Differential localisation of GFP fusions to cytoskeleton-binding proteins in animal, plant, and yeast cells

Summary.  The structure and functioning of the cytoskeleton is controlled and regulated by cytoskeleton-associated proteins. Fused to the green-fluorescent protein (GFP), these proteins can be used as tools to monitor changes in the organisation of the cytoskeleton in living cells and tissues in different organisms. Since the localisation of a specific cytoskeleton protein may indicate a particular function for the associated cytoskeletal element, studies of cytoskeleton-binding proteins fused to GFP may provide insight into the organisation and functioning of the cytoskeleton. In this article, we focused on two animal proteins, human T-plastin and bovine tau, and studied the distribution of their respective GFP fusions in animal COS cells, plant epidermal cells (Allium cepa), and yeast cells (Saccharomyces cerevisiae). Plastin-GFP localised preferentially to membrane ruffles, lamellipodia and focal adhesion points in COS cells, to the actin filament cytoskeleton within cytoplasmic strands in onion epidermal cells, and to cortical actin patches in yeast cells. Thus, in these 3 very different types of cells plastin-GFP associated with mobile structures in which there are high rates of actin turnover. Chemical fixation was found to drastically alter the distribution of plastin-GFP. Tau-GFP bound to microtubules in COS cells and onion epidermal cells but failed to bind to yeast microtubules. Thus, animal and plant microtubules appear to have a common tau binding site which is absent in yeast. We conclude that the study of the distribution patterns of microtubule- and actin-filament-binding proteins fused to GFP in heterologous systems should be a valuable tool in furthering our knowledge about cytoskeleton function in eukaryotic cells. Received January 12, 2002; accepted March 7, 2002; published online June 24, 2002 RID="*" ID="*" Correspondence and reprints (present address): Institute of Botany, University of Bonn, Kirschallee 1, 53115 Bonn, Federal Republic of Germany. Abbreviation: smRS-GFP soluble modified red-shifted GFP.     

Reorganization of cytoskeletal proteins by Escherichia coli heat-stable enterotoxin (STa)-mediated signaling cascade

Background

IP₃-mediated calcium mobilization from intracellular stores activates and translocates PKC-α from cytosol to membrane fraction in response to STa in COLO-205 cell line. The present study was undertaken to determine the involvement of cytoskeleton proteins in translocation of PKC-α to membrane from cytosol in the Escherichiacoli STa-mediated signaling cascade in a human colonic carcinoma cell line COLO-205.

Methods

Western blots and consequent densitometric analysis were used to assess time-dependent redistribution of cytoskeletal proteins. This redistribution was further confirmed by using confocal microscopy. Pharmacological reagents were applied to colonic carcinoma cells to disrupt the microfilaments (cytochalasin D) and microtubules (nocodazole).

Results

STa treatment in COLO-205 cells showed dynamic redistribution and an increase in actin content in the Triton-insoluble fraction, which corresponds to an increase in polymerization within 1 min. Moreover, pharmacological disruption of actin-based cytoskeleton greatly disturbed PKC-α translocation to the membrane.

Conclusions

These results suggested that the organization of actin cytoskeleton is rapidly rearranged following E. coli STa treatment and the integrity of the actin cytoskeleton played a crucial role in PKC-α movement in colonic cells. Depolymerization of tubulin had no effect on the ability of the kinase to be translocated to the membrane.

General significance

In the present study, we have shown for the first time that in colonic carcinoma cells, STa-mediated rapid changes of actin cytoskeleton arrangement might be involved in the translocation of PKC-α to membrane.     

The brush border cytoskeleton is not static: in vivo turnover of proteins

The shape and stability of intestinal epithelial cell microvilli are maintained by a cytoskeletal core composed of a bundle of actin filaments with several associated proteins. The core filaments are intimately associated with the overlying plasma membrane, in which there occur rapid turnover of proteins and constant incorporation of new membrane. Previous work has shown that starvation or inhibition of protein synthesis results in modulation of microvillar length, which indicates that there may be cytoskeletal protein turnover. We demonstrate herein, by means of in vivo pulse labeling with radioactive amino acids, that turnover of brush border cytoskeletal proteins occurs in mature absorptive cells. Turnover of cytoskeletal proteins appears to be quite slow relative to membrane protein turnover, which suggests that the turnover of these two microvillar compartments is not coupled. We thus conclude that cytoskeletal protein turnover may be a factor used to maintain normal length and stability of microvilli and that the cytoskeleton cannot be considered a static structure.     

