scholarly journals Mutational analysis of phosphorylation sites in the Dictyostelium myosin II tail: disruption of myosin function by a single charge change

FEBS Letters ◽  
2000 ◽  
Vol 466 (2-3) ◽  
pp. 267-272 ◽  
Author(s):  
Steffen Nock ◽  
Wenchuan Liang ◽  
Hans M Warrick ◽  
James A Spudich
Keyword(s):  
Mutational Analysis ◽  
Myosin Ii ◽  
Phosphorylation Sites ◽  
Single Charge ◽  
Dictyostelium Myosin ◽  
Charge Change

scholarly journals Identification of three phosphorylation sites on each heavy chain of Acanthamoeba myosin II.

1981 ◽  
Vol 256 (24) ◽  
pp. 12811-12816 ◽  
Author(s):  
G.P. Côté ◽  
J.H. Collins ◽  
E.D. Korn
Keyword(s):  
Heavy Chain ◽  
Myosin Ii ◽  
Phosphorylation Sites

scholarly journals Raf-1 activation disrupts its binding to keratins during cell stress

2004 ◽  
Vol 166 (4) ◽  
pp. 479-485 ◽  
Author(s):  
Nam-On Ku ◽  
Haian Fu ◽  
M. Bishr Omary
Keyword(s):  
Cell Signaling ◽  
Kinase Activity ◽  
Cultured Cells ◽  
Mutational Analysis ◽  
Cell Stress ◽  
Phosphorylation Sites ◽  
Dependent Manner ◽  
Raf Kinase ◽  
Toxin Exposure ◽  
Keratin 14

Keratins 8 and 18 (K8/18) heteropolymers may regulate cell signaling via the known K18 association with 14-3-3 proteins and 14-3-3 association with Raf-1 kinase. We characterized Raf–keratin–14-3-3 associations and show that Raf associates directly with K8, independent of Raf kinase activity or Ras–Raf interaction, and that K18 is a Raf physiologic substrate. Raf activation during oxidative and toxin exposure in cultured cells and animals disrupt keratin–Raf association in a phosphorylation-dependent manner. Mutational analysis showed that 14-3-3 residues that are essential for Raf binding also regulate 14-3-3–keratin association. Similarly, Raf phosphorylation sites that are important for binding to 14-3-3 are also essential for Raf binding to K8/18. Therefore, keratins may modulate some aspects of Raf signaling under basal conditions via sequestration by K8, akin to Raf–14-3-3 binding. Keratin-bound Raf kinase is released upon Raf hyperphosphorylation and activation during oxidative and other stresses.

Role of myosin II tail sequences in its function and localization at the cleavage furrow in Dictyostelium

1999 ◽  
Vol 112 (13) ◽  
pp. 2195-2201 ◽  
Author(s):  
S. Shu ◽  
R.J. Lee ◽  
J.M. LeBlanc-Straceski ◽  
T.Q. Uyeda
Keyword(s):  
Myosin Head ◽  
Myosin Ii ◽  
Equatorial Region ◽  
Chain Gene ◽  
Cleavage Furrow ◽  
Tail Domain ◽  
Specific Domain ◽  
Dictyostelium Myosin ◽  
Skeletal Myosin

Cytoplasmic myosin II accumulates in the cleavage furrow and provides the force for cytokinesis in animal and amoeboid cells. One model proposes that a specific domain in the myosin II tail is responsible for its localization, possibly by interacting with a factor concentrated in the equatorial region. To test this possibility, we have expressed myosins carrying mutations in the tail domain in a strain of Dictyostelium cells from which the endogenous myosin heavy chain gene has been deleted. The mutations used in this study include four internal tail deletions: Mydelta824-941, Mydelta943-1464, Mydelta943-1194 and Mydelta1156-1464. Contrary to the prediction of the hypothesis, immunofluorescence staining demonstrated that all mutant myosins were able to move toward the furrow region. Chimeric myosins, which consisted of a Dictyostelium myosin head and chicken skeletal myosin tail, also efficiently localized to the cleavage furrow. All these deletion and chimeric mutant myosins, except for Mydelta943-1464, the largest deletion mutant, were able to support cytokinesis in suspension. Our data suggest that there is no single specific domain in the tail of Dictyostelium myosin II that is required for its functioning at and localization to the cleavage furrow.

