172 related articles for article (PubMed ID: 31550137)
41. Engineering of multiple modular pathways for high-yield production of 5-aminolevulinic acid in Escherichia coli.
Zhang J; Weng H; Zhou Z; Du G; Kang Z
Bioresour Technol; 2019 Feb; 274():353-360. PubMed ID: 30537593
[TBL] [Abstract][Full Text] [Related]
42. Facile Expansion of the Variety of Orthogonal Ligand/Aptamer Pairs for Artificial Riboswitches.
Ogawa A; Inoue H; Itoh Y; Takahashi H
ACS Synth Biol; 2023 Jan; 12(1):35-42. PubMed ID: 36566430
[TBL] [Abstract][Full Text] [Related]
43. Engineering and characterization of fluorogenic glycine riboswitches.
Ketterer S; Gladis L; Kozica A; Meier M
Nucleic Acids Res; 2016 Jul; 44(12):5983-92. PubMed ID: 27220466
[TBL] [Abstract][Full Text] [Related]
44. Development of Artificial Riboswitches for Monitoring of Naringenin In Vivo.
Jang S; Jang S; Xiu Y; Kang TJ; Lee SH; Koffas MAG; Jung GY
ACS Synth Biol; 2017 Nov; 6(11):2077-2085. PubMed ID: 28749656
[TBL] [Abstract][Full Text] [Related]
45. RNA aptamers as genetic control devices: the potential of riboswitches as synthetic elements for regulating gene expression.
Berens C; Groher F; Suess B
Biotechnol J; 2015 Feb; 10(2):246-57. PubMed ID: 25676052
[TBL] [Abstract][Full Text] [Related]
46. Design criteria for synthetic riboswitches acting on transcription.
Wachsmuth M; Domin G; Lorenz R; Serfling R; Findeiß S; Stadler PF; Mörl M
RNA Biol; 2015; 12(2):221-31. PubMed ID: 25826571
[TBL] [Abstract][Full Text] [Related]
47. Next-level riboswitch development-implementation of Capture-SELEX facilitates identification of a new synthetic riboswitch.
Boussebayle A; Torka D; Ollivaud S; Braun J; Bofill-Bosch C; Dombrowski M; Groher F; Hamacher K; Suess B
Nucleic Acids Res; 2019 May; 47(9):4883-4895. PubMed ID: 30957848
[TBL] [Abstract][Full Text] [Related]
48. A real-time control system of gene expression using ligand-bound nucleic acid aptamer for metabolic engineering.
Wang J; Cui X; Yang L; Zhang Z; Lv L; Wang H; Zhao Z; Guan N; Dong L; Chen R
Metab Eng; 2017 Jul; 42():85-97. PubMed ID: 28603040
[TBL] [Abstract][Full Text] [Related]
49. Engineering Escherichia coli for efficient coproduction of polyhydroxyalkanoates and 5-aminolevulinic acid.
Zhang X; Zhang J; Xu J; Zhao Q; Wang Q; Qi Q
J Ind Microbiol Biotechnol; 2018 Jan; 45(1):43-51. PubMed ID: 29264661
[TBL] [Abstract][Full Text] [Related]
50. The dynamic nature of RNA as key to understanding riboswitch mechanisms.
Haller A; Soulière MF; Micura R
Acc Chem Res; 2011 Dec; 44(12):1339-48. PubMed ID: 21678902
[TBL] [Abstract][Full Text] [Related]
51. Aptazyme-based riboswitches and logic gates in mammalian cells.
Nomura Y; Yokobayashi Y
Methods Mol Biol; 2015; 1316():141-8. PubMed ID: 25967059
[TBL] [Abstract][Full Text] [Related]
52. A Glycine Riboswitch in
Khani A; Popp N; Kreikemeyer B; Patenge N
Front Microbiol; 2018; 9():200. PubMed ID: 29527194
[TBL] [Abstract][Full Text] [Related]
53. FRET-based optical assay for selection of artificial riboswitches.
Harbaugh SV; Chapleau ME; Chushak YG; Stone MO; Kelley-Loughnane N
Methods Mol Biol; 2014; 1111():77-91. PubMed ID: 24549613
[TBL] [Abstract][Full Text] [Related]
54. Ligand-induced conformational capture of a synthetic tetracycline riboswitch revealed by pulse EPR.
Wunnicke D; Strohbach D; Weigand JE; Appel B; Feresin E; Suess B; Müller S; Steinhoff HJ
RNA; 2011 Jan; 17(1):182-8. PubMed ID: 21097555
[TBL] [Abstract][Full Text] [Related]
55. Modular riboswitch toolsets for synthetic genetic control in diverse bacterial species.
Robinson CJ; Vincent HA; Wu MC; Lowe PT; Dunstan MS; Leys D; Micklefield J
J Am Chem Soc; 2014 Jul; 136(30):10615-24. PubMed ID: 24971878
[TBL] [Abstract][Full Text] [Related]
56. Tuning riboswitch-mediated gene regulation by rational control of aptamer ligand binding properties.
Rode AB; Endoh T; Sugimoto N
Angew Chem Int Ed Engl; 2015 Jan; 54(3):905-9. PubMed ID: 25470002
[TBL] [Abstract][Full Text] [Related]
57. RiboCas: A Universal CRISPR-Based Editing Tool for Clostridium.
Cañadas IC; Groothuis D; Zygouropoulou M; Rodrigues R; Minton NP
ACS Synth Biol; 2019 Jun; 8(6):1379-1390. PubMed ID: 31181894
[TBL] [Abstract][Full Text] [Related]
58. Systematic Comparison and Rational Design of Theophylline Riboswitches for Effective Gene Repression.
Wang X; Fang C; Wang Y; Shi X; Yu F; Xiong J; Chou SH; He J
Microbiol Spectr; 2023 Feb; 11(1):e0275222. PubMed ID: 36688639
[TBL] [Abstract][Full Text] [Related]
59. Sequence elements distal to the ligand binding pocket modulate the efficiency of a synthetic riboswitch.
Weigand JE; Gottstein-Schmidtke SR; Demolli S; Groher F; Duchardt-Ferner E; Wöhnert J; Suess B
Chembiochem; 2014 Jul; 15(11):1627-37. PubMed ID: 24954073
[TBL] [Abstract][Full Text] [Related]
60. Linking aptamer-ligand binding and expression platform folding in riboswitches: prospects for mechanistic modeling and design.
Aboul-ela F; Huang W; Abd Elrahman M; Boyapati V; Li P
Wiley Interdiscip Rev RNA; 2015; 6(6):631-50. PubMed ID: 26361734
[TBL] [Abstract][Full Text] [Related]
[Previous] [Next] [New Search]