Elizabeth Blankman scite author profile

Summary To maintain mechanical homeostasis, cells must recognize and respond to changes in cytoskeletal integrity. By imaging live cells expressing fluorescently tagged cytoskeletal proteins, we observed that actin stress fibers undergo local, acute, force-induced elongation and thinning events that compromise their stress transmission function, followed by stress fiber repair that restores this capability. The LIM protein, zyxin, rapidly accumulates at sites of strain-induced stress fiber damage and is essential for stress fiber repair and generation of traction force. Zyxin promotes recruitment of the actin regulatory proteins, α-actinin and VASP, to compromised stress fiber zones. α-Actinin plays a critical role in restoration of actin integrity at sites of local stress fiber damage, while both α-actinin and VASP independently contribute to limiting stress fiber elongation at strain sites, thus promoting stabilization of the stress fiber. Our findings demonstrate a mechanism for rapid repair and maintenance of the structural integrity of the actin cytoskeleton.

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Mechanosensing through Direct Binding of Tensed F-Actin by LIM Domains

Sun

et al. 2020

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Zinc fingers can act as Zn2+ sensors to regulate transcriptional activation domain function

et al. 2003

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The yeast Zap1 transcription factor controls the expression of genes involved in zinc accumulation and storage. Zap1 is active in zinc-limited cells and repressed in replete cells. Zap1 has two activation domains, AD1 and AD2, which are both regulated by zinc. AD2 function was mapped to a region containing two Cys2His2 zinc fingers, ZF1 and ZF2, that are not involved in DNA binding. More detailed mapping placed AD2 almost precisely within the endpoints of ZF2, suggesting a role for these fingers in regulating activation domain function. Consistent with this hypothesis, ZF1 and ZF2 bound zinc in vitro but less stably than did zinc fingers involved in DNA binding. Furthermore, mutations predicted to disrupt zinc binding to ZF1 and/or ZF2 rendered AD2 constitutively active. Our results also indicate that the repressed form of AD2 requires an intramolecular interaction between ZF1 and ZF2. These studies suggest that these zinc fingers play an unprecedented role as zinc sensors to control activation domain function.

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LIM Domains Target Actin Regulators Paxillin and Zyxin to Sites of Stress Fiber Strain

et al. 2013

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Contractile actomyosin stress fibers are critical for maintaining the force balance between the interior of the cell and its environment. Consequently, the actin cytoskeleton undergoes dynamic mechanical loading. This results in spontaneous, stochastic, highly localized strain events, characterized by thinning and elongation within a discrete region of stress fiber. Previous work showed the LIM-domain adaptor protein, zyxin, is essential for repair and stabilization of these sites. Using live imaging, we show paxillin, another LIM-domain adaptor protein, is also recruited to stress fiber strain sites. Paxillin recruitment to stress fiber strain sites precedes zyxin recruitment. Zyxin and paxillin are each recruited independently of the other. In cells lacking paxillin, actin recovery is abrogated, resulting in slowed actin recovery and increased incidence of catastrophic stress fiber breaks. For both paxillin and zyxin, the LIM domains are necessary and sufficient for recruitment. This work provides further evidence of the critical role of LIM-domain proteins in responding to mechanical stress in the actin cytoskeleton.

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The Zap1 transcriptional activator also acts as a repressor by binding downstream of the TATA box in ZRT2

Bird

Blankman

Stillman

et al. 2004

EMBO J

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The zinc-responsive transcriptional activator Zap1 regulates the expression of both high-and low-affinity zinc uptake permeases encoded by the ZRT1 and ZRT2 genes. Zap1 mediates this response by binding to zinc-responsive elements (ZREs) located within the promoter regions of each gene. ZRT2 has a remarkably different expression profile in response to zinc compared to ZRT1. While ZRT1 is maximally induced during zinc limitation, ZRT2 is repressed in low zinc but remains induced upon zinc supplementation. In this study, we determined the mechanism underlying this paradoxical Zap1-dependent regulation of ZRT2. We demonstrate that a nonconsensus ZRE (ZRT2 ZRE3), which overlaps with one of the ZRT2 transcriptional start sites, is essential for repression of ZRT2 in low zinc and that Zap1 binds to ZRT2 ZRE3 with a low affinity. The low-affinity ZRE is also essential for the ZRT2 expression profile. These results indicate that the unusual pattern of ZRT2 regulation among Zap1 target genes involves the antagonistic effect of Zap1 binding to a lowaffinity ZRE repressor site and high-affinity ZREs required for activation.

