Understanding the Mechanisms of Brain Aging and Longevity in Neurons

In a new editorial, researchers discuss interconnected mechanisms of neuronal functionality and available tools to investigate neuronal aging and longevity. 

Neurons, the building blocks of the nervous system, play a vital role in our body’s function and longevity. Unlike other cells, neurons do not undergo replicative aging. However, they are still susceptible to various sources of damage throughout life, leading to neuronal death. Understanding the mechanisms behind aging and neuronal death is crucial for uncovering the secrets of brain longevity and developing potential interventions to promote healthy aging.

In a new editorial, researchers Fang Fang, Robert Usselman and Renee Reijo Pera from University of Science and Technology of China, Florida Institute of Technology and McLaughlin Research Institute discussed new interconnected mechanisms of neuronal functionality and available tools to investigate neuronal aging and longevity. On December 13, 2023, their editorial was published in Aging’s Volume 15, Issue 23, entitled, “Aging and neuronal death.”

Neuronal Durability, Differentiation & Maintenance

Neurons, born during embryonic development, must function in the body for the entire lifespan of the organism. They are incredibly durable cells, but they are not immune to damage. Neurons require a significant amount of oxygen and glucose to carry out their activities, making them vulnerable to ischemia. Ischemia occurs when the blood supply to a particular tissue is restricted, leading to oxygen and nutrient deprivation. 

Neurons can accumulate damage over time, which may result in cell death linked to reactive oxygen species (ROS). Neurons may also die due to ion overload and swelling caused by the malfunction of voltage-gated ion channels on their membranes. High concentrations of neurotransmitters and the accumulation of misfolded proteins are also implicated in neuronal death, observed in various neurodegenerative diseases.

To gain insights into the factors that promote neuron differentiation and maintenance, researchers have developed innovative screening methods. For example, Cui and colleagues described a high-throughput screening method using a luciferase reporter construct inserted downstream of the endogenous tyrosine hydroxylase (TH) gene. They differentiated neurons from human pluripotent stem cells and monitored their activity over time. This approach allows for the modeling of cell survival and demise, providing valuable information about the factors that influence neuronal longevity.

The Role of ROS in Survival & Death

Reactive oxygen species (ROS) are molecules produced during normal cellular metabolism. They play a crucial role in various biological processes but can also lead to oxidative stress when their levels exceed normal functional levels. Recent research has shed light on the distinction between global and local ROS balances and imbalances in cell phenotyping and mitochondrial energy management.

While global ROS homeostasis is essential for overall cellular health, ROS signaling pathways are driven locally by cellular microdomain-specific ROS production and degradation. Neurons have developed mechanisms to control ROS production and combat oxidative stress. For example, they express neurotrophic proteins that enhance mitochondrial activity, promoting the overall health of neurons.

“A sustained disruption of ROS balance can result in desirable enhanced cell signaling or undesirable oxidative stress, which can either improve function or diminish performance, respectively.”

Mechanisms for Longevity

Neurons have evolutionarily developed intricate mechanisms to maintain their longevity. They possess a distinct transcriptome signature that represses genes related to neural excitation and synaptic function. By preventing neurons from experiencing ion overload, this mechanism contributes to their long-term survival.

These brain cells have also developed specific DNA repair mechanisms to correct errors induced by active transcription. Neurons can turn off pro-apoptotic genes through alternative splicing, avoiding apoptosis and promoting long-term survival. These interconnected mechanisms work together to reduce the accumulation of aging-related damage in neurons. Understanding the fundamental mechanisms that enable the longevity of neurons is crucial for developing interventions that promote healthy brain aging. Researchers can use novel tools, including cell-based models, imaging techniques and animal studies, to investigate these mechanisms.

