Nesprins LINC the nucleus and cytoskeleton

Available online at www.sciencedirect.com

Nesprins LINC the nucleus and cytoskeleton Jason A Mellada, Derek T Warrena and Catherine M Shanahan Like other spectrin repeat proteins, nesprins co-ordinate and maintain cellular architecture by linking membranous organelles to the cytoskeleton. However nuclear envelope (NE) nesprins, uniquely hardwire the nuclear lamina to the cytoskeleton and molecular motors. Emerging evidence suggests that nesprins also form a continuous network linking the plasma membrane to the NE that potentially translates mechanical stimuli into nuclear reorganisation. Surprisingly, this network is also essential for cytoskeletal organisation and its disruption has dramatic effects on nuclear migration, centrosomal positioning, focal adhesion maturation and cell motility. Herein we review recent advances in our understanding of how nesprins couple to various filamentous systems within the cell and emphasise the importance of both KASH and KASH-less nesprin isoforms in these interactions. Address BHF Centre of Research Excellence, Division of Cardiovascular Medicine, King’s College London, SE5 9NU, UK a These authors contributed equally. Corresponding author: Shanahan, Catherine M ([email protected])

Current Opinion in Cell Biology 2011, 23:47–54 This review comes from a themed issue on Cell structure and dynamics Edited by Anne Ridley and Rebecca Heald Available online 20th December 2010 0955-0674/$ – see front matter # 2010 Elsevier Ltd. All rights reserved. DOI 10.1016/j.ceb.2010.11.006

Introduction The nuclear envelope (NE) is a highly organised structure that partitions the nuclear and cytoplasmic environments of the cell. It is composed of two lipid bilayers, the inner nuclear membrane (INM) and the outer nuclear membrane (ONM) and these are separated by a lumenal space [1,2]. Nuclear pore complexes span these membranes and regulate protein transport between the nucleoplasm and the cytosol [1,2]. NE structural and functional integrity is maintained via specific components of the INM and ONM that also physically link the cytoskeleton and nuclear lamina; a meshwork of intermediate filaments (IF) consisting of A-type and B-type lamins that underlie the INM (Figure 1) [3]. These essential connections enable the nucleus to maintain its position and tension within the cell during cell www.sciencedirect.com

polarisation, migration and differentiation and also relay mechanical signals to the nucleus [4]. The evolutionarily conserved, multi-isomeric Nuclear Envelope SPectRIN repeat proteins (nesprins) are an emerging family of nuclear-cytoplasmic couplers. Four genes (SYNE 1–4) encoding nesprins 1–4 have been identified so far. Nesprins are characterised by a central rod region of variable length, comprised of multiple spectrin repeats, and a C-terminal Klarsicht/ANC-1/Syne homology (KASH) transmembrane domain that facilitates NE localisation [5]. The nesprins are also characterised by variable N-terminal motifs that enable interactions with different components of the cytoskeleton. Giant isoforms of nesprin1 (1 MDa in size) and nesprin-2 (800 kDa) have Nterminal calponin homology (CH) domains that link to filamentous actin (F-actin), nesprin-3 (110 kDa) has a plectin-binding motif that permits interactions with cytoplasmic IFs while nesprin-4 interacts indirectly with microtubules [5–7]. Importantly, nesprins localise via the KASH domain to both the INM and ONM and are partitioned to these domains depending on their size and binding partners (Figure 1) [8]. INM nesprins-1/2 possess C-terminal spectrin repeats that can interact with both the INM protein emerin and A-type lamins [9,10]. Thus, nesprins can form structural connections on either face of the NE. Nesprins and other KASH-domain proteins are recruited to the NE by binding to the Sad1p-UNC84 (SUN) domain proteins Sun1 and Sun2 within the perinuclear space, forming the linker of the nucleoskeleton and cytoskeleton (LINC) complex (Figure 1) [8]. The LINC anchors the nuclear lamina, which binds INM Sun proteins, to the cytoskeleton via ONM nesprins. Overexpression of dominant-negative KASH domain constructs and knockdown of LINC components nesprins-1/2, Sun1/2 or lamin A uncouples the INM from the ONM, detaches the nucleus from the cytoskeleton and decreases mechanical stiffness [8]. The importance of the LINC in cytoskeletal organisation and biomechanical signalling is further reflected in the wide range of disease phenotypes resulting from mutations in nesprins-1/2, including cardiac and skeletal muscle defects in Emery Dreifuss muscular dystrophy (EDMD), cerebellar defects in autosomal recessive spinocerebellar ataxia 1 (ARCA1) and tendon contractures in autosomal recessive arthrogryposis multiplex congenita (AMC) [11–13].

