Publications
] . (2015). Elimination of carbon catabolite repression in Clostridium acetobutylicum-a journey toward simultaneous use of xylose and glucose. Applied Microbiology and Biotechnology, 99, 7579-7588.
2015_elimination_of_carbon_catabolite_repression_in_clostridium_acetobutylicum_-_a_journey_toward_simultaneous_use_of_xylose_and_glucose.pdf
2015_elimination_of_carbon_catabolite_repression_in_clostridium_acetobutylicum_-_a_journey_toward_simultaneous_use_of_xylose_and_glucose.pdf. (1999). Effect of SecB chaperone on production of periplasmic penicillin acylase in Escherichia coli. Biotechnology Progress, 15, 439-445.
. (2002). Effect of pH on high-temperature production of bacterial penicillin acylase in Escherichia coli. Biotechnology Progress, 18, 668-671.
. (2007). Effect of heat-shock proteins for relieving physiological stress and enhancing the production of penicillin acylase in Escherichia coli. Biotechnology and Bioengineering, 96, 956-966. 2006_effect_of_heat-shock_proteins_for_relieving_physiological_stress_and_enhancing_the_production_of_penicillin_acylase_in_escherichia_coli.pdf
2006_effect_of_heat-shock_proteins_for_relieving_physiological_stress_and_enhancing_the_production_of_penicillin_acylase_in_escherichia_coli.pdf. (2008). Effect of folding factors in rescuing unstable heterologous lipase B to enhance its overexpression in the periplasm of Escherichia coli. Applied Microbiology and Biotechnology, 79, 1035-1044.
. (2000). Effect of carbon source on inclusion body formation upon overproduction of periplasmic penicillin acylase in Escherichia coli. Journal of the Chinese Institute of Chemical Engineers, 31, 219-224.
. (2010). Effect of aberrant disulfide bond formation on protein conformation and molecular property of recombinant therapeutics. Pure and Applied Chemistry, 82, 149-159.
. (2011). Disulfide bond formation and its impact on the biological activity and stability of recombinant therapeutic proteins produced by Escherichia coli expression system. Biotechnology Advances, 29, 923-929. 2011_disulfide_bond_formation.pdf
2011_disulfide_bond_formation.pdf (2016). Disruption of the Reductive 1,3-Propanediol Pathway Triggers Production of 1,2-Propanediol for Sustained Glycerol Fermentation by Clostridium pasteurianum. Applied and Environmental Microbiology, 82, 5375-5388. 2016_disruption_of_the_reductive_13-propanediol_pathway.pdf
2016_disruption_of_the_reductive_13-propanediol_pathway.pdf. (2013). Development of an electrotransformation protocol for genetic manipulation of Clostridium pasteurianum. Biotechnology for Biofuels, 6. 2013_development_of_an_electrotransformation_protocol_for_genetic_manipulation_of_clostridium_pasteurianum.pdf
2013_development_of_an_electrotransformation_protocol_for_genetic_manipulation_of_clostridium_pasteurianum.pdf. (2016). Development of a CRISPR-Cas9 Tool Kit for Comprehensive Engineering of Bacillus subtilis. Applied and Environmental Microbiology, 82, 4876-4895. 2016_development_of_a_crispr-cas9_toolkit_for_comprehensive_engineering_of_bacillus_subtilis.pdf
2016_development_of_a_crispr-cas9_toolkit_for_comprehensive_engineering_of_bacillus_subtilis.pdf (2011). Developing an RNase-free bioprocess to produce pharmaceutical-grade plasmid DNA using selective precipitation and membrane chromatography. Separation and Purification Technology, 83, 121-129.
. (2012). Developing an Extended Genomic Engineering Approach Based on Recombineering to Knock-in Heterologous Genes to Escherichia coli Genome. Molecular Biotechnology, 51, 109-118.
. (2001). DegP-coexpression minimizes inclusion-body formation upon overproduction of recombinant penicillin acylase in Escherichia coli. Biotechnology and Bioengineering, 73, 484-492. 2001_degp-coexpression_minimizes_inclusion_body_formation_upon_overproduction_of_recombinant_penicillin_acylase_in_escherichia_coli.pdf
2001_degp-coexpression_minimizes_inclusion_body_formation_upon_overproduction_of_recombinant_penicillin_acylase_in_escherichia_coli.pdf. (2005). Cytoplasmic overexpression, folding, and processing of penicillin acylase precursor in Escherichia coli. Biotechnology Progress, 21, 1357-1365.
. (2015). Coupling the CRISPR/Cas9 System with Lambda Red Recombineering Enables Simplified Chromosomal Gene Replacement in Escherichia coli. Applied and Environmental Microbiology, 81, 5103-5114. 2015_coupling_the_crispr_cas9_system_with_lambda_red_recombineering_enables_simplified_chromosomal_gene_replacement_in_escherichia_coli.pdf
2015_coupling_the_crispr_cas9_system_with_lambda_red_recombineering_enables_simplified_chromosomal_gene_replacement_in_escherichia_coli.pdf. (2006). Characterization of the T7 promoter system for expressing penicillin acylase in Escherichia coli. Applied Microbiology and Biotechnology, 72, 529-536.
(2005). Chaperone-mediated folding and maturation of the penicillin acylase precursor in the cytoplasm of Escherichia coli. Applied and Environmental Microbiology, 71, 6247-6253. 2005_chaperone-mediated_folding_and_maturation_of_penicillin_acylase_precursor_in_the_cytoplasm_of_escherichia_coli.pdf
2005_chaperone-mediated_folding_and_maturation_of_penicillin_acylase_precursor_in_the_cytoplasm_of_escherichia_coli.pdf (2022). Carbon nanogels exert multipronged attack on resistant bacteria and strongly constrain resistance evolution. Journal of Colloid and Interface Science, 608, 1813-1826. 2022_carbon_nanogels_exert_multipronged_attack_on_resistant_bacteria_and_strongly_constrain_resistance_evolution.pdf
2022_carbon_nanogels_exert_multipronged_attack_on_resistant_bacteria_and_strongly_constrain_resistance_evolution.pdf. (2023). Biotechnology, "Intellectual Properties", and "Human Rights". Contact Dr. Chou for the preprint.