Conclusions

Neurons, although durable cells, are susceptible to various forms of damage that can lead to their demise. By studying the interplay between ROS, neuronal excitation, DNA repair, and apoptosis, researchers aim to uncover the secrets of brain longevity and develop strategies to mitigate the effects of aging on neurons. By understanding these mechanisms, researchers aim to develop interventions that promote healthy brain aging and enhance our overall understanding of brain health.

“Together, these findings suggest that neurons have evolved a set of intrinsically interconnected mechanisms to reduce long-term accumulations of aging-related damages. Disruption in these mechanisms may tip the neuron homeostasis off-balance and drive the neurons into the path of degeneration. We have a plethora of tools to probe the fundamental mechanisms with hopes of translation to clinical applications.”

Click here to read the full editorial published in Aging.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

What Makes Children of Older Fathers at Increased Risk of Autism?

In this new study, researchers investigated the relationship between paternal age, the BEGAIN gene and autism.

Autism spectrum disorder (ASD) is a neurodevelopmental disorder characterized by deficits in communication and social interaction, as well as repetitive behaviors. It has been observed that children born to older fathers have an increased risk of developing ASD and other neurodevelopmental disorders. This phenomenon suggests that paternal age may have an impact on the risk of ASD in offspring.

Recent research has focused on understanding the potential mechanisms underlying the association between paternal age and ASD. One area of interest is the epigenome, specifically DNA methylation, which refers to the addition or removal of methyl groups to DNA molecules. DNA methylation can affect gene expression and play a role in various biological processes.

In a new study, researchers Ramya Potabattula, Andreas Prell, Marcus Dittrich, Caroline Nava, Christel Depienne, Yosra Bejaoui, Nady El Hajj, Thomas Hahn, Martin Schorsch, and Thomas Haaf from Julius Maximilians University, Groupe Hospitalier Pitié-Salpêtrière, University Hospital Essen, Hamad Bin Khalifa University, and Fertility Center in Wiesbaden, Germany, explored the relationship between paternal age, DNA methylation of the BEGAIN gene, and the risk of ASD. The BEGAIN gene encodes a protein involved in protein-protein interactions at synapses, which are crucial for proper brain function. On November 28, 2023, their research paper was published in Aging’s Volume 15, Issue 22, entitled, “Effects of paternal and chronological age on BEGAIN methylation and its possible role in autism.”

“So far, only 40 genes with sperm ageDMRs [age-associated differentially methylated regions] have been replicated in at least three independent genome-wide methylation screens [19], which makes them primary candidates for mediating paternal age effects on the next generation. Here, we focused on one of these top candidates, the BEGAIN promoter region.”

The Study

The study focused on examining the impact of paternal age on BEGAIN methylation. Various techniques were employed to investigate this relationship. Sperm samples from normozoospermic individuals attending a fertility center were analyzed. The researchers aimed to understand how paternal age influences BEGAIN methylation, specifically observing its trends in sperm.

To extend their exploration of transgenerational effects, fetal cord blood samples were also examined. The team aimed to discern whether paternal age influenced BEGAIN methylation differently in male and female offspring. The research team employed meticulous analyses to understand the sex-specific patterns associated with paternal age and BEGAIN methylation.

They also delved into the effects of chronological age on BEGAIN methylation. Peripheral blood samples from individuals of different ages were analyzed to investigate the relationship between chronological age and BEGAIN methylation. The study aimed to discern whether BEGAIN methylation undergoes changes with age in a sex-specific manner.

“It is tempting to speculate that transmission of paternal age-associated sperm methylation changes into the next generation modulates BEGAIN regulation and susceptibility to neurodevelopmental disorders.”

The Results

The research yielded significant findings. A negative correlation between paternal age and BEGAIN methylation was identified, suggesting a decrease in BEGAIN methylation in sperm as paternal age increases. The sex-specific impact of paternal age on BEGAIN methylation was observed, with a significant negative correlation in male offspring but not in female offspring.

Regarding chronological age, a significant negative correlation with BEGAIN methylation was found in males but not in females, indicating a potential sex-specific age-related change in BEGAIN methylation.

