The Effect of pH, Metal Ions, and Insoluble Solids on the Production of Fumarate and Malate by Rhizopus delemar in the Presence of CaCO3

Ronoh, Dominic Kibet; Swart, Reuben Marc; Nicol, Willie; Brink, Hendrik Gideon

doi:10.3390/catal12030263

Cited by 3 publications

(5 citation statements)

References 42 publications

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“…Although the final FA concentration for fermentation with free and immobilized cells was slightly different (31.23 and 32.03 g/L, respectively), the volumetric productivity for fermentation with immobilized cells (1.335 g/L/h) was six times higher than that for fermentation with free cells (0.217 g/L/h). Ronoh et al (2022) reported the effect of CaCO3 on the co-production of FA and malic acid by the immobilized R. delemar . The increased concentration of calcium ions to 10 g/L resulted in a three-fold enhancement of MA titres.…”

Section: Discussionmentioning

confidence: 99%

“…Thus, fungal cell immobilization for fermentation is complex process influenced by various parameters. One crucial parameter is fungal morphology, which is directly affected by culture conditions, including agitation rate, temperature, medium composition, initial spore concentration, and the immobilization matrix used ( Ronoh et al, 2022 ). Our study demonstrated that, despite the potential use of immobilized cells for FA fermentation, they proved to be less efficient and productive compared to free cells.…”

Section: Discussionmentioning

confidence: 99%

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Fumaric acid production from fermented oil palm empty fruit bunches using fungal isolate K20: a comparison between free and immobilized cells

Boondaeng,

Keabpimai,

Trakunjae

et al. 2024

PeerJ

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This study investigated the potential of using steam-exploded oil palm empty fruit bunches (EFB) as a renewable feedstock for producing fumaric acid (FA), a food additive widely used for flavor and preservation, through a separate hydrolysis and fermentation process using the fungal isolate K20. The efficiency of FA production by free and immobilized cells was compared. The maximum FA concentration (3.25 g/L), with 0.034 g/L/h productivity, was observed after incubation with the free cells for 96 h. Furthermore, the production was scaled up in a 3-L air-lift fermenter using oil palm EFB-derived glucose as the substrate. The FA concentration, yield, and productivity from 100 g/L initial oil palm EFB-derived glucose were 44 g/L, 0.39 g/g, and 0.41 g/L/h, respectively. The potential for scaling up the fermentation process indicates favorable results, which could have significant implications for industrial applications.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Fumaric acid production from fermented oil palm empty fruit bunches using fungal isolate K20: a comparison between free and immobilized cells

Boondaeng,

Keabpimai,

Trakunjae

et al. 2024

PeerJ

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show abstract

“…With 60 or 100 g/L CaCO 3 compared to 20 g/L, carbonate was available until the end of the fermentation, which prevented a drop in pH and resulted in a higher malic to fumaric acid ratio. The authors ruled out the presence of insoluble solids as influencing factor but found increased ion concentrations and different pH values to affect the production profile [ 39 ]. Schmitt et al also observed a positive effect of calcium carbonate on malic acid productivity and associated it with its ability to control the pH as buffering agent, although the authors pointed out that this may not be its only function [ 32 ].…”

Section: Discussionmentioning

confidence: 99%

“…Ronoh et al reported a decreased glucose consumption and fumaric acid production of R. delemar with 20 g/L Ca 2+ in the medium, which suggests inhibition. However, they also observed an increased, albeit delayed, formation of malic acid which might be attributed to a stimulatory effect of Ca 2+ on the enzyme fumarase [ 39 ]. The results described in all these references were obtained for cultivations using glucose as carbon source.…”

Section: Discussionmentioning

confidence: 99%

Optimization of l-malic acid production from acetate with Aspergillus oryzae DSM 1863 using a pH-coupled feeding strategy

