Kaushik Sengupta

Nuclear lamins: major factors in the structural organization and function of the nucleus and chromatin

Over the past few years it has become evident that the intermediate filament proteins, the types A and B nuclear lamins, not only provide a structural framework for the nucleus, but are also essential for many aspects of normal nuclear function. Insights into lamin-related functions have been derived from studies of the remarkably large number of disease-causing mutations in the human lamin A gene. This review provides an up-to-date overview of the functions of nuclear lamins, emphasizing their roles in epigenetics, chromatin organization, DNA replication, transcription, and DNA repair. In addition, we discuss recent evidence supporting the importance of lamins in viral infections.

The highly conserved nuclear lamin Ig-fold binds to PCNA: its role in DNA replication.

This study provides insights into the role of nuclear lamins in DNA replication. Our data demonstrate that the Ig-fold motif located in the lamin C terminus binds directly to proliferating cell nuclear antigen (PCNA), the processivity factor necessary for the chain elongation phase of DNA replication. We find that the introduction of a mutation in the Ig-fold, which alters its structure and causes human muscular dystrophy, inhibits PCNA binding. Studies of nuclear assembly and DNA replication show that lamins, PCNA, and chromatin are closely associated in situ. Exposure of replicating nuclei to an excess of the lamin domain containing the Ig-fold inhibits DNA replication in a concentration-dependent fashion. This inhibitory effect is significantly diminished in nuclei exposed to the same domain bearing the Ig-fold mutation. Using the crystal structures of the lamin Ig-fold and PCNA, molecular docking simulations suggest probable interaction sites. These findings also provide insights into the mechanisms underlying the numerous disease-causing mutations located within the lamin Ig-fold.

Structural analysis of the DNA-binding domain of the Erwinia amylovora RcsB protein and its interaction with the RcsAB box.

The transcriptional regulator RcsB interacts with other coactivators to control the expression of biosynthetic operons in enterobacteria. While in a heterodimer complex with the regulator RcsA the RcsAB box consensus is recognized, DNA binding sites for RcsB without RcsA have also been identified. The conformation of RcsB might therefore be modulated upon interaction with various coactivators, resulting in the recognition of different DNA targets. We report the solution structure of the C-terminal DNA-binding domain of the RcsB protein from Erwinia amylovora spanning amino acid residues 129–215 solved by heteronuclear magnetic resonance (NMR) spectroscopy. The C-terminal domain is composed of four α-helices where two central helices form a helix-turn-helix motif similar to the structures of the regulatory proteins GerE, NarL, and TraR. Amino acid residues involved in the RcsA independent DNA binding of RcsB were identified by titration studies with a RcsAB box consensus fragment. Data obtained from NMR spectroscopy together with surface plasmon resonance measurements demonstrate that the RcsAB box is specifically recognized by the RcsAB heterodimer as well as by RcsB alone. However, the binding constant of RcsB alone at target promoters from Escherichia coli, E. amylovora, and Pantoea stewartii was approximately 1 order of magnitude higher compared with that of the RcsAB heterodimer. We present evidence that the obvious role of RcsA is not to alter the DNA binding specificity of RcsB but to stabilize RcsB-DNA complexes.

Regulation of Nuclear Lamin Polymerization by Importin α

Nuclear lamins are integral components of the nuclear envelope and are important for the regulation of many aspects of nuclear function, including gene transcription and DNA replication. During interphase, the lamins form an intranuclear intermediate filament network that must be disassembled and reassembled when cells divide. Little is known about factors regulating this assembly/disassembly cycle. Using in vitro nuclear assembly and lamin assembly assays, we have identified a role for the nuclear transport factor importin α in the regulation of lamin assembly. Exogenous importin α inhibited nuclear lamin assembly in Xenopus interphase egg nuclear assembly assays. Fractionation of the egg extract used for nuclear assembly identified a high molecular weight complex containing the major egg lamin, XLB3, importin α, and importin β. This complex could be dissociated by RanGTP or a competing nuclear localization sequence, indicating that lamin assembly is Ran- and importin α-dependent in the egg extract. We show that the addition of importin α to purified lamin B3 prevents the assembly of lamins in solution. Lamin assembly assays show that importin α prevents the self-association of lamins required to assemble lamin filaments into the typical paracrystals formed in vitro. These results suggest a role for importin α in regulating lamin assembly and possibly modulating the interactions of lamins with lamin-binding proteins.

Viscoelastic Behavior of Human Lamin A Proteins in the Context of Dilated Cardiomyopathy

Lamins are intermediate filament proteins of type V constituting a nuclear lamina or filamentous meshwork which lines the nucleoplasmic side of the inner nuclear membrane. This protein mesh provides a supporting scaffold for the nuclear envelope and tethers interphase chromosome to the nuclear periphery. Mutations of mainly A-type lamins are found to be causative for at least 11 human diseases collectively termed as laminopathies majority of which are characterised by aberrant nuclei with altered structural rigidity, deformability and poor mechanotransduction behaviour. But the investigation of viscoelastic behavior of lamin A continues to elude the field. In order to address this problem, we hereby present the very first report on viscoelastic properties of wild type human lamin A and some of its mutants linked with Dilated cardiomyopathy (DCM) using quantitative rheological measurements. We observed a dramatic strain-softening effect on lamin A network as an outcome of the strain amplitude sweep measurements which could arise from the large compliance of the quasi-cross-links in the network or that of the lamin A rods. In addition, the drastic stiffening of the differential elastic moduli on superposition of rotational and oscillatory shear stress reflect the increase in the stiffness of the laterally associated lamin A rods. These findings present a preliminary insight into distinct biomechanical properties of wild type lamin A protein and its mutants which in turn revealed interesting differences.

