Two-photon microscopy: visualization of kidney dynamics.

The introduction of two-photon microscopy, along with the development of new fluorescent probes and innovative computer software, has advanced the study of intracellular and intercellular processes in the tissues of living organisms. Researchers can now determine the distribution, behavior, and interactions of labeled chemical probes and proteins in live kidney tissue in real time without fixation artifacts. Chemical probes, such as fluorescently labeled dextrans, have extended our understanding of dynamic events with subcellular resolution. To accomplish expression of specific proteins in vivo, cDNAs of fluorescently labeled proteins have been cloned into adenovirus vectors and infused by micropuncture to induce proximal tubule cell infection and protein expression. The localization and intensity of the expressed fluorescent proteins can be observed repeatedly at different time points allowing for enhanced quantitative analysis while limiting animal use. Optical sections of images acquired with the two-photon microscope can be 3-D reconstructed and quantified with Metamorph, Voxx, and Amira software programs.

Ischemic injury induces ADF relocalization to the apical domain of rat proximal tubule cells.

Breakdown of proximal tubule cell apical membrane microvilli is an early-occurring hallmark of ischemic acute renal failure. Intracellular mechanisms responsible for these apical membrane changes remain unknown, but it is known that actin cytoskeleton alterations play a critical role in this cellular process. Our laboratory previously demonstrated that ischemia-induced cell injury resulted in dephosphorylation and activation of the actin-binding protein, actin depolymerizing factor [(ADF); Schwartz, N, Hosford M, Sandoval RM, Wagner MC, Atkinson SJ, Bamburg J, and Molitoris BA. Am J Physiol Renal Fluid Electrolyte Physiol 276: F544-F551, 1999]. Therefore, we postulated that ischemia-induced ADF relocalization from the cytoplasm to the apical microvillar microfilament core was an early event occurring before F-actin alterations. To directly investigate this hypothesis, we examined the intracellular localization of ADF in ischemic rat cortical tissues by immunofluorescence and quantified the concentration of ADF in brush-border membrane vesicles prepared from ischemic rat kidneys by using Western blot techniques. Within 5 min of the induction of ischemia, ADF relocalized to the apical membrane region. The length of ischemia correlated with the time-related increase in ADF in isolated brush-border membrane vesicles. Finally, depolymerization of microvillar F-actin to G-actin was documented by using colocalization studies for G- and F-actin. Collectively, these data indicate that ischemia induces ADF activation and relocalization to the apical domain before microvillar destruction. These data further suggest that ADF plays a critical role in microvillar microfilament destruction and apical membrane damage during ischemia.

Pathophysiology and functional significance of apical membrane disruption during ischemia.

The characteristic structure of polarized proximal tubule cells is drastically altered by the onset of ischemic acute renal failure. Distinctive apical brush border microvilli disruption occurs rapidly and in a duration-dependent fashion. Microvillar membranes internalize into the cytosol of the cell or are shed into the lumen as blebs. The microvillar actin core disassembles concurrent with or preceding these membrane changes. Actin and its associated binding proteins no longer interact to form these highly regulated apical membrane structures necessary for microvilli. The resultant epithelial cells have a reduced apical membrane surface that is not polarized either structurally, biochemically or physiologically. Furthermore, the changes in the apical microvilli result in tubular obstruction, reduced Na+ absorption, and partly explain the reduction in glomerular filtration rate. Recent evidence suggests these actin surface membrane alterations induced by ischemia are secondary to activation and relocation of the actin-associated protein, actin depolymerizing factor/cofilin, to the apical membrane domain. Activated (dephosphorylated) actin depolymerizing factor/cofilin proteins bind filamentous actin, increasing subunit treadmilling rates and filament severing. Once activated, the diffuse cytoplasmic distribution of the actin depolymerizing factor/cofilin protein relocalizes to the luminal membrane blebs. During recovery the actin depolymerizing factor/cofilin proteins are again phosphorylated and reassume their normal diffuse cytoplasmic localization. This evidence strongly supports the hypothesis that actin depolymerizing factor/cofilin proteins play a significant role in ischemia-induced injury in the proximal tubule cells.

Actin Purified from Maize Pollen Functions in Living Plant Cells.

A vast array of actin binding proteins (ABPs), together with intracellular signaling molecules, modulates the spatiotemporal distribution of actin filaments in eukaryotic cells. To investigate the complex regulation of actin organization in plant cells, we designed experiments to reconstitute actin-ABP interactions in vitro with purified components. Because vertebrate skeletal [alpha]-actin has distinct and unpredictable binding affinity for nonvertebrate ABPs, it is essential that these in vitro studies be performed with purified plant actin. Here, we report the development of a new method for isolating functional actin from maize pollen. The addition of large amounts of recombinant profilin to pollen extracts facilitated the depolymerization of actin filaments and the formation of a profilin-actin complex. The profilin-actin complex was then isolated by affinity chromatography on poly-L-proline-Sepharose, and actin was selectively eluted with a salt wash. Pollen actin was further purified by one cycle of polymerization and depolymerization. The recovery of functional actin by this rapid and convenient procedure was substantial; the average yield was 6 mg of actin from 10 g of pollen. We undertook an initial physicochemical characterization of this native pollen actin. Under physiological conditions, pollen actin polymerized with kinetics similar in quality to those for vertebrate [alpha]-actin and had a critical concentration for assembly of 0.6 [mu]M. Moreover, pollen actin interacted specifically and in a characteristic fashion with several ABPs. Tradescantia cells were microinjected and used as an experimental system to study the behavior of pollen actin in vivo. We demonstrated that purified pollen actin ameliorated the effects of injecting excess profilin into live stamen hair cells.