Hsp90 Protein in Fission Yeast Swo1p and UCS Protein Rng3p Facilitate Myosin II Assembly and Function

ABSTRACT The F-actin-based molecular motor myosin II is involved in a variety of cellular processes such as muscle contraction, cell motility, and cytokinesis. In recent years, a family of myosin II-specific cochaperones of the UCS family has been identified from work with yeasts, fungi, worms, and humans. Biochemical analyses have shown that a complex of Hsp90 and the Caenorhabditis elegans UCS domain protein UNC-45 prevent myosin head aggregation, thereby allowing it to assume a proper structure. Here we demonstrate that a temperature-sensitive mutant of the fission yeast Hsp90 (Swo1p), swo1-w1, is defective in actomyosin ring assembly at the restrictive temperature. Two alleles of swo1, swo1-w1 and swo1-26, showed synthetic lethality with a specific mutant allele of the fission yeast type II myosin head, myo2-E1, but not with two other mutant alleles of myo2 or with mutations affecting 14 other genes important for cytokinesis. swo1-w1 also showed a strong genetic interaction with rng3-65, a gene encoding a mutation in the fission yeast UCS domain protein Rng3p, which has previously been shown to be important for myosin II assembly. A similar deleterious effect was found when myo2-E1, swo1-w1, and rng3-65 were pharmacologically treated with geldanamycin to partially inhibit Hsp90 function. Interestingly, Swo1p-green fluorescent protein is detected at the improperly assembled actomyosin rings in myo2-E1 but not in a wild-type strain. Yeast two-hybrid and coimmunoprecipitation analyses verified interactions between Rng3p and the myosin head domain as well as interactions between Rng3p and Swo1p. Our analyses of Myo2p, Swo1p, and the UCS domain protein Rng3p establish that Swo1p and Rng3p collaborate in vivo to modulate myosin II function.

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The Mechanism of Replication of Single-Stranded DNA. VI. Requirements for Ribonucleoside Triphosphates and DNA Polymerase III

Canadian Journal of Biochemistry ◽

10.1139/o73-214 ◽

1973 ◽

Vol 51 (12) ◽

pp. 1588-1597 ◽

Cited By ~ 7

Author(s):

David T. Denhardt ◽

Makoto Iwaya ◽

Grant McFadden ◽

Gerald Schochetman

Keyword(s):

Dna Polymerase ◽

Dna Polymerases ◽

Temperature Sensitive ◽

Restrictive Temperature ◽

Dna Polymerase Iii ◽

Single Stranded Dna ◽

E Coli ◽

Polymerase Iii

Evidence is presented that in Escherichia coli made permeable to nucleotides by exposure to toluene, the synthesis of a DNA chain complementary to the infecting single-stranded DNA of bacteriophage [Formula: see text] requires ATP as well as the four deoxyribonucleoside triphosphates. This synthesis results in the formation of the parental double-stranded replicative-form (RF) molecule. The ATP is not required simply to prevent degradation of the ribonucleoside or deoxyribonucleoside triphosphates; it can be partially substituted for by other ribonucleoside triphosphates.No single one of the known E. coli DNA polymerases appears to be uniquely responsible in vivo for the formation of the parental RF. Since [Formula: see text] replicates well in strains lacking all, or almost all, of the in-vitro activities of DNA polymerases I and II, neither of these two enzymes would seem essential; and in a temperature-sensitive E. coli mutant (dnaEts) deficient in DNA polmerase-I activity and possessing a temperature-sensitive DNA polymerase III, the viral single-stranded DNA is efficiently incorporated into an RF molecule at the restrictive temperature. In contrast, both RF replication and progeny single-stranded DNA synthesis are dependent upon DNA polymerase III activity.

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Genetic Analysis of Yeast RPA1 Reveals Its Multiple Functions in DNA Metabolism

Genetics ◽

10.1093/genetics/148.3.989 ◽

1998 ◽

Vol 148 (3) ◽

pp. 989-1005 ◽

Cited By ~ 5

Author(s):

Keiko Umezu ◽

Neal Sugawara ◽

Clark Chen ◽

James E Haber ◽

Richard D Kolodner

Keyword(s):

