| 1. |
- Liu, Lifang, 1979, et al.
(författare)
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Balanced globin protein expression and heme biosynthesis improve production of human hemoglobin in Saccharomyces cerevisiae
- 2014
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Ingår i: Metabolic Engineering. - : Elsevier BV. - 1096-7176 .- 1096-7184. ; 21, s. 9-16
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Tidskriftsartikel (refereegranskat)abstract
- Due to limitations associated with whole blood for transfusions (antigen compatibility, transmission of infections, supply and storage), the use of cell-free hemoglobin as an oxygen carrier substitute has been in the center of research interest for decades. Human hemoglobin has previously been synthesized in yeast, however the challenge is to balance the expression of the two different globin subunits, as well as the supply of the prosthetic heme required for obtaining the active hemoglobin (alpha(2)beta(2)). In this work we evaluated the expression of different combinations of alpha and beta peptides and combined this with metabolic engineering of the heme biosynthetic pathway. Through evaluation of several different strategies we showed that engineering the biosynthesis pathway can substantially increase the heme level in yeast cells, and this resulted in a significant enhancement of human hemoglobin production. Besides demonstration of improved hemoglobin production our work demonstrates a novel strategy for improving the production of complex proteins, especially multimers with a prosthetic group. Crown Copyright (C) 2013 Published by Elsevier Inc. on behalf of International Metabolic Engineering Society. All rights reserved.
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| 2. |
- Liu, Zihe, et al.
(författare)
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Improved Production of a Heterologous Amylase in Saccharomyces cerevisiae by Inverse Metabolic Engineering
- 2014
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Ingår i: Applied and Environmental Microbiology. - 0099-2240 .- 1098-5336. ; 80:17, s. 5542-5550
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Tidskriftsartikel (refereegranskat)abstract
- The increasing demand for industrial enzymes and biopharmaceutical proteins relies on robust production hosts with high protein yield and productivity. Being one of the best-studied model organisms and capable of performing posttranslational modifications, the yeast Saccharomyces cerevisiae is widely used as a cell factory for recombinant protein production. However, many recombinant proteins are produced at only 1% (or less) of the theoretical capacity due to the complexity of the secretory pathway, which has not been fully exploited. In this study, we applied the concept of inverse metabolic engineering to identify novel targets for improving protein secretion. Screening that combined UV-random mutagenesis and selection for growth on starch was performed to find mutant strains producing heterologous amylase 5-fold above the level produced by the reference strain. Genomic mutations that could be associated with higher amylase secretion were identified through whole-genome sequencing. Several single-point mutations, including an S196I point mutation in the VTA1 gene coding for a protein involved in vacuolar sorting, were evaluated by introducing these to the starting strain. By applying this modification alone, the amylase secretion could be improved by 35%. As a complement to the identification of genomic variants, transcriptome analysis was also performed in order to understand on a global level the transcriptional changes associated with the improved amylase production caused by UV mutagenesis.
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| 3. |
- Liu, Zihe, 1984, et al.
(författare)
-
Improved Production of a Heterologous Amylase in Saccharomyces cerevisiae by Inverse Metabolic Engineering
- 2014
-
Ingår i: Applied and Environmental Microbiology. - : American Society for Microbiology. - 1098-5336 .- 0099-2240. ; 80:17, s. 5542-5550
-
Tidskriftsartikel (refereegranskat)abstract
- The increasing demand for industrial enzymes and biopharmaceutical proteins relies on robust production hosts with high protein yield and productivity. Being one of the best-studied model organisms and capable of performing posttranslational modifications, the yeast Saccharomyces cerevisiae is widely used as a cell factory for recombinant protein production. However, many recombinant proteins are produced at only 1% (or less) of the theoretical capacity due to the complexity of the secretory pathway, which has not been fully exploited. In this study, we applied the concept of inverse metabolic engineering to identify novel targets for improving protein secretion. Screening that combined UV-random mutagenesis and selection for growth on starch was performed to find mutant strains producing heterologous amylase 5-fold above the level produced by the reference strain. Genomic mutations that could be associated with higher amylase secretion were identified through whole-genome sequencing. Several single-point mutations, including an S196I point mutation in the VTA1 gene coding for a protein involved in vacuolar sorting, were evaluated by introducing these to the starting strain. By applying this modification alone, the amylase secretion could be improved by 35%. As a complement to the identification of genomic variants, transcriptome analysis was also performed in order to understand on a global level the transcriptional changes associated with the improved amylase production caused by UV mutagenesis.
