Sense of place among children of an isolated island community

Sweeney, Rena.

10 April 2008

No description available.

Insights Into the Function of Prenylation From Nuclear Lamin Farnesylation

Sinensky, Michael

01 January 2011

The discovery of mammalian protein prenylation was originally motivated by an effort to identify a nonsterol isoprenoid which indirect evidence suggested was a coregulator of isoprenoid biosynthesis and played a critical role in cellular proliferation. The first prenylated proteins to be identified were the nuclear lamin proteins-B lamins and prelamin A-which were subsequently shown to be farnesylated at a carboxyl-terminal CAAX motif. In both types of lamin, the farnesylation and carboxymethylation play a role in targeting these proteins to the nuclear envelope. The nucleus can be demonstrated to be a CAAX processing compartment for the lamins. In the case of prelamin A, there is removal of a carboxyl-terminal polypeptide which is specifically catalyzed by the enzyme Zmpste24. This processing event is necessary for assembly of lamin A into the lamina and may play a role in cell cycle control. Because the nucleus contains only one target membrane, lamin farnesylation and carboxymethylation may be sufficient to allow association with this membrane. This stands in contrast to farnesylated proteins expressed in the cytoplasm.

farnesylation

Hutchinson-Gilford progeria syndrome

nucleus

prelamin A

retinoblastoma protein and endoprotease

Alternative splicing of LMNA gene : lessons from a new mouse model of Hutchinson-Gilfort progeria syndrome / L’épissage alternatif du gène LMNA : leçons d’un nouveau modèle de souris qui reproduit le syndrome progéroïde de Hutchinson-Gilford

Lopez Mejia, Isabel Cristina

05 September 2011

Le vieillissement est un processus complexe qui peut être influencé par des facteurs environnementaux et génétiques. Le syndrome progéroïde de Hutchinson-Gilford (HGPS ou progéria) fourni une preuve irréfutable de l'implication de l'épissage dans le processus de vieillissement. La progéria est une maladie due à une mutation hétérozygote silencieuse qui renforce l'utilisation d'un site 5' d'épissage interne dans l'exon 11 de l'ARN pré-messager LMNA, ce qui entraîne la production d'une protéine tronquée appelée «progérine». Le défaut d'épissage du gène LMNA a aussi lieu dans les cellules de personnes âgées, et la correction de ce défaut permet un sauvetage partiel des anomalies qu'il provoque. Ceci fait de l'ARN pré-messager LMNA une cible très attractive pour des thérapies ayant pour but de corriger l'épissage. Mes travaux de thèse ont montré que cette mutation silencieuse active un site d'épissage 5' dans l'exon 11 en changeant la structure de l'ARN. Ce changement de structure facilite l'interaction de la snRNP U1 avec le site d'épissage et permet ainsi sa modulation par les protéines SR SRSF1 et SRSF6. J'ai aussi participé à la caractérisation d'un nouveau modèle murin qui reproduit l'altération d'épissage des patients HGPS au niveau du gène Lmna souris. De façon surprenante, ce modèle récapitule tous les phénotypes du syndrome HGPS. Les souris homozygotes, dans lesquelles la plupart de la lamine A est convertie en progérine, ne vivent pas plus de 5 mois, alors que les souris hétérozygotes vivent autour d'un an et que les contrôles sauvages vivent deux ans. Étonnamment, des souris qui n'expriment ni la lamine A ni la progérine, mais uniquement de la lamine C, vivent plus longtemps que les souris contrôle, suggérant que la lamine A et la progérine, qui sont produites à partir du même transcrit, participent à la régulation de la durée de la vie. De plus, la caractérisation initiale des souris HGPS indique que l'expression de la progérine est délétère pour le tissu adipeux, établissant ainsi un lien inattendu entre l'épuisement du tissu adipeux et le vieillissement accéléré. Ce nouveau modèle murin est actuellement en train d'être utilisé pour des approches de modulation de l'épissage aberrant du gène LMNA avec des oligonucléotides antisense et des petites molécules chimiques. / Aging is a complex cellular and organismal process that can be influenced by environmental as well as genetic factors. A striking proof-of-concept that splicing regulation plays an important role in the aging process is provided by Hutchinson-Gilford progeria syndrome (HGPS), a disease caused by a heterozygous silent mutation that enhances the use of an internal 5' splice site in exon 11 of LMNA pre-mRNA and leads to the production of a truncated protein called “progerin”. The LMNA splicing defect also occurs with increased frequency in cells from healthy aged individuals and correction of this defect leads to partial reversal of age-related dysfunction. This makes LMNA pre-mRNA an attractive target for splicing-correction therapies. During my PhD thesis I have characterized the splicing mechanism responsible for progerin production and demonstrated that this process is conserved from mouse to human. I have found that HGPS mutation changes the accessibility of the exon 11 internal 5' splice site, allowing its modulation by U1 snRNP and a subset of SR proteins, namely SRSF6 and SRSF1. I have also participated to the characterization of a new mouse model reproducing human HGPS splicing alteration in the mouse Lmna gene. Strikingly, this model recapitulates all phenotypic manifestations of HGPS. The homozygous mice, where most lamin A is converted to progerin, lived no longer than 5 months, whereas heterozygous mice lived in average one year and wild type littermates up to two years. Unexpectedly, mice expressing neither lamin A nor progerin, but only lamin C, lived longer than wild type littermates mice, suggesting that lamin A and progerin which are produced from the same transcript, control critical steps of lifespan. Furthermore, initial characterization of HGPS mouse model indicated that progerin expression is deleterious for adipose tissue, establishing an unexpected link between adipose tissue depletion and accelerated aging. The new mouse model is currently being used for pharmacological modulation of LMNA aberrant splicing by antisense oligonucleotides and small molecules.

