Integrated strain- and process design enable production of 220 g L−1 itaconic acid with Ustilago maydis

Tehrani, Hamed Hosseinpour; Becker, Johanna; Bator, Isabel; Saur, Katharina Maria; Meyer, Svenja; Lóia, Ana Catarina Rodrigues; Blank, Lars M.; Wierckx, Nick

doi:10.1186/s13068-019-1605-6

Cited by 65 publications

(85 citation statements)

References 73 publications

(125 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As last modification, ria1, encoding the itaconate cluster regulator, was overexpressed by a promoter exchange to improve itaconate and decrease malate production (Geiser et al, 2016b). This was achieved by the inclusion of the P etef promoter into the repair template yielding a marker-free insertion (Hosseinpour Tehrani et al, 2019a). For the generation of Δcyp3, ΔMEL, ΔUA and ΔP ria1 ::P etef , the CRISPR/Cas9 system was used, while Δdgat was achieved using the FRT/FLP-mediated approach.…”

Section: Resultsmentioning

confidence: 99%

AnUstilago maydischassis for itaconic acid production without by‐products

Becker

Tehrani

Gauert

et al. 2019

Microbial Biotechnology

Self Cite

View full text Add to dashboard Cite

Summary Ustilago maydis is a promising yeast for the production of a range of valuable metabolites, including itaconate, malate, glycolipids and triacylglycerols. However, wild‐type strains generally produce a potpourri of all of these metabolites, which hinders efficient production of single target chemicals. In this study, the diverse by‐product spectrum of U. maydis was reduced through strain engineering using CRISPR/Cas9 and FLP/FRT, greatly increasing the metabolic flux into the targeted itaconate biosynthesis pathway. With this strategy, a marker‐free chassis strain could be engineered, which produces itaconate from glucose with significantly enhanced titre, rate and yield. The lack of by‐product formation not only benefited itaconate production, it also increases the efficiency of downstream processing improving cell handling and product purity.

show abstract

Section: Resultsmentioning

confidence: 99%

AnUstilago maydischassis for itaconic acid production without by‐products

Becker

Tehrani

Gauert

et al. 2019

Microbial Biotechnology

Self Cite

View full text Add to dashboard Cite

show abstract

“…Itaconic acid is also produced from citrate through the intermediate cis-aconitate which is decarboxylated to itaconate as illustrated in Figure 1M. Titers in the range of 120-220 g/L have been reported with itaconate yields ranging from 0.45 to as high as 0.58 g itaconic acid/ g glucose and maximal production rates from 0.45 to 1g/L-h (Hevekerl et al, 2014;Huang et al, 2014;Krull et al, 2017a;Tehrani et al, 2019). In addition, the chemical decarboxylation of itaconic acid to MA has been demonstrated via several different catalytic routes, mostly reliant on metal catalysts.…”

Section: Itaconic Acidmentioning

confidence: 99%

“…The route to MA through itaconic acid may well be the most mature, with previous scale up and commercial production but key improvements to reduce costs would include improving the yield of fermentation, as well as increasing the volumetric rate of production by at least 2 fold (Bafana and Pandey, 2018). Recent efforts have been aimed at engineering organisms beyond A. terreus including U. maydis, Y. lipolytica, and E. coli (Krull et al, 2017b;Tehrani et al, 2019;Zhao et al, 2019).…”

Section: Itaconic Acidmentioning

confidence: 99%

A Review of the Biotechnological Production of Methacrylic Acid

Lebeau

Efromson

Lynch

2020

Front. Bioeng. Biotechnol.

View full text Add to dashboard Cite

Industrial biotechnology can lead to new routes and potentially to more sustainable production of numerous chemicals. We review the potential of biobased routes from sugars to the large volume commodity, methacrylic acid, involving fermentation based bioprocesses. We cover the key progress over the past decade on direct and indirect fermentation based routes to methacrylic acid including both academic as well as patent literature. Finally, we take a critical look at the potential of biobased routes to methacrylic acid in comparison with both incumbent as well as newer greener petrochemical based processes.

show abstract

“…Recently, itaconic acid production with U. maydis and other Ustilaginaceae such as U. cynodontis has been improved considerably by genetic engineering (16)(17)(18)(19). This, along with advances in bioprocess design enabled by the yeast morphology (19)(20)(21), has considerably enhanced the yield, titer, and rate of itaconic acid production by Ustilago.…”

Section: Introductionmentioning

confidence: 99%

“…Since nitrogen limitation is a prerequisite for itaconic acid production with U. maydis, the residual NH 4 + -concentration present in the cellulase-containing supernatants had to be monitored (42). The supernatants were diluted accordingly to reach a nal NH 4 + -concentration equivalent to the 0.8 g/L NH 4 Cl, typically present in itaconic acid production medium for U. maydis (18,20,21).…”

Section: Introductionmentioning

confidence: 99%

Consolidated Bioprocessing of Cellulose to Itaconic Acid by a Co-Culture of Trichoderma Reesei and Ustilago Maydis.

Schlembach

Tehrani

Blank

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

Background: Itaconic acid is a bio-derived platform chemical with uses ranging from polymer synthesis to biofuel production. The efficient conversion of cellulosic waste streams into itaconic acid could thus enable the sustainable production of a variety of substitutes for fossil oil based products. However, the realization of such a process is currently hindered by an expensive conversion of cellulose into fermentable sugars. Here, we present the stepwise development of a fully consolidated bioprocess (CBP), which is capable to directly convert recalcitrant cellulose into itaconic acid without the need for separate cellulose hydrolysis including the application of commercial cellulases. The process is based on a synthetic microbial consortium of the cellulase producer Trichoderma reesei and the itaconic acid producing yeast Ustilago maydis. Results: The efficiency of the process was compared to a simultaneous hydrolysis and fermentation setup (SSF). Because of the additional substrate consumption of T. reesei in the CBP, the itaconic acid yield was significantly lower in the CBP than in the SSF. In order to increase yield and productivity of itaconic acid in the CBP, the population dynamics was manipulated by varying the inoculation delay between T. reesei and U. maydis. Surprisingly, neither inoculation delay nor inoculation density significantly affected the population development or the CBP performance. Instead, the substrate availability was the most important parameter. U. maydis was only able to grow and to produce itaconic acid when the cellulose concentration and thus, the sugar supply rate, was high. Finally, the metabolic processes during fed-batch CBP were analyzed in depth by online respiration measurements. A method was developed to estimate cellulose consumption, itaconic acid formation as well as the actual itaconic acid production yield online. Again, substrate availability was the key factor also controlling itaconic acid yield. In summary, an itaconic acid titer of 34 g/L with a total productivity of up to 0.07 g/L/h and a yield of 0.16 g/g could be reached during fed-batch cultivation. Conclusion: This study demonstrates the feasibility of consortium based CBP for itaconic acid production and also lays the fundament for the development and improvement of similar microbial consortia for cellulose based organic acid production.

show abstract

Integrated strain- and process design enable production of 220 g L−1 itaconic acid with Ustilago maydis

Cited by 65 publications

References 73 publications

AnUstilago maydischassis for itaconic acid production without by‐products

AnUstilago maydischassis for itaconic acid production without by‐products

A Review of the Biotechnological Production of Methacrylic Acid

Consolidated Bioprocessing of Cellulose to Itaconic Acid by a Co-Culture of Trichoderma Reesei and Ustilago Maydis.

Contact Info

Product

Resources

About