A neoSENS target.
Other posts have discussed nuclear and mitochondrial DNA and how alterations is the information encoded therein can affect cell function. With the exception of a post by Wolfram in the early part of this year, the "3rd" type of DNA - ribosomal DNA - and how it influences aging has been largely ignored both within our community and somewhat by the biogerontology research community as an anti-senescence target.
Firstly some background: ribosomal DNA (rDNA) is DNA that encodes ribosomal RNA (rRNA) rather than messenger RNA (mRNA) which is ultimately translated into a protein. rDNA genes are found next to each other in stretches of hundreds of tandem repeats along one or more chromosomes. Once rDNA is transcribed into rRNA it associates to form ribosomes whose function is to translate the mRNA of any gene into an amino acid chain or protein. Hence ribosomes are directly responsible for protein manufacture. The rDNA tandem repeat region which is transcribed by RNA polymerase I becomes a discrete microscopically identifiable region inside the nucleus known as the nucleolus.
With the nucleolus being the region of ribosomal biogenesis which in turn is directly related to the capacity of the cell to translate mRNA, it stands to reason that mechanisms could exist to regulate the production of ribosomes and that the region of the chromosome where the rDNA tandem repeats are found is of vital importance to the cell's ability to manufacture protein. Just as telomerase negative cells become increasingly chromosomally unstable with each mitotic division that bring them closer to their Hayflick limit, so it could be that as time goes on, the progressive DNA damage that is occurring in the cell - most particularly in the rDNA region - reduces its ability to synthesize protein.
There is considerable evidence supporting the relationship between aging and reduced rDNA: it has been observed in humans ranging in age from infancy to 76 years that as age progresses the amount of hybridizable rDNA decreases at a rate of 0.5% per year (1) . Interestingly, the same test performed in dogs showed a ratio increase of 1:7 (2) - comparable to the well known lifespan ratio between humans and dogs. This age related reduction was confirmed in human fibroblasts using silver staining of nucleolar organizing regions (3). More recently, using PCR to quantitate rDNA, two components of the ribosome unit, the 28S and 5S subunit rDNA genes, were found to be reduced in copy number as age increased (4).
So what is causing this age dependent loss of rDNA? In rat germ and liver cells the reason appears to be hypermethylation (5). In Werners syndrome patients rDNA genes are found to be increasingly methylated (6). The observation that the 18S subunit gene is not decreased in aging suggests a possible recombination event (4) associated with loss of rDNA. In any case and whatever the mechanism of rDNA gene expression decrease, the effect of decreased ribosomal function could be devastating to cell physiology.
(1) Mechanisms of Ageing and Development, Volume 11, Issues 5-6, December 1979, Pages 371-378
Loss of hybridizable ribosomal DNA from human post-mitotic tissues during aging: I. Age-dependent loss in human myocardium
Bernard L. Strehler, Mei-Ping Chang and Lorin K. Johnson
(2) Mechanisms of Ageing and Development, Volume 11, Issues 5-6, December 1979, Pages 379-382
Loss of hybridizable ribosomal DNA from human post-mitotic tissues during aging: II. Age-dependent loss in human cerebral cortex — Hippocampal and somatosensory cortex comparison
Bernard L. Strehler and Mei-Ping Chang
(3)Mechanisms of Ageing and Development 92 (1996) 101–109
A longitudinal study of human age-related ribosomal RNA gene activity as detected by silver-stained NORs Samuel Thomas, Asit B. Mukherjee
(4) The International Journal of Biochemistry & Cell Biology 37 (2005) 409–415 (Attached)
Preferential loss of 5S and 28S rDNA genes in human adipose tissue during ageing
A. Zafiropoulos, E. Tsentelierou, M. Linardakis, A. Kafatos, D.A. Spandidosa
(5) PNAS 100 No 4 (2003) 1775-1780
Aging results in hypermethylation of ribosomal DNA in sperm and liver of male rats
Christopher C. Oakes, Dominic J. Smiraglia, Christoph Plass, Jacquetta M. Trasler and Bernard Robaire
(6) FASEB 14 (2000) 1715-1724
Accelerated methylation of ribosomal RNA genes during the cellular senescence of Werner syndrome fibroblasts
AMRITA MACHWE, DAVID K. ORREN, AND VILHELM A. BOHR
Attached Files
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Preferential_loss_of_5S_and_28S_rDNA_genes_in_human_adipose_tissue_during_ageing_.pdf 166.78KB
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