The study also explored the association between BEGAIN methylation and Autism Spectrum Disorder (ASD). Individuals with ASD were found to have significantly lower levels of BEGAIN methylation compared to age- and sex-matched controls, suggesting a potential involvement of BEGAIN methylation in the development of ASD.

Furthermore, the researchers identified a genetic variant, SNP rs7141087, associated with BEGAIN methylation. The CC genotype of this SNP was linked to lower levels of BEGAIN methylation compared to the TT genotype, potentially contributing to observed differences in BEGAIN methylation between individuals with ASD and controls.

“Individuals with CC genotype of SNP rs7141087 which show a 6% lower methylation than the TT genotype are significantly more frequent in our ASD group than in controls. This could be due to an association of the C allele with autism.”

Conclusions & Future Research

In conclusion, this research provides valuable insights into the effects of paternal and chronological age on BEGAIN methylation and its potential role in ASD. The findings suggest that paternal age and chronological age can influence BEGAIN methylation, and these changes may be associated with an increased risk of ASD. Further research is needed to fully understand the mechanisms underlying these associations and their implications for the development of ASD.

“The male-specific hypomethylation of the BEGAIN promoter in blood, and by extrapolation other somatic tissues is exaggerated in males suffering from autism. Moreover, our results also show a paternal age effect on BEGAIN methylation in sperm and the male offspring (FCB). […] However, the functional implications of small age-associated methylation changes in BEGAIN in a multifactorial disease model remain to be elucidated.”

Click here to read the full study published in Aging.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

How a Receptor Boosts WNT Signals in Pancreatic Cancer

In this new study, researchers revealed a novel role for LGR6 in enhancing WNT signals in pancreatic cancer. 

Pancreatic cancer is one of the deadliest forms of cancer, with a very low survival rate and limited treatment options. Understanding the molecular mechanisms that drive the development and progression of this disease is crucial for finding new ways to prevent and treat it. One of the key players in pancreatic cancer is the WNT signaling pathway, which regulates many aspects of cell growth, differentiation and survival. WNT signaling is often dysregulated in pancreatic cancer, leading to uncontrolled cell proliferation, invasion and resistance to therapy.

“The canonical WNT pathway is reportedly an essential protagonist in organ development as well as oncogenesis in multiple cancers.”

How does WNT signaling become so powerful in pancreatic cancer cells? In a new study, researchers Jing Wang, Dominik T. Koch, Felix O. Hofmann, Daniel Härtwig, Iris Beirith, Klaus Peter Janssen, Alexandr V. Bazhin, Hanno Niess, Jens Werner, Bernhard W. Renz, and Matthias Ilmer from Ludwig-Maximilians-University, University of Science and Technology of China, Technical University of Munich, and German Cancer Consortium revealed a novel role for a receptor called LGR6 in enhancing WNT signals in this disease. Their research paper was published on September 27, 2023, in Aging’s Volume 15, Issue 20, entitled, “WNT enhancing signals in pancreatic cancer are transmitted by LGR6.”

The Study

LGR6 is a member of the leucine-rich repeat-containing G-protein-coupled receptor (LGR) family, which can bind to proteins called R-spondins (RSPOs). RSPOs are known to potentiate WNT signaling by preventing the degradation of WNT receptors and co-receptors on the cell surface. The authors of this study note that LGR5 has previously been described as a WNT target gene as well as a marker of cancer stem cells. In this study, the team aimed to determine whether its homologue LGR6 incorporates similar functional aspects in pancreatic ductal adenocarcinoma (PDAC).

“In this work, we aimed to decipher the functions of LGR6 in WNT signaling of PDAC, apart from its assumed assignment as a receptor to RSPO. Taken into account the connections between WNT signaling and EMT, we further hypothesized a likely interplay of LGR6 and EMT.”

