Capping protein regulators fine-tune actin assembly dynamics

Edwards, Marc; Zwolak, Adam; Schafer, Dorothy A.; Sept, David; Domínguez, Roberto; Cooper, John A.

doi:10.1038/nrm3869

Cited by 245 publications

(275 citation statements)

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“…One prediction of this model is that cells expressing a version of CP that cannot see the CPI motif in CARMIL and related proteins (e.g., CD2AP and CKIP) should phenocopy Arp2/3-inhibited cells. This prediction has recently received direct support by the work of Edwards et al (29).Studies using gene ablation or RNAi have demonstrated that CARMIL proteins play important roles in the formation of cortical actin structures like pseudopodia and macropinocytic crowns in Dictyostelium and lamellipodia in tissue culture cells (1,19). In contrast, relatively little is known regarding the importance of V-1 in vivo (30-32), especially with respect to effects on actin assembly and organization.…”

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confidence: 95%

“…Studies using gene ablation or RNAi have demonstrated that CARMIL proteins play important roles in the formation of cortical actin structures like pseudopodia and macropinocytic crowns in Dictyostelium and lamellipodia in tissue culture cells (1,19). In contrast, relatively little is known regarding the importance of V-1 in vivo (30-32), especially with respect to effects on actin assembly and organization.…”

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confidence: 99%

“…To date, two direct regulators of CP activity have been identified. The first, CARMIL, is a ∼125-kDa protein that binds CP tightly via a small, highly conserved domain known as CAH3 or CPI (1,19). CP bound to CPI binds the barbed end with an affinity of ∼50 nM, which, although still quite significant, is ∼100-fold weaker than free CP (20,21).…”

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confidence: 99%

“…Finally, we present evidence that V-1's ability to sequester CP is regulated by phosphorylation, suggesting that cells may manipulate the level of active CP to tune their "actin phenotype." actin | capping protein | V-1 | myotrophin | CARMIL T he addition of Capping Protein (CP) to seed-initiated actin polymerization assays results in the rapid cessation of polymerization because CP binds with very high affinity to the fastgrowing barbed end of the actin filament to block further monomer addition (1). Direct extrapolation of this simple, potent biochemical property would suggest that the cell's content of F-actin should rise and fall as its content of CP is artificially forced to fall and rise, respectively.…”

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V-1 regulates capping protein activity in vivo

Jung

Alexander

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Capping Protein (CP) plays a central role in the creation of the Arp2/ 3-generated branched actin networks comprising lamellipodia and pseudopodia by virtue of its ability to cap the actin filament barbed end, which promotes Arp2/3-dependent filament nucleation and optimal branching. The highly conserved protein V-1/Myotrophin binds CP tightly in vitro to render it incapable of binding the barbed end. Here we addressed the physiological significance of this CP antagonist in Dictyostelium, which expresses a V-1 homolog that we show is very similar biochemically to mouse V-1. Consistent with previous studies of CP knockdown, overexpression of V-1 in Dictyostelium reduced the size of pseudopodia and the cortical content of Arp2/3 and induced the formation of filopodia. Importantly, these effects scaled positively with the degree of V-1 overexpression and were not seen with a V-1 mutant that cannot bind CP. V-1 is present in molar excess over CP, suggesting that it suppresses CP activity in the cytoplasm at steady state. Consistently, cells devoid of V-1, like cells overexpressing CP described previously, exhibited a significant decrease in cellular F-actin content. Moreover, V-1-null cells exhibited pronounced defects in macropinocytosis and chemotactic aggregation that were rescued by V-1, but not by the V-1 mutant. Together, these observations demonstrate that V-1 exerts significant influence in vivo on major actin-based processes via its ability to sequester CP. Finally, we present evidence that V-1's ability to sequester CP is regulated by phosphorylation, suggesting that cells may manipulate the level of active CP to tune their "actin phenotype."T he addition of Capping Protein (CP) to seed-initiated actin polymerization assays results in the rapid cessation of polymerization because CP binds with very high affinity to the fastgrowing barbed end of the actin filament to block further monomer addition (1). Direct extrapolation of this simple, potent biochemical property would suggest that the cell's content of F-actin should rise and fall as its content of CP is artificially forced to fall and rise, respectively. Indeed, this finding was reported many years ago in Dictyostelium amoeba (2). This simple view of CP's role in regulating actin assembly in vivo falls short of the whole story, however. The additional complexity arises from the critical relationship between CP and the Arp2/3 complex, the major actin nucleating machine that generates the branched actin networks comprising lamellipodia and pseudopodia (3). At the heart of this relationship is the fact that CP increases the rate of Arp2/3-dependent filament nucleation and promotes optimal branching by rapidly capping filaments (4). As a result, CP promotes actin-related proteins 2 and 3 (Arp2/3)-driven actin assembly and motility (4, 5). This effect was evident from early solution experiments focused on defining the function of the Arp2/3 complex (6), verified by in vitro reconstitution of the Arp2/3-dependent motility of Listeria (5), and explained mecha...

