Using the drug-protein interactome to identify anti-ageing compounds for humans.

Advancing age is the dominant risk factor for most of the major killer diseases in developed countries. Hence, ameliorating the effects of ageing may prevent multiple diseases simultaneously. Drugs licensed for human use against specific diseases have proved to be effective in extending lifespan and healthspan in animal models, suggesting that there is scope for drug repurposing in humans. New bioinformatic methods to identify and prioritise potential anti-ageing compounds for humans are therefore of interest. In this study, we first used drug-protein interaction information, to rank 1,147 drugs by their likelihood of targeting ageing-related gene products in humans. Among 19 statistically significant drugs, 6 have already been shown to have pro-longevity properties in animal models (p < 0.001). Using the targets of each drug, we established their association with ageing at multiple levels of biological action including pathways, functions and protein interactions. Finally, combining all the data, we calculated a ranked list of drugs that identified tanespimycin, an inhibitor of HSP-90, as the top-ranked novel anti-ageing candidate. We experimentally validated the pro-longevity effect of tanespimycin through its HSP-90 target in Caenorhabditis elegans.

Mitochondrial clearance and increased HSF-1 activity are coupled to promote longevity in fasted Caenorhabditis elegans.

Fasting has emerged as a potent means of preserving tissue function with age in multiple model organisms. However, our understanding of the relationship between food removal and long-term health is incomplete. Here, we demonstrate that in the nematode worm Caenorhabditis elegans, a single period of early-life fasting is sufficient to selectively enhance HSF-1 activity, maintain proteostasis capacity and promote longevity without compromising fecundity. These effects persist even when food is returned, and are dependent on the mitochondrial sirtuin, SIR-2.2 and the H3K27me3 demethylase, JMJD-3.1. We find that increased HSF-1 activity upon fasting is associated with elevated SIR-2.2 levels, decreased mitochondrial copy number and reduced H3K27me3 levels at the promoters of HSF-1 target genes. Furthermore, consistent with our findings in worms, HSF-1 activity is also enhanced in muscle tissue from fasted mice, suggesting that the potentiation of HSF-1 is a conserved response to food withdrawal.

Empowering students to confront environmental injustice: Dialogue, theory, empathy, and partnership.

Many students find environmental justice to be emotionally overwhelming and/or politically alienating, and there is currently little work that provides instructors with effective techniques for addressing these types of challenges. In this paper, upon situating the environmental studies classroom and the broader undergraduate experience in sociohistorical context, we identify four sequential strategies for engaging and empowering students on environmental justice issues. First, instructors can facilitate an open and honest dialogue by strategically framing course content for the unique composition of the audience, sharing their own racialized experiences (or working with a guest speaker who would be willing to do so), and using interactive assignments to encourage student participation. Second, social theory can be presented to students as complimentary (rather than competing) ideas which can be used for creative, real-world problem solving. Third, instructors and students can cultivate empathy by acknowledging different standpoints, particularly those that have been historically marginalized. Lastly, by working in partnerships with community-based organizations, instructors and students can think and work beyond hero/savior and perpetrator/victim narratives. These strategies are not intended as a set of silver bullets, but rather as a series of potential starting points that are informed by recent scholarship on these topics.

Loss of MTCH-1 suppresses age-related proteostasis collapse through the inhibition of programmed cell death factors.

The age-related loss of protein homeostasis (proteostasis) is at the heart of numerous neurodegenerative diseases. Therefore, finding ways to preserve proteome integrity in aged cells may be a powerful way to promote long-term health. Here, we show that reducing the activity of a highly conserved mitochondrial outer membrane protein, MTCH-1/MTCH2, suppresses age-related proteostasis collapse in Caenorhabditis elegans without disrupting development, growth, or reproduction. Loss of MTCH-1 does not influence proteostasis capacity in aged tissues through previously described pathways but instead operates by reducing CED-4 levels. This results in the sequestration of HSP-90 by inactive CED-3, which in turn leads to an increase in HSF-1 activity, transcriptional remodeling of the proteostasis network, and maintenance of proteostasis capacity with age. Together, our findings reveal a role for programmed cell death factors in determining proteome health and suggest that inhibiting MTCH-1 activity in adulthood may safeguard the aging proteome and suppress age-related diseases.

A Mitochondrial Stress-Specific Form of HSF1 Protects against Age-Related Proteostasis Collapse.

The loss of protein homeostasis (proteostasis) is a primary driver of age-related tissue dysfunction. Recent studies have revealed that the failure of proteostasis with age is triggered by developmental and reproductive cues that repress the activity of proteostasis-related pathways in early adulthood. In Caenorhabditis elegans, reduced mitochondrial electron transport chain (ETC) function during development can override signals that promote proteostasis collapse in aged tissues. However, it is unclear precisely how these beneficial effects are mediated. Here, we reveal that in response to ETC impairment, the PP2A complex generates a dephosphorylated, mitochondrial stress-specific variant of the transcription factor HSF-1. This results in the selective induction of small heat shock proteins in adulthood, thereby protecting against age-related proteostasis collapse. We propose that mitochondrial signals early in life can protect the aging cytosolic proteome by tailoring HSF-1 activity to preferentially drive the expression of non-ATP-dependent chaperones.