Poster Title Index
Index of Poster Abstracts
Rapid Fire Poster Session 1 (Sunday, June 26, 2016, 6:00-6:30PM)
Order # | Title | Presenter | Page |
1 | Flux Control at the Malonyl-CoA Node through Hierarchical Dynamic Pathway Regulation in Saccharomyces Cerevisiae | Florian David | 1 |
2 | Membrane Engineering Strategies to Improve Production of Biorenewable Fuels and Chemicals | Laura Jarboe | 1 |
3 | On-Chip Analysis, Indexing and Screening for Chemical Producing Bacteria in Microfluidic Static Droplet Array | Sungho Jang | 1 |
4 | Engineering of a Novel Cellulose-Adherent Cellulolytic Saccharomyces Cerevisiae for Cellulosic Biofuel Production | Zhuo Liu | 2 |
5 | The Production of D-2,3-Butanediol and Meso-2,3-Butanediol with High Optical Purity in Engineered Bacillus Licheniformis WX02 | Qin Wang | 3 |
6 | Systems Metabolic Engineering of Corynebacterium Glutamicum for Production of Bio-Based 1,3-Propanediol from Lignocellulose | Zhen Chen and Jinhai Huang | 3 |
7 | Engineering Yeast Cell Factories for Production of High-Value Isoprenoids | Anastasia Krivoruchko | 3 |
8 | Rapid Evolution for High Performance Nano-Cellulosome By Module Library Approach | Hikaru Nakazawa | 3 |
9 | Sustainable Biorefining in Unsterilized Wastewater By Engineering of the Extreme Alkaliphile Bacillus Marmarensis | David G. Wernick | 4 |
10 | Engineering of Hydroxytyrosol Production in Escherichia coli | Erika Yoshida | 4 |
11 | Engineering Escherichia coli for the Production of Propionic Acid through the Wood-Werkman Cycle | R Axayacatl Gonzalez-Garcia | 4 |
12 | Mathematical Model Based Understanding and Engineering of the Phenylpropanoid Pathway in Arabidopsis | John A. Morgan | 5 |
13 | Rational Metabolic Engineering of Escherichia coli for Ethylene Glycol Production from D-Xylose | Kris Niño G. Valdehuesa | 6 |
14 | From Niche to Bulk - Glycolipids and Derivatives Synthesized from Sugar | Lars M. Blank | 6 |
15 | A Genetic Switch for Stable, Long-Term Fermentative Production of Anabolic Products in Yeast | Penelope Chua | 7 |
16 | Heterologous Production of n-Butanol at High Yield Using a Complete and Fully Functionnal Clostridial Pathway | Isabelle Meynial-Salles | 7 |
17 | Advances in Engineering of Bacterial Methyl Ketone Synthesis for Biofuels | Harry R. Beller | 8 |
18 | Production of Aromatics in Microbes | Shiqin Yu | 8 |
19 | Engineering Zymomonas Mobilis for the Production of Biofuels and Value-Added Chemicals | Min Zhang | 15 |
20 | Random or Targeted Genetic Approaches for the Production of Isopropanol By Clostridium Beijerinckii DSM6423 | Nicolas Lopes Ferreira | 20 |
Poster Session 1 (Sunday, June 26, 2016, 6:30-7:15PM)
| Title | Presenter | Page |
21 | Optimization of the Functional Expression of Plant Cytochrome P450s in Yeast | Lærke Marie Münter Lassen | 9 |
22 | Optimization of Displayed Cellulases in Yeast Suitable for Ionic Liquid Pretreated Biomass by Cocktail δ Integration Methodology | Chiaki Ogino | 9 |
23 | Metabolic Analysis of Antibody-Producing Chinese Hamster Ovary Cell Culture Suppressing Antibody Aggregation | Takeshi Omasa | 9 |
24 | Ethanol Production from Alkaline Pretreated Miscanthus Using Respiration-Deficient Thermotolerant Yeast | Jungwoo Yang | 10 |
25 | Retron-Based Targeted Mutagenesis Enabling In Vivo Continuous Evolution in E. coli | Xiang Zheng | 10 |
26 | An Engineered Saccharomyces Cerevisiae for Producing (S)-3-Hydroxybutyrate | Kyung Mun Cho | 10 |
27 | Production of Organic Acids in Fungal Hosts | Merja Penttilä | 10 |
28 | Characterization of a Keystone Enzyme in the Metabolism of 3,6-Anhydro-L-Galactose, a Main Sugar Component of Red Macroalgae | Sora Yu | 11 |
29 | Construction of a Corynebacterium Glutamicum Platform Strain for the Production of High-Value Plant Secondary Metabolites | Nicolai Kallscheuer
| 11 |
30 | Is Acid Pretreatment Beneficial for the Saccharification and Fermentation of Alginate from Brown Macroalgae? | Damao Wang | 12 |
31 | Diversion of Fatty Acid Synthesis Pathway of Escherichia coli for Production of Long Chain Fatty Alcohol | Zia Fatma | 12 |
32 | Can Ag43 Mediate Surface Display Efficiently in Escherichia coli? | I-Son Ng | 12 |
33 | Bioalcohol Production By Metabolically Engineered Cyanobacteria Using Photobioreactor | Jun-ichi Horiuchi | 13 |
34 | Application of Escherichia coli Coculture System for n-Butanol Production | Yun-Peng Chao | 13 |
35 | TAR1 Is Required for Artemisinin Biosynthesis and Trichome Development in Artemisia Annua L | Hexin Tan | 14 |
36 | Heterologous Expression of Cold-Adaptive Amaylase from Arthrobacter sp | Sumi Kim | 14 |
37 | Ethanol Production from Alkaline Pretreated Miscanthus Using Respiration-Deficient Thermotolerant Yeast |
| 14 |
38 | Glutamate Biosensor Based on Chimeric Two-Component Regulatory System Introduced into Escherichia coli | Jong-il CHOI | 14 |