Dna Replication ◽

Dna Binding ◽

Protein A ◽

Temperature Sensitive ◽

Restrictive Temperature ◽

Physical Analysis ◽

Single Stranded Dna ◽

Temperature Sensitive Mutants

Abstract Replication protein A (RPA) is a single-stranded DNA-binding protein identified as an essential factor for SV40 DNA replication in vitro. To understand the in vivo functions of RPA, we mutagenized the Saccharomyces cerevisiae RFA1 gene and identified 19 ultraviolet light (UV) irradiation- and methyl methane sulfonate (MMS)-sensitive mutants and 5 temperature-sensitive mutants. The UV- and MMS-sensitive mutants showed up to 104 to 105 times increased sensitivity to these agents. Some of the UV- and MMS-sensitive mutants were killed by an HO-induced double-strand break at MAT. Physical analysis of recombination in one UV- and MMS-sensitive rfa1 mutant demonstrated that it was defective for mating type switching and single-strand annealing recombination. Two temperature-sensitive mutants were characterized in detail, and at the restrictive temperature were found to have an arrest phenotype and DNA content indicative of incomplete DNA replication. DNA sequence analysis indicated that most of the mutations altered amino acids that were conserved between yeast, human, and Xenopus RPA1. Taken together, we conclude that RPA1 has multiple roles in vivo and functions in DNA replication, repair, and recombination, like the single-stranded DNA-binding proteins of bacteria and phages.

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Genetic suppression of defective profilin by attenuated Myosin II reveals a potential role for Myosin II in actin dynamics in vivo in fission yeast

Molecular Biology of the Cell ◽

10.1091/mbc.e20-04-0224 ◽

2020 ◽

Vol 31 (19) ◽

pp. 2107-2114 ◽

Cited By ~ 1

Author(s):

Paola Zambon ◽

Saravanan Palani ◽

Shekhar Sanjay Jadhav ◽

Pananghat Gayathri ◽

Mohan K. Balasubramanian

Keyword(s):

Fission Yeast ◽

Double Mutant ◽

Potential Role ◽

Myosin Ii ◽

Model Organism ◽

Actin Dynamics ◽

Mutant Analysis ◽

Genetic Suppression

This work reveals an in vivo role for Myosin II in actin dynamics, potentially in its disassembly and turnover. The work uses double mutant analysis to arrive at this conclusion using the fission yeast as a model organism.

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Interaction of the Endocytic Scaffold Protein Pan1 with the Type I Myosins Contributes to the Late Stages of Endocytosis

Molecular Biology of the Cell ◽

10.1091/mbc.e07-05-0436 ◽

2007 ◽

Vol 18 (8) ◽

pp. 2893-2903 ◽

Cited By ~ 29

Author(s):

Sarah L. Barker ◽

Linda Lee ◽

B. Daniel Pierce ◽

Lymarie Maldonado-Báez ◽

David G. Drubin ◽

...

Keyword(s):

Late Stage ◽

Actin Polymerization ◽

Fluorescent Protein ◽

Temperature Sensitive ◽

Type I ◽

Reading Frame ◽

Rich Domain ◽

C Terminus

The yeast endocytic scaffold Pan1 contains an uncharacterized proline-rich domain (PRD) at its carboxy (C)-terminus. We report that the pan1-20 temperature-sensitive allele has a disrupted PRD due to a frame-shift mutation in the open reading frame of the domain. To reveal redundantly masked functions of the PRD, synthetic genetic array screens with a pan1ΔPRD strain found genetic interactions with alleles of ACT1, LAS17 and a deletion of SLA1. Through a yeast two-hybrid screen, the Src homology 3 domains of the type I myosins, Myo3 and Myo5, were identified as binding partners for the C-terminus of Pan1. In vitro and in vivo assays validated this interaction. The relative timing of recruitment of Pan1-green fluorescent protein (GFP) and Myo3/5-red fluorescent protein (RFP) at nascent endocytic sites was revealed by two-color real-time fluorescence microscopy; the type I myosins join Pan1 at cortical patches at a late stage of internalization, preceding the inward movement of Pan1 and its disassembly. In cells lacking the Pan1 PRD, we observed an increased lifetime of Myo5-GFP at the cortex. Finally, Pan1 PRD enhanced the actin polymerization activity of Myo5–Vrp1 complexes in vitro. We propose that Pan1 and the type I myosins interactions promote an actin activity important at a late stage in endocytic internalization.

