A microfluidic platform for transcription- and amplification-free detection of zepto-mole amounts of nucleic acid molecules.

Here we report the development of a device for the transcription- and amplification-free detection of DNA and RNA molecules down to the zepto-mole range. A microfluidic chip with a built-in microarray was used for manipulation of nano-liter sample volumes. Specific staining and immobilization of the target molecules was achieved via a double hybridization approach thereby avoiding bias due to enzymatic processes like reverse transcription and PCR amplification. Therefore, target molecules were indirectly labeled by pre-hybridization to complementary Cy5-labeled probes. The remaining single-stranded portion of each target molecule could subsequently hybridize to complementary capture probes of a microarray. Thus a target-mediated immobilization of labeled DNA took place. By means of an ultra-sensitive fluorescence readout, all molecules hybridized to the microarray could be detected. The combination of minimized sample volume and single molecule detection yielded a detection limit of 39 fM (831 molecules in 35.4 nl assay volume) for target DNA and 16 fM (338 molecules) for target RNA after 1h on-chip hybridization.

A PDMS-based biochip with integrated sub-micrometre position control for TIRF microscopy of the apical cell membrane.

A poly(dimethylsiloxane) (PDMS)-based biochip with an integrated pressure controlled positioning system with sub-micrometre precision was realized. The biochip was easy and cheap to manufacture and enabled positioning in a wet environment. It allowed the application of total internal reflection fluorescence (TIRF) microscopy at the dorsal cell membrane, which is not adhering to a support. Specifically, the chip enabled TIRF microscopy at the apical membrane of polarized epithelial cells. Thereby, the device allowed us for the first time to monitor individual fusion events of GPI-GFP bearing vesicles at the apical membrane in live Madin-Darby canine kidney II (MDCK II) cells. Moreover, a mapping of fusion sites became feasible and revealed that the whole apical membrane is fusion competent. In total, the biochip offers an all-in-one solution for apical TIRF microscopy and contributes a novel tool to study trafficking processes close to the apical plasma membrane in polarized epithelial cells.

Spatial regulation of Fus3 MAP kinase activity through a reaction-diffusion mechanism in yeast pheromone signalling.

Signal transduction through mitogen-activated protein kinase (MAPK) cascades is thought to occur through the assembly of macromolecular complexes. We quantified the abundance of complexes in the cytoplasm among the MAPKs Ste11, Ste7, Fus3 and the scaffold protein Ste5 in yeast pheromone signalling using fluorescence cross-correlation spectroscopy (FCCS). Significant complex concentrations were observed that remained unchanged on pheromone stimulation, demonstrating that global changes in complex abundances do not contribute to the transmission of signal through the cytoplasm. On the other hand, investigation of the distribution of active Fus3 (Fus3(PP)) across the cytoplasm using fluorescence lifetime imaging microscopy (FLIM) revealed a gradient of Fus3(PP) activity emanating from the tip of the mating projection. Spatial partitioning of Fus3 activating kinases to this site and deactivating phosphatases in the cytoplasm maintain this Fus3(PP)-activity distribution. Propagation of signalling from the shmoo is, therefore, spatially constrained by a gradient-generating reaction-diffusion mechanism.