39 | Assembly of New Minicellulosomes through Disulfide Bonds Using Yeast a-Agglutinin on Saccharomyces Cerevisiae Surface for Cellulosic Ethanol Production | Jin Hou | 14 |
40 | Hyper-Exg1 Export Promotes the Biotransformation of Mogrosides in Saccharomyces Cerevisiae kre6Δ Mutants | Reuben Wang | 15 |
41 | Production of 3-Aminopropionic Acid, a Precursor for Nylon-3 Synthesis By a Metabolically Engineered Escherichia coli | Je Woong Kim | 15 |
42 | Engineering Zymomonas Mobilis for the Production of Biofuels and Value-Added Chemicals | Min Zhang | 15 |
43 | Metabolic Engineering of Escherichia coli for Production of Tyrosine and Cadaverine through Microbial Gene Repression System Using the Synthetic Small RNAs | Hannah Chung | 16 |
44 | Diversifying the Chemical Structures of Polymer Precursors Produced in E. coli | Robert W. Haushalter | 16 |
45 | Phenol Production By Metabolically Engineered Escherichia coli | Ji Yeon Ha | 16 |
46 | Metabolic Engineering of Limonene Overproduction in the Oleaginous Yeast Yarrowia Lipolytica | Liujing Wei | 17 |
47 | Modular Pathway Rewiring of Saccharomyces Cerevisiae Enables High-Level Production of L-Ornithine | Jiufu Qin | 17 |
48 | Microbial Production of Poly(3-hydroxybutyrate-co-3-hydroxyvalerate) in Escherichia coli By a Rational Metabolic Engineering | Jung Eun Yang | 17 |
49 | Fermentative Production of Enantiomerically Pure S-1,2-Propanediol from Glucose By Engineered E. coli Strain | Bo Yu | 18 |
50 | Heterologous Biosynthesis of Plant Secondary Metabolites Derived from Phenylpropanoid and Flavonoid Pathway in Escherichia coli | Shin Hui Ha | 18 |
51 | Engineering Clostridium Thermocellum to Produce Ethanol from Cellulose at High Yield and Titer | Daniel Olson | 18 |
52 | Establishment of a Platform Strain for Production of Short-Chain Fatty Acids and Alkane through Metabolic Engineering | Yoo-Sung Ko | 18 |
53 | Productions of Fuels and Chemicals from Alginate and Mannitol, Promising Carbon Sources in Brown Macroalgae | Shigeyuki Kawai | 19 |
54 | Metabolic Engineering and Adaptive Evolution of Escherichia coli for 3-Hydroxypropionate Production Under Low pH Conditions | Baowei Wang | 19 |
55 | Random or Targeted Genetic Approaches for the Production of Isopropanol By Clostridium Beijerinckii DSM6423 | Nicolas Lopes Ferreira | 20 |
56 | Bioconversion of Methane to Butanol By Metabolic Engineering of Methanosarcina Acetivorans and Escherichia coli | Jacqueline Gonzalez | 20 |
57 | Recombinant Saccharomyces Cerevisiae Construction through Rapid DNA Assembly and Evolutionary Engineering and High-Efficiency Lignocellulose Hydrolysates Fermentation | Anli Geng | 21 |
58 | Disruption of PHO13 Improves Ethanol Production Via the Xylose Isomerase Pathway | Takahiro Bamba | 21 |
59 | Synthetic Yeast Cell Factories for High-Level Production of Oleo-Chemicals and Advanced Biofuels | Yongjin J. Zhou | 22 |
60 | Direct and High-Productive Conversion from a Cyanobacterium Arthrospira Platensis to Ethanol | Shimpei Aikawa | 22 |
61 | Re-Engineered β-Oxidation Reversal for the Synthesis of ω-Fuctionalized Carboxylic Acids in Escherichia coli | Seokjung Cheong | 22 |
62 | Selection-Based Molecular Breeding of Non-Mevalonate Pathway for Efficient Production of Terpenes | Miki Tashiro-Iwasaki | 23 |
63 | Non-Sterilized Fermentation for Ethanol or L-Lactic Acid from Waste Substrate By Metabolic Engineering of Thermoanaerobacterium Sp. strain | Muzi Zhu | 23 |
64 | Metabolic Engineering for Upgrading Isopropyl Alcohol Production By Escherichia coli Based on 13c-Metabolic Flux Data | Nobuyuki Okahashi | 24 |
65 | Metabolic Analysis of Solventogenic Clostridium Saccharoperbutylacetonicum N1-4 (HMT) | Elizabeth Saunders | 24 |
66 | Screening and Characterization of Novel Xylose Dehydrogenase for the Production of D-Xylonic Acid from D-Xylose in Escherichia coli | Kris Niño G. Valdehuesa | 25 |
67 | Metabolic Engineering in Synechocystis PCC 6803 for the Production of Butanol | Rui Miao | 25 |
68 | Pushing the Boundaries of Biofuels and Oleochemicals Production in Oleaginous Yeasts | Rodrigo Ledesma-Amaro | 25 |
69 | Characterization and Engineering of a Formaldehyde-Responsive Promoter-Regulator System for Synthetic Methylotrophy and Beyond | Nicholas R. Sandoval | 26 |
70 | Genome Sequence of a Novel Marine Strain Alg07 Gives Insight into the Degradation Pathways of Algal Polysaccharides and Monosaccharide | Yueming Zhu, Yan Men, Jiangang Yang, and Yuanxia Sun | 26 |
71 | Engineering for Efficient NADPH Cofactor Supply in Cytorchrome P450 Monoxygenase Reaction | Kwon-Young Choi | 27 |
72 | Developing Novel Pathways for Butanol Production in E. coli | Sofia Ferreira | 27 |
73 | Breeding of Homo-Butanol-Fermentative Strain Using Clostridium Saccharoperbutylacetonicum ATCC27021 | Masaharu Mukoyama | 27 |
