Your search keyword '"Enzyme specificity"' showing total 1,738 results

1. Cottonseed meal derived porous carbon prepared via the protease pretreatment and reduced activator dosage carbonization for supercapacitor.

Author

Peng, Lina, Wu, Dongling, Wang, Tao, Guo, Jia, and Jia, Dianzeng

Subjects

*COTTONSEED meal, *CARBONIZATION, *ENZYME specificity, *CARBON-based materials, *ENERGY density

Abstract

The high catalytic activity and specificity of enzymes can be used to pretreat biomass. Herein, the resourceful, reproducible, cheap, and crude protein-rich cottonseed meal (CM) is selected as a precursor and the protease in the K2CO3–KHCO3 buffer solution is used as the enzyme degradation substance to pretreat CM. The crude protein content is significantly reduced by the protease degradation, and, meanwhile, it results in a looser and porous structure of CM. What is more, it significantly reduces the amount of activator. In the subsequent carbonization process, the K2CO3–KHCO3 in the buffer solution is also used as an activating agent (the mass ratio of CM to activator is 2:1), and after carbonization, the O, S, and N doped porous carbon is obtained. The optimized PCM-800-4 exhibits high heteroatom contents and a hierarchical porous structure. The specific capacitance of the prepared porous carbon reaches up to 233 F g−1 in 6M KOH even when 10 mg of active material is loaded. In addition, a K2CO3–KHCO3/EG based gel electrolyte is prepared and the fabricated flexible capacitor exhibits an energy density of 15.6 Wh kg−1 and a wide temperature range (−25 to 100 °C). This study presents a simple enzymatic degradation and reduced activator dosage strategy to prepare a cottonseed meal derived carbon material and looks forward to preparing porous carbon using other biomass. [ABSTRACT FROM AUTHOR]

Published

2023

2. Purification and characterisation of laccase from the medicinal wild mushroom Coriolus brevis.

Author

Kim, Yeon-Ho, Park, Seo-Young, Jung, Na-Hee, Kim, Hyun-A, Hong, Sungguan, and Kong, Kwang-Hoon

Subjects

*POLLUTANTS, *ENZYME specificity, *ENVIRONMENTAL degradation, *MOLECULAR weights, *BIOCHEMICAL substrates, *LACCASE

Abstract

Laccases are enzymes that catalyse oxidation of various aromatic compounds, with potential industrial and environmental applications. Here, a novel laccase, Cb Laccase, was purified to homogeneity from the medicinal wild mushroom Coriolus brevis using standard chromatographic procedures. The overall yield was approximately 11 %. Gel filtration and sodium dodecyl sulphate–polyacrylamide gel electrophoresis revealed that Cb Laccase is a monomer with a molecular mass of 51 kDa. The optimal reaction pH with 2,2′-azinobis-(3-ethylbenzothiazoline-6-sulfonic acid) as a substrate was low (pH 2.5), and the optimal reaction temperature was relatively high (70 °C). The enzyme exhibited very low K m (0.02 mM) and high catalytic efficiency (7.2 × 106) with syringaldazine, and its substrate specificity followed the order: syringaldazine > o -dianisidine > 2,2′-azinobis-(3-ethylbenzothiazoline-6-sulfonic acid) > 2,6-dimethoxyphenol > catechol. Addition of 1 mM Cu2+ enhanced the enzymatic activity, whereas dithiothreitol, sodium azide, and diethyldithiocarbamic acid significantly inhibited it. The enzyme was highly stable at high temperatures, over a wide range of pH values, and in the presence of various detergents. These findings suggest that Cb Laccase is distinct from laccases previously purified from other sources and may be useful for the degradation of environmental pollutants. [Display omitted] • Cb Laccase was purified from Coriolus brevis and then characterized. • It was a 51-kDa monomeric enzyme with varying specificities across substrates. • It was stable at high temperatures, over a wide pH range, and in detergents. • It could potentially be applicable in environmental pollutant degradation studies. [ABSTRACT FROM AUTHOR]

Published

2024

3. Structural and functional analysis of l-methionine oxidase identified through sequence data mining.

Author

Kawamura, Yui, Sugiura, Sayaka, Araseki, Hayato, Chisuga, Taichi, and Nakano, Shogo

Subjects

*ENZYME specificity, *IMINO acids, *CATALYTIC domains, *CRYSTAL structure, *FUNCTIONAL analysis

Abstract

l -Amino acid oxidase (LAAO), an FAD-dependent enzyme, catalyzes the oxidation of l -amino acids (l -AAs) to their corresponding imino acids. While LAAOs, which can oxidize charged or aromatic l -AAs specifically, have been extensively characterized across various species, LAAOs that have high specificity toward alkyl-chain l -AAs, such as l -Met, are hardly characterized for now. In this study, we screened a highly specific l -Met oxidizing LAAOs from Burkholderiales bacterium (BbMetOx) and Undibacterium sp. KW1 (UndMetOx) using sequence similarity network (SSN) analysis. These enzymes displayed an order of magnitude higher specific activity towards l -Met compared to other l -AAs. Enzyme activity assays showed that these LAAOs operate optimally at moderate condition because the optimal pH and T m values were pH 7.0 and 58–60°C. We determined the crystal structures of wild-type BbMetOx (BbMetOx(WT)) and an inactivated mutant, BbMetOx (K304A), at 2.7 Å and 2.2 Å resolution, respectively. The overall structure of BbMetOx is closely similar to other known LAAOs of which structures were determined. Comparative analysis of the BbMetOx structures revealed significant conformational changes in the catalytic domain, particularly a movement of approximately 8 Å in the C α atom of residue Y180. Further analysis highlighted four residues, i.e., Y180, M182, F300, and M302, as critical for l -Met recognition, with alanine substitution at these positions resulting in loss of activity. This study not only underscores the utility of SSN for discovering novel LAAOs but also advances our understanding of substrate specificity in this enzyme family. [ABSTRACT FROM AUTHOR]

Published

2024

4. Theoretical Calculation–Driven Metal–Organic Framework Nanozymes: Catalytic Mechanisms and Applications.

Author

Zhang, Ziyu, Yuan, Zhishuang, Zhang, Ziyan, Guan, Jing, Tan, Weiqiang, Zhang, Guangyao, and Chai, Huining

Subjects

*ENZYME specificity, *OXIDATION-reduction reaction, *SYNTHETIC enzymes, *DENSITY functional theory, *CHARGE exchange

Abstract

ABSTRACT Metal–organic framework (MOF) nanozymes have garnered widespread attention in the field of biomimetic catalysis due to their highly controllable porous structure and surface functionalization, enabling them to mimic the catalytic activity and specificity of natural enzymes while offering greater stability and reusability. In recent years, significant progress has been made in the theoretical computation studies of MOF nanozymes' catalytic reactions, providing deep insights into their catalytic and analytical mechanisms. This review comprehensively gathers the latest research progress of theoretical calculation–driven MOF nanozymes on their catalytic mechanisms and applications. First, the methods that can be used for theoretical calculations of MOF nanozymes, especially density functional theory (DFT), are reviewed to help deeply analyze the active site distribution, electron transfer pathways, and adsorption and activation mechanisms of reactants of MOF nanozymes. Subsequently, this review deeply studies the contribution of these theoretical calculation methods to revealing the catalytic reaction mechanism of MOF nanozymes (such as active sites and enzyme‐like activity), especially the specific role of electron transfer and reaction energy changes in key reaction steps. Finally, this review looks forward to the challenges and opportunities in the theoretical computation for the future design and application of MOF nanozymes, especially in accurately predicting catalytic activities, understanding complex reaction mechanisms, and guiding the synthesis of new nanozyme materials. By integrating theoretical calculations with experimental research, the study of MOF nanozymes is expected to forge new avenues in biomimetic catalysis and provide effective strategies for addressing challenges in the fields of sensing, biomedicine, and environmental protection. [ABSTRACT FROM AUTHOR]

Published

2024

5. Catalytic activities of wild‐type C. elegansDAF‐2 kinase and dauer‐associated mutants.

Author

Krishnan, Harini, Ahmed, Sultan, Hubbard, Stevan R., and Miller, W. Todd

Subjects

*ENZYME specificity, *PROTEIN-tyrosine kinases, *PHYSIOLOGY, *BIOCHEMICAL substrates, *CAENORHABDITIS elegans

Abstract

DAF‐2, the Caenorhabditis elegans insulin‐like receptor homolog, regulates larval development, metabolism, stress response, and lifespan. The availability of numerous daf‐2 mutant alleles has made it possible to elucidate the genetic mechanisms underlying these physiological processes. The DAF‐2 pathway is significantly conserved with the human insulin/IGF‐1 signaling pathway; it includes proteins homologous to human IRS, GRB‐2, and PI3K, making it an important model to investigate human pathological conditions. We expressed and purified the kinase domain of wild‐type DAF‐2 to examine the catalytic activity and substrate specificity of the enzyme. Like the human insulin receptor kinase, DAF‐2 kinase phosphorylates tyrosines within specific YxN or YxxM motifs, which are important for recruiting downstream effectors. DAF‐2 kinase phosphorylated peptides derived from the YxxM and YxN motifs located in the C‐terminal extension of the receptor tyrosine kinase, consistent with the idea that the DAF‐2 receptor may possess independent signaling capacity. Unlike the human insulin or IGF‐1 receptor kinases, DAF‐2 kinase was poorly inhibited by the small‐molecule inhibitor linsitinib. We also expressed and purified mutant kinases corresponding to daf‐2 alleles that result in partial loss‐of‐function phenotypes in C. elegans. These mutations caused a complete loss of kinase function in vitro. Our biochemical investigations provide new insights into DAF‐2 kinase function, and the approach should be useful for studying other mutations to shed light on DAF‐2 signaling in C. elegans physiology. [ABSTRACT FROM AUTHOR]

Published

2024

6. Neuropeptide inactivation regulates egg-laying behavior to influence reproductive health in Caenorhabditis elegans.

Author

Lo, Jacqueline Y., Adam, Katelyn M., and Garrison, Jennifer L.

