnut honey has high nutritional supplement potential, and exhibits good pharmacodynamic activity and special taste characteristics. Flavour-related free amino acids were primarily aromatic free amino acids and umami free amino acids. Pharmacodynamic free amino acids accounted for 61.22–83.85%. Results also showed that free amino acids contribute to the geographical tracing of honey, and samples of gallnut honey at different altitudes can be distinguished by cluster analysis.

Impact of Amino Acid Supplementation on Aroma Development in Vidal Icewine: A Comparative Study of Saccharomyces and Non-Saccharomyces Fermentations

This study explored the effects of branched-chain amino acid (leucine, isoleucine, valine, and threonine) supplementation on the aroma development of Vidal icewine, fermented separately using commercial Saccharomyces cerevisiae (F33) and non-Saccharomyces (Hanseniaspora uvarum, Hu) yeast. The results indicated that Hu played a pivotal role in enhancing aromatic complexity by producing higher concentrations of esters, medium-chain fatty acids, and terpenes. Particularly, samples with L-isoleucine (1.0 g/L) and L-threonine (1.0 g/L) significantly increased key compounds such as beta-damascenone, isoamyl acetate, and phenethyl acetate, resulting in pronounced floral, fruity, and honey-like aromas. Conversely, during F33 fermentation, samples with added valine (1.0 g/L), threonine (1.4 g/L), and L-leucine (0.6 g/L) exhibited higher concentrations of higher alcohols and ethyl esters, crucial for delivering floral-fruity aromas. These findings suggest that precisely controlling the supply of amino acids during fermentation, through the selection of appropriate yeast strains and amino acid types, can effectively control the aromatic properties of icewine. This study offers new insights for improving icewine quality.

Anti-amyloid activity of amino acid functionalized magnetic nanoparticles on αLactalbumin aggregation

Protein amyloid aggregation involves structural changes in native protein conformers and the formation of amyloid fibrils that accumulate in deposits in the human body. This study explores the effect of magnetic nanoparticles functionalized with amino acids (aaMNPs)—cysteine (Cys), poly-L-lysine (PLL), or proline (Pro)—on the amyloid aggregation of α-lactalbumin (αLA) and its amyloid fibrils (LAF). Our results from thioflavin T fluorescence assay (ThT), atomic force microscopy (AFM), and infrared spectroscopy revealed that the studied aaMNPs inhibit αLA fibrillization and destruct LAF in a concentration-dependent manner. The type of amino acid used for nanoparticle functionalization significantly influences the anti-amyloid efficacy. ProMNPs exhibit the highest inhibitory activity, with the timing of their addition being crucial Conversely, CysMNPs demonstrate the highest destructing activity. AFM image analysis through grain mapping was employed to quantify the anti-amyloid effects of aaMNPs. Cytotoxicity testing on kidney cells identified PLLMNPs as the only cytotoxic nanoparticles in our study. These findings clarify the mechanisms of inhibition and destruction of LAF in the presence of aaMNPs, which could inform the design of nanoparticles for therapeutic purposes in the future.

Electrodeposition of Cu with Amino Acids Toward Electrocatalytic Enhancement of CO₂ Reduction Reactions