The turnover of cell surface proteins of carrot protoplasts

The covalent modification of cell surface proteins with N-hydroxysuccinimide esters of biotin was used to develop a strategy for following the turnover of proteins on the surface of carrot (Daucus carota L.) protoplasts. A biotinylation/internalisation assay was established which enabled the turnover of cell surface proteins to be examined by biochemical and immunocytochemical techniques. The detection of biotinylated proteins after sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blotting indicated that a variety of proteins on the surface of the protoplasts were covalently modified. Immunolocalisation of biotinylated proteins in protoplasts directly after their derivatisation, demonstrated that the proteins were initially restricted to the cell surface. Incubation of biotinylated protoplasts at 25 °C for 1 h resulted in the detection of biotin-labelled proteins on the cell surface and intracellularly. A small proportion of these proteins was associated with coated pits, the Golgi apparatus and vacuolar compartments. Biochemical analysis of internalised proteins revealed that a polypeptide of approximate M_r 100 000 was internalised by the protoplasts. Immunolabelling of a biotinylated protein of M_r 100 000 by an antibody raised against an isoform of a tobacco plasma-membrane H⁺-ATPase, strongly suggests that the plasma-membrane H⁺-ATPase is internalised by carrot protoplasts. The implications of these results are discussed within the context of endocytosis in plants. Received: 13 July 1998 / Accepted: 11 November 1998     

Exit of proteins and fragments thereof from mitochondria is accelerated by the import of cytosolic synthesized proteins

Most mitochondrial proteins are synthesized on cytosolic ribosomes and imported into mitochondria. Incubation of ³⁵S-methionine labeled mitochondria from rat hepatocytes with proteins synthesized in a cell-free system, using messenger RNA from rat liver, dramatically increased the release of mitochondrial proteins and fragments thereof into the medium. Since the synthesized proteins include cytosolic precursors of mitochondrial proteins, our results strongly suggest that import of proteins from the cytosol into mitochondria influences the half-life of proteins in these organelles. The use of this simple approach — i.e. combining the study of protein import and exit with mitochondria — to further clarify intracellular protein turnover and its regulation is suggested.     

Role of penicillin-binding proteins in bacterial cell morphogenesis

The penicillin-binding proteins (PBPs) polymerize and modify peptidoglycan, the stress-bearing component of the bacterial cell wall. As part of this process, the PBPs help to create the morphology of the peptidoglycan exoskeleton together with cytoskeleton proteins that regulate septum formation and cell shape. Genetic and microscopic studies reveal clear morphological responsibilities for class A and class B PBPs and suggest that the mechanism of shape determination involves differential protein localization and interactions with specific cell components. In addition, the low molecular weight PBPs, by varying the substrates on which other PBPs act, alter peptidoglycan synthesis or turnover, with profound effects on morphology.     

Phosphorylation and protein kinase activities of chromosomal non histone proteins from chick embryo fibroblasts

Confluent chick embryo fibroblasts were cultured in vitro in (i) medium which prevented the cells from dividing, (ii) medium which stimulated the cells to divide synchronously, (iii) medium without lysine in which the cells were blocked in G₁.Chromosomal non histone proteins (NHP) were extracted from cells pulse labelled with ³²P phosphate, and the radioactivity analyzed by acrylamide gel electrophoresis. Several radioactive peaks were found all along the gel in the NHP from confluent and stimulated cells. The highest phosphorylation was found in the fast moving proteins, but the stimulation of the cells increases the phosphorylation of the slower moving proteins. In the NHP from cells cultured in the medium without lysine only the slow migrating proteins were phosphorylated.NHP were extracted from unlabelled cell cultures in the three different media, incubated with [γ-³²P] ATP and analyzed by acrylamide gel electrophoresis. Highly labelled peaks were observed in the fast moving proteins from stimulated cells and from cells cultured in a medium deprived from lysine.By comparing in vivo and in vitro phosphorylation, it can be concluded that in confluent cells the turnover of bound phosphate is slow. In stimulated cells there is a fast turnover of the phosphate bound to fast migrating proteins and a slow turnover of the phosphate bound to slow migrating proteins. In cells cultured in a medium without lysine there is a very fast turnover of the phosphate bound to a small group of fast migrating proteins and very little turnover of the phosphate bound to slow migrating proteins.The cells were incubated with labelled lysine and NHP analyzed by gel electrophoresis. The radioactivity of individual NHP varied with the culture conditions, but in all cases, there was little radioactivity in the fast moving proteins. The phosphate groups submitted to a fast turnover are bound to stable proteins.Phosvitin and casein kinase activities were measured in the NHP fractions. Nine-ten peaks of activities were observed with each substrate. Some variations were observed which apparently correlate with the culture conditions.     

