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Your search keyword '"Czajka, Jeffrey J"' showing total 23 results
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23 results on '"Czajka, Jeffrey J"'

1. BayFlux: A Bayesian method to quantify metabolic Fluxes and their uncertainty at the genome scale

Author

Backman, Tyler WH, Schenk, Christina, Radivojevic, Tijana, Ando, David, Singh, Jahnavi, Czajka, Jeffrey J, Costello, Zak, Keasling, Jay D, Tang, Yinjie, Akhmatskaya, Elena, and Martin, Hector Garcia

Subjects
Biological Sciences, Industrial Biotechnology, 1.4 Methodologies and measurements, Underpinning research, Bayes Theorem, Uncertainty, Metabolic Flux Analysis, Carbon Isotopes, Models, Biological, Mathematical Sciences, Information and Computing Sciences, Bioinformatics
Abstract

Metabolic fluxes, the number of metabolites traversing each biochemical reaction in a cell per unit time, are crucial for assessing and understanding cell function. 13C Metabolic Flux Analysis (13C MFA) is considered to be the gold standard for measuring metabolic fluxes. 13C MFA typically works by leveraging extracellular exchange fluxes as well as data from 13C labeling experiments to calculate the flux profile which best fit the data for a small, central carbon, metabolic model. However, the nonlinear nature of the 13C MFA fitting procedure means that several flux profiles fit the experimental data within the experimental error, and traditional optimization methods offer only a partial or skewed picture, especially in "non-gaussian" situations where multiple very distinct flux regions fit the data equally well. Here, we present a method for flux space sampling through Bayesian inference (BayFlux), that identifies the full distribution of fluxes compatible with experimental data for a comprehensive genome-scale model. This Bayesian approach allows us to accurately quantify uncertainty in calculated fluxes. We also find that, surprisingly, the genome-scale model of metabolism produces narrower flux distributions (reduced uncertainty) than the small core metabolic models traditionally used in 13C MFA. The different results for some reactions when using genome-scale models vs core metabolic models advise caution in assuming strong inferences from 13C MFA since the results may depend significantly on the completeness of the model used. Based on BayFlux, we developed and evaluated novel methods (P-13C MOMA and P-13C ROOM) to predict the biological results of a gene knockout, that improve on the traditional MOMA and ROOM methods by quantifying prediction uncertainty.

Published
2023

2. Tuning a high performing multiplexed-CRISPRi Pseudomonas putida strain to further enhance indigoidine production

Author

Czajka, Jeffrey J, Banerjee, Deepanwita, Eng, Thomas, Menasalvas, Javier, Yan, Chunsheng, Munoz, Nathalie Munoz, Poirier, Brenton C, Kim, Young-Mo, Baker, Scott E, Tang, Yinjie J, and Mukhopadhyay, Aindrila

Subjects
Prevention, Genetics, Growth coupling, C-13-MFA, Pseudomonas putida KT2440, Multiplexed CRISPR interference, Indigoidine Cpf1/Cas12a, 13C-MFA, Cpf1/Cas12a, Indigoidine
Abstract

In this study, a 14-gene edited Pseudomonas putida KT2440 strain for heterologous indigoidine production was examined using three distinct omic datasets. Transcriptomic data indicated that CRISPR/dCpf1-interference (CRISPRi) mediated multiplex repression caused global gene expression changes, implying potential undesirable changes in metabolic flux. 13C-metabolic flux analysis (13C-MFA) revealed that the core P. putida flux network after CRISPRi repression was conserved, with moderate reduction of TCA cycle and pyruvate shunt activity along with glyoxylate shunt activation during glucose catabolism. Metabolomic results identified a change in intracellular TCA metabolites and extracellular metabolite secretion profiles (sugars and succinate overflow) in the engineered strains. These omic analyses guided further strain engineering, with a random mutagenesis screen first identifying an optimal ribosome binding site (RBS) for Cpf1 that enabled stronger product-substrate pairing (1.6-fold increase). Then, deletion strains were constructed with excision of the PHA operon (ΔphaAZC-IID) resulting in a 2.2-fold increase in indigoidine titer over the optimized Cpf1-RBS construct at the end of the growth phase (∼6 h). The maximum indigoidine titer (at 72 h) in the ΔphaAZC-IID strain had a 1.5-fold and 1.8-fold increase compared to the optimized Cpf1-RBS construct and the original strain, respectively. Overall, this study demonstrated that integration of omic data types is essential for understanding responses to complex metabolic engineering designs and directly quantified the effect of such modifications on central metabolism.