Subjects

*TISSUE physiology, *ENZYME specificity, *PEPTIDES, *EXTRACELLULAR enzymes, *HEALTH behavior, *NEUROPEPTIDES

Abstract

Neural communication requires both fast-acting neurotransmitters and neuromodulators that function on slower timescales to communicate. Endogenous bioactive peptides, often called "neuropeptides," comprise the largest and most diverse class of neuromodulators that mediate crosstalk between the brain and peripheral tissues to regulate physiology and behaviors conserved across the animal kingdom. Neuropeptide signaling can be terminated through receptor binding and internalization or degradation by extracellular enzymes called neuropeptidases. Inactivation by neuropeptidases can shape the dynamics of signaling in vivo by specifying both the duration of signaling and the anatomic path neuropeptides can travel before they are degraded. For most neuropeptides, the identity of the relevant inactivating peptidase(s) is unknown. Here, we established a screening platform in C. elegans utilizing mass spectrometry-based peptidomics to discover neuropeptidases and simultaneously profile the in vivo specificity of these enzymes against each of more than 250 endogenous peptides. We identified NEP-2, a worm ortholog of the mammalian peptidase neprilysin-2, and demonstrated that it regulates specific neuropeptides, including those in the egg-laying circuit. We found that NEP-2 is required in muscle cells to regulate signals from neurons to modulate both behavior and health in the reproductive system. Taken together, our results demonstrate that peptidases, which are an important node of regulation in neuropeptide signaling, affect the dynamics of signaling to impact behavior, physiology, and aging. [Display omitted] • Neuropeptidomic screen identified a neuropeptidase, NEP-2, and its targets • NEP-2 regulates NLP-3 neuropeptides to modulate egg-laying behavior • Expression of nep-2 in muscle, and not neurons, is required for proper egg laying • Targeting NEP-2 in animals with compromised egg-laying (matricide) improves health Neuropeptidases are an important and understudied node of regulation in peptidergic circuits. Lo et al. use neuropeptidomics to identify NEP-2 as a neuropeptidase in C. elegans and simultaneously link it to endogenous peptide targets. They demonstrate how NEP-2 regulates the dynamics of peptidergic signaling to impact behavior and aging. [ABSTRACT FROM AUTHOR]

Published

2024

7. Feature sequence- based genome mining uncovers the hidden diversity of bacterial siderophore pathways.

Author

Shaohua Gu, Yuanzhe Shao, Rehm, Karoline, Bigler, Laurent, Di Zhang, Ruolin He, Ruichen Xu, Jiqi Shao, Alexandre Jousset, Friman, Ville-Petri, Xiaoying Bian, Zhong Wei, Kümmerli, Rolf, and Zhiyuan Li

Subjects

*METABOLITES, *ENZYME specificity, *BACTERIAL genomes, *SECONDARY metabolism, *BACTERIAL metabolism, *MICROBIAL metabolites

Abstract

Microbial secondary metabolites are a rich source for pharmaceutical discoveries and play crucial ecological functions. While tools exist to identify secondary metabolite clusters in genomes, precise sequencetofunction mapping remains challenging because neither function nor substrate specificity of biosynthesis enzymes can accurately be predicted. Here, we developed a knowledgeguided bioinformatic pipeline to solve these issues. We analyzed 1928 genomes of Pseudomonas bacteria and focused on iron-scavenging pyoverdines as model metabolites. Our pipeline predicted 188 chemically different pyoverdines with nearly 100% structural accuracy and the presence of 94 distinct receptor groups required for the uptake of ironloaded pyoverdines. Our pipeline unveils an enormous yet overlooked diversity of siderophores (151 new structures) and receptors (91 new groups). Our approach, combining feature sequence with phylogenetic approaches, is extendable to other metabolites and microbial genera, and thus emerges as powerful tool to reconstruct bacterial secondary metabolism pathways based on sequence data. [ABSTRACT FROM AUTHOR]

Published

2024

8. Exploring the Kinetics and Thermodynamics of a Novel Histidine Ammonia-Lyase from Geobacillus kaustophilus.

Author

Salas-Garrucho, Francisco Manuel, Carrillo-Moreno, Alba, Contreras, Lellys M., Rodríguez-Vico, Felipe, Clemente-Jiménez, Josefa María, and Las Heras-Vázquez, Francisco Javier

Subjects

*ENZYME specificity, *BIOTECHNOLOGY, *AMINO acid metabolism, *CIRCULAR dichroism, *BIOCHEMICAL substrates

Abstract

Histidine ammonia-lyase (HAL) plays a pivotal role in the non-oxidative deamination of L-histidine to produce trans-urocanic, a crucial process in amino acid metabolism. This study examines the cloning, purification, and biochemical characterization of a novel HAL from Geobacillus kaustophilus (GkHAL) and eight active site mutants to assess their effects on substrate binding, catalysis, thermostability, and secondary structure. The GkHAL enzyme was successfully overexpressed and purified to homogeneity. Its primary sequence displayed 40.7% to 43.7% similarity with other known HALs and shared the same oligomeric structure in solution. Kinetic assays showed that GkHAL has optimal activity at 85 °C and pH 8.5, with high thermal stability even after preincubation at high temperatures. Mutations at Y52, H82, N194, and E411 resulted in a complete loss of catalytic activity, underscoring their essential role in enzyme function, while mutations at residues Q274, R280, and F325 did not abolish activity but did reduce catalytic efficiency. Notably, mutants R280K and F325Y displayed novel activity with L-histidinamide, expanding the substrate specificity of HAL enzymes. Circular dichroism (CD) analysis showed minor secondary structure changes in the mutants but no significant effect on global GkHAL folding. These findings suggest that GkHAL could be a promising candidate for potential biotechnological applications. [ABSTRACT FROM AUTHOR]

Published

2024

9. De novo engineering of programmable and multi-functional biomolecular condensates for controlled biosynthesis.

Author

Yu, Wenwen, Jin, Ke, Wang, Dandan, Wang, Nankai, Li, Yangyang, Liu, Yanfeng, Li, Jianghua, Du, Guocheng, Lv, Xueqin, Chen, Jian, Ledesma-Amaro, Rodrigo, and Liu, Long

Subjects

GENETIC translation, ENZYME specificity, PHASE separation, BIOSYNTHESIS, BIOMOLECULES

Abstract

There is a growing interest in the creation of engineered condensates formed via liquid–liquid phase separation (LLPS) to exert precise cellular control in prokaryotes. However, de novo design of cellular condensates to control metabolic flux or protein translation remains a challenge. Here, we present a synthetic condensate platform, generated through the incorporation of artificial, disordered proteins to realize specific functions in Bacillus subtilis. To achieve this, the "stacking blocks" strategy is developed to rationally design a series of LLPS-promoting proteins for programming condensates. Through the targeted recruitment of biomolecules, our investigation demonstrates that cellular condensates effectively sequester biosynthetic pathways. We successfully harness this capability to enhance the biosynthesis of 2'-fucosyllactose by 123.3%. Furthermore, we find that condensates can enhance the translation specificity of tailored enzyme fourfold, and can increase N-acetylmannosamine titer by 75.0%. Collectively, these results lay the foundation for the design of engineered condensates endowed with multifunctional capacities. Biomolecular condensates can serve as synthetic organelle-like compartments within prokaryotes. Here, the authors report a synthetic condensate platform, generated through the incorporation of artificial, disordered proteins, and demonstrate control of metabolic flux and protein translation in Bacillus subtilis. [ABSTRACT FROM AUTHOR]

Published

2024

10. Characterization of a GDS(L)-like hydrolase from Pleurotus sapidus with an unusual SGNH motif.

Author

Fingerhut, Miriam A., Henrich, Lea, Lauber, Christiane, Broel, Niklas, Ghezellou, Parviz, Karrer, Dominik, Spengler, Bernhard, Langfelder, Kim, Stressler, Timo, Zorn, Holger, and Gand, Martin

Subjects

*ENZYME specificity, *TRICHODERMA reesei, *ISOELECTRIC focusing, *BIOCHEMICAL substrates, *FERULIC acid

Abstract

The GDS(L)-like lipase from the Basidiomycota Pleurotus sapidus (PSA_Lip) was heterologously expressed using Trichoderma reesei with an activity of 350 U L−1. The isoelectric point of 5.0 was determined by isoelectric focusing. The novel PSA_Lip showed only 23.8–25.1%, 25.5%, 26.6% and 28.4% identity to the previously characterized GDSL-like enzymes phospholipase, plant lipase, acetylcholinesterase and acetylxylan esterase, from the carbohydrate esterase family 16, respectively. Therefore, the enzyme was purified from the culture supernatant and the catalytic properties and the substrate specificity of the enzyme were investigated using different assays to reveal its potential function. While no phospholipase, acetylcholinesterase and acetylxylan esterase activities were detected, studies on the hydrolysis of ferulic acid methyl ester (~ 8.3%) and feruloylated carbohydrate 5-O-transferuloyl-arabino-furanose (~ 0.8%) showed low conversions of these substrates. By investigating the hydrolytic activity towards p-nitrophenyl-(pNP)-esters with various chain-lengths, the highest activity was determined for medium chain-length pNP-octanoate at 65 °C and a pH value of 8, while almost no activity was detected for pNP-hexanoate. The enzyme is highly stable when stored at pH 10 and 4 °C for at least 7 days. Moreover, using consensus sequence analysis and homology modeling, we could demonstrate that the PSA_Lip does not contain the usual SGNH residues in the actives site, which are usually present in GDS(L)-like enzymes. [ABSTRACT FROM AUTHOR]

Published

2024

11. Substrate specificity of a branch of aromatic dioxygenases determined by three distinct motifs.

Author

Cui, Chengsen, Yang, Lu-Jia, Liu, Zi-Wei, Shu, Xian, Zhang, Wei-Wei, Gao, Yuan, Wang, Yu-Xuan, Wang, Te, Chen, Chun-Chi, Guo, Rey-Ting, and Gao, Shu-Shan

Subjects

SUBSTRATES (Materials science), ENZYME specificity, BIOCHEMICAL substrates, AMINO acid sequence, TERTIARY structure, DIOXYGENASES

Abstract

The inversion of substrate size specificity is an evolutionary roadblock for proteins. The Duf4243 dioxygenases GedK and BTG13 are known to catalyze the aromatic cleavage of bulky tricyclic hydroquinone. In this study, we discover a Duf4243 dioxygenase PaD that favors small monocyclic hydroquinones from the penicillic-acid biosynthetic pathway. Sequence alignments between PaD and GedK and BTG13 suggest PaD has three additional motifs, namely motifs 1-3, distributed at different positions in the protein sequence. X-ray crystal structures of PaD with the substrate at high resolution show motifs 1-3 determine three loops (loops 1-3). Most intriguing, loops 1-3 stack together at the top of the pocket, creating a lid-like tertiary structure with a narrow channel and a clearly constricted opening. This drastically changes the substrate specificity by determining the entry and binding of much smaller substrates. Further genome mining suggests Duf4243 dioxygenases with motifs 1-3 belong to an evolutionary branch that is extensively involved in the biosynthesis of natural products and has the ability to degrade diverse monocyclic hydroquinone pollutants. This study showcases how natural enzymes alter the substrate specificity fundamentally by incorporating new small motifs, with a fixed overall scaffold-architecture. It will also offer a theoretical foundation for the engineering of substrate specificity in enzymes and act as a guide for the identification of aromatic dioxygenases with distinct substrate specificities. The Duf4243 dioxygenases GedK and BTG13 are known to catalyze the aromatic cleavage of bulky tricyclic hydroquinone. Here, the authors discover a distinct Duf4243 dioxygenase PaD that favors small monocyclic hydroquinones from the penicillic-acid biosynthetic pathway and determine the structural basis for its changed substrate specificity. [ABSTRACT FROM AUTHOR]

Published

2024

12. Bacterial Purine Nucleoside Phosphorylases from Mesophilic and Thermophilic Sources: Characterization of Their Interaction with Natural Nucleosides and Modified Arabinofuranoside Analogues.

Author

Bychek, Irina A., Zenchenko, Anastasia A., Kostromina, Maria A., Khisamov, Marat M., Solyev, Pavel N., Esipov, Roman S., Mikhailov, Sergey N., and Varizhuk, Irina V.

