The molecular architecture of lamins in somatic cells

Turgay, Yagmur; Eibauer, Matthias; Goldman, Anne E.; Shimi, Takeshi; Khayat, Maayan; Ben‐Harush, Kfir; Dubrovsky-Gaupp, Anna; Sapra, K. Tanuj; Goldman, Robert D.; Medalia, Ohad

doi:10.1038/nature21382

Cited by 359 publications

(441 citation statements)

References 41 publications

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“…Localizing individual or rare proteins and transient biomolecular complexes in situ using cryoEM is difficult due to the crowded cellular landscape that is visible by cryoEM. Currently, proteins are identified by, e.g., immunolabeling using gold beads, or tagged with proteins that accumulate heavy metals to become electron dense . However, these are not optimal, with generally a poor binding efficiency and difficulties with intracellular delivery of both heavy metals and (immuno)labeling agents .…”

Section: Applications and Future Perspectivesmentioning

confidence: 99%

Correlated Cryo Super‐Resolution Light and Cryo‐Electron Microscopy on Mammalian Cells Expressing the Fluorescent Protein rsEGFP2

et al. 2019

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Super‐resolution light microscopy (SRM) enables imaging of biomolecules within cells with nanometer precision. Cryo‐fixation by vitrification offers optimal structure preservation of biological specimens and permits sequential cryo electron microscopy (cryoEM) on the same sample, but is rarely used for SRM due to various technical challenges and the lack of fluorophores developed for vitrified conditions. Here, a protocol to perform correlated cryoSRM and cryoEM on intact mammalian cells using fluorescent proteins and commercially available equipment is described. After cell culture and sample preparation by plunge‐freezing, cryoSRM is performed using the reversibly photoswitchable fluorescent protein rsEGFP2. Next, a super‐resolved image is reconstructed to guide cryoEM imaging to the feature of interest. Finally, the cryoSRM and cryoEM images are correlated to combine information from both imaging modalities. Using this protocol, a localization precision of 30 nm for cryoSRM is routinely achieved. No impediments to successive cryoEM imaging are detected, and the protocol is compatible with a variety of cryoEM techniques. When the optical set‐up and analysis pipeline is established, the total duration of the protocol for experienced cryoEM users is 3 days, not including cell culture.

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Section: Applications and Future Perspectivesmentioning

confidence: 99%

Correlated Cryo Super‐Resolution Light and Cryo‐Electron Microscopy on Mammalian Cells Expressing the Fluorescent Protein rsEGFP2

et al. 2019

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“…The different lamin subtypes are assembled into structurally similar filaments that form a densely interwoven meshwork apposed to the INM [11,12]. Recent cryo-electron tomography revealed that lamin filaments in cultured cells are unexpectedly thin: they have an ~3.5 nm diameter, and most likely contain two dimers per filament cross-section [13 •• ]. By contrast, cytoplasmic intermediate filaments have a diameter of ~10 nm [14].…”

Section: The Regulatory Framework At the Inner Nuclear Membranementioning

confidence: 99%

“…The diagram illustrates the direct connection of the ONM with the peripheral ER, and the lipid bilayer continuity between the ONM and INM at NPCs. Nuclear lamin filaments [13 •• ] are depicted as a green meshwork underlying the INM. Widely studied INM proteins are shown, with transmembrane segments and folded domains represented by cylinders spanning the lipid bilayer and external to it, respectively.…”

Section: Figurementioning

confidence: 99%

Messages from the voices within: regulation of signaling by proteins of the nuclear lamina

Gerace

Tapia

2018

Current Opinion in Cell Biology

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The nuclear lamina (NL) is a protein scaffold lining the nuclear envelope that consists of nuclear lamins and associated transmembrane proteins. It helps to organize the nuclear envelope, chromosomes, and the cytoplasmic cytoskeleton. The NL also has an important role in regulation of signaling, as highlighted by the wide range of human diseases caused by mutations in the genes for NL proteins with associated signaling defects. This review will consider diverse mechanisms for signaling regulation by the NL that have been uncovered recently, including interaction with signaling effectors, modulation of actin assembly and compositional alteration of the NL. Cells with discrete NL mutations often show disruption of multiple signaling pathways, however, and for the most part the mechanistic basis for these complex phenotypes remains to be elucidated.

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“…They bear an NLS leading to their importation into the nucleoplasm. In the nucleus, lamins A and C are constituents of the nuclear matrix: (i) the lamina where they interact with B‐type lamins, with several nuclear envelope transmembrane partner proteins (NETs) of the INM and with the NPC, and (ii) the internal nuclear meshwork forming a component of the nucleoskeleton (Cau et al., 2014; Gruenbaum & Foisner, 2015; Turgay et al., 2017). This lamin meshwork plays a major role in cell structure by conferring the architecture of the nucleoplasm and maintaining the nuclear shape (Ungricht & Kutay, 2017).…”

Section: Lamins and Laminopathiesmentioning

confidence: 99%

MicroRNAs in hereditary and sporadic premature aging syndromes and other laminopathies

et al. 2018

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SummaryHereditary and sporadic laminopathies are caused by mutations in genes encoding lamins, their partners, or the metalloprotease ZMPSTE24/FACE1. Depending on the clinical phenotype, they are classified as tissue‐specific or systemic diseases. The latter mostly manifest with several accelerated aging features, as in Hutchinson–Gilford progeria syndrome (HGPS) and other progeroid syndromes. MicroRNAs are small noncoding RNAs described as powerful regulators of gene expression, mainly by degrading target mRNAs or by inhibiting their translation. In recent years, the role of these small RNAs has become an object of study in laminopathies using in vitro or in vivo murine models as well as cells/tissues of patients. To date, few miRNAs have been reported to exert protective effects in laminopathies, including miR‐9, which prevents progerin accumulation in HGPS neurons. The recent literature has described the potential implication of several other miRNAs in the pathophysiology of laminopathies, mostly by exerting deleterious effects. This review provides an overview of the current knowledge of the functional relevance and molecular insights of miRNAs in laminopathies. Furthermore, we discuss how these discoveries could help to better understand these diseases at the molecular level and could pave the way toward identifying new potential therapeutic targets and strategies based on miRNA modulation.

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The molecular architecture of lamins in somatic cells

Cited by 359 publications

References 41 publications

Correlated Cryo Super‐Resolution Light and Cryo‐Electron Microscopy on Mammalian Cells Expressing the Fluorescent Protein rsEGFP2

Correlated Cryo Super‐Resolution Light and Cryo‐Electron Microscopy on Mammalian Cells Expressing the Fluorescent Protein rsEGFP2

Messages from the voices within: regulation of signaling by proteins of the nuclear lamina

MicroRNAs in hereditary and sporadic premature aging syndromes and other laminopathies

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