The researchers found that LGR6 is differentially expressed in various pancreatic cancer cell lines, depending on their phenotype and WNT activation status. Cell lines that have a more epithelial-like appearance and are more sensitive to WNT signals tend to express higher levels of LGR6 than cell lines that have a more mesenchymal-like appearance and are less responsive to WNT signals. Moreover, the researchers showed that adding RSPOs to the culture medium increased LGR6 expression in the epithelial-like cell lines, suggesting that there is a positive feedback loop between LGR6 and WNT signaling.

To investigate the functional role of LGR6 in pancreatic cancer, the researchers used small interfering RNAs (siRNAs) to knock down its expression in two epithelial-like cell lines. They found that reducing LGR6 levels decreased the activation of WNT signaling, as measured by the expression of WNT target genes and the accumulation of β-catenin, a key mediator of WNT signals. It is important to note that β-catenin is also a key mediator of epithelial–mesenchymal transition (EMT) — a process by which epithelial cells disconnect from each other and transdifferentiate into mesenchymal cells. Furthermore, the researchers observed that knocking down LGR6 impaired the ability of PDAC cells to form colonies in soft agar, a measure of their tumorigenic potential. It also reduced their capacity to form spheres in suspension, a measure of their stemness or self-renewal ability.

“Taken together, we present new evidence in PDAC that LGR6 might be a novel WNT target gene in this tumor. LGR6 seems to be involved in EMT and cancer stemness.”

Conclusions

This study sheds new light on the molecular mechanisms that modulate WNT signaling in pancreatic cancer and reveals a novel role for LGR6 as a WNT enhancer. Their results suggest that LGR6 is an important regulator of WNT signaling and stemness in pancreatic cancer cells, especially those with an epithelial phenotype. The authors propose that LGR6 may act as a switch that amplifies WNT signals in response to RSPOs, thereby enhancing the malignant properties of pancreatic cancer cells. They also speculate that LGR6 may have potential value for treatment stratification of pancreatic cancer patients, as its expression may indicate the responsiveness of tumors to therapies targeting WNT signaling.

“This knowledge could be applicable for detection and treatment of special subsets of pancreatic cancer cells. Further research is still needed to dissect the exact mechanisms under physiological as well as pathological conditions of benign and cancerous pancreatic cells.”

Click here to read the full study published in Aging.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

Rapamycin’s Therapeutic Potential in Treating Werner Syndrome

In this new study, researchers from Japan investigated the molecular mechanisms of subcutaneous fat dysfunction in Werner syndrome.

Between 1904 and 2008, researchers found that approximately 75% of patients with Werner syndrome (WS) worldwide were of Japanese descent. WS is a rare genetic disorder that causes premature aging and increases the risk of various age-related diseases, such as diabetes, cardiovascular disease and cancer. One of the hallmarks of WS is the loss of subcutaneous fat, which is the layer of fat under the skin that helps regulate body temperature and store energy. Subcutaneous fat loss leads to severe insulin resistance, which means that the body cannot use glucose effectively and has high blood sugar levels. But what causes subcutaneous fat loss in WS? And how does it affect the metabolism and health of WS patients? 

In a new study, researchers Daisuke Sawada, Hisaya Kato, Hiyori Kaneko, Daisuke Kinoshita, Shinichiro Funayama, Takuya Minamizuka, Atsushi Takasaki, Katsushi Igarashi, Masaya Koshizaka, Aki Takada-Watanabe, Rito Nakamura, Kazuto Aono, Ayano Yamaguchi, Naoya Teramoto, Yukari Maeda, Tomohiro Ohno, Aiko Hayashi, Kana Ide, Shintaro Ide, Mayumi Shoji, Takumi Kitamoto, Yusuke Endo, Hideyuki Ogata, Yoshitaka Kubota, Nobuyuki Mitsukawa, Atsushi Iwama, Yasuo Ouchi, Naoya Takayama, Koji Eto, Katsunori Fujii, Tomozumi Takatani, Tadashi Shiohama, Hiromichi Hamada, Yoshiro Maezawa, and Koutaro Yokote from Chiba University Graduate School of Medicine, Chiba University Hospital, Kazusa DNA Research Institute, The University of Tokyo, Kyoto University, and International University of Welfare and Health School of Medicine aimed to shed light on these questions by investigating the molecular mechanisms of subcutaneous fat dysfunction in WS. On October 3, 2023, their research paper was published in Aging’s Volume 15, Issue 19, entitled, “Senescence-associated inflammation and inhibition of adipogenesis in subcutaneous fat in Werner syndrome.”

