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Mol. Cells 2011; 32(4): 349-358
Published online October 17, 2011
https://doi.org/10.1007/s10059-011-0088-5
© The Korean Society for Molecular and Cellular Biology
Novel GFP Expression Using a Short N-Terminal Polypeptide through the Defined Twin-Arginine Translocation (Tat) Pathway
Correspondence to : *Correspondence: sangjl@nrfdi.go.kr
Escherichia coli is frequently used as a convenient host organism for soluble recombinant protein expression. However, additional strategies are needed for proteins with complex folding characteristics. Here, we suggested that the acidic, neutral, and alkaline isoelectric point (pI) range curves correspond to the channels of the E. coli type-II cytoplasmic membrane translocation (periplasmic translocation) pathways of twin-arginine translocation (Tat), Yid, and general secretory pathway (Sec), respectively, for unfolded and folded target proteins by examining the characteristic pI values of the N-termini of the signal sequences or the leader sequences, matching with the known diameter of the translocation channels, and analyzing the N-terminal pI value of the signal sequences of the Tat substrates. To confirm these proposed translocation pathways, we investigated the soluble expression of the folded green fluorescent protein (GFP) with short N-terminal polypeptides exhibiting pI and hydrophilicity separately or collectively. This, in turn, revealed the existence of an anchor function with a specific directionality based on the N-terminal pI value (termed as N-terminal pI-specific directionality) and distinguished the presence of the E. coli type-II cytoplasmic membrane translocation pathways of Tat, Yid, and Sec for the unfolded and folded target pro-teins. We concluded that the pI value and hydrophilicity of the short N-terminal polypeptide, and the total translational efficiency of the target proteins based on the ?GRNA value of the N-terminal coding regions are important factors for promoting more efficient translocation (secretion) through the largest diameter of the Tat channel. These results show that the short N-terminal polypeptide could substitute for the Tat signal sequence with improved efficiency.
Keywords delta GRNA value of the N-terminal coding region, E. coli type-II cytoplasmic membrane translocation pathways (Tat, Yid, and Sec), highly hydro-philic N-termini of the modified signal sequences, N-terminal hydrophilicity, N-terminal pI with an anchor func
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Research Article
Mol. Cells 2011; 32(4): 349-358
Published online October 31, 2011 https://doi.org/10.1007/s10059-011-0088-5
Copyright © The Korean Society for Molecular and Cellular Biology.
Novel GFP Expression Using a Short N-Terminal Polypeptide through the Defined Twin-Arginine Translocation (Tat) Pathway
Sang Jun Lee*, Yun Hee Han, Young Ok Kim, Bo Hye Nam, and Hee Jeong Kong
Biotechnology Research Division, National Fisheries Research and Development Institute, Busan 619-902, Korea
Correspondence to:*Correspondence: sangjl@nrfdi.go.kr
Abstract
Escherichia coli is frequently used as a convenient host organism for soluble recombinant protein expression. However, additional strategies are needed for proteins with complex folding characteristics. Here, we suggested that the acidic, neutral, and alkaline isoelectric point (pI) range curves correspond to the channels of the E. coli type-II cytoplasmic membrane translocation (periplasmic translocation) pathways of twin-arginine translocation (Tat), Yid, and general secretory pathway (Sec), respectively, for unfolded and folded target proteins by examining the characteristic pI values of the N-termini of the signal sequences or the leader sequences, matching with the known diameter of the translocation channels, and analyzing the N-terminal pI value of the signal sequences of the Tat substrates. To confirm these proposed translocation pathways, we investigated the soluble expression of the folded green fluorescent protein (GFP) with short N-terminal polypeptides exhibiting pI and hydrophilicity separately or collectively. This, in turn, revealed the existence of an anchor function with a specific directionality based on the N-terminal pI value (termed as N-terminal pI-specific directionality) and distinguished the presence of the E. coli type-II cytoplasmic membrane translocation pathways of Tat, Yid, and Sec for the unfolded and folded target pro-teins. We concluded that the pI value and hydrophilicity of the short N-terminal polypeptide, and the total translational efficiency of the target proteins based on the ?GRNA value of the N-terminal coding regions are important factors for promoting more efficient translocation (secretion) through the largest diameter of the Tat channel. These results show that the short N-terminal polypeptide could substitute for the Tat signal sequence with improved efficiency.
Keywords: delta GRNA value of the N-terminal coding region, E. coli type-II cytoplasmic membrane translocation pathways (Tat, Yid, and Sec), highly hydro-philic N-termini of the modified signal sequences, N-terminal hydrophilicity, N-terminal pI with an anchor func
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