The electrochemical reduction of carbon dioxide (CO2) is attracting technology because it can convert CO2 into a useful resource with zero emissions by using surplus electricity and renewable energy. For achieving efficient electrolysis of CO2, the development of a high performance electrocatalysts is required. Copper (Cu) is the only metal that is capable of electrochemically converting CO2 to hydrocarbons, but the high overpotential of hydrocarbon formation and the low selectivity of the reduction products have been problems. One of the solutions to these problems is the hybridization of metal and organic materials, in which the metal serves as the CO2 reduction reaction sites and the organic material stabilizes the intermediates [1]. In this study, we have electrodeposited Cu with five different types of amino acids which is expecting stabilization of CO2 reductive intermediates and evaluated its catalytic activity of electrochemical reduction of CO2.The electrodeposited Cu with amino acids was obtained by a constant current electrolysis at -2.0 mA cm-2 for 1.0 C cm-2 from the aqueous solutions containing 10 mmol dm-3 CuSO4･5H2O, 0.1 mol dm-3 Na2SO4, and 1.0 mmol dm-3 amino acids in a three-electrode cell with carbon paper (CP) as the working electrode, platinum wire as the counter electrode, and Ag/AgCl as the reference electrode. The pH of electrolytic bath was fixed at 1.10 by adding H2SO4. The obtained electrodeposited Cu samples were characterized by Raman measurement, high-angle annular dark-field scanning transmission electron microscopy (HAADF-STEM), energy dispersive X-ray spectroscopy (EDS) measurement, scanning electron microscopy (SEM) and X-ray diffraction (XRD). The electrochemical reduction of CO2 has been conducted by a constant potential electrolysis at -1.27 V vs. RHE of 0.5 mol dm-3 KHCO3 aqueous solutions saturated with CO2. The amount of reductive gas products was quantified by gas chromatograph- mass spectrometer (GC-MS) and gas chromatograph thermal conductivity detector (GC-TCD).The chronopotentiograms obtained during the electrodeposition of Cu, both in the presence and absence of 1.0 mmol dm−3 of the various amino acids showed different potential required to reach a current of −4.0 mA depending on the amino acids. However, considering the result of the open-circuit-potential measurement, the amino acids do not form complexes with Cu2+, suggesting that the electrolysis species remain consistent regardless of the amino acid present in the Cu electrodeposition bath. Therefore, the differences observed in the chronopotentiograms during Cu electrodeposition are attributed to the adsorption of amino acids on the electrodeposited Cu. The adsorption of amino acids on electrodeposited Cu was confirmed by Raman spectra and EDS spectra obtained from cross-sectional HAADF-STEM images. The peak of Raman spectra originating from amino acids was observed from electrodeposited Cu when Cu electrodeposition was conducted with amino acids, confirming the higher ratio of N and Cu on the surface compared to within the particle in the EDS spectra. Surface morphologies were observed by using SEM. CP has fiber-like structure but electrodeposited Cu without and with amino acids were deposited such coating CP fiber. The particle size of electrodeposited Cu with amino acids was more homogeneous, and the particles were more densely packed together than pure electrodeposited Cu. However, changing diffraction patterns and peak broadening due to loading amino acids in XRD were not observed.The electrochemical reduction of CO2 on electrodeposited Cu samples was performed and the faradic efficiency (FE) of the CO2 reduction gas products were calculated. All electrodeposited Cu with and without amino acids showed a higher FE for the electrochemical reduction of CO2 to CH4 compared to Cu foil (24.2%) and different values depending on amino acids. In particular, electrodeposited with L-histidine containing imidazole groups showed a high FE of 67.6%, effectively suppressing the hydrogen evolution reaction. This finding highlights the important role of functional groups in amino acids, especially imidazole, in facilitating the electrochemical conversion of CO2 to CH4. This study shows that certain functional groups in amino acids have a crucial influence on the catalytic efficiency of electrodeposited Cu in CO2 reduction reaction applications.[1] S. Jia et al., Angew. Chem. Int. Ed. 2021, 60, 10977–10982.

Root morphology, nitrogen metabolism and amino acid metabolism in soybean under low phosphorus stress.