“[…] research on WS is important as it can provide insights into the pathogenesis and development of treatments not only for WS but also for general age-related diseases [5].”

The Study

The researchers analyzed subcutaneous fat samples from four Japanese patients with WS and compared them with samples from healthy individuals. They found that WS subcutaneous fat cells showed signs of cellular senescence, which is a state of irreversible growth arrest that occurs when cells are exposed to stress or damage. Senescent cells secrete inflammatory molecules that can harm neighboring cells and tissues, known as senescence-associated secretory phenotype, or SASP.

The study also revealed that WS subcutaneous fat cells had impaired adipogenesis, which is the ability to differentiate into mature fat cells that can store lipids and secrete hormones. This was associated with reduced expression of genes involved in insulin signaling and lipid metabolism, such as IRS1, PI3K, AKT, and SREBP1. Moreover, the researchers found that rapamycin, a drug that inhibits a protein called mTOR that regulates cell growth and metabolism, could partially restore insulin signaling and adipogenesis in WS subcutaneous fat cells.

“These results suggest that rapamycin rescues cellular senescence and insulin resistance in WSVF [WS subcutaneous adipose tissues], and extends the lifespan of the WS model in vivo.”

Their findings suggest that senescence-associated inflammation and inhibition of adipogenesis play a role in subcutaneous fat reduction and dysfunction in WS, which may contribute to insulin resistance and metabolic disorders. This study also provides evidence that targeting mTOR with rapamycin or other drugs may have therapeutic potential for improving subcutaneous fat function and metabolic health in WS patients.

Conclusions

This study is one of the first to explore the molecular mechanisms of subcutaneous fat dysfunction in WS using human samples. It adds to the growing body of research on the role of senescence and inflammation in aging and age-related diseases. It also highlights the importance of subcutaneous fat as a key metabolic organ that affects not only body shape but also systemic health.

“Rapamycin, an inhibitor of the mammalian target of rapamycin (mTOR), alleviated premature cellular senescence, rescued the decrease in insulin signaling, and extended the lifespan of WS model of C. elegans. To the best of our knowledge, this study is the first to reveal the critical role of cellular senescence in subcutaneous lipoatrophy and severe insulin resistance in WS, highlighting the therapeutic potential of rapamycin for this disease.”

Click here to read the full study published in Aging.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

How Cognitive Reserve Can Help You Sleep Better and Think Sharper

In a new study, researchers investigated the association between sleep, cognitive reserve and cognition in older adults.

Sleep is vital for our health and well-being, but as we age, we tend to experience less and less of it. In particular, we lose some of the deep sleep stages, known as slow wave sleep (SWS), that are crucial for memory consolidation and brain maintenance. This can affect cognitive performance and increase our risk of developing dementia.

Not everyone is equally vulnerable to the negative effects of poor sleep quality. Some people seem to be more resilient and able to cope with less SWS without compromising their mental abilities. What makes them different? One possible factor is cognitive reserve (CR).

CR is a concept that refers to the brain’s ability to adapt and compensate for age-related changes or brain damage. It is influenced by various aspects of our life experiences, such as education, occupation, leisure activities, social interactions, and mental stimulation. People with higher CR are thought to have more efficient brain networks, more cognitive strategies, and more brain reserve (i.e., more neurons and connections) that can buffer the impact of aging or pathology on cognition.