Epissage alternatif

Proteines SR

Vieillissement

Lmna

Alternative splicing

SR proteins

Hutchinson-Gilford Progeria Syndrome

Aging

Lmna

The role of lamin A and emerin in mediating genome organisation

Godwin, Lauren Sarah

January 2010

The nuclear matrix (NM) is proposed to be a permanent network of core filaments underlying thicker fibres, present regardless of transcriptional activity. It is found to be both RNA and protein rich; indeed, numerous important nuclear proteins are components of the structure. In addition to mediating the organisation of entire chromosomes, the NM has also been demonstrated to tether telomeres via their TTAGGG repeats. In order to examine telomeric interactions with the NM, a technique known as the DNA halo preparation has been employed. Regions of DNA that are tightly attached to the structure are found within a so-called residual nucleus, while those sequences forming lesser associations produce a halo of DNA. Coupled with various FISH methodologies, this technique allowed the anchorage of genomic regions by the NM, to be analysed. In normal fibroblasts, the majority of chromosomes and telomeres were extensively anchored to the NM. Such interactions did not vary significantly in proliferating and senescent nuclei. However, a decrease in NM-associated telomeres was detected in quiescence. Since lamin A is an integral component of the NM, it seemed pertinent to examine chromosome and telomere NM-anchorage in Hutchinson-Gilford Progeria Syndrome (HGPS) fibroblasts, which contain mutant forms of lamin A. Indeed, genome tethering by the NM was perturbed in HGPS. In immortalised HGPS fibroblasts, this disrupted anchorage appeared to be rescued; the implications of this finding will be discussed. This study also suggested that telomere-NM interactions are aberrant in X-linked Emery-Dreifuss Muscular Dystrophy (X-EDMD), which is caused by mutant forms of emerin, another NM-associated protein. The positioning of selected genes in control and X-EDMD cell lines was examined in un-extracted nuclei using 2D and 3D FISH. Subtle shifts in the organisation of these genes were detected in diseased cells; however, their expression levels remained unaltered. Furthermore, in order to examine the architectural integrity of the nuclear lamina in lamin A and emerin mutant cell lines, scanning electron microscopy (SEM) was employed. This work revealed that such structures were indeed compromised in disease. The findings presented in this thesis highlight the importance of lamin A and emerin in mediating the organisation of the genome and taken together, promote the hypothesis that dysfunctional NM dynamics may well contribute to disease pathology.

