Simultaneous multiple-excitation multiphoton microscopy yields increased imaging sensitivity and specificity.

BACKGROUND: Multiphoton microscopy (MPM) offers many advantages over conventional wide-field and confocal laser scanning microscopy (CLSM) for imaging biological samples such as 3D resolution of excitation, reduced phototoxicity, and deeper tissue imaging. However, adapting MPM for critical multi-color measurements presents a challenge because of the largely overlapping two-photon absorption (TPA) peaks of common biological fluorophores. Currently, most multi-color MPM relies on the absorbance at one intermediate wavelength of multiple dyes, which introduces problems such as decreased and unequal excitation efficiency across the set of dyes. RESULTS: Here we describe an MPM system incorporating two, independently controlled sources of two-photon excitation whose wavelengths are adjusted to maximally excite one dye while minimally exciting the other. We report increased signal-to-noise ratios and decreased false positive emission bleed-through using this novel multiple-excitation MPM (ME-MPM) compared to conventional single-excitation MPM (SE-MPM) in a variety of multi-color imaging applications. CONCLUSIONS: Similar to the tremendous gain in popularity of CLSM after the introduction of multi-color imaging, we anticipate that the ME-MPM system will further increase the popularity of MPM. In addition, ME-MPM provides an excellent tool to more rapidly design and optimize pairs of fluorescence probes for multi-color two-photon imaging, such as CFP/YFP or GFP/DsRed for CLSM.

Doublecortin maintains bipolar shape and nuclear translocation during migration in the adult forebrain.

The ability of the mature mammalian nervous system to continually produce neuronal precursors is of considerable importance, as manipulation of this process might one day permit the replacement of cells lost as a result of injury or disease. In mammals, the anterior subventricular zone (SVZa) region is one of the primary sites of adult neurogenesis. Here we show that doublecortin (DCX), a widely used marker for newly generated neurons, when deleted in mice results in a severe morphological defect in the rostral migratory stream and delayed neuronal migration that is independent of direction or responsiveness to Slit chemorepulsion. DCX is required for nuclear translocation and maintenance of bipolar morphology during migration of these cells. Our data identifies a critical function for DCX in the movement of newly generated neurons in the adult brain.

Factors influencing cell fate in the infarct rim.

In focal ischemia, the fate of penumbral cells is closely linked to the infarcted tissue. Because of the release of cytosolic material from damaged cells, the biochemical and ionic alterations within the core are dramatic. Hence, adjacent cells ( infarct rim) are generally exposed to these changes and may be deleteriously affected. To mimic such conditions in vitro, we have employed a slice culture system and used an ischemic solution (IS) that resembles the milieu in the territory of infarct rim. In contrast to normal artificial cerebral spinal fluid, IS is characterized by low O(2), glucose, pH; excitotoxic levels of glutamate; and ionic alterations. In organotypic hippocampal slice cultures, we examined cell injury/death using propidium iodide following exposure to IS. Our data show significant cell injury starting at approximately 8 h following IS exposure with cell injury spreading as a function of exposure duration. We further studied the effect of each component in the IS separately, i.e., acidosis, hypoxia, ionic shifts or glutamate exitotoxicity and were able to isolate the contribution of each of these effectors to the IS-induced cell death. Our results suggest that in IS, acidosis exacerbates the potential for injury while ionic shifts, especially those of K(+) and Na(+), alleviate the potential for cell death.

GSK3beta and PKCzeta function in centrosome localization and process stabilization during Slit-mediated neuronal repolarization.

In comparison with other migratory cells, neurons exhibit a unique, highly polarized morphology and a distinctive pattern of movement. This migration consists of a repeating of three distinct phases: neurite outgrowth, movement of the centrosome into the leading process, and translocation of the nucleus towards the centrosome. The direction of movement is under the control of extracellular guidance cues, but mechanisms by which these determine neuronal polarity, centrosome position, and neuronal movement are not well understood. We found that in primary olfactory bulb neuronal precursors, Slit-mediated repolarization consisted of growth of a new process from the previous trailing edge, then reorientation of the centrosome followed by nuclear translocation in the reverse direction. Inhibition of cell polarity factors GSK3beta or PKCzeta resulted in impaired centrosome reorientation and process stabilization. Our findings suggest that activation of cell polarity signaling and positioning of the centrosome ahead of the nucleus are important steps in repolarization in response to guidance cues.

Dishevelled genes mediate a conserved mammalian PCP pathway to regulate convergent extension during neurulation.

The planar cell polarity (PCP) pathway is conserved throughout evolution, but it mediates distinct developmental processes. In Drosophila, members of the PCP pathway localize in a polarized fashion to specify the cellular polarity within the plane of the epithelium, perpendicular to the apicobasal axis of the cell. In Xenopus and zebrafish, several homologs of the components of the fly PCP pathway control convergent extension. We have shown previously that mammalian PCP homologs regulate both cell polarity and polarized extension in the cochlea in the mouse. Here we show, using mice with null mutations in two mammalian Dishevelled homologs, Dvl1 and Dvl2, that during neurulation a homologous mammalian PCP pathway regulates concomitant lengthening and narrowing of the neural plate, a morphogenetic process defined as convergent extension. Dvl2 genetically interacts with Loop-tail, a point mutation in the mammalian PCP gene Vangl2, during neurulation. By generating Dvl2 BAC (bacterial artificial chromosome) transgenes and introducing different domain deletions and a point mutation identical to the dsh1 allele in fly, we further demonstrated a high degree of conservation between Dvl function in mammalian convergent extension and the PCP pathway in fly. In the neuroepithelium of neurulating embryos, Dvl2 shows DEP domain-dependent membrane localization, a pre-requisite for its involvement in convergent extension. Intriguing, the Loop-tail mutation that disrupts both convergent extension in the neuroepithelium and PCP in the cochlea does not disrupt Dvl2 membrane distribution in the neuroepithelium, in contrast to its drastic effect on Dvl2 localization in the cochlea. These results are discussed in light of recent models on PCP and convergent extension.