Your search keyword '"Miyamoto RY"' showing total 6 results

1. Coordinated conformational changes in P450 decarboxylases enable hydrocarbons production from renewable feedstocks.

Author

Generoso WC, Alvarenga AHS, Simões IT, Miyamoto RY, Melo RR, Guilherme EPX, Mandelli F, Santos CA, Prata R, Santos CRD, Colombari FM, Morais MAB, Pimentel Fernandes R, Persinoti GF, Murakami MT, and Zanphorlin LM

Subjects

Crystallography, X-Ray, Decarboxylation, Alkenes metabolism, Alkenes chemistry, Protein Conformation, Biocatalysis, Substrate Specificity, Hydroxylation, Molecular Dynamics Simulation, Carboxy-Lyases metabolism, Carboxy-Lyases chemistry, Carboxy-Lyases genetics, Catalytic Domain, Hydrocarbons metabolism, Hydrocarbons chemistry, Cytochrome P-450 Enzyme System metabolism, Cytochrome P-450 Enzyme System genetics, Cytochrome P-450 Enzyme System chemistry

Abstract

Fatty acid peroxygenases have emerged as promising biocatalysts for hydrocarbon biosynthesis due to their ability to perform C-C scission, producing olefins - key building blocks for sustainable materials and fuels. These enzymes operate through non-canonical and complex mechanisms that yield a bifurcated chemoselectivity between hydroxylation and decarboxylation. In this study, we elucidate structural features in P450 decarboxylases that enable the catalysis of unsaturated substrates, expanding the mechanistic pathways for decarboxylation reaction. Combining X-ray crystallography, molecular dynamics simulations, and machine learning, we have identified intricate molecular rearrangements within the active site that enable the Cβ atom of the substrate to approach the heme iron, thereby promoting oleate decarboxylation. Furthermore, we demonstrate that the absence of the aromatic residue in the Phe-His-Arg triad preserves chemoselectivity for alkenes, providing a distinct perspective on the molecular determinants of decarboxylation activity. Ultimately, these findings enable the sustainable production of biohydrocarbons from industrial feedstocks., Competing Interests: Competing interests: The authors declare no competing interests., (© 2025. The Author(s).)

Published

2025

2. Thermoascus aurantiacus harbors an esterase/lipase that is highly activated by anionic surfactant.

Author

de Melo VS, de Melo RR, Rade LL, Miyamoto RY, Milan N, de Souza CM, de Oliveira VM, Simões IT, de Lima EA, Guilherme EPX, Pinheiro GMS, Inacio Ramos CH, Persinoti GF, Generoso WC, and Zanphorlin LM

Subjects

Sodium Dodecyl Sulfate chemistry, Substrate Specificity, Hydrolysis, Fungal Proteins chemistry, Fungal Proteins metabolism, Anions chemistry, Anions metabolism, Enzyme Stability, Surface-Active Agents chemistry, Surface-Active Agents pharmacology, Lipase metabolism, Lipase chemistry, Esterases metabolism, Esterases chemistry

Abstract

Fungal lipolytic enzymes play crucial roles in various lipid bio-industry processes. Here, we elucidated the biochemical and structural characteristics of an unexplored fungal lipolytic enzyme (TaLip) from Thermoascus aurantiacus var. levisporus, a strain renowned for its significant industrial relevance in carbohydrate-active enzyme production. TaLip belongs to a poorly understood phylogenetic branch within the class 3 lipase family and prefers to hydrolyze mainly short-chain esters. Nonetheless, it also displays activity against natural long-chain triacylglycerols. Furthermore, our analyses revealed that the surfactant sodium dodecyl sulfate (SDS) enhances the hydrolytic activity of TaLip on pNP butyrate by up to 5.0-fold. Biophysical studies suggest that interactions with SDS may prevent TaLip aggregation, thereby preserving the integrity and stability of its monomeric form and improving its performance. These findings highlight the resilience of TaLip as a lipolytic enzyme capable of functioning in tandem with surfactants, offering an intriguing enzymatic model for further exploration of surfactant tolerance and activation in biotechnological applications., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