Subjects

*ENZYME specificity, *NUCLEOSIDE synthesis, *PHOSPHORYLASES, *BIOCHEMICAL substrates, *ORGANIC solvents, *NUCLEOSIDE derivatives

Abstract

The enzymatic synthesis of nucleoside derivatives is an important alternative to multi-step chemical methods traditionally used for this purpose. Despite several undeniable advantages of the enzymatic approach, there are a number of factors limiting its application, such as the limited substrate specificity of enzymes, the need to work at fairly low concentrations, and the physicochemical properties of substrates—for example, low solubility. This research conducted by our group is dedicated to the advantages and limitations of using purine nucleoside phosphorylases (PNPs), the main enzymes for the metabolic reutilization of purines, in the synthesis of modified nucleoside analogues. In our work, the substrate specificity of PNP from various bacterial sources (mesophilic and thermophilic) was studied, and the effect of substrate, increased temperature, and the presence of organic solvents on the conversion rate was investigated. [ABSTRACT FROM AUTHOR]

Published

2024

13. Advances in Cathepsin S Inhibition: Challenges and Breakthroughs in Drug Development.

Author

Ajani, Temitope A., Magwebu, Zandisiwe E., Chauke, Chesa G., and Obikeze, Kenechukwu

Subjects

*ENZYME specificity, *AMINO acid residues, *PROTEOLYTIC enzymes, *AMINO acid sequence, *CAT diseases

Abstract

Cathepsin S (CatS) is a proteolytic enzyme and a member of the cysteine protease family of proteolytic enzymes. Cathepsins S, K, and L are particularly similar in terms of their amino acid sequences and interactions with substrates, and this has made it difficult to develop inhibitors with specificity for either CatS, CatK, or CatL. The involvement of CatS in various disease pathophysiologies (autoimmune disorders, cardiovascular diseases, cancer, etc.) has made it a very important target in drug development. Efforts have been made since the early 1990s to develop a specific CatS inhibitor without any major success. Following many failed efforts to develop an inhibitor for CatS, it was discovered that interactions with the amino acid residues at the S2 and S3 pockets of CatS are critical for the identification of CatS-specific inhibitors. Amino acid residues at these pockets have been the target of recent research focused on developing a non-covalent, reversible, and specific CatS inhibitor. Methods applied in the identification of CatS inhibitors include molecular modeling, in-vitro screening, and in-vivo studies. The molecular modeling process has proven to be very successful in the identification of CatS-specific inhibitors, with R05459072 (Hoffmann-La Roche) and LY3000328 (Eli Lilly Company) which has completed phase 1 clinical trials. CatS inhibitors identified from 2011 to 2023 with promising prospects are discussed in this article. [ABSTRACT FROM AUTHOR]

Published

2024

14. Multiple UDP glycosyltransferases modulate benzimidazole drug sensitivity in the nematode Caenorhabditis elegans in an additive manner.

Author

Sharma, Nidhi, Au, Vinci, Martin, Kiana, Edgley, Mark L., Moerman, Don, Mains, Paul E., and Gilleard, John S.

Subjects

*ENZYME specificity, *RNA interference, *CAENORHABDITIS elegans, *SMALL interfering RNA, *GENETIC mutation, *HAEMONCHUS contortus

Abstract

[Display omitted] • Multiple ugt genes modulate benzimidazole sensitivity in Caenorhabditis elegans. • Genetic mutations revealed that loss of ugt-9 and ugt-11 had the strongest effects. • Multiple UGT enzymes have overlapping but not completely redundant functions. • UGT enzymes may represent "druggable" targets to improve benzimidazole potency. Xenobiotic biotransformation is an important modulator of anthelmintic drug potency and a potential mechanism of anthelmintic resistance. Both the free-living nematode Caenorhabditis elegans and the ruminant parasite Haemonchus contortus biotransform benzimidazole drugs by glucose conjugation, likely catalysed by UDP-glycosyltransferase (UGT) enzymes. To identify C. elegans genes involved in benzimidazole drug detoxification, we first used a comparative phylogenetic analysis of UGTs from humans , C. elegans and H. contortus, combined with available RNAseq datasets to identify which of the 63 C. elegans ugt genes are most likely to be involved in benzimidazole drug biotransformation. RNA interference knockdown of 15 prioritized C. elegans genes identified those that sensitized animals to the benzimidazole derivative albendazole (ABZ). Genetic mutations subsequently revealed that loss of ugt-9 and ugt-11 had the strongest effects. The " ugt-9 cluster " includes these genes, together with six other closely related ugt s. A CRISPR-Cas-9 deletion that removed seven of the eight ugt-9 cluster genes had greater ABZ sensitivity than the single largest-effect mutation. Furthermore, a double mutant of ugt-22 (which is not a member of the ugt-9 cluster) with the ugt-9 cluster deletion further increased ABZ sensitivity. This additivity of mutant phenotypes suggest that ugt genes act in parallel, which could have several, not mutually exclusive, explanations. ugt mutations have different effects with different benzimidazole derivatives, suggesting that enzymes with different specificities could together more efficiently detoxify drugs. Expression patterns of ugt-9, ugt-11 and ugt-22 gfp reporters differ and so likely act in different tissues which may, at least in part, explain their additive effects on drug potency. Overexpression of ugt-9 alone was sufficient to confer partial ABZ resistance, indicating increasing total UGT activity protects animals. In summary, our results suggest that the multiple UGT enzymes have overlapping but not completely redundant functions in benzimidazole drug detoxification and may represent "druggable" targets to improve benzimidazole drug potency. [ABSTRACT FROM AUTHOR]

Published

2024

15. Expression and characterization of a novel microbial GH9 glucanase, IDSGLUC9-4, isolated from shee.

Author

Yongzhen Zhu, Shuning Bai, Nuo Li, Jun-Hong Wang, Jia-Kun Wang, Qian Wang, Kaiying Wang, and Tietao Zhang

Subjects

*TIME-of-flight mass spectrometry, *HIGH performance liquid chromatography, *ENZYME specificity, *BIOCHEMICAL substrates, *POLYSACCHARIDES, *OLIGOSACCHARIDES

Abstract

Objective: This study aimed to identify and characterize a novel endo-β-glucanase, IDSGLUC9-4, from the rumen metatranscriptome of Hu sheep. Methods: A novel endo-β-glucanase, IDSGLUC9-4, was heterologously expressed in Escherichia coli and biochemically characterized. The optimal temperature and pH of recombinant IDSGLUC9-4 were determined. Subsequently, substrate specificity of the enzyme was assessed using mixed-linked glucans including barley β-glucan and Icelandic moss lichenan. Thin-layer chromatography (TLC), high-performance liquid chromatography (HPLC), matrix assisted laser desorption ionization time of flight mass spectrometry analyses were conducted to determine the products released from polysaccharides and cello-oligosaccharides substrates. Results: The recombinant IDSGLUC9-4 exhibited temperature and pH optima of 40°C and pH 6.0, respectively. It exclusively hydrolyzed mixed-linked glucans, with significant activity observed for barley β-glucan (109.59±3.61 μmol/mg min) and Icelandic moss lichenan (35.35±1.55 μmol/mg min). TLC and HPLC analyses revealed that IDSGLUC9-4 primarily released cellobiose, cellotriose, and cellotetraose from polysaccharide substrates. Furthermore, after 48 h of reaction, IDSGLUC9-4 removed most of the glucose, indicating transglycosylation activity alongside its endo-glucanase activity. Conclusion: The recombinant IDSGLUC9-4 was a relatively acid-resistant, mesophilic endo-glucanase (EC 3.2.1.4) that hydrolyzed glucan-like substrates, generating predominantly G3 and G4 oligosaccharides, and which appeared to have glycosylation activity. These findings provided insights into the substrate specificity and product profiles of rumen-derived GH9 glucanases and contributed to the expanding knowledge of cellulolytic enzymes and novel herbivore rumen enzymes in general. [ABSTRACT FROM AUTHOR]

Published

2024

16. Conserved amino acid residues and gene expression patterns associated with the substrate preferences of the competing enzymes FLS and DFR.

Author

Choudhary, Nancy and Pucker, Boas

Subjects

*BIOCHEMICAL substrates, *AMINO acid residues, *AMINO acid sequence, *ORNAMENTAL plants, *ENZYME specificity, *FLAVONES

Abstract

Background: Flavonoids, an important class of specialized metabolites, are synthesized from phenylalanine and present in almost all plant species. Different branches of flavonoid biosynthesis lead to products like flavones, flavonols, anthocyanins, and proanthocyanidins. Dihydroflavonols form the branching point towards the production of non-colored flavonols via flavonol synthase (FLS) and colored anthocyanins via dihydroflavonol 4-reductase (DFR). Despite the wealth of publicly accessible data, there remains a gap in understanding the mechanisms that mitigate competition between FLS and DFR for the shared substrate, dihydroflavonols. Results: An angiosperm-wide comparison of FLS and DFR sequences revealed the amino acids at positions associated with the substrate specificity in both enzymes. A global analysis of the phylogenetic distribution of these amino acid residues revealed that monocots generally possess FLS with Y132 (FLSY) and DFR with N133 (DFRN). In contrast, dicots generally possess FLSH and DFRN, DFRD, and DFRA. DFRA, which restricts substrate preference to dihydrokaempferol, previously believed to be unique to strawberry species, is found to be more widespread in angiosperms and has evolved independently multiple times. Generally, angiosperm FLS appears to prefer dihydrokaempferol, whereas DFR appears to favor dihydroquercetin or dihydromyricetin. Moreover, in the FLS-DFR competition, the dominance of one over the other is observed, with typically only one gene being expressed at any given time. Conclusion: This study illustrates how almost mutually exclusive gene expression and substrate-preference determining residues could mitigate competition between FLS and DFR, delineates the evolution of these enzymes, and provides insights into mechanisms directing the metabolic flux of the flavonoid biosynthesis, with potential implications for ornamental plants and molecular breeding strategies. [ABSTRACT FROM AUTHOR]

Published

2024

17. Chemoenzymatic Synthesis of Plant‐Derived Kavalactone Natural Products by Dynamic Resolution Using a Biosynthetic O‐Methyltransferase Tailoring Enzyme.

Author

Rydzek, Simon, Guth, Florian, Friedrich, Steffen, Noske, Jakob, Höcker, Birte, and Hahn, Frank

Subjects

*ENZYME specificity, *CHIMERIC proteins, *NATURAL products, *BIOCHEMICAL substrates, *BIOCATALYSIS, *KINETIC resolution

Abstract

Biosynthetic enzymes have enormous potential for the chemoenzymatic synthesis of natural products and other bioactive compounds. Methyltransferases are promising tools for the selective enzymatic modification of complex structures. This paper describes the production, purification and biochemical characterization of the O‐methyltransferase JerF, which catalyzes unique 4‐methoxy‐5,6‐dihydropyranone formation in jerangolid A biosynthesis. Isolation problems had hitherto prevented detailed studies on JerF and were solved by the fusion to maltose‐binding protein. The differentiation of JerF between styryl‐substituted dihydropyrandion enantiomers was investigated. In combination with a spontaneous racemization occurring with this type of substrates, a new enzymatic dynamic kinetic resolution was observed, which was used for the enantioselective chemoenzymatic synthesis of kavalactone natural products and new derivatives. In combination with an HMT‐based SAM regeneration system, (+)‐kavain, (+)‐11,12‐dimethoxykavain and (+)‐12‐fluorokavain were prepared in 3–4 steps on a 100 μmol scale with overall yields of 37–57 % and ees of 70–86 %. A mutational study based on an AlphaFold 2 model provided indications for active site residues with an influence on the performance of the enzyme that could be targeted for engineering in the future. This example illustrates how the exceptional enzymatic activities and specificities of biosynthetic enzymes can be exploited for the development of new synthesis approaches. [ABSTRACT FROM AUTHOR]

Published

2024

18. Tuning almond lipase features by the buffer used during immobilization: The apparent biocatalysts stability depends on the immobilization and inactivation buffers and the substrate utilized.