Structural Alterations of Lamin A Protein in Dilated Cardiomyopathy

Lamin A protein, encoded by the LMNA gene, belongs to the type V intermediate filament protein family and is a major nuclear protein component of higher metazoan organisms, including humans. Lamin A along with B-type lamins impart structural rigidity to the nucleus by forming a lamina that is closely apposed to the inner nuclear membrane and is also present as a filamentous network in the interior of the nucleus. A vast number of mutations that lead to a diverse array of at least 11 diseases in humans, collectively termed laminopathies, are being gradually uncovered in the LMNA gene. Dilated cardiomyopathy (DCM) is one such laminopathy in which ventricular dilation leads to an increase in systolic and diastolic volumes, resulting in cardiac arrhythmia and ultimately myocardial infarction. The point mutations in lamin A protein span the entire length of the protein, with a slight preponderance in the central α-helical coiled-coil forming domain. In this work, we have focused on three such important mutations that had been previously observed in DCM-afflicted patients producing severe symptoms. This is the first report to show that these mutations entail significant alterations in the secondary and tertiary structure of the protein, hence perturbing the intrinsic self-association behavior of lamin A protein. Comparison of the enthalpy changes accompanying the deoligomerization process for the wild type and the mutants suggests a difference in the energetics of their self-association. This is further corroborated by the formation of the aggregates of different size and distribution formed inside the nuclei of transfected cells.

Characterization of unfolding mechanism of human lamin A Ig fold by single-molecule force spectroscopy-implications in EDMD.

A- and B-type lamins are intermediate filament proteins constituting the nuclear lamina underneath the nuclear envelope thereby conferring proper shape and mechanical rigidity to the nucleus. Lamin proteins are also shown to be related diversely to basic nuclear processes. More than 400 mutations in human lamin A protein alone have been reported to produce at least 11 different disease conditions jointly termed as laminopathies. These mutations in lamin A are scattered throughout its helical rod domain, as well as the C-terminal domain containing the conserved Ig-fold region. The commonality of phenotypes in all these diseases is characterized by misshapen nuclei of the affected tissues which might stem from altered rigidity of the supporting lamina hence lamins. Here we have focused on autosomal dominant Emery-Dreifuss Muscular Dystrophy, one such laminopathy where R453W is the causative mutation located in the Ig domain of lamin A. We have investigated by single-molecule force spectroscopy how a stretching mechanical perturbation senses the destabilizing effect of the mutation in the lamin A Ig domain and compared the mechanoelastic properties of the mutant R453W with that of the wild-type in conjunction with steered molecular dynamics. Furthermore, we have shown the interaction of Ig domain with emerin, another key player and interacting partner in the pathogenesis of EDMD, is disrupted in the R453W mutant. This altered mechanoresistance of Ig domain itself and consequent uncoupling of lamin A-emerin interaction might underlie the altered mechanotransduction properties of EDMD affected nuclei.

Significance of 1B and 2B domains in modulating elastic properties of lamin A.

Nuclear lamins are type V intermediate filament proteins which form an elastic meshwork underlying the inner nuclear membrane. Lamins directly contribute to maintain the nuclear shape and elasticity. More than 400 mutations have been reported in lamin A that are involved in diseases known as laminopathies. These mutations are scattered mainly in the lamin rod domain along with some in its C-terminal domain. The contribution of the rod domain towards the elasticity of lamin A molecule was hitherto unknown. Here, we have elucidated the significance of the 1B and 2B domains of the rod in modulating the elastic behavior of lamin A by single-molecule force spectroscopy. In addition, we have also studied the network forming capacity of these domains and their corresponding viscoelastic behavior. We have shown that the 1B domain has the ability to form a lamin-like network and resists larger deformation. However at the single-molecular level, both the domains have comparable mechanical properties. The self-assembly of the 1B domain contributes to the elasticity of the lamin A network.

Hsp70 clears misfolded kinases that partitioned into distinct quality-control compartments

Hsp70 facilitates maturation of newly synthesized kinases and assists degradation of kinases under normal and stressed conditions. Hsp70 degrades misfolded kinases that partition into different quality-control compartments by promoting their ubiquitination, thus protecting cells from proteotoxic stress.

Differential role of nonmuscle myosin II isoforms during blebbing of MCF-7 cells

One molecular cue that regulates cellular protrusions such as blebbing and lamellipodia in tumor cells has been less explored than other environmental factors. NM II-A induces blebbing and NM II-C1 induces lamellipodia in tumor cells. NM-II isoforms can change the protrusive activity of a tumor cell.