et al. 2022

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Background Malic acid, a dicarboxylic acid mainly used in the food industry, is currently produced from fossil resources. The utilization of low-cost substrates derived from biomass could render microbial processes economic. Such feedstocks, like lignocellulosic hydrolysates or condensates of fast pyrolysis, can contain high concentrations of acetic acid. Acetate is a suitable substrate for l-malic acid production with the filamentous fungus Aspergillus oryzae DSM 1863, but concentrations obtained so far are low. An advantage of this carbon source is that it can be used for pH control and simultaneous substrate supply in the form of acetic acid. In this study, we therefore aimed to enhance l-malate production from acetate with A. oryzae by applying a pH-coupled feeding strategy. Results In 2.5-L bioreactor fermentations, several feeding strategies were evaluated. Using a pH-coupled feed consisting of 10 M acetic acid, the malic acid concentration was increased about 5.3-fold compared to the batch process without pH control, resulting in a maximum titer of 29.53 ± 1.82 g/L after 264 h. However, it was not possible to keep both the pH and the substrate concentration constant during this fermentation. By using 10 M acetic acid set to a pH of 4.5, or with the repeated addition of NaOH, the substrate concentration could be maintained within a constant range, but these strategies did not prove beneficial as lower maximum titers and yields were obtained. Since cessation of malic acid production was observed in later fermentation stages despite carbon availability, a possible product inhibition was evaluated in shake flask cultivations. In these experiments, malate and succinate, which is a major by-product during malic acid production, were added at concentrations of up to 50 g/L, and it was found that A. oryzae is capable of organic acid production even at high product concentrations. Conclusions This study demonstrates that a suitable feeding strategy is necessary for efficient malic acid production from acetate. It illustrates the potential of acetate as carbon source for microbial production of the organic acid and provides useful insights which can serve as basis for further optimization.

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“…in which it was further proposed that many of the effects and interactions of Ca 2+ with fungal physiology link to the maintenance of Ca 2+ homeostasis, with multiple channels and transporters dedicated to this task. Consequently, the magnitude of these effects is likely to be complex with synchronous interactions likely -as was observed in a recent study by Ronoh et al 44 in which a compounded interaction between Ca 2+ and pH were observed to affect the production of MA by Rhizopus oryzae.…”

mentioning

confidence: 93%

Malic acid production by Aspergillus oryzae: the immobilized fungal fermentation route

Brink

Geyer‐Johnson

Swart

et al. 2022

Biofuels Bioprod Bioref

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It has been proposed that the microbial bioproduction of chemical precursors could reduce societal overreliance on the petrochemical industry. However, economic implementation remains elusive due to a lack of understanding of the mechanisms involved. The current study evaluated malic acid production using a novel immobilized Aspergillus oryzae fungal bed bioreactor. The experimental procedures involved two different nitrogen sources (urea and (NH4)2SO4), two‐phase growth/production and simultaneous single‐step growth/production runs, the presence and absence of added CO2, the presence and absence of pH control, and the use of glucose and dl‐malate as the carbon sources. The experimental malic acid titers were remarkably poor (between 1.7 and 3.3 g.L−1) in comparison with CaCO3 buffered malic acid titers from literature (concentrations in excess of 100 g.L−1 have been reported reported). In contrast, citric acid was observed to be the main metabolite. The dl‐malate carbon source was consumed with concomitant growth, indicating A. oryzae′s ability to utilize both d and l enantiomers of malic acid. Detailed metabolic flux analyses predicted partial consumption of urea during growth, while (NH4)2SO4 was fully utilized. During the urea runs, significant amounts of glycogen were accumulated in the biomass – which were utilized as substrate during the production run. Nitrogen limitations induced significant lipid production, corresponding to citric acid accumulation in the media; the mechanism for fungal lipid biosynthesis involves citric acid excretion at the expense of malic acid. These results indicate a possible calcareous trigger for malic acid production as opposed to the traditionally accepted nitrogen starvation mechanism – nitrogen starvation resulted in lipid accumulation with corresponding malate loss. © 2022 The Authors. Biofuels, Bioproducts and Biorefining published by Society of Industrial Chemistry and John Wiley & Sons Ltd.

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The Effect of pH, Metal Ions, and Insoluble Solids on the Production of Fumarate and Malate by Rhizopus delemar in the Presence of CaCO3

Cited by 3 publications

References 42 publications

Fumaric acid production from fermented oil palm empty fruit bunches using fungal isolate K20: a comparison between free and immobilized cells

Fumaric acid production from fermented oil palm empty fruit bunches using fungal isolate K20: a comparison between free and immobilized cells

Optimization of l-malic acid production from acetate with Aspergillus oryzae DSM 1863 using a pH-coupled feeding strategy

Malic acid production by Aspergillus oryzae: the immobilized fungal fermentation route

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