Author

Cherni, Oumaima, Carballares, Diego, Siar, El Hocine, Abellanas-Perez, Pedro, de Andrades, Diandra, de Moraes Polizeli, Maria de Lourdes Teixeira, Rocha-Martin, Javier, Bahri, Sellema, and Fernandez-Lafuente, Roberto

Subjects

*LIPASES, *ENZYME stability, *BIOCHEMICAL substrates, *ENZYMES, *IMMOBILIZED enzymes, *ENZYME specificity, *GLYCINE receptors

Abstract

The lipase from Prunus dulcis almonds was inactivated under different conditions. At pH 5 and 9, enzyme stability remained similar under the different studied buffers. However, when the inactivation was performed at pH 7, there were some clear differences on enzyme stability depending on the buffer used. The enzyme was more stable in Gly than when Tris was employed for inactivation. Then, the enzyme was immobilized on methacrylate beads coated with octadecyl groups at pH 7 in the presence of Gly, Tris, phosphate and HEPES. Its activity was assayed versus triacetin and S -methyl mandelate. The biocatalyst prepared in phosphate was more active versus S -methyl mandelate, while the other ones were more active versus triacetin. The immobilized enzyme stability at pH 7 depends on the buffer used for enzyme immobilization. The buffer used in the inactivation and the substrate used determined the activity. For example, glycine was the buffer that promoted the lowest or the highest stabilities depending on the substrate used to quantify the activities. • The activity and stability of the lipase from almond depends on the buffer at pH 7. • The enzyme was immobilized via interfacial activation using different buffers at pH 7. • The properties of the biocatalysts were quite different. • The enzyme stability depended on the used substrate for activity determination. • A strong relation between inactivation and immobilization buffer and substrate was detected. [ABSTRACT FROM AUTHOR]

Published

2024

19. Increase in the specificity of immunoassay methods by direct targeting different epitopes; sequential chain reactions.

Author

Ahmadi, Yasin, Ahmadi, Hamid, and Aghebati-Maleki, Leili

Subjects

*ENZYME specificity, *BIOCHEMICAL substrates, *IMMUNOASSAY, *EPITOPES, *SENSITIVITY & specificity (Statistics)

Abstract

Immunoassay methods typically involve the use of antibodies, which are either labeled with an enzyme to generate a detectable product or directly tagged with a radioactive or fluorescent substrate. One approach to enhance the specificity of immuno-detection methods is by employing a combination of different antibodies, such as primary and secondary. However, relying solely on one antibody targeting another may not offer the highest level of precision for improving immunoassay specificity; A novel strategy for enhancing the specificity of immunoassay techniques involves directly targeting different epitopes of an antigen. This approach entails utilizing sequential chain reactions facilitated by distinct enzymes bound to various antibodies, each directed at specific epitopes on the antigen. Such an innovative method holds promise for advancing the specificity of immunoassay methods. [ABSTRACT FROM AUTHOR]

Published

2024

20. Hydroxysteroid 17-β dehydrogenase 14 (HSD17B14) is an L-fucose dehydrogenase, the initial enzyme of the L-fucose degradation pathway.

Author

Witecka, Apolonia, Kazak, Varvara, Kwiatkowski, Sebastian, Kiersztan, Anna, Jagielski, Adam K., Kozminski, Wiktor, Augustyniak, Rafal, and Drozak, Jakub

Subjects

*ENZYME specificity, *BIOCHEMICAL substrates, *GLYCOPROTEINS, *ESCHERICHIA coli, *BIOSYNTHESIS, *GLYCOLIPIDS

Abstract

L-Fucose (6-deoxy-L-galactose), a monosaccharide abundant in glycolipids and glycoproteins produced by mammalian cells, has been extensively studied for its role in intracellular biosynthesis and recycling of GDP-L-fucose for fucosylation. However, in certain mammalian species, L-fucose is efficiently broken down to pyruvate and lactate in a poorly understood metabolic pathway. In the 1970s, L-fucose dehydrogenase, an enzyme responsible for the initial step of this pathway, was partially purified from pig and rabbit livers and characterized biochemically. However, its molecular identity remained elusive until recently. This study reports the purification, identification, and biochemical characterization of the mammalian L-fucose dehydrogenase. The enzyme was purified from rabbit liver approximately 340-fold. Mass spectrometry analysis of the purified protein preparation identified mammalian hydroxysteroid 17-β dehydrogenase 14 (HSD17B14) as the sole candidate enzyme. Rabbit and human HSD17B14 were expressed in HEK293T and Escherichia coli, respectively, purified, and demonstrated to catalyze the oxidation of L-fucose to L-fucono-1,5-lactone, as confirmed by mass spectrometry and NMR analysis. Substrate specificity studies revealed that L-fucose is the preferred substrate for both enzymes. The human enzyme exhibited a catalytic efficiency for L-fucose that was 359-fold higher than its efficiency for estradiol. Additionally, recombinant rat HSD17B14 exhibited negligible activity towards L-fucose, consistent with the absence of L-fucose metabolism in this species. The identification of the gene-encoding mammalian L-fucose dehydrogenase provides novel insights into the substrate specificity of enzymes belonging to the 17-b-hydroxysteroid dehydrogenase family. This discovery also paves the way for unraveling the physiological functions of the L-fucose degradation pathway, which remains enigmatic. [ABSTRACT FROM AUTHOR]

Published

2024

21. Carbon nitride coupled two-dimensional metal–organic framework core–shell catalyst for photo-enzymatic synergistic degradation of bisphenol A.

Author

Dong, Yicen, Zhou, Jie, Su, Zheng, Lei, Juying, Zhou, Liang, and Liu, Yongdi

Subjects

*NITRIDES, *METAL-organic frameworks, *ENZYME specificity, *BISPHENOL A, *CATALYSTS, *HYDROGEN peroxide, *ENDOCRINE disruptors

Abstract

Bisphenol A (BPA), as a typical endocrine disruptor, can cause serious harm to human health. In order to solve the limitation of biological enzyme method in the degradation of BPA in actual water, we successfully prepared a photo-enzyme-coupled catalyst CN-HRP@ZIP by in situ generation of a metal–organic skeleton coated with HRP on the carbon nitride surface. The photo-enzymatic synergy of the material and the low mass transfer resistance caused by the two-dimensional ZIP make CN-HRP@ZIP can achieve 100% degradation of BPA at 40 min. The degradation rate was 3.92 times that of CN and 1.65 times that of CN-HRP@ZIF, respectively. The immobilization of the enzyme broadened the degradation pathway and enhanced the resistance to anionic interference by enzyme specificity. The direct conversion of hydrogen peroxide by the enzyme and the indirect enhancement of photocatalytic superoxide radical production increased the concentration of superoxide radicals in the system, and CN-HRP@ZIP maintained a high degradation rate of more than 90% in five cycles. The stability of the enzymatic activity of the material was much higher than that of the free enzyme under extreme pH, high temperature, and organic solvent immersion. These studies provide a new reference for the application of photo-enzymatic synergistic degradation in industrial wastewater treatment. [ABSTRACT FROM AUTHOR]

Published

2024

22. An ISG15-Based High-Throughput Screening Assay for Identification and Characterization of SARS-CoV-2 Inhibitors Targeting Papain-like Protease.

Author

Samrat, Subodh Kumar, Kumar, Prashant, Liu, Yuchen, Chen, Ke, Lee, Hyun, Li, Zhong, Chen, Yin, and Li, Hongmin

Subjects

*FLUORESCENCE resonance energy transfer, *CHEMICAL libraries, *BINDING sites, *ENZYME specificity, *SMALL molecules

Abstract

Emergence of newer variants of SARS-CoV-2 underscores the need for effective antivirals to complement the vaccination program in managing COVID-19. The multi-functional papain-like protease (PLpro) of SARS-CoV-2 is an essential viral protein that not only regulates the viral replication but also modulates the host immune system, making it a promising therapeutic target. To this end, we developed an in vitro interferon stimulating gene 15 (ISG15)-based Förster resonance energy transfer (FRET) assay and screened the National Cancer Institute (NCI) Diversity Set VI compound library, which comprises 1584 small molecules. Subsequently, we assessed the PLpro enzymatic activity in the presence of screened molecules. We identified three potential PLpro inhibitors, namely, NSC338106, 651084, and 679525, with IC50 values in the range from 3.3 to 6.0 µM. These molecules demonstrated in vitro inhibition of the enzyme activity and exhibited antiviral activity against SARS-CoV-2, with EC50 values ranging from 0.4 to 4.6 µM. The molecular docking of all three small molecules to PLpro suggested their specificity towards the enzyme's active site. Overall, our study contributes promising prospects for further developing potential antivirals to combat SARS-CoV-2 infection. [ABSTRACT FROM AUTHOR]

Published

2024

23. Support Enzyme Loading Influences the Effect of Aldehyde Dextran Modification on the Specificity of Immobilized Ficin for Large Proteins.

Author

Siar, El Hocine, Abellanas-Perez, Pedro, Rocha-Martin, Javier, and Fernandez-Lafuente, Roberto

Subjects

*ENZYME specificity, *ENZYMES, *STERIC hindrance, *ALDEHYDES, *DEXTRAN

Abstract

It has been reported that the modification of immobilized glyoxyl–ficin with aldehyde dextran can promote steric hindrances that greatly reduce the activity of the immobilized protease against hemoglobin, while the protease still maintained a reasonable level of activity against casein. In this paper, we studied if this effect may be different depending on the amount of ficin loaded on the support. For this purpose, both the moderately loaded and the overloaded glyoxyl–ficin biocatalysts were prepared and modified with aldehyde dextran. While the moderately loaded biocatalyst had a significantly reduced activity, mainly against hemoglobin, the activity of the overloaded biocatalyst was almost maintained. This suggests that aldehyde dextran was able to modify areas of the moderately loaded enzyme that were not available when the enzyme was overloaded. This modification promoted a significant increase in biocatalyst stability for both biocatalysts, but the stability was higher for the overloaded biocatalyst (perhaps due to a combination of inter- and intramolecular crosslinking). [ABSTRACT FROM AUTHOR]

Published

2024

24. Identify Regioselective Residues of Ginsenoside Hydrolases by Graph-Based Active Learning from Molecular Dynamics.

Author

Li, Yi, Peng, Hong-Qian, Wen, Meng-Liang, and Yang, Li-Quan

Subjects

*GRAPH neural networks, *ENZYME specificity, *MOLECULAR dynamics, *GINSENOSIDES, *HYDROLASES

Abstract

Identifying the catalytic regioselectivity of enzymes remains a challenge. Compared to experimental trial-and-error approaches, computational methods like molecular dynamics simulations provide valuable insights into enzyme characteristics. However, the massive data generated by these simulations hinder the extraction of knowledge about enzyme catalytic mechanisms without adequate modeling techniques. Here, we propose a computational framework utilizing graph-based active learning from molecular dynamics to identify the regioselectivity of ginsenoside hydrolases (GHs), which selectively catalyze C6 or C20 positions to obtain rare deglycosylated bioactive compounds from Panax plants. Experimental results reveal that the dynamic-aware graph model can excellently distinguish GH regioselectivity with accuracy as high as 96–98% even when different enzyme–substrate systems exhibit similar dynamic behaviors. The active learning strategy equips our model to work robustly while reducing the reliance on dynamic data, indicating its capacity to mine sufficient knowledge from short multi-replica simulations. Moreover, the model's interpretability identified crucial residues and features associated with regioselectivity. Our findings contribute to the understanding of GH catalytic mechanisms and provide direct assistance for rational design to improve regioselectivity. We presented a general computational framework for modeling enzyme catalytic specificity from simulation data, paving the way for further integration of experimental and computational approaches in enzyme optimization and design. [ABSTRACT FROM AUTHOR]

Published

2024

25. Biotechnological Production of the Recombinant Two-Component Lantibiotic Lichenicidin in a Bacterial Expression System.

Author

Antoshina, D. V., Balandin, S. V., Tagaev, A. A., Potemkina, A. A., and Ovchinnikova, T. V.

