Secondary literature sources for PROF
The following references were automatically generated.
- Olazabal IM, Machesky LM
- Abp1p and cortactin, new "hand-holds" for actin.
- J Cell Biol. 2001; 154: 679-82
- Display abstract
Recently, two new ligands of the Arp2/3 complex have been described that may shed light on the way cells organize complex networks of actin in response to signals. Abp1p, a yeast protein involved in endocytosis, and cortactin, a mammalian src substrate, both enhance the ability of the Arp2/3 complex to assemble branched actin filament networks.
- Witke W, Sutherland JD, Sharpe A, Arai M, Kwiatkowski DJ
- Profilin I is essential for cell survival and cell division in early mouse development.
- Proc Natl Acad Sci U S A. 2001; 98: 3832-6
- Display abstract
Profilins are thought to play a central role in the regulation of de novo actin assembly by preventing spontaneous actin polymerization through the binding of actin monomers, and the adding of monomeric actin to the barbed actin-filament ends. Other cellular functions of profilin in membrane trafficking and lipid based signaling are also likely. Binding of profilins to signaling molecules such as Arp2/3 complex, Mena, VASP, N-WASP, dynamin I, and others, further implicates profilin and actin as regulators of diverse motile activities. In mouse, two profilins are expressed from two distinct genes. Profilin I is expressed at high levels in all tissues and throughout development, whereas profilin II is expressed in neuronal cells. To examine the function of profilin I in vivo, we generated a null profilin I (pfn1(ko)) allele in mice. Homozygous pfn1(ko/ko) mice are not viable. Pfn1(ko/ko) embryos died as early as the two-cell stage, and no pfn1(ko/ko) blastocysts were detectable. Adult pfn1(ko/wt) mice show a 50% reduction in profilin I expression with no apparent impairment of cell function. However, pfn1(ko/wt) embryos have reduced survival during embryogenesis compared with wild type. Although weakly expressed in early embryos, profilin II cannot compensate for lack of profilin I. Our results indicate that mouse profilin I is an essential protein that has dosage-dependent effects on cell division and survival during embryogenesis.
- Holt MR, Koffer A
- Cell motility: proline-rich proteins promote protrusions.
- Trends Cell Biol. 2001; 11: 38-46
- Display abstract
Many proline-rich proteins participate in delivering actin monomers to specific cellular locations where actin-rich membrane protrusions, such as ruffles, filopodia and microspikes, are formed. These protrusions are necessary for cell motility. Actin monomer is usually delivered to the site of polymerization in the form of profilactin - a complex of G-actin with a polyproline-binding protein, profilin. Here, we describe proline-rich proteins involved in regulating actin polymerization and classify them according to their role in recruiting profilin to the membrane.
- Wolven AK, Belmont LD, Mahoney NM, Almo SC, Drubin DG
- In vivo importance of actin nucleotide exchange catalyzed by profilin.
- J Cell Biol. 2000; 150: 895-904
- Display abstract
The actin monomer-binding protein, profilin, influences the dynamics of actin filaments in vitro by suppressing nucleation, enhancing nucleotide exchange on actin, and promoting barbed-end assembly. Profilin may also link signaling pathways to actin cytoskeleton organization by binding to the phosphoinositide PIP(2) and to polyproline stretches on several proteins. Although activities of profilin have been studied extensively in vitro, the significance of each of these activities in vivo needs to be tested. To study profilin function, we extensively mutagenized the Saccharomyces cerevisiae profilin gene (PFY1) and examined the consequences of specific point mutations on growth and actin organization. The actin-binding region of profilin was shown to be critical in vivo. act1-157, an actin mutant with an increased intrinsic rate of nucleotide exchange, suppressed defects in actin organization, cell growth, and fluid-phase endocytosis of pfy1-4, a profilin mutant defective in actin binding. In reactions containing actin, profilin, and cofilin, profilin was required for fast rates of actin filament turnover. However, Act1-157p circumvented the requirement for profilin. Based on the results of these studies, we conclude that in living cells profilin promotes rapid actin dynamics by regenerating ATP actin from ADP actin-cofilin generated during filament disassembly.
- Korenbaum E, Nordberg P, Bjorkegren-Sjogren C, Schutt CE, Lindberg U, Karlsson R
- The role of profilin in actin polymerization and nucleotide exchange.