74 | Identifying NAD-Dependent Methanol Dehydrogenases for Synthetic Methylotrophy | Robert K. Bennett | 28 |
75 | High Level 3-Hydroxypropionate Production Via Malonyl-CoA Pathway | Guang Zhao | 28 |
76 | Engineering a Short, Aldolase-Based Pathway for 1,3-Butanediol Production in Escherichia coli | Kayla Nemr | 29 |
77 | Direct Fermentation of L-Lactic Acid from Starch By Genetically Engineered Aspergillus Oryzae | Satoshi Wakai | 29 |
78 | Improved Co-Production of Hydrogen and Ethanol in Escherichia coli By the Deletion of Phosphofructokinase-1 and Activating Pentose-Phosphate Pathway | Balaji Sundara Sekar | 30 |
79 | Simultaneous Co-Fermentation of Glucose and Xylose By Single and Mixed Cultures of Engineered Yeast | Yong-Su Jin | 30 |
80 | Protein Engineering for the Production 5-Hydroxytrypophan and Serotonin in Escherichia coli | J. Aníbal Mora-Villalobos | 30 |
81 | Correlation of the Nifh gene Expression and a Metabolic Model for the Hydrogen Production By a Phototropic Mixed Culture | Victor H. Jurado Marbán | 31 |
82 | Discovery and Evaluation of Novel Pathways for Production of the Second Generation of Biofuels | Milenko Tokic | 31 |
83 | Systems-Level Analysis of Saccharomyces Cerevisiae Engineered for Production of 3-Hydroxypropionic Acid | Kanchana R. Kildegaard | 32 |
84 | Engineering Clostridium beijerinckii for Butanol Production from Corn Cob | Tianrui Zhang | 32 |
85 | Caffeic Acid Production By Simultaneous Saccharification and Fermentation of Kraft Pulp Using Recombinant Escherichia coli | Hideo Kawaguchi | 33 |
86 | Enhanced Enzyme Stability through Fusion of Self-Assembled Cellulose Binding Domain | Moonjung Kim | 33 |
87 | The DOE JGI DNA Synthesis Science Program | Yasuo Yoshikuni | 33 |
88 | Molecular Toolbox for Co-Expression of Chaperones for Heterologous Protein Production in Lactic Acid Bacteriametabolic Engineering XI: Design, Synthesis and System Integration for Metabolic Engineering | Dave Siak-Wei Ow | 34 |
89 | Enhanced Solvents Production in Consolidated Bioprocessing Consortia By Promotion of Metabolites Exchange Via Modules Metabolic Engineering | Zhiqiang Wen | 34 |
90 | Engineering Zymomonas Mobilis for the Production of Biofuels and Value-Added Chemicals | Min Zhang | 35 |
91 | Metabolic Engineering of Anaerobic Itaconate Production in E. coli | Ruud Weusthuis | 35 |
92 | Escherichia coli Chromosomal Engineering Toward High Titer Phenylalanine and Tyrosine Production | Daisuke Koma | 35 |
93 | Isotopically Nonstationary 13c-Metabolic Flux Analysis Under Photoautotropic Conditions for a Glycogen Mutant of Synechococcus Sp. PCC 7002 | Pramod P. Wangikar | 36 |
Rapid Fire Poster Session 2 (Monday, June 27, 2016, 4:30-5:30PM)
Order # | Title | Presenter | Page |
1 | Gamma-Aminobutyric Acid Production Via GABA Shunt By the Introduction of Synthetic Scaffolds in Recombinant Escherichia coli | Soonho Hong | 37 |
2 | Iso-Propanol Production By Engineered Cyanobacteria, Synechococcus Elongatus pcc 7942 | Yasutaka Hirokawa | 37 |
3 | Developing Genome Editing Tools for Thermophilic Bacilli | Ioannis Mougiakos | 37 |
4 | Computational Design Strategies for Synthesizing Fusion Proteins and Enhancing Their Expression | Dong-Yup Lee | 38 |
5 | A Glucose-Sensing Toggle Switch Enables Autonomous Control That Improves Production but Avoids Growth-Toxicity | William Bothfeld | 38 |
6 | Enhanced Integration of Large DNA into E. coli Chromosome By Crispr/Cas9 | Hung Li | 38 |
7 | Fluorescent Biosensors for In Vivo Single-Cell Analysis of the Physiology of Saccharomyces Cerevisiae | Daniel P. Brink | 39 |
8 | Advances in Genome Engineering Techniques Enable Fast and Efficient Construction of Microbial Cell Factories | Tadas Jakociunas | 39 |
9 | Expanding the Substrate Range and Product Portfolio of Y. Lipolytica through Metabolic Pathway Engineering and Synthetic Biology Tool Development | Kelly Markham | 39 |
10 | Expression of Native-Sized Spider Silk Protein in Escherichia coli through Metabolic Engineering and Synthetic Biology Approach | Hannah Chung | 40 |
11 | A Metabolic Valve of Glycolytic Flux for the Design of Optimal Cell Factory | Jae Hyung Lim | 40 |
12 | Powering Nitrogen Fixation: the Metabolism of the Aerobic Diazotroph, Azotobacter Vinelandii, As Revealed By 13c-Metabolic Flux Analysis | Camil A. C. Diaz | 40 |
13 | Multiple Gene Repression in Cyanobacteria Using Crispri | Lun Yao | 41 |
14 | Deriving Consistent Core Models from Genome-Scale Metabolic Networks and Their Application for Computing Metabolic Engineering Targets | Oliver Hädicke | 41 |
15 | Identification and Engineering of n-Butanol Biosensors By Transcriptome Analysis in Yeast | Shuobo Shi | 42 |
16 | How Uncertainty in Kinetic Parameters Affects Metabolic Control Analysis of Optimally Grown E. coli | Tuure Hameri | 43 |