scholarly journals Myosin IIB assembly state determines its mechanosensitive dynamics

2019 ◽  
Vol 218 (3) ◽  
pp. 895-908 ◽  
Author(s):  
Eric S. Schiffhauer ◽  
Yixin Ren ◽  
Vicente A. Iglesias ◽  
Priyanka Kothari ◽  
Pablo A. Iglesias ◽  
...  
Keyword(s):  
Mathematical Modeling ◽  
Cell Shape ◽  
Cellular Response ◽  
Myosin Ii ◽  
3T3 Cells ◽  
Dictyostelium Myosin ◽  
Highly Sensitive ◽  
Key Players ◽  
Nih 3T3 ◽  
Shape Changes

Dynamical cell shape changes require a highly sensitive cellular system that can respond to chemical and mechanical inputs. Myosin IIs are key players in the cell’s ability to react to mechanical inputs, demonstrating an ability to accumulate in response to applied stress. Here, we show that inputs that influence the ability of myosin II to assemble into filaments impact the ability of myosin to respond to stress in a predictable manner. Using mathematical modeling for Dictyostelium myosin II, we predict that myosin II mechanoresponsiveness will be biphasic with an optimum established by the percentage of myosin II assembled into bipolar filaments. In HeLa and NIH 3T3 cells, heavy chain phosphorylation of NMIIB by PKCζ, as well as expression of NMIIA, can control the ability of NMIIB to mechanorespond by influencing its assembly state. These data demonstrate that multiple inputs to the myosin II assembly state integrate at the level of myosin II to govern the cellular response to mechanical inputs.

scholarly journals Identification of key phosphorylation sites in PTH1R that determine arrestin3 binding and fine-tune receptor signaling

2016 ◽  
Vol 473 (22) ◽  
pp. 4173-4192 ◽  
Author(s):  
Diana Zindel ◽  
Sandra Engel ◽  
Andrew R. Bottrill ◽  
Jean-Philippe Pin ◽  
Laurent Prézeau ◽  
...  
Keyword(s):  
Energy Transfer ◽  
G Protein ◽  
Mutational Analysis ◽  
Resonance Energy Transfer ◽  
Resonance Energy ◽  
Receptor Activation ◽  
Phosphorylation Sites ◽  
Parathyroid Hormone Receptor ◽  
Extracellular Signal ◽  
G Protein Coupled

The parathyroid hormone receptor 1 (PTH1R) is a member of family B of G-protein-coupled receptors (GPCRs), predominantly expressed in bone and kidney where it modulates extracellular Ca2+ homeostasis and bone turnover. It is well established that phosphorylation of GPCRs constitutes a key event in regulating receptor function by promoting arrestin recruitment and coupling to G-protein-independent signaling pathways. Mapping phosphorylation sites on PTH1R would provide insights into how phosphorylation at specific sites regulates cell signaling responses and also open the possibility of developing therapeutic agents that could target specific receptor functions. Here, we have used mass spectrometry to identify nine sites of phosphorylation in the C-terminal tail of PTH1R. Mutational analysis revealed identified two clusters of serine and threonine residues (Ser489–Ser495 and Ser501–Thr506) specifically responsible for the majority of PTH(1–34)-induced receptor phosphorylation. Mutation of these residues to alanine did not affect negatively on the ability of the receptor to couple to G-proteins or activate extracellular-signal-regulated kinase 1/2. Using fluorescence resonance energy transfer and bioluminescence resonance energy transfer to monitor PTH(1–34)-induced interaction of PTH1R with arrestin3, we show that the first cluster Ser489–Ser495 and the second cluster Ser501–Thr506 operated in concert to mediate both the efficacy and potency of ligand-induced arrestin3 recruitment. We further demonstrate that Ser503 and Thr504 in the second cluster are responsible for 70% of arrestin3 recruitment and are key determinants for interaction of arrestin with the receptor. Our data are consistent with the hypothesis that the pattern of C-terminal tail phosphorylation on PTH1R may determine the signaling outcome following receptor activation.

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