Your search keyword '"Erdos, Michael"' showing total 7 results

1. Bone dysplasia in Hutchinson‐Gilford progeria syndrome is associated with dysregulated differentiation and function of bone cell populations.

Author

Cabral, Wayne A., Stephan, Chris, Terajima, Masahiko, Thaivalappil, Abhirami A., Blanchard, Owen, Tavarez, Urraca L., Narisu, Narisu, Yan, Tingfen, Wincovitch, Stephen M., Taga, Yuki, Yamauchi, Mitsuo, Kozloff, Kenneth M., Erdos, Michael R., and Collins, Francis S.

Subjects

PROGERIA, CELL populations, BONE cells, CELL physiology, DYSPLASIA, EXTRACELLULAR matrix

Abstract

Hutchinson‐Gilford progeria syndrome (HGPS) is a premature aging disorder affecting tissues of mesenchymal origin. Most individuals with HGPS harbor a de novo c.1824C > T (p.G608G) mutation in the gene encoding lamin A (LMNA), which activates a cryptic splice donor site resulting in production of the toxic "progerin" protein. Clinical manifestations include growth deficiency, lipodystrophy, sclerotic dermis, cardiovascular defects, and bone dysplasia. Here we utilized the LmnaG609G knock‐in (KI) mouse model of HGPS to further define mechanisms of bone loss associated with normal and premature aging disorders. Newborn skeletal staining of KI mice revealed altered rib cage shape and spinal curvature, and delayed calvarial mineralization with increased craniofacial and mandibular cartilage content. MicroCT analysis and mechanical testing of adult femurs indicated increased fragility associated with reduced bone mass, recapitulating the progressive bone deterioration that occurs in HGPS patients. We investigated mechanisms of bone loss in KI mice at the cellular level in bone cell populations. Formation of wild‐type and KI osteoclasts from marrow‐derived precursors was inhibited by KI osteoblast‐conditioned media in vitro, suggesting a secreted factor(s) responsible for decreased osteoclasts on KI trabecular surfaces in vivo. Cultured KI osteoblasts exhibited abnormal differentiation characterized by reduced deposition and mineralization of extracellular matrix with increased lipid accumulation compared to wild‐type, providing a mechanism for altered bone formation. Furthermore, quantitative analyses of KI transcripts confirmed upregulation of adipogenic genes both in vitro and in vivo. Thus, osteoblast phenotypic plasticity, inflammation and altered cellular cross‐talk contribute to abnormal bone formation in HGPS mice. [ABSTRACT FROM AUTHOR]

Published

2023

2. Genetic reduction of mTOR extends lifespan in a mouse model of Hutchinson‐Gilford Progeria syndrome.

Author

Cabral, Wayne A., Tavarez, Urraca L., Beeram, Indeevar, Yeritsyan, Diana, Boku, Yoseph D., Eckhaus, Michael A., Nazarian, Ara, Erdos, Michael R., and Collins, Francis S.

Subjects

PROGERIA, LABORATORY mice, CARDIOVASCULAR diseases, CARDIOVASCULAR system, ANIMAL disease models

Abstract

Hutchinson‐Gilford progeria syndrome (HGPS) is a rare accelerated aging disorder most notably characterized by cardiovascular disease and premature death from myocardial infarction or stroke. The majority of cases are caused by a de novo single nucleotide mutation in the LMNA gene that activates a cryptic splice donor site, resulting in production of a toxic form of lamin A with a 50 amino acid internal deletion, termed progerin. We previously reported the generation of a transgenic murine model of progeria carrying a human BAC harboring the common mutation, G608G, which in the single‐copy state develops features of HGPS that are limited to the vascular system. Here, we report the phenotype of mice bred to carry two copies of the BAC, which more completely recapitulate the phenotypic features of HGPS in skin, adipose, skeletal, and vascular tissues. We further show that genetic reduction of the mechanistic target of rapamycin (mTOR) significantly extends lifespan in these mice, providing a rationale for pharmacologic inhibition of the mTOR pathway in the treatment of HGPS. [ABSTRACT FROM AUTHOR]

Published

2021

3. Global genome splicing analysis reveals an increased number of alternatively spliced genes with aging.

Author

Rodríguez, Sofía A., Grochová, Diana, McKenna, Tomás, Borate, Bhavesh, Trivedi, Niraj S., Erdos, Michael R., and Eriksson, Maria

Subjects

GENETIC engineering, ADIPOSE tissues, SPLICEOSOMES, SKELETAL muscle, GENOMES, THYMUS

