scholarly journals Pushing for answers: is myosin V directly involved in moving mitochondria?

2008 ◽  
Vol 181 (1) ◽  
pp. 15-18 ◽  
Author(s):  
Rajeshwari R. Valiathan ◽  
Lois S. Weisman
Keyword(s):  
Cell Division ◽  
Light Chain ◽  
Budding Yeast ◽  
Myosin V ◽  
Class V ◽  
Mitochondrial Transport ◽  
Direct Involvement ◽  
Cell Biol ◽  
Myosin Motors

In budding yeast, the actin-based class V myosin motors, Myo2 and Myo4, transport virtually all organelles from mother to bud during cell division. Until recently, it appeared that mitochondria may be an exception, with studies showing that the Arp2/3 complex is required for their movement. However, several recent studies have proposed that Myo2 has a direct involvement in mitochondria inheritance. In this issue, Altmann et al. (Altmann, K., M. Frank, D. Neumann, S. Jakobs, and B. Westermann. 2008. J. Cell Biol. 181:119–130) provide the strongest support yet that Myo2 and its associated light chain Mlc1 function directly and significantly in both mitochondria–actin interactions and in the movement of mitochondria from mother to bud. The conflicting functions of Arp 2/3 and Myo2 may be reconciled by the existence of multiple pathways involved in mitochondrial transport.

scholarly journals A new piece in the kinetochore jigsaw puzzle

2014 ◽  
Vol 206 (4) ◽  
pp. 457-459
Author(s):  
Kevin D. Corbett ◽  
Arshad Desai
Keyword(s):  
Cell Division ◽  
Signaling Pathways ◽  
Chromosome Segregation ◽  
Budding Yeast ◽  
Eukaryotic Cell ◽  
Jigsaw Puzzle ◽  
New Model ◽  
Cell Biol ◽  
Chromosome Attachment ◽  
Spindle Microtubules

In eukaryotic cell division, the kinetochore mediates chromosome attachment to spindle microtubules and acts as a scaffold for signaling pathways, ensuring the accuracy of chromosome segregation. The architecture of the kinetochore underlies its function in mitosis. In this issue, Hornung et al. (2014. J. Cell Biol. http://dx.doi.org/201403081) identify an unexpected linkage between the inner and outer regions of the kinetochore in budding yeast that suggests a new model for the construction of this interface.

scholarly journals Myosin Motors and Not Actin Comets Are Mediators of the Actin-based Golgi-to-Endoplasmic Reticulum Protein Transport

2003 ◽  
Vol 14 (2) ◽  
pp. 445-459 ◽  
Author(s):  
Juan M. Durán ◽  
Ferran Valderrama ◽  
Susana Castel ◽  
Juana Magdalena ◽  
Mónica Tomás ◽  
...  
Keyword(s):  
Endoplasmic Reticulum ◽  
Golgi Complex ◽  
Light Chain ◽  
Shiga Toxin ◽  
Actin Filaments ◽  
Protein Transport ◽  
Myosin Ii ◽  
Nonmuscle Myosin ◽  
Nonmuscle Myosin Ii ◽  
Myosin Motors

We have previously reported that actin filaments are involved in protein transport from the Golgi complex to the endoplasmic reticulum. Herein, we examined whether myosin motors or actin comets mediate this transport. To address this issue we have used, on one hand, a combination of specific inhibitors such as 2,3-butanedione monoxime (BDM) and 1-[5-isoquinoline sulfonyl]-2-methyl piperazine (ML7), which inhibit myosin and the phosphorylation of myosin II by the myosin light chain kinase, respectively; and a mutant of the nonmuscle myosin II regulatory light chain, which cannot be phosphorylated (MRLC2AA). On the other hand, actin comet tails were induced by the overexpression of phosphatidylinositol phosphate 5-kinase. Cells treated with BDM/ML7 or those that express the MRLC2AA mutant revealed a significant reduction in the brefeldin A (BFA)-induced fusion of Golgi enzymes with the endoplasmic reticulum (ER). This delay was not caused by an alteration in the formation of the BFA-induced tubules from the Golgi complex. In addition, the Shiga toxin fragment B transport from the Golgi complex to the ER was also altered. This impairment in the retrograde protein transport was not due to depletion of intracellular calcium stores or to the activation of Rho kinase. Neither the reassembly of the Golgi complex after BFA removal nor VSV-G transport from ER to the Golgi was altered in cells treated with BDM/ML7 or expressing MRLC2AA. Finally, transport carriers containing Shiga toxin did not move into the cytosol at the tips of comet tails of polymerizing actin. Collectively, the results indicate that 1) myosin motors move to transport carriers from the Golgi complex to the ER along actin filaments; 2) nonmuscle myosin II mediates in this process; and 3) actin comets are not involved in retrograde transport.