17 | Bioengineering Magnetic Nanoparticles in Magnetotactic Bacteria | Maiko Furubayashi | 43 |
18 | The Second Generation Ogab Method Makes It Feasible for Assembly More Than 50 DNA Fragments at One-Step | Kenji Tsuge | 44 |
19 | Mining Metabolism for Unannotated Enzymatic Functions and Serendipitous Metabolic Pathways | James Jeffryes | 44 |
20 | Ensemble Modeling of Cyanobacteria Metabolism Using Multi-Omics Data | Fumio Matsuda | 45 |
21 | Engineering of an NADPH/NADP+ Redox Sensor in Yeast | Jie Zhang | 45 |
22 | The Genome-Scale Metabolic Model for Chlorella vulgaris Utex 395 Reveals Quantitative Flux Distributions for Compartmental-Pathway Activity Under Polytrophic Growth | Cristal Zuniga P
| 46 |
23 | Creation of Novel Allosteric Regulation of Proteins for Synthetic Biology Based on a New Concept of Thermodynamic Model | An-Ping Zeng | 46 |
24 | Development of Selection Method for Directed Evolution of Genetic Switches in Saccharomyces Cerevisiae | Masahiro Tominaga | 46 |
25 | Approaches to Improve the Titers of Natural Products in E. coli | J. Andrew Jones | 47 |
26 | How Much Is It? Predicting Enzyme Costs with a Genome Scale Model of Yeast: Applications to Metabolic Engineering | Benjamín J. Sánchez | 47 |
27 | Growth-Coupled Fermentation Predicted By Next-Generation Genome-Scale Models | Zachary A. King | 48 |
28 | Engineering the Spliceosome of Saccharomyces Cerevisiae to Splice Heterologous Introns from Distant Fungi | Anthony B. DeNicola | 48 |
29 | Crispri-Guided Balancing of a Biosynthetic Pathway Increases Terpenoids Production | Dae-Hee Lee | 48 |
30 | Synbio-Guided Metabolic Taming of Pseudomonas Putida | Pablo I. Nikel | 49 |
31 | Orthogonal Design of Metabolic Pathways | A. Vikram Pandit | 49 |
32 | Performance Comparison of Two Biosensor-Guided Evolutionary Genetic Circuits on the Improvement of Metabolic Production at the Genomic Level | Yinan Wu | 50 |
33 | Identifying and Producing Precursors to Commercial Chemical Products | Jennifer L. Reed | 50 |
34 | Cell-Free Biosynthesis of Complex Molecules Using Designed and Tailored Permeabilized Cells | Elmar Heinzle | 51 |
35 | Harnessing the Crispr/dCas9 Crispri System for Rapid Assessment of Metabolic Engineering Strategies to Improve Natural Product Titers in E. coli | Brady F. Cress | 51 |
36 | Crispr-Cas Assisted Metabolic Engineering of Lipid Metabolism in Saccharomyces Cerevisiae | Raphael Ferreira | 52 |
37 | Sugar Synthesis from CO2 in E. coli | Niv Antonovsky | 52 |
38 | Metagenomic Data to Molecules: Novel Metabolites Identified from the Human Gut Microbiome | Fang-Yuan Chang | 52 |
39 | Synthetic Biology in the Design of Versatile Expression Systems in Synechocystis Sp. PCC 6803 | Kati Thiel and Edita Mulaku | 53 |
40 | Rational and Evolutionary Engineering of Industrial Saccharomyces Cerevisiae Strains for Production of Chemicals from Xylose-Rich Feedstocks | Vratislav Stovicek | 53 |
Poster Session 2 (Monday, June 27, 2016, 5:30-7:00PM)
| Title | Presenter | Page |
41 | Combining Metabolic Engineering and Biocompatible Chemistry for High-Yield Production of Homo-Diacetyl and Homo-(S,S)-2,3-Butanediol | Jianming Liu | 54 |
42 | Metabolic Engineering of Saccharomyces Cerevisiae for Production of Short / Medium Chain Fatty Acids | Zhiwei Zhu | 54 |
43 | Total Biosynthesis of Opiates By Engineered Escherichia coli | Akira Nakagawa | 54 |
44 | Construction of Platform Strains Producing Cosmeceutical Materials with Yarrowia Lipolytica | Byung Jo Yu | 54 |
45 | Itaconic Acid and Beyond: New Insights into the Itaconic Acid Production Pathway of Ustilago Maydis | Nick Wierckx | 55 |
46 | Engineering Escherichia coli for High Selective Production of Butyric Acid | Chung Jen Chiang | 55 |
47 | Metabolic Engineering to Produce Rosmarinic Acid in Baker´s Yeast Saccharomyces Cereviciae | Gheorghe Manuel Borja Zamfir | 56 |
48 | Metabolic Pathways of Alginate-Derived Monomers in the Marine Bacterium Saccharophagus Degradans 2-40T | Do Hyoung Kim | 56 |
49 | Chassis Optimization for Recombinant Rhamnolipid Synthesis | Till Tiso | 56 |
50 | 20 Years After Launch: 13C Metabolic Flux Analysis Becomes Visual | Wolfgang Wiechert | 57 |
51 | 13C-Metabolic Flux Analysis at Its Limits: Identifiability of Anaplerotic Reactions in Corynebacterium Glutamicum | Wolfgang Wiechert | 57 |
52 | Engineering Biofuel Tolerance Using Efflux Pumps | Georg Basler | 58 |
53 | Microbial Cell Factory for C5 Platform Chemicals: Aminovalerate and Glutarate | Tong Un Chae | 58 |
54 | Model-Based Metabolic Engineering of Escherichia coli for High Yield Itaconic Acid Production | Björn-Johannes Harder | 58 |
55 | In Vitro Metabolic Pathway for the Salvage Synthesis of Nicotinamide Cofactor | Kohsuke Honda | 59 |
