Connecting actin monomers by iso-peptide bond is a toxicity mechanism of the
            <i>Vibrio cholerae</i>
            MARTX toxin

Kudryashov, Dmitri S.; Durer, Zeynep A. Oztug; Ytterberg, A. Jimmy; Sawaya, M.R.; Pashkov, I.; Procházková, Kateřina; Yeates, Todd O.; Loo, Rachel R. Ogorzalek; Loo, Joseph A.; Satchell, K.J.F.; Reisler, Emil

doi:10.1073/pnas.0808082105

Cited by 70 publications

(81 citation statements)

References 40 publications

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“…Filament structures are stabilized through the binding of phalloidin at the interface of three subunits in F-actin, and thus, the assembly of polymerization-impaired actins can be frequently rescued by this reagent. Similarly, cofilin can also rescue the polymerization of some assembly impaired actin mutants and chemically or enzymatically modified actins by bridging adjacent subunits and remodeling the intersubunit interface in the filament (34,35). However, for the F169C actin mutant, only phalloidin (but not and on plates at 24 and 30°C.…”

Section: Effect Of Mutations On Yeast Cellmentioning

confidence: 99%

A Nucleotide State-sensing Region on Actin

Kudryashov

Grintsevich

Rubenstein

et al. 2010

Journal of Biological Chemistry

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The nucleotide state of actin (ATP, ADP-P i , or ADP) is known to impact its interactions with other actin molecules upon polymerization as well as with multiple actin binding proteins both in the monomeric and filamentous states of actin. Recently, molecular dynamics simulations predicted that a sequence located at the interface of subdomains 1 and 3 (W-loop; residues 165-172) changes from an unstructured loop to a ␤-turn conformation upon ATP hydrolysis (Zheng, X., Diraviyam, K., and Sept, D. (2007) Biophys. J. 93, 1277-1283). This region participates directly in the binding to other subunits in F-actin as well as to cofilin, profilin, and WH2 domain proteins and, therefore, could contribute to the nucleotide sensitivity of these interactions. The present study demonstrates a reciprocal communication between the W-loop region and the nucleotide binding cleft on actin. Point mutagenesis of residues 167, 169, and 170 and their site-specific labeling significantly affect the nucleotide release from the cleft region, whereas the ATP/ADP switch alters the fluorescence of probes located in the W-loop. In the ADP-P i state, the W-loop adopts a conformation similar to that in the ATP state but different from the ADP state. Binding of latrunculin A to the nucleotide cleft favors the ATP-like conformation of the W-loop, whereas ADP-ribosylation of Arg-177 forces the W-loop into a conformation distinct from those in the ADP and ATP-states. Overall, our experimental data suggest that the W-loop of actin is a nucleotide sensor, which may contribute to the nucleotide state-dependent changes in F-actin and nucleotide state-modulated interactions of both G-and F-actin with actin-binding proteins.Actin, one of the most abundant and conserved eukaryotic proteins, is involved in a variety of cellular functions, from cell division and migration to intracellular transport and endo-and exocytosis. Under physiological conditions, monomeric actin (G-actin) 3 and filamentous actin (F-actin) are in a dynamic equilibrium, strongly favoring the latter. Very low basal ATPase activity of G-actin is amplified strongly upon its polymerization, and the release of inorganic P i in general follows the polymerization with some delay (2, 3). Consequently, under equilibrium conditions, a typical actin filament contains ATP protomers at the growing end followed by an ADP-P i -enriched region and then by an extended ADP region in the rest of the filament. The nature of the bound nucleotide influences the properties of G-and F-actin and controls their interactions with a number of actin-binding proteins (ABP), which play key regulatory and structural roles in the dynamics and maintenance of the actin cytoskeleton. Nucleotide-sensitive ABPs regulate nucleotide exchange rates and the polymerization of G-actin, the nucleation of new filaments, and disassembly of mature filaments. Thus, preferential binding of the Arp2/3 nucleating complex to ATP and ADP-P i F-actin, cofilin to ADP-F-actin, and profilin to ATP-G-actin leads to the acceleration of directe...