Subjects

*BIOTECHNOLOGY, *ANTIMICROBIAL peptides, *ENZYME specificity, *PEPTIDES, *BIOCHEMICAL substrates

Abstract

Objective: Lantibiotics are a family of bacterial antimicrobial peptides synthesized by ribosomes, that undergo post-translational modification to form lanthionine (Lan) and methyllanthionine (MeLan) residues. Lantibiotics are currently considered promising agents for combating antibiotic-resistant bacterial infections. This paper presents a biotechnological method for obtaining two components of the lantibiotic lichenicidin from Bacillus licheniformis B-511, Lchα and Lchβ. Such a system has the potential to facilitate the production of not only lichenicidin, but also other lantibiotics, including two-component ones, and also to enable the study of their biosynthesis and the activity and substrate specificity of modifying enzymes. Methods: The developed system is based on heterologous coexpression of the genes of Lchα and Lchβ precursors with the genes of their corresponding modifying enzymes in the cytoplasm of Escherichia coli BL21(DE3). Subsequent steps included immobilized metal affinity chromatography of the His-tagged hybrid peptide under denaturing conditions, cyanogen bromide cleavage in acidic medium, and final purification using reverse-phase HPLC. Results and Discussion: The system was employed for the expression and purification of lantibiotics, resulting in the successful isolation of the β-component of lichenicidin in high yield (approximately 4 mg/L of culture). This purified beta component exhibited structural and functional characteristics comparable to its natural counterpart, which was purified from the natural producer. However, the yield of the mature α-component of lichenicidin in such a system was significantly lower. Conclusions: The work presents a biotechnological method for obtaining recombinant two-component lantibiotic lichenicidin, which has proven to be particularly effective in the case of Lchβ. The developed method can also be applied to the production of other promising lantibiotics and their further research. [ABSTRACT FROM AUTHOR]

Published

2024

26. Opportunities for nanomaterials in enzyme therapy.

Author

Torres-Herrero, Beatriz, Armenia, Ilaria, Ortiz, Cecilia, de la Fuente, Jesús Martinez, Betancor, Lorena, and Grazú, Valeria

Subjects

*ENZYME specificity, *ENZYME replacement therapy, *BIOCOMPATIBILITY, *ENZYMES, *NANOSTRUCTURED materials, *NANOBIOTECHNOLOGY, *NEUROPEPTIDES

Abstract

In recent years, enzyme therapy strategies have rapidly evolved to catalyze essential biochemical reactions with therapeutic potential. These approaches hold particular promise in addressing rare genetic disorders, cancer treatment, neurodegenerative conditions, wound healing, inflammation management, and infectious disease control, among others. There are several primary reasons for the utilization of enzymes as therapeutics: their substrate specificity, their biological compatibility, and their ability to generate a high number of product molecules per enzyme unit. These features have encouraged their application in enzyme replacement therapy where the enzyme serves as the therapeutic agent to rectify abnormal metabolic and physiological processes, enzyme prodrug therapy where the enzyme initiates a clinical effect by activating prodrugs, and enzyme dynamic or starving therapy where the enzyme acts upon host substrate molecules. Currently, there are >20 commercialized products based on therapeutic enzymes, but approval rates are considerably lower than other biologicals. This has stimulated nanobiotechnology in the last years to develop nanoparticle-based solutions that integrate therapeutic enzymes. This approach aims to enhance stability, prevent rapid clearance, reduce immunogenicity, and even enable spatio-temporal activation of the therapeutic catalyst. This comprehensive review delves into emerging trends in the application of therapeutic enzymes, with a particular emphasis on the synergistic opportunities presented by incorporating enzymes into nanomaterials. Such integration holds the promise of enhancing existing therapies or even paving the way for innovative nanotherapeutic approaches. [Display omitted] • Enzyme therapies offer new advanced treatments for a wide range of medical conditions. • Enzyme specificity and high product yield are crucial for prodrug activation, replacement, dynamic and starving therapies. • Combining enzymes and nanomaterials enables precise targeting and spatio-temporal remote control of these therapies. [ABSTRACT FROM AUTHOR]

Published

2024

27. Inter domain linker region affects properties of CBM6 in GH5_34 arabinoxylanases and alters oligosaccharide product profile.

Author

Norlander, Siri, Jasilionis, Andrius, Allahgholi, Leila, Wennerberg, Christina, Grey, Carl, Adlercreutz, Patrick, and Karlsson, Eva Nordberg

Subjects

*ENZYME specificity, *OLIGOSACCHARIDES, *OLIGOSACCHARIDE analysis, *ARABINOXYLANS, *CATALYTIC domains, *CATALYTIC activity, *XYLANASES

Abstract

Understanding the relation between enzyme domain structure and catalytic activity is crucial for optimal engineering of novel enzymes for lignocellulose bioconversion. Xylanases with varying specificities are commonly used to valorise the hemicellulose arabinoxylan (AX), yet characterization of specific arabinoxylanases remain limited. Two homologous GH5_34 arabinoxylanases, Hh Xyn5A and Ct Xyn5A, in which the two domains are connected by a 40-residue linker, exhibit distinct activity on AX, yielding different reaction product patterns, despite high sequence identity, conserved active sites and similar domain composition. In this study, the carbohydrate binding module 6 (CBM6), or the inter domain linker together with CBM6, were swapped to investigate their influence on hydrolytic activity and oligosaccharide product pattern on cereal AXs. The variants, with only CBM6 swapped, displayed reduced activity on commercial wheat and rye AX, as well as on extracted oat fibre, compared to the original enzymes. Additionally, exchange of both linker and CBM6 resulted in a reduced ratio of enzyme produced in soluble form in Escherichia coli cultivations, causing loss of activity of both Hh Xyn5A and Ct Xyn5A variants. Analysis of oligosaccharide product patterns applying HPAEC–PAD revealed a decreased number of reaction products for Ct Xyn5A with swapped CBM6, which resembled the product pattern of Hh Xyn5A. These findings emphasize the importance of the CBM6 interactions with the linker and the catalytic domain for enzyme activity and specificity, and underlines the role of the linker in enzyme structure organisation and product formation, where alterations in linker interactions with the catalytic and/or CBM6 domains, influence enzyme-substrate association and specificity. [ABSTRACT FROM AUTHOR]

Published

2024

28. Formate Dehydrogenase: Recent Developments for NADH and NADPH Recycling in Biocatalysis.

Author

Maier, Artur, Mguni, Lindelo M., Ngo, Anna C. R., and Tischler, Dirk

Subjects

*ENZYME specificity, *PROTEIN engineering, *BIOCATALYSIS, *DEHYDROGENASES, *BIOCONVERSION

Abstract

Formate dehydrogenases (FDHs) catalyze the oxidation of formate to CO2 while reducing NAD(P)+ to NAD(P)H and are classified into two main classes: metal‐dependent (Mo‐ or W‐containing) and metal‐independent FDHs. The latter are oxygen‐tolerant and relevant as a cofactor regeneration system for various bioprocesses and gained more and more attention due to their ability to catalyze the reverse CO2 reduction. This review gives an overview of metal‐independent FDHs, the recent advances made in this field, and their relevance for future applications in biocatalysis. This includes the exploitation of novel FDHs which have altered co‐substrate specificity as well as enzyme engineering approaches to improve process stability and general performance. [ABSTRACT FROM AUTHOR]

Published

2024

29. Crystal structure of a newly identified M61 family aminopeptidase with broad substrate specificity that is solely responsible for recycling acidic amino acids.

Author

Jamdar, Sahayog N., Yadav, Pooja, Kulkarni, Bhushan S., Sudesh, Kumar, Ashwani, and Makde, Ravindra D.

Subjects

*SUBSTRATES (Materials science), *BIOCHEMICAL substrates, *AMINO acids, *PEPTIDASE, *ENZYME specificity, *CRYSTAL structure

Abstract

Aminopeptidases with varied substrate specificities are involved in different crucial physiological processes of cellular homeostasis. They also have wide applications in food and pharma industries. Within the bacterial cell, broad specificity aminopeptidases primarily participate in the recycling of amino acids by degrading oligopeptides generated via primary proteolysis mediated by cellular ATP‐dependent proteases. However, in bacteria, a truly broad specificity enzyme, which can cleave off acidic, basic, Gly and hydrophobic amino acid residues, is extremely rare. Here, we report structure–function of a putative glycyl aminopeptidase (M61xc) from Xanthomonas campestris pv campestris (Xcc) belonging to the M61 peptidase family. The enzyme exhibits broad specificity and cleaves Ala, Leu, Asp, Glu, Met, Ser, Phe, Tyr, Gly, Arg, and Lys at the N terminus, optimally of peptides with a length of 3–7 amino acids. Further, we report the high‐resolution crystal structure of M61xc in the apo form (2.1 Å) and bestatin‐bound form (1.95 Å), detailing its catalytic and substrate preference mechanisms. Comparative analysis of enzyme activity in crude cell extracts from both wild‐type and m61xc‐knockout mutant strains of Xcc has elucidated the unique intracellular role of M61xc. This study suggests that M61xc is the exclusive enzyme in these bacteria that is responsible for liberating Asp/Glu residues from the N‐termini of peptides. Also, in view of its broad specificity and peptide degradation ability, it could be considered equivalent to M1 or other oligomeric peptidases from families like M17, M18, M42 or S9, who have an important auxiliary role in post‐proteasomal protein degradation in prokaryotes. [ABSTRACT FROM AUTHOR]

Published

2024

30. Simultaneous quantification of six proteins related to liver injury using nano liquid chromatography–tandem mass spectrometry.

Author

Cai, Siyu, Su, Yuan, Shi, Mengtian, Wang, Dandan, Chen, David Da Yong, and Yan, Binjun

Subjects

*LIVER proteins, *LIQUID chromatography-mass spectrometry, *LIVER injuries, *ASPARTATE aminotransferase, *ENZYME specificity, *ALANINE aminotransferase, *MASS transfer coefficients

Abstract

Rationale: In clinical diagnosis of liver injury, which is an important health concern, serum aminotransferase assays have been the go‐to method used worldwide. However, the measurement of serum enzyme activity has limitations, including inadequate disease specificity and enzyme specificity. Methods: With the high selectivity and specificity provided by nano liquid chromatography–tandem mass spectrometry (LC/MS/MS), this work describes a method for the simultaneous determination of six proteins in liver that can be potentially used as biomarkers for liver injury: glutamic‐pyruvic transaminase 1 (GPT1), glutamic oxaloacetic transaminase 1 (GOT1), methionine adenosyl transferase 1A (MAT1A), glutathione peroxidase 1 (GPX1), cytokeratin 18 (KRT18) and apolipoprotein E (APOE). Results: In validation, the method was shown to have good selectivity and sensitivity (limits of detection at pg/mL level). The analytical method revealed that, compared with normal mice, in carbon tetrachloride‐induced acute liver injury mice, liver MAT1A and GPX1 were significantly lower (p < 0.01 and p < 0.05, respectively), KRT18 was significantly higher (p < 0.05) and APOE and GPT1 were marginally significantly lower (p between 0.05 and 0.1). This is the first work reporting the absolute contents of GPT1, GOT1, MAT1A, GPX1 and KRT18 proteins based on LC/MS. Conclusions: The proposed method provides a basis for establishing more specific diagnostic indicators of liver injury. [ABSTRACT FROM AUTHOR]

Published

2024

31. Enzymatic one-step synthesis of natural 2-pyrones and new-to-nature derivatives from coenzyme A esters.

Author

Manoilenko, Svitlana, Dippe, Martin, Fuchs, Tristan, Eisenschmidt-Bönn, Daniela, Ziegler, Jörg, Bauer, Anne-Katrin, and Wessjohann, Ludger A.