610

Building A Tensegrity-Based Computational Model to Understand Endothelial Alignment Under Flow

Tamara Habes Al Muhtaseb (11535130)

29 November 2021

Endothelial cells form the lining of the walls of blood vessels and are continuously subjected to mechanical stimuli from the blood flow. Microtubule-organizing center (MTOC),<br>also known as centrosome is a structure found in eukaryotic cells close to the nucleus. MTOC relocates relative to the nucleus when endothelial cells are exposed to shear stress which determines their polarization, thus it plays a critical role in cell migration and wound healing. The nuclear lamina, a mesh-like network that lies underneath the nuclear membrane, is composed of lamins, type V intermediate filament proteins. Mutations in LMNA gene that encodes A-type lamins cause the production of a mutant form of lamin A called progerin and leads to a rare premature aging disease known as Hutchinson-Gilford Progeria Syndrome<br><div>(HGPS). The goal of this study is to investigate how fluid flow affects the cytoskeleton of endothelial cells.</div><div><br></div>This thesis consists of two main sections; computational mechanical modeling and laboratory experimental work. The mechanical model was implemented using Ansys Workbench software as a tensegrity-based cellular model in order to simulate the state of an endothelial cell under the effects of induced shear stress from the blood fluid flow. This tensegrity-based cellular model - composed of a plasma membrane, cytoplasm, nucleus, microtubules, and<br><div>actin filaments - aims to understand the effects of the fluid flow on the mechanics of the cytoskeleton. In addition, the laboratory experiments conducted in this study examined the MTOC-nuclear orientation of endothelial cells under shear stress with the presence of wound healing. Wild-type lamin A and progerin-expressing BAECs were studied under static and sheared conditions.</div><div><br></div><div> Moreover, a custom MATLAB code was utilized to measure the MTOC-nuclear orientation</div>angle and classification. Results demonstrate that shear stress leads to different responses of the MTOC orientation between the wild-type and progerin-expressing cells around the vertical wound edge. Future directions for this study involve additional experimental work together with the improved simulation results to confirm the MTOC orientation<br>relative to the nucleus under shear stress.

Hutchinson-Gilford Progeria Syndrome

Tensegrity structure

Computational Modeling

shear stress

Involvement of Xeroderma Pigmentosum Group A (XPA) in Progeria Arising From Defective Maturation of Prelamin A

Liu, Yiyong, Wang, Youjie, Rusinol, Antonio E., Sinensky, Michael S., Liu, Ji, Shell, Steven M., Zou, Yue

01 February 2008

Cellular accumulation of DNA damage has been widely implicated in cellular senescence, aging, and premature aging. In Hutchinson-Gilford progeria syndrome (HGPS) and restrictive dermopathy (RD), premature aging is linked to accumulation of DNA double-strand breaks (DSBs), which results in genome instability. However, how DSBs accumulate in cells despite the presence of intact DNA repair proteins remains unknown. Here we report that the recruitment of DSB repair factors Rad50 and Rad51 to the DSB sites, as marked by γ-H2AX, was impaired in human HGPS and Zmpste24-deficient cells. Consistently, the progeria-associated DSBs appeared to be unrepairable although DSBs induced by camptothecin were efficiently removed in the progeroid cells. We also found that these progeroid cells exhibited nuclear foci of xeroderma pigmentosum group A (XPA), a unique nucleotide excision repair protein. Strikingly, these XPA foci colocalized with the DSB sites in the progeroid cells. This XPA-DSB association was further confirmed and found to be mediated by DNA, using a modified chromatin immunoprecipitation assay and coimmunoprecipitation. RNA interference (RNAi) knockdown of XPA in HGPS cells partially restored DSB repair as evidenced by Western blot analysis, immunofluorescence and comet assays. We propose that the uncharacteristic localization of XPA to or near DSBs inhibits DSB repair, thereby contributing to the premature aging phenotypes observed in progeria arising from genetic defects in prelamin A maturation.

DNA damage

DNA double strand breaks and repair

Hutchinson-Gilford progeria syndrome

lamin A

zmpste24

Biomedical Sciences

A Finite Element Model for Investigation of Nuclear Stresses in Arterial Endothelial Cells

Rumberger, Charles B.

