Anced CFP because of its high quantum yield [7]. Such studies allow researchers to precisely correlate the timing of two interdependent cellular events or to track the movement of ions or molecules from one compartment to another. An additional advantage of alternate color FRET sensors, particularly those that avoid using a variant of YFP which is quenched by acid [8], is that they are likely to be less sensitive to pH perturbations. While in principle the concept of generating alternate color FRET sensors 25033180 is attractive, in practice there are a number challenges that have limited availability of non-CFP/YFP biosensors. First and foremost, the vast majority of the.120 FRET-based biosensors currently available are based on CFP/ YFP and as noted in a recent publication [6], changing the FPs often requires extensive re-optimization of the sensor. Secondly, the biophysical (folding, maturation, oligomerization state) and photophysical properties (brightness) of red and orange FPs still lag behind those of the cyan-yellow counterparts [9], making it challenging to identify a robust alternate FRET pair. Indeed of the non-CFP/YFP biosensors developed thus far, each research team chose a different combination of FRET partners [5,10,11,12,13,14].Alternately Colored FRET Sensors for ZincTitle Loaded From File sensor cDNA was cloned into pcDNA3.1(+) between BamHI and EcoRI. To localize sensors to either the nucleus or the cytosol, a nuclear localization (NLS) or nuclear exclusion (NES) signal sequence was cloned upstream of the BamHI site, such that the signal sequence is at the N-terminus of the sensor. For nuclear or cytosolic localization the following primers were used: 59ATGCCTAAAAAAAAACGTAAAGTTGAAGATGCTGGATCC-39 (NLS) and 59-ATGCTTCAACTTCCTCCTCTTGAACGTCTTACTCTTGGATCC-39 (NES). Sensors containing localization Otein. For the PAP4 serum that did not produce significant matches sequences for endoplasmic reticulum, Golgi apparatus, and mitochondria were developed previously [15,17]. Clover lacks the C-terminal residues GITLMDELYK that are present in other GFP-based proteins. During the initial cloning of ZapCmR1 there was an inadvertent addition of the linker MVSKGEEL to the N-terminus of mRuby2 so the sensor contains this additional linker.Figure 1. Nuclear Localization and Nuclear Exclusion Signal Sequence constructs. A NLS and NES were cloned into pcDNA 3.1 (+) vector upstream BamH I. A) Schematic of FRET sensor construct. B) Representative images of transfected sensor showing localization to either the nucleus or cytosol. Scale bar = 20 mm. doi:10.1371/journal.pone.0049371.gIn vitro FRET Sensor Protein PurificationPlasmids containing the sensors were transformed into BL21 E. coli, expression was induced with 500 mM isopropyl b-D-1thiogalactopyranoside (IPTG) (Gold Biotechnology), and sensor protein was purified by the His-tag using Ni2+ affinity chromatography. Purified sensor was buffer exchanged into 10 mM MOPS, 100 mM KCl pH 7.4 and absorption and emission spectra were recorded using a Tecan Safire-II fluorescence plate reader with the following parameters: ZapSM2 and ZapSR2, excitation: 380 nm, emission: 470?50 nm; ZapOC2 and ZapOK2, excitation: 525 nm, emission: 540?50 nm; ZapCmR excitation: 445 nm, emission: 470?00 nm. All measurements had an emission bandwidth of 10 nm.In this work, we developed alternately colored Zn2+ biosensors, testing a series of green-red and orange-red FP combinations. Because it is common for sensors to exhibit diminished responses in cells compared to in vitro [15,16], we screened the panel of senso.Anced CFP because of its high quantum yield [7]. Such studies allow researchers to precisely correlate the timing of two interdependent cellular events or to track the movement of ions or molecules from one compartment to another. An additional advantage of alternate color FRET sensors, particularly those that avoid using a variant of YFP which is quenched by acid [8], is that they are likely to be less sensitive to pH perturbations. While in principle the concept of generating alternate color FRET sensors 25033180 is attractive, in practice there are a number challenges that have limited availability of non-CFP/YFP biosensors. First and foremost, the vast majority of the.120 FRET-based biosensors currently available are based on CFP/ YFP and as noted in a recent publication [6], changing the FPs often requires extensive re-optimization of the sensor. Secondly, the biophysical (folding, maturation, oligomerization state) and photophysical properties (brightness) of red and orange FPs still lag behind those of the cyan-yellow counterparts [9], making it challenging to identify a robust alternate FRET pair. Indeed of the non-CFP/YFP biosensors developed thus far, each research team chose a different combination of FRET partners [5,10,11,12,13,14].Alternately Colored FRET Sensors for Zincsensor cDNA was cloned into pcDNA3.1(+) between BamHI and EcoRI. To localize sensors to either the nucleus or the cytosol, a nuclear localization (NLS) or nuclear exclusion (NES) signal sequence was cloned upstream of the BamHI site, such that the signal sequence is at the N-terminus of the sensor. For nuclear or cytosolic localization the following primers were used: 59ATGCCTAAAAAAAAACGTAAAGTTGAAGATGCTGGATCC-39 (NLS) and 59-ATGCTTCAACTTCCTCCTCTTGAACGTCTTACTCTTGGATCC-39 (NES). Sensors containing localization sequences for endoplasmic reticulum, Golgi apparatus, and mitochondria were developed previously [15,17]. Clover lacks the C-terminal residues GITLMDELYK that are present in other GFP-based proteins. During the initial cloning of ZapCmR1 there was an inadvertent addition of the linker MVSKGEEL to the N-terminus of mRuby2 so the sensor contains this additional linker.Figure 1. Nuclear Localization and Nuclear Exclusion Signal Sequence constructs. A NLS and NES were cloned into pcDNA 3.1 (+) vector upstream BamH I. A) Schematic of FRET sensor construct. B) Representative images of transfected sensor showing localization to either the nucleus or cytosol. Scale bar = 20 mm. doi:10.1371/journal.pone.0049371.gIn vitro FRET Sensor Protein PurificationPlasmids containing the sensors were transformed into BL21 E. coli, expression was induced with 500 mM isopropyl b-D-1thiogalactopyranoside (IPTG) (Gold Biotechnology), and sensor protein was purified by the His-tag using Ni2+ affinity chromatography. Purified sensor was buffer exchanged into 10 mM MOPS, 100 mM KCl pH 7.4 and absorption and emission spectra were recorded using a Tecan Safire-II fluorescence plate reader with the following parameters: ZapSM2 and ZapSR2, excitation: 380 nm, emission: 470?50 nm; ZapOC2 and ZapOK2, excitation: 525 nm, emission: 540?50 nm; ZapCmR excitation: 445 nm, emission: 470?00 nm. All measurements had an emission bandwidth of 10 nm.In this work, we developed alternately colored Zn2+ biosensors, testing a series of green-red and orange-red FP combinations. Because it is common for sensors to exhibit diminished responses in cells compared to in vitro [15,16], we screened the panel of senso.
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