George T. Hanson

Investigating mitochondrial redox potential with redox-sensitive green fluorescent protein indicators.

Current methods for determining ambient redox potential in cells are labor-intensive and generally require destruction of tissue. This precludes single cell or real time studies of changes in redox poise that result from metabolic processes or environmental influences. By substitution of surface-exposed residues on the Aequorea victoria green fluorescent protein (GFP) with cysteines in appropriate positions to form disulfide bonds, reduction-oxidation-sensitive GFPs (roGFPs) have been created. roGFPs have two fluorescence excitation maxima at about 400 and 490 nm and display rapid and reversible ratiometric changes in fluorescence in response to changes in ambient redox potential in vitro and in vivo. Crystal structure analyses of reduced and oxidized crystals of roGFP2 at 2.0- and 1.9-Å resolution, respectively, reveal in the oxidized state a highly strained disulfide and localized main chain structural changes that presumably account for the state-dependent spectral changes. roGFP1 has been targeted to the mitochondria in HeLa cells. Fluorometric measurements on these cells using a fluorescence microscope or in cell suspension using a fluorometer reveal that the roGFP1 probe is in dynamic equilibrium with the mitochondrial redox status and responds to membrane-permeable reductants and oxidants. The roGFP1 probe reports that the matrix space in HeLa cell mitochondria is highly reducing, with a midpoint potential near -360 mV (assuming mitochondrial pH ∼8.0 at 37 °C). In other work (C. T. Dooley, T. M. Dore, G. Hanson, W. C. Jackson, S. J. Remington, and R. Y. Tsien, submitted for publication), it is shown that the cytosol of HeLa cells is also unusually reducing but somewhat less so than the mitochondrial matrix.

Imaging Dynamic Redox Changes in Mammalian Cells with Green Fluorescent Protein Indicators

Changes in the redox equilibrium of cells influence a host of cell functions. Alterations in the redox equilibrium are precipitated by changing either the glutathione/glutathione-disulfide ratio (GSH/GSSG) and/or the reduced/oxidized thioredoxin ratio. Redox-sensitive green fluorescent proteins (GFP) allow real time visualization of the oxidation state of the indicator. Ratios of fluorescence from excitation at 400 and 490 nm indicate the extent of oxidation and thus the redox potential while canceling out the amount of indicator and the absolute optical sensitivity. Because the indicator is genetically encoded, it can be targeted to specific proteins or organelles of interest and expressed in a wide variety of cells and organisms. We evaluated roGFP1 (GFP with mutations C48S, S147C, and Q204C) and roGFP2 (the same plus S65T) with physiologically or toxicologically relevant oxidants both in vitro and in living mammalian cells. Furthermore, we investigated the response of the redox probes under physiological redox changes during superoxide bursts in macrophage cells, hyperoxic and hypoxic conditions, and in responses to H2O2-stimulating agents, e.g. epidermal growth factor and lysophosphatidic acid.

Structural basis of spectral shifts in the yellow-emission variants of green fluorescent protein.

BACKGROUND Because of its ability to spontaneously generate its own fluorophore, the green fluorescent protein (GFP) from the jellyfish Aequorea victoria is used extensively as a fluorescent marker in molecular and cell biology. The yellow fluorescent proteins (YFPs) have the longest wavelength emissions of all GFP variants examined to date. This shift in the spectrum is the result of a T203Y substitution (single-letter amino acid code), a mutation rationally designed on the basis of the X-ray structure of GFP S65T. RESULTS We have determined the crystal structures of YFP T203Y/S65G/V68L/S72A and YFP H148G to 2.5 and 2.6 A resolution, respectively. Both structures show clear electron density for nearly coplanar pi-pi stacking between Tyr203 and the chromophore. The chromophore has been displaced by nearly 1 A in comparison to other available structures. Although the H148G mutation results in the generation of a solvent channel to the chromophore cavity, intense fluorescence is maintained. The chromophore in the intact protein can be titrated, and the two variants have pKa values of 7.0 (YFP) and 8.0 (YFP H148G). CONCLUSIONS The observed red shift of the T203Y YFP variant is proposed to be mainly due to the additional polarizability of the pi-stacked Tyr203. The altered location of the chromophore suggests that the exact positions of nearby residues are not crucial for the chemistry of chromophore formation. The YFPs significantly extend the pH range over which GFPs may be employed as pH indicators in live cells.

A replicating module as the unit of mitochondrial structure and functioning

The mitochondrion within human cells in tissue culture is pleomorphic and highly dynamic. The organelle mass can exist as thousands of small ovoids or as one continuous reticulum. In either state, the mitochondrial mass is in constant thermal motion, as well as moving in approximately 0.8-microm jumps that are determined by, and related to, attachments with cytoskeletal elements. Many protein complexes, such as the pyruvate dehydrogenase (PDH) complex and DNA containing nucleoids, are dispersed through the mass and as though fixed by attachments to membranes, such that they can become distributed to all of the individual small ovoid mitochondria when the reticulum becomes fragmented. This leads us to propose that a replicating module is the repeating unit of mitochondrial structure. Studies to examine heterogeneity of functioning within the organelle mass are briefly reviewed.

Third-generation GFP biosensors for real-time readout of pH and redox potential in living cells

Green fluorescent protein variants have been developed that report real-time change in pH and redox potential in living cells. The variants involve cysteine substitutions near the chromophore, which greatly alter the sensitivity of the protein to changes in its environment. Measurements can be made on single living cells in the fluorescence microscope or in cell suspension with an ordinary fluorimeter. The indicators are ratiometric by emission and/or excitation, which means that measurements at two different wavelengths are sufficient to determine both the quantity being measured and the indicator GFP concentration. The photophysics of a novel blue/green dual emission GFP variant will be presented. The design principles, crystal structures and ultrafast spectroscopic analysis of probe response will be discussed in terms of atomic models involving excited state proton transfer. Some applications in living cells will be presented.