Inés Rauschert scite author profile

Nuclear lamins support the nuclear envelope and provide anchorage sites for chromatin. They are involved in DNA synthesis, transcription, and replication. It has previously been reported that the lack of Lamin A/C expression in lymphoma and leukaemia is due to CpG island promoter hypermethylation. Here, we provide evidence that Lamin A/C is silenced via this mechanism in a subset of neuroblastoma cells. Moreover, Lamin A/C expression can be restored with a demethylating agent. Importantly, Lamin A/C reintroduction reduced cell growth kinetics and impaired migration, invasion, and anchorage-independent cell growth. Cytoskeletal restructuring was also induced. In addition, the introduction of lamin Δ50, known as Progerin, caused senescence in these neuroblastoma cells. These cells were stiffer and developed a cytoskeletal structure that differed from that observed upon Lamin A/C introduction. Of relevance, short hairpin RNA Lamin A/C depletion in unmethylated neuroblastoma cells enhanced the aforementioned tumour properties. A cytoskeletal structure similar to that observed in methylated cells was induced. Furthermore, atomic force microscopy revealed that Lamin A/C knockdown decreased cellular stiffness in the lamellar region. Finally, the bioinformatic analysis of a set of methylation arrays of neuroblastoma primary tumours showed that a group of patients (around 3%) gives a methylation signal in some of the CpG sites located within the Lamin A/C promoter region analysed by bisulphite sequencing PCR. These findings highlight the importance of Lamin A/C epigenetic inactivation for a subset of neuroblastomas, leading to enhanced tumour properties and cytoskeletal changes. Additionally, these findings may have treatment implications because tumour cells lacking Lamin A/C exhibit more aggressive behaviour.

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Hyperglycemia and hyperlipidemia can induce morphophysiological changes in rat cardiac cell line

Varela

Rauschert

Romanelli

et al. 2021

Biochemistry and Biophysics Reports

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H9c2 cardiac cells were incubated under the control condition and at different hyperglycemic and hyperlipidemic media, and the following parameters were determined and quantified: a) cell death, b) type of cell death, and c) changes in cell length, width and height. Of all the proven media, the one that showed the greatest differences compared to the control was the medium glucose (G) 33 mM + 500 μM palmitic acid. This condition was called the hyperglycemic and hyperlipidemic condition (HHC). Incubation of H9c2 cells in HHC promoted 5.2 times greater total cell death when compared to the control. Of the total death ofthe HHC cells, 38.6% was late apoptotic and 8.3% early apoptotic. HHC also changes cell morphology. The reordering of the actin cytoskeleton and cell stiffness was also studied in control and HHC cells. The actin cytoskeleton was quantified and the number and distance of actin bundles were not the same in the control as under HHC. Young's modulus images show a map of cell stiffness. Cells incubated in HHC with the reordered actin cytoskeleton were stiffer than those incubated in control. The region of greatest stiffness was the peripheral zone of HHC cells (where the number of actin bundles was higher and the distance between them smaller). Our results suggest a correlation between the reordering of the actin cytoskeleton and cell stiffness. Thus, our study showed that HHC can promote morphophysiological changes in rat cardiac cells confirming that gluco-and lipotoxicity may play a central role in the development of diabetic cardiomyopathy.

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The Arabidopsis TETRATRICOPEPTIDE THIOREDOXIN-LIKE 1 Gene Is Involved in Anisotropic Root Growth during Osmotic Stress Adaptation

Cuadrado-Pedetti¹,

Rauschert

Sainz³

et al. 2021

Genes

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Mutations in the Arabidopsis TETRATRICOPEPTIDE THIOREDOXIN-LIKE 1 (TTL1) gene cause reduced tolerance to osmotic stress evidenced by an arrest in root growth and root swelling, which makes it an interesting model to explore how root growth is controlled under stress conditions. We found that osmotic stress reduced the growth rate of the primary root by inhibiting the cell elongation in the elongation zone followed by a reduction in the number of cortical cells in the proximal meristem. We then studied the stiffness of epidermal cell walls in the root elongation zone of ttl1 mutants under osmotic stress using atomic force microscopy. In plants grown in control conditions, the mean apparent elastic modulus was 448% higher for live Col-0 cell walls than for ttl1 (88.1 ± 2.8 vs. 16.08 ± 6.9 kPa). Seven days of osmotic stress caused an increase in the stiffness in the cell wall of the cells from the elongation zone of 87% and 84% for Col-0 and ttl1, respectively. These findings suggest that TTL1 may play a role controlling cell expansion orientation during root growth, necessary for osmotic stress adaptation.

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Intrinsic nanomechanical changes in live diabetic cardiomyocytes

Benech

Benech²,

Zambrana³

et al. 2015

Cardiovasc Regen Med

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Patients with diabetes develop a cardiomyopathy that is independent of both coronary artery disease and hypertension and contributes to mortality and morbidity caused by diabetes. The mechanisms underlying the development of diabetic cardiomyopathy are poorly understood. Several reports showed that an early manifestation of diabetic myocardial dysfunction is an increased diastolic left ventricular (LV) stiffness. This increase is usually attributed to myocardial fibrosis or to myocardial deposition of advanced glycation end products. Alteration of the stiffness (resting tension) of the diabetic cardiomyocyte was also proposed to be an important factor contributing to increased LV stiffness. Some of these data were obtained from isolated cardiomyocytes from human frozen biopsy samples that had been thawed, mechanically disrupted, and incubated with Triton X-100, disrupting sarcolemmal and sarcoplasmic membranes. We therefore determined the stiffness of live isolated cardiomyocytes from control and streptozotocin-treated mice using atomic force microscopy (AFM) nanoindentation. We show that 3 months of type 1 diabetes provoked fragmentation and disorder of myocardial fibers, interstitial collagen deposition, reduction in SERCA2a calcium pump expression and changes in F-actin organization. Moreover, we show that live isolated diabetic cardiomyocytes are stiffer than control cardiomyocytes when tested in Tyrode buffer with different ionic compositions. Hence, it is very likely that intrinsic mechanical changes of cardiomyocytes are an important factor in increasing myocardial stiffness in vivo.

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Inés Rauschert

Diabetes increases stiffness of live cardiomyocytes measured by atomic force microscopy nanoindentation

Promoter hypermethylation as a mechanism for Lamin A/C silencing in a subset of neuroblastoma cells

Hyperglycemia and hyperlipidemia can induce morphophysiological changes in rat cardiac cell line

The Arabidopsis TETRATRICOPEPTIDE THIOREDOXIN-LIKE 1 Gene Is Involved in Anisotropic Root Growth during Osmotic Stress Adaptation

Intrinsic nanomechanical changes in live diabetic cardiomyocytes

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