Monitoring cytosolic and ER Zn(2+) in stimulated breast cancer cells using genetically encoded FRET sensors.

The Zn(2+)-specific ion channel ZIP7 has been implicated to play an important role in releasing Zn(2+) from the ER. External stimulation of breast cancer cells has been proposed to induce phosphorylation of ZIP7 by CK2α, resulting in ZIP7-mediated Zn(2+) release from the ER into the cytosol. Here, we examined whether changes in cytosolic and ER Zn(2+) concentrations can be detected upon such external stimuli. Two previously developed FRET sensors for Zn(2+), eZinCh-2 (Kd = 1 nM at pH 7.1) and eCALWY-4 (Kd = 0.63 nM at pH 7.1), were expressed in both the cytosol and the ER of wild-type MCF-7 and TamR cells. Treatment of MCF-7 and TamR cells with external Zn(2+) and pyrithione, one of the previously used triggers, resulted in an immediate increase in free Zn(2+) in both cytosol and ER, suggesting that Zn(2+) was directly transferred across the cellular membranes by pyrithione. Cells treated with a second trigger, EGF/ionomycin, showed no changes in intracellular Zn(2+) levels, neither in multicolor imaging experiments that allowed simultaneous imaging of cytosolic and ER Zn(2+), nor in experiments in which cytosolic and ER Zn(2+) were monitored separately. In contrast to previous work using small-molecule fluorescent dyes, these results indicate that EGF-ionomycin treatment does not result in significant changes in cytosolic Zn(2+) levels as a result from Zn(2+) release from the ER. These results underline the importance of using genetically encoded fluorescent sensors to complement and verify intracellular imaging experiments with synthetic fluorescent Zn(2+) dyes.

Genetically-encoded FRET-based sensors for monitoring Zn(2+) in living cells.

Genetically-encoded fluorescent sensor proteins are attractive tools for studying intracellular Zn(2+) homeostasis and signaling. Here we provide an overview of recently developed sensors based on Förster Resonance Energy Transfer (FRET). The pros and cons of the various sensors are discussed with respect to Zn(2+) affinity, dynamic range, intracellular targeting and multicolor imaging. Recent applications of these sensors are described, as well as some of the challenges that remain to be addressed in future research.

eZinCh-2: A Versatile, Genetically Encoded FRET Sensor for Cytosolic and Intraorganelle Zn(2+) Imaging.

Zn(2+) plays essential and diverse roles in numerous cellular processes. To get a better understanding of intracellular Zn(2+) homeostasis and the putative signaling role of Zn(2+), various fluorescent sensors have been developed that allow monitoring of Zn(2+) concentrations in single living cells in real time. Thus far, two families of genetically encoded FRET-based Zn(2+) sensors have been most widely applied, the eCALWY sensors developed by our group and the ZapCY sensors developed by Palmer and co-workers. Both have been successfully used to measure cytosolic free Zn(2+), but distinctly different concentrations have been reported when using these sensors to measure Zn(2+) concentrations in the ER and mitochondria. Here, we report the development of a versatile alternative FRET sensor containing a de novo Cys2His2 binding pocket that was created on the surface of the donor and acceptor fluorescent domains. This eZinCh-2 sensor binds Zn(2+) with a high affinity that is similar to that of eCALWY-4 (Kd = 1 nM at pH 7.1), while displaying a substantially larger change in emission ratio. eZinCh-2 not only provides an attractive alternative for measuring Zn(2+) in the cytosol but was also successfully used for measuring Zn(2+) in the ER, mitochondria, and secretory vesicles. Moreover, organelle-targeted eZinCh-2 can also be used in combination with the previously reported redCALWY sensors to allow multicolor imaging of intracellular Zn(2+) simultaneously in the cytosol and the ER or mitochondria.

Robust red FRET sensors using self-associating fluorescent domains.

Elucidation of subcellular signaling networks by multiparameter imaging is hindered by a lack of sensitive FRET pairs spectrally compatible with the classic CFP/YFP pair. Here, we present a generic strategy to enhance the traditionally poor sensitivity of red FRET sensors by developing self-associating variants of mOrange and mCherry that allow sensors to switch between well-defined on- and off states. Requiring just a single mutation of the mFruit domain, this new FRET pair improved the dynamic range of protease sensors up to 10-fold and was essential to generate functional red variants of CFP-YFP-based Zn(2+) sensors. The large dynamic range afforded by the new red FRET pair allowed simultaneous use of differently colored Zn(2+) FRET sensors to image Zn(2+) over a broad concentration range in the same cellular compartment.