PIN-G reporter for imaging and defining trafficking signals in membrane proteins

Lynn McKeown; Vicky C. Jones; Owen T. Jones; Victoria Jones

PIN-G reporter for imaging and defining trafficking signals in membrane proteins

Lynn McKeown, Vicky C. Jones, Owen T. Jones, Victoria Jones

Research output: Contribution to journal › Article › peer-review

Abstract

The identification of motifs that control the intracellular trafficking of proteins is a fundamental objective of cell biology. Once identified, such regions should, in principle, be both necessary and sufficient to direct any randomly distributed protein, acting as a reporter, to the subcellular compartment in question. However, most reporter proteins have limited versatility owing to their endogenous expression and limited modes of detection - especially in live cells. To surmount such limitations, we engineered a plasmid - pING - encoding an entirely artificial, type I transmembrane reporter protein (PIN-G), containing HA, cMyc and GFP epitope, and fluorescence tags. Although originally designed for trafficking studies, pIN technology is a powerful tool applicable to almost every area of biology. Here we describe the methodologies used routinely in analyzing pIN constructs and some of their derivatives. © 2009 Humana Press.

Original language	English
Pages (from-to)	235-248
Number of pages	13
Journal	Methods in Molecular Biology
Volume	574
Publication status	Published - 2009

Keywords

epitope tags
Green fluorescent protein (GFP)
lentivirus
live imaging
photoactivation
reporter constructs
trafficking

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

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title = "PIN-G reporter for imaging and defining trafficking signals in membrane proteins",

abstract = "The identification of motifs that control the intracellular trafficking of proteins is a fundamental objective of cell biology. Once identified, such regions should, in principle, be both necessary and sufficient to direct any randomly distributed protein, acting as a reporter, to the subcellular compartment in question. However, most reporter proteins have limited versatility owing to their endogenous expression and limited modes of detection - especially in live cells. To surmount such limitations, we engineered a plasmid - pING - encoding an entirely artificial, type I transmembrane reporter protein (PIN-G), containing HA, cMyc and GFP epitope, and fluorescence tags. Although originally designed for trafficking studies, pIN technology is a powerful tool applicable to almost every area of biology. Here we describe the methodologies used routinely in analyzing pIN constructs and some of their derivatives. {\textcopyright} 2009 Humana Press.",

keywords = "epitope tags, Green fluorescent protein (GFP), lentivirus, live imaging, photoactivation, reporter constructs, trafficking",

author = "Lynn McKeown and Jones, {Vicky C.} and Jones, {Owen T.} and Victoria Jones",

year = "2009",

language = "English",

volume = "574",

pages = "235--248",

journal = "Methods in Molecular Biology",

issn = "1064-3745",

publisher = "Humana Press Inc.",

}

TY - JOUR

T1 - PIN-G reporter for imaging and defining trafficking signals in membrane proteins

AU - McKeown, Lynn

AU - Jones, Vicky C.

AU - Jones, Owen T.

AU - Jones, Victoria

PY - 2009

Y1 - 2009

N2 - The identification of motifs that control the intracellular trafficking of proteins is a fundamental objective of cell biology. Once identified, such regions should, in principle, be both necessary and sufficient to direct any randomly distributed protein, acting as a reporter, to the subcellular compartment in question. However, most reporter proteins have limited versatility owing to their endogenous expression and limited modes of detection - especially in live cells. To surmount such limitations, we engineered a plasmid - pING - encoding an entirely artificial, type I transmembrane reporter protein (PIN-G), containing HA, cMyc and GFP epitope, and fluorescence tags. Although originally designed for trafficking studies, pIN technology is a powerful tool applicable to almost every area of biology. Here we describe the methodologies used routinely in analyzing pIN constructs and some of their derivatives. © 2009 Humana Press.

AB - The identification of motifs that control the intracellular trafficking of proteins is a fundamental objective of cell biology. Once identified, such regions should, in principle, be both necessary and sufficient to direct any randomly distributed protein, acting as a reporter, to the subcellular compartment in question. However, most reporter proteins have limited versatility owing to their endogenous expression and limited modes of detection - especially in live cells. To surmount such limitations, we engineered a plasmid - pING - encoding an entirely artificial, type I transmembrane reporter protein (PIN-G), containing HA, cMyc and GFP epitope, and fluorescence tags. Although originally designed for trafficking studies, pIN technology is a powerful tool applicable to almost every area of biology. Here we describe the methodologies used routinely in analyzing pIN constructs and some of their derivatives. © 2009 Humana Press.

KW - epitope tags

KW - Green fluorescent protein (GFP)

KW - lentivirus

KW - live imaging

KW - photoactivation

KW - reporter constructs

KW - trafficking

M3 - Article

C2 - 19685313

SN - 1064-3745

VL - 574

SP - 235

EP - 248

JO - Methods in Molecular Biology

JF - Methods in Molecular Biology

ER -

PIN-G reporter for imaging and defining trafficking signals in membrane proteins

Abstract

Keywords

UN SDGs

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