- Biochemistry. 1998; 37: 9274-83
- Display abstract
Properties of human profilin I mutated in the major actin-binding site were studied and compared with wild-type profilin using beta/gamma-actin as interaction partner. The mutants ranged in affinity, from those that only weakly affected polymerization of actin to one that bound actin more strongly than wild-type profilin. With profilins, whose sequestering activity was low, the concentration of free actin monomers observed at steady-state of polymerization [Afree], was close to that seen with actin alone ([Acc], critical concentration of polymerization). Profilin mutants binding actin with an intermediate affinity like wild-type profilin caused a lowering of [Afree] as compared to [Acc], indicating that actin monomers and profilin:actin complexes participate in polymer formation. With a mutant profilin, which bound actin more strongly than the wild-type protein, an efficient sequestration of actin was observed, and in this case, the [Afree] at steady state was again close to [Acc], suggesting that the mutant profilin:actin had a greatly lowered ability to incorporate actin subunits at the (+)-end. The results from the kinetic and steady-state experiments presented are consonant with the idea that profilin:actin complexes are directly incorporated at the (+)-end of actively polymerizing actin filaments, while they do not support the view that profilin facilitates polymer formation.
- Suetsugu S, Miki H, Takenawa T
- The essential role of profilin in the assembly of actin for microspike formation.
- EMBO J. 1998; 17: 6516-26
- Display abstract
Profilin was first identified as an actin monomer binding protein; however, recent reports indicate its involvement in actin polymerization. To date, there is no direct evidence of a functional role in vivo for profilin in actin cytoskeletal reorganization. Here, we prepared a profilin mutant (H119E) defective in actin binding, but retaining the ability to bind to other proteins. This mutant profilin I suppresses actin polymerization in microspike formation induced by N-WASP, the essential factor in microspike formation. Profilin associates both in vivo and in vitro with N-WASP at proline-rich sites different from those to which Ash/Grb2 binds. This association between profilin and N-WASP is required for N-WASP-induced efficient microspike elongation. Moreover, we succeeded in reconstituting microspike formation in permeabilized cells using profilin I combined with N-WASP and its regulator, Cdc42. These findings provide the first evidence that profilin is a key molecule linking a signaling network to rapid actin polymerization in microspike formation.
- Schmidt A, Hall MN
- Signaling to the actin cytoskeleton.
- Annu Rev Cell Dev Biol. 1998; 14: 305-38
- Display abstract
The actin cytoskeleton is a highly dynamic network composed of actin polymers and a large variety of associated proteins. The main functions of the actin cytoskeleton are to mediate cell motility and cell shape changes during the cell cycle and in response to extracellular stimuli, to organize the cytoplasm, and to generate mechanical forces within the cell. The reshaping and functions of the actin cytoskeleton are regulated by signaling pathways. Here we broadly review the actin cytoskeleton and the signaling pathways that regulate it. We place heavy emphasis on the yeast actin cytoskeleton.
- Theriot JA
- Accelerating on a treadmill: ADF/cofilin promotes rapid actin filament turnover in the dynamic cytoskeleton.
- J Cell Biol. 1997; 136: 1165-8
- Alvarez-Martinez MT, Porte F, Liautard JP, Sri Widada J
- Effects of profilin-annexin I association on some properties of both profilin and annexin I: modification of the inhibitory activity of profilin on actin polymerization and inhibition of the self-association of annexin I and its interactions with liposomes.
- Biochim Biophys Acta. 1997; 1339: 331-40
- Display abstract
We have previously shown that annexin I, a member of a family of calcium-dependent phospholipid and membrane binding proteins, interacts with profilin with high specificity and affinity. This finding further suggests that annexin I is involved through profilin in the regulation of membrane-cytoskeleton organization. We have investigated the consequences of a complex formed by these two proteins on the functions of both profilin and annexin I. Annexin I is able to modify the inhibitory effect of profilin on actin polymerization. This action is partial and the mechanism involved appears to be complex. On the other hand, the association between annexin I and profilin is sufficiently strong to inhibit the self-association of annexin I. The binding capacity of annexin I to liposomes containing phosphatidylserine, which mimics annexin I binding to membranes, is also decreased by profilin. This binding is nevertheless restored when phosphatidylinositol 4,5-biphosphate (PtdInsP2) is included in the liposomes. Finally, the capacity of annexin I to aggregate liposomes is also modified. It is worthwhile mentioning that the liposomes-binding and liposomes-aggregating activities of annexin I are independently regulated. The cell localization and functions of annexin I and profilin suggest that interaction between these two proteins may be directly implicated in the regulation of membrane-cytoskeleton. The phospholipid composition of membranes may be one of the modulating factors.