Published
2022

3. Biosynthesis of terpene compounds using the non-model yeast Yarrowia lipolytica: grand challenges and a few perspectives

Author

Worland, Alyssa M, Czajka, Jeffrey J, Li, Yanran, Wang, Yechun, Tang, Yinjie J, and Su, Wei Wen

Subjects
Biological Sciences, Industrial Biotechnology, Fermentation, Metabolic Engineering, Terpenes, Yarrowia, Engineering, Technology, Biotechnology, Agricultural biotechnology, Industrial biotechnology, Medical biotechnology
Abstract

Yarrowia lipolytica has emerged as an important non-model host for terpene production. However, three main challenges remain in industrial production using this yeast. First, considerable knowledge gaps exist in metabolic flux across multiple compartments, cofactor generation, and catabolism of non-sugar carbon sources. Second, many enzymatic steps in the complex-terpene synthesis pathway can pose rate-limitations, causing accumulation of toxic intermediates and increased metabolic burdens. Third, metabolic shifts, morphological changes, and genetic mutations are poorly characterized under industrial fermentation conditions. To overcome these challenges, systems metabolic analysis, protein engineering, novel pathway engineering, model-guided strain design, and fermentation optimization have been attempted with some successes. Further developments that address these challenges are needed to advance the Yarrowia lipolytica platform for industrial-scale production of high-value terpenes, including those with highly complex structures such as anticancer molecules withanolides and insecticidal limonoids.

Published
2020

5. Model metabolic strategy for heterotrophic bacteria in the cold ocean based on Colwellia psychrerythraea 34H

Author

Czajka, Jeffrey J, Abernathy, Mary H, Benites, Veronica T, Baidoo, Edward EK, Deming, Jody W, and Tang, Yinjie J

Subjects
Earth Sciences, Oceanography, Biological Sciences, Industrial Biotechnology, Infection, Affordable and Clean Energy, Life Below Water, Alteromonadaceae, Cold Temperature, Energy Metabolism, Heterotrophic Processes, Models, Biological, Oceans and Seas, ED pathway, gluconeogensis, marine psychrophile, metabolic flux, short-chain fatty acids
Abstract

Colwellia psychrerythraea 34H is a model psychrophilic bacterium found in the cold ocean-polar sediments, sea ice, and the deep sea. Although the genomes of such psychrophiles have been sequenced, their metabolic strategies at low temperature have not been quantified. We measured the metabolic fluxes and gene expression of 34H at 4 °C (the mean global-ocean temperature and a normal-growth temperature for 34H), making comparative analyses at room temperature (above its upper-growth temperature of 18 °C) and with mesophilic Escherichia coli When grown at 4 °C, 34H utilized multiple carbon substrates without catabolite repression or overflow byproducts; its anaplerotic pathways increased flux network flexibility and enabled CO2 fixation. In glucose-only medium, the Entner-Doudoroff (ED) pathway was the primary glycolytic route; in lactate-only medium, gluconeogenesis and the glyoxylate shunt became active. In comparison, E. coli, cold stressed at 4 °C, had rapid glycolytic fluxes but no biomass synthesis. At their respective normal-growth temperatures, intracellular concentrations of TCA cycle metabolites (α-ketoglutarate, succinate, malate) were 4-17 times higher in 34H than in E. coli, while levels of energy molecules (ATP, NADH, NADPH) were 10- to 100-fold lower. Experiments with E. coli mutants supported the thermodynamic advantage of the ED pathway at cold temperature. Heat-stressed 34H at room temperature (2 hours) revealed significant down-regulation of genes associated with glycolytic enzymes and flagella, while 24 hours at room temperature caused irreversible cellular damage. We suggest that marine heterotrophic bacteria in general may rely upon simplified metabolic strategies to overcome thermodynamic constraints and thrive in the cold ocean.