Identification and characterization of novel ERC‐55 interacting proteins: Evidence for the existence of several ERC‐55 splicing variants; including the cytosolic ERC‐55‐C

ERC‐55, encoded from RCN2, is localized in the ER and belongs to the CREC protein family. ERC‐55 is involved in various diseases and abnormal cell behavior, however, the function is not well defined and it has controversially been reported to interact with a cytosolic protein, the vitamin D receptor. We have used a number of proteomic techniques to further our functional understanding of ERC‐55. By affinity purification, we observed interaction with a large variety of proteins, including those secreted and localized outside of the secretory pathway, in the cytosol and also in various organelles. We confirm the existence of several ERC‐55 splicing variants including ERC‐55‐C localized in the cytosol in association with the cytoskeleton. Localization was verified by immunoelectron microscopy and sub‐cellular fractionation. Interaction of lactoferrin, S100P, calcyclin (S100A6), peroxiredoxin‐6, kininogen and lysozyme with ERC‐55 was further studied in vitro by SPR experiments. Interaction of S100P requires [Ca²⁺] of ～10^?7 M or greater, while calcyclin interaction requires [Ca²⁺] of >10^?5 M. Interaction with peroxiredoxin‐6 is independent of Ca²⁺. Co‐localization of lactoferrin, S100P and calcyclin with ERC‐55 in the perinuclear area was analyzed by fluorescence confocal microscopy. The functional variety of the interacting proteins indicates a broad spectrum of ERC‐55 activities such as immunity, redox homeostasis, cell cycle regulation and coagulation.     

A rat liver cell-free system for the synthesis of proteins and their transport into mitochondria

A rat liver cytosol was used to study protein synthesis per se and also to study import of proteins into mitochondria since rat liver cytosol represents an environment closer to that of liver mitochondria than the generally used reticulocytes lysates. Two ATP-regenerating systems were compared. The creatine phosphate/creatine kinase yields higher protein synthesis than the phosphoenol pyruvate/pyruvate kinase system. Hemin, necessary to maintain synthesis by reticulocyte lysates, does not affect the rat liver cytosol. The level of protein synthesis obtained with this cell-free system is comparable to other eukaryotic systems described recently and to the expected value for "in vivo" conditions. Isolated mitochondria incorporated, under our standard conditions, newly synthesized proteins linearly up to 30 min, it ceases when a component(s) in the cytosol had been depleted; addition of freshly translated cytosol restores the import. The bulk of imported proteins are retained in mitoplasts or in mitochondria after treatment with trypsin. The cytosol system will be useful to study questions such as regulation of liver mRNA translation and mitochondrial protein turnover.     

The cell shape proteins MreB and MreC control cell morphogenesis by positioning cell wall synthetic complexes

MreB, the bacterial actin homologue, is thought to function in spatially co-ordinating cell morphogenesis in conjunction with MreC, a protein that wraps around the outside of the cell within the periplasmic space. In Caulobacter crescentus, MreC physically associates with penicillin-binding proteins (PBPs) which catalyse the insertion of intracellularly synthesized precursors into the peptidoglycan cell wall. Here we show that MreC is required for the spatial organization of components of the peptidoglycan-synthesizing holoenzyme in the periplasm and MreB directs the localization of a peptidoglycan precursor synthesis protein in the cytosol. Additionally, fluorescent vancomycin (Van-FL) labelling revealed that the bacterial cytoskeletal proteins MreB and FtsZ, as well as MreC and RodA, were required for peptidoglycan synthetic activity. MreB and FtsZ were found to be required for morphogenesis of the polar stalk. FtsZ was required for a cell cycle-regulated burst of peptidoglycan synthesis early in the cell cycle resulting in the synthesis of cross-band structures, whereas MreB was required for lengthening of the stalk. Thus, the bacterial cytoskeleton and cell shape-determining proteins such as MreC, function in concert to orchestrate the localization of cell wall synthetic complexes resulting in spatially co-ordinated and efficient peptidoglycan synthetic activity.     

Cell cycle-related transfer of proteins between the nucleus and cytoplasm of Physarum polycephalum

The proteins of wild-type and polyploid plasmodia of P. polycephalum were prelabelled with [³H]leucine and [¹⁴C]leucine. The two types of plasmodia were then fused for 2 h. Following fusion the nuclei were isolated and the smaller wild-type cell nuclei separated from the larger polyploid cell nuclei. The proteins were isolated from the recipient cell nuclei and the recipient nuclear proteins extracted. Ratios of ³H/¹⁴C in the various nuclear protein fractions show that during fusion differential transfer of labelled preformed proteins from the donor cell into the recipient cell nucleus occurs. The quantity of proteins transferred varies among the different fractions and with the phase of the cell cycle. Isotopic dilution experiments indicate that these differences in protein transfer are, in part, due to a high rate of synthesis and turnover of the nuclear proteins.     