Nesprins associate with multiple cytoskeletal systems The LINC has primarily been characterised as serving three functions: to tether the nucleus to the cytoskeleton, Current Opinion in Cell Biology 2011, 23:47–54

48 Cell structure and dynamics

Figure 1

Actin cytoskeleton Intermediate filaments

Microtubules Nesprin-4

Nesprin-3

Cytoplasm

Nesprins-1/2

Plectin

Kif5B

ONM Nuclear pore complex

SUN domain

SUN domain

SUN domain

SUN domain INM

Emerin Nucleoplasm

CH domain

Nuclear lamina

Spectrin repeat

KASH domain

SUN domain containing protein Current Opinion in Cell Biology

The LINC complex facilitates the coupling of the nuclear lamina to cytoplasmic cytoskeletal systems via the nesprins. The LINC complex is comprised of SUN domain containing proteins (SUN1 and 2, UNC84 and SPAG4) on the INM that bind to the nuclear lamina via interactions with lamin A, and potentially smaller nesprin-1/2 isoforms and emerin. The KASH domain of the larger isoforms of nesprins-1/2, nesprin-3 and nesprin-4 at the ONM associate with the SUN domain within the luminal space to tether the NE to either cytoplasmic actin, IFs or microtubule networks.

facilitate the mechanotransduction of peripheral signals to the nucleus and also to regulate cytoplasmic filament organisation during migration, adhesion and polarity establishment. It is clear that ONM nesprins are integral to all of these roles owing to their ability to indirectly or directly interact with all three major cytoplasmic filaments (Table 1). Connections with the actin cytoskeleton

The most characterised nesprin LINCs anchor the nucleus to the actin cytoskeleton. Surprisingly, the direct linkage of the NE to F-actin defines the mechanical properties of the entire cell via mechanotransduction between the cytoplasm and the nucleus [4]. Uncoupling of this mechanical link, in either nesprin-1 KASH domain or C-terminal spectrin repeat knockout mice, results in a loss of cellular tension that induces abnormal localisation of skeletal muscle nuclei and defects in strain transCurrent Opinion in Cell Biology 2011, 23:47–54

mission between the cell and nucleus [14,15]. Moreover, nuclear morphology is defined by thick actin bundles that are organised into a curved shell overlaying the nucleus, moulding it into a shape resembling overall cell morphology. Chemicals that depolymerise F-actin or inhibit Rho kinase, a key regulator of F-actin organisation and actomyosin contractility, release the nucleus from these physical constraints, resulting in nuclear morphology defects [16]. Similarly, disruption of the LINC complex, by either the expression of dominantnegative nesprin KASH constructs or mutation of nuclear lamina proteins, eliminates this actin shell and induces nuclear morphology defects [16]. Furthermore, uncoupling of the nucleus from the actin cytoskeleton triggers a loss of cellular tension. This loss of tension impacts on maturation of focal adhesions, important macromolecular cell–matrix adhesions that transmit mechanical force and other signals, as well as on cell motility. This suggests that www.sciencedirect.com

Nesprins LINC the nucleus and cytoskeleton Mellad, Warren and Shanahan 49

Table 1 Summary of demonstrated nesprin LINC complexes. Nesprins connect the NE to the cytoskeleton via direct interactions with F-actin or indirectly to microtubule and IF binding proteins. Connection Actin