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Functional Characterization of the Fission Yeast Phosphatidylserine Synthase Gene, pps1, Reveals Novel Cellular Functions for Phosphatidylserine

Eukaryotic Cell ◽

10.1128/ec.00300-07 ◽

2007 ◽

Vol 6 (11) ◽

pp. 2092-2101 ◽

Cited By ~ 25

Author(s):

Yasuhiro Matsuo ◽

Edward Fisher ◽

Jana Patton-Vogt ◽

Stevan Marcus

Keyword(s):

Stationary Phase ◽

Fission Yeast ◽

Cell Morphology ◽

Fluorescent Protein ◽

Single Gene ◽

Functional Characterization ◽

Cellular Functions ◽

Phosphatidylserine Synthase

ABSTRACT To investigate the contributions of phosphatidylserine to the growth and morphogenesis of the rod-shaped fission yeast Schizosaccharomyces pombe, we have characterized the single gene in this organism, pps1, encoding a predicted phosphatidylserine synthase. S. pombe pps1Δ mutants grow slowly in rich medium and are inviable in synthetic minimal medium. They do not produce detectable phosphatidylserine in vivo and possess negligible in vitro phosphatidylserine synthase activity, indicating that pps1 encodes the major phosphatidylserine synthase activity in S. pombe. Supplementation of growth medium with ethanolamine partially suppresses the growth-defective phenotype of pps1Δ cells, reflecting the likely importance of phosphatidylserine as a precursor for phosphatidylethanolamine in S. pombe. In medium lacking ethanolamine, pps1Δ mutants exhibit striking cell morphology, cytokinesis, actin cytoskeleton, and cell wall remodeling and integrity defects. Overexpression of pps1 likewise leads to defects in cell morphology and cytokinesis, thus implicating phosphatidylserine as a dosage-dependent regulator of these processes. During log-phase growth, green fluorescent protein-Pps1p fusion proteins are concentrated at the cell and nuclear peripheries as well as presumptive endoplasmic reticulum membranes, while in stationary-phase cells, they are redistributed to unusual cytoplasmic structures of unknown origin. Moreover, stationary-phase pps1Δ cultures retain very poor viability relative to wild-type S. pombe cells, even in medium containing ethanolamine, demonstrating a role for phosphatidylserine in the physiological adaptations required for stationary-phase survival. Our findings reveal novel cellular functions for phosphatidylserine and emphasize the usefulness of S. pombe as a model organism for elucidating potentially conserved biological and molecular functions of this phospholipid.

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Saccharomyces cerevisiae Nip7p is required for efficient 60S ribosome subunit biogenesis.

Molecular and Cellular Biology ◽

10.1128/mcb.17.9.5001 ◽

1997 ◽

Vol 17 (9) ◽

pp. 5001-5015 ◽

Cited By ~ 67

Author(s):

N I Zanchin ◽

P Roberts ◽

A DeSilva ◽

F Sherman ◽

D S Goldfarb

Keyword(s):

Saccharomyces Cerevisiae ◽

Fluorescent Protein ◽

Open Reading Frames ◽

Growth Defect ◽

Temperature Sensitive ◽

Protein Fusion ◽

Acid Protein ◽

Conserved Gene ◽

Green Fluorescent

The Saccharomyces cerevisiae temperature-sensitive (ts) allele nip7-1 exhibits phenotypes associated with defects in the translation apparatus, including hypersensitivity to paromomycin and accumulation of halfmer polysomes. The cloned NIP7+ gene complemented the nip7-1 ts growth defect, the paromomycin hypersensitivity, and the halfmer defect. NIP7 encodes a 181-amino-acid protein (21 kDa) with homology to predicted products of open reading frames from humans, Caenorhabditis elegans, and Arabidopsis thaliana, indicating that Nip7p function is evolutionarily conserved. Gene disruption analysis demonstrated that NIP7 is essential for growth. A fraction of Nip7p cosedimented through sucrose gradients with free 60S ribosomal subunits but not with 80S monosomes or polysomal ribosomes, indicating that it is not a ribosomal protein. Nip7p was found evenly distributed throughout the cytoplasm and nucleus by indirect immunofluorescence; however, in vivo localization of a Nip7p-green fluorescent protein fusion protein revealed that a significant amount of Nip7p is present inside the nucleus, most probably in the nucleolus. Depletion of Nip7-1p resulted in a decrease in protein synthesis rates, accumulation of halfmers, reduced levels of 60S subunits, and, ultimately, cessation of growth. Nip7-1p-depleted cells showed defective pre-rRNA processing, including accumulation of the 35S rRNA precursor, presence of a 23S aberrant precursor, decreased 20S pre-rRNA levels, and accumulation of 27S pre-rRNA. Delayed processing of 27S pre-rRNA appeared to be the cause of reduced synthesis of 25S rRNA relative to 18S rRNA, which may be responsible for the deficit of 60S subunits in these cells.

