scholarly journals A novel split kinesin assay identifies motor proteins that interact with distinct vesicle populations

2012 ◽  
Vol 198 (4) ◽  
pp. 749-761 ◽  
Author(s):  
Brian Jenkins ◽  
Helena Decker ◽  
Marvin Bentley ◽  
Julie Luisi ◽  
Gary Banker
Keyword(s):  
Cell Biology ◽  
Hippocampal Neurons ◽  
Systematic Approach ◽  
Living Cells ◽  
Motor Domain ◽  
Challenging Problem ◽  
Experimental Paradigm ◽  
Kinesin Motor ◽  
Selective Transport ◽  
Cultured Hippocampal Neurons

Identifying the kinesin motors that interact with different vesicle populations is a longstanding and challenging problem with implications for many aspects of cell biology. Here we introduce a new live-cell assay to assess kinesin–vesicle interactions and use it to identify kinesins that bind to vesicles undergoing dendrite-selective transport in cultured hippocampal neurons. We prepared a library of “split kinesins,” comprising an axon-selective kinesin motor domain and a series of kinesin tail domains that can attach to their native vesicles; when the split kinesins were assembled by chemical dimerization, bound vesicles were misdirected into the axon. This method provided highly specific results, showing that three Kinesin-3 family members—KIF1A, KIF13A, and KIF13B—interacted with dendritic vesicle populations. This experimental paradigm allows a systematic approach to evaluate motor–vesicle interactions in living cells.

Application of FRAP and digitized fluorescence microscopy to problems in cell membrane dynamics

1988 ◽  
Vol 46 ◽  
pp. 118-119
Author(s):  
K. Jacobson ◽  
A. Ishihara ◽  
B. Holifield ◽  
F. Zhang
Keyword(s):  
Fluorescence Microscopy ◽  
Cell Biology ◽  
Extended Period ◽  
Dynamic Structure ◽  
Living Cells ◽  
Membrane Dynamics ◽  
Molecular Cell Biology ◽  
Image Averaging ◽  
Single Living Cells ◽  
Single Living

Our laboratory is concerned with understanding the dynamic structure of the plasma membrane with particular reference to the movement of membrane constituents during cell locomotion. In addition to the standard tools of molecular cell biology, we employ both fluorescence recovery after photo- bleaching (FRAP) and digitized fluorescence microscopy (DFM) to investigate individual cells. FRAP allows the measurement of translational mobility of membrane and cytoplasmic molecules in small regions of single, living cells. DFM is really a new form of light microscopy in that the distribution of individual classes of ions, molecules, and macromolecules can be followed in single, living cells. By employing fluorescent antibodies to defined antigens or fluorescent analogs of cellular constituents as well as ultrasensitive, electronic image detectors and video image averaging to improve signal to noise, fluorescent images of living cells can be acquired over an extended period without significant fading and loss of cell viability.

scholarly journals Cell penetration efficiency analysis of different atomic force microscopy nanoneedles into living cells

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Marcos Penedo ◽  
Tetsuya Shirokawa ◽  
Mohammad Shahidul Alam ◽  
Keisuke Miyazawa ◽  
Takehiko Ichikawa ◽  
...  
Keyword(s):  
Atomic Force Microscopy ◽  
Cell Membrane ◽  
Cell Biology ◽  
Cell Damage ◽  
Efficiency Analysis ◽  
Living Cells ◽  
Biomolecular Recognition ◽  
Cell Penetration ◽  
Force Microscopy ◽  
Atomic Force

AbstractOver the last decade, nanoneedle-based systems have demonstrated to be extremely useful in cell biology. They can be used as nanotools for drug delivery, biosensing or biomolecular recognition inside cells; or they can be employed to select and sort in parallel a large number of living cells. When using these nanoprobes, the most important requirement is to minimize the cell damage, reducing the forces and indentation lengths needed to penetrate the cell membrane. This is normally achieved by reducing the diameter of the nanoneedles. However, several studies have shown that nanoneedles with a flat tip display lower penetration forces and indentation lengths. In this work, we have tested different nanoneedle shapes and diameters to reduce the force and the indentation length needed to penetrate the cell membrane, demonstrating that ultra-thin and sharp nanoprobes can further reduce them, consequently minimizing the cell damage.

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