In plant cells, for example ... However, thanks to the state-of-the-art cryo-electron microscopes, the researchers have now been able to gain new insights into the interaction between Vipp1 ...

Imaging wall-less plant cells every six minutes for 24 hours revealed how the cells build their protective barriers.

Advanced techniques are allowing scientists to witness the process where plant cells generate cellulose fibers.

Plant cells crammed with chloroplasts ... to places we'd never seen before - the electron microscope. The specimen is put in a vacuum and is viewed not by light waves but by a single beam of ...

Proteins in the sheath of cellular protrusions control how effectively cells can adhere to surfaces. Biological cells often ...

The way we study plant cells ... a standard microscope. So, instead of a zoomed-in picture where individual elements may become blurred or distorted, the physical size of the cells increases ...

The diagram below shows the same plant cell, as viewed with the light microscope, and with the transmission electron microscope. Animal and plant cells have certain structures in common.

In plant and other photosynthetic cells ... which in turn aggregate into particles that are observable via electron microscopy. A cell can rapidly mobilize these particles whenever it needs ...

In their article published in Nature, the Monash team used cryo‐electron microscopy ... The GPCR and plant-like transporter work together to sense cholesterol and regulate cell growth, thus ...

Biological cells often possess thin, hair-like protrusions on their surface known as cilia, which serve various functions ranging from movement to sensing environmental signals. Researchers from ...

In a groundbreaking study on the synthesis of cellulose -- a major constituent of all plant cell walls -- a team has captured images of the microscopic process of cell-wall building continuously over ...