F-actin

Nesprin

Function

Meckelin

Nesprin-1 Nesprin-2 Nesprin-2

IF

Lamin A Plectin

Nesprin-1/2 Nesprin-3

Chromatin organisation, NE architecture. NE-IF coupling

Microtubules

Kinesin-1 Kinesin-2 Dynein Dynactin

Nesprin-2/4 Nesprin-1 Nesprin-1/2 Nesprin-1/2

Nuclear migration, polarity. Vesicular transport. Nuclear migration, polarity. Nuclear migration, polarity

nuclear tethering to the actin cytoskeleton may be crucial for F-actin organisation throughout the cell [17,18,19]. Although the N-terminal paired CH domains remain the only characterised F-actin-binding module within nesprins-1/2 [20,21], evidence now exists for alternative connections to the actin cytoskeleton. For instance, nesprin-2 CH domain knockout dermal fibroblasts display nuclear blebbing and lobulations in vitro characteristic of LINC disruption. Interestingly, after several passages, these fibroblasts gradually express a novel, N-terminally truncated giant nesprin-2 isoform that alleviates this phenotype [22]. This suggests that similar to their homologues dystrophin and utrophin, nesprin spectrin repeats may also bind filamentous actin either directly or indirectly via as yet unknown binding partners [23–25]. Intriguingly, emerging data support the existence of Factin at the INM. Recent studies have shown that the nesprin binding partners emerin and lamin-A serve to stabilise and bundle F-actin [26,27]. Importantly, Factin may potentially contribute to LINC stability as emerin, lamin A and nesprin-1/2 spectrin repeats can all interact with the nucleoplasmic N-termini of Sun1/2 [28,29,30,31]. However, the nature and abundance of actin filaments at the INM remains controversial and further work is required to determine if INM nesprins and nuclear actin are also components of the LINC complex.

Connections with the centrosome/ microtubule network Nesprins also make multiple indirect connections with the microtubule network by forming microtubule motor LINCs. Analogous to the roles of UNC-83 and ZYG-12 in C. elegans and Klarsicht in Drosophila, these LINCs are essential for both nuclear and centrosomal positioning and therefore cell polarity [8]. Recent studies have demonstrated that nesprins-1/2 interact with dynein/ dynactin and kinesin-1 in the developing mouse brain and loss of these interactions in double nesprin-1/2KASH knockout mice uncouples the centrosome from www.sciencedirect.com

Nuclear positioning, Mechanotransduction. Ciliogenesis.

the neuronal nucleus resulting in severe nucleokinesis and interkinetic nuclear migration defects [30]. Similarly, zebrafish nesprin-2 also binds to dynactin and is necessary for photoreceptor interkinetic nuclear migration as demonstrated by knockdown and dominant-negative KASH overexpression studies [32]. Moreover, interactions between nesprin-4 and kinesin-1 regulate epithelial cell polarity and nuclear positioning with nesprin-4 overexpression dramatically displacing the centrosome and Golgi away from the NE [6]. Interestingly, a central spectrin repeat region of nesprin-1 also binds to the kinesin-2 subunit Kif3b and appears to play a role in cytokinesis and membrane transport. However whether these functions are mediated by a nesprin NE LINC or a KASH-less isoform (see below) must be explored further [33].

Nesprins associate with intermediate filament systems in the nucleus and cytoplasm Nesprins tether to IF systems in both the nucleus and cytoplasm and these connections potentially serve important organisational roles within the cell. The nuclear lamina is an IF meshwork and lamins-A/C were the first binding partners identified for nesprin-1 and nesprin-2. Our understanding of these complexes remains poor and it is not yet clear if these interactions are all LINC-dependent [5]. However both nesprins and lamins bind to multiple integral membrane proteins of the INM and one important function for these nuclear lamina complexes is the organisation of heterochromatin, which is facilitated by auxiliary proteins such as BAF, LAP2a and possibly smaller nesprin-1/2 isoforms [34,35]. Indeed, the dramatic heterochromatin reorganisation induced by knockdown of nesprins-1/2 in U2OS cells and fibroblasts may be partially attributed to the loss of INM isoforms and consequently disruption of a direct link between mechanical stimuli and chromatin organisation, although this possibility requires further investigation [12]. An emerging area for investigation is the interaction between nesprins and cytoplasmic IF networks. These LINCs are proposed to connect the NE to another form of Current Opinion in Cell Biology 2011, 23:47–54

50 Cell structure and dynamics

Figure 2

SR1

SR45

Nesprin-1 Giant 1β 1 1β 2 1α1 1α2

Drop1 CPG2

Nesprin-2 SR1

SR18

Giant 2γ 2β 1 2β 2 2α1 2α2

Nesprin-3

3α CH domain 3β

Spectrin repeat Nesprin-4 KASH domain

4 Current Opinion in Cell Biology

Previously published nesprin isoforms. LINC adaptability is increased by the generation of multiple nesprin isoforms of variable length and with different SR domains. The majority of isoforms characterised so far are N-terminal truncations that retain the KASH domain, suggesting that the proximity of cytoskeletal filaments and other nesprin-bound complexes to the NE may have functional significance. In addition, the number of characterised KASH-less isoforms is steadily increasing.