56 | Engineering Lipid Homeostasis Mechanisms for an Efficient Production of Fatty Acid-Derived Chemicals in S. Cerevisiae | Paulo G. Teixeira | 59 |
57 | A Synthetic Biology Approach to Enhancing Metabolic Engineering of Clostridium Acetobutylicum | Pawel Mordaka | 59 |
58 | Rational Modular Design of Yeast Strains Towards Overproduction of Industrially Relevant Products | Helder Lopes | 60 |
59 | A Hierarchy of Modeling Frameworks for Cyanobacterial Metabolism: From Gsms to ME Models | Costas D. Maranas | 60 |
60 | Heuristic Design and Engineering of pH-Inducible Yeast Promoters | Arun S. Rajkumar | 61 |
61 | Production of Sphingolipids By Metabolically Engineered Escherichia coli | Ji Yeon Ha | 61 |
62 | Metabolic Engineering of Mannheimia Succiniciproducens for the Production of Gamma-Butyrolactone | Won Jun Kim | 61 |
63 | Metabolic Engineering of Ralstonia Eutropha for the Biosynthesis of Polyhydroxyalkanoates from Sucrose | Jung Eun Yang | 62 |
64 | Elementary Mode Analysis for Efficient Succinic Acid Production in Mannheimia Succiniciproducens | Won Jun Kim | 62 |
65 | Convergent Rapid Evolution of Fructose Operon Reveals Its Important Role in Sugar Uptake and Its Effect on Lysine Production | Zhihao Wang | 62 |
66 | Characterization of the Eucalyptus grandis Terpenome Using Engineered Yeast Strains | Rachel Li | 63 |
67 | Cameo: A Python Library for Computer Aided Metabolic Engineering and Optimization of Cell Factories | João G.R. Cardoso | 63 |
68 | Combinatorial Design of Biosynthetic Pathways for the Generation of Beta-Arylamines | Robert Warden-Rothman | 63 |
69 | Design of Novel Biosynthetic Pathways for the Production of Industrially Valuable Chemicals | Dong In Kim | 64 |
70 | Homo-Organic Acid Production with Minimal Byproducts through Multi-Objective Optimization of Microbial Metabolism | Dong In Kim | 64 |
71 | 3’ UTR Engineering to Improve Functional Expression of Insoluble and/or Structurally Unstable Enzymes and Proteins in Escherichia coli | Jin-Byung Park | 64 |
72 | Production of Astaxanthin Using Isoprenoid Pathways in Metabolically Engineered Escherichia coli | Seon Young Park | 65 |
73 | Production of Fumaric Acid from Glucose By a Metabolically Engineered Escherichia coli | Je Woong Kim | 65 |
74 | Predictive Pathogen Biology: Genome-Based Prediction of Pathogenic Potential and Countermeasures Targets | Debjit Ray | 65 |
75 | Marker-Free Crispr/Cas9 Based Genome Editing of Penicillium Chrysogenum | Yvonne Nygård | 66 |
76 | Disruption of the Butyrate Kinase (buk) Gene Is Vital for the High Butyric Acid Selectivity in Clostridium Acetobutylicum | Shin Hui Ha | 66 |
77 | Modulation of Carbon Preference in Enterobacter Aerogenes for Efficient Utilization of Sugarcane Molasses for 2,3-Butanediol Production | Moo-Young Jung | 66 |
78 | Engineering Bacterial Biocatalysts for the Production of Polyhydroxyalkanaote Biopolymers | Christopher Nomura | 67 |
79 | Bringing Ethyl Acetate Production into the Biobased Economy | Aleksander Kruis | 67 |
80 | A Simple Metabolic Flux Balance Analysis of Biomass and Bioethanol Production in Kluyveromyces Marxianus ATCC 26548 Batch Culture | Khairiah Abd Karim | 67 |
81 | Rational Design of Spider Silk-Based Biomaterials | Zhi-Gang Qian | 68 |
82 | Production of Acrylic Acid By Metabolically Engineered Escherichia coli | Yoo-Sung Ko | 68 |
83 | Metabolic Engineering of Escherichia coli for the Production of 2-Hydroxyacids Containing Polyhydroxyalkanoates | So Young Choi | 68 |
84 | Engineering of a Cell Factory That Can Utilizing the Biomass for Biochemical Production | Qingsheng Qi | 69 |
85 | Understanding Thermotolerance of Kluyveromyces Marxianus: A Constraint-Based Modelling Approach | Simonas Marcisauskas | 69 |
86 | Metabolic Engineering for Chemicals Production By Solving Reducing Equivalent Problems | Xueli Zhang | 69 |
87 | Metabolic Flux Rewiring and Physiology in E. coli Upper Central Carbon Metabolism Knockout Strains | Christopher P. Long | 69 |
88 | Phylogenetic and Molecular Dynamics Simulation of 3D-Structures of [Nifese] Hydrogenase: The Biological Relevance to Their Gas Cavity Development | Takashi Tamura | 70 |
89 | Development of Pantoea species As a Platform for the Production of High Value Terpenoids | James Williamson | 70 |
90 | Elucidation of Clostridium Acetobutylicum metabolism Using Parallel Labeling Experiments and 13c Metabolic Flux Analysis | Jennifer Au | 71 |
91 | Genome-Scale Modeling Coupled with Crispri for Improving Biofuel Production in Cyanobacteria | Kiyan Shabestary | 71 |
92 | Biosynthesis of a Novel Terpolymer P(LA-co-3HB-co-3HP) from Unrelated Carbon Source | Yilin Ren | 71 |
93 | Synthetic Transcription Regulation System for Orthogonal Control of Gene Expression | Jussi Jantti | 72 |
94 | Metabolic Engineering for the Production of Diverse Polyhydroxyalkanoates in Escherichia coli | So Young Choi | 72 |
