Photoacoustic imaging allows absorption-based high-resolution spectroscopic in vivo imaging at a depth beyond that of optical microscopy. Until recently, photoacoustic imaging has largely been restricted to visualizing the vasculature through endogenous haemoglobin contrast, with most non-vascularized tissues remaining invisible unless exogenous contrast agents are administered. Genetically encodable photoacoustic contrast is attractive as it allows selective labelling of cells, permitting studies of, for example, specific genetic expression, cell growth or more complex biological behaviours in vivo. In this study we report a novel photoacoustic imaging scanner and a tyrosinase-based reporter system that causes human cell lines to synthesize the absorbing pigment eumelanin, thus providing strong photoacoustic contrast. Detailed threedimensional images of xenografts formed of tyrosinase-expressing cells implanted in mice are obtained in vivo to depths approaching 10 mm with a spatial resolution below 100 μm. This scheme is a powerful tool for studying cellular and genetic processes in deep mammalian tissues.O ptical techniques such as fluorescence or bioluminescence imaging are widely used to visualize biological tissues in vivo 1-4 . However, strong optical scattering fundamentally limits the penetration depth or spatial resolution. Microscopy and other techniques that utilize ballistic photons 4 can provide cellular resolution, but only to sub-millimetre penetration depths, while diffuse optical methods such as fluorescence optical tomography 1 can provide greater penetration depths (on the scale of centimetres) but with only limited spatial resolution (on the scale of millimetres). Photoacoustic imaging (PAI) offers the prospect of overcoming these limitations 5-8 . Here, ultrasound waves generated by the absorption of laser light by tissue chromophores are used to produce images of biological tissues based on optical absorption. Because acoustic waves are scattered much less than photons in soft tissues, PAI avoids the depth and spatial resolution limitations of purely optical imaging techniques: depths of a few centimetres with scalable spatial resolution ranging from tens to hundreds of micrometres (depending on depth) are readily achievable.Although strong absorption by haemoglobin enables the acquisition of exquisite three-dimensional photoacoustic (PA) images of the vasculature 9-14 , most cells and tissues are relatively weakly absorbing at visible and near-infrared wavelengths and are thus indistinguishable in the absence of exogenous contrast. The latter can be provided by nanoparticle-or dye-based targeted contrast agents 15-17 , but these can present challenges in achieving effective specific targeting and clearance. The use of reporter genes to provide genetically encoded exogenous PA contrast would avoid these limitations and has the further advantage of providing opportunities to study more complex biological behaviours such as cell growth dynamics and intracellular processes such as gene expressi...
SHOC2 is mutated in Noonan syndrome and plays a key role in the activation of the ERK-MAPK pathway, which is upregulated in the majority of human cancers. SHOC2 functions as a PP1-regulatory protein and as an effector of MRAS. Here we show that SHOC2 and MRAS form a complex with SCRIB, a polarity protein with tumor suppressor properties. SCRIB functions as a PP1-regulatory protein and antagonizes SHOC2-mediated RAF dephosphorylation through a mechanism involving competition for PP1 molecules within the same macromolecular complex. SHOC2 function is selectively required for the malignant properties of tumor cells with mutant RAS, and both MRAS and SHOC2 play a key role in polarized migration. We propose that MRAS, through its ability to recruit a complex with paradoxical components, coordinates ERK pathway spatiotemporal dynamics with polarity and that this complex plays a key role during tumorigenic growth.
Red-shifted bioluminescent emitters allow improved in vivo tissue penetration and signal quantification, and have led to the development of beetle luciferin analogues that elicit red-shifted bioluminescence with firefly luciferase (Fluc). However, unlike natural luciferin, none have been shown to emit different colors with different luciferases. We have synthesized and tested the first dual-color, far-red to near-infrared (nIR) emitting analogue of beetle luciferin, which, akin to natural luciferin, exhibits pH dependent fluorescence spectra and emits bioluminescence of different colors with different engineered Fluc enzymes. Our analogue produces different far-red to nIR emission maxima up to λmax=706 nm with different Fluc mutants. This emission is the most red-shifted bioluminescence reported without using a resonance energy transfer acceptor. This improvement should allow tissues to be more effectively probed using multiparametric deep-tissue bioluminescence imaging.
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