cell–matrix adhesion known as hemidesmosomes, providing further mechanical support for cells. For example, nesprin-3 binds to the CH domain of the IF-crosslinker plectin and thus forms a continuous IF network between the NE and hemidesmosomes [7,36]. Nesprin-3 appears to be central to IF LINC complex function as both plectin and keratins are drawn to the nuclear periphery of keratinocytes overexpressing nesprin3a [7]. It has been proposed that when actin filaments are naturally or artificially depolymerised the nesprin-3-dependent relocalisation of endogenous plectin to the nuclear periphery may facilitate rapid reorganisation of the cytoskeleton [7]. Current Opinion in Cell Biology 2011, 23:47–54

Different LINCs for different tissues The properties of a mechanically coupled, differentiated muscle cell are vastly different to a fibroblast or a polarised cell such as an endothelial cell. Thus, different cell types have unique biomechanical properties that are likely to require customised connections between the nucleus and cytoskeleton. It is likely that this specialisation is accomplished through the tissue-specific expression of nesprin genes and isoforms allowing cells to fine-tune these connections (Figure 2). For example, nesprin-4 is highly expressed only in specialised secretory epithelium where it is thought to be essential for www.sciencedirect.com

Nesprins LINC the nucleus and cytoskeleton Mellad, Warren and Shanahan 51

establishing centrosome positioning and cell polarity. Similarly, nesprin-1 is essential for neuromuscular junction (NMJ) formation and nesprin-2 is highly enriched in photoreceptor nuclei however the functional reasons for this specificity are not yet clear [6,15,30,32,37]. Nesprin isoforms also vary greatly between different tissues [38]. Nesprins 1/2 are especially abundant in muscle and express muscle specific isoforms. Moreover, mutations

in nesprin-1 and nesprin-2 have been reported in the muscle specific disease EDMD but these mutations appear to have little impact on other tissues. There is also a switch from larger to smaller NE nesprin isoforms during human myotube differentiation. This may serve to adapt LINC function enabling cells to change from a dynamic motile phenotype to a rigid, stable contractile phenotype [39]. It will be interesting to determine

Figure 3

Plasma membrane Binding partners? KASH domain containing isoforms?

KASH-less isoforms?

Actin IFs Microtubules

Cytoplasm

ONM Nuclear pore complex

SUN domain

SUN domain

SUN domain INM

Emerin

Nucleoplasm

Nuclear lamina

Actin filaments

CH domain

Spectrin repeat

KASH domain

SUN domain containing protein Current Opinion in Cell Biology

Nesprins form a mechanotransduction network between the plasma membrane and NE via connections with cytoplasmic cytoskeletal systems. Nesprins localise to the plasma membrane; whether or not these isoforms retain the KASH domain and how they are targeted remain unknown. The nesprin bridging network via the cytoskeleton potentially allows cells to maintain tension between the plasma membrane and nucleus that is essential for both organelle and cytoskeletal organisation within a cell [4]. www.sciencedirect.com

Current Opinion in Cell Biology 2011, 23:47–54

52 Cell structure and dynamics

whether LINCs are also able to dynamically respond to mechanical stimuli thus enabling the cell to rapidly adapt to different environmental conditions. The method of nesprin tethering to the NE may also contribute to LINC functional specialisation. Emerging evidence exists for non-canonical LINCs that do not solely rely on Sun1/2 or lamin A. For instance, Sun1/2 redundantly tether nesprin in some cell types but not in others [36,40,41,42] while torsin-1A, an ATPase localised to the perinuclear space, is also a KASH binding protein that regulates nesprin NE localisation [43,44]. LINCs have recently been implicated in highly specialised roles and have been shown to mediate chromosome pairing during meiosis in C. elegans. It will be important to determine if analogous specialised LINCs also operate in vertebrates [45].

