Aromatic catabolic pathway selection for optimal production of pyruvate and lactate from lignin.

Lignin represents an untapped feedstock for the production of fuels and chemicals, but its intrinsic heterogeneity makes lignin valorization a significant challenge. In nature, many aerobic organisms degrade lignin-derived aromatic molecules through conserved central intermediates including catechol and protocatechuate. Harnessing this microbial approach offers potential for lignin upgrading in modern biorefineries, but significant technical development is needed to achieve this end. Catechol and protocatechuate are subjected to aromatic ring cleavage by dioxygenase enzymes that, depending on the position, ortho or meta relative to adjacent hydroxyl groups, result in different products that are metabolized through parallel pathways for entry into the TCA cycle. These degradation pathways differ in the combination of succinate, acetyl-CoA, and pyruvate produced, the reducing equivalents regenerated, and the amount of carbon emitted as CO2-factors that will ultimately impact the yield of the targeted product. As shown here, the ring-cleavage pathways can be interchanged with one another, and such substitutions have a predictable and substantial impact on product yield. We demonstrate that replacement of the catechol ortho degradation pathway endogenous to Pseudomonas putida KT2440 with an exogenous meta-cleavage pathway from P. putida mt-2 increases yields of pyruvate produced from aromatic molecules in engineered strains. Even more dramatically, replacing the endogenous protocatechuate ortho pathway with a meta-cleavage pathway from Sphingobium sp. SYK-6 results in a nearly five-fold increase in pyruvate production. We further demonstrate the aerobic conversion of pyruvate to l-lactate with a yield of 41.1 ± 2.6% (wt/wt). Overall, this study illustrates how aromatic degradation pathways can be tuned to optimize the yield of a desired product in biological lignin upgrading.

[1]  M. A. Eiteman,et al.  Aerobic production of alanine by Escherichia coli aceF ldhA mutants expressing the Bacillus sphaericus alaD gene , 2004, Applied Microbiology and Biotechnology.

[2]  Matthias S. Müller,et al.  The Emerging Role of , 2004 .

[3]  L. N. Ornston,et al.  The Conversion of Catechol and Protocatechuate to β-Ketoadipate by Pseudomonas putida I. BIOCHEMISTRY , 1966 .

[4]  C. Vamsee-Krishna,et al.  Metabolic diversity in bacterial degradation of aromatic compounds. , 2007, Omics : a journal of integrative biology.

[5]  Shigeaki Harayama,et al.  The meta cleavage operon of TOL degradative plasmid pWWO comprises 13 genes , 1990, Molecular and General Genetics MGG.

[6]  M. Yamasaki,et al.  Molecular cloning of the protocatechuate 4,5-dioxygenase genes of Pseudomonas paucimobilis , 1990, Journal of bacteriology.

[7]  N. Kamimura,et al.  The Protocatechuate 4,5-Cleavage Pathway: Overview and New Findings , 2014 .

[8]  M. Mishra,et al.  Biodegradation of Lignocellulosic Waste in the Environment , 2015 .

[9]  V. Lorenzo,et al.  Biotechnological domestication of pseudomonads using synthetic biology , 2014, Nature Reviews Microbiology.

[10]  김인호,et al.  Pseudomonas putida , 2002 .

[11]  Qipeng Yuan,et al.  Extending shikimate pathway for the production of muconic acid and its precursor salicylic acid in Escherichia coli. , 2014, Metabolic engineering.

[12]  Eduardo Díaz,et al.  Genomic analysis of the aromatic catabolic pathways from Pseudomonas putida KT2440. , 2002, Environmental microbiology.

[13]  Steven J. Steindel,et al.  4 Lactate Dehydrogenase , 1975 .

[14]  C. Marx Development of a broad-host-range sacB-based vector for unmarked allelic exchange , 2008, BMC Research Notes.

[15]  J. Puchalka,et al.  Generation of a catR deficient mutant of P. putida KT2440 that produces cis, cis-muconate from benzoate at high rate and yield. , 2011, Journal of biotechnology.

[16]  Gerald A. Tuskan,et al.  Lignin Valorization: Improving Lignin Processing in the Biorefinery , 2014, Science.

[17]  D. Gibson,et al.  THE BACTERIAL DEGRADATION OF CATECHOL. , 1965, The Biochemical journal.

[18]  Kelvin H. Lee,et al.  Genomic analysis. , 2000, Current opinion in biotechnology.

[19]  G. Hegeman,et al.  Regulation of the meta Cleavage Pathway for Benzoate Oxidation by Pseudomonas putida , 1969, Journal of bacteriology.

[20]  Michael Sauer,et al.  Lactate production yield from engineered yeasts is dependent from the host background, the lactate dehydrogenase source and the lactate export , 2006, Microbial cell factories.