In a new study, researchers Valentin Ourry, Stéphane Rehel, Claire André, Alison Mary, Léo Paly, Marion Delarue, Florence Requier, Anne Hendy, Fabienne Collette, Natalie L. Marchant, Francesca Felisatti, Cassandre Palix, Denis Vivien, Vincent de la Sayette, Gaël Chételat, Julie Gonneaud, and Géraldine Rauchs from Normandie University, UNI – ULB Neuroscience Institute, University of Liege, University College London, and CHU de Caen aimed to identify individuals in whom sleep disturbances might have greater behavioral consequences. On September 28, 2023, their research paper was published in Aging’s Volume 15, Issue 18, entitled, “Effect of cognitive reserve on the association between slow wave sleep and cognition in community-dwelling older adults.”

The Study

The researchers investigated whether CR could modulate the association between SWS and cognition in older adults. The researchers recruited 135 cognitively intact older adults (mean age: 69.4 years) from the Age-Well randomized controlled trial and measured their sleep quality using polysomnography — a technique that records brain waves, eye movements, muscle activity, and other physiological signals during sleep. They also assessed their cognitive performance using neuropsychological tests that evaluated executive function (i.e., the ability to plan, organize, monitor, and control one’s behavior) and episodic memory (i.e., the ability to remember personal events and experiences).

To estimate CR, the researchers used two measures of cognitive engagement throughout life: a questionnaire that asked about the frequency and diversity of participation in various activities (such as reading, playing games, learning languages, etc.) in different age periods; and a composite score based on the highest level of education attained, the complexity of the main occupation held, and the current cognitive activity level.

The results showed that SWS was positively associated with episodic memory performance, meaning that participants who had more SWS tended to have better memory scores. However, this association was not observed for executive function performance. CR proxies modulated the associations between SWS and both executive and episodic memory performance. Specifically, participants with higher CR were able to maintain cognitive performance despite low amounts of SWS, whereas participants with lower CR showed a steeper decline in performance as SWS decreased.

“This study provides the first evidence that CR may protect against the deleterious effects of age-related sleep changes on cognition.”

Conclusions

The study suggests that engaging in cognitively stimulating activities throughout life may enhance one’s ability to cope with less SWS without compromising one’s mental abilities. It also highlights the importance of considering individual differences in CR when evaluating the impact of sleep quality on cognition in older adults.

The authors were forthcoming about limitations of their study, such as the cross-sectional design that does not allow causal inferences, the relatively small sample size that limits the generalizability of the findings, and the use of proxy measures that may not capture all aspects of CR. They also point out some directions for future research, such as exploring the underlying mechanisms of how CR influences sleep-cognition relationships, examining whether CR can also modulate the effects of other sleep parameters (such as sleep duration or fragmentation) on cognition, and investigating whether interventions that target sleep quality or CR can improve cognitive outcomes in older adults.

In conclusion, this study suggests that CR may be an important factor that can help us sleep better and think sharper as we age. It also encourages us to keep our brains active and challenged throughout our lives, as this may benefit not only our cognitive functioning but also our sleep quality.

“These findings are important to understand the factors promoting successful aging and suggest that the deleterious impact of sleep disturbances could be counteracted by an enriched lifestyle. This will help to design non-pharmacological interventions to promote successful aging and counter age-related sleep changes.”

Click here to read the full study published in Aging.

Interested in reading more about cognitive reserve and aging? Click here.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

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For media inquiries, please contact [email protected].

The Role of R-loops in Neuronal Aging

In a new editorial, researcher Hana Hall discusses the role of R-loops in neuronal aging and neurodegeneration. 

R-loops are structures that form when the nascent RNA hybridizes with the template DNA strand, displacing the non-template strand. In other words, R-loops are like temporary tangles in our DNA where a new RNA molecule forms by copying one of the DNA strands and pushes aside the other DNA strand. Nascent RNA refers to the newly synthesized RNA molecule that is produced during the process of transcription. In addition to transcription, R-loops are involved in various biological processes, such as splicing, DNA repair and chromatin remodeling. However, when R-loop homeostasis is disrupted, they can also cause transcriptional impairment, genome instability and cellular dysfunction.