Phosphorus deficiency is a major influence on growth and development of soybean. Therefore, improving phosphorus utilization efficiency in soybean is a research priority for the soybean community. In this experiment, Liaodou 13 (high phosphorus utilization: HPE) and Tiefeng 3 (low phosphorus utilization: LPE) were used as test varieties. We investigated changes in root morphology, amino acid content, and content of key substances of the nitrogen metabolic pathway with normal phosphorus (0.5 mM) and low phosphorus (0.005 mM) treatments. The results showed that the root length, root surface area and number of lateral roots of HPE roots were higher than those of LPE roots under normal and low phosphorus conditions. The contents of different types of amino acids showed different trends in two varieties. The HPE showed small change in the content of total hydrolyzed amino acids under the low phosphorus condition when compared to the normal phosphorus treatment by a 6.67% decrease, on the contrary LPE showed a drastic decrease by 20.36%. However, HPE exhibited similar decreasing trends in the contents of hydrolyzed and free aspartic acid with the low phosphorus treatment. Moreover, the contents of free histidine and valine in LPE were significantly increased by 657.84% and 149.29% respectively, in contrast to significant decreases in HPE. In aspects of major nutrient elements, the contents of phosphorus, total nitrogen and ammonia nitrogen in both HPE and LPE varieties decreased to dramatic levels. However, the nitrate nitrogen content significantly increased 78.51% for HPE and 65.12% for LPE. Compare to the normal condition, the GOGAT activity in HPE decreased by 5.18% but increased by 33.10% in LPE. Compare to the normal condition, the GS activity in HPE increased by 7.26% but decreased by 21.72% in LPE under phosphorus deficiency. In summary, the phosphorus-efficient soybean variety HPE exhibited superior tolerance to low phosphorus deficiency through advantageous root morphology, phosphorus uptake and transfer capability, and balanced amino acid metabolism and nitrogen metabolism pathways.

Comparative Metabolomic Analysis of the Nutrient Composition of Different Varieties of Sweet Potato.

Sweet potatoes are rich in amino acids, organic acids, and lipids, offering exceptional nutritional value. To accurately select varieties with higher nutritional value, we employed liquid chromatography-tandem mass spectrometry (LC-MS/MS) to analyze the metabolic profiles of three types of sweet potatoes (white sweet potato flesh, BS; orange sweet potato flesh, CS; and purple sweet potato flesh, ZS). When comparing CS vs. BS, ZS vs. BS, and ZS vs. CS, we found differences in 527 types of amino acids and their derivatives, 556 kinds of organic acids, and 39 types of lipids. After excluding the derivatives, we found 6 amino acids essential for humans across the three sweet potatoes, with 1 amino acid, 11 organic acids, and 2 lipids being detected for the first time. CS had a higher content of essential amino acids, while ZS had a lower content. Succinic acid served as a characteristic metabolite for ZS, helping to distinguish it from the other two varieties. These findings provide a theoretical basis for assessing the nutritional value of sweet potatoes and setting breeding targets while facilitating the selection of optimal varieties for food processing, medicine, and plant breeding.

Enzymatization of Nila Fish (Oreochromis Niloticus) Protein Hydolysate by Combination of Bromelin and Pepsin Enzymes

Nile Tilapia (Oreochromis niloticus) is a freshwater fish with better nutritional content compared to other freshwater fish, making it suitable for use as a source for protein hydrolysate production. Protein hydrolysate is the result of the breakdown of protein into short-chain compounds through hydrolysis. This research aims to hydrolyze the minced Nile tilapia meat using a combination of bromelain and pepsin enzymes at a concentration of 5% and pH 7 conditions for 5-6 hours. The hydrolysis results using the combination of bromelain and pepsin enzymes (B100: P0) have a yield value of 12.68%, ash content of 2.94%, protein of 57.25%, water 2.65%, and fat 10.25% with a degree of hydrolysis of 61.46%. The hydrolysate has antibacterial properties against Staphylococcus aureus and Escherichia coli bacteria with inhibition zones of approximately 8.3 mm and 8.5 mm, respectively, at a concentration of 1 (mg/µL), contains 15 types of amino acids with the highest composition being lysine 5.12% and the highest non-essential amino acid being aspartic acid 5.75%.

New insights into the evolution and function of the UMAMIT (USUALLY MULTIPLE ACIDS MOVE IN AND OUT TRANSPORTER) gene family.