- Lambrechts A, van Damme J, Goethals M, Vandekerckhove J, Ampe C
- Purification and characterization of bovine profilin II. Actin, poly(L-proline) and inositolphospholipid binding.
- Eur J Biochem. 1995; 230: 281-6
- Display abstract
We purified profilin from bovine brain and were able to separate the two isoforms present in this tissue. Since functional characteristics for profilin II are lacking, we assayed the actin, the phosphatidylinositol 4,5-bisphosphate and the poly(L-proline) binding properties of this isoform. Profilin II binds actin with a similar affinity to that of profilin I, although it inhibits actin polymerization more strongly than profilin I under non-equilibrium conditions. Profilin II also binds the anionic phospholipid phosphatidylinositol 4,5-bisphosphate. Profilin II binds to poly(L-proline) more strongly than does profilin I; this is especially evident at more acidic pH values. This difference is explained by an amino acid exchange in the carboxy-terminal part of the protein which has been implicated in poly(L-proline) binding [Bjorkegren, C., Rozycki, M., Schutt, C., Lindberg, U. & Karlsson, R. (1993) FEBS Lett. 333, 123-126; Metzler, W., Bell, A., Ernst, E., Lavoie, T. & Mueller, L. (1994) J. Biol. Chem. 369, 4620-4625].
- Gieselmann R, Kwiatkowski DJ, Janmey PA, Witke W
- Distinct biochemical characteristics of the two human profilin isoforms.
- Eur J Biochem. 1995; 229: 621-8
- Display abstract
The biochemical characteristics of a new human profilin isoform are described. We refer to this recently described isoform as profilin II (isoelectric point 5.9) in comparison to profilin I (pI 8.4). We expressed both isoforms in bacteria and compared their actin-binding properties, binding to poly(L-proline), affinities for phosphatidylinositol 4,5-bisphosphate [PtdIns(4,5)P2], and their effects on nucleotide exchange on actin. Profilin I and profilin II have similar affinities for PtdIns(4,5)P2 and poly(L-proline), and both accelerate nucleotide exchange on monomeric actin to the same extent. However, the affinity of profilin I for monomeric actin is about five times higher than the affinity of profilin II for actin. Potential structural differences of profilin I and profilin II that might explain the difference in actin binding are discussed.
- Carlier MF, Pantaloni D
- Actin assembly in response to extracellular signals: role of capping proteins, thymosin beta 4 and profilin.
- Semin Cell Biol. 1994; 5: 183-91
- Display abstract
In motile non-muscle cells, G-actin sequestering proteins, capping proteins and profilin regulate actin assembly in response to extracellular signals. The regulation of actin sequestration/assembly is performed via the control of the concentration of free G-actin at steady-state. The increase in free G-actin mediated by capping proteins results in an increased sequestration of actin. When barbed ends are uncapped upon cell stimulation, the participation of profilin-actin in filament assembly causes a decrease in free G-actin, which results in the depletion of the pool of sequestered actin and concomitant increase in the F-actin pool.
- Welch MD, Holtzman DA, Drubin DG
- The yeast actin cytoskeleton.
- Curr Opin Cell Biol. 1994; 6: 110-9
- Display abstract
Budding and fission yeast present significant advantages for studies of the actin cytoskeleton. The application of classical and molecular genetic techniques provides a facile route for the analysis of structure/function relationships, for the isolation of novel proteins involved in cytoskeletal function, and for deciphering the signals that regulate actin assembly in vivo. This review focuses on the budding yeast Saccharomyces cerevisiae and also identifies some recent advances from studies on the fission yeast Schizosaccharomyces pombe, for which studies on the actin cytoskeleton are still in their infancy.
- Janmey PA
- Phosphoinositides and calcium as regulators of cellular actin assembly and disassembly.
- Annu Rev Physiol. 1994; 56: 169-91
- Ampe C, Vandekerckhove J
- Actin-actin binding protein interfaces.