Published
2018

6. Engineering the oleaginous yeast Yarrowia lipolytica to produce the aroma compound β-ionone

Author

Czajka, Jeffrey J, Nathenson, Justin A, Benites, Veronica T, Baidoo, Edward EK, Cheng, Qianshun, Wang, Yechun, and Tang, Yinjie J

Subjects
Responsible Consumption and Production, Metabolic Engineering, Norisoprenoids, Yarrowia, 13C labeling, Acetyl-CoA, Fed-batch fermentation, Machine learning, Strain stability, Terpenoid, β-carotene, Microbiology, Industrial Biotechnology, Biotechnology
Abstract

Backgroundβ-Ionone is a fragrant terpenoid that generates a pleasant floral scent and is used in diverse applications as a cosmetic and flavoring ingredient. A growing consumer desire for natural products has increased the market demand for natural β-ionone. To date, chemical extraction from plants remains the main approach for commercial natural β-ionone production. Unfortunately, changing climate and geopolitical issues can cause instability in the β-ionone supply chain. Microbial fermentation using generally recognized as safe (GRAS) yeast offers an alternative method for producing natural β-ionone. Yarrowia lipolytica is an attractive host due to its oleaginous nature, established genetic tools, and large intercellular pool size of acetyl-CoA (the terpenoid backbone precursor).ResultsA push-pull strategy via genome engineering was applied to a Y. lipolytica PO1f derived strain. Heterologous and native genes in the mevalonate pathway were overexpressed to push production to the terpenoid backbone geranylgeranyl pyrophosphate, while the carB and biofunction carRP genes from Mucor circinelloides were introduced to pull flux towards β-carotene (i.e., ionone precursor). Medium tests combined with machine learning based data analysis and 13C metabolite labeling investigated influential nutrients for the β-carotene strain that achieved > 2.5 g/L β-carotene in a rich medium. Further introduction of the carotenoid cleavage dioxygenase 1 (CCD1) from Osmanthus fragrans resulted in the β-ionone production. Utilization of in situ dodecane trapping avoided ionone loss from vaporization (with recovery efficiencies of ~ 76%) during fermentation operations, which resulted in titers of 68 mg/L β-ionone in shaking flasks and 380 mg/L in a 2 L fermenter. Both β-carotene medium tests and β-ionone fermentation outcomes indicated the last enzymatic step CCD1 (rather than acetyl-CoA supply) as the key bottleneck.ConclusionsWe engineered a GRAS Y. lipolytica platform for sustainable and economical production of the natural aroma β-ionone. Although β-carotene could be produced at high titers by Y. lipolytica, the synthesis of β-ionone was relatively poor, possibly due to low CCD1 activity and non-specific CCD1 cleavage of β-carotene. In addition, both β-carotene and β-ionone strains showed decreased performances after successive sub-cultures. For industrial application, β-ionone fermentation efforts should focus on both CCD enzyme engineering and strain stability improvement.

Published
2018

16. Tuning a high performing multiplexed-CRISPRi Pseudomonas putida strain to further enhance indigoidine production

Author

Czajka, Jeffrey J., primary, Banerjee, Deepanwita, additional, Eng, Thomas, additional, Menasalvas, Javier, additional, Yan, Chunsheng, additional, Munoz, Nathalie Munoz, additional, Poirier, Brenton C., additional, Kim, Young-Mo, additional, Baker, Scott E., additional, Tang, Yinjie J., additional, and Mukhopadhyay, Aindrila, additional

Published
2022
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17. Optimizing a High Performing Multiplex-CRISPRi P. putida strain with Integrated Metabolomics and 13C-Metabolic Flux Analyses

Author

Czajka, Jeffrey J, primary, Banerjee, Deepanwita, additional, Eng, Thomas T, additional, Menasalvas, Javier, additional, Yan, Chunsheng, additional, Munoz Munoz, Nathalie, additional, Poirier, Brenton C, additional, Kim, Young-Mo, additional, Baker, Scott E, additional, Tang, Yinjie J, additional, and Mukhopadhyay, Aindrila, additional

Published
2021
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21. Tuning a high performing multiplexed-CRISPRi Pseudomonas putidastrain to further enhance indigoidine production

Author

Czajka, Jeffrey J., Banerjee, Deepanwita, Eng, Thomas, Menasalvas, Javier, Yan, Chunsheng, Munoz, Nathalie Munoz, Poirier, Brenton C., Kim, Young-Mo, Baker, Scott E., Tang, Yinjie J., and Mukhopadhyay, Aindrila

