| 913 - 929 |
Fibrous proteins: At the crossroads of genetic engineering and biotechnological applications
Yigit S, Dinjaski N, Kaplan DL |
| 930 - 943 |
Current and future prospects for CRISPR-based tools in bacteria
Luo ML, Leenay RT, Beisel CL |
| 944 - 952 |
Characterizing and predicting carboxylic acid reductase activity for diversifying bioaldehyde production
Moura M, Pertusi D, Lenzini S, Bhan N, Broadbelt LJ, Tyo KEJ |
| 953 - 960 |
Production in Pichia pastoris of protein-based polymers with small heterodimer-forming blocks
Domeradzka NE, Werten MWT, de Vries R, de Wolf FA |
| 961 - 969 |
Genome-scale metabolic model of Pichia pastoris with native and humanized glycosylation of recombinant proteins
Irani ZA, Kerkhoven EJ, Shojaosadati SA, Nielsen J |
| 970 - 978 |
Immobilization of enzymes using non-ionic colloidal liquid aphrons (CLAs): Activity kinetics, conformation, and energetics
Ward K, Xi JS, Stuckey DC |
| 979 - 988 |
Inactivation of nitrate reductase alters metabolic branching of carbohydrate fermentation in the cyanobacterium Synechococcus sp strain PCC 7002
Qian X, Kumaraswamy GK, Zhang SY, Gates C, Ananyev GM, Bryant DA, Dismukes GC |
| 989 - 1000 |
Assessing the influence of biofilm surface roughness on mass transfer by combining optical coherence tomography and two-dimensional modeling
Li CY, Wagner M, Lackner S, Horn H |
| 1001 - 1010 |
Linking hydrolysis performance to Trichoderma reesei cellulolytic enzyme profile
Lehmann L, Ronnest NP, Jorgensen CI, Olsson L, Stocks SM, Jorgensen HS, Hobley T |
| 1011 - 1023 |
Mechanistic modeling of enzymatic hydrolysis of cellulose integrating substrate morphology and cocktail composition
Huron M, Hudebine D, Ferreira NL, Lachenal D |
| 1024 - 1034 |
Hydrolysis of synthetic polyesters by Clostridium botulinum esterases
Perz V, Baumschlager A, Bleymaier K, Zitzenbacher S, Hromic A, Steinkellner G, Pairitsch A, Lyskowski A, Gruber K, Sinkel C, Kuper U, Ribitsch D, Guebitz GM |
| 1035 - 1045 |
Achieving complete nitrogen removal by coupling nitritation-anammox and methane-dependent denitrification: A model-based study
Chen XM, Guo JH, Xie GJ, Yuan ZG, Ni BJ |
| 1046 - 1055 |
Microscale profiling of photosynthesis-related variables in a highly productive biofilm photobioreactor
Li T, Piltz B, Podola B, Dron A, de Beer D, Melkonian M |
| 1056 - 1066 |
Engineering Rhodosporidium toruloides for increased lipid production
Zhang SY, Skerker JM, Rutter CD, Maurer MJ, Arkin AP, Rao CV |
| 1067 - 1074 |
Molecular variation of the nonribosomal peptide-polyketide siderophore yersiniabactin through biosynthetic and metabolic engineering
Ahmadi MK, Fawaz S, Fang L, Yu ZP, Pfeifer BA |
| 1075 - 1083 |
Lactic acid production from cellobiose and xylose by engineered Saccharomyces cerevisiae
Turner TL, Zhang GC, Oh EJ, Subramaniam V, Adiputra A, Subramaniam V, Skory CD, Jang JY, Yu BJ, Park I, Jin YS |
| 1084 - 1093 |
Deletion of a telomeric region on chromosome 8 correlates with higher productivity and stability of CHO cell lines
Ritter A, Voedisch B, Wienberg J, Wilms B, Geisse S, Jostock T, Laux H |
| 1094 - 1101 |
Improving expression of recombinant human IGF-1 using IGF-1R knockout CHO cell lines
Romand S, Jostock T, Fornaro M, Schmidt J, Ritter A, Wilms B, Laux H |
| 1102 - 1112 |
Dynamic metabolic flux analysis using a convex analysis approach: Application to hybridoma cell cultures in perfusion
de Sousa SF, Bastin G, Jolicoeur M, Vande Wouwer A |
| 1113 - 1123 |
Ligand-inducible dimeric antibody for selecting antibodies against a membrane protein based on mammalian cell proliferation
Miura T, Nagamune T, Kawahara M |
| 1124 - 1136 |
Assessment of nitric oxide (NO) redox reactions contribution to nitrous oxide (N2O) formation during nitrification using a multispecies metabolic network model
Perez-Garcia O, Chandran K, Villas-Boas SG, Singhal N |
| 1137 - 1147 |
Natural isotope correction of MS/MS measurements for metabolomics and C-13 fluxomics
Niedenfuhr S, ten Pierick A, van Dam PTN, Suarez-Mendez CA, Noh K, Wahl SA |