- Semin Cell Biol. 1994; 5: 175-82
- Display abstract
The recent elucidation of the three-dimensional structure of gelsolin segment 1 and profilin provides new insights on how these proteins recognize actin. Although the picture is still incomplete and not all biochemical data are consolidated, the results offer clues on how these proteins exert their effect on actin and how they may modulate the cytoskeleton dynamics. Binding studies on the villin head piece, thymosin beta 4 and mutants of both peptides allowed to identify critical residues important for actin binding and give the first picture of new actin binding interfaces. The interface of the modelled actomyosin complex is also briefly discussed.
- Magdolen V, Drubin DG, Mages G, Bandlow W
- High levels of profilin suppress the lethality caused by overproduction of actin in yeast cells.
- FEBS Lett. 1993; 316: 41-7
- Display abstract
Overproduction of actin is lethal to yeast cells. In contrast, overexpression of the profilin gene, PFY1, encoding an actin-binding protein, leads to no very obvious phenotype. Interestingly, profilin overproduction can compensate for the deleterious effects of too much actin in a profilin concentration-dependent manner. Our results, thus, document that actin and profilin interact in vivo. Immunofluorescence studies suggest that suppression works by reducing actin assembly. We observed, however, that even massive overproduction of profilin fails to fully restore the wild-type phenotype (e.g. the wild-type appearance of the actin microfilament system). This may indicate that actin monomer sequestration is not the only mechanism by which the balance of actin polymerization is controlled.
- Buss F, Temm-Grove C, Henning S, Jockusch BM
- Distribution of profilin in fibroblasts correlates with the presence of highly dynamic actin filaments.
- Cell Motil Cytoskeleton. 1992; 22: 51-61
- Display abstract
We have used polyclonal and monoclonal antibodies raised against calf thymus profilin to localize the corresponding protein in translocating, spreading, and stationary rat fibroblasts. Immunofluorescence of whole cells and immunogold labeling on ventral membranes of lysis-squirted cells showed that profilin was markedly enriched in the highly dynamic lamellipodia or pseudopodial lobes. Within these regions, a significant fraction was colocalized with dynamic actin filaments organized in actin ribs, cortical filaments, or stress fiber-like bundles, and little profilin was found in membrane areas appearing free of actin. In contrast, stress fibers of stationary cells as well as actin arcs and ring-like bundles of spreading and migrating cells showed very little label. These results are discussed in context with the proposed role of profilin in regional membrane dynamics typical for fibroblasts and are compared to previous data (Hartwig et al.: J. Cell Biol. 109:1571-1579, 1989) on profilin distribution in platelets and granulocytes.
- Aderem A
- Signal transduction and the actin cytoskeleton: the roles of MARCKS and profilin.
- Trends Biochem Sci. 1992; 17: 438-43
- Display abstract
MARCKS and profilin, two actin-binding proteins, are discussed to illustrate the mechanism by which extracellular signals are coupled to changes in the structure of the actin cytoskeleton. MARCKS is a filamentous actin-crosslinking protein that appears to function as an integrator of protein kinase C and calcium (Ca2+)/calmodulin signals in the regulation of actin-membrane interactions. New data suggest that profilin is activated by the coordinated action of receptor tyrosine kinases and phospholipase C-gamma 1 to stimulate the stabilization of actin filaments.
- Goldschmidt-Clermont PJ, Machesky LM, Doberstein SK, Pollard TD
- Mechanism of the interaction of human platelet profilin with actin.
- J Cell Biol. 1991; 113: 1081-9
- Display abstract
We have reexamined the interaction of purified platelet profilin with actin and present evidence that simple sequestration of actin monomers in a 1:1 complex with profilin cannot explain many of the effects of profilin on actin assembly. Three different methods to assess binding of profilin to actin show that the complex with platelet actin has a dissociation constant in the range of 1 to 5 microM. The value for muscle actin is similar. When bound to actin, profilin increases the rate constant for dissociation of ATP from actin by 1,000-fold and also increases the rate of dissociation of Ca2+ bound to actin. Kinetic simulation showed that the profilin exchanges between actin monomers on a subsecond time scale that allows it to catalyze nucleotide exchange. On the other hand, polymerization assays give disparate results that are inconsistent with the binding assays and each other: profilin has different effects on elongation at the two ends of actin filaments; profilin inhibits the elongation of platelet actin much more strongly than muscle actin; and simple formation of 1:1 complexes of actin with profilin cannot account for the strong inhibition of spontaneous polymerization. We suggest that the in vitro effects on actin polymerization may be explained by a complex mechanism that includes weak capping of filament ends and catalytic poisoning of nucleation. Although platelets contain only 1 profilin for every 5-10 actin molecules, these complex reactions may allow substoichiometric profilin to have an important influence on actin assembly. We also confirm the observation of I. Lassing and U. Lindberg (1985. Nature [Lond.] 318:472-474) that polyphosphoinositides inhibit the effects of profilin on actin polymerization, so lipid metabolism must also be taken into account when considering the functions of profilin in a cell.
