Mark B. Frampton scite author profile

Inspired by Nature, biocatalysis and biotechnology have quickly become burgeoning fields in silicon chemistry. From cell cultures to isolated enzymes researchers are exploring the use of biological systems to affect chemical transformations at or near silicon atoms. This review will examine the history of biotechnology as it pertains to organosilicon compounds (i.e., compounds with one or more Si-C bonds) and provide some insights into future directions for the field.

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Enzyme-mediated sol–gel processing of alkoxysilanes

Frampton

Vawda

Fletcher

et al. 2008

Chem. Commun.

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Synthesis of lipase-catalysed silicone-polyesters and silicone-polyamides at elevated temperatures

Frampton

Zelisko

2013

Chem. Commun.

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More and more enzymes are being explored as alternatives to conventional catalysts in chemical reactions. To utilize these biocatalysts to their fullest, it is incumbent on researchers to gain a complete understanding of the reaction conditions that particular enzymes will tolerate. To this end siloxane-containing polyesters and polyamides have been produced via N435-mediated catalysis at temperatures well above the normal denaturation temperature for free CalB. Low molecular weight disiloxane-based acceptors release the enzyme from its acylated state with equal proficiency while longer chain siloxanes favours polyester synthesis. The thermal tolerance of the enzyme catalyst is increased using longer chain diesters and generally more hydrophobic substrates.

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Chain length selectivity during the polycondensation of siloxane-containing esters and alcohols by immobilized Candida antarctica lipase B

Frampton

Zelisko

2014

Enzyme and Microbial Technology

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The adaptive significance of unproductive alternative splicing in primates

Skandalis

Frampton²,

Seger³

et al. 2010

RNA

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Alternative gene splicing is pervasive in metazoa, particularly in humans, where the majority of genes generate splice variant transcripts. Characterizing the biological significance of alternative transcripts is methodologically difficult since it is impractical to assess thousands of splice variants as to whether they actually encode proteins, whether these proteins are functional, or whether transcripts have a function independent of protein synthesis. Consequently, to elucidate the functional significance of splice variants and to investigate mechanisms underlying the fidelity of mRNA splicing, we used an indirect approach based on analyzing the evolutionary conservation of splice variants among species. Using DNA polymerase b as an indicator locus, we cloned and characterized the types and frequencies of transcripts generated in primary cell lines of five primate species. Overall, we found that in addition to the canonical DNA polymerase b transcript, there were 25 alternative transcripts generated, most containing premature terminating codons. We used a statistical method borrowed from community ecology to show that there is significant diversity and little conservation in alternative splicing patterns among species, despite high sequence similarity in the underlying genomic (exonic) sequences. However, the frequency of alternative splicing at this locus correlates well with life history parameters such as the maximal longevity of each species, indicating that the alternative splicing of unproductive splice variants may have adaptive significance, even if the specific RNA transcripts themselves have no function. These results demonstrate the validity of the phylogenetic conservation approach in elucidating the biological significance of alternative splicing.

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Mark B. Frampton

Organosilicon Biotechnology

Enzyme-mediated sol–gel processing of alkoxysilanes

Synthesis of lipase-catalysed silicone-polyesters and silicone-polyamides at elevated temperatures

Chain length selectivity during the polycondensation of siloxane-containing esters and alcohols by immobilized Candida antarctica lipase B

The adaptive significance of unproductive alternative splicing in primates

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