N-Lobe Dynamics of Myosin Light Chain Dictates Its Mode of Interaction with Myosin V IQ1†

Biochemistry ◽  
2008 ◽  
Vol 47 (47) ◽  
pp. 12332-12345 ◽  
Author(s):  
Irene Amata ◽  
Mariana Gallo ◽  
Matteo Pennestri ◽  
Maurizio Paci ◽  
Antonella Ragnini-Wilson ◽  
...  
Keyword(s):  
Light Chain ◽  
Myosin Light Chain ◽  
Myosin V ◽  
Lobe Dynamics

scholarly journals Structural Changes in the Myosin Motors Induced by Stretch and Phosphorylation of the Myosin Regulatory Light Chain in Rat Cardiac Trabeculae

2021 ◽  
Vol 120 (3) ◽  
pp. 251a-252a
Author(s):  
So-Jin Park-Holohan ◽  
Elisabetta Brunello ◽  
Thomas Kampourakis ◽  
Martin Rees ◽  
Malcolm Irving ◽  
...  
Keyword(s):  
Light Chain ◽  
Structural Changes ◽  
Regulatory Light Chain ◽  
Myosin Regulatory Light Chain ◽  
Myosin Motors

scholarly journals Investigating molecular crowding during cell division and hyperosmotic stress in budding yeast with FRET

2021 ◽  
pp. 75-118
Author(s):  
Sarah Lecinski ◽  
Jack W. Shepherd ◽  
Lewis Frame ◽  
Imogen Hayton ◽  
Chris MacDonald ◽  
...  
Keyword(s):  
Cell Division ◽  
Budding Yeast ◽  
Hyperosmotic Stress ◽  
Molecular Crowding

Phenotypic consequences of tubulin overproduction in Saccharomyces cerevisiae: differences between alpha-tubulin and beta-tubulin

1990 ◽  
Vol 10 (10) ◽  
pp. 5295-5304
Author(s):  
B Weinstein ◽  
F Solomon
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Cell Division ◽  
Microtubule Assembly ◽  
Beta Tubulin ◽  
Alpha Tubulin ◽  
Tubulin Genes ◽  
Data Support ◽  
Cell Biol

Overexpression of alpha- and beta-tubulin genes in Saccharomyces cerevisiae, separately or together, leads to accumulation of large excesses of each of the polypeptides and arrest of cell division. However, other consequences of overexpression of these genes differ in several ways. As shown previously (D. Burke, P. Gasdaska, and L. Hartwell, Mol. Cell. Biol. 9:1049-1059, 1989), overexpression of beta-tubulin leads, at early times, to loss of microtubule structures and loss of viability. Eventually, the excess beta-tubulin forms abnormal structures. We show here that, in contrast, overexpression of alpha-tubulin led to none of these phenotypes and in fact could suppress each of the phenotypes associated with beta-tubulin accumulation. Truncated forms of beta-tubulin that were not competent to carry out microtubule functions also failed to elicit the beta-tubulin-specific phenotypes when overexpressed. The data support the hypothesis that beta-tubulin in excess over alpha-tubulin is uniquely toxic, perhaps because it interferes with normal microtubule assembly.

scholarly journals The regulatory light chain mediates inactivation of myosin motors during active shortening of cardiac muscle

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Thomas Kampourakis ◽  
Malcolm Irving
Keyword(s):  
Light Chain ◽  
Heart Muscle ◽  
Muscle Cells ◽  
Normal Function ◽  
Regulatory Light Chain ◽  
Terminal Domain ◽  
Venous Filling ◽  
Heart Muscle Cells ◽  
Underlying Mechanisms ◽  
Myosin Motors

AbstractThe normal function of heart muscle depends on its ability to contract more strongly at longer length. Increased venous filling stretches relaxed heart muscle cells, triggering a stronger contraction in the next beat- the Frank-Starling relation. Conversely, heart muscle cells are inactivated when they shorten during ejection, accelerating relaxation to facilitate refilling before the next beat. Although both effects are essential for the efficient function of the heart, the underlying mechanisms were unknown. Using bifunctional fluorescent probes on the regulatory light chain of the myosin motor we show that its N-terminal domain may be captured in the folded OFF state of the myosin dimer at the end of the working-stroke of the actin-attached motor, whilst its C-terminal domain joins the OFF state only after motor detachment from actin. We propose that sequential folding of myosin motors onto the filament backbone may be responsible for shortening-induced de-activation in the heart.

