Superior Proton‐Transfer Catalytic Promiscuity of Cytochrome <i>c</i> in Self‐Organized Media

Rani, Sheetal; Dasgupta, Basundhara; Bhati, Gaurav Kumar; Tomar, Kalpana; Rakshit, Sabyasachi; Maiti, Subhabrata

doi:10.1002/cbic.202000768

Cited by 14 publications

(20 citation statements)

References 82 publications

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“…The substrates 5-nitrobenzisoxazole (NBI) and 2-cyanophenol (CNP) for Kemp elimination were synthesized and characterized as reported in the literature. 41 …”

Section: Methodsmentioning

confidence: 99%

Perpetuating enzymatically induced spatiotemporal pH and catalytic heterogeneity of a hydrogel by nanoparticles

et al. 2022

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“…The substrates 5-nitrobenzisoxazole (NBI) and 2-cyanophenol (CNP) for Kemp elimination were synthesized and characterized as reported in the literature. 41 …”

Section: Methodsmentioning

confidence: 99%

Perpetuating enzymatically induced spatiotemporal pH and catalytic heterogeneity of a hydrogel by nanoparticles

et al. 2022

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“…In certain cases, instead of dampening, macromolecular crowding results in an enhancement in enzymatic activity (for example, glucosidase, phosphoglycerate kinase, etc.). In particular, enzyme activity has an anomalous effect and needs more study on a case-by-case basis. − Unsurprisingly, realizing the crowding effect on the catalytic property of enzymes is a growing area of research because it offers wide-ranging diversity and surprises in terms of the enzymatic property.…”

Section: Introductionmentioning

confidence: 99%

Macromolecular Crowding Effect on the Activity of Liposome-Bound Alkaline Phosphatase: A Paradoxical Inhibitory Action

Deshwal

Maiti

2021

Langmuir

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The cytoplasm of a cell is extremely crowded, with 20–30% being large biomolecules. This crowding enforces a significant amount of the physical and chemical barrier around biomolecules, so understanding any biomolecular event within the cellular system is challenging. Unsurprisingly, enzymes show a diverse kind of catalytic behavior inside a crowded environment and thus have remained an area of active interest in the last few decades. The situation can become even more complex and exciting in the case of understanding the behavior of a membrane-bound enzyme (almost 25–30% of enzymes are membrane-bound) in such a crowded environment that until now has remained unexplored. Herein, we have particularly investigated how a membrane-bound enzyme (using liposome-bound alkaline phosphatase) can behave in a crowded environment comprising polymer molecule-like poly(ethylene glycol) (PEG) of different weights (PEG400, PEG4000, and PEG9000) and Ficoll 400. We have compared the activity using a polymer microbead conjugated enzyme and have found that liposome-bound alkaline phosphatase had much higher activity in crowded environments, showing the importance and superiority of soft-deformable particles (i.e., vesicles) over hard spheres in macro-molecularly crowded media. Interstingly, we have found a paradoxical behavior of inhibitors in terms of both their extent and pathway of inhibitory action. For instance, phosphates, known as competitive inhibitors in buffer, behave as uncompetitive inhibitors in liposome-bound enzymes in crowded media with an ∼5-fold less inhibitory effect, whereas phenyl alanine (an uncompetitive inhibitor in buffer) did not show any inhibitory potential when the enzyme was membrane-bound and in crowded media containing PEG9000 (30 wt %). Overall, this demonstration elucidates aspects of membrane-bound enzymes in crowded media in terms of both catalytic behavior and inhibitory actions and can lead to further studies of the understanding of enzymatic behavior in such complex crowded environments having a dampening effect in regular diffusive transport.

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“…The evolutionarily "elderly" global fold common to nitrous oxide reductases and cytochrome oxidases (subunit II) may be more adaptable due to its long vigil in time and may even accommodate novel -adaptive -catalytic properties [30]. Long coiled segments are characteristic of DNA and RNA binding proteins, including DNA and RNA chaperones [31] and even as oligomerization interfaces.…”

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confidence: 99%

A Hypothesis on How the Azolla Symbiosis Mitigates Nitrous Oxide Based on In Silico Analyses

Gunawardana

Herath

2022

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Nitrous oxide is a long-lived greenhouse gas that exists for 114 years in the atmosphere and is 298-fold more potent than carbon dioxide in its global warming potential. Two recent studies showcased the utility of Azolla plants for a lesser footprint in nitrous oxide production from urea and other supplements to the irrigated ecosystem, which mandates exploration since there is still no clear solution to nitrous oxide in paddy fields or in other ecosystems. Here, we propose a solution based on the evolution of a single cytochrome oxidase subunit II protein (WP_013192178.1) from the cyanobiont Trichormus azollae that we hypothesize to be able to quench nitrous oxide. First, we draw attention to a domain in the candidate protein that is emerging as a sensory periplasmic Y_Y_Y domain that is inferred to bind nitrous oxide. Secondly, we draw the phylogeny of the candidate protein showcasing the poor bootstrap support of its position in the wider clade showcasing its deviation from the core function. Thirdly, we show that the NtcA protein, the apical N-effecting transcription factor, can putatively bind to a promoter sequence of the gene coding for the candidate protein (WP_013192178.1), suggesting a function associated with heterocysts and N-metabolism. Our fourth point involves a string of histidines at the C-terminal extremity of the WP_013192178.1 protein that is missing on all other T. azollae cytochrome oxidase subunit II counterparts, suggesting that such histidines are perhaps involved in forming a Cu center. As the fifth point, we showcase a unique glycine-183 in a lengthy linker region containing multiple glycines that is absent in all proximal Nostocales cyanobacteria, which we predict to be a DNA binding residue. We propose a mechanism of action for the WP_013192178.1 protein based on our in silico analyses. In total, we hypothesize the incomplete and rapid conversion of a likely heterocystous cytochrome oxidase subunit II protein to an emerging nitrous oxide sensing/quenching subunit based on bioinformatics analyses and past literature, which can have repercussions to climate change and consequently, future human life.

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Superior Proton‐Transfer Catalytic Promiscuity of Cytochrome c in Self‐Organized Media

Cited by 14 publications

References 82 publications

Perpetuating enzymatically induced spatiotemporal pH and catalytic heterogeneity of a hydrogel by nanoparticles

Perpetuating enzymatically induced spatiotemporal pH and catalytic heterogeneity of a hydrogel by nanoparticles

Macromolecular Crowding Effect on the Activity of Liposome-Bound Alkaline Phosphatase: A Paradoxical Inhibitory Action

A Hypothesis on How the Azolla Symbiosis Mitigates Nitrous Oxide Based on In Silico Analyses

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