UMAMIT proteins have been known as key players in amino acid transport. In Arabidopsis, functions of several UMAMITs have been characterized, but their precise mechanism, evolutionary history and functional divergence remain elusive. In this study, we conducted phylogenetic analysis of the UMAMIT gene family across key species in the evolutionary history of plants, ranging from algae to angiosperms. Our findings indicate that UMAMIT proteins underwent a substantial expansion from algae to angiosperms, accompanied by the stabilization of the EamA (the main domain of UMAMIT) structure. Phylogenetic studies suggest that UMAMITs may have originated from green algae and be divided into four subfamilies. These proteins first diversified in bryophytes and subsequently experienced gene duplication events in seed plants. Subfamily I was potentially associated with amino acid transport in seeds. Regarding subcellular localization, UMAMITs were predominantly localized in the plasma membrane and chloroplasts. However, members from clade 8 in subfamily III exhibited specific localization in the tonoplast. These members may have multiple functions, such as plant disease resistance and root development. Furthermore, our protein structure prediction revealed that the four-helix bundle motif is crucial in controlling the UMAMIT switch for exporting amino acid. We hypothesize that the specific amino acids in the amino acid binding region determine the type of amino acids being transported. Additionally, subfamily II contains genes that are specifically expressed in reproductive organs and roots in angiosperms, suggesting neofunctionalization. Our study highlights the evolutionary complexity of UMAMITs and underscores their crucial role in the adaptation and diversification of seed plants.

Variations in endosperm structure facilitate the formation of high protein quality in tetraploid rice

AbstractRice (Oryza sativa L.) is an important food source and a primary source of high‐quality protein. Polyploid breeding is an effective approach to improving the nutritional quality of crops. Several stable tetraploid rice lines with both high seed setting rates and high protein content have been bred. In the present study, the protein quality of two tetraploid rice lines GD2‐4x and GD4‐4x with high protein content was analyzed in detail, and mechanisms associated with the high protein quality were explored from the perspective of endosperm structure. The results showed that the total protein content of GD2‐4x and GD4‐4x increased significantly by 40.27% and 35.15%, respectively, when compared to that of 9311‐2x (control). The content of each protein component also increased significantly, with a major increase being observed in glutelin content. The contents of 16 types of amino acids and total amino acids, as well as contents of nutrient limiting essential amino acids, such as lysine, threonine, and methionine, in tetraploid rice lines increased significantly when compared to those in the control. The thickness of the aleurone layer on the dorsal, lateral, and ventral positions of GD2‐4x and GD4‐4x seeds during different developmental days increased significantly when compared to that of 9311‐2x seeds. Amyloplasts were more regular and loosely arranged in GD2‐4x and GD4‐4x seeds. The tetraploid rice lines had higher total protein and amino acid contents, with glutelin accounting for the highest proportion of the increase. The tetraploid rice lines with high protein content had higher nutritional quality and value than the diploid rice line. The high protein quality of tetraploid rice lines could be associated with an increase in aleurone layer thickness, as well as changes in amyloplast morphology and distribution. This study demonstrates that polyploidization is an effective breeding approach to improving the nutritional quality and value of rice seeds. The results provide a theoretical basis for the utilization of tetraploid high protein rice lines and a reference for improving the nutritional quality of other crops.

Misincorporations of amino acids in p53 in human cells at artificially constructed termination codons in the presence of the aminoglycoside Gentamicin.