95 | 1-Propanol Production of S. Cerevisiae Engineering 2-Ketobutyrate Biosynthetic Pathway | Yuya Nishimura | 73 |
96 | Biosynthesis of Tetrahydrocannabinolic Acid - from Biotransformation Studies to Biotechnological Production | Oliver Kayser | 73 |
97 | Efficient Fermentative Production of Polymer-Grade D-Lactate By an Engineered Alkaliphilic Bacillus | Yanfen Xue | 74 |
98 | Effective Estimation of Dynamic Metabolic Fluxes Using 13c Labeling and Piecewise Affine Approximation: From Theory to Practical Applicability | Robin Schumacher | 74 |
99 | A Hacked 3D Printer Towards the Printing of Materials through Biological Organisms | Lina M. González | 74 |
100 | Re-Assemblying the Peptidoglycan for Enhanced Production of Polyhydroxyalkanoates | Xingchen Zhang | 75 |
101 | Novel in silico Molecular Modeling for the Enhancement of Enzyme Activity | Ji-Yeun Yi | 75 |
102 | Analysis and Design of Metabolic Engineering and Synthetic Biology Strategies Using Large Scale Dynamic Models of Metabolism | Geogios Fengos | 75 |
103 | Metabolite-Centric Flux Analysis for Rational Design and Engineering of Microbes | Meiyappan Lakshmanan | 76 |
104 | Production of Short Chain Butyl Esters By E. coli As a Strategy for Butanol Extraction | Micaela Chacón | 76 |
105 | Metabolic Network of Synechococcus Sp PCC 7002: Genome Scale Metabolic Model, Flux Analysis and Network Modifications for Biofuel Production | John I Hendry | 76 |
106 | Computational Tools for the Synthetic Biology of Natural Products | Rainer Breitling | 77 |
107 | Metabolic Engineering of an Acid-Tolerant Yeast Pichia Kudriavzevii NG7 for Gypsum-Free Production of D-Lactic Acid | Hyun Joo Park | 77 |
108 | In Vivo Activation of Apo-Hydrogenases Using Synthetic Analogues of the Active Site | Namita Khanna | 77 |
109 | Production of 3-Hydroxypropionic Acid from Glycerol By Metabolically Engineered Klebsiella Pneumoniae L17 in Bioelectrochemical System | Changman Kim | 77 |
110 | Pyruvic Acid Production Using Thermotolerant Halomonas sp. KM-1 | Yoshinao Azuma | 78 |
111 | Development of Shewanalla Oneidensis MR-1 for Bioelectricity Generation from Glycerol: Induction of Glycerol Uptake Module | Mi-yeon Kim | 78 |
112 | Yeast Cell Factories for Production of Taxadiene | Hulya Karaca Gencer | 79 |
113 | Computational Pathway Design for Efficient Bio-Production during Stationary Phase | Yoshihiro Toya | 79 |
114 | Integration of Quality By Design, Programming Languages, and Cross-Platform Automation for Closing the Design, Build, Test Cycle in Metabolic Engineering | Chris Grant | 80 |
115 | Metabolic Engineering of Clostridium Acetobutylicum with CoA Metabolite Analysis for Enhanced Butanol Production | Sang-Hyun Lee | 80 |
116 | A Multi-Scale, Multi-Disciplinary Approach for Assessing the Technological, Economic, and Environmental Performance of Bio- Based Chemicals | Miguel A. Campodonico | 81 |
117 | Metabolic Engineering for Co-Production of Fuels and Chemicals Using a Single Microorganism | Sunghoon Park | 81 |
118 | Isoprene Production By Coupling Methylerythritol Phosphate and Mevalonate Pathway in Escherichia coli | Yu Jiang | 81 |
119 | Multiscale Design of Cell Factories | Markus J. Herrgård | 82 |
120 | Construction of Highly Efficient Expression Systems in Halomonas Based on Orthogonal Transcriptional Machinery | Han Zhao | 82 |
121 | Heterologous Biosynthesis and Omics-Guided Metabolic Engineering for Overproduction of Spinosad in Streptomyces | Gao-Yi Tan | 82 |
122 | Identifying Patterns in Kinetic Parameters That Determine the Impact of Rate-Limiting Enzymes | Ljubisa Miskovic | 82 |
123 | A Linear-Programming Based Modeling Strategy for Capturing Metabolite Dynamics and Metabolite-Dependent Regulation for Genome-Scale Metabolic Modeling | Robert Dromms | 83 |
124 | Microbial Block Copolymerization of 3-Hydroxyalkanoates | Xiangbin Chen | 83 |
125 | Engineering Lactococcus Lactis for the Synthesis of Plant Polyphenols | Paula Gaspar | 84 |
126 | Poly(3-hydroxybutyrate-co-4-hydroxybutyrate) Production By Halomonas TD01 in Continues and Open Fermentation Process with Low Sodium Concentration | Jianwen Ye | 84 |
127 | "Metabolic Engineering of Bacillus Subtilis for the Production of 3-Hydroxypropionic Acid" | Aida Kalantari | 84 |
128 | Characterization of UDP-Glycosyltransferase Bioparts and Metabolic Engineering of Saccharomyces Cerevisiae to Produce Bioactive Rare Ginsenosides | Pingping Wang | 85 |
129 | A Widget-Based Data-Analytic Metabolomics Pipeline | Soha Hassoun | 85 |
130 | Engineering of Glycolytic Pathway for Production of Isobutanol in Cofactor-Balanced Manner | Hwimin Jung | 86 |
131 | Optimization of Phenylpropanoid Production in Saccharomyces Cerevisiae through Disruption of Double Bound Reductase Activity | Beata Joaanna Lehka | 86 |
