Probabilistic approach to predicting substrate specificity of methyltransferases.

Probabilistic approach to predicting substrate specificity of methyltransferases.

We present a general probabilistic framework for predicting the substrate specificity of enzymes. We designed this approach to be easily applicable to different organisms and enzymes. Therefore, our predictive models do not rely on species-specific properties and use mostly sequence-derived data. Ma...

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Main Authors: Teresa Szczepińska, Jan Kutner, Michał Kopczyński, Krzysztof Pawłowski, Andrzej Dziembowski, Andrzej Kudlicki, Krzysztof Ginalski, Maga Rowicka
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2014-03-01
Series:PLoS Computational Biology
Online Access:https://www.ncbi.nlm.nih.gov/pmc/articles/pmid/24651469/?tool=EBI
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spelling doaj-ea542f2c61514b8b97d558b23c4cb4782021-04-21T15:41:20ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582014-03-01103e100351410.1371/journal.pcbi.1003514Probabilistic approach to predicting substrate specificity of methyltransferases.Teresa SzczepińskaJan KutnerMichał KopczyńskiKrzysztof PawłowskiAndrzej DziembowskiAndrzej KudlickiKrzysztof GinalskiMaga RowickaWe present a general probabilistic framework for predicting the substrate specificity of enzymes. We designed this approach to be easily applicable to different organisms and enzymes. Therefore, our predictive models do not rely on species-specific properties and use mostly sequence-derived data. Maximum Likelihood optimization is used to fine-tune model parameters and the Akaike Information Criterion is employed to overcome the issue of correlated variables. As a proof-of-principle, we apply our approach to predicting general substrate specificity of yeast methyltransferases (MTases). As input, we use several physico-chemical and biological properties of MTases: structural fold, isoelectric point, expression pattern and cellular localization. Our method accurately predicts whether a yeast MTase methylates a protein, RNA or another molecule. Among our experimentally tested predictions, 89% were confirmed, including the surprising prediction that YOR021C is the first known MTase with a SPOUT fold that methylates a substrate other than RNA (protein). Our approach not only allows for highly accurate prediction of functional specificity of MTases, but also provides insight into general rules governing MTase substrate specificity.https://www.ncbi.nlm.nih.gov/pmc/articles/pmid/24651469/?tool=EBI
collection DOAJ
language English
format Article
sources DOAJ
author Teresa Szczepińska
Jan Kutner
Michał Kopczyński
Krzysztof Pawłowski
Andrzej Dziembowski
Andrzej Kudlicki
Krzysztof Ginalski
Maga Rowicka
spellingShingle Teresa Szczepińska
Jan Kutner
Michał Kopczyński
Krzysztof Pawłowski
Andrzej Dziembowski
Andrzej Kudlicki
Krzysztof Ginalski
Maga Rowicka
Probabilistic approach to predicting substrate specificity of methyltransferases.
PLoS Computational Biology
author_facet Teresa Szczepińska
Jan Kutner
Michał Kopczyński
Krzysztof Pawłowski
Andrzej Dziembowski
Andrzej Kudlicki
Krzysztof Ginalski
Maga Rowicka
author_sort Teresa Szczepińska
title Probabilistic approach to predicting substrate specificity of methyltransferases.
title_short Probabilistic approach to predicting substrate specificity of methyltransferases.
title_full Probabilistic approach to predicting substrate specificity of methyltransferases.
title_fullStr Probabilistic approach to predicting substrate specificity of methyltransferases.
title_full_unstemmed Probabilistic approach to predicting substrate specificity of methyltransferases.
title_sort probabilistic approach to predicting substrate specificity of methyltransferases.
publisher Public Library of Science (PLoS)
series PLoS Computational Biology
issn 1553-734X
1553-7358
publishDate 2014-03-01
description We present a general probabilistic framework for predicting the substrate specificity of enzymes. We designed this approach to be easily applicable to different organisms and enzymes. Therefore, our predictive models do not rely on species-specific properties and use mostly sequence-derived data. Maximum Likelihood optimization is used to fine-tune model parameters and the Akaike Information Criterion is employed to overcome the issue of correlated variables. As a proof-of-principle, we apply our approach to predicting general substrate specificity of yeast methyltransferases (MTases). As input, we use several physico-chemical and biological properties of MTases: structural fold, isoelectric point, expression pattern and cellular localization. Our method accurately predicts whether a yeast MTase methylates a protein, RNA or another molecule. Among our experimentally tested predictions, 89% were confirmed, including the surprising prediction that YOR021C is the first known MTase with a SPOUT fold that methylates a substrate other than RNA (protein). Our approach not only allows for highly accurate prediction of functional specificity of MTases, but also provides insight into general rules governing MTase substrate specificity.
url https://www.ncbi.nlm.nih.gov/pmc/articles/pmid/24651469/?tool=EBI
work_keys_str_mv AT teresaszczepinska probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
AT jankutner probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
AT michałkopczynski probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
AT krzysztofpawłowski probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
AT andrzejdziembowski probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
AT andrzejkudlicki probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
AT krzysztofginalski probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
AT magarowicka probabilisticapproachtopredictingsubstratespecificityofmethyltransferases
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