Multi-phosphorylation reaction and clustering tune Pom1 gradient mid-cell levels according to cell size

Autor: Lina Carlini, Thais Reichler, Suliana Manley, Anna Archetti, Charlotte Floderer, Veneta Gerganova, Sophie G. Martin, Laetitia Michon
Jazyk: angličtina
Rok vydání: 2019
Předmět:
0301 basic medicine
Cytoplasm
Cell
Cell Membrane/metabolism
Cytoplasm/enzymology
Phosphorylation
Protein Binding
Protein Kinases/analysis
Protein Kinases/metabolism
Protein Processing
Post-Translational

Protein-Serine-Threonine Kinases/metabolism
Schizosaccharomyces/enzymology
Schizosaccharomyces pombe Proteins/analysis
Schizosaccharomyces pombe Proteins/metabolism
Pom1 DYRK kinase
S. pombe
cell biology
cell size
concentration gradient
diffusion
single particle tracking PALM
protein-kinase
Plasma protein binding
localization
0302 clinical medicine
division
Biology (General)
0303 health sciences
biology
Chemistry
Kinase
General Neuroscience
General Medicine
cdr2
Membrane
medicine.anatomical_structure
microscopy
Medicine
family kinase pom1
Research Article
QH301-705.5
growth
Science
Protein Serine-Threonine Kinases
General Biochemistry
Genetics and Molecular Biology

Pom1
03 medical and health sciences
Schizosaccharomyces
medicine
fission
Mitosis
030304 developmental biology
mitosis
Total internal reflection fluorescence microscope
General Immunology and Microbiology
Cell growth
Cell Membrane
Cell Biology
biology.organism_classification
030104 developmental biology
Schizosaccharomyces pombe
Biophysics
Schizosaccharomyces pombe Proteins
Protein Kinases
030217 neurology & neurosurgery
Zdroj: eLife, Vol 8 (2019)
eLife, vol. 8, pp. e45983
eLife
Popis: Protein concentration gradients pattern developing organisms and single cells. In Schizosaccharomyces pombe rod-shaped cells, Pom1 kinase forms gradients with maxima at cell poles. Pom1 controls the timing of mitotic entry by inhibiting Cdr2, which forms stable membrane-associated nodes at mid-cell. Pom1 gradients rely on membrane association regulated by a phosphorylation-dephosphorylation cycle and lateral diffusion modulated by clustering. Using quantitative PALM imaging, we find individual Pom1 molecules bind the membrane too transiently to diffuse from pole to mid-cell. Instead, we propose they exchange within longer lived clusters forming the functional gradient unit. An allelic series blocking auto-phosphorylation shows that multi-phosphorylation shapes and buffers the gradient to control mid-cell levels, which represent the critical Cdr2-regulating pool. TIRF imaging of this cortical pool demonstrates more Pom1 overlaps with Cdr2 in short than long cells, consistent with Pom1 inhibition of Cdr2 decreasing with cell growth. Thus, the gradients modulate Pom1 mid-cell levels according to cell size.
eLife digest All organisms need to know how to arrange different cell types during the development of their organs and tissues. This information is provided by protein concentration patterns, or gradients, that tell cells how to behave based on where they are positioned. The same fundamental principles also work on a smaller scale. For example, although the rod-shaped yeast Schizosaccharomyces pombe is a single-celled organism, it uses protein concentration gradients to control its growth and timing of division. Before S. pombe cells divide, they need to check that they have reached the right size. Several mechanisms contribute to this information. One of them involves a concentration gradient of a protein known as Pom1, which is found on the cell membrane, with more protein at the cell extremities and less towards the middle. Pom1 serves to block the activity of Cdr2 – an enzyme that localizes to the cell middle and controls cell division. An open question has been whether Pom1 levels at the center drop as the cell grows, coordinating growth and division. One explanation for how the Pom1 gradient could be regulated is by the removal and addition of phosphate groups. At the cell’s tip, an enzyme removes phosphate groups from Pom1, causing it to bind to the membrane. As Pom1 diffuses along the membrane, it continuously ‘re-phosphorylates’ itself. This promotes Pom1 to gradually detach, restricting it from spreading along the membrane towards the cell middle. Another explanation is that clusters of Pom1, formed at the membrane, help establish a gradient by moving along the membrane at different rates: larger clusters, formed in high concentration areas, move slower than smaller clusters, causing levels of Pom1 to be higher at the tip, and lower towards the middle. Now, Gerganova et al. set out to find which of these two processes contributes more to shaping the Pom1 gradient, and determine where Pom1 acts on Cdr2. Gerganova et al. used super resolution microscopy to track individual Pom1 molecules inside yeast cells. This revealed two findings. First, that individual Pom1 molecules do not travel all the way from the cell tip to the center, but ‘hop’ between clusters as they move towards the middle. Second, in longer cells levels of Pom1 on the membrane drop at the center, where Pom1 encounters Cdr2. As a result, Cdr2 will come across higher levels of Pom1 in short cells, but low levels of Pom1 in long cells. This allows Pom1 to act as a measure of cell size, preventing short cells from dividing too soon. The role of clusters in creating gradients is not only relevant for yeast cell division. It could potentially apply to the gradients that organize cells and tissues in different organisms. Future work could examine whether similar principles apply in more complex systems.
Databáze: OpenAIRE