Abstract

Alternative splicing ( AS) is a key regulatory mechanism for the development of different tissues; however, not much is known about changes to alternative splicing during aging. Splicing events may become more frequent and widespread genome-wide as tissues age and the splicing machinery stringency decreases. Using skin, skeletal muscle, bone, thymus, and white adipose tissue from wild-type C57 BL6/J male mice (4 and 18 months old), we examined the effect of age on splicing by AS analysis of the differential exon usage of the genome. The results identified a considerable number of AS genes in skeletal muscle, thymus, bone, and white adipose tissue between the different age groups (ranging from 27 to 246 AS genes corresponding to 0.3-3.2% of the total number of genes analyzed). For skin, skeletal muscle, and bone, we included a later age group (28 months old) that showed that the number of alternatively spliced genes increased with age in all three tissues ( P < 0.01). Analysis of alternatively spliced genes across all tissues by gene ontology and pathway analysis identified 158 genes involved in RNA processing. Additional analysis of AS in a mouse model for the premature aging disease Hutchinson-Gilford progeria syndrome was performed. The results show that expression of the mutant protein, progerin, is associated with an impaired developmental splicing. As progerin accumulates, the number of genes with AS increases compared to in wild-type skin. Our results indicate the existence of a mechanism for increased AS during aging in several tissues, emphasizing that AS has a more important role in the aging process than previously known. [ABSTRACT FROM AUTHOR]

Published

2016

4. Loss of lamin B1 results in prolongation of S phase and decondensation of chromosome territories.

Author

Camps, Jordi, Wangsa, Darawalee, Falke, Martin, Brown, Markus, Case, Chanelle M., Erdos, Michael R., and Ried, Thomas

Subjects

CYTOSKELETAL proteins, RNA interference, COLON cancer, CANCER cells, GENETIC engineering research

Abstract

Nuclear lamin B1 (LMNB1) constitutes one of the major structural proteins in the lamina mesh. We silenced the expression of LMNB1 by RNA interference in the colon cancer cell line DLD-1 and showed a dramatic redistribution of H3K27me3 from the periphery to a more homogeneous nuclear dispersion. In addition, we observed telomere attrition and an increased frequency of micronuclei and nuclear blebs. By 3D-FISH analyses, we demonstrated that the volume and surface of chromosome territories were significantly larger in LMNB1-depleted cells, suggesting that LMNB1 is required to maintain chromatin condensation in interphase nuclei. These changes led to a prolonged S phase due to activation of Chk1. Finally, silencing of LMNB1 resulted in extensive changes in alternative splicing of multiple genes and in a higher number of enlarged nuclear speckles. Taken together, our results suggest a mechanistic role of the nuclear lamina in the organization of chromosome territories, maintenance of genome integrity and proper gene splicing. [ABSTRACT FROM AUTHOR]

Published

2014

5. Human longevity and common variations in the LMNA gene: a meta-analysis.

Author

Conneely, Karen N., Capell, Brian C., Erdos, Michael R., Sebastiani, Paola, Solovieff, Nadia, Swift, Amy J., Baldwin, Clinton T., Budagov, Temuri, Barzilai, Nir, Atzmon, Gil, Puca, Annibale A., Perls, Thomas T., Geesaman, Bard J., Boehnke, Michael, and Collins, Francis S.

Subjects

PROGERIA, HUMAN genetic variation, GENETIC mutation, CELL physiology, CELLULAR aging, GENETIC regulation, META-analysis, THERAPEUTICS

Abstract

A mutation in the LMNA gene is responsible for the most dramatic form of premature aging, Hutchinson-Gilford progeria syndrome (HGPS). Several recent studies have suggested that protein products of this gene might have a role in normal physiological cellular senescence. To explore further LMNA's possible role in normal aging, we genotyped 16 SNPs over a span of 75.4 kb of the LMNA gene on a sample of long-lived individuals (LLI) (US Caucasians with age ≥ 95 years, N = 873) and genetically matched younger controls ( N = 443). We tested all common nonredundant haplotypes (frequency ≥ 0.05) based on subgroups of these 16 SNPs for association with longevity. The most significant haplotype, based on four SNPs, remained significant after adjustment for multiple testing (OR = 1.56, P = 2.5 × 10−5, multiple-testing-adjusted P = 0.0045). To attempt to replicate these results, we genotyped 3619 subjects from four independent samples of LLI and control subjects from (i) the New England Centenarian Study (NECS) ( N = 738), (ii) the Southern Italian Centenarian Study (SICS) ( N = 905), (iii) France ( N = 1103), and (iv) the Einstein Ashkenazi Longevity Study ( N = 702). We replicated the association with the most significant haplotype from our initial analysis in the NECS sample (OR = 1.60, P = 0.0023), but not in the other three samples ( P > 0.15). In a meta-analysis combining all five samples, the best haplotype remained significantly associated with longevity after adjustment for multiple testing in the initial and follow-up samples (OR = 1.18, P = 7.5 × 10−4, multiple-testing-adjusted P = 0.037). These results suggest that LMNA variants may play a role in human lifespan. [ABSTRACT FROM AUTHOR]