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Implication of a novel multiprotein Dam1p complex in outer kinetochore function

The Journal of Cell Biology ◽

10.1083/jcb.200109063 ◽

2001 ◽

Vol 155 (7) ◽

pp. 1137-1146 ◽

Cited By ~ 133

Author(s):

Iain M. Cheeseman ◽

Christine Brew ◽

Michael Wolyniak ◽

Arshad Desai ◽

Scott Anderson ◽

...

Keyword(s):

Mitotic Spindle ◽

Fluorescent Protein ◽

Temperature Sensitive ◽

Temperature Sensitive Mutants ◽

Phosphorylation Event ◽

Spindle Microtubules ◽

Green Fluorescent ◽

Kinetochore Function

Dam1p, Duo1p, and Dad1p can associate with each other physically and are required for both spindle integrity and kinetochore function in budding yeast. Here, we present our purification from yeast extracts of an ∼245 kD complex containing Dam1p, Duo1p, and Dad1p and Spc19p, Spc34p, and the previously uncharacterized proteins Dad2p and Ask1p. This Dam1p complex appears to be regulated through the phosphorylation of multiple subunits with at least one phosphorylation event changing during the cell cycle. We also find that purified Dam1p complex binds directly to microtubules in vitro with an affinity of ∼0.5 μM. To demonstrate that subunits of the Dam1p complex are functionally important for mitosis in vivo, we localized Spc19–green fluorescent protein (GFP), Spc34-GFP, Dad2-GFP, and Ask1-GFP to the mitotic spindle and to kinetochores and generated temperature-sensitive mutants of DAD2 and ASK1. These and other analyses implicate the four newly identified subunits and the Dam1p complex as a whole in outer kinetochore function where they are well positioned to facilitate the association of chromosomes with spindle microtubules.

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A novel histone H4 mutant defective in nuclear division and mitotic chromosome transmission.

Molecular and Cellular Biology ◽

10.1128/mcb.16.3.1017 ◽

1996 ◽

Vol 16 (3) ◽

pp. 1017-1026 ◽

Cited By ~ 52

Author(s):

M M Smith ◽

P Yang ◽

M S Santisteban ◽

P W Boone ◽

A T Goldstein ◽

...

Keyword(s):

Mitotic Chromosome ◽

Nuclear Division ◽

Dna Recombination ◽

Chromosome Loss ◽

Temperature Sensitive ◽

Restrictive Temperature ◽

Histone H4 ◽

Eukaryotic Chromosome ◽

Chromosome Transmission

The histone proteins are essential for the assembly and function of th e eukaryotic chromosome. Here we report the first isolation of a temperature-sensitive lethal histone H4 mutant defective in mitotic chromosome transmission Saccharomyces cerevisiae. The mutant requires two amino acid substitutions in histone H4: a lethal Thr-to-Ile change at position 82, which lies within one of the DNA-binding surfaces of the protein, and a substitution of Ala to Val at position 89 that is an intragenic suppressor. Genetic and biochemical evidence shows that the mutant histone H4 is temperature sensitive for function but not for synthesis, deposition, or stability. The chromatin structure of 2 micrometer circle minichromosomes is temperature sensitive in vivo, consistent with a defect in H4-DNA interactions. The mutant also has defects in transcription, displaying weak Spt- phenotypes. At the restrictive temperature, mutant cells arrest in the cell cycle at nuclear division, with a large bud, a single nucleus with 2C DNA content, and a short bipolar spindle. At semipermissive temperatures, the frequency of chromosome loss is elevated 60-fold in the mutant while DNA recombination frequencies are unaffected. High-copy CSE4, encoding an H3 variant related to the mammalian CENP-A kinetochore antigen, was found to suppress the temperature sensitivity of the mutant without suppressing the Spt- transcription defect. These genetic, biochemical, and phenotypic results indicate that this novel histone H4 mutant defines one or more chromatin-dependent steps in chromosome segregation.