[21]  L. Alberghina,et al.  Development of Metabolically Engineered Saccharomyces cerevisiae Cells for the Production of Lactic Acid , 1995, Biotechnology progress.

[22]  Christopher M Thomas,et al.  Complete sequence of the IncP-9 TOL plasmid pWW0 from Pseudomonas putida. , 2002, Environmental microbiology.

[23]  Caroline S. Harwood,et al.  THE β-KETOADIPATE PATHWAY AND THE BIOLOGY OF SELF-IDENTITY , 1996 .

[24]  M. A. Eiteman,et al.  The effect of acetate pathway mutations on the production of pyruvate in Escherichia coli , 2003, Applied Microbiology and Biotechnology.

[25]  Eric C. D. Tan,et al.  Process Design and Economics for the Conversion of Lignocellulosic Biomass to Hydrocarbons: Dilute-Acid and Enzymatic Deconstruction of Biomass to Sugars and Biological Conversion of Sugars to Hydrocarbons , 2013 .

[26]  Todd J. Clark,et al.  Mutations in catB, the Gene Encoding Muconate Cycloisomerase, Activate Transcription of the Distalben Genes and Contribute to a Complex Regulatory Circuit in Acinetobacter sp. Strain ADP1 , 2000, Journal of bacteriology.

[27]  G. Hegeman,et al.  Phenol and Benzoate Metabolism by Pseudomonas putida: Regulation of Tangential Pathways , 1969, Journal of bacteriology.

[28]  H. Hara,et al.  Characterization of the 4-Carboxy-4-Hydroxy-2-Oxoadipate Aldolase Gene and Operon Structure of the Protocatechuate 4,5-Cleavage Pathway Genes in Sphingomonas paucimobilis SYK-6 , 2003, Journal of bacteriology.

[29]  L. N. Ornston,et al.  The conversion of catechol and protocatechuate to beta-ketoadipate by Pseudomonas putida. 3. Enzymes of the catechol pathway. , 1966, The Journal of biological chemistry.

[30]  L. N. Ornston,et al.  The conversion of catechol and protocatechuate to beta-ketoadipate by Pseudomonas putida. , 1966, The Journal of biological chemistry.

[31]  M. A. Prieto,et al.  The polyhydroxyalkanoate metabolism controls carbon and energy spillage in Pseudomonas putida. , 2012, Environmental microbiology.

[32]  G. Hegeman Synthesis of the Enzymes of the Mandelate Pathway by Pseudomonas putida II. Isolation and Properties of Blocked Mutants , 1966, Journal of bacteriology.

[33]  Christoph Wittmann,et al.  In-silico-driven metabolic engineering of Pseudomonas putida for enhanced production of poly-hydroxyalkanoates. , 2013, Metabolic engineering.

[34]  Todd J. Clark,et al.  Benzoate Decreases the Binding of cis,cis-Muconate to the BenM Regulator despite the Synergistic Effect of Both Compounds on Transcriptional Activation , 2004, Journal of bacteriology.

[35]  D. Gibson Microbial degradation of aromatic compounds. , 1967, Science.

[36]  C. Weber,et al.  Biosynthesis of cis,cis-Muconic Acid and Its Aromatic Precursors, Catechol and Protocatechuic Acid, from Renewable Feedstocks by Saccharomyces cerevisiae , 2012, Applied and Environmental Microbiology.

[37]  D. Pieper,et al.  Aerobic Degradation of Aromatic Hydrocarbons , 2016 .

[38]  R. Crawford Novel pathway for degradation of protocatechuic acid in Bacillus species , 1975, Journal of bacteriology.

[39]  L. N. Ornston,et al.  The beta-ketoadipate pathway. , 1973, Advances in microbial physiology.

[40]  D. W. Ribbons,et al.  New Pathways in the Oxidative Metabolism of Aromatic Compounds by Micro-Organisms , 1960, Nature.

[41]  K. Timmis Handbook of hydrocarbon and lipid microbiology , 2010 .

[42]  S. Lee,et al.  Metabolic engineering of Escherichia coli for the production of l-valine based on transcriptome analysis and in silico gene knockout simulation , 2007, Proceedings of the National Academy of Sciences.

[43]  E I Garvie,et al.  Bacterial lactate dehydrogenases. , 1980, Microbiological reviews.

[44]  U. Sauer,et al.  Convergent Peripheral Pathways Catalyze Initial Glucose Catabolism in Pseudomonas putida: Genomic and Flux Analysis , 2007, Journal of bacteriology.

[45]  Mo Xian,et al.  Biosynthesis of isoprene in Escherichia coli via methylerythritol phosphate (MEP) pathway , 2011, Applied Microbiology and Biotechnology.

[46]  T. Ohta,et al.  D-lactate dehydrogenase is a member of the D-isomer-specific 2-hydroxyacid dehydrogenase family. Cloning, sequencing, and expression in Escherichia coli of the D-lactate dehydrogenase gene of Lactobacillus plantarum. , 1991, The Journal of biological chemistry.