3. Dimer-assisted mechanism of (un)saturated fatty acid decarboxylation for alkene production.

Author

Rade LL, Generoso WC, Das S, Souza AS, Silveira RL, Avila MC, Vieira PS, Miyamoto RY, Lima ABB, Aricetti JA, de Melo RR, Milan N, Persinoti GF, Bonomi AMFLJ, Murakami MT, Makris TM, and Zanphorlin LM

Subjects

Decarboxylation, Cytochrome P-450 Enzyme System metabolism, Oxidation-Reduction, Fatty Acids metabolism, Alkenes chemistry

Abstract

The enzymatic decarboxylation of fatty acids (FAs) represents an advance toward the development of biological routes to produce drop-in hydrocarbons. The current mechanism for the P450-catalyzed decarboxylation has been largely established from the bacterial cytochrome P450 OleT JE . Herein, we describe OleTP RN , a poly-unsaturated alkene-producing decarboxylase that outrivals the functional properties of the model enzyme and exploits a distinct molecular mechanism for substrate binding and chemoselectivity. In addition to the high conversion rates into alkenes from a broad range of saturated FAs without dependence on high salt concentrations, OleTP RN can also efficiently produce alkenes from unsaturated (oleic and linoleic) acids, the most abundant FAs found in nature. OleTP RN performs carbon-carbon cleavage by a catalytic itinerary that involves hydrogen-atom transfer by the heme-ferryl intermediate Compound I and features a hydrophobic cradle at the distal region of the substrate-binding pocket, not found in OleT JE , which is proposed to play a role in the productive binding of long-chain FAs and favors the rapid release of products from the metabolism of short-chain FAs. Moreover, it is shown that the dimeric configuration of OleTP RN is involved in the stabilization of the A-A' helical motif, a second-coordination sphere of the substrate, which contributes to the proper accommodation of the aliphatic tail in the distal and medial active-site pocket. These findings provide an alternative molecular mechanism for alkene production by P450 peroxygenases, creating new opportunities for biological production of renewable hydrocarbons.

Published

2023

4. Mechanism of high-mannose N-glycan breakdown and metabolism by Bifidobacterium longum.

Author

Cordeiro RL, Santos CR, Domingues MN, Lima TB, Pirolla RAS, Morais MAB, Colombari FM, Miyamoto RY, Persinoti GF, Borges AC, de Farias MA, Stoffel F, Li C, Gozzo FC, van Heel M, Guerin ME, Sundberg EJ, Wang LX, Portugal RV, Giuseppe PO, and Murakami MT

Subjects

Animals, Humans, Cryoelectron Microscopy, Polysaccharides chemistry, Mannosidases metabolism, Glycoside Hydrolases chemistry, Bifidobacterium metabolism, Mammals, Mannose metabolism, Bifidobacterium longum metabolism

Abstract

Bifidobacteria are early colonizers of the human gut and play central roles in human health and metabolism. To thrive in this competitive niche, these bacteria evolved the capacity to use complex carbohydrates, including mammalian N-glycans. Herein, we elucidated pivotal biochemical steps involved in high-mannose N-glycan utilization by Bifidobacterium longum. After N-glycan release by an endo-β-N-acetylglucosaminidase, the mannosyl arms are trimmed by the cooperative action of three functionally distinct glycoside hydrolase 38 (GH38) α-mannosidases and a specific GH125 α-1,6-mannosidase. High-resolution cryo-electron microscopy structures revealed that bifidobacterial GH38 α-mannosidases form homotetramers, with the N-terminal jelly roll domain contributing to substrate selectivity. Additionally, an α-glucosidase enables the processing of monoglucosylated N-glycans. Notably, the main degradation product, mannose, is isomerized into fructose before phosphorylation, an unconventional metabolic route connecting it to the bifid shunt pathway. These findings shed light on key molecular mechanisms used by bifidobacteria to use high-mannose N-glycans, a perennial carbon and energy source in the intestinal lumen., (© 2022. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2023