Concluding remarks In conclusion, our knowledge of nesprin LINCs and their role in attaching the NE to the cytoskeleton has increased dramatically over the past few years. However, we still lack a complete understanding of the complexity of connections nesprins make with the filamentous cytoskeletal systems and identification of novel binding partners will help to address this deficit. Additionally, increasing evidence implicates the KASH containing nesprins as signalling scaffolds at the NE and potentially the KASH-less isoforms in other subcellular compartments. However, these KASH-less isoforms remain to be fully characterised. Indeed, a comprehensive read out of nesprin isoform profiles, localisations and interactions in different cell types will enable us to better understand both nesprin and LINC complex variability and function.

Acknowledgements Finally, in addition to their mechanical roles in LINC complex function, recent evidence suggests that nesprins may also serve as signalling scaffold proteins at the NE. Nesprin-2 has recently been shown to regulate WNT signalling and binds alpha and beta catenin at the NE, suggesting that in addition to their structural/mechanical roles LINC complexes may also function as signalling platforms [46].

This work was supported by British Heart Foundation (BHF) grants to CMS.

References and recommended reading Papers of particular interest, published within the annual period of review, have been highlighted as:  of special interest  of outstanding interest 1.

Chi YH, Chen ZJ, Jeang KT: The nuclear envelopathies and human diseases. J Biomed Sci 2009, 16:96.

2.

Hetzer MW: The nuclear envelope. Cold Spring Harb Perspect Biol 2010, 2:a000539.

3.

Goldberg MW, Fiserova J, Huttenlauch I, Stick R: A new model for nuclear lamina organization. Biochem Soc Trans 2008, 36:1339-1343.

KASH-less nesprin isoforms The body of nesprin research so far has primarily concentrated on how disruption of NE isoforms alters cytoskeletal organisation and the mechanical properties of the cell. However, immunofluorescence microscopy studies using antibodies generated to different regions of the giant nesprin-1/2 isoforms and also GFP-tagged fusion constructs suggest that nesprins also localise to the plasma membrane in actin rich structures such as focal adhesions, filopodia and lamellopodia [20,21,47]. Meckelin, a transmembrane protein that localises to the primary cilium and the plasma membrane, has been identified as a novel nesprin-2 binding partner [48]. Importantly, nesprin-2 and meckelin colocalise at filopodia and microspikes, suggesting that nesprins may perform additional roles in tethering filamentous cytoskeletal networks to the plasma membrane in a manner analogous to their function at the NE (Figure 3). It is unknown whether these plasma membrane nesprin isoforms retain the KASH domain. However, evidence suggests that KASH-less isoforms are expressed and localise throughout the cell [30,48]. Although data are limited, emerging studies suggest that the primary function of these KASH-less isoforms is also as signalling scaffolds. Nesprin-2 isoforms interact with PLCg1 and PI3K at the plasma membrane and with ERK1/2 in the nucleus where it acts to regulate the nuclear activity of these kinases [49,50]. Clearly, further work is required to fully characterise these isoforms and elucidate their specific functions. Current Opinion in Cell Biology 2011, 23:47–54

4. 

Wang N, Tytell JD, Ingber DE: Mechanotransduction at a distance: mechanically coupling the extracellular matrix with the nucleus. Nat Rev Mol Cell Biol 2009, 10:75-82. A comprehensive review of the current understanding of cellular mechanotransduction. 5.

Warren DT, Zhang Q, Weissberg PL, Shanahan CM: Nesprins: intracellular scaffolds that maintain cell architecture and coordinate cell function? Expert Rev Mol Med 2005, 7:1-15.

6.

Roux KJ, Crisp ML, Liu Q, Kim D, Kozlov S, Stewart CL, Burke B: Nesprin 4 is an outer nuclear membrane protein that can induce kinesin-mediated cell polarization. Proc Natl Acad Sci USA 2009, 106:2194-2199.

7.

Wilhelmsen K, Litjens SH, Kuikman I, Tshimbalanga N, Janssen H, van den Bout I, Raymond K, Sonnenberg A: Nesprin-3, a novel outer nuclear membrane protein, associates with the cytoskeletal linker protein plectin. J Cell Biol 2005, 171:799-810.

8.

Razafsky D, Hodzic D: Bringing KASH under the SUN: the many faces of nucleo-cytoskeletal connections. J Cell Biol 2009, 186:461-472.

9.

Wilson KL, Holaska JM, Montes de Oca R, Tifft K, Zastrow M, Segura-Totten M, Mansharamani M, Bengtsson L: Nuclear membrane protein emerin: roles in gene regulation, actin dynamics and human disease. Novartis Found Symp 2005, 264:51-58 discussion 58–62, 227–230.