Subjects

*POLYKETIDE synthases, *ENZYME specificity, *POLYKETIDES, *ESTERS, *DIOXYGENASES, *AMINO acid residues, *SYNTHASES, *NATURAL products

Abstract

The 2-pyrone moiety is present in a wide range of structurally diverse natural products with various biological activities. The plant biosynthetic routes towards these compounds mainly depend on the activity of either type III polyketide synthase-like 2-pyrone synthases or hydroxylating 2-oxoglutarate dependent dioxygenases. In the present study, the substrate specificity of these enzymes is investigated by a systematic screening using both natural and artificial substrates with the aims of efficiently forming (new) products and understanding the underlying catalytic mechanisms. In this framework, we focused on the in vitro functional characterization of a 2-pyrone synthase Gh2PS2 from Gerbera x hybrida and two dioxygenases AtF6'H1 and AtF6'H2 from Arabidopsis thaliana using a set of twenty aromatic and aliphatic CoA esters as substrates. UHPLC-ESI-HRMSn based analyses of reaction intermediates and products revealed a broad substrate specificity of the enzymes, enabling the facile "green" synthesis of this important class of natural products and derivatives in a one-step/one-pot reaction in aqueous environment without the need for halogenated or metal reagents and protective groups. Using protein modeling and substrate docking we identified amino acid residues that seem to be important for the observed product scope. • Enzymatic synthesis led to the one-pot formation of 2-pyrones from coenzyme A esters. • Promiscuous polyketide synthases or hydroxylases were applied in the reactions. • The syntheses yielded both natural and new-to-nature 2-pyrones including coumarins. • The formed derivatives constitute lead structures for improved aromas and biocides. [ABSTRACT FROM AUTHOR]

Published

2024

32. Shaking Hands with Streptococcal Antibody-Degrading Enzymes for Clinical Use (Review).

Author

Jain, S., Srivastava, S., Gulati, I., and Bhandari, K.

Subjects

*ENZYME specificity, *IMMUNE response, *IMMUNOGLOBULIN G, *STREPTOCOCCUS pyogenes, *COMPLEMENT activation

Abstract

Antibody-degrading enzymes are one among crucial virulence factors of pathogenic bacteria and parasites for they help the inhabitant evade the attacks of the host immune system. IdeS and EndoS are two such well-characterised enzymes of Streptococcus pyogenes that have the ability to cleave specific peptide bonds within the hinge region of the antibody and deglycosylate the molecule leading to loss of its effector functions, including activation of complement cascade by classical pathway and bridgement of cytotoxic cells. This forms the basis for development of enzyme-based interventions for antibody-mediated clinical conditions including various autoimmune disorders, organ rejection during transplantations, and therapeutic viral vector destruction. The specificity of these enzymes is exploited in efficient proteolytic processing of anti-cancer monoclonal antibodies for their characterization and production of clinically-important fragments. Use of antibody-degrading enzymes in clinical settings comes with some unmet challenges in terms of safe application, economical production, efficient immobilization, patient-friendly delivery, and limited scope. [ABSTRACT FROM AUTHOR]

Published

2024

33. Purification, characterisation and immobilisation of a protease‐resistant α‐galactosidase from Monascus purpureus and its application in removal of raffinose family oligosaccharides.

Author

Zhu, Chong, Katrolia, Priti, and Kopparapu, Narasimha Kumar

Subjects

*MONASCUS purpureus, *RAFFINOSE, *OLIGOSACCHARIDES, *ENZYME specificity, *GALACTOSE, *SOY proteins, *MICROENCAPSULATION, *GALACTOSIDASES

Abstract

Summary: In this study, an α‐galactosidase (MPG) was produced by submerged fermentation from Monascus purpureus, a food‐grade fungus used for making red yeast rice. MPG was purified from intracellular extract which showed a subunit molecular mass of 95 kDa. MPG was optimally active at pH 4.0 and 50 °C and was stable between pH 3.5–8.0 and at temperatures up to 50 °C. The enzyme retained its activity in the presence of most of the metal ions except Cu2+ and Fe2+. MPG exhibited remarkable resistance to the proteases, pepsin, trypsin and proteinase K as well as to the sugars, galactose and sucrose. Moreover, it retained complete activity under simulated gastric conditions. The enzyme displayed specificity for the substrates, melibiose, raffinose and stachyose and was able to hydrolyze these oligosaccharides. It was effective in the removal of non‐digestible raffinose family oligosaccharides (RFOs) from soybeans, chickpeas and kidney beans. MPG was immobilised onto chitosan and the immobilised enzyme (iMPG) displayed higher optimal temperature (60 °C), better thermostability and substrate specificity as compared to MPG. iMPG was also capable of hydrolyzing RFOs in chickpeas and could be efficiently reused six times. In view of their superior properties, MPG and iMPG may have great prospects in the food and feed industries for the removal of RFOs from soy and other legumes. [ABSTRACT FROM AUTHOR]

Published

2024

34. Introduction of a Sodium-Binding Motif into Subunits a and c of Bacillus sp. PS3 Proton F-ATPase Does Not Result in Sodium Specificity of the Enzyme.

Author

Bruman, S. M., Litvin, A. V., Lapashina, A. S., and Feniouk, B. A.

Subjects

*ENZYME specificity, *ADENOSINE triphosphatase, *BACILLUS (Bacteria), *PLAYSTATION video game consoles, *AMINO acid sequence, *PROTON conductivity

Abstract

In bacteria, F-type ATPase (F-ATPase) plays a key role in bioenergetics and couples ATP synthesis/hydrolysis with the transport of ions (H+ or Na+) across the membrane. The ion specificity of the enzyme is determined by the amino acid sequence of subunits c and a. Here, we introduced several mutations (7 in subunit c and 6 in subunit a) into F-ATPase of thermophilic bacterium Bacillus sp. PS3 in order to change the ion specificity of the enzyme from proton to sodium. The mutations did not affect the ATPase activity of the enzyme, but led to loss of proton conductivity and impaired the binding of subunit a to the c-subunit oligomer, rather than changed the ion specificity. [ABSTRACT FROM AUTHOR]

Published

2024

35. Thiol dioxygenases: from structures to functions.

Author

Perri, Monica and Licausi, Francesco

Subjects

*DIOXYGENASES, *SULFINIC acids, *ENZYME specificity, *X-ray crystallography, *SMALL molecules, *PROTEOLYSIS

Abstract

Thiol dioxygenases (TDOs) participate in the metabolism of small thiol-containing molecules, and more recently they were discovered to contribute to cell signaling. A specific clade of TDOs in plants and metazoans regulates the oxygen-dependent degradation of regulatory proteins through the N-degron pathway. X-ray crystallography, spectroscopic analyses, and dynamic simulations have identified crucial features for the activity and specificity of TDOs. These techniques have also assisted in designing mutant variants and exploring their consequences in vitro and in vivo. Structural information, along with the design of activity assays in heterologous systems, has guided the identification of specific inhibitors. Thiol oxidation to dioxygenated sulfinic acid is catalyzed by an enzyme family characterized by a cupin fold. These proteins act on free thiol-containing molecules to generate central metabolism precursors and signaling compounds in bacteria, fungi, and animal cells. In plants and animals, they also oxidize exposed N-cysteinyl residues, directing proteins to proteolysis. Enzyme kinetics, X-ray crystallography, and spectroscopy studies prompted the formulation and testing of hypotheses about the mechanism of action and the different substrate specificity of these enzymes. Concomitantly, the physiological role of thiol dioxygenation in prokaryotes and eukaryotes has been studied through genetic and physiological approaches. Further structural characterization is necessary to enable precise and safe manipulation of thiol dioxygenases (TDOs) for therapeutic, industrial, and agricultural applications. [ABSTRACT FROM AUTHOR]

Published

2024

36. Isolation and Characterization of Phenylalanine Ammonia Lyase (PAL) Genes in Ferula pseudalliacea : Insights into the Phenylpropanoid Pathway.

Author

Shahidi, Pegah, Bahramnejad, Bahman, Vafaee, Yavar, Dastan, Dara, and Heidari, Parviz

Subjects

*PHENYLALANINE ammonia lyase, *PHENYLPROPANOIDS, *FERULA, *ENZYME specificity, *ENZYME kinetics, *CARROTS

Abstract

Phenylalanine ammonia lyase (PAL) is a key enzyme regulating the biosynthesis of the compounds of the phenylpropanoid pathway. This study aimed to isolate and characterize PAL genes from Ferula pseudalliacea Rech.f. (Apiales: Apiaceae) to better understand the regulation of metabolite production. Three PAL gene isoforms (FpPAL1-3) were identified and cloned using the 3′-RACE technique and confirmed by sequencing. Bioinformatics analysis revealed important structural features, such as phosphorylation sites, physicochemical properties, and evolutionary relationships. Expression analysis by qPCR demonstrated the differential transcription profiles of each FpPAL isoform across roots, stems, leaves, flowers, and seeds. FpPAL1 showed the highest expression in stems, FpPAL2 in roots and flowers, and FpPAL3 in flowers. The presence of three isoforms of PAL in F. pseudalliacea, along with the diversity of PAL genes and their tissue-specific expression profiles, suggests that complex modes of regulation exist for phenylpropanoid biosynthesis in this important medicinal plant. The predicted interaction network revealed associations with key metabolic pathways, emphasizing the multifaceted roles of these PAL genes. In silico biochemical analyses revealed the hydrophilicity of the FpPAL isozyme; however, further analysis of substrate specificity and enzyme kinetics can clarify the specific role of each FpPAL isozyme. These comprehensive results increase the understanding of PAL genes in F. pseudalliacea, helping to characterize their contributions to secondary metabolite biosynthesis. [ABSTRACT FROM AUTHOR]

Published

2024

37. The monodomain Kunitz protein EgKU-7 from the dog tapeworm Echinococcus granulosus is a high-affinity trypsin inhibitor with two interaction sites.

Author

Fló, Martín, Pellizza, Leonardo, Durán, Rosario, Alvarez, Beatriz, and Fernández, Cecilia

Subjects

*ECHINOCOCCUS granulosus, *SERINE proteinase inhibitors, *TAPEWORMS, *ENZYME specificity, *TRYPSIN inhibitors, *PROTEINS, *DOGS, *PEPTIDASE

Abstract

Typical Kunitz proteins (I2 family of the MEROPS database, Kunitz-A family) are metazoan competitive inhibitors of serine peptidases that form tight complexes of 1:1 stoichiometry, mimicking substrates. The cestode Echinococcus granulosus, the dog tapeworm causing cystic echinococcosis in humans and livestock, encodes an expanded family of monodomain Kunitz proteins, some of which are secreted to the dog host interface. The Kunitz protein EgKU-7 contains, in addition to the Kunitz domain with the anti-peptidase loop comprising a critical arginine, a C-terminal extension of ~20 amino acids. Kinetic, electrophoretic, and mass spectrometry studies using EgKU-7, a C-terminally truncated variant, and a mutant in which the critical arginine was substituted by alanine, show that EgKU-7 is a tight inhibitor of bovine and canine trypsins with the unusual property of possessing two instead of one site of interaction with the peptidases. One site resides in the anti-peptidase loop and is partially hydrolyzed by bovine but not canine trypsins, suggesting specificity for the target enzymes. The other site is located in the C-terminal extension. This extension can be hydrolyzed in a particular arginine by cationic bovine and canine trypsins but not by anionic canine trypsin. This is the first time to our knowledge that a monodomain Kunitz-A protein is reported to have two interaction sites with its target. Considering that putative orthologs of EgKU-7 are present in other cestodes, our finding unveils a novel piece in the repertoire of peptidase-inhibitor interactions and adds new notes to the evolutionary host-parasite concerto. [ABSTRACT FROM AUTHOR]

Published

2024

38. Does Acinetobacter calcoaceticus glucose dehydrogenase produce self-damaging H2O2?

Author

Lublin, Victoria, Kauffmann, Brice, Engilberge, Sylvain, Durola, Fabien, Gounel, Sébastien, Bichon, Sabrina, Jean, Cloée, Mano, Nicolas, Giraud, Marie-France, Chavas, Léonard Michel Gabriel Henri, Thureau, Aurélien, Thompson, Andrew, and Stines-Chaumeil, Claire