132 | A Synthetic Biology Approach for the Design of Flexible and Efficient Production Platforms in Synechocystis Sp PCC6803 | Hariharan Dandapani | 87 |
133 | Sisbi: Software to Aid the Industrial Biotechnology Decision Process | Simão Soares | 87 |
134 | Metabolic Engineering of Pseudomonas Putida KT2440 for Complete Mineralization of Methyl Parathion and Gamma-Hexachlorocyclohexane | Ting Gong | 87 |
135 | Metabolic Engineering of Yarrowia Lipolytica for Value-Added Products Synthesis from Glycerol | Aleksandra Maria Mironczuk | 87 |
136 | Metabolic Engineering of Cupriavidus Necator for Heterotrophic and Autotrophic Alka(e)Ne Production | Lucie Crépin | 88 |
137 | Engineering Yeast for Production of Glycolic Acid | Outi Koivistoinen | 88 |
138 | Understanding the MEP Pathway for the Production of Terpenoids | Daniel Volke | 88 |
139 | Enhanced Production of Lipids from Glycerol By Engineered Yeast Yarrowia Lipolytica | Adam Dobrowolski | 89 |
140 | Efficient Bioproduction By Psychrophile-Based Simple Biocatalysts | Takahisa Tajima | 89 |
141 | Substrate Channeling for the Production of 2,3-Butanediol in Saccharomyces Cerevisiae | Sujin Kim | 90 |
142 | Transcriptional and Translational Regulation of Enzymes Involved in 3-Hydroxypropionic Acid Production Using Synthetic Cassette Architecture | Mugesh Sankaranarayanan | 90 |
143 | Enhancement of Protocatechuate Decarboxylation for the Effective Production of Muconic Acid from Renewable Feedstocks | Tomonori Sonoki | 90 |
144 | An Engineered E. coli Platform for Production of Chemicals from Renewable Oils | Martin Gustavsson | 91 |
145 | Co-Production of 3-Hydroxypropionic Acid and 1,3-Propanediol Using Glycerol By Klebsiella Pneumoniae J2B: Reduction of Carbon Traffic at Pyruvate Node | Yeounjoo Ko | 91 |
146 | Synthetic Promoter Systems for Controlling Saccharomyces Cerevisiae Gene Expression | Robert Sidney Cox III | 92 |
147 | Production of Itaconic Acid By Enhancing Functional Expression of Cada in Escherichia coli | Jong Hyun Choi | 92 |
148 | Mmsr-Mediated 3-Hydroxypropionic Acid-Inducible Gene Expression System of Pseudomonas Denitrificans | Nam Hoai Nguyen | 92 |
149 | Engineering Escherichia coli for Terminal (ω) - Functionalized Long Chain Dicarboxylic Acids Production from Renewable Fatty Acids and Plant Oils | Sathesh-Prabu Chandran | 93 |
150 | Unraveling the Metabolic Interactions in Plasmodium Falciparum Using a Novel Genome-Scale Model Reconstruction | Anush Chiappino Pepe | 93 |
151 | Design of a Cost-Effective Strategy for Secretory Production of Recombinant CCN Proteins By Mammalian Cells | Shr-Jeng Jim Leu | 94 |
152 | Construction of Saccharomyces Cerevisiae Cell Factory for β-Amyrin Production | Ming Zhu | 94 |
153 | Redgem and Lumpgem: Systematic Approaches for Reduction of Genome-Scale Metabolic Models | Meric Ataman | 95 |
154 | "ATLAS of Biochemistry", a Repository of All Possible Biochemical Reactions for Synthetic Biology and Metabolic Engineering Studies | Jasmin Hafner | 95 |
155 | Development and Application of Metabolic Network Models | Qiang Hua | 96 |
156 | Kinetic Modeling of Metabolism in Obligatory Anaerobes | Costas Maranas | 96 |
157 | Tracing Optimal Conversion Stoichiometries Using Native and Novel Biotransformation | Costas D. Maranas | 97 |
158 | Efficient 3-Hydroxypropionic Acid Production from Glycerol Using Metabolically Engineered Klebsiella Pneumonia | Hui Wu and Zhimin Li | 97 |
159 | Bacterial Fermentation Platform for Producing Artificial Aromatic Amines and Its Utilization for High-Performance Aromatic Polyamide Synthesis | Shunsuke Masuo | 97 |
160 | Metabolic Engineering and Synthetic Biological Approach for Enhancing and Structurally Modulating Nargenicin A1 from Nocardia Sp. CS682 | Dipesh Dhakal | 98 |
161 | Application of Synthetic Biology for the Production of Flavonol Glycosides in Escherichia coli | Prakash Parajuli | 98 |
162 | Optimization of the Production of Butanol in Recombinant Pseudomonas Putida Using Large-Scale Kinetic Models | Milenko Tokic | 99 |
163 | Overexpression Self-Repressing Regulator Dnro Enhances Production of Daunorubicin in Blda Deficient Streptomyces Peucetius ATCC 27952 | Anaya Raj Pokhrel | 99 |
164 | Principal Studies on the Scopolamine Biosynthesis in Duboisia Spp. for Heterologous Reconstruction of Tropane Alkaloid Biosynthesis | Oliver Kayser | 99 |
165 | Functional Characterization of NES and GES, Nerolidol Synthase and Geranyllinalool Synthase Responsible for the Formation of the Homoterpene Volatiles in Tripterygium Wilfordii | Ping Su | 100 |
166 | β-Keto Acids Platform for Ketones and Alcohols Production in Saccharomyces Cerevisiae | Zongjie Dai | 100 |
167 | Production of Sulfated Organic Compounds in Cell Factories | Christian B. Jendresen | 101 |
Rapid Fire Poster Session 3 (Tuesday, June 28, 2016, 4:30-5:30PM)