Published

2012

6. Angiopoietin‐2 reverses endothelial cell dysfunction in progeria vasculature.

Author

Vakili, Sahar, Izydore, Elizabeth K., Losert, Leonhard, Cabral, Wayne A., Tavarez, Urraca L., Shores, Kevin, Xue, Huijing, Erdos, Michael R., Truskey, George A., Collins, Francis S., and Cao, Kan

Abstract

bstract Hutchinson‐Gilford progeria syndrome (HGPS) is a rare premature aging disorder in children caused by a point mutation in the lamin A gene, resulting in a toxic form of lamin A called progerin. Accelerated atherosclerosis leading to heart attack and stroke are the major causes of death in these patients. Endothelial cell (EC) dysfunction contributes to the pathogenesis of HGPS related cardiovascular diseases (CVD). Endothelial cell–cell communications are important in the development of the vasculature, and their disruptions contribute to cardiovascular pathology. However, it is unclear how progerin interferes with such communications that lead to vascular dysfunction. An antibody array screening of healthy and HGPS patient EC secretomes identified Angiopoietin‐2 (Ang2) as a down‐regulated signaling molecule in HGPS ECs. A similar down‐regulation of Ang2 mRNA and protein was detected in the aortas from an HGPS mouse model. Addition of Ang2 to HGPS ECs rescues vasculogenesis, normalizes endothelial cell migration and gene expression, and restores nitric oxide bioavailability through eNOS activation. Furthermore, Ang2 addition reverses unfavorable paracrine effects of HGPS ECs on vascular smooth muscle cells. Lastly, by utilizing adenine base editor (ABE)‐corrected HGPS ECs and progerin‐expressing HUVECs, we demonstrated a negative correlation between progerin and Ang2 expression. Lastly, our results indicated that Ang2 exerts its beneficial effect in ECs through Tie2 receptor binding, activating an Akt‐mediated pathway. Together, these results provide molecular insights into EC dysfunction in HGPS and suggest that Ang2 treatment has potential therapeutic effects in HGPS‐related CVD. [ABSTRACT FROM AUTHOR]

Published

2024

7. Analysis of somatic mutations identifies signs of selection during in vitro aging of primary dermal fibroblasts.

Author

Narisu, Narisu, Rothwell, Rebecca, Vrtačnik, Peter, Rodríguez, Sofía, Didion, John, Zöllner, Sebastian, Erdos, Michael R., Collins, Francis S., and Eriksson, Maria

Subjects

SOMATIC mutation, PROGERIA, CELLULAR aging, GENETIC drift, XERODERMA pigmentosum, CANCER treatment

Abstract

Somatic mutations are critical for cancer development and may play a role in age‐related functional decline. Here, we used deep sequencing to analyze the prevalence of somatic mutations during in vitro cell aging. Primary dermal fibroblasts from healthy subjects of young and advanced age, from Hutchinson–Gilford progeria syndrome and from xeroderma pigmentosum complementation groups A and C, were first restricted in number and then expanded in vitro. DNA was obtained from cells pre‐ and post‐expansion and sequenced at high depth (1656× mean coverage), over a cumulative 290 kb target region, including the exons of 44 aging‐related genes. Allele frequencies of 58 somatic mutations differed between the pre‐ and post‐cell culture expansion passages. Mathematical modeling revealed that the frequency change of three of the 58 mutations was unlikely to be explained by genetic drift alone, indicative of positive selection. Two of these three mutations, CDKN2A c.53C>T (T18M) and ERCC8 c.*772T>A, were identified in cells from a patient with XPA. The allele frequency of the CDKN2A mutation increased from 0% to 55.3% with increasing cell culture passage. The third mutation, BRCA2 c.6222C>T (H2074H), was identified in a sample from a healthy individual of advanced age. However, further validation of the three mutations suggests that other unmeasured variants probably provide the selective advantage in these cells. Our results reinforce the notions that somatic mutations occur during aging and that some are under positive selection, supporting the model of increased tissue heterogeneity with increased age. [ABSTRACT FROM AUTHOR]

Published

2019