Positioning of chemosensory proteins and FtsZ through the Rhodobacter sphaeroides cell cycle

Bacterial chemotaxis depends on signalling through large protein complexes. Each cell must inherit a complex on division, suggesting some co‐ordination with cell division. In Escherichia coli the membrane‐spanning chemosensory complexes are polar and new static complexes form at pre‐cytokinetic sites, ensuring positioning at the new pole after division and suggesting a role for the bacterial cytoskeleton. Rhodobacter sphaeroides has both membrane‐associated and cytoplasmic, chromosome‐associated chemosensory complexes. We followed the relative positions of the two chemosensory complexes, FtsZ and MreB in aerobic and in photoheterotrophic R. sphaeroides cells using fluorescence microscopy. FtsZ forms polar spots after cytokinesis, which redistribute to the midcell forming nodes from which FtsZ extends circumferentially to form the Z‐ring. Membrane‐associated chemosensory proteins form a number of dynamic unit‐clusters with mature clusters containing about 1000 CheW₃ proteins. Individual clusters diffuse randomly within the membrane, accumulating at new poles after division but not colocalizing with either FtsZ or MreB. The cytoplasmic complex colocalizes with FtsZ at midcells in new‐born cells. Before cytokinesis one complex moves to a daughter cell, followed by the second moving to the other cell. These data indicate that two homologous complexes use different mechanisms to ensure partitioning, and neither complex utilizes FtsZ or MreB for positioning.     

Release of insulin receptor substrate proteins from an intracellular complex coincides with the development of insulin resistance

Insulin receptor substrate (IRS) proteins are major substrates of the insulin receptor (IR). IRS-1 associates with an insoluble multiprotein complex, possibly the cytoskeleton, in adipocytes. This localization may facilitate interaction with the IR at the cell surface. In the present study, we examined the hypothesis that the release of IRS proteins from this location may be a mechanism for insulin desensitization. We show that a second IRS protein, IRS-2, is associated with a multiprotein complex in adipocytes with similar characteristics to the IRS-1 complex. Insulin treatment (15-60 min) caused the release of IRS-1 and IRS-2 from this complex (high speed pellet; HSP) into the cytosol, whereas the level of tyrosyl-phosphorylated IRS proteins remained constant. Chronic insulin treatment resulted in a dramatic reduction in IRS-1 and IRS-2 in the HSP, eventually (>2 h) leading to IRS protein degradation and decreased levels of tyrosyl-phosphorylated IRS proteins. Okadaic acid, which rapidly induces insulin resistance in adipocytes independently of IR function, caused an almost quantitative release of IRS-1 into the cytosol commensurate with a significant reduction in tyrosyl-phosphorylated IRS proteins. Platelet-derived growth factor, a factor known to compromise insulin signaling, caused a more moderate release of IRS proteins from the HSP. Collectively, these results suggest that the assembly of IRS-1/IRS-2 into a multiprotein complex facilitates coupling to the IR and that the regulated release from this location may represent a novel mechanism of insulin resistance.     

Tubulin,actin and heterotrimeric G proteins: Coordination of signaling and structure

G proteins mediate signals from membrane G protein coupled receptors to the cell interior, evoking significant regulation of cell physiology. The cytoskeleton contributes to cell morphology, motility, division, and transport functions. This review will discuss the interplay between heterotrimeric G protein signaling and elements of the cytoskeleton. Also described and discussed will be the interplay between tubulin and G proteins that results in atypical modulation of signaling pathways and cytoskeletal dynamics. This will be extended to describe how tubulin and G proteins act in concert to influence various aspects of cellular behavior. This article is part of a Special Issue entitled: Reciprocal influences between cell cytoskeleton and membrane channels, receptors and transporters.This article is part of a Special Issue entitled: Reciprocal influences between cell cytoskeleton and membrane channels, receptors and transporters. Guest Editor: Jean Claude Hervé.     