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V-1 regulates capping protein activity in vivo

Jung

Alexander

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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“…To circumvent this promiscuity, we focused our investigation on the early intracellular trafficking events of newly synthesized GPRC5B proteins. We show that most newly synthesized GPRC5B protein is released in exosomes as opposed to microvesicles and that an adaptor protein, CD2AP (27), mediates internalization of cell surfacelocalized GPRC5B as an early event. Surprisingly, we found that the internalized GPRC5B proteins subsequently accumulated in the Golgi complex prior to exosomal release and that the L-type lectin LMAN2 (28,29) impedes the exosomal release of GPRC5B specifically from the trans Golgi network (TGN), possibly by interfering with the physical association of GPRC5B and GGA1, an adaptor protein implicated in TGN-to-endosome trafficking (30,31), or possibly by opposing the biosynthetic secretory trafficking through TGN-to-endoplasmic reticulum (ER) retrograde transport (28).…”

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Adaptor Protein CD2AP and L-type Lectin LMAN2 Regulate Exosome Cargo Protein Trafficking through the Golgi Complex

Kwon

Nacke

et al. 2016

Journal of Biological Chemistry

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Edited by Thomas SöllnerExosomes, 40 -150-nm extracellular vesicles, transport biological macromolecules that mediate intercellular communications. Although exosomes are known to originate from maturation of endosomes into multivesicular endosomes (also known as multivesicular bodies) with subsequent fusion of the multivesicular endosomes with the plasma membrane, it remains unclear how cargos are selected for exosomal release. Using an inducible expression system for the exosome cargo protein GPRC5B and following its trafficking trajectory, we show here that newly synthesized GPRC5B protein accumulates in the Golgi complex prior to its release into exosomes. The L-type lectin LMAN2 (also known as VIP36) appears to be specifically required for the accumulation of GPRC5B in the Golgi complex and restriction of GPRC5B transport along the exosomal pathway. This may occur due to interference with the adaptor protein GGA1-mediated trans Golgi network-to-endosome transport of GPRC5B. The adaptor protein CD2AP-mediated internalization following cell surface delivery appears to contribute to the Golgi accumulation of GPRC5B, possibly in parallel with biosynthetic/secretory trafficking from the endoplasmic reticulum. Our data thus reveal a Golgi-traversing pathway for exosomal release of the cargo protein GPRC5B in which CD2AP facilitates the entry and LMAN2 impedes the exit of the flux, respectively.

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Differential expression of CARMIL‐family genes during zebrafish development

Stark

Cooper

2015

Cytoskeleton

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CARMILs are a conserved family of large multidomain proteins that regulate and target actin assembly by interacting with actin capping protein (CP). Vertebrates contain three highly conserved CARMIL isoforms encoded by three genes, whereas lower organisms contain only one isoform and gene. In order to investigate the functions of vertebrate CARMILs, we identified and characterized the three CARMIL genes in zebrafish (Danio rerio). We isolated and sequenced complete and partial cDNAs from embryos. The three genes display distinct spatial and temporal expression patterns during development. Sequence and phylogenetic analyses of cDNAs and predicted protein sequences reveal that the three zebrafish genes fall into the three conserved isoform groups previously defined for other vertebrates, which have isoform-specific and overlapping functions in human cultured cells. These results provide new tools and offer insight into understanding the role of the regulation of actin assembly dynamics during embryonic development and tissue morphogenesis.

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Capping protein regulators fine-tune actin assembly dynamics

Cited by 245 publications

References 178 publications

V-1 regulates capping protein activity in vivo

V-1 regulates capping protein activity in vivo

Adaptor Protein CD2AP and L-type Lectin LMAN2 Regulate Exosome Cargo Protein Trafficking through the Golgi Complex

Differential expression of CARMIL‐family genes during zebrafish development

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