Subjects

*ENZYME specificity, *GLUCOSE, *PQQ (Biochemistry), *BLOOD sugar measurement, *ACINETOBACTER, *CATALASE

Abstract

The soluble glucose dehydrogenase (sGDH) from Acinetobacter calcoaceticus has been widely studied and is used, in biosensors, to detect the presence of glucose, taking advantage of its high turnover and insensitivity to molecular oxygen. This approach, however, presents two drawbacks: the enzyme has broad substrate specificity (leading to imprecise blood glucose measurements) and shows instability over time (inferior to other oxidizing glucose enzymes). We report the characterization of two sGDH mutants: the single mutant Y343F and the double mutant D143E/Y343F. The mutants present enzyme selectivity and specificity of 1.2 (Y343F) and 5.7 (D143E/Y343F) times higher for glucose compared with that of the wild-type. Crystallographic experiments, designed to characterize these mutants, surprisingly revealed that the prosthetic group PQQ (pyrroloquinoline quinone), essential for the enzymatic activity, is in a cleaved form for both wild-type and mutant structures. We provide evidence suggesting that the sGDH produces H2O2, the level of production depending on the mutation. In addition, spectroscopic experiments allowed us to follow the self-degradation of the prosthetic group and the disappearance of sGDH's glucose oxidation activity. These studies suggest that the enzyme is sensitive to its self-production of H2O2. We show that the premature aging of sGDH can be slowed down by adding catalase to consume the H2O2 produced, allowing the design of a more stable biosensor over time. Our research opens questions about the mechanism of H2O2 production and the physiological role of this activity by sGDH. [ABSTRACT FROM AUTHOR]

Published

2024

39. Expression and Characterization of an Efficient Alginate Lyase from Psychromonas sp. SP041 through Metagenomics Analysis of Rotten Kelp.

Author

Wang, Ping, Cai, Yi, Zhong, Hua, Chen, Ruiting, Yi, Yuetao, Ye, Yanrui, and Li, Lili

Subjects

*ALGINIC acid, *ENZYME specificity, *METAGENOMICS, *BROWN algae, *KELPS

Abstract

Alginate is derived from brown algae, which can be cultivated in large quantities. It can be broken down by alginate lyase into alginate oligosaccharides (AOSs), which exhibit a higher added value and better bioactivity than alginate. In this study, metagenomic technology was used to screen for genes that code for high-efficiency alginate lyases. The candidate alginate lyase gene alg169 was detected from Psychromonas sp. SP041, the most abundant species among alginate lyase bacteria on selected rotten kelps. The alginate lyase Alg169 was heterologously expressed in Escherichia coli BL21 (DE3), Ni-IDA-purified, and characterized. The optimum temperature and pH of Alg169 were 25 °C and 7.0, respectively. Metal ions including Mn2+, Co2+, Ca2+, Mg2+, Ni2+, and Ba2+ led to significantly increased enzyme activity. Alg169 exhibited a pronounced dependence on Na+, and upon treatment with Mn2+, its activity surged by 687.57%, resulting in the highest observed enzyme activity of 117,081 U/mg. Bioinformatic analysis predicted that Alg169 would be a double-domain lyase with a molecular weight of 65.58 kDa. It is a bifunctional enzyme with substrate specificity to polyguluronic acid (polyG) and polymannuronic acid (polyM). These results suggest that Alg169 is a promising candidate for the efficient manufacturing of AOSs from brown seaweed. [ABSTRACT FROM AUTHOR]

Published

2024

40. Does Acinetobacter calcoaceticus glucose dehydrogenase produce self-damaging H2O2?

Author

Lublin, Victoria, Kauffmann, Brice, Engilberge, Sylvain, Durola, Fabien, Gounel, Sébastien, Bichon, Sabrina, Jean, Cloée, Mano, Nicolas, Giraud, Marie-France, Chavas, Léonard Michel Gabriel Henri, Thureau, Aurélien, Thompson, Andrew, and Stines-Chaumeil, Claire

Subjects

ENZYME specificity, GLUCOSE, PQQ (Biochemistry), BLOOD sugar measurement, ACINETOBACTER, CATALASE

Abstract

The soluble glucose dehydrogenase (sGDH) from Acinetobacter calcoaceticus has been widely studied and is used, in biosensors, to detect the presence of glucose, taking advantage of its high turnover and insensitivity to molecular oxygen. This approach, however, presents two drawbacks: the enzyme has broad substrate specificity (leading to imprecise blood glucose measurements) and shows instability over time (inferior to other oxidizing glucose enzymes). We report the characterization of two sGDH mutants: the single mutant Y343F and the double mutant D143E/Y343F. The mutants present enzyme selectivity and specificity of 1.2 (Y343F) and 5.7 (D143E/Y343F) times higher for glucose compared with that of the wild-type. Crystallographic experiments, designed to characterize these mutants, surprisingly revealed that the prosthetic group PQQ (pyrroloquinoline quinone), essential for the enzymatic activity, is in a cleaved form for both wild-type and mutant structures. We provide evidence suggesting that the sGDH produces H2O2, the level of production depending on the mutation. In addition, spectroscopic experiments allowed us to follow the self-degradation of the prosthetic group and the disappearance of sGDH's glucose oxidation activity. These studies suggest that the enzyme is sensitive to its self-production of H2O2. We show that the premature aging of sGDH can be slowed down by adding catalase to consume the H2O2 produced, allowing the design of a more stable biosensor over time. Our research opens questions about the mechanism of H2O2 production and the physiological role of this activity by sGDH. [ABSTRACT FROM AUTHOR]

Published

2024

41. Flexible active-site loops fine-tune substrate specificity of hyperthermophilic metallo-oxidases.

Author

Brissos, Vânia, Borges, Patrícia T., Sancho, Ferran, Lucas, Maria Fátima, Frazão, Carlos, Conzuelo, Felipe, and Martins, Lígia O.

Subjects

*BIOCHEMICAL substrates, *IRON ions, *ENZYME specificity, *HIGH throughput screening (Drug development), *OXIDASES, *AMINE oxidase

Abstract

Hyperthermophilic ('superheat-loving') archaea found in high-temperature environments such as Pyrobaculum aerophilum contain multicopper oxidases (MCOs) with remarkable efficiency for oxidizing cuprous and ferrous ions. In this work, directed evolution was used to expand the substrate specificity of P. aerophilum McoP for organic substrates. Six rounds of error-prone PCR and DNA shuffling followed by high-throughput screening lead to the identification of a hit variant with a 220-fold increased efficiency (kcat/Km) than the wild-type for 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulphonic acid) (ABTS) without compromising its intrinsic activity for metal ions. The analysis of the X-ray crystal structure reveals four proximal mutations close to the T1Cu active site. One of these mutations is within the 23-residues loop that occludes this site, a distinctive feature of prokaryotic MCOs. The increased flexibility of this loop results in an enlarged tunnel and one additional pocket that facilitates bulky substrate-enzyme interactions. These findings underscore the synergy between mutations that modulate the dynamics of the active-site loop enabling enhanced catalytic function. This study highlights the potential of targeting loops close to the T1Cu for engineering improvements suitable for biotechnological applications. [ABSTRACT FROM AUTHOR]

Published

2024

42. Lipase-Catalyzed Preparation and Optimization of Structured Phosphatidylcholine Containing Nervonic Acid.

Author

Ang, Xun, Chen, Hong, Xiang, Jiqian, Wei, Fang, and Quek, Siew Young

Subjects

*LIPASES, *LECITHIN, *ENZYME specificity, *ACIDOLYSIS, *ACIDS, *CHEMICAL structure

Abstract

This study investigated the incorporation of nervonic acid into the chemical structure of phosphatidylcholine via a lipase-catalyzed acidolysis reaction to obtain a functional phospholipid. Lipase immobilization was conducted, and Amberlite XAD7-HP was selected as a carrier to immobilize phospholipase A1 (PLA1) for subsequent experiments. The main acidolysis reaction parameters, including enzyme load, substrate ratio, temperature, and water content, were studied against the reaction time. The optimum reaction conditions obtained were enzyme load, 20%; reaction temperature, 55 °C; water content, 1%; and reaction time, 9 h. The maximum incorporation of nervonic acid into phosphatidylcholine was 48 mol%, with PC recovery at 61.6 mol%. The positional distribution of structured phosphatidylcholine shows that nervonic acid was found in the sn-1 position due to enzyme specificity and in the sn-2 position, possibly due to acyl migration. [ABSTRACT FROM AUTHOR]

Published

2024

43. Druggable Sterol Metabolizing Enzymes in Infectious Diseases: Cell Targets to Therapeutic Leads.

Author

Nes, W. David, Chaudhuri, Minu, and Leaver, David J.

Subjects

*DRUG design, *COMMUNICABLE diseases, *ENZYME specificity, *ENZYMES, *SMALL molecules, *ISOPENTENOIDS

Abstract

Sterol biosynthesis via the mevalonate-isoprenoid pathway produces ergosterol (24β-methyl cholesta-5,7-dienol) necessary for growth in a wide-range of eukaryotic pathogenic organisms in eukaryotes, including the fungi, trypanosomes and amoebae, while their animal hosts synthesize a structurally less complicated product—cholesterol (cholest-5-enol). Because phyla-specific differences in sterol metabolizing enzyme architecture governs the binding and reaction properties of substrates and inhibitors while the order of sterol metabolizing enzymes involved in steroidogenesis determine the positioning of crucial chokepoint enzymes in the biosynthetic pathway, the selectivity and effectiveness of rationally designed ergosterol biosynthesis inhibitors toward ergosterol-dependent infectious diseases varies greatly. Recent research has revealed an evolving toolbox of mechanistically distinct tight-binding inhibitors against two crucial methylation-demethylation biocatalysts—the C24 sterol methyl transferase (absent from humans) and the C14-sterol demethylase (present generally in humans and their eukaryotic pathogens). Importantly for rational drug design and development, the activities of these enzymes can be selectively blocked in ergosterol biosynthesis causing loss of ergosterol and cell killing without harm to the host organism. Here, we examine recent advances in our understanding of sterol biosynthesis and the reaction differences in catalysis for sterol methylation-demethylation enzymes across kingdoms. In addition, the novelties and nuances of structure-guided or mechanism-based approaches based on crystallographic mappings and substrate specificities of the relevant enzyme are contrasted to conventional phenotypic screening of small molecules as an approach to develop new and more effective pharmacological leads. [ABSTRACT FROM AUTHOR]

Published

2024

44. Unveiling the Broad Substrate Specificity of Deoxynivalenol Oxidation Enzyme DepA and Its Role in Detoxifying Trichothecene Mycotoxins.

