捷克共和国Masaryk大学使用JPK公司的NanoWizard® 原子力显微镜和ForceRobot®全自动 图谱机械人系统研究生物分子间相互作用和细胞间相互作用。
JPK Instruments, a world-leading manufacturer of nanoanalytic
instrumentation for research in life sciences and soft matter, reports
on the Skládal Research Group at Masaryk University, Brno, Czech
Republic. They are studying biomolecules and cells with JPK’s
NanoWizard® AFM and ForceRobot® systems as part of a development of new
Dr Jan Pribyl is Deputy Group Leader in the research group of Professor Petr Skládal at Masaryk University, Brno in the Czech Republic. The main research aim of the group was to develop electrochemical and acoustic (QCM) biosensors. This provided the motivation to use AFM. The plan was to use this high resolution imaging technique to visualize biomolecules, nanoparticles and/or other nanostructured objects on the surface of solid, non-transparent biosensor transducers (electrodes). This work started some nine years ago but the main step forward occurred with the purchase of the JPK NanoWizard® AFM and ForceRobot® in 2014. These are located at the Nanobio Core Facility, part of CEITEC. Used intensively for over three years now, they provided the combination of AFM with an inverted optical microscope, a sophisticated system that enabled force-mapping which allowed the group to start intensive research on living cell cultures. The key difference of the JPK systems from other AFMs available in the laboratory has been the ability to easily image bio samples in liquid.
The work to date has looked at various types of sample. These include cardiomyocytes – where the biomechanical properties such as force and beating rate can easily recorded by AFM when used with a properly calibrated cantilever on the surface of the cardiomyocyte cluster. Cluster may be kept in a standard Petri dish, held by JPK’s PetriDishHeater™. The contents of the Petri dish can be changed using integrated tubes which enable solutions of drugs affecting cardiomyocyte properties to be studied such as the effect of various compounds on biomechanical properties of different types of cardiomyocytes.
Another sample set was CAL51 (a breast cancer cell line) - Hippo effectors YAP/TAZ act as on–off mechanosensing switches by sensing modifications in extracellular matrix (ECM) composition and mechanics. The group has used AFM nanoindentation to monitor changes in cellular stiffness, when the activity of these switches was affected.
The effect of the mechanical properties of supporting materials on the stiffness of fibroblasts grown on such surface has been investigated. Other parameters, such as cell morphology and actin fiber structure are evaluated simultaneously. Also, the mechanical properties of young plants in the area of hypocotyl and roots may be studied to illustrate differences between different plant mutants. These experiments are performed on living plant organisms under near in-vivo conditions. These and other experiments have been written up and published – see references below.
Asked about the reasons he likes to use the NanoWizard®, Dr Pribyl had much to say. “First of all, the combination with optical (fluorescence) microscopy must be mentioned. We mostly use the JPK AFM system work with living cells, where the optical image is essential. Fluorescence emission is monitored, when cells with expressed YFP/GFP protein are localized. We are upgrading our Olympus microscope with an Andor Zyla sCMOS camera which can be interfaced with the JPK software allowing direct overlay of optical and AFM images. This will bring us a new potential for cell research.” Other key benefits he gets from the system include robustness of operation when imaging/analysing hundreds of cells in a year.
The QI™ mode (quantitative imaging) is more than just a quantitative approach. As Dr Pribyl says, “I personally appreciate the precise driving of the tip contact with the sample in each point of the visualized area by keeping the constant force during the short force-distance curve measurements. This is especially useful for so called 'problematic' samples, such as elastic materials (cells, hydrogels, etc.), where it is not easy to perform imaging using the standard imaging modes such as contact and AC mode.”
YAP regulates cell mechanics by controlling focal adhesion assembly Nardone, Pribyl et al, NATURE COMMUNICATIONS 8: 15321.
Atomic force microscopy combined with human pluripotent stem cell derived cardiomyocytes for biomechanical sensing Pesl, Pribyl et al, Biosensors and Bioelectronics 85 (2016): 751–757.