Abstract

In this study, a 14-gene edited Pseudomonas putidaKT2440 strain for heterologous indigoidine production was examined using three distinct omic datasets. Transcriptomic data indicated that CRISPR/dCpf1-interference (CRISPRi) mediated multiplex repression caused global gene expression changes, implying potential undesirable changes in metabolic flux. 13C-metabolic flux analysis (13C-MFA) revealed that the core P. putidaflux network after CRISPRi repression was conserved, with moderate reduction of TCA cycle and pyruvate shunt activity along with glyoxylate shunt activation during glucose catabolism. Metabolomic results identified a change in intracellular TCA metabolites and extracellular metabolite secretion profiles (sugars and succinate overflow) in the engineered strains. These omic analyses guided further strain engineering, with a random mutagenesis screen first identifying an optimal ribosome binding site (RBS) for Cpf1 that enabled stronger product-substrate pairing (1.6–fold increase). Then, deletion strains were constructed with excision of the PHA operon (ΔphaAZC-IID) resulting in a 2.2–fold increase in indigoidine titer over the optimized Cpf1-RBS construct at the end of the growth phase (∼6 h). The maximum indigoidine titer (at 72 h) in the ΔphaAZC-IIDstrain had a 1.5–fold and 1.8–fold increase compared to the optimized Cpf1-RBS construct and the original strain, respectively. Overall, this study demonstrated that integration of omic data types is essential for understanding responses to complex metabolic engineering designs and directly quantified the effect of such modifications on central metabolism.

Published
2022
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22. Analysis of Yarrowia lipolyticagrowth, catabolism, and terpenoid biosynthesis during utilization of lipid-derived feedstock

Author

Worland, Alyssa M., Czajka, Jeffrey J., Xing, Yun, Harper, Willie F., Moore, Aryiana, Xiao, Zhengyang, Han, Zhenlin, Wang, Yechun, Su, Wei Wen, and Tang, Yinjie J.

Abstract

This study employs biomass growth analyses and 13C-isotope tracing to investigate lipid feedstock utilization by Yarrowia lipolytica. Compared to glucose, oil-feedstock in the minimal medium increases the yeast's biomass yields and cell sizes, but decreases its protein content (<20% of total biomass) and enzyme abundances for product synthesis. Labeling results indicate a segregated metabolic network (the glycolysis vs. the TCA cycle) during co-catabolism of sugars (glucose or glycerol) with fatty acid substrates, which facilitates resource allocations for biosynthesis without catabolite repressions. This study has also examined the performance of a β-carotene producing strain in different growth mediums. Canola oil-containing yeast-peptone (YP) has resulted in the best β-carotene titer (121 ± 13 mg/L), two-fold higher than the glucose based YP medium. These results highlight the potential of Y. lipolyticafor the valorization of waste-derived lipid feedstock.

Published
2020
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23. CRISPR-Cas9/Cas12a systems for efficient genome editing and large genomic fragment deletions in Aspergillus niger .

Author

Yuan G, Deng S, Czajka JJ, Dai Z, Hofstad BA, Kim J, and Pomraning KR

Abstract

CRISPR technology has revolutionized fungal genetic engineering by accelerating the pace and expanding the feasible scope of experiments in this field. Among various CRISPR-Cas systems, Cas9 and Cas12a are widely used in genetic and metabolic engineering. In filamentous fungi, both Cas9 and Cas12a have been utilized as CRISPR nucleases. In this work we first compared efficacies and types of genetic edits for CRISPR-Cas9 and -Cas12a systems at the polyketide synthase ( albA ) gene locus in Aspergillus niger . By employing a tRNA-based gRNA polycistronic cassette, both Cas9 and Cas12a have demonstrated equally remarkable editing efficacy. Cas12a showed potential superiority over Cas9 protein when one gRNA was used for targeting, achieving an editing efficiency of 86.5% compared to 31.7% for Cas9. Moreover, when employing two gRNAs for targeting, both systems achieved up to 100% editing efficiency for single gene editing. In addition, the CRISPR-Cas9 system has been reported to induce large genomic deletions in various species. However, its use for engineering large chromosomal segments deletions in filamentous fungi still requires optimization. Here, we engineered Cas9 and -Cas12a-induced large genomic fragment deletions by targeting various genomic regions of A . niger ranging from 3.5 kb to 40 kb. Our findings demonstrate that targeted engineering of large chromosomal segments can be achieved, with deletions of up to 69.1% efficiency. Furthermore, by targeting a secondary metabolite gene cluster, we show that fragments over 100 kb can be efficiently and specifically deleted using the CRISPR-Cas9 or -Cas12a system. Overall, in this paper, we present an efficient multi-gRNA genome editing system utilizing Cas9 or Cas12a that enables highly efficient targeted editing of genes and large chromosomal regions in A . niger ., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Yuan, Deng, Czajka, Dai, Hofstad, Kim and Pomraning.)

Published
2024
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