In Trichoderma reesei, carbon catabolite repression (CCR) significantly downregulates the transcription of cellulolytic enzymes, which is usually mediated by the zinc finger protein Cre1. It was found that there is a conserved region at the C-terminus of Cre1/CreA in several cellulase-producing fungi that contains up to three continuous S/T phosphorylation sites. Here, S387, S388, T389, and T390 at the C-terminus of Cre1 in T. reesei were mutated to valine for mimicking an unphosphorylated state, thereby generating the transformants Tr_Cre1 S387V , Tr_Cre1 S388V , Tr_Cre1 T389V , and Tr_Cre1 T390V , respectively. Transcription of cel7a in Tr_ Cre1 S388V was markedly higher than that of the parent strain when grown in glucose-containing media. Under these conditions, both filter paperase (FPase) and p-nitrophenyl-β-D-cellobioside (pNPCase) activities, as well as soluble proteins from Tr_Cre1 S388V were significantly increased by up to 2-to 3-fold compared with that of other transformants and the parent strain. The results suggested that S388 is critical site of phosphorylation for triggering CCR at the terminus of Cre1. To our knowledge, this is the first report demonstrating an improvement of cellulase production in T. reesei under CCR by mimicking dephosphorylation at the C-terminus of Cre1. Taken together, we developed a precision engineering strategy based on the modification of phosphorylation sites of Cre1 transcription factor to enhance the production of cellulase in T. reesei under CCR.
Summary
Human milk oligosaccharides (HMOs), the third most abundant solid component of human milk, are reported to be beneficial to infant health. The biosynthesis of lacto-
N
-biose (LNB), the building block for HMOs, suffers from excessive addition of cofactors and intermediate inhibition. Here, we developed an
in vitro
multienzyme cascade composed of LNB module, ATP regeneration, and pyruvate oxidase-driven phosphate recycling to produce LNB. The integration between ATP regeneration and Pi alleviation increased the LNB conversion ratio and resulted in a ΔG'° decrease of 540 KJ/mol. Under optimal conditions, the LNB conversion ratio was improved from 0.34 to 0.83 mol/mol GlcNAc and the ATP addition decreased to 50%. Finally, 0.96 mol/mol GlcNAc and 71.6 mg LNB g
−1
GlcNAc h
−1
of LNB yield was achieved in a 100-mL reaction system. The synergistic strategy not only paves the way for producing LNB but also facilitates other chemicals with multienzyme cascades.
Carbon catabolite repression (CCR), which is mainly mediated by Cre1 and triggered by glucose, leads to a decrease in cellulase production in
Trichoderma reesei
. Many studies have focused on modifying Cre1 for alleviating CCR. Based on the homologous alignment of CreA from wild-type
Penicillium oxalicum
114–2 (Po-0) and cellulase hyperproducer JUA10-1(Po-1), we constructed a C-terminus substitution strain—Po-2—with decreased transcriptional levels of cellulase and enhanced CCR. Results revealed that the C-terminal domain of CreA
Po−1
plays an important role in alleviating CCR. Furthermore, we replaced the C-terminus of Cre1 with that of CreA
Po−1
in
T. reesei
(Tr-0) and generated Tr-1. As a control, the C-terminus of Cre1 was truncated and Tr-2 was generated. The transcriptional profiles of these transformants revealed that the C-terminal chimera greatly improves cellulase transcription in the presence of glucose and thus upregulates cellulase in the presence of glucose and weakens CCR, consistent with truncating the C-terminus of Cre1 in Tr-0. Therefore, we propose constructing a C-terminal chimera as a new strategy to improve cellulase production and alleviate CCR in the presence of glucose.
In Trichoderma reesei, carbon catabolite repression (CCR) significantly downregulates the transcription of cellulolytic enzymes, which is usually mediated by the zinc finger protein Cre1. It was found that there is a conserved region at the C-terminus of Cre1/CreA in several cellulase-producing fungi that contains up to three continuous S/T phosphorylation sites. Here, S387, S388, T389, and T390 at the C-terminus of Cre1 in T.reesei were mutated to valine for mimicking an unphosphorylated state, thereby generating the transformants Tr_Cre1 S387V , Tr_Cre1 S388V , Tr_Cre1 T389V , and Tr_Cre1 T390V , respectively. Transcription of cel7a in Tr_ Cre1 S388V was markedly higher than that of the parent strain when grown in glucose-containing media. Under these conditions, both filter paperase (FPase) and p-nitrophenyl-β-D-cellobioside (pNPCase) activities, as well as soluble proteins from Tr_Cre1 S388V were significantly increased by up to 2-to 3-fold compared with that of other transformants and the parent strain. To our knowledge, this is the first report demonstrating an improvement of cellulase production in fungal species under CCR by mimicking dephosphorylation at the C-terminus of Cre1. Taken together, we developed a precision engineering strategy based on the modification of phosphorylation sites of Cre1 transcription factor to enhance the production of cellulase in fungal species under CCR.
AbbreviationsCCR: carbon catabolite repression; RT-qPCR: reverse transcription quantitative polymerase chain reaction; PKA: cyclic adenosine monophosphate (cAMP)-dependent protein kinase A; FP: filter paper
The
nonproductive adsorption of cellulase onto lignin significantly
inhibited the enzymatic hydrolysis of lignocellulosic biomass. In
this study, we constructed a rapid fluorescence detection (RFD) system,
and using this system, we demonstrated that the addition of cationic
additives DTAB or polyDADMAC greatly increased the partition coefficients
of cellulose/lignin, reduced nonproductive adsorption, and enhanced
the hydrolysis efficiency of lignocellulose compared to those of Tweens
or PEGs. Moreover, the addition of polyDADMAC and DTAB increased the
glucose yield released from the mixture of Avicel and AICS-lignin
(MCL) by 16.9 and 20.6%, respectively, and reduced the inhibition
rate of lignin by 16.9 and 20.7%, respectively. Interestingly, polyDADMAC
or DTAB treatment performed more effectively for the enzymatic hydrolysis
of pretreated lignocellulosic biomass, compared with MCL. We confirmed
that the reduced hydrophobicity and increased zeta potential of lignin
cocontribute to the dampening nonproductive adsorption of lignin.
In particular, the zeta potential values of lignin and the partition
coefficients of Avicel/lignin with the addition of additives showed
a good correlation, suggesting that electrostatic force also plays
a crucial role in the adsorbing of cellulase on lignin. This work
will be conducive to decreasing the nonproductive binding of cellulase
onto lignin and enhancing cellulose conversion.
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