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| 4. |
- Liu, Lifang, 1979, et al.
(författare)
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Genome-scale analysis of the high-efficient protein secretion system of Aspergillus oryzae
- 2014
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Ingår i: BMC Systems Biology. - : Springer Science and Business Media LLC. - 1752-0509. ; 8:73
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Tidskriftsartikel (refereegranskat)abstract
- Background: The koji mold, Aspergillus oryzae is widely used for the production of industrial enzymes due to its particularly high protein secretion capacity and ability to perform post-translational modifications. However, systemic analysis of its secretion system is lacking, generally due to the poorly annotated proteome. Results: Here we defined a functional protein secretory component list of A. oryzae using a previously reported secretory model of S. cerevisiae as scaffold. Additional secretory components were obtained by blast search with the functional components reported in other closely related fungal species such as Aspergillus nidulans and Aspergillus niger. To evaluate the defined component list, we performed transcriptome analysis on three a-amylase over-producing strains with varying levels of secretion capacities. Specifically, secretory components involved in the ER-associated processes (including components involved in the regulation of transport between ER and Golgi) were significantly up-regulated, with many of them never been identified for A. oryzae before. Furthermore, we defined a complete list of the putative A. oryzae secretome and monitored how it was affected by overproducing amylase. Conclusion: In combination with the transcriptome data, the most complete secretory component list and the putative secretome, we improved the systemic understanding of the secretory machinery of A. oryzae in response to high levels of protein secretion. The roles of many newly predicted secretory components were experimentally validated and the enriched component list provides a better platform for driving more mechanistic studies of the protein secretory pathway in this industrially important fungus.
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| 5. |
- Liu, Lifang, 1979
(författare)
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Systems Biology of Recombinant Protein Production by Fungi
- 2014
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Systems biology has emerged as a highly potent tool for studying biological processes over the last decades. However, its application to complex metabolic processes such as protein secretion is still at the infant stage. Saccharomyces cerevisiae and Aspergillus oryzae are two important fungal cell factories which occupy significant proportions of recombinant protein productions, whereas various bottlenecks and undiscovered mechanisms limit their full potential as robust hosts.In this thesis, systems biology approaches were applied to explore these two organisms in respect of protein production. By utilizing and engineering the yeast endogenous heme synthesis, we demonstrated the possibility for efficient production of complex proteins (e.g. multimer with a prosthetic group) by yeast. Applying inverse metabolic engineering, we identified many genomic variants that may contribute to improve protein secretion in yeast. Specifically, we examined the effect of a single point mutation on VTA1 encoding a regulatory protein in the MVB pathway in endocytosis. Our result suggests that the VTA1S196I mutation might help to accelerate nutrient uptake via endocytosis, which subsequently enhanced protein synthesis and secretion. Oxygen is an important element associated with normal cellular metabolism as well as protein production. We studied how Rox1p, a heme-dependent transcription repressor of many hypoxia-induced genes, affect protein production in yeast, under aerobic conditions. By knocking out ROX1, we observed a 100% increase in the α-amylase production. Through genome wide transcriptome analysis we identified several Rox1p targets and based on this suggested their roles in improving protein productions. Lastly, applying comparative genomics study, we enriched the list of core protein components involved in the secretory machinery of A. oryzae. To verify the list, several high α-amylase producing strains were constructed. The transcriptional responses of these strains to α-amylase production were studied using microarray, through which several strategies including overexpressing the up-regulated cell wall proteins EglD and Cwp1 and knocking out the genes encoding extracellular proteins competing for the secretory pathway, were proposed.
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