scholarly journals Abundances of transcripts, proteins, and metabolites in the cell cycle of budding yeast reveal coordinate control of lipid metabolism

2020 ◽  
Vol 31 (10) ◽  
pp. 1069-1084 ◽  
Author(s):  
Heidi M. Blank ◽  
Ophelia Papoulas ◽  
Nairita Maitra ◽  
Riddhiman Garge ◽  
Brian K. Kennedy ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Lipid Metabolism ◽  
Cell Division ◽  
Yeast Cell ◽  
Budding Yeast ◽  
Yeast Cells ◽  
Dynamic Changes ◽  
Coordinate Control ◽  
Cycle Dependent ◽  
Budding Yeast Cell Cycle

In several systems, including budding yeast, cell cycle-dependent changes in the transcriptome are well studied. In contrast, few studies queried the proteome during cell division. There is also little information about dynamic changes in metabolites and lipids in the cell cycle. Here, the authors present such information for dividing yeast cells.

scholarly journals Specific Inhibition of Elm1 Kinase Activity Reveals Functions Required for Early G1 Events

2003 ◽  
Vol 23 (17) ◽  
pp. 6327-6337 ◽  
Author(s):  
Aparna Sreenivasan ◽  
Anthony C. Bishop ◽  
Kevan M. Shokat ◽  
Douglas R. Kellogg
Keyword(s):  
Cell Cycle ◽  
Cell Division ◽  
Cell Growth ◽  
Kinase Activity ◽  
Budding Yeast ◽  
Specific Inhibition ◽  
Bud Emergence ◽  
Wee1 Kinase ◽  
Yeast Homolog

ABSTRACT In budding yeast, the Elm1 kinase is required for coordination of cell growth and cell division at G2/M. Elm1 is also required for efficient cytokinesis and for regulation of Swe1, the budding yeast homolog of the Wee1 kinase. To further characterize Elm1 function, we engineered an ELM1 allele that can be rapidly and selectively inhibited in vivo. We found that inhibition of Elm1 kinase activity during G2 results in a phenotype similar to the phenotype caused by deletion of the ELM1 gene, as expected. However, inhibition of Elm1 kinase activity earlier in the cell cycle results in a prolonged G1 delay. The G1 requirement for Elm1 kinase activity occurs before bud emergence, polarization of the septins, and synthesis of G1 cyclins. Inhibition of Elm1 kinase activity during early G1 also causes defects in the organization of septins, and inhibition of Elm1 kinase activity in a strain lacking the redundant G1 cyclins CLN1 and CLN2 is lethal. These results demonstrate that the Elm1 kinase plays an important role in G1 events required for bud emergence and septin organization.

scholarly journals Spindle-independent condensation-mediated segregation of yeast ribosomal DNA in late anaphase

2005 ◽  
Vol 168 (2) ◽  
pp. 209-219 ◽  
Author(s):  
Félix Machín ◽  
Jordi Torres-Rosell ◽  
Adam Jarmuz ◽  
Luis Aragón
Keyword(s):  
Cell Division ◽  
Ribosomal Dna ◽  
Budding Yeast ◽  
Mitotic Cell ◽  
Yeast Genome ◽  
Daughter Cells ◽  
Late Anaphase ◽  
Mother And Daughter ◽  
The Right ◽  
Chromosome Resolution

Mitotic cell division involves the equal segregation of all chromosomes during anaphase. The presence of ribosomal DNA (rDNA) repeats on the right arm of chromosome XII makes it the longest in the budding yeast genome. Previously, we identified a stage during yeast anaphase when rDNA is stretched across the mother and daughter cells. Here, we show that resolution of sister rDNAs is achieved by unzipping of the locus from its centromere-proximal to centromere-distal regions. We then demonstrate that during this stretched stage sister rDNA arrays are neither compacted nor segregated despite being largely resolved from each other. Surprisingly, we find that rDNA segregation after this period no longer requires spindles but instead involves Cdc14-dependent rDNA axial compaction. These results demonstrate that chromosome resolution is not simply a consequence of compacting chromosome arms and that overall rDNA compaction is necessary to mediate the segregation of the long arm of chromosome XII.

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