Kumars Riyahi scite author profile

The free radical theory of aging proposes that mitochondrial production of reactive oxygen species (ROS) determines the rate of aging. Supporting this hypothesis, longer-lived species produce fewer ROS than shorter-lived ones, and calorically restricted rodents live longer and produce fewer ROS than controls. We studied such correlation in Drosophila melanogaster in caloric restriction and in mutant flies overexpressing the mitochondrial adenine nucleotide translocase (ANT). Caloric restriction extended life span, but there was no significant difference in mitochondrial ROS production compared with controls. ANT overexpressers had significantly lower ROS production (because they had lower membrane potential), but their life span was not extended compared to wild type. Our results show two examples in which mitochondrial ROS production and life span are not correlated.

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Chordate βγ-crystallins and the evolutionary developmental biology of the vertebrate lens

Riyahi

Shimeld

2007

Comparative Biochemistry and Physiology Part B: Biochemistry an

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Telomere elongation through hTERT immortalization leads to chromosome repositioning in control cells and genomic instability in Hutchinson‐Gilford progeria syndrome fibroblasts, expressing a novel SUN1 isoform

Bikkul

Faragher

Worthington

et al. 2019

Genes Chromosomes & Cancer

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Immortalizing primary cells with human telomerase reverse transcriptase (hTERT) has been common practice to enable primary cells to be of extended use in the laboratory because they avoid replicative senescence. Studying exogenously expressed hTERT in cells also affords scientists models of early carcinogenesis and telomere behavior. Control and the premature ageing disease—Hutchinson‐Gilford progeria syndrome (HGPS) primary dermal fibroblasts, with and without the classical G608G mutation have been immortalized with exogenous hTERT. However, hTERT immortalization surprisingly elicits genome reorganization not only in disease cells but also in the normal control cells, such that whole chromosome territories normally located at the nuclear periphery in proliferating fibroblasts become mislocalized in the nuclear interior. This includes chromosome 18 in the control fibroblasts and both chromosomes 18 and X in HGPS cells, which physically express an isoform of the LINC complex protein SUN1 that has previously only been theoretical. Additionally, this HGPS cell line has also become genomically unstable and has a tetraploid karyotype, which could be due to the novel SUN1 isoform. Long‐term treatment with the hTERT inhibitor BIBR1532 enabled the reduction of telomere length in the immortalized cells and resulted that these mislocalized internal chromosomes to be located at the nuclear periphery, as assessed in actively proliferating cells. Taken together, these findings reveal that elongated telomeres lead to dramatic chromosome mislocalization, which can be restored with a drug treatment that results in telomere reshortening and that a novel SUN1 isoform combined with elongated telomeres leads to genomic instability. Thus, care should be taken when interpreting data from genomic studies in hTERT‐immortalized cell lines.

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Interphase Chromosomes in Replicative Senescence: Chromosome Positioning as a Senescence Biomarker and the Lack of Nuclear Motor-Driven Chromosome Repositioning in Senescent Cells

Mehta

Riyahi

Pereira

et al. 2021

Front. Cell Dev. Biol.

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This study demonstrates, and confirms, that chromosome territory positioning is altered in primary senescent human dermal fibroblasts (HDFs). The chromosome territory positioning pattern is very similar to that found in HDFs made quiescent either by serum starvation or confluence; but not completely. A few chromosomes are found in different locations. One chromosome in particular stands out, chromosome 10, which is located in an intermediate location in young proliferating HDFs, but is found at the nuclear periphery in quiescent cells and in an opposing location of the nuclear interior in senescent HDFs. We have previously demonstrated that individual chromosome territories can be actively and rapidly relocated, with 15 min, after removal of serum from the culture media. These chromosome relocations require nuclear motor activity through the presence of nuclear myosin 1β (NM1β). We now also demonstrate rapid chromosome movement in HDFs after heat-shock at 42°C. Others have shown that heat shock genes are actively relocated using nuclear motor protein activity via actin or NM1β (Khanna et al., 2014; Pradhan et al., 2020). However, this current study reveals, that in senescent HDFs, chromosomes can no longer be relocated to expected nuclear locations upon these two types of stimuli. This coincides with a entirely different organisation and distribution of NM1β within senescent HDFs.

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Kumars Riyahi

The effects of exogenous antioxidants on lifespan and oxidative stress resistance in Drosophila melanogaster

Lack of Correlation between Mitochondrial Reactive Oxygen Species Production and Life Span in Drosophila

Chordate βγ-crystallins and the evolutionary developmental biology of the vertebrate lens

Telomere elongation through hTERT immortalization leads to chromosome repositioning in control cells and genomic instability in Hutchinson‐Gilford progeria syndrome fibroblasts, expressing a novel SUN1 isoform

Interphase Chromosomes in Replicative Senescence: Chromosome Positioning as a Senescence Biomarker and the Lack of Nuclear Motor-Driven Chromosome Repositioning in Senescent Cells

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