Order # | Title | Presenter | Page |
1 | Construction of Novel Synthetic Heterologous Pathway for the Production and Polymerization of Green Biodegradable Polyester Precursors By Corynebacterium Glutamicum | Meerza A. Razak | 102 |
2 | Construction of a Single-batch Fermentation System to Simulate Human Intestinal Microbiota | Kengo Sasaki | 102 |
3 | Characterization of Physiological and Transcriptional Properties of Improved Protein Secretion Yeast Strains | Mingtao Huang | 103 |
4 | Industrial Strain Improvement for Food Functionality | Ana Rute Neves | 103 |
5 | Reducing Exogenous Enzyme Requirements in Biofuels Production By Metabolic Engineering | Deepak Kumar | 103 |
6 | Harnessing Sigma Factor Gene Overexpression for Production By Corynebacterium Glutamicum | Hironori Taniguchi | 104 |
7 | Prediction of Stress Resistance By Gene Expression Profiles | Chikara Furusawa | 104 |
8 | (13)C-Metabolic Flux Analysis of Ethanol-Assimilating Saccharomyces Cerevisiae for S-Adenosyl-L-Methionine Production | Kenshi Hayakawa | 105 |
9 | Elucidating Flux Coupling Relationships in Xylose Fermentation By Scheffersomyces Stipitis Via Fluxomics | Meng Liang | 105 |
10 | Advancing Dual-Phase Production Strategies with Corynebacterium Glutamicum through Systems Biology | Julian Lange | 106 |
11 | Regulation of Cyanobacteria in Producing Fuels and Chemicals | Weiwen Zhang | 106 |
12 | Effective Analysis and Application of Fungal Secondary Metabolism Gene Clusters | Masayuki Machida | 106 |
13 | Robust Identification of Metabolic Engineering Targets Via Pool Efflux Capacities (PECs) | Ralf Takors | 107 |
14 | Metabolic Engineering of Cyanobacteria Using Genome-Scale Modeling and Crispri | Paul Hudson | 107 |
15 | From Gene to Activity - Exploring the Potential of the Nestlé Culture Collection | Christoph J. Bolten | 107 |
16 | Metabolically Engineered Escherichia coli for Renewable Production of a Three Carbon Diamine, 1,3-Diaminopropane | Tong Un Chae | 108 |
17 | Design, Construction, and Validation of Modular Chassis Cells for Efficient Combinatorial Biosynthesis of Chemicals | Cong T. Trinh | 108 |
18 | An LC-MS/MS and Modeling Method for Increased Precision and Scope of Directly Measurable Fluxes at a Genome-Scale | Douglas McCloskey | 108 |
19 | Building a C1 Gas Fermentation Platform for Sustainable Chemicals: A Systems Metabolic Engineering Approach | Esteban Marcellin | 108 |
20 | Genome-Wide Identification of Genes Involved in NADPH Supply | Lumeng Ye | 109 |
21 | Production of Specialized Fatty Acids in Saccharomyces Cerevisiae | Ângela de Carvalho | 109 |
22 | With Atmospheric Room Temperature Plasma (ARTP) Mutagenesis to Screening the Spirulina Platensis Mutant Strains and Omics Analysis | Nan Su | 110 |
23 | Biosensor-Driven Adaptive Laboratory Evolution of Amino Acid Production in Corynebacterium Glutamicum | Julia Frunzke | 110 |
24 | A Toolbox for Accelerating Strain Engineering of Oleaginous Yeast Yarrowia Lipolytica | Carina Holkenbrink | 110 |
25 | Production of Terpenoids in Escherichia coli: Optimizing the Metabolic Network and the Production Process | Miguel Angel Valderrama-Gomez | 111 |
26 | Modulating Flux-Competing Enzyme Squalene Synthase By Protein Degradation Mechanism to Improve Sesquiterpene Production in Saccharomyces Cerevisiae | Bingyin Peng | 111 |
27 | 3-Amino-4-Hydroxy Benzoic Acid Production Via 3,4-AcAHBA in Escherichia coli | Alexander Krylov and Yousuke Nishio | 112 |
28 | Engineering Key Functions Conferring Cellular Robustness: Detoxification, Membrane Permeability and Protective Metabolites in Yeast | Maurizio Bettiga | 112 |
29 | Design of a Bio-Based Adipic Acid Microbial Cell Factory: The Challenging Choice of Microbial Host and Metabolic Pathway | Emma Karlsson | 112 |
30 | A Novel, Ultra-Sensitive Multiple Input-Output System for Target Identification in Systems Metabolic Engineering of E. coli | Lifu Song | 113 |
31 | Development of Mini-Bioreactors for Evolution of Thermotolerance | Mathias Lehnen | 113 |
32 | Matching the Demand of Protein Production By Metabolic Engineering of the Central Metabolism: Lessons Learned from Cofactor and Amino Acid Metabolism in Yeasts | Diethard Mattanovich | 114 |
33 | Synthetic Rescue Couples NADPH Generation to Metabolite Overproduction in Saccharomyces Cerevisiae | Siavash Partow | 114 |
34 | An Evolutionary Approach for Development of Novel Riboswitches with Desired Dose-Response Curve | Sungyeon Jang | 115 |
35 | Engineering Genome-Reduced Corynebacterium Glutamicum for Isoprenoid Production | Petra Peters-Wendisch | 115 |
36 | A Novel Role for Enzyme I of the PTS System in E. coli during Growth on Both Glycolytic and Gluconeogenic Substrates | Christopher P. Long and Jennifer Au | 116 |
37 | Engineering and Analyzing Streptomyces strain for... |