- Yonezawa N, Nishida E
- [Actin and actin binding proteins in neuronal tissues]
- Tanpakushitsu Kakusan Koso. 1990; 35: 589-96
- Way M, Weeds A
- Actin-binding proteins. Cytoskeletal ups and downs.
- Nature. 1990; 344: 292-4
- Edamatsu M, Hirono M, Watanabe Y
- Purification and characterization of Tetrahymena profilin.
- Biochem Biophys Res Commun. 1990; 170: 957-62
- Display abstract
We subjected Tetrahymena cell extract to a poly(L-proline) affinity column for isolating profilin and obtained a protein of 12.8 kDa. Purified 12.8 kDa protein dose-dependently inhibited the polymerization of Tetrahymena actin more strongly than that of rabbit skeletal muscle actin. Because the 12.8 kDa protein fulfills properties common to profilins, the protein is considered to be Tetrahymena profilin. The present paper is the first report of the isolation of an actin-binding protein from Tetrahymena.
- Haarer BK, Brown SS
- Structure and function of profilin.
- Cell Motil Cytoskeleton. 1990; 17: 71-4
- Vandekerckhove JS, Kaiser DA, Pollard TD
- Acanthamoeba actin and profilin can be cross-linked between glutamic acid 364 of actin and lysine 115 of profilin.
- J Cell Biol. 1989; 109: 619-26
- Display abstract
Acanthamoeba profilin was cross-linked to actin via a zero-length isopeptide bond using carbodiimide. The covalently linked 1:1 complex was purified and treated with cyanogen bromide. This cleaves actin into small cyanogen bromide (CNBr) peptides and leaves the profilin intact owing to its lack of methionine. Profilin with one covalently attached actin CNBr peptide was purified by gel filtration followed by gel electrophoresis and electroblotting on polybase-coated glass-fiber membranes. Since the NH2 terminus of profilin is blocked, Edman degradation gave only the sequence of the conjugated actin CNBr fragment beginning with Trp-356. The profilin-actin CNBr peptide conjugate was digested further with trypsin and the cross-linked peptide identified by comparison with the tryptic peptide pattern obtained from carbodiimide-treated profilin. Amino-acid sequence analysis of the cross-linked tryptic peptides produced two residues at each cycle. Their order corresponds to actin starting at Trp-356 and profilin starting at Ala-94. From the absence of the phenylthiohydantoin-amino acid residues in specific cycles, we conclude that actin Glu-364 is linked to Lys-115 in profilin. Experiments with the isoforms of profilin I and profilin II gave identical results. The cross-linked region in profilin is homologous with sequences in the larger actin filament capping proteins fragmin and gelsolin.
- Lindberg U, Schutt CE, Hellsten E, Tjader AC, Hult T
- The use of poly(L-proline)-Sepharose in the isolation of profilin and profilactin complexes.
- Biochim Biophys Acta. 1988; 967: 391-400
- Display abstract
In the purification of proline hydroxylase by affinity chromatography on poly(L-proline)-Sepharose it was found earlier that two other components, profilin and the complex profilin-actin, also bind with high affinity to this matrix. We have exploited this observation to develop a rapid procedure for the isolation of profilin and profilin-actin complexes in high yields directly from high-speed supernatants of crude tissue-extracts. Through an extensive search for elution conditions, avoiding poly(L-proline) as the desorbant, we have found that active proteins can be recovered from the affinity column with a buffer containing 30% dimethyl sulphoxide. Subsequent chromatography on hydroxylapatite separates free profilin and the two isoforms of profilactin, profilin-actin beta and profilin-actin gamma. The profilin-actin complexes produced this way have high specific activities in the DNAase-inhibition assay, give rise to filaments on addition of Mg2+, and can be crystallized. From the isolated profilin-actin complexes the beta- and gamma-actin isoforms of non-muscle cells can easily be prepared in a polymerization competent form. Pure profilin is either obtained from an excess pool present in some extracts or by dissociation of profilin-actin complexes and removal of the actin.