Discovery of Toxin-Degrading Enzymes with Positive Unlabeled Deep Learning

Zhang, Dachuan; Xing, Huadong; Liu, Dongliang; Han, Mengying; Cai, Pengli; Lin, Huikang; Tian, Yu; Guo, Yinghao; Sun, Bin; Le, Yingying; Tian, Ye; Wu, Aibo; Hu, Qian-Nan

doi:10.1021/acscatal.3c04461

Cited by 7 publications

(4 citation statements)

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“…However, it could not provide clear insights on, for example, PCF-intensive substructures and raw materials to guide the design of more sustainable molecules and processes. The attention mechanism has been used to identify important features that affect the activity of molecules, enzymes, and reactions. , FineChem 2 employs the attention mechanism to capture the contributions of substructures in a chemical to its PCF, thereby promoting learned knowledge and improving the model interpretability.…”

Section: Resultsmentioning

confidence: 99%

“…The attention mechanism has been used to identify important features that affect the activity of molecules, enzymes, and reactions. 22 , 49 FineChem 2 employs the attention mechanism to capture the contributions of substructures in a chemical to its PCF, thereby promoting learned knowledge and improving the model interpretability.…”

Section: Resultsmentioning

confidence: 99%

“…The contamination of proxy data is transmitted to these pre-LCA tools, compromising their performance. Furthermore, while ML has been successfully applied in many fields, interpretability remains challenging for ML-based models. , Previous tools used Shapley additive explanations (SHAP) to identify the critical molecular descriptors that are relevant to PCFs. However, the detailed correlations between PCFs and functional groups and substructures cannot be distinctly quantified, which limits their application in the design of more sustainable molecules.…”

Section: Introductionmentioning

confidence: 99%

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Enhanced Deep-Learning Model for Carbon Footprints of Chemicals

Zhang,

Wang,

Oberschelp

et al. 2024

ACS Sustainable Chem. Eng.

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Millions of chemicals have been designed; however, their product carbon footprints (PCFs) are largely unknown, leaving questions about their sustainability. This general lack of PCF data is because the data needed for comprehensive environmental analyses are typically not available in the early molecular design stages. Several predictive tools have been developed to estimate the PCF of chemicals, which are applicable to only a narrow range of common chemicals and have limited predictive ability. Here, we propose FineChem 2, which is based on a novel transformer framework and first-hand industry data, for accurately predicting the PCF of chemicals. Compared to previous tools, FineChem 2 demonstrates significantly better predictive power, and its applicability domains are improved by ∼75% on a diverse set of chemicals on the global market, including the high-productionvolume chemicals identified by regulators, daily chemicals, and chemical additives in food and plastics. In addition, through better interpretability from the attention mechanism, FineChem 2 may successfully identify PCF-intensive substructures and critical raw materials of chemicals, providing insights into the design of more sustainable molecules and processes. Therefore, we highlight FineChem 2 for estimating the PCF of chemicals, contributing to advancements in the sustainable transition of the global chemical industry.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Enhanced Deep-Learning Model for Carbon Footprints of Chemicals

Zhang,

Wang,

Oberschelp

et al. 2024

ACS Sustainable Chem. Eng.

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“…They elaborate on leveraging computational biology for searching genomic databases to identify candidate organisms with potential mycotoxin detoxification capabilities, which can be further enhanced via synthetic biology techniques to optimize the expression and activity of these enzymes. For instance, Zhang et al [ 241 ] utilized a positive unlabeled deep learning approach to identify new enzymes capable of degrading mycotoxins such as OTA, demonstrating the potential of machine learning to predict enzyme-substrate specificity in complex substrates traditionally challenging for experimental approaches. This method, leveraging data from extensive biochemical databases, underscores a shift towards rapid, high-throughput screening methods that could revolutionize the discovery of biodegrading enzymes in synthetic biology frameworks.…”

Section: Methods For Avoiding or Mitigating The Presence Of Mycotoxin...mentioning

confidence: 99%

Comprehensive Review of Aflatoxin and Ochratoxin A Dynamics: Emergence, Toxicological Impact, and Advanced Control Strategies

Nazareth,

Soriano Pérez,

Luz

et al. 2024

Foods

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Filamentous fungi exhibit remarkable adaptability to diverse substrates and can synthesize a plethora of secondary metabolites. These metabolites, produced in response to environmental stimuli, not only confer selective advantages but also encompass potentially deleterious mycotoxins. Mycotoxins, exemplified by those originating from Alternaria, Aspergillus, Penicillium, and Fusarium species, represent challenging hazards to both human and animal health, thus warranting stringent regulatory control. Despite regulatory frameworks, mycotoxin contamination remains a pressing global challenge, particularly within cereal-based matrices and their derived by-products, integral components of animal diets. Strategies aimed at mitigating mycotoxin contamination encompass multifaceted approaches, including biological control modalities, detoxification procedures, and innovative interventions like essential oils. However, hurdles persist, underscoring the imperative for innovative interventions. This review elucidated the prevalence, health ramifications, regulatory paradigms, and evolving preventive strategies about two prominent mycotoxins, aflatoxins and ochratoxin A. Furthermore, it explored the emergence of new fungal species, and biocontrol methods using lactic acid bacteria and essential mustard oil, emphasizing their efficacy in mitigating fungal spoilage and mycotoxin production. Through an integrative examination of these facets, this review endeavored to furnish a comprehensive understanding of the multifaceted challenges posed by mycotoxin contamination and the emergent strategies poised to ameliorate its impact on food and feed safety.

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