10. Zastrow MS, Vlcek S, Wilson KL: Proteins that bind A-type lamins: integrating isolated clues. J Cell Sci 2004, 117:979-987. 11. Gros-Louis F, Dupre N, Dion P, Fox MA, Laurent S, Verreault S, Sanes JR, Bouchard JP, Rouleau GA: Mutations in SYNE1 lead to a newly discovered form of autosomal recessive cerebellar ataxia. Nat Genet 2007, 39:80-85. www.sciencedirect.com

Nesprins LINC the nucleus and cytoskeleton Mellad, Warren and Shanahan 53

12. Zhang Q, Bethmann C, Worth NF, Davies JD, Wasner C, Feuer A, Ragnauth CD, Yi Q, Mellad JA, Warren DT et al.: Nesprin-1 and -2 are involved in the pathogenesis of Emery Dreifuss muscular dystrophy and are critical for nuclear envelope integrity. Hum Mol Genet 2007, 16:2816-2833. 13. Attali R, Warwar N, Israel A, Gurt I, McNally E, Puckelwartz M, Glick B, Nevo Y, Ben-Neriah Z, Melki J: Mutation of SYNE-1, encoding an essential component of the nuclear lamina, is responsible for autosomal recessive arthrogryposis. Hum Mol Genet 2009, 18:3462-3469. 14. Puckelwartz MJ, Kessler EJ, Kim G, Dewitt MM, Zhang Y, Earley JU, Depreux FF, Holaska J, Mewborn SK, Pytel P et al.: Nesprin-1 mutations in human and murine cardiomyopathy. J Mol Cell Cardiol 2010, 48:600-608. 15. Zhang J, Felder A, Liu Y, Guo LT, Lange S, Dalton ND, Gu Y, Peterson KL, Mizisin AP, Shelton GD et al.: Nesprin 1 is critical for nuclear positioning and anchorage. Hum Mol Genet 2010, 19:329-341. 16. Khatau SB, Hale CM, Stewart-Hutchinson PJ, Patel MS,  Stewart CL, Searson PC, Hodzic D, Wirtz D: A perinuclear actin cap regulates nuclear shape. Proc Natl Acad Sci USA 2009, 106:19017-19022. The first evidence that the actin cytoskeleton directly influences nuclear morphology. 17. Chancellor TJ, Lee J, Thodeti CK, Lele T: Actomyosin tension  exerted on the nucleus through nesprin-1 connections influences endothelial cell adhesion, migration, and cyclic strain-induced reorientation. Biophys J 2010, 99:1-9. Nesprin depletion recapitulates the migration and polarity defects observed in A-type lamin deficient cells, indicating that attachment of the nucleus to the cytoskeleton via LINC regulates tension across the cell. 18. Houben F, Willems CH, Declercq IL, Hochstenbach K, Kamps MA,  Snoeckx LH, Ramaekers FC, Broers JL: Disturbed nuclear orientation and cellular migration in A-type lamin deficient cells. Biochim Biophys Acta 2009, 1793:312-324. Demonstrates that loss of the LINC complex in cells lacking A-type lamins significantly disrupts cellular migration and polarity. 19. Hale CM, Shrestha AL, Khatau SB, Stewart-Hutchinson PJ, Hernandez L, Stewart CL, Hodzic D, Wirtz D: Dysfunctional connections between the nucleus and the actin and microtubule networks in laminopathic models. Biophys J 2008, 95:5462-5475. 20. Zhen YY, Libotte T, Munck M, Noegel AA, Korenbaum E: NUANCE, a giant protein connecting the nucleus and actin cytoskeleton. J Cell Sci 2002, 115:3207-3222. 21. Padmakumar VC, Abraham S, Braune S, Noegel AA, Tunggal B, Karakesisoglou I, Korenbaum E: Enaptin, a giant actin-binding protein, is an element of the nuclear membrane and the actin cytoskeleton. Exp Cell Res 2004, 295:330-339. 22. Luke Y, Zaim H, Karakesisoglou I, Jaeger VM, Sellin L, Lu W,  Schneider M, Neumann S, Beijer A, Munck M et al.: Nesprin-2 Giant (NUANCE) maintains nuclear envelope architecture and composition in skin. J Cell Sci 2008, 121:1887-1898. Importantly, this study suggests that nesprins make additional, CH domain-independent connections with F-actin and that isoform expression is controlled by a compensatory feedback mechanism. 23. Sutherland-Smith AJ, Moores CA, Norwood FL, Hatch V, Craig R, Kendrick-Jones J, Lehman W: An atomic model for actin binding by the CH domains and spectrin-repeat modules of utrophin and dystrophin. J Mol Biol 2003, 329:15-33. 24. Rybakova IN, Humston JL, Sonnemann KJ, Ervasti JM: Dystrophin and utrophin bind actin through distinct modes of contact. J Biol Chem 2006, 281:9996-10001. 25. Winder SJ, Hemmings L, Maciver SK, Bolton SJ, Tinsley JM, Davies KE, Critchley DR, Kendrick-Jones J: Utrophin actin binding domain: analysis of actin binding and cellular targeting. J Cell Sci 1995, 108(Pt 1):63-71. 26. Holaska JM, Kowalski AK, Wilson KL: Emerin caps the pointed end of actin filaments: evidence for an actin cortical network at the nuclear inner membrane. PLoS Biol 2004, 2:E231. www.sciencedirect.com

