Disrupted HSF1 regulation in normal and exceptional brain aging.

Brain aging is a major risk factor for cognitive diseases such as Alzheimer's disease (AD) and vascular dementia. The rate of aging and age-related pathology are modulated by stress responses and repair pathways that gradually decline with age. However, recent reports indicate that exceptional longevity sustains and may even enhance the stress response. Whether normal and exceptional aging result in either attenuated or enhanced stress responses across all organs is unknown. This question arises from our understanding that biological age differs from chronological age and evidence that the rate of aging varies between organs. Thus, stress responses may differ between organs and depend upon regenerative capacity and ability to manage damaged proteins and proteotoxicity. To answer these questions, we assessed age-dependent changes in brain stress responses with normally aged wild type and long-lived Dwarf mice. Results from this study show that normal aging unfavorably impacts activation of the brain heat shock (HS) axis with key changes noted in the transcription factor, HSF1, and its regulation. Exceptional aging appears to preserve and strengthen many elements of HSF1 activation in the brain. These results support the possibility that reconstitution of aging brain stress responses requires a multi-factorial approach that addresses HSF1 protein levels, its DNA binding, and regulatory elements such as phosphorylation and protein interactions.

A simplified and sensitive immunoprecipitation approach for the analysis of HSF1 in murine liver tissue.

Heat shock factor 1, HSF1, is one of several family members that recognize repeated nGAAn sequences associated with the heat shock element of heat shock and other genes. This transactivator is activated from a monomeric to trimeric form by oxidative, thermal and other stressors. Various studies show that HSF1 levels increase with cancer and decrease with aging and neurodegenerative disorders. It has a role in development as well as infections and inflammation. HSF1 is regulated by post-translational modifications and interactions with other proteins such as HSBP-1. Given its central importance in stress responsivity, various methods have been developed to identify HSF1 and its interacting partners. To date, multiple studies use conventional immunoprecipitation of HSF1 with commercially available antibodies which work well in cell lines but not whole tissue extracts. To remedy this shortfall, we developed a technique to retrieve activated HSF1 with an oligonucleotide link to a magnetic bead. The method captures HSF1 using a DNA sequence specific for HSF1 binding sites on promoter of heat shock genes. Confirmation of tissue derived HSF1 is identified using antibody against HSF1. The magnetic beads conjugated with DNA sequence specific to HSF1 binding was capable of yielding a reproducible band of high signal intensity with low background after native gel electrophoresis and ECL. Thus, the trimeric form of HSF1 can be isolated from tissue with magnetic beads conjugated with a short DNA sequence specific to HSF1 binding. This new method to identify HSF1 is economic, easy, and reproducible and does not require specialized equipment. It overcomes limitations of HSF1 tissue extraction by conventional immunoprecipitation, thus allowing for new approaches to understand HSF1 function in animal and human tissue.•HSF1 is a transcription factor that homotrimerize and binds to a conserved regulatory site, the heat shock element (HSE), consists of repeats of pentameric sequence '5-nGAAn-3' present in the promoters of inducible heat shock protein genes.•This protocol allows isolation of trimeric forms of HSF1 from tissue lysate using magnetic beads conjugated with a short DNA sequence with specific binding to HSF1.•This method is easy, economic and does not require unique instrumentation.

Augmentation of the heat shock axis during exceptional longevity in Ames dwarf mice.

How the heat shock axis, repair pathways, and proteostasis impact the rate of aging is not fully understood. Recent reports indicate that normal aging leads to a 50% change in several regulatory elements of the heat shock axis. Most notably is the age-dependent enhancement of inhibitory signals associated with accumulated heat shock proteins and hyper-acetylation associated with marked attenuation of heat shock factor 1 (HSF1)-DNA binding activity. Because exceptional longevity is associated with increased resistance to stress, this study evaluated regulatory check points of the heat shock axis in liver extracts from 12 months and 24 months long-lived Ames dwarf mice and compared these findings with aging wild-type mice. This analysis showed that 12M dwarf and wild-type mice have comparable stress responses, whereas old dwarf mice, unlike old wild-type mice, preserve and enhance activating elements of the heat shock axis. Old dwarf mice thwart negative regulation of the heat shock axis typically observed in usual aging such as noted in HSF1 phosphorylation at Ser307 residue, acetylation within its DNA binding domain, and reduction in proteins that attenuate HSF1-DNA binding. Unlike usual aging, dwarf HSF1 protein and mRNA levels increase with age and further enhance by stress. Together these observations suggest that exceptional longevity is associated with compensatory and enhanced HSF1 regulation as an adaptation to age-dependent forces that otherwise downregulate the heat shock axis.