[47]  D. Clark,et al.  Regulation of the ldhA gene, encoding the fermentative lactate dehydrogenase of Escherichia coli. , 2001, Microbiology.

[48]  K. Timmis,et al.  Pedigree and taxonomic credentials of Pseudomonas putida strain KT2440. , 2002, Environmental microbiology.

[49]  Gregg T. Beckham,et al.  Adipic acid production from lignin , 2015 .

[50]  J. Larner,et al.  Isolation and characterization of bovine lactate dehydrogenase X. , 1970, Biochemistry.

[51]  Christopher D. Reeves,et al.  Microbial production of isoprenoids , 2011 .

[52]  P. Williams,et al.  The evolution of pathways for aromatic hydrocarbon oxidation inPseudomonas , 1994, Biodegradation.

[53]  J. Buer,et al.  Long-Term Anaerobic Survival of the Opportunistic Pathogen Pseudomonas aeruginosa via Pyruvate Fermentation , 2004, Journal of bacteriology.

[54]  V. M. D. Martins dos Santos,et al.  pH‐stat fed‐batch process to enhance the production of cis, cis‐muconate from benzoate by Pseudomonas putida KT2440‐JD1 , 2012, Biotechnology progress.

[55]  R. Lurz,et al.  Activity of the hybrid trp-lac (tac) promoter of Escherichia coli in Pseudomonas putida. Construction of broad-host-range, controlled-expression vectors. , 1983, Gene.

[56]  Bruce E Dale,et al.  Deconstruction of lignocellulosic biomass to fuels and chemicals. , 2011, Annual review of chemical and biomolecular engineering.

[57]  J. Heider,et al.  Microbial degradation of aromatic compounds — from one strategy to four , 2011, Nature Reviews Microbiology.

[58]  N. Kamimura,et al.  Characterization of the Protocatechuate 4,5-Cleavage Pathway Operon in Comamonas sp. Strain E6 and Discovery of a Novel Pathway Gene , 2010, Applied and Environmental Microbiology.

[59]  K. Shimizu,et al.  The effect of pfl gene knockout on the metabolism for optically pure d-lactate production by Escherichia coli , 2004, Applied Microbiology and Biotechnology.

[60]  G. Hegeman Synthesis of the Enzymes of the Mandelate Pathway by Pseudomonas putida I. Synthesis of Enzymes by the Wild Type , 1966, Journal of bacteriology.

[61]  José C del Río,et al.  Biodegradation of lignocellulosics: microbial, chemical, and enzymatic aspects of the fungal attack of lignin. , 2005, International microbiology : the official journal of the Spanish Society for Microbiology.

[62]  N. Kaplan,et al.  Chemical characterization of D-lactate dehydrogenase from Escherichia coli B. , 1968, The Journal of biological chemistry.

[63]  E. Hardiman,et al.  Pathways for degradation of lignin in bacteria and fungi. , 2011, Natural product reports.

[64]  Rahul Singh,et al.  The emerging role for bacteria in lignin degradation and bio-product formation. , 2011, Current opinion in biotechnology.

[65]  V. de Lorenzo,et al.  Engineering an anaerobic metabolic regime in Pseudomonas putida KT2440 for the anoxic biodegradation of 1,3-dichloroprop-1-ene. , 2013, Metabolic engineering.

[66]  E. Papoutsakis,et al.  A comparative view of metabolite and substrate stress and tolerance in microbial bioprocessing: From biofuels and chemicals, to biocatalysis and bioremediation. , 2010, Metabolic engineering.

[67]  J. W. Frost,et al.  Environmentally compatible synthesis of adipic acid from D-glucose , 1994 .

[68]  C. J. McGrath,et al.  Effect of exchange rate return on volatility spill-over across trading regions , 2012 .

[69]  Kathleen A. Curran,et al.  Metabolic engineering of muconic acid production in Saccharomyces cerevisiae. , 2013, Metabolic engineering.

[70]  Christopher W. Johnson,et al.  Lignin valorization through integrated biological funneling and chemical catalysis , 2014, Proceedings of the National Academy of Sciences.

[71]  B. Weckhuysen,et al.  The catalytic valorization of lignin for the production of renewable chemicals. , 2010, Chemical reviews.

[72]  Y. Katayama,et al.  Uncovering the Protocatechuate 2,3-Cleavage Pathway Genes , 2009, Journal of bacteriology.

[73]  S. Atsumi,et al.  Recent progress in synthetic biology for microbial production of C3–C10 alcohols , 2012, Front. Microbio..

[74]  Ka-Yiu San,et al.  Metabolic engineering of Escherichia coli: increase of NADH availability by overexpressing an NAD(+)-dependent formate dehydrogenase. , 2002, Metabolic engineering.