5. Paradigm shift in xylose isomerase usage: a novel scenario with distinct applications.

Author

Miyamoto RY, de Melo RR, de Mesquita Sampaio IL, de Sousa AS, Morais ER, Sargo CR, and Zanphorlin LM

Subjects

Saccharomyces cerevisiae metabolism, Aldose-Ketose Isomerases chemistry, Aldose-Ketose Isomerases metabolism, Xylose metabolism

Abstract

Isomerases are enzymes that induce physical changes in a molecule without affecting the original molecular formula. Among this class of enzymes, xylose isomerases (XIs) are the most studied to date, partly due to their extensive application in industrial processes to produce high-fructose corn sirups. In recent years, the need for sustainable initiatives has triggered efforts to improve the biobased economy through the use of renewable raw materials. In this context, D-xylose usage is crucial as it is the second-most abundant sugar in nature. The application of XIs in biotransforming xylose, enabling downstream metabolism in several microorganisms, is a smart strategy for ensuring a low-carbon footprint and producing several value-added biochemicals with broad industrial applications such as in the food, cosmetics, pharmaceutical, and polymer industries. Considering recent advancements that have expanded the range of applications of XIs, this review provides a comprehensive and concise overview of XIs, from their primary sources to the biochemical and structural features that influence their mechanisms of action. This comprehensive review may help address the challenges involved in XI applications in different industries and facilitate the exploitation of xylose bioprocesses.

Published

2022

6. Crystal structure of a novel xylose isomerase from Streptomyces sp. F-1 revealed the presence of unique features that differ from conventional classes.

Author

Miyamoto RY, de Sousa AS, Vieira PS, de Melo RR, Scarpassa JA, Ramos CHI, Murakami MT, Ruller R, and Zanphorlin LM

Subjects

Aldose-Ketose Isomerases metabolism, Amino Acid Sequence, Catalytic Domain, Crystallography, X-Ray, Models, Molecular, Protein Conformation, Sequence Alignment, Streptomyces chemistry, Streptomyces metabolism, Substrate Specificity, Aldose-Ketose Isomerases chemistry, Streptomyces enzymology

Abstract

Background: Enzymatic isomerization is a promising strategy to solve the problem of xylose fermentation and, consequently, to leverage the production of advanced biofuels and biochemicals. In a previous work, our research group discovered a new strain of Streptomyces with great biotechnological potential due to its ability to produce a broad arsenal of enzymes related to lignocellulose degradation., Methods: We applied a multidisciplinary approach involving enzyme kinetics, biophysical methods, small angle X-ray scattering and X-ray crystallography to investigate two novel xylose isomerases, XylA1F1 and XylA2F1, from this strain., Results: We showed that while XylA1F1 prefers to act at lower temperatures and relatively lower pH, XylA2F1 is extremely stable at higher temperatures and presents a higher turnover number. Structural analysis revealed that XylA1F1 exhibits unique properties in the active site not observed in classical XylAs from classes I and II nor in its ortholog XylA2F1. It encompasses the natural substitutions, M86A and T93K, that create an extra room for substrate accommodation and narrow the active-site entrance, respectively. Such modifications may contribute to the functional differentiation of these enzymes., Conclusions: We have characterized two novel xylose isomerases that display distinct functional behavior and harbor unprecedented amino-acid substitutions in the catalytic interface., General Significance: Our findings contribute to a better understanding of the functional and structural aspects of xylose isomerases, which might be instrumental for the valorization of the hemicellulosic fraction of vegetal biomass., Competing Interests: Declaration of Competing Interest The authors declare that they have no competing interests., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020