Promoter methylation and age-related downregulation of Klotho in rhesus monkey

King, Gwendalyn D.; Rosene, Douglas L.; Abraham, Carmela R.

doi:10.1007/s11357-011-9315-4

Cited by 82 publications

(70 citation statements)

References 61 publications

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“…Since uremic toxins are believed to act via inflammatory pathways and we see evidence of neuroinflammation in our system, it is quite possible that elevated promoter methylation underlies the decreased brain α-Klotho seen in nephrectomized rats. Supporting this idea further, kl promoter methylation can be modulated in the brain, since an age-dependent increase that correlates with decreased protein expression has been reported in the white matter of rhesus monkeys (King et al, 2012). Altered promoter methylation in the brains of our animals is clearly a hypothesis that can be tested relatively easily.…”

Section: How Does Kidney Damage Cause Loss Of α-Klotho In the Brain? supporting

confidence: 71%

“…Some studies of α-Klotho gene expression have been reported, indicating that the kl promoter can be activated by testosterone and the androgen receptor (Hsu et al, 2014), and by the transcription factor Egr-1 (Choi et al, 2010). Perhaps most intriguingly however, α-Klotho transcription is strongly repressed by promoter methylation (Azuma et al, 2012;King et al, 2012;Sun et al, 2012). This phenomenon has been suggested to underlie the tightly controlled tissue-specific pattern of α-Klotho expression (Azuma et al, 2012) and is reported to increase with age (King et al, 2012).…”

Section: How Does Kidney Damage Cause Loss Of α-Klotho In the Brain? mentioning

confidence: 99%

“…Perhaps most intriguingly however, α-Klotho transcription is strongly repressed by promoter methylation (Azuma et al, 2012;King et al, 2012;Sun et al, 2012). This phenomenon has been suggested to underlie the tightly controlled tissue-specific pattern of α-Klotho expression (Azuma et al, 2012) and is reported to increase with age (King et al, 2012). Interestingly, increased KL promoter methylation has also been described in a number of cancers, including cervical carcinoma, colorectal, breast and gastric cancers Pan et al, 2011;Rubinek et al, 2012;Wang et al, 2011).…”

Section: How Does Kidney Damage Cause Loss Of α-Klotho In the Brain? mentioning

confidence: 99%

See 2 more Smart Citations

The relevance of α-KLOTHO to the central nervous system: Some key questions

Cararo-Lopes

Mazucanti

Scavone

et al. 2017

Ageing Research Reviews

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Section: How Does Kidney Damage Cause Loss Of α-Klotho In the Brain? supporting

confidence: 71%

Section: How Does Kidney Damage Cause Loss Of α-Klotho In the Brain? mentioning

confidence: 99%

Section: How Does Kidney Damage Cause Loss Of α-Klotho In the Brain? mentioning

confidence: 99%

See 1 more Smart Citation

The relevance of α-KLOTHO to the central nervous system: Some key questions

Cararo-Lopes

Mazucanti

Scavone

et al. 2017

Ageing Research Reviews

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“…Additionally, pyrosequencing requires multiple sequencing primers and Sanger sequencing traditionally required cloning of PCR products, a laborious task (Zhang et al 2009). Nevertheless, these techniques have been used to great effect to generate base-specific analysis of selected regions and changes in methylation, but not hydroxymethylation, with aging (Noer et al 2007;Maegawa et al 2010;King et al 2012). …”

Section: Base-specificity Of Dna Modificationsmentioning

confidence: 99%

Analysis of DNA modifications in aging research

et al. 2018

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As geroscience research extends into the role of epigenetics in aging and age-related disease, researchers are being confronted with unfamiliar molecular techniques and data analysis methods that can be difficult to integrate into their work. In this review, we focus on the analysis of DNA modifications, namely cytosine methylation and hydroxymethylation, through nextgeneration sequencing methods. While older techniques for modification analysis performed relative quantitation across regions of the genome or examined average genome levels, these analyses lack the desired specificity, rigor, and genomic coverage to firmly establish the nature of genomic methylation patterns and their response to aging. With recent methodological advances, such as whole genome bisulfite sequencing (WGBS), bisulfite oligonucleotide capture sequencing (BOCS), and bisulfite amplicon sequencing (BSAS), cytosine modifications can now be readily analyzed with base-specific, absolute quantitation at both cytosine-guanine dinucleotide (CG) and non-CG sites throughout the genome or within specific regions of interest by next-generation sequencing. Additional advances, such as oxidative bisulfite conversion to differentiate methylation from hydroxymethylation and analysis of limited input/single-cells, have great promise for continuing to expand epigenomic capabilities. This review provides a background on DNA modifications, the current state-of-theart for sequencing methods, bioinformatics tools for converting these large data sets into biological insights, and perspectives on future directions for the field.

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“…Additionally the validation approach used can be a model for qualification of other capture probe sets developed in the future. An exciting future direction of BOCS methodology in general will be the application of this technology to other important animal models in biomedical research, such as non-human primates (King et al 2012) and mice, which have been established as important model systems for disease research in the areas of neuroscience, substance abuse, and aging.…”

Section: Rat Genome Methylation Analysismentioning

confidence: 99%

Bisulfite oligonucleotide-capture sequencing for targeted base- and strand-specific absolute 5-methylcytosine quantitation

Masser

Stanford

Hadad

et al. 2016

AGE

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Epigenetic regulation through DNA methylation (5mC) plays an important role in development, aging, and a variety of diseases. Genome-wide studies of base-and strand-specific 5mC are limited by the extensive sequencing required. Targeting bisulfite sequencing to specific genomic regions through sequence AGE (2016) capture with complimentary oligonucleotide probes retains the advantages of bisulfite sequencing while focusing sequencing reads on regions of interest, enables analysis of more samples by decreasing the amount of sequence required per sample, and provides base-and strand-specific absolute quantitation of CG and non-CG methylation levels. As an example, an oligonucleotide capture set to interrogate 5mC levels in all rat RefSeq gene promoter regions (18,814) and CG islands, shores, and shelves (18,411) was generated. Validation using whole-genome methylation standards and biological samples demonstrates enrichment of the targeted regions and accurate base-specific quantitation of CG and non-CG methylation for both forward and reverse genomic strands. A total of 170 Mb of the rat genome is covered including 6.6 million CGs and over 67 million non-CG sites, while reducing the amount of sequencing required by~85 % as compared to existing wholegenome sequencing methods. This oligonucleotide capture targeting approach and quantitative validation workflow can also be applied to any genome of interest.

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Promoter methylation and age-related downregulation of Klotho in rhesus monkey

Cited by 82 publications

References 61 publications

The relevance of α-KLOTHO to the central nervous system: Some key questions

The relevance of α-KLOTHO to the central nervous system: Some key questions

Analysis of DNA modifications in aging research

Bisulfite oligonucleotide-capture sequencing for targeted base- and strand-specific absolute 5-methylcytosine quantitation

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