autophagy Archives - Sanford Burnham Prebys
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New roles for autophagy genes in cellular waste management and aging

AuthorCommunications
Date

January 3, 2024

Autophagy genes help extrude protein aggregates from neurons in the nematode C. elegans.

Autophagy, which declines with age, may hold more mysteries than researchers previously suspected. In the January 4 issue of Nature Aging, it was noted that scientists from the Buck Institute, Sanford Burnham Prebys and Rutgers University have uncovered possible novel functions for various autophagy genes, which may control different forms of disposal including misfolded proteins—and ultimately affect aging.

“While this is very basic research, this work is a reminder that it is critical for us to understand whether we have the whole story about the different genes that have been related to aging or age-related diseases,” said Professor Malene Hansen, PhD, Buck’s chief scientific officer, who is also the study’s co-senior author. “If the mechanism we found is conserved in other organisms, we speculate that it may play a broader role in aging than has been previously appreciated and may provide a method to improve life span.”

These new observations provide another perspective to what was traditionally thought to be occurring during autophagy.

Autophagy is a cellular “housekeeping” process that promotes health by recycling or disposing of damaged DNA and RNA and other cellular components in a multi-step degradative process. It has been shown to be a key player in preventing aging and diseases of aging, including cancer, cardiovascular disease, diabetes and neurodegeneration. Notably, research has shown that autophagy genes are responsible for prolonged life span in a variety of long-lived organisms.

The classical explanation of how autophagy works is that the cellular “garbage” to be dealt with is sequestered in a membrane-surrounded vesicle, and ultimately delivered to lysosomes for degradation. However, Hansen, who has studied the role of autophagy in aging for most of her career, was intrigued by an accumulation of evidence that indicated that this was not the only process in which autophagy genes can function.

“There had been this growing notion over the last few years that genes in the early steps of autophagy were ‘moonlighting’ in processes outside of this classical lysosomal degradation,” she said. “Additionally, while it is known that multiple autophagy genes are required for increased life span, the tissue-specific roles of specific autophagy genes are not well defined.”

To comprehensively investigate the role that autophagy genes play in neurons—a key cell type for neurodegenerative diseases—the team analyzed Caenorhabditis elegans, a tiny worm that is frequently used to model the genetics of aging and which has a very well-studied nervous system. The researchers specifically inhibited autophagy genes functioning at each step of the process in the neurons of the animals, and found that neuronal inhibition of early-acting, but not late-acting, autophagy genes, extended life span.

An unexpected aspect was that this life span extension was accompanied by a reduction in aggregated protein in the neurons (an increase is associated with Huntington’s disease, for example), and an increase in the formation of so-called exophers. These giant vesicles extruded from neurons were identified in 2017 by Monica Driscoll, PhD, a collaborator and professor at Rutgers University.

“Exophers are thought to be essentially another cellular garbage disposal method, a mega-bag of trash,” said Caroline Kumsta, PhD, co-senior author and assistant professor at Sanford Burnham Prebys “When there is either too much trash accumulating in neurons, or when the normal ‘in-house’ garbage disposal system is broken, the cellular waste is then being thrown out in these exophers.

“Interestingly, worms that formed exophers had reduced protein aggregation and lived significantly longer. This finding suggests a link between this process of this massive disposal event to overall health,” said Kumsta. The team found that this process was dependent on a protein called ATG-16.2.

The study identified several new functions for the autophagy protein ATG-16.2, including in exopher formation and life span determination, which led the team to speculate that this protein plays a nontraditional and unexpected role in the aging process. If this same mechanism is operating in other organisms, it may provide a method of manipulating autophagy genes to improve neuronal health and increase life span.

“But first we have to learn more—especially how ATG-16.2 is regulated and whether it is relevant in a broader sense, in other tissues and other species,” Hansen said. The Hansen and Kumsta teams are planning on following up with a number of longevity models, including nematodes, mammalian cell cultures, human blood and mice.

“Learning if there are multiple functions around autophagy genes like ATG-16.2 is going to be super important in developing potential therapies,” Kumsta said. “It is currently very basic biology, but that is where we are in terms of knowing what those genes do.”

The traditional explanation that aging and autophagy are linked because of lysosomal degradation may need to expand to include additional pathways, which would have to be targeted differently to address the diseases and the problems that are associated with that. “It will be important to know either way,” Hansen said. “The implications of such additional functions may hold a potential paradigm shift.” 
 
DOI: 10.1038/s43587-023-00548-1

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Do worms get stressed? We asked an expert

AuthorMiles Martin
Date

April 19, 2023

The National Institutes of Health recognizes April as National Stress Awareness Month, with the goal of bringing awareness to the health impact of stress.



 

Stress comes in many forms—from the psychological stress we experience during difficult moments to the biological stress in our smallest cells. At Sanford Burnham Prebys, Assistant Professor Caroline Kumsta, PhD, uses small worms (nematodes) to study the negative relationship between cellular stress and aging (yes, aging can be stressful!). On the flip side, she’s also exploring how we can use small amounts of stress to improve health and potentially treat neurodegenerative diseases. 

