Successive detection of insulin-like growth factor-II bound to receptors on a living cell surface using an AFM.

In this study, we have developed a method of mechanical force detection for ligands bound to receptors on a cell surface, both of which are involved in a signal transduction pathway. This pathway is an autocrine pathway, involving the production of insulin-like growth factor-II (IGF-II) and activation of the IGF-I receptor, involved in myoblast differentiation induced by MyoD in C3H10T1/2 mouse mesenchymal stem cells. Differentiation of C3H10T1/2 was induced with the DNA demethylation agent 5-azacytidine (5-aza). The etched AFM tip used in the force detection had a flat surface of which about 10 µm(2) was in contact with a cell surface. The forces required to rupture the interactions of IGF-IIs on a cell and anti mouse IGF-II polyclonal antibody immobilized on an etched AFM tip were measured within 5 days of induction of differentiation. The mean unbinding force for a single paired antibody-ligand on a cell was about 81 pN, which was measured at a force loading rate of about 440 nN/s. The percentage of unbinding forces over 100 pN increased to 32% after 2 days from the addition of 5-aza to the medium. This method could be used in non-invasive and successive evaluation of a living cell's behavior.

Evaluation of the actin cytoskeleton state using an antibody-functionalized nanoneedle and an AFM.

A cell diagnosis technique was developed, which uses an Atomic Force Microscope (AFM) and an ultra-thin AFM probe sharpened to a diameter of 200 nm (nanoneedle). Due to the high aspect ratio of the nanoneedle, it was successfully inserted into a living cell without affecting its viability. Furthermore, by functionalizing the nanoneedle with specific antibodies and measuring the unbinding forces ('fishing forces') during evacuation of the nanoneedle from the cell, it was possible to measure specific mechanical interactions between the antibody-functionalized nanoneedle and the intracellular contents of the cell. In this study, an anti-actin-antibody-functionalized nanoneedle was used to evaluate the actin cytoskeleton state in living cells. To examine the effect of cytoskeleton condition on the measured fishing forces, the cytoskeleton-disrupting drugs cytochalasin D (cytD) and Y-27632 were used, showing a marked decrease in the measured fishing forces following incubation with either of the drugs. Furthermore, the technique was used to measure the time course changes in a single cell during incubation with cytD, showing a gradual time-dependent decrease in fishing forces. Even minute doses of the drugs, the effects of which were hardly evident by optical and fluorescence methods, could be clearly detected by the measurement of nanoneedle-protein fishing forces, pointing to the high sensitivity of this detection method. This technique may prove beneficial for the evaluation of cytoskeleton conditions in health and disease, and for the selection of specific cells according to their intracellular protein contents, without the need for introduction of marker proteins into the cell.

Mechanical force-based probing of intracellular proteins from living cells using antibody-immobilized nanoneedles.

We developed a method combining atomic force microscopy (AFM) and antibody-immobilized nanoneedles to discriminate living cells by probing intracellular cytoskeletal proteins without the need for cell labeling. The nanoneedles are ultra-thin AFM probes sharpened to 200 nm in diameter. While retracting a nanoneedle inserted into a cell, we measured the mechanical force needed to unbind the antibody-target protein complex. Using this method, the intermediate filament protein, nestin and neurofilament were successfully detected in mouse embryonic carcinoma P19 cells and rat primary hippocampal cells within a minute for a single cell and cell differentiation states could be determined. Additionally, the measured magnitude of the force detecting nestin was indicative of the malignancy of breast cancer cells. This method was shown to affect neither the doubling time of cells nor does it leave extrinsic antibodies within the examined cells, allowing to be used in subsequent analyses in their native state.