Author

Zhu, Yan, Chan, Edicon Tze Shun, Abraham, Nadine, Li, Xiu-Zhen, Wang, Weijun, Mats, Lili, Zhu, Honghui, Carere, Jason, and Zhou, Ting

Subjects

*DEOXYNIVALENOL, *ENZYME specificity, *FUSARIUM toxins, *MYCOTOXINS, *PQQ (Biochemistry), *MOLECULAR docking, *RESPONSE surfaces (Statistics), *ENZYMES

Abstract

DepA, a pyrroloquinoline quinone (PQQ)-dependent enzyme isolated from Devosia mutans 17-2-E-8, exhibits versatility in oxidizing deoxynivalenol (DON) and its derivatives. This study explored DepA's substrate specificity and enzyme kinetics, focusing on DON and 15-acetyl-DON. Besides efficiently oxidizing DON, DepA also transforms 15-acetyl-DON into 15-acetyl-3-keto-DON, as identified via LC-MS/MS and NMR analysis. The kinetic parameters, including the maximum reaction rate, turnover number, and catalytic efficiency, were thoroughly evaluated. DepA-PQQ complex docking was deployed to rationalize the substrate specificity of DepA. This study further delves into the reduced toxicity of the transformation products, as demonstrated via enzyme homology modeling and in silico docking analysis with yeast 80S ribosomes, indicating a potential decrease in toxicity due to lower binding affinity. Utilizing the response surface methodology and central composite rotational design, mathematical models were developed to elucidate the relationship between the enzyme and cofactor concentrations, guiding the future development of detoxification systems for liquid feeds and grain processing. This comprehensive analysis underscores DepA's potential for use in mycotoxin detoxification, offering insights for future applications. [ABSTRACT FROM AUTHOR]

Published

2024

45. Broad Chain-Length Specificity of the Alkane-Forming Enzymes NoCER1A and NoCER3A/B in Nymphaea odorata.

Author

Kojima, Hisae, Yamamoto, Kanta, Suzuki, Takamasa, Hayakawa, Yuri, Niwa, Tomoko, Tokuhiro, Kenro, Katahira, Satoshi, Higashiyama, Tetsuya, and Ishiguro, Sumie

Subjects

*ENZYME specificity, *SURFACE cleaning, *CELL culture, *ALKANES, *BIOSYNTHESIS

Abstract

Many terrestrial plants produce large quantities of alkanes for use in epicuticular wax and the pollen coat. However, their carbon chains must be long to be useful as fuel or as a petrochemical feedstock. Here, we focus on Nymphaea odorata , which produces relatively short alkanes in its anthers. We identified orthologs of the Arabidopsis alkane biosynthesis genes AtCER1 and AtCER3 in N. odorata and designated them NoCER1A, NoCER3A and NoCER3B. Expression analysis of NoCER1A and NoCER3A/B in Arabidopsis cer mutants revealed that the N. odorata enzymes cooperated with the Arabidopsis enzymes and that the NoCER1A produced shorter alkanes than AtCER1, regardless of which CER3 protein it interacted with. These results indicate that AtCER1 frequently uses a C30 substrate, whereas NoCER1A, NoCER3A/B and AtCER3 react with a broad range of substrate chain lengths. The incorporation of shorter alkanes disturbed the formation of wax crystals required for water-repellent activity in stems, suggesting that chain-length specificity is important for surface cleaning. Moreover, cultured tobacco cells expressing NoCER1A and NoCER3A/B effectively produced C19–C23 alkanes, indicating that the introduction of the two enzymes is sufficient to produce alkanes. Taken together, our findings suggest that these N. odorata enzymes may be useful for the biological production of alkanes of specific lengths. 3D modeling revealed that CER1s and CER3s share a similar structure that consists of N- and C-terminal domains, in which their predicted active sites are respectively located. We predicted the complex structure of both enzymes and found a cavity that connects their active sites. [ABSTRACT FROM AUTHOR]

Published

2024

46. Comparative Analysis of Shikonin and Alkannin Acyltransferases Reveals Their Functional Conservation in Boraginaceae.

Author

Oshikiri, Haruka, Li, Hao, Manabe, Misaki, Yamamoto, Hirobumi, Yazaki, Kazufumi, and Takanashi, Kojiro

Subjects

*ACYLTRANSFERASES, *SHIKONIN, *BORAGINACEAE, *ENZYME specificity, *COMPARATIVE studies, *PLANT species, *NICOTIANA benthamiana, *NICOTIANA

Abstract

Shikonin and its enantiomer, alkannin, are bioactive naphthoquinones produced in several plants of the family Boraginaceae. The structures of these acylated derivatives, which have various short-chain acyl moieties, differ among plant species. The acylation of shikonin and alkannin in Lithospermum erythrorhizon was previously reported to be catalyzed by two enantioselective BAHD acyltransferases, shikonin O-acyltransferase (LeSAT1) and alkannin O-acyltransferase (LeAAT1). However, the mechanisms by which various shikonin and alkannin derivatives are produced in Boraginaceae plants remain to be determined. In the present study, evaluation of six Boraginaceae plants identified 23 homologs of LeSAT1 and LeAAT1, with 15 of these enzymes found to catalyze the acylation of shikonin or alkannin, utilizing acetyl-CoA, isobutyryl-CoA or isovaleryl-CoA as an acyl donor. Analyses of substrate specificities of these enzymes for both acyl donors and acyl acceptors and determination of their subcellular localization using Nicotiana benthamiana revealed a distinct functional differentiation of BAHD acyltransferases in Boraginaceae plants. Gene expression of these acyltransferases correlated with the enantiomeric ratio of produced shikonin/alkannin derivatives in L. erythrorhizon and Echium plantagineum. These enzymes showed conserved substrate specificities for acyl donors among plant species, indicating that the diversity in acyl moieties of shikonin/alkannin derivatives involved factors other than the differentiation of acyltransferases. These findings provide insight into the chemical diversification and evolutionary processes of shikonin/alkannin derivatives. [ABSTRACT FROM AUTHOR]

Published

2024

47. Bio‐Inspired Microreactors Continuously Synthesize Glucose Precursor from CO2 with an Energy Conversion Efficiency 3.3 Times of Rice.

Author

Zhu, Yujiao, Xie, Fengjia, Wun, Tommy Ching Kit, Li, Kecheng, Lin, Huan, Tsoi, Chi Chung, Jia, Huaping, Chai, Yao, Zhao, Qian, Lo, Benedict Tsz‐woon, Leu, Shao‐Yuan, Jia, Yanwei, Ren, Kangning, and Zhang, Xuming

Subjects

*ENERGY consumption, *ENERGY conversion, *MICROREACTORS, *ENZYME specificity, *GLUCOSE, *OXYGENASES, *GLUCOSE analysis

Abstract

Excessive CO2 and food shortage are two grand challenges of human society. Directly converting CO2 into food materials can simultaneously alleviate both, like what green crops do in nature. Nevertheless, natural photosynthesis has a limited energy efficiency due to low activity and specificity of key enzyme D‐ribulose‐1,5‐bisphosphate carboxylase/oxygenase (RuBisCO). To enhance the efficiency, many prior studies focused on engineering the enzymes, but this study chooses to learn from the nature to design more efficient reactors. This work is original in mimicking the stacked structure of thylakoids in chloroplasts to immobilize RuBisCO in a microreactor using the layer‐by‐layer strategy, obtaining the continuous conversion of CO2 into glucose precursor at 1.9 nmol min−1 with enhanced activity (1.5 times), stability (≈8 times), and reusability (96% after 10 reuses) relative to the free RuBisCO. The microreactors are further scaled out from one to six in parallel and achieve the production at 15.8 nmol min−1 with an energy conversion efficiency of 3.3 times of rice, showing better performance of this artificial synthesis than NPS in terms of energy conversion efficiency. The exploration of the potential of mass production would benefit both food supply and carbon neutralization. [ABSTRACT FROM AUTHOR]

Published

2024

48. Halophilic filamentous fungi and their enzymes: Potential biotechnological applications.

Author

Ben Hmad, Ines and Gargouri, Ali

Subjects

*FILAMENTOUS fungi, *HALOPHILIC microorganisms, *ENZYME specificity, *METABOLITES, *ACTION spectrum

Abstract

Recently, interest in the study of microorganisms growing under extreme conditions, particularly halophiles, has increased due to their potential use in industrial processes. Halophiles are the class of microorganisms that grow optimally at high NaCl concentrations and are capable of producing halophilic enzymes capable of catalyzing reactions under harsh conditions. So far, fungi are the least studied halophilic microorganisms, even though they have been shown to counteract these extreme conditions by producing secondary metabolites with very interesting properties. This review highlights mechanisms that allow halophilic fungi to adapt high salinity and the specificity of their enzymes to a spectrum of action in industrial and environmental applications. The peculiarities of these enzymes justify the urgent need to apply green alternative compounds in industries. • Fungi are the least studied microorganisms among halophiles. • Different mechanisms of adaptation of halophilic fungi. • Fungal halozymes and their peculiarities. • Various applications of fungal halozymes. [ABSTRACT FROM AUTHOR]

Published

2024

49. Highly Promiscuous Flavonoid Di- O -glycosyltransferases from Carthamus tinctorius L.

Author

Xu, Xiaoyu, Xia, Meng, Han, Yang, Tan, Honghu, Chen, Yanying, Song, Xinqi, Yuan, Shijun, Zhang, Yifeng, Su, Ping, and Huang, Luqi

Subjects

*SAFFLOWER, *FLAVONOIDS, *FLAVONOID glycosides, *ISOFLAVONES, *ENZYME specificity, *FLAVANONES

Abstract

Safflower (Carthamus tinctorius L.) has been recognized for its medicinal value, but there have been limited studies on the glycosyltransferases involved in the biosynthesis of flavonoid glycosides from safflower. In this research, we identified two highly efficient flavonoid O-glycosyltransferases, CtOGT1 and CtOGT2, from safflower performing local BLAST alignment. By constructing a prokaryotic expression vector, we conducted in vitro enzymatic reactions and discovered that these enzymes were capable of catalyzing two-step O-glycosylation using substrates such as kaempferol, quercetin, and eriodictyol. Moreover, they exhibited efficient catalytic activity towards various compounds, including flavones (apigenin, scutellarein), dihydrochalcone (phloretin), isoflavones (genistein, daidzein), flavanones (naringenin, glycyrrhizin), and flavanonols (dihydrokaempferol), leading to the formation of O-glycosides. The broad substrate specificity of these enzymes is noteworthy. This study provides valuable insights into the biosynthetic pathways of flavonoid glycosides in safflower. The discovery of CtOGT1 and CtOGT2 enhances our understanding of the enzymatic processes involved in synthesizing flavonoid glycosides in safflower, contributing to the overall comprehension of secondary metabolite biosynthesis in this plant species. [ABSTRACT FROM AUTHOR]

Published

2024

50. Tuning Almond Lipase Features by Using Different Immobilization Supports.

Author

Cherni, Oumaima, Carballares, Diego, Siar, El Hocine, Abellanas-Perez, Pedro, de Andrades, Diandra, Rocha-Martin, Javier, Bahri, Sellema, and Fernandez-Lafuente, Roberto

Subjects

*LIPASES, *ENZYME stability, *ENZYME specificity, *IMMOBILIZED enzymes, *ALMOND, *ISOMERS

Abstract

The lipase from Prunus dulcis almonds has been immobilized for the first time. For this purpose, two different supports, an octadecyl methacrylate particulate support, and aminated agarose (monoaminoethyl-N-aminoethyl) have been utilized. Both immobilized biocatalysts show improved enzyme stability, but great changes in enzyme specificity were detected. The enzyme immobilized via ion exchange maintained its activity intact versus p-nitrophenyl butyrate, while the enzyme immobilized on the hydrophobic support fully lost its activity versus this substrate, which was confirmed to be due to substrate adsorption on the support. However, this biocatalyst was much more active versus triacetin (more than 10-fold), R- or S- methyl mandelate at pH 7. At pH 9, a strong effect of using phosphate or bicarbonate as reaction buffers was detected. Using bicarbonate, the interfacially immobilized enzyme presented no activity versus R-isomer, but it was very active versus the S-isomer and triacetin. Using a phosphate buffer during the reaction, all compounds were recognized as substrates. The enzyme immobilized via ion exchange was significantly more active using phosphate; in fact, using bicarbonate, the enzyme was inactive versus both methyl mandelate isomers. This paper shows for the first time a great interaction between the effects of the immobilization protocol and buffer used during reaction on the enantiospecificity of lipases. [ABSTRACT FROM AUTHOR]

Published

2024