12 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Cellular structural mechanics play a key role in homeostasis by transducing mechanical signals to regulate gene expression and by providing adaptive structural stability for the cell. The alteration of nuclear mechanics in various laminopathies and in natural aging can damage these key functions. Arterial endothelial cells appear to be especially vulnerable due to the importance of shear force mechanotransduction to structure and gene regulation as is made evident by the prominent role of atherosclerosis in Hutchinson-Gilford progeria syndrome (HGPS) and in natural aging. Computational models of cellular mechanics may provide a useful tool for exploring the structural hypothesis of laminopathy at the intracellular level. This thesis explores this topic by introducing the biological background of cellular mechanics and lamin proteins in arterial endothelial cells, investigating disease states related to aberrant lamin proteins, and exploring computational models of the cell structure. It then presents a finite element model designed specifically for investigation of nuclear shear forces in arterial endothelial cells. Model results demonstrate that changes in nuclear material properties consistent with those observed in progerin-expressing cells may result in substantial increases in stress concentrations on the nuclear membrane. This supports the hypothesis that progerin disrupts homeostatic regulation of gene expression in response to hemodynamic shear by altering the mechanical properties of the nucleus.

finite element modelling

laminopathy

Hutchinson-Gilford progeria syndrome

nuclear stresses

endothelial cell

ANSYS

Python

cellular mechanotransduction

Recherche des mécanismes impliqués dans les dérégulations de l'épissage alternatif à l'origine de la progéria et étude du rôle de l'étape d'épissage dans les changements globaux d'expression des gènes en réaction au choc thermique / Search of the mechanisms involved in alternative splicing misregulations resulting in progeria and study of the role of the splicing step in global changes of gene expression in response to thermic stress

Vautrot, Valentin

12 December 2013

Le syndrome de Hutchinson-Gilford, ou progéria, est une pathologie génétique rare qui se caractérise par des symptômes assimilés à un vieillissement prématuré. Les mutations à l'origine de la progéria affectent le gène LMNA, codant la lamine A, qui joue un rôle majeur dans la formation, la maintenance et la résistance du noyau. Ces mutations activent l'utilisation de sites 5' alternatif ou cryptique d'épissage présents dans l'exon 11 du pré-ARNm LMNA en amont du site normalement utilisé. Nous avons révélé un effet des mutations sur la structure secondaire de l'ARN aux alentours des mutations, qui permet l'augmentation de l'utilisation des sites d'épissage mutants. De plus, nous avons montré l'implication de plusieurs protéines SR (SRSF1, SRSF5 et SRSF6) dans la régulation de l'utilisation des différents sites d'épissage. D'autre part, il a déjà été observé que les noyaux des cellules des patients atteints de progéria contiennent des granules de stress, les nSB, situés dans les régions péricentromériques des chromosomes et contenant des ARN dits satellite III et des facteurs d'épissage. Des nSB similaires sont formés dans les cellules saines suite à divers stress, comme le stress thermique. Il est possible que ces nSB séquestrent ces facteurs d'épissage afin de réguler le profil d'épissage alternatif des cellules pendant la régénération après un stress. Nous avons purifié les protéines associées aux ARN satellite III in vitro afin de trouver de nouveaux composants des nSB et analysé, par emploi de puces jonction-exon, le transcriptome de cellules soumises à un choc thermique, pour mieux comprendre à terme comment la formation des nSB peut affecter l'épissage alternatif / The Hutchinson-Gilford syndrome, also called progeria, is a rare genetic disease, characterized by symptoms that can be assimilated to accelerated natural ageing. Mutations that cause progeria affect the LMNA gene, which codes the lamin A that plays a major role in the shaping, maintenance and resistance of the nucleus. These mutations lead to the activation of alternative or cryptic 5' splice sites located within the exon 11 of LMNA pre-mRNA upstream from the normal 5' splice site. Our work revealed an effect of the mutations on the 2D RNA structure of the splice sites, which contributes to the increased use of the mutant sites. On top of it, we showed the impact of several SR proteins, (SRSF1, SRSF5 and SRSF6) on the regulation of the use of the exon 11 5' splice sites. On the other hand, it was previously observed that cells from progeria patients contain nuclear stress bodies (nSB), located in chromosomal pericentromeric regions and containing satellite III RNAs and several splicing regulatory proteins. Similar bodies are formed in healthy cells submitted to various stresses such as heat shock. A work hypothesis is that those nSBs sequester splicing factors in order to regulate the global alternative splicing profile in cells during the recovery period after stress. We purified proteins associated with satellite III RNAs in vitro, to find new components of the nSBs, and analyzed the transcriptome of cells subjected to heat shock using exon junction microarrays, in order to eventually understand how nSB formation can affect alternative splicing