Readthrough of a translation termination codon is regulated by ribosomal A site recognition and insertion of near-cognate tRNAs. Small molecules exist that mediate incorporation of amino acids at the stop codon and production of full-length, often functional protein but defining the actual amino acid that is incorporated remains a challenging area. Herein, we report on the development a human cell model that can be used to determine whether rules can be developed using mass spectrometry that define the type of amino acid that is placed at a premature termination codon (PTC) during readthrough mediated by an aminoglycoside. The first PTC we analyzed contained the relatively common cancer-associated termination signal at codon 213 in the p53 gene. Despite of identifying a tryptic peptide with the incorporation of an R at codon 213 in the presence of the aminoglycoside, there were no other tryptic peptides detected across codon 213 that could be recovered; hence we constructed a more robust artificial PTC model. P53 expression plasmids were developed that incorporate a string of single synthetic TGA (opal) stop codons at S127P128A129 within the relatively abundant tryptic p53 peptide 121-SVTCTYSPALNK-132. The treatment of cells stably expressing the p53-TGA129 mutation, treated with Gentamicin, followed by immunoprecipitation and trypsinization of p53, resulted in the identification R, W, or C within the tryptic peptide at codon-TGA129; as expected based on the two-base pairing of the respective anticodons in the tRNA to UGA, with R being the most abundant. By contrast, incorporating the amber or ochre premature stop codons, TAA129 or TAG129 resulted in the incorporation of a Y or Q amino acid, again as expected based on the two base pairings to the anticodons, with Q being the most abundant. A reproducible non-canonical readthrough termination codon-skip event at the extreme C-terminus at codon 436 in the SBP-p53 fusion protein was detected which provided a novel assay for non-canonical readthrough at an extreme C-terminal PTC. The incorporation of amino acids at codons 127, 128, or 129 generally result in a p53 protein that is predicted to be 'unfolded' or inactive as defined by molecular dynamic simulations presumably because the production of mixed wild-type p53 and mutant oligomers are known to be inactive through dominant negative effects of the mutation. The data highlight the need to not only produce novel small molecules that can readthrough PTCs or C-terminal termination codons, but also the need to design methods to insert the required amino acid at the position that could result in a 'wild-type' functional protein.

Enhancing biocompatibility and degradation control of biodegradable polymers through amino acid grafting: A study on 4arm-PLGA-Amino acid copolymers

Non-degradable polymers, when retained in the body for long periods, can cause chronic inflammation and immune responses. This issue increases the costs related to secondary surgeries and overall healthcare. Conversely, while biodegradable polymers such as PLGA offer an alternative, their degradation rate is challenging to precisely control. Additionally, their mechanical properties deteriorate during the degradation process, and the degradation by-products may lead to localized acidification or other adverse reactions. In this study, we introduce a new biodegradable copolymer called 4arm-PLGA-Amino acid (4aPLGA-Amino acid). This copolymer is synthesized by grafting amino acids onto 4arm-PLGA (4aPLGA) using triphosgene, which is both environmentally friendly and cost-effective. The incorporation of amino acids aims to enhance the biocompatibility and functionality of the copolymer. By varying the types of amino acids grafted, the degradation rate of 4aPLGA can be modulated, thereby improving its potential for applications in drug delivery systems. This modification also promotes cell attachment and proliferation, making it suitable for tissue engineering and regenerative medicine. The study demonstrated that 4aPLGA-Amino acid significantly improved biocompatibility, degradation control, and mechanical properties, broadening its applicability in various biomedical engineering fields.

Omiganan-Based Synthetic Antimicrobial Peptides for the Healthcare of Infectious Endophthalmitis.