We spoke to Kumsta about her research to learn more about how nematodes, stress and neurodegenerative diseases are all related.

Why do you work with nematodes?
Nematodes are very good for aging research because they have a short life span—only a few weeks—so we can measure the effects of aging within a reasonable amount of time. Another reason why we like these worms is because we can measure stress responses in more than individual cells. We can use nematodes to study broader, more systemic responses, as well as how stress responses are communicated from tissue to tissue. We can only see these effects if we look at how stress responses are orchestrated across the entire organism. Even though worms don’t look like us, a lot of the basic biological machinery we study is the same as in humans because stress responses evolved a long, long time ago.

How do worms help you study aging and cellular stress responses?
“What doesn’t kill you makes you stronger” is true in biology—in other words, small amounts of stress can actually be beneficial for organisms, including humans. We’re studying this idea in nematodes by giving them a small heat shock early in their lives, almost like giving them a few minutes in a sauna. The heat triggers stress responses in the worms at the cellular level, and one of these responses is that the worms’ cells induce a cellular recycling process, called autophagy. Autophagy recycles cellular components and helps keep cells healthy and free from debris. This is a beneficial process that helps increase the life span of the worms. My team is exploring how this process works and figuring out how we can use it to fight diseases.

How can your work in nematodes help us study human diseases?
Our main target is neurodegenerative diseases. One of the drivers of diseases like Alzheimer’s, Parkinson’s or Huntington’s disease is that proteins accumulate in the brain in aggregates or clumps. We’ve seen that nematodes that have had a heat shock early in their lives have reduced clumping of disease-relevant proteins. This is because when autophagy kicks in as a stress response, it helps slow the accumulation of these clumpy proteins. We’re ultimately looking for ways to boost the cellular recycling process in humans as a way to treat degenerative diseases. We can imagine heat therapy as a treatment intervention, and we are currently developing methods of measuring autophagy status in humans so that we will be able to test potential interventions. 

Institute News

Top Sanford Burnham Prebys research stories of 2021

AuthorSusan Gammon
Date

December 14, 2021

This year’s most popular research stories include scientific breakthroughs in COVID-19, cancer, schizophrenia and more.

As we bid farewell to 2021, let’s celebrate our most newsworthy research breakthroughs. Despite the continuing challenges brought on by COVID-19, Sanford Burnham Prebys achieved important milestones on the frontiers of biomedical science.

The following 10 research-related stories received top views on Newswise—the press release distribution service for journalists seeking health and science news.
 

  1. COVID-19: Scientists identify human genes that fight infection


    A research team was able to pinpoint specific human genes that control viral infection. The information sheds new light on factors that lead to severe disease and guides therapeutic options.
     
  2. Tumor marker may help overcome endocrine treatment-resistant breast cancer


    The study discovered a new approach to select breast cancer patients for HER2 therapy and could help individuals avoid disease relapse or progression of endocrine-sensitive disease.
     
  3. Scientists identify potential drug candidates for deadly pediatric leukemia


    Two existing drugs—JAK inhibitors and Mepron—show promise for a subtype of acute myeloid leukemia (AML) that is more common in children. The drugs are proven safe in humans, which could accelerate clinical studies.
     
  4. Leprosy drug holds promise as at-home treatment for COVID-19


    Scientists found that the leprosy drug clofazimine, which is FDA approved and on the World Health Organization’s List of Essential Medicines, exhibits potent antiviral activities against SARS-CoV-2, and could become an important weapon against future pandemics.
     
  5. Researchers dig deeper into how cells transport their waste for recycling


    Research describing how the “trash bags” in a cell—called autophagosomes—are tagged for recycling opened new paths to understand age-related diseases such as cancer and neurological disorders.
     
  6. New drug combination shows promise as powerful treatment for AML


    Researchers identified two drugs that are potent against acute myeloid leukemia (AML) when combined, but only weakly effective when used alone. The study provides a scientific rationale for advancing clinical studies of the drug combination.
     
  7. Biomarker could help diagnose schizophrenia at an early age


    A study described how elevated levels of a protein called CRMP2—found in the brain and blood—could become a format for a rapid, minimally invasive blood test to support the diagnosis of schizophrenia.
     
  8. Scientists identify “immune cop” that detects SARS-CoV-2


    Researchers discovered the sensor in human lungs that detects SARS-CoV-2 and signals that it’s time to mount an antiviral attack. The sensor activates interferon, the body’s own frontline defender against viral invasion.
     
  9. Study finds promising therapeutic target for colitis


    Scientists identified an enzyme in the gut that triggers an inflammatory cascade leading to colitis. Therapeutically targeting the enzyme may be a viable approach to help the millions of people worldwide affected by the disorder.
     