27. Simon DN, Zastrow MS, Wilson KL: Direct actin binding to A and B-type lamin tails and actin filament bundling by the lamin A tail. Nucleus 2010, 1:1-9. Similar to the presence of intermediate filament networks both inside and outside the nucleus, this paper now reveals that F-actin exists on both faces of the NE. Surprisingly, lamins can directly bind and bundle F-actin at the INM. 28. Haque F, Lloyd DJ, Smallwood DT, Dent CL, Shanahan CM, Fry AM, Trembath RC, Shackleton S: SUN1 interacts with nuclear lamin A and cytoplasmic nesprins to provide a physical connection between the nuclear lamina and the cytoskeleton. Mol Cell Biol 2006, 26:3738-3751. 29. Haque F, Mazzeo D, Patel JT, Smallwood DT, Ellis JA,  Shanahan CM, Shackleton S: Mammalian SUN protein interaction networks at the inner nuclear membrane and their role in laminopathy disease processes. J Biol Chem 2010, 285:3487-3498. Highlights the complexity of the LINC complex and describes novel INM interactions involving nesprin spectrin repeats, emerin and Sun1/2. 30. Zhang X, Lei K, Yuan X, Wu X, Zhuang Y, Xu T, Xu R, Han M: SUN1/ 2 and Syne/Nesprin-1/2 complexes connect centrosome to the nucleus during neurogenesis and neuronal migration in mice. Neuron 2009, 64:173-187. 31. Padmakumar VC, Libotte T, Lu W, Zaim H, Abraham S, Noegel AA, Gotzmann J, Foisner R, Karakesisoglou I: The inner nuclear membrane protein Sun1 mediates the anchorage of Nesprin-2 to the nuclear envelope. J Cell Sci 2005, 118:3419-3430. 32. Del Bene F, Wehman AM, Link BA, Baier H: Regulation of neurogenesis by interkinetic nuclear migration through an apical-basal notch gradient. Cell 2008, 134:1055-1065. 33. Fan J, Beck KA: A role for the spectrin superfamily member Syne-1 and kinesin II in cytokinesis. J Cell Sci 2004, 117:619-629. 34. Worman HJ, Courvalin JC: Nuclear envelope, nuclear lamina, and inherited disease. Int Rev Cytol 2005, 246:231-279. 35. Malik P, Zuleger N, Schirmer EC: Nuclear envelope influences on genome organization. Biochem Soc Trans 2010, 38:268-272. 36. Ketema M, Wilhelmsen K, Kuikman I, Janssen H, Hodzic D, Sonnenberg A: Requirements for the localization of nesprin-3 at the nuclear envelope and its interaction with plectin. J Cell Sci 2007, 120:3384-3394. 37. Puckelwartz MJ, Kessler E, Zhang Y, Hodzic D, Randles KN, Morris G, Earley JU, Hadhazy M, Holaska JM, Mewborn SK et al.: Disruption of nesprin-1 produces an Emery Dreifuss muscular dystrophy-like phenotype in mice. Hum Mol Genet 2009, 18:607-620. 38. Zhang Q, Skepper JN, Yang F, Davies JD, Hegyi L, Roberts RG, Weissberg PL, Ellis JA, Shanahan CM: Nesprins: a novel family of spectrin-repeat-containing proteins that localize to the nuclear membrane in multiple tissues. J Cell Sci 2001, 114:4485-4498. 39. Randles KN, Lam le T, Sewry CA, Puckelwartz M, Furling D,  Wehnert M, McNally EM, Morris GE: Nesprins, but not sun proteins, switch isoforms at the nuclear envelope during muscle development. Dev Dyn 2010, 239:998-1009. The first in-depth study of changes in nesprin isoform expression during muscle development. 40. Ostlund C, Folker ES, Choi JC, Gomes ER, Gundersen GG,  Worman HJ: Dynamics and molecular interactions of linker of nucleoskeleton and cytoskeleton (LINC) complex proteins. J Cell Sci 2009. An elegant description of LINC complex stability at the NE using FRAP, showing that these complexes are fluid. 41. Crisp M, Liu Q, Roux K, Rattner JB, Shanahan C, Burke B, Stahl PD, Hodzic D: Coupling of the nucleus and cytoplasm: role of the LINC complex. J Cell Biol 2006, 172:41-53. 42. Lei K, Zhang X, Ding X, Guo X, Chen M, Zhu B, Xu T, Zhuang Y, Xu R, Han M: SUN1 and SUN2 play critical but partially redundant roles in anchoring nuclei in skeletal muscle cells in mice. Proc Natl Acad Sci USA 2009, 106:10207-10212. Current Opinion in Cell Biology 2011, 23:47–54

