Integration of metabolism and regulation reveals rapid adaptability to growth on non-native substrates

Trivedi, Vikas D.; Sullivan, Sean F.; Choudhury, Deepankar; Gopinarayanan, Venkatesh Endalur; Hart, Taylor; Nair, Nikhil U.

doi:10.1101/2022.05.21.492926

Cited by 3 publications

(11 citation statements)

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“…While all three approaches reached similar nal cell concentrations on each of the three substrates, the ∆GAL80 condition took roughly twice the time to do so compared with Gal3p Syn4.1 and Gal3p MC (>30 h vs. ~18 h) suggesting that de-regulation of the regulon results in reduced tness relative to strains in which the native regulatory organization is maintained. As sucrose and glucose are both capable of exerting repression on the GAL regulon 19 , subculturing all three strains from these two native substrates into complex (YP) media containing the non-native substrate xylose should therefore result in growth-coupled expression of xylose catabolic genes and rapid growth. Upon subculturing from sucrose, we observed that all three approaches enabled growth.…”

Section: Resultsmentioning

confidence: 99%

“…By placing heterologous genes for either xylose or arabinose catabolism under the control of GAL-responsive (Leloir pathway) promoters, the GAL regulon could be adapted for growth on these non-native substrates. Upon comparing this regulon-coordinated (REG) approach to growth with simple constitutive overexpression of the same catabolic genes, which we term a constitutive (CONS) approach, we found that our semi-synthetic regulon yielded superior growth rates on both xylose (µ = 0.24 h -1 vs. 0.11 h -1 ) and arabinose (µ = 0.27 h -1 vs. 0.06 h -1 ), respectively with minimal metabolic engineering 19 .…”

Section: Introductionmentioning

confidence: 99%

“…Once freed from repression, Gal4p -the master activator of the GAL regulon -binds to its cognate Upstream Activating Sequences (UAS) to directly induce transcription of galactose catabolic genes (Leloir pathway) and indirectly modulates the transcript and/or protein abundance of numerous growth-associated genes (Figure 1A) 16,17 . We previously reported the construction of a variant of sensor protein Gal3p (Gal3p Syn4.1 ) that strongly activates the GAL regulon by the pentose sugars xylose and arabinose 18,19 . By placing heterologous genes for either xylose or arabinose catabolism under the control of GAL-responsive (Leloir pathway) promoters, the GAL regulon could be adapted for growth on these non-native substrates.…”

Section: Introductionmentioning

confidence: 99%

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Towards universal synthetic heterotrophy using a metabolic coordinator

Sullivan

Shetty²,

Bharadwaj³

et al. 2022

Preprint

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Engineering the utilization of non-native substrates, or synthetic heterotrophy, in proven industrial microbes such as Saccharomyces cerevisiae represents an opportunity to valorize plentiful and renewable sources of carbon and energy as potential inputs to biotechnological processes. We previously demonstrated that activation of the galactose (GAL) regulon, a regulatory structure used by this yeast to coordinate substrate utilization with biomass formation during growth on galactose, during growth on the non-native substrate xylose results in a vastly altered gene expression profile and faster growth compared with constitutive overexpression of the same heterologous catabolic pathway. However, this effort involved the creation of a xylose-inducible variant of Gal3p (Gal3pSyn4.1), the sensor protein of the GAL regulon, preventing this semi-synthetic regulon approach from being easily adapted to additional non-native substrates. Here, we report the construction of a variant Gal3pMC (metabolic coordinator) that exhibits robust GAL regulon activation in the presence of structurally diverse substrates and recapitulates the dynamics of the native system. Multiple molecular modeling studies confirm that Gal3pMC occupies conformational states corresponding to galactose-bound Gal3p in an inducer-independent manner. Using Gal3pMC to test a regulon approach to the assimilation of the non-native lignocellulosic sugars xylose, arabinose, and cellobiose yields higher growth rates and final cell densities when compared with a constitutive overexpression of the same set of catabolic genes. The subsequent demonstration of rapid and complete co-utilization of all three non-native substrates suggests that Gal3pMC-mediated dynamic global gene expression changes by GAL regulon activation may be universally beneficial for engineering synthetic heterotrophy.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Towards universal synthetic heterotrophy using a metabolic coordinator

Sullivan

Shetty²,

Bharadwaj³

et al. 2022

Preprint

Self Cite

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“…A similar range of growth rates was observed for the xylose constructs (0.20 − 0.21 h -1 ) but the substantially reduced final cell density of two of the arrangements (ϕ-XK-XI and XK-ϕ-XI) indicates that there can be fitness consequences to expression imbalances. As no clearly superior combination could be identified to the initial arabinose and xylose designs, we decided to re-test a Consolidated approach to co-utilization on 1 % of each substrate (Figure 6E) using designs (ABD for arabinose, XI-ϕ-XK for xylose) identified as optimal in a related investigation by our lab into efficient pentose assimilation 19 .…”

Section: Gal3p MC Enables Rapid and Complete Co-utilization Of Multip...mentioning

confidence: 99%

“…Upon comparing this regulon-coordinated (REG) approach to growth with simple constitutive overexpression of the same catabolic genes, which we term a constitutive (CONS) approach, we found that our semi-synthetic regulon yielded superior growth rates on both xylose (µ = 0.24 h -1 vs. 0.11 h -1 ) and arabinose (µ = 0.27 h -1 vs. 0.06 h -1 ), respectively with minimal metabolic engineering 19 . Significantly, a transcriptomic comparison showed relative upregulation of genes associated with cell division and mitochondrial biogenesis in the REG strain while the CONS strain showed upregulation of stress response and starvation-associated genes 18 .…”

Section: Introductionmentioning

confidence: 99%

Towards universal synthetic heterotrophy using a metabolic coordinator

Sullivan

Shetty²,

Bharadwaj³

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

Engineering the utilization of non-native substrates, or synthetic heterotrophy, in proven industrial microbes such asSaccharomyces cerevisiaerepresents an opportunity to valorize plentiful and renewable sources of carbon and energy as potential inputs to biotechnological processes. We previously demonstrated that activation of the galactose (GAL) regulon, a regulatory structure used by this yeast to coordinate substrate utilization with biomass formation during growth on galactose, during growth on the non-native substrate xylose results in a vastly altered gene expression profile and faster growth compared with constitutive overexpression of the same heterologous catabolic pathway. However, this effort involved the creation of a xylose-inducible variant of Gal3p (Gal3pSyn4.1), the sensor protein of the GAL regulon, preventing this semi-synthetic regulon approach from being easily adapted to additional non-native substrates. Here, we report the construction of a variant Gal3pMC(metabolic coordinator) that exhibits robust GAL regulon activation in the presence of structurally diverse substrates and recapitulates the dynamics of the native system. Multiple molecular modeling studies confirm that Gal3pMCoccupies conformational states corresponding to galactose-bound Gal3p in an inducer-independent manner. Using Gal3pMCto test a regulon approach to the assimilation of the non-native lignocellulosic sugars xylose, arabinose, and cellobiose yields higher growth rates and final cell densities when compared with a constitutive overexpression of the same set of catabolic genes. The subsequent demonstration of rapid and complete co-utilization of all three non-native substrates suggests that Gal3pMC-mediated dynamic global gene expression changes by GAL regulon activation may be universally beneficial for engineering synthetic heterotrophy.

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