A synthetic RNA-based biosensor for fructose-1,6-bisphosphate that reports glycolytic flux

Ortega, Álvaro Darío; Takhaveev, Vakil; Vedelaar, Silke R.; Long, Yi; Mestre-Farràs, Neus; Incarnato, Danny; Ersoy, Franziska; Olsen, Lars Folke; Mayer, Günter; Heinemann, Matthias

doi:10.1016/j.chembiol.2021.04.006

Cited by 21 publications

(34 citation statements)

References 64 publications

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“…In many fermentation processes, end products are synthesized starting from sugars (Francois et al, 2020;Maicas, 2020;Sharma et al, 2020). GlyRNA (Glycolytic RNA probe) was selected as an aptameric sensor for glycolytic flux, because degradation of its mRNA is sensible to the intracellular concentration of fructosebisphosphate (Ortega et al, 2021). Given that the sensor's response decreases with an increasing concentration of fructosebisphosphate, a negative peak denotes maximum glycolytic flux.…”

Section: Five Biosensors Are Selected To Monitor the Yeast Intracellular Status During Stressmentioning

confidence: 99%

Real-Time Monitoring of the Yeast Intracellular State During Bioprocesses With a Toolbox of Biosensors

2022

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Industrial fermentation processes strive for high robustness to ensure optimal and consistent performance. Medium components, fermentation products, and physical perturbations may cause stress and lower performance. Cellular stress elicits a range of responses, whose extracellular manifestations have been extensively studied; whereas intracellular aspects remain poorly known due to lack of tools for real-time monitoring. Genetically encoded biosensors have emerged as promising tools and have been used to improve microbial productivity and tolerance toward industrially relevant stresses. Here, fluorescent biosensors able to sense the yeast intracellular environment (pH, ATP levels, oxidative stress, glycolytic flux, and ribosome production) were implemented into a versatile and easy-to-use toolbox. Marker-free and efficient genome integration at a conserved site on chromosome X of Saccharomyces cerevisiae strains and a commercial Saccharomyces boulardii strain was developed. Moreover, multiple biosensors were used to simultaneously monitor different intracellular parameters in a single cell. Even when combined together, the biosensors did not significantly affect key physiological parameters, such as specific growth rate and product yields. Activation and response of each biosensor and their interconnection were assessed using an advanced micro-cultivation system. Finally, the toolbox was used to screen cell behavior in a synthetic lignocellulosic hydrolysate that mimicked harsh industrial substrates, revealing differences in the oxidative stress response between laboratory (CEN.PK113-7D) and industrial (Ethanol Red) S. cerevisiae strains. In summary, the toolbox will allow both the exploration of yeast diversity and physiological responses in natural and complex industrial conditions, as well as the possibility to monitor production processes.

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Section: Five Biosensors Are Selected To Monitor the Yeast Intracellular Status During Stressmentioning

confidence: 99%

Real-Time Monitoring of the Yeast Intracellular State During Bioprocesses With a Toolbox of Biosensors

2022

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“…Proximity labeling with intact and split promiscuous biotin ligase (BirA) promise to uncover new tethering factors and metabolite transporters that selectively operate at MCSs [ 168 , 169 ]. Technologies such as in situ mass spectrometry imaging, isotopic labelling and fluorescent or genetically encoded RNA-based metabolite sensors will help reveal the flux of polar metabolites between different organelles [ [170] , [171] , [172] ]. Combined with functional genomics, in vitro reconstitution, and organelle-specific proteomics in different cells and tissues [ 173 , 174 ], these in situ labeling techniques may lead to the discovery of new pathways, or branches of known pathways, that ensure coordination of organelle function across a range of physiological states.…”

Section: Discussionmentioning

confidence: 99%

Organelle transporters and inter-organelle communication as drivers of metabolic regulation and cellular homeostasis

Jain

Zoncu

2022

Molecular Metabolism

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“…After having established that the RBM log-likelihoods and the fitnesses of the aptamers in our dataset are strongly interrelated, we now use the RBM model to generate new sequences in silico (see Methods Sec Restricted Boltzmann Machine: Definition, training, sampling). Note that the number of available sequences at any round, <10 6 , is much smaller than the number of possible sequences over 20 nucleotides, 4 20 ' 10 12 . Hence, it is a non trivial problem to (where w μi is the weight of the connection between hidden unit μ and visible unit i for nucleotide s i ) to the corresponding hidden units for the sequences s in the dataset (gray) and average activity (black).…”

Section: Rbm Trained From Unique Sequences Generate Diverse Aptamers ...mentioning

confidence: 99%

“…Multiple different experimental approaches exist to select specific molecular target binder such as antibodies, short peptides, proteins or small molecules. Single stranded oligonucleotides (DNA or RNA) have also been shown to be able to specifically bind with high affinity to a plethora of various targets, including small metabolites, proteins, nucleic acids, viruses, exosomes, and cells of specific tissue [1][2][3][4][5][6][7][8][9][10], showing promise for applications that range from diagnostics to targeted disease therapy [11]. These short oligonucleotides, called aptamers, are selected from an initial pool of sequences by a procedure known as Systematic Evolution of Ligands by Exponential Enrichment (SELEX) [12,13].…”

Section: Introductionmentioning

confidence: 99%

Generative and interpretable machine learning for aptamer design and analysis of in vitro sequence selection

et al. 2022

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Selection protocols such as SELEX, where molecules are selected over multiple rounds for their ability to bind to a target of interest, are popular methods for obtaining binders for diagnostic and therapeutic purposes. We show that Restricted Boltzmann Machines (RBMs), an unsupervised two-layer neural network architecture, can successfully be trained on sequence ensembles from single rounds of SELEX experiments for thrombin aptamers. RBMs assign scores to sequences that can be directly related to their fitnesses estimated through experimental enrichment ratios. Hence, RBMs trained from sequence data at a given round can be used to predict the effects of selection at later rounds. Moreover, the parameters of the trained RBMs are interpretable and identify functional features contributing most to sequence fitness. To exploit the generative capabilities of RBMs, we introduce two different training protocols: one taking into account sequence counts, capable of identifying the few best binders, and another based on unique sequences only, generating more diverse binders. We then use RBMs model to generate novel aptamers with putative disruptive mutations or good binding properties, and validate the generated sequences with gel shift assay experiments. Finally, we compare the RBM’s performance with different supervised learning approaches that include random forests and several deep neural network architectures.

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A synthetic RNA-based biosensor for fructose-1,6-bisphosphate that reports glycolytic flux

Cited by 21 publications

References 64 publications

Real-Time Monitoring of the Yeast Intracellular State During Bioprocesses With a Toolbox of Biosensors

Real-Time Monitoring of the Yeast Intracellular State During Bioprocesses With a Toolbox of Biosensors

Organelle transporters and inter-organelle communication as drivers of metabolic regulation and cellular homeostasis

Generative and interpretable machine learning for aptamer design and analysis of in vitro sequence selection

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