Putative microtubule-associated proteins from the Arabidopsis genome

Summary. Plant microtubule-associated proteins (MAPs) are important in modulating the function of the microtubule cytoskeleton. Various plant MAPs have already been described. However, because of the complexity of the plant microtubule cytoskeleton and its responses to developmental and environmental stimuli, there are undoubtedly many more MAPs to be discovered. We have used a literature search and the BLAST protein comparison program to identify which model MAPs from other taxa have close homologues in Arabidopsis thaliana. The search revealed Arabidopsis homologues of 14 model MAPs, with E values (numbers of proteins that will match the model protein merely by chance) of <1×10^–10 and homologous domains spanning 98–599 amino acid residues, representing 57.1–97.0% of the model MAP sequence, as well as 22.5–72.8% amino acid identities and 76.3–96.2% conservation of secondary structure in the homologous domain. All of the Arabidopsis homologues have either a full cDNA clone or an expressed sequence tag in the GenBank database and therefore are expressed. The proteins are likely to regulate a variety of functions, including tubulin folding, microtubule nucleation and polymerisation dynamics, microtubule-dependent cell cycle control, organisation of microtubule arrays, interaction of microtubules with plasma-membrane-associated protein complexes, and interactions with various other proteins. The exact functions of these putative MAPs in the plant cell remain to be elucidated empirically. The identification of these putative MAPs opens new avenues for the investigation of the complexities of the plant microtubule cytoskeleton.Present address: School of Biological Sciences, University of Manchester, Manchester, United Kingdom.Correspondence and reprints: School of Biological Sciences A12, University of Sydney, NSW 2006, Australia.Received October 21, 2002; accepted December 30, 2002; published online September 23, 2003     

Uptake of ribosomal proteins by isolate HeLa nuclei.

The uptake of radioactive ribosomal proteins by isolated HeLa cell nuclei has been studied. Ribosomal proteins are taken up by nuclei $\text{in vitro}$ more rapidly than are cytosol proteins, suggesting that the uptake is selective. In addition, the ribosomal proteins are found associated with the nucleolus to a greater extent than are the cytosol proteins.     

Nuclear localization of herpesvirus proteins: potential role for the cellular framework.

Two herpes simplex virus proteins, the major capsid protein and the major DNA binding protein, are specifically localized to the nucleus of infected cells. We have found that the major proportion of these proteins is associated with the detergent-insoluble matrix or cytoskeletal framework of the infected cell from the time of their synthesis until they have matured to their final binding site in the cell nucleus. These results suggest that these two proteins may interact with or bind to the cellular cytoskeleton during or soon after their synthesis and throughout transport into the cell nucleus. In addition, the DNA binding protein remains associated with the nuclear skeleton at times when it is bound to viral DNA. Thus, viral DNA may also be attached to the nuclear framework. We have demonstrated that the DNA binding protein and the capsid protein exchange from the cytoplasmic framework to the nuclear framework, suggesting the direct movement of the proteins from one structure to the other. Inhibition of viral DNA replication enhanced the binding of the DNA binding protein to the cytoskeleton and increased the rate of exchange from the cytoplasmic framework to the nuclear framework, suggesting a functional relationship between these events. Inhibition of viral DNA replication resulted in decreased synthesis and transport of the capsid protein. We have been unable to detect any artificial binding of these proteins to the cytoskeleton when solubilized viral proteins were mixed with a cytoskeletal fraction or a cell monolayer. This suggested that the attachment of these proteins to the cytoskeleton represents the actual state of these proteins within the cell.     

Differential localisation of GFP fusions to cytoskeleton-binding proteins in animal,plant, and yeast cells. Green-fluorescent protein

The structure and functioning of the cytoskeleton is controlled and regulated by cytoskeleton-associated proteins. Fused to the green-fluorescent protein (GFP), these proteins can be used as tools to monitor changes in the organisation of the cytoskeleton in living cells and tissues in different organisms. Since the localisation of a specific cytoskeleton protein may indicate a particular function for the associated cytoskeletal element, studies of cytoskeleton-binding proteins fused to GFP may provide insight into the organisation and functioning of the cytoskeleton. In this article, we focused on two animal proteins, human T-plastin and bovine tau, and studied the distribution of their respective GFP fusions in animal COS cells, plant epidermal cells (Allium cepa), and yeast cells (Saccharomyces cerevisiae). Plastin-GFP localised preferentially to membrane ruffles, lamellipodia and focal adhesion points in COS cells, to the actin filament cytoskeleton within cytoplasmic strands in onion epidermal cells, and to cortical actin patches in yeast cells. Thus, in these 3 very different types of cells plastin-GFP associated with mobile structures in which there are high rates of actin turnover. Chemical fixation was found to drastically alter the distribution of plastin-GFP. Tau-GFP bound to microtubules in COS cells and onion epidermal cells but failed to bind to yeast microtubules. Thus, animal and plant microtubules appear to have a common tau binding site which is absent in yeast. We conclude that the study of the distribution patterns of microtubule- and actin-filament-binding proteins fused to GFP in heterologous systems should be a valuable tool in furthering our knowledge about cytoskeleton function in eukaryotic cells.