Linkam Scientific Launch New Cryo-Correlative Cooling Stage

Market leaders in temperature controlled microscopy, Linkam Scientific Instruments, have developed a stage for cryo-correlative light/electron microscopy (cryo-CLEM), a breakthrough in the imaging of cells at cryo temperatures.

Linkam's new stage for cryo-correlative light/electron microscopy (cryo-CLEM)

Linkam are pleased to announce the development and launch of a stage for cryo-correlative light/electron microscopy (cryo-CLEM). It was designed in collaboration with scientists at the Leiden University Medical Centre (LUMC) led by Bram Koster and Erik Bos. Cryo-CLEM is the correlation of images captured with a cryostage on a fluorescent light microscope and images of the same sample observed with Transmission Electron Microscopy (TEM).

Dr Lucy Collinson of the London Research Institute (LRI) and Cancer Research UK (CRUK), is using the correlative stage as part of a workflow that starts with cells expressing cancer-related genes and ends with imaging in synchrotrons located in Oxford, Berlin, and Barcelona. Within the synchrotrons, the scientists are able to image the cells using a cutting-edge technique called 'soft X-ray tomography'. The LRI focuses on three themes of research: the biology of tissues and tumours, cellular regulatory mechanisms and genomic integrity & cell cycle.

The correlative stage can hold samples at a stable -196°C enabling scientists to study TEM grid samples at 100x magnification, identifying areas of further interest, and facilitating the movement of these analysed grids to the TEM. With automated liquid nitrogen control, heated optics and a digital display the unit is a compact and efficient system for this work.

In particular, Dr Collinson is working with Dr. Sharon Tooze, Head of the Secretory Pathways Laboratory at the LRI, to study cells that are undergoing autophagy (or 'self-eating'), which is a normal process involving degradation and recycling of unnecessary or dysfunctional cell components. Autophagy is upregulated when cells are starved and plays a fundamental role in a large number of cellular processes including development, immunity, cancer and neurodegeneration. The Tooze Lab studies proteins involved in the autophagy process by linking them to fluorescent markers and expressing them in cells.

With Dr. Liz Duke, a Principal Beamline Scientist at the Diamond Light Source synchrotron in Oxfordshire, they have developed a process for imaging these fluorescent proteins in cells as close to their living state as possible, considering that they must place them in a vacuum to take very high magnification images. They grow the cells on very thin carbon films attached to a 3mm diameter gold grid and freeze the cells in liquid ethane at –174C. The correlative stage is used to image the fluorescence in the cells while they are still frozen. The frozen grids are then shipped to the synchrotron, where they put them into the soft X-ray microscope so that they can image the structure of the entire cell in 3D. They have already started to make new discoveries about how autophagy progresses, and will soon apply the technique to other important cancer-related projects.

Published on December 11, 2012 at 5:31 AM