Transcriptomic and fluxomic changes in Streptomyces lividans producing heterologous protein

Wouter Daniels,Tobias Busche,Anastassios Economou,Jeroen Bouvin,Lieve Van Mellaert,Kristel Bernaerts,Christian Rückert,Ólafur H Friðjónsson,Bart Nicolai,Spyridoula Karamanou,Kenneth Simoens,Jörn Kalinowski,Jozef Anné

doi:10.1186/s12934-018-1040-6

Wouter Daniels, Tobias Busche + Show 11 more

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https://doi.org/10.1186/s12934-018-1040-6

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Abstract

BackgroundThe Gram-positive Streptomyces lividans TK24 is an attractive host for heterologous protein production because of its high capability to secrete proteins—which favors correct folding and facilitates downstream processing—as well as its acceptance of methylated DNA and its low endogeneous protease activity. However, current inconsistencies in protein yields urge for a deeper understanding of the burden of heterologous protein production on the cell. In the current study, transcriptomics and ^{13}hbox {C}-based fluxomics were exploited to uncover gene expression and metabolic flux changes associated with heterologous protein production. The Rhodothermus marinus thermostable cellulase A (CelA)—previously shown to be successfully overexpressed in S. lividans—was taken as an example protein.ResultsRNA-seq and ^{13}hbox {C}-based metabolic flux analysis were performed on a CelA-producing and an empty-plasmid strain under the same conditions. Differential gene expression, followed by cluster analysis based on co-expression and co-localization, identified transcriptomic responses related to secretion-induced stress and DNA damage. Furthermore, the OsdR regulon (previously associated with hypoxia, oxidative stress, intercellular signaling, and morphological development) was consistently upregulated in the CelA-producing strain and exhibited co-expression with isoenzymes from the pentose phosphate pathway linked to secondary metabolism. Increased expression of these isoenzymes matches to increased fluxes in the pentose phosphate pathway. Additionally, flux maps of the central carbon metabolism show increased flux through the tricarboxylic acid cycle in the CelA-producing strain. Redirection of fluxes in the CelA-producing strain leads to higher production of NADPH, which can only partly be attributed to increased secretion.ConclusionsTranscriptomic and fluxomic changes uncover potential new leads for targeted strain improvement strategies which may ease the secretion stress and metabolic burden associated with heterologous protein synthesis and secretion, and may help create a more consistently performing S. lividans strain. Yet, links to secondary metabolism and redox balancing should be further investigated to fully understand the S. lividans metabolome under heterologous protein production.

Highlights

The Gram-positive Streptomyces lividans TK24 is an attractive host for heterologous protein production because of its high capability to secrete proteins—which favors correct folding and facilitates downstream processing—as well as its acceptance of methylated DNA and its low endogeneous protease activity
Differential gene expression and cluster analysis Differential expression analysis was performed on RNAseq data of S. lividans TK24 carrying either pIJ486 or pIJ486-vsi-celA (CelA-producing strain) in the exponential growth phase in a minimal medium with glucose
We set out to determine the changes in gene expression and central carbon fluxes resulting from heterologous production and secretion of thermostable cellulase cellulase A (CelA) in S. lividans through RNA-seq and 13C-MFA on a both a strain containing pIJ486-vsi-CelA and a reference strain containing empty pIJ486

Summary

Introduction

The Gram-positive Streptomyces lividans TK24 is an attractive host for heterologous protein production because of its high capability to secrete proteins—which favors correct folding and facilitates downstream processing—as well as its acceptance of methylated DNA and its low endogeneous protease activity. The OsdR regulon (previously associated with hypoxia, oxidative stress, intercellular signaling, and morphological development) was consistently upregulated in the CelA-producing strain and exhibited co-expression with isoenzymes from the pentose phosphate pathway linked to secondary metabolism Increased expression of these isoenzymes matches to increased fluxes in the pentose phosphate pathway. Additional increases in protein production might be obtained by finding genetic targets based on a thorough understanding of the metabolic burden caused by recombinant protein production The presence of such metabolic effects that can be exploited was shown by metabolomics studies on a S. lividans strain producing murine Tumour Necrosis Factor-α, and that showed profound changes in its metabolic fingerprint [8], as well as in the activation of overflow metabolism [8, 9]

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