Bacterial endophthalmitis is a severe infection of the aqueous or vitreous humor of the eye that can lead to permanent vision loss. Due to the rapid emergence of antibiotic resistance and dose-limiting toxicities, the standard treatment of bacterial endophthalmitis via the intravitreal injection of broad-spectrum antibiotics remains inadequate. Membrane active cationic antimicrobial peptides (AMPs) have emerged as a promising class of effective and broad-spectrum antimicrobial agents with potential to overcome antibiotic resistance. In this work, we investigate, for the first time, the use of omiganan (IK-12), a 12-amino acid indolicidin derivative for the treatment of bacterial endophthalmitis. Additionally, IK-12 was used as a template to perform amino acid rearrangements, without altering the length or type of amino acids, to yield a series of new derivative AMPs with varying extents of secondary structure formation under membrane mimicking conditions. IK-12 and its derivatives demonstrated strong and broad-spectrum antibacterial activities against a panel of clinically isolated Gram-positive and Gram-negative bacteria, including methicillin-resistant Staphylococcus aureus commonly implicated in bacterial endophthalmitis. Interestingly, two of the new IK-12 derivatives, IP-12 and WP-12, showed lower geometric mean minimum inhibitory concentration and higher 50% hemolysis concentration values, which effectively translated into 2- to 3.4-fold higher bacterial selectivity than the parent IK-12. Furthermore, the intravitreal injection of IK-12, IP-12, and WP-12 in a rabbit model of MRSA-induced endophthalmitis led to considerably improved clinical presentation and reduced recruitment of inflammatory cells. In all, these results demonstrate the potential of IK-12 and its derivatives, IP-12 and WP-12, as promising candidates for the treatment of bacterial endophthalmitis.

Research Progress on Antioxidant Peptides from Fish By-Products: Purification, Identification, and Structure-Activity Relationship.

Background/Objectives: Excessive reactive oxygen species (ROS) can lead to oxidative stress, which has become an urgent problem requiring effective solutions. Due to the drawbacks of chemically synthesized antioxidants, there is a growing interest in natural antioxidants, particularly antioxidant peptides. Methods: By reviewing recent literature on antioxidant peptides, particularly those extracted from various parts of fish, summarize which fish by-products are more conducive to the extraction of antioxidant peptides and elaborate on their characteristics. Results: This article summarizes recent advancements in extracting antioxidant peptides from fish processing by-products, Briefly introduced the purification and identification process of antioxidant peptides, specifically focusing on the extraction of antioxidant peptides from various fish by-products. Additionally, this article comprehensively reviews the relationship between amino acid residues that compose antioxidant peptides and their potential mechanisms of action. It explores the impact of amino acid types, molecular weight, and structure-activity relationships on antioxidant efficacy. Conclusions: Different amino acid residues can contribute to the antioxidant activity of peptides by scavenging free radicals, chelating metal ions, and modulating enzyme activities. The smaller the molecular weight of the antioxidant peptide, the stronger its antioxidant activity. Additionally, the antioxidant activity of peptides is influenced by specific amino acids located at the C-terminus and N-terminus positions. Simultaneously, this review provides a more systematic analysis and a broader perspective based on existing research, concluded that fish viscera are more favorable for the extraction of antioxidant peptides, providing new insights for the practical application of fish by-products. This could increase the utilization of fish viscera and reduce the environmental pollution caused by their waste, offering valuable references for the study and application of antioxidant peptides from fish by-products.

Antioxidant activities of Saudi honey samples related to their content of short peptides

This study explored the effect of geographical and floral origins on the antioxidant activities of Saudi honey samples related to their content of short peptides originated from honeybee proteins. The studied antioxidants were the total protein concentration, catalase activity, phenolic acids and flavonoids. The antioxidant activity assays included were the 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical scavenging assay, the ferric reducing antioxidant power (FRAP) assay and Ascorbic acid Equivalent Antioxidant Capacity (AEAC). The studied honey samples were obtained from the southwestern region of Saudi Arabia, namely Asir (65) and Jazan (25). The floral origins of the honey samples were Acacia (51), Ziziphus (4) and polyfloral (35). The LC/MS technique was used to detect the short peptides and the mascot database was used to identify the short peptides, their precursor proteins and the protease enzymes that produce them. Jazan honey was characterized by high number of short peptides. The short peptides were originated from honeybee proteins by the action of proteases from the honeybees and bacteria. The antioxidant activity of the honey samples increase with the increase of their content of short peptides and proteins. The amino acids type and sequence of the short peptides qualify them to act as antioxidant, antimicrobial, anti-diabetic, anti-hypertension, immunomodulatory and cholesterol lowering peptides.