Syndrome de Hutchinson-Gilford

Progéria

Lamine A

Épissage alternatif

Granules de stress nucléaires

Choc thermique

Micropuces "exon-junction"

ARN satellite III

Hutchinson-Gilford Progeria Syndrome

Lamin A

Alternative splicing

Nuclear stress bodies

Heat shock

Exon junction microarray

Satellite III RNA

616.042

572.88

Hallermann-Streiff Syndrome: No Evidence for a Link to Laminopathies

Kortüm, F., Chyrek, M., Fuchs, S., Albrecht, B., Gillessen-Kaesbach, G., Mütze, U., Seemanova, E., Tinschert, S., Wieczorek, D., Rosenberger, G., Kutsche, K.

04 August 2020

Hallermann-Streiff syndrome (HSS) is a rare inherited disorder characterized by malformations of the cranium and facial bones, congenital cataracts, microphthalmia, skin atrophy, hypotrichosis, proportionate short stature, teeth abnormalities, and a typical facial appearance with prominent forehead, small pointed nose, and micrognathia. The genetic cause of this developmental disorder is presently unknown. Here we describe 8 new patients with a phenotype of HSS. Individuals with HSS present with clinical features overlapping with some progeroid syndromes that belong to the laminopathies, such as Hutchinson-Gilford progeria syndrome (HGPS) and mandibuloacral dysplasia (MAD). HGPS is caused by de novo point mutations in the LMNA gene, coding for the nuclear lamina proteins lamin A and C. MAD with type A and B lipodystrophy are recessive disorders resulting from mutations in LMNA and ZMPSTE24 , respectively. ZMPSTE24 in addition to ICMT encode proteins involved in posttranslational processing of lamin A. We hypothesized that HSS is an allelic disorder to HGPS and MAD. As the nuclear shape is often irregular in patients with LMNA mutations, we first analyzed the nuclear morphology in skin fibroblasts of patients with HSS, but could not identify any abnormality. Sequencing of the genes LMNA, ZMPSTE24 and ICMT in the 8 patients with HSS revealed the heterozygous missense mutation c.1930C>T (p.R644C) in LMNA in 1 female. Extreme phenotypic diversity and low penetrance have been associated with the p.R644C mutation. In ZMPSTE24 and ICMT , no pathogenic sequence change was detected in patients with HSS. Together, we found no evidence that HSS is another laminopathy.

info:eu-repo/classification/ddc/610

ddc:610

info:eu-repo/classification/ddc/570

ddc:570

Estudo genético-clínico de pacientes com síndromes progeróides / Genetic and clinical study of patients with progerioid syndromes