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Mapping the DNA Binding Domain of the Zap1 Zinc-responsive Transcriptional Activator

Bird

Evans-Galea

Blankman

et al. 2000

Journal of Biological Chemistry

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The Zap1 transcriptional activator of Saccharomyces cerevisiae plays a major role in zinc homeostasis by inducing the expression of several genes under zinc-limited growth conditions. This activation of gene expression is mediated by binding of the protein to one or more zinc-responsive elements present in the promoters of its target genes. To better understand how Zap1 functions, we mapped its DNA binding domain using a combined in vivo and in vitro approach. Our results show that the Zap1 DNA binding domain maps to the carboxyl-terminal 194 amino acids of the protein; this region contains five of its seven potential zinc finger domains. Fusing this region to the Gal4 activation domain complemented a zap1⌬ mutation for low zinc growth and also conferred high level expression on a zinc-responsive element-lacZ reporter. In vitro, the purified 194-residue fragment bound to DNA with a high affinity (dissociation constant in the low nanomolar range) similar to that of longer fragments of Zap1. Furthermore, by deletion and sitedirected mutagenesis, we demonstrated that each of the five carboxyl-terminal zinc fingers are required for high affinity DNA binding.

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Mechanical stress triggers nuclear remodeling and the formation of transmembrane actin nuclear lines with associated nuclear pore complexes

Hoffman

Smith

Jensen

et al. 2020

MBoC

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A mechanical-biochemical feedback loop regulates remodeling in the actin cytoskeleton

Stachowiak¹,

Smith

Blankman

et al. 2014

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

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Cytoskeletal actin assemblies transmit mechanical stresses that molecular sensors transduce into biochemical signals to trigger cytoskeletal remodeling and other downstream events. How mechanical and biochemical signaling cooperate to orchestrate complex remodeling tasks has not been elucidated. Here, we studied remodeling of contractile actomyosin stress fibers. When fibers spontaneously fractured, they recoiled and disassembled actin synchronously. The disassembly rate was accelerated more than twofold above the resting value, but only when contraction increased the actin density to a threshold value following a time delay. A mathematical model explained this as originating in the increased overlap of actin filaments produced by myosin II-driven contraction. Above a threshold overlap, this mechanical signal is transduced into accelerated disassembly by a mechanism that may sense overlap directly or through associated elastic stresses. This biochemical response lowers the actin density, overlap, and stresses. The model showed that this feedback mechanism, together with rapid stress transmission along the actin bundle, spatiotemporally synchronizes actin disassembly and fiber contraction. Similar actin remodeling kinetics occurred in expanding or contracting intact stress fibers but over much longer timescales. The model accurately described these kinetics, with an almost identical value of the threshold overlap that accelerates disassembly. Finally, we measured resting stress fibers, for which the model predicts constant actin overlap that balances disassembly and assembly. The overlap was indeed regulated, with a value close to that predicted. Our results suggest that coordinated mechanical and biochemical signaling enables extended actomyosin assemblies to adapt dynamically to the mechanical stresses they convey and direct their own remodeling.echanical signaling plays critical roles in diverse cellular processes such as cell migration, adhesion, differentiation, morphogenesis, and gene transcription (1-3). In these contexts, cytoskeletal actin structures spatially distribute mechanical stresses, thereby rapidly communicating mechanical information to remote locations within the cell (4). Transduction of this information to altered biochemical activity of local molecular mechanosensors can then activate remodeling of the cytoskeleton and other downstream events (2, 3). Mixed signaling pathways of this type involving either stress or strain sensors have been identified. The cytoskeleton conveys stresses that alter the binding activity of talin to vinculin in focal adhesions (5), and mechanical strains in actin networks in vitro were transduced by filamin cross-linkers into altered binding affinities for proteins that regulate downstream actin remodeling (6). However, it remains unclear how mechanical and biochemical signaling are coordinated in vivo to orchestrate complex cell-scale reorganizations of the cytoskeleton.Far from passive, actomyosin assemblies that convey mechanical stress are active and dynamic ...

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