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Tropomyosin and Myosin-II Cellular Levels Promote Actomyosin Ring Assembly in Fission Yeast

Molecular Biology of the Cell ◽

10.1091/mbc.e09-10-0852 ◽

2010 ◽

Vol 21 (6) ◽

pp. 989-1000 ◽

Cited By ~ 55

Author(s):

Benjamin C. Stark ◽

Thomas E. Sladewski ◽

Luther W. Pollard ◽

Matthew Lord

Keyword(s):

Motor Activity ◽

Atpase Activity ◽

Fission Yeast ◽

Actin Filaments ◽

Myosin Ii ◽

Bound State ◽

Contractile Ring ◽

Ring Assembly

Myosin-II (Myo2p) and tropomyosin are essential for contractile ring formation and cytokinesis in fission yeast. Here we used a combination of in vivo and in vitro approaches to understand how these proteins function at contractile rings. We find that ring assembly is delayed in Myo2p motor and tropomyosin mutants, but occurs prematurely in cells engineered to express two copies of myo2. Thus, the timing of ring assembly responds to changes in Myo2p cellular levels and motor activity, and the emergence of tropomyosin-bound actin filaments. Doubling Myo2p levels suppresses defects in ring assembly associated with a tropomyosin mutant, suggesting a role for tropomyosin in maximizing Myo2p function. Correspondingly, tropomyosin increases Myo2p actin affinity and ATPase activity and promotes Myo2p-driven actin filament gliding in motility assays. Tropomyosin achieves this by favoring the strong actin-bound state of Myo2p. This mode of regulation reflects a role for tropomyosin in specifying and stabilizing actomyosin interactions, which facilitates contractile ring assembly in the fission yeast system.

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NHP6A and NHP6B, which encode HMG1-like proteins, are candidates for downstream components of the yeast SLT2 mitogen-activated protein kinase pathway.

Molecular and Cellular Biology ◽

10.1128/mcb.14.4.2391 ◽

1994 ◽

Vol 14 (4) ◽

pp. 2391-2403 ◽

Cited By ~ 79

Author(s):

C Costigan ◽

D Kolodrubetz ◽

M Snyder

Keyword(s):

Protein Kinase ◽

Synthetic Lethality ◽

Mapk Pathway ◽

Mitogen Activated Protein Kinase ◽

Growth Defect ◽

Temperature Sensitive ◽

Restrictive Temperature ◽

Mitogen Activated Protein ◽

Multiple Copies ◽

Delta Cells

The yeast SLK1 (BCK1) gene encodes a mitogen-activated protein kinase (MAPK) activator protein which functions upstream in a protein kinase cascade that converges on the MAPK Slt2p (Mpk1p). Dominant alleles of SLK1 have been shown to bypass the conditional lethality of a protein kinase C mutation, pkc1-delta, suggesting that Pkc1p may regulate Slk1p function. Slk1p has an important role in morphogenesis and growth control, and deletions of the SLK1 gene are lethal in a spa2-delta mutant background. To search for genes that interact with the SLK1-SLT2 pathway, a synthetic lethal suppression screen was carried out. Genes which in multiple copies suppress the synthetic lethality of slk1-1 spa2-delta were identified, and one, the NHP6A gene, has been extensively characterized. The NHP6A gene and the closely related NHP6B gene were shown previously to encode HMG1-like chromatin-associated proteins. We demonstrate here that these genes are functionally redundant and that multiple copies of either NHP6A or NHP6B suppress slk1-delta and slt2-delta. Strains from which both NHP6 genes were deleted (nhp6-delta mutants) share many phenotypes with pkc1-delta, slk1-delta, and slt2-delta mutants. nhp6-delta cells display a temperature-sensitive growth defect that is rescued by the addition of 1 M sorbitol to the medium, and they are sensitive to starvation. nhp6-delta strains also exhibit a variety of morphological and cytoskeletal defects. At the restrictive temperature for growth, nhp6-delta mutant cells contain elongated buds and enlarged necks. Many cells have patches of chitin staining on their cell surfaces, and chitin deposition is enhanced at the necks of budded cells. nhp6-delta cells display a defect in actin polarity and often accumulate large actin chunks. Genetic and phenotypic analysis indicates that NHP6A and NHP6B function downstream of SLT2. Our results indicate that the Slt2p MAPK pathway in Saccharomyces cerevisiae may mediate its function in cell growth and morphogenesis, at least in part, through high-mobility group proteins.

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