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Section: Effect Of Mutations On Yeast Cellmentioning

confidence: 99%

A Nucleotide State-sensing Region on Actin

Kudryashov

Grintsevich

Rubenstein

et al. 2010

Journal of Biological Chemistry

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“…First, we pre-incubated HeLa nuclear extracts with vehicle or the purified actin-crosslinking domain (ACD) of V. cholera MARTX. ACD toxin catalyzes inter-molecular amide bond formation between actin monomers, covalently crosslinking monomeric actin (Kudryashov et al, 2008). Western blots of ACD-treated nuclear extracts showed a ladder of actin crosslinked into oligomers of increasing molecular weights and a concomitant decrease in the amount of non-crosslinked actin (Fig.…”

Section: Crosslinking or Polymerizing Nuclear Actin Inhibits Mrna Tramentioning

confidence: 99%

“…Briefly, purified HeLa nuclear extract (30 µg, Promega) in transcription buffer (20 mM HEPES pH 7.9, 20% glycerol, 100 mM KCl, 0.2 mM EDTA, 0.5 mM PMSF, and 0.5 mM DTT) with 1 mM ATP and 4 mM MgCl 2 was pre-incubated with 0.5 µM purified ACD (Kudryashov et al, 2008) or buffer alone for 1 h at room temperature or with 10 µM phalloidin for 30 min at 4°C. After pre-incubation, RNAse T1 was added, along with 200 ng P41 DNA template containing the adenoviral major late promoter and G-less transcribing region and 0.4 mM of ATP, UTP and 0.02 mM CTP.…”

Section: In Vitro Transcription Assaymentioning

confidence: 99%

Persistent nuclear actin filaments inhibit transcription by RNA polymerase II

Serebryannyy

Parilla

Annibale

et al. 2016

Journal of Cell Science

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Actin is abundant in the nucleus and it is clear that nuclear actin has important functions. However, mystery surrounds the absence of classical actin filaments in the nucleus. To address this question, we investigated how polymerizing nuclear actin into persistent nuclear actin filaments affected transcription by RNA polymerase II. Nuclear filaments impaired nuclear actin dynamics by polymerizing and sequestering nuclear actin. Polymerizing actin into stable nuclear filaments disrupted the interaction of actin with RNA polymerase II and correlated with impaired RNA polymerase II localization, dynamics, gene recruitment, and reduced global transcription and cell proliferation. Polymerizing and crosslinking nuclear actin in vitro similarly disrupted the actin-RNA-polymerase-II interaction and inhibited transcription. These data rationalize the general absence of stable actin filaments in mammalian somatic nuclei. They also suggest a dynamic pool of nuclear actin is required for the proper localization and activity of RNA polymerase II.

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“…Additionally, many VgrG proteins contain C-terminal extensions, some of which possess effector function, such as the actin cross-linking domain (ACD) of VgrG-1 in V. cholerae (11). This domain covalently cross-links actin monomers by catalyzing intermolecular isopeptide bonds (15). After uptake of bacteria into macrophage cell lines, VgrG-1 or its ACD domain was translocated into the host cell cytosol to cross-link cellular actin, thereby impairing subsequent phagocytic function (11,16,17).…”

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confidence: 99%

In vivo actin cross-linking induced by Vibrio cholerae type VI secretion system is associated with intestinal inflammation

Mekalanos

2010

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

192

168

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Type VI secretion systems (T6SSs) have recently been recognized as potential virulence determinants of many Gram-negative bacterial pathogens. Although mechanistic studies are lacking, T6SS-dependent phenotypes can be observed in various animal models of infection. Presumably translocation of T6SS effectors into target cells is involved in virulence, but few such effectors have been identified. A hallmark of T6SS function is the in vitro secretion of Hcp and VgrG proteins, which are thought to form part of an extracellular secretion apparatus. One well-characterized effector domain is the C-terminal actin cross-linking domain (ACD) of the VgrG-1 protein, constitutively secreted by the T6SS of Vibrio cholerae strain V52. Previous work indicated that translocation of VgrG-1 occurred only after endocytic uptake of bacteria into host cells. VgrG-1-induced actin cross-linking impaired phagocytic activity of host cells, eventually causing cell death. To determine whether V. cholerae T6SS is functional during animal infection, derivatives of V52 were used to infect infant mice. In this infection model a diarrheal response occurred, and actin cross-linking could be detected. These host responses were dependent on a functional T6SS and on the ACD of VgrG-1. Gene expression and histologic studies showed innate immune activation and immune cell infiltration in the intestinal lumen. The T6SS-dependent inflammatory response was also associated with increased recovery of V. cholerae from the intestine. We conclude that the T6SS of V52 induces an inflammatory diarrhea that facilitates replication of V. cholerae within the intestine.innate immunity | VgrG | virulence effector | ACD | MARTX

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Connecting actin monomers by iso-peptide bond is a toxicity mechanism of the Vibrio cholerae MARTX toxin

Cited by 70 publications

References 40 publications

A Nucleotide State-sensing Region on Actin

A Nucleotide State-sensing Region on Actin

Persistent nuclear actin filaments inhibit transcription by RNA polymerase II

In vivo actin cross-linking induced by Vibrio cholerae type VI secretion system is associated with intestinal inflammation

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