54 Cell structure and dynamics

43. Vander Heyden AB, Naismith TV, Snapp EL, Hodzic D, Hanson PI: LULL1 retargets TorsinA to the nuclear envelope revealing an activity that is impaired by the DYT1 dystonia mutation. Mol Biol Cell 2009, 20:2661-2672. 44. Nery FC, Zeng J, Niland BP, Hewett J, Farley J, Irimia D, Li Y, Wiche G, Sonnenberg A, Breakefield XO: TorsinA binds the KASH domain of nesprins and participates in linkage between nuclear envelope and cytoskeleton. J Cell Sci 2008, 121:3476-3486. 45. Penkner A, Tang L, Novatchkova M, Ladurner M, Fridkin A, Gruenbaum Y, Schweizer D, Loidl J, Jantsch V: The nuclear envelope protein Matefin/SUN-1 is required for homologous pairing in C. elegans meiosis. Dev Cell 2007, 12:873-885. 46. Neumann S, Schneider M, Daugherty RL, Gottardi CJ, Eming SA, Beijer A, Noegel AA, Karakesisoglou I: Nesprin-2 interacts with {alpha}-catenin and regulates Wnt signaling at the nuclear envelope. J Biol Chem 2010, 285:34932-34938. 47. Zhang Q, Ragnauth CD, Skepper JN, Worth NF, Warren DT, Roberts RG, Weissberg PL, Ellis JA, Shanahan CM: Nesprin-2 is a

Current Opinion in Cell Biology 2011, 23:47–54

multi-isomeric protein that binds lamin and emerin at the nuclear envelope and forms a subcellular network in skeletal muscle. J Cell Sci 2005, 118:673-687. 48. Dawe HR, Adams M, Wheway G, Szymanska K, Logan CV,  Noegel AA, Gull K, Johnson CA: Nesprin-2 interacts with meckelin and mediates ciliogenesis via remodelling of the actin cytoskeleton. J Cell Sci 2009, 122:2716-2726. Provides further evidence of NE-independent nesprin function and implicates nesprins in plasma membrane coupling to the cytoskeleton. 49. Warren DT, Tajsic T, Mellad JA, Searles R, Zhang Q, Shanahan CM: Novel nuclear nesprin-2 variants tether active extracellular signal-regulated MAPKs 1 and 2 at promyelocytic leukaemia protein nuclear bodies and act to regulate smooth muscle cell proliferation. J Biol Chem 2009. 50. Seung Jin Han JHL, Ki Young Choi, Seung Hwan Hong: Novel p104 protein regulates cell proliferation through PI3K inhibition and p27Kip1 expression. BMB Rep 2009, 43:199-204.

www.sciencedirect.com