Biocatalysis in Silicon Chemistry

Frampton, Mark B.; Zelisko, Paul M.

doi:10.1002/asia.201700214

Cited by 8 publications

(12 citation statements)

References 121 publications

(279 reference statements)

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“…Even though silicon is the second most abundant element in the Earth's crust, the silicon chemistry of the biological world is very limited. Diatoms, for example, can incorporate ortho ‐silicic acid as stabilizing units in skeletons and materials; this process is usually based on the hydrolysis or alcoholysis of Si−O bonds . Biocatalytic approaches for the formation of silicon polymers and small molecules are so far limited to the formation of Si−OR bonds through condensation reactions .…”

Section: Methodsmentioning

confidence: 99%

“…Diatoms, for example, can incorporate ortho ‐silicic acid as stabilizing units in skeletons and materials; this process is usually based on the hydrolysis or alcoholysis of Si−O bonds . Biocatalytic approaches for the formation of silicon polymers and small molecules are so far limited to the formation of Si−OR bonds through condensation reactions . Although enzymatic manipulations of functional groups in the neighborhood of or remote to the silicon in various organosilicon compounds have been reported, the direct biocatalytic functionalization of silicon centers remained unknown until this group engineered a cytochrome c enzyme in 2016 to catalyze carbene insertion into Si−H bonds in vitro and in vivo .…”

Section: Methodsmentioning

confidence: 99%

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Selective Enzymatic Oxidation of Silanes to Silanols

et al. 2020

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Compared to the biological world's rich chemistry for functionalizing carbon, enzymatic transformations of the heavier homologue silicon are rare. We report that a wild‐type cytochrome P450 monooxygenase (P450BM3 from Bacillus megaterium, CYP102A1) has promiscuous activity for oxidation of hydrosilanes to give silanols. Directed evolution was applied to enhance this non‐native activity and create a highly efficient catalyst for selective silane oxidation under mild conditions with oxygen as the terminal oxidant. The evolved enzyme leaves C−H bonds present in the silane substrates untouched, and this biotransformation does not lead to disiloxane formation, a common problem in silanol syntheses. Computational studies reveal that catalysis proceeds through hydrogen atom abstraction followed by radical rebound, as observed in the native C−H hydroxylation mechanism of the P450 enzyme. This enzymatic silane oxidation extends nature's impressive catalytic repertoire.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Selective Enzymatic Oxidation of Silanes to Silanols

et al. 2020

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“… 39 , 40 Most of these reactions were developed for the enantioselective reduction of silicon compounds and have been summarized in detail in excellent reviews by Frampton and Zelisko. 41 , 42 …”

Section: Biotransformation Of Siliconmentioning

confidence: 99%

Biocatalytic Transformations of Silicon—the Other Group 14 Element

et al. 2021

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Significant inroads have been made using biocatalysts to perform new-to-nature reactions with high selectivity and efficiency. Meanwhile, advances in organosilicon chemistry have led to rich sets of reactions holding great synthetic value. Merging biocatalysis and silicon chemistry could yield new methods for the preparation of valuable organosilicon molecules as well as the degradation and valorization of undesired ones. Despite silicon’s importance in the biosphere for its role in plant and diatom construction, it is not known to be incorporated into any primary or secondary metabolites. Enzymes have been found that act on silicon-containing molecules, but only a few are known to act directly on silicon centers. Protein engineering and evolution has and could continue to enable enzymes to catalyze useful organosilicon transformations, complementing and expanding upon current synthetic methods. The role of silicon in biology and the enzymes that act on silicon-containing molecules are reviewed to set the stage for a discussion of where biocatalysis and organosilicon chemistry may intersect.

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“…To this end, microorganisms capable of producing a variety of precursor molecules have the potential to be expanded in their use to include rare-element analogues which can be further utilized in downstream chemical applications [3] . Such transformations include small molecules containing silicon and halogens, for example, that are suitable for reactions like cross-couplings [23] , electrophilic cleavage [24] , and polymerizations [25] . These efforts involve both protein engineering and synthetic biology along with metabolic engineering to expand the chemical reach of cellular metabolism.…”

Section: Cellular Destinations For Uncommon Elementsmentioning

confidence: 99%

“…Other organisms, including Pichia pijperi , have shown to be more efficient at reducing these and expression of toluene dioxygenase in E. coli results in the dioxygenation of several phenyl silanes [118] . Free enzymes in non-aqueous solvents can perform more complex reactions such as polymerizations and generation of siloxane-phospholipids, but these conditions are not immediately compatible with in vivo use [24] .…”

Section: Selenium and The Metalloidsmentioning

confidence: 99%

Expanding beyond canonical metabolism: Interfacing alternative elements, synthetic biology, and metabolic engineering

Reed

Alper

2018

Synthetic and Systems Biotechnology

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Metabolic engineering offers an exquisite capacity to produce new molecules in a renewable manner. However, most industrial applications have focused on only a small subset of elements from the periodic table, centered around carbon biochemistry. This review aims to illustrate the expanse of chemical elements that can currently (and potentially) be integrated into useful products using cellular systems. Specifically, we describe recent advances in expanding the cellular scope to include the halogens, selenium and the metalloids, and a variety of metal incorporations. These examples range from small molecules, heteroatom-linked uncommon elements, and natural products to biomining and nanotechnology applications. Collectively, this review covers the promise of an expanded range of elemental incorporations and the future impacts it may have on biotechnology.

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Biocatalysis in Silicon Chemistry

Cited by 8 publications

References 121 publications

Selective Enzymatic Oxidation of Silanes to Silanols

Selective Enzymatic Oxidation of Silanes to Silanols

Biocatalytic Transformations of Silicon—the Other Group 14 Element

Expanding beyond canonical metabolism: Interfacing alternative elements, synthetic biology, and metabolic engineering

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