  10. Scientists shrink pancreatic tumors by starving their cellular “neighbors”


    For the first time, blocking “cell drinking,” or micropinocytosis in the thick tissue surrounding a pancreatic tumor, was shown to slow tumor growth—providing more evidence that micropinocytosis is an important therapeutic target.
Institute News

Dietary restriction increases lifespan through effects on the gut

AuthorJessica Moore
Date

July 14, 2016

Dietary restriction, or limited food intake without malnutrition, has beneficial effects on longevity in many species, including humans. A new study from the Sanford Burnham Prebys Medical Discovery Institute (SBP), published today in PLoS Genetics, represents a major advance in understanding how dietary restriction leads to these advantages.

“In this study, we used the small roundworm C. elegans as a model to show that autophagy in the intestine is critical for lifespan extension,” said Malene Hansen, PhD, associate professor in SBP’s Development, Aging, and Regeneration Program and senior author of the study. “We found that the gut of dietary-restricted worms has a higher than normal rate of autophagy, which appears to improve fitness in multiple ways—preserving intestinal integrity and maintaining the animal’s ability to move around.”

Autophagy, or cellular recycling, is well known to play a role in lifespan extension. Autophagy involves breaking down the cell’s parts—its protein-making, power-generating, and transport systems—into small molecules. This both eliminates unnecessary or broken cell machinery and provides building blocks to make new cell components, which is especially important when starting materials are not provided by the diet.

In this study the research team wanted to understand how dietary restriction impacts autophagy in the intestine, whose proper function is already known to be important for long life.

“The strain of worms we used, called eat-2, is genetically predisposed to eat less, and they live longer than normal worms, so they provide an ideal model in which to investigate how dietary restriction extends lifespan,” said Sara Gelino, PhD, research associate in Hansen’s lab and lead author of the study. “We found that blocking autophagy in their intestines significantly shortened their lifespans, showing that autophagy in this organ is key for longevity.

“These results led us to examine how inhibiting autophagy impacts the function of the intestine. We found that while normal worms’ gut barriers become leaky as they get older, those of eat-2 worms remain intact. Preventing autophagy eliminated this benefit, which indicates that a non-leaky intestine is an important factor for long life.”

“How intestinal integrity relates to longevity is not clearly understood,” Hansen commented. “It’s possible that the decline in the gut’s barrier function associated with normal aging might let damaging substances or pathogens into the body.”

The research team also observed that turning off autophagy in the intestine made the slow-eating, long-lived worms move around less.

“The decrease in physical activity indicates that autophagy in one organ can have a major impact on other organs, in this case probably muscle or motor neurons,” said Hansen. “Finding the link between motility and autophagy in the intestine will require further research, but we speculate that inhibiting autophagy in the gut may impair the gut’s ability to metabolize nutrients or secrete hormones important for the function of other organs.”

While these results suggest that boosting autophagy in the gut is generally beneficial, Hansen cautions that further research is needed: “Before we can consider regulating autophagy to manage disease, we need to learn a lot more about how the process works both in a single cell as well as in the whole organism.”

Many of these future studies will also employ C. elegans. “Even though worms are much simpler than humans, many of the same basic mechanisms drive their biology. The knowledge we gain from this fast-paced research could eventually contribute to the development of new treatments that help people live longer, healthier lives,” added Hansen.

The paper is available online here.

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New drug squashes cancer’s last-ditch efforts to survive

Authorsgammon
Date

June 25, 2015

As a tumor grows, its cancerous cells ramp up an energy-harvesting process to support its hasty development. This process, called autophagy, is normally used by a cell to recycle damaged organelles and proteins, but is also co-opted by cancer cells to meet their increased energy and metabolic demands. Continue reading “New drug squashes cancer’s last-ditch efforts to survive”

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Newly discovered cell stress pathway could hold therapeutic promise for diverse diseases

AuthorGuest Blogger
Date

January 5, 2015

This post was written by Janelle Weaver, PhD, a freelance writer.

When cells are faced with unfavorable environmental conditions, such as limited nutrient availability, the activation of adaptive stress responses can help protect them against damage or death. For example, stressed cells can maintain sufficient energy levels for survival by degrading and recycling unnecessary or dysfunctional cellular components. This survival mechanism, known as autophagy (literally, ‘self-digestion’), also plays key roles in a variety of biological processes such as development and aging, and is often perturbed in various diseases. Even though tight control of autophagy is key to survival, relatively little is known about the signaling molecules that regulate this essential process. Continue reading “Newly discovered cell stress pathway could hold therapeutic promise for diverse diseases”

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Sanford-Burnham researcher awarded American Federation for Aging Research award

Authorsgammon
Date

December 23, 2014

Malene Hansen, PhD, associate professor in our Development, Aging, and Regeneration Program has been awarded the Julie Martin Mid-Career Award in Aging Research. The award includes a new grant to continue her research in the field of aging. Hansen is a three-time American Federation for Aging Research (AFAR) grant recipient. AFAR’s grants are given to scientists at institutions nationwide based on hard work, ingenuity, and leadership that advance cutting-edge research to help us live healthier, longer lives. Continue reading “Sanford-Burnham researcher awarded American Federation for Aging Research award”