Long Terminal Repeat (LTR) Retrotransposons are an abundant class of genomic parasites that replicate by insertion of new copies into the host genome. Fungal LTR retrotransposons prevent mutagenic insertions through diverse targeting mechanisms that avoid coding sequences, but conserved principles guiding their target site selection have not been established. Here we show that insertion of the fission yeast LTR retrotransposon Tf1 is guided by the DNA binding protein Sap1, and that the efficiency and location of the targeting depend on the activity of Sap1 as a replication fork barrier. We propose that Sap1 and the fork arrest it causes guide insertion of Tf1 by tethering the integration complex to target sites.
Tropomyosin, a coiled-coil protein that binds along the length of the actin filament, is a universal regulator of the actin cytoskeleton. We have taken a bioinformatics/proteomic approach to studying structure-function relationships in this protein. The presence of a single, essential tropomyosin gene, cdc8, in fission yeast, Schizosaccharomyces pombe, enables a systems-based approach to define the residues that are important for cellular functions. Using molecular evolution methodologies we identified the most conserved residues and related them to the coiled coil structure. Mutants in which one or more of 21 of the most conserved surface residues was mutated to Ala were tested for the ability to rescue growth of a temperature-sensitive cdc8 mutant when overexpressed at the restrictive temperature. Based on altered morphology of the septum and actin cytoskeleton, we selected three sets of mutations for construction of mutant cdc8 strains using marker reconstitution mutagenesis and analysis of recombinant protein in vitro: D16A.K30A, V114S.E117A.H118A and R121A.D131A.E138A. The mutations have sequence-specific effects on cellular morphology including cell length, organization of cytoskeletal structures (actin patches, actin cables and contractile rings), and in vitro actin affinity, lending credence to the proteomic approach introduced here. We propose that bioinformatics is a valid analysis tool for defining structure-function relationships in conserved proteins in this model organism.
Recent models suggest that the mechanism of protein folding is determined by the balance between the stability of secondary structural elements and the hydrophobicity of the sequence. Here we determine the role of these factors in the folding kinetics of Im9* by altering the secondary structure propensity or hydrophobicity of helices I, II or IV by the substitution of residues at solvent exposed sites. The folding kinetics of each variant were measured at pH 7.0 and 10 degrees C, under which conditions wild-type Im9* folds with two-state kinetics. We show that increasing the helicity of these sequences in regions known to be structured in the folding intermediate of Im7*, switches the folding of Im9* from a two- to three-state mechanism. By contrast, increasing the hydrophobicity of helices I or IV has no effect on the kinetic folding mechanism. Interestingly, however, increasing the hydrophobicity of solvent-exposed residues in helix II stabilizes the folding intermediate and the rate-limiting transition state, consistent with the view that this helix makes significant non-native interactions during folding. The results highlight the generic importance of intermediates in folding and show that such species can be populated by increasing helical propensity or by stabilizing inter-helix contacts through non-native interactions.
Tropomyosin is a coiled-coil protein that binds and regulates actin filaments. The tropomyosin gene in Schizosaccharomyces pombe, cdc8, is required for formation of actin cables, contractile rings, and polar localization of actin patches. The roles of conserved residues were investigated in gene replacement mutants. The work validates an evolution-based approach to identify tropomyosin functions in living cells and sites of potential interactions with other proteins. A cdc8 mutant with near-normal actin affinity affects patch polarization and vacuole fusion, possibly by affecting Myo52p, a class V myosin, function. The presence of labile residual cell attachments suggests a delay in completion of cell division and redistribution of cell patches following cytokinesis. Another mutant with a mild phenotype is synthetic negative with GFP-fimbrin, inferring involvement of the mutated tropomyosin sites in interaction between the two proteins. Proteins that assemble in the contractile ring region before actin do so in a mutant cdc8 strain that cannot assemble condensed actin rings, yet some cells can divide. Of general significance, LifeAct-GFP negatively affects the actin cytoskeleton, indicating caution in its use as a biomarker for actin filaments.
Transposable Elements are molecular parasites that persist in their host genome by generating new copies to outpace natural selection. Here we measure the parameters governing the copy number dynamics of the fission yeast Tf2 retrotransposons, using experimental and natural populations and a strain where all Tf2 copies are removed. Natural population genomes display active and persistent Tf2 colonies, but in the absence of selection mitotic recombination deletes Tf2 elements at rates that far exceed transposition. We show that Tf2 elements provide a fitness contribution to their host by dynamically rewiring the transcriptional response to metabolic stress. Therefore, Tf2 elements exhibit a mutualistic rather than parasitic behavior toward their host.
Actin cytoskeleton remodeling is crucial for many vital cellular processes including division, growth, and motility. The actin regulatory protein cofilin contributes to actin remodeling dynamics by creating new filament ends and replenishing the actin monomer pool. Cooperative cofilin binding introduces a topological and mechanical asymmetry at boundaries of bare and cofilin decorated filament segments, which is proposed to facilitate filament severing. Cofilin binding to actin filaments is regulated by phosphorylation. However, the extent to which phosphorylation modulates human cofilin binding cooperativity and severing has not been systematically evaluated. We utilize fluorescence spectroscopy and an Ising model with cooperative nearest-neighbor interactions to quantitate wild-type and phosphomimetic mutant (S3D) human cofilin binding to actin filaments. Modulation of filament mechanics and severing upon cofilin binding is assessed by fluorescence microscopy. The S3D binds filaments with weaker intrinsic binding affinity, yet cooperative interactions are comparable to wild-type cofilin. Preliminary data suggest the phosphorylation mimic mutation also impacts the ability of cofilin to modulate filament mechanics and severing activity.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.