Lazzaro Filho, Ricardo Di

10 October 2017

Algumas síndromes genéticas monogênicas apresentam fenótipos considerados progeróides, ou seja, desenvolvem precocemente características clínicas semelhantes às observadas no envelhecimento humano normal. A relação fisiopatológica entre essas doenças e o processo de envelhecimento vem sendo estudada, sendo que o entendimento dos mecanismos moleculares em um campo contribui para a compreensão do outro. As síndromes de Hutchinson-Gilford e Rothmund-Thomson são duas condições progeróides raras, já bem caracterizadas clinicamente, que são causadas por alterações nos genes LMNA (em um alelo) e RECQL4 (nos dois alelos), respectivamente. No entanto, em cerca de 40% a 60% dos indivíduos com a síndrome de Rothmund-Thomson, não são encontradas mutações em RECQL4, constituindo um subgrupo chamado de tipo I; desse modo, os casos com alteração no gene constituem o tipo II da síndrome. Indivíduos com o tipo II apresentam um risco aumentado para o desenvolvimento de câncer, particularmente o osteossarcoma. Neste trabalho, nove pacientes com sinais progeróides foram avaliados clinicamente e tiveram o DNA sequenciado. Um paciente recebeu o diagnóstico clínico de síndrome de Hutchinson-Gilford, que foi confirmado pela mutação patogênica mais frequente encontrada no gene LMNA (p.Gly608Gly). Oito pacientes jovens, com mediana de idade de 2 anos e 2 meses, foram diagnosticados clinicamente como afetados pela síndrome de Rothmund-Thomson, cujas características clínicas mais comuns incluíam déficit pôndero-estatural, cabelos e sobrancelhas/cílios esparsos, fronte ampla, lesão cutânea (eritema em face e lesão poiquilodérmica) e anomalias ósseas, alterações típicas da síndrome. Catarata estava presente em 50% dos indivíduos. Nenhum dos pacientes desenvolveu algum tipo de tumor até o momento. O sequenciamento do gene RECQL4 mostrou a presença de três variantes patogênicas diferentes, em três probandos (37,5%), sendo dois em homozigose e um em heterozigose composta, todas já descritas previamente na literatura. Em busca de alterações em outro gene que pudesse explicar o quadro apresentado pelos pacientes sem mutação, três dos probandos, incluindo os genitores de um deles, tiveram o exoma sequenciado. No entanto, não foram encontradas, nessa etapa, variantes adicionais que explicassem na totalidade os fenótipos apresentados. Comparando os achados clínicos dos pacientes com a síndrome de Rothmund-Thomson tipo I e tipo II, foi observada diferença estatisticamente significante na incidência de catarata subcapsular nos pacientes sem mutação (p<0,05), semelhante ao que é descrito na literatura. Diante dos achados clínicos e moleculares obtidos, foi realizado o aconselhamento genético para todos os indivíduos, enfatizando a evolução, os cuidados e acompanhamentos necessários para as duas doenças em questão e fornecendo informações aos genitores dos probandos sobre o risco de recorrência para a prole futura / Some monogenic disorders exhibit progeroid phenotypes, in other words, they develop premature characteristics similar to those observed in normal human aging. The physiopathological correlation between these diseases and the aging process has being studied, and the understanding of the molecular mechanisms in one field contributes to the understanding of the other. The Hutchinson-Gilford and Rothmund-Thomson syndromes are two clinically well-characterized rare progerioid conditions that are caused by changes in the LMNA (in one allele) and RECQL4 (in both alleles) genes, respectively. However, in about 40% to 60% of individuals with Rothmund-Thomson syndrome, no mutations are found in RECQL4, constituting a subgroup called type I; thus, cases with mutations in the gene constitute the type II group of the syndrome. Individuals with type II have an increased risk for the development of cancer, particularly osteosarcoma. In this study, nine patients with progerioid signs were clinically evaluated and had the DNA sequenced. One patient was clinically diagnosed with Hutchinson-Gilford syndrome, which was confirmed by the most frequent pathogenic mutation found in the LMNA gene (p.Gly608Gly). Eight young patients with median age of 2 years and 2 months were clinically diagnosed as affected by Rothmund-Thomson syndrome, whose most common clinical features included: short stature; sparse hair, eyebrows and eyelashes; erythematous skin lesions and poikiloderma; and bone abnormalities; all typical of the syndrome. Cataract was present in 50% of individuals. None of the patients has developed any type of tumor at this time. Sequencing of the RECQL4 gene showed the presence of three different pathogenic variants in three probands (37.5%), two in homozygous and one in compound heterozygosity, all previously described in the literature. In search of alterations in another gene that could explain the phenotype presented by the patients without mutation, three of the probands, including the parents of one of them, had the exoma sequenced. However, there were no additional variants at this stage that fully explained the phenotypes presented by these individuals. Comparing the clinical findings of patients with Rothmund-Thomson syndrome type I and type II, a statistically significant difference was observed in the incidence of subcapsular cataract in patients without mutation (p <0.05), similar to that described in the literature. In light of the clinical and molecular findings, genetic counseling was performed for all individuals, emphasizing the evolution, care and follow-up needed for the two diseases in question and providing information to the parents of the probands on the risk of recurrence for future offspring

Aconselhamento genético

Genetic counseling

Hutchinson-Gilford syndrome

Progeroid

Progeroide

Rothmund-Thomson syndrome

Síndrome de Hutchinson-Gliford

Síndrome de Rothmund-Thomson