During development, the axons of neurons in the mammalian central nervous system lose their ability to regenerate after injury. In order to study the regeneration process, we used a laser dissector system based on a sub-nanosecond pulsed UVA laser to inflict a partial damage to the axon of mouse hippocampal neurons. The use of such laser gives the possibility to deliver very low average power to the sample to be ablated. Therefore, the collateral damage due to temperature rise was reduced and for the first time, we were able to manipulate the neurite of cultured mouse neurons during the first days in vitro with sub-cellular precision. Force spectroscopy measurements were performed in parallel during and after the partial ablation of the neurite, by the use of a bead attached to the neurite membrane and held in an optical trap. The sub-piconewton and millisecond resolution of the force spectroscopy measurements allowed to quantify the damage inflicted to the process and to monitor the viscoelastic properties of the axonal membrane during regeneration. The reorganization and regeneration of the axon was documented by long-term (24-48 hours) bright-field live imaging using an optical microscope equipped with a custom-built cell culture incubator.
Articles tagged with: cytoskleton
During morphogenesis, neuronal precursor cells migrate from the zone where they are born to their final destination, which, in some cases, is at a distance of several millimeters. After reaching their destination, neurons must establish appropriate synaptic connections by sending out from their soma projections called neurites. The motion of neurites is guided by growth cones located at their tips. Growth cones contain a variety of chemical and
mechanical receptors and sophisticated biochemical machinery that couples these receptors to the cytoskeleton. Extruding from the tip of the growth cone are highly motile structures called filopodia and lamellipodia that are used to explore and probe the environment. All these complex events, which are at the basis of neuronal development and differentiation, involve cell motility requiring a precise control of cellular and molecular motors.
We study, by optical tweezers and force spectroscopy, the dynamic of cytoskeletal elements in the growth cone, and how the growth cone navigate in a controlled mechano-chemical micro-enviroment.