“R-loops have been shown and studied in a wide range of organisms and while they have important regulatory roles, persistent R-loops can be detrimental to cell function and survival, having been closely linked to both gene expression dysregulation and increased genome instability.”

In a new editorial paper, researcher Hana Hall from the Purdue Institute for Integrative Neuroscience at Purdue University discusses the role of R-loops in neuronal aging and neurodegeneration. On September 13, 2023, her editorial was published in Aging’s Volume 15, Issue 17, and entitled, “R-loops in neuronal aging.” Hall summarizes her recent study and the current knowledge on how R-loop levels change during aging, how they affect gene expression and neuronal function, and how they are regulated by different factors.

“In our recent study, we demonstrated that R-loops accumulate in fly PR [photoreceptor] neurons by middle age and significantly increase into late-life stages [5].”

The Editorial

According to Hall, R-loop levels increase with age in different organisms and tissues, including neurons. This could be due to several reasons, such as reduced expression or activity of R-loop resolving enzymes (e.g., Top3β, RNase H1), increased transcriptional activity or stress, or impaired DNA repair mechanisms. Hall also highlighted that R-loop accumulation is associated with decreased expression of long and highly expressed genes, which are enriched for neuronal functions. This could lead to impaired neuronal activity and communication, as well as increased vulnerability to neurodegenerative diseases.

“Our study provides first evidence of R-loop accumulation in aging neurons and a contributing role in loss of neuronal function during aging.”

Hall further discussed how R-loop homeostasis is modulated by various factors, such as chromatin structure, epigenetic modifications, RNA-binding proteins, and non-coding RNAs. She also mentioned some potential therapeutic strategies to restore R-loop balance in aging neurons, such as overexpressing or delivering R-loop resolving enzymes, modulating chromatin accessibility or targeting specific R-loop forming genes.

Conclusions

Hall concluded that R-loops are important players in neuronal aging and neurodegeneration, and that more studies are needed to understand their molecular mechanisms and functional consequences. She also suggested that R-loop mapping could be used as a biomarker to monitor neuronal health and disease progression. This editorial provides a comprehensive overview of the current knowledge of R-loops in neuronal aging, and highlights the challenges and opportunities for future research. 

“Undoubtedly, R-loops are at the crossroads of several hallmarks of aging, namely transcriptional stress, genome instability, and chronic immune response. Targeting R-loop levels thus may help restore these pathways to a normal/healthy state and slow down or prevent the onset of age-dependent neurodegenerative diseases.”

Click here to read the full editorial published in Aging.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

The Impact of Age on Melanoma: Insights from Recent Research

In a new editorial, researchers delve into the intricate dynamics of melanoma and aim to illuminate differences in age-related incidence, prognosis and treatment.

In the realm of cancer research, one persistent trend has emerged — the incidence of invasive melanoma rises steadily with advancing age. While this insidious disease remains rare in children and adolescents, it progressively asserts its presence as individuals grow older. The connection between age and melanoma incidence persists around the world, albeit with varying rates in different countries. 

Australia has the highest melanoma rates in the world. According to the Melanoma Institute Australia, every 30 minutes an Australian is diagnosed with melanoma and every 6 hours an Australian dies from it. Thankfully, research is making a difference. In the last decade, the 5-year overall survival rate for advanced melanoma has increased from less than 10% to more than 50%. In 2011, melanoma was Australia’s 7th most deadly cancer. In 2021, melanoma was Australia’s 11th most deadly cancer.

Figure 1. Melanoma incidence (A) and mortality (B) according to age [2].

In a new editorial paper, researchers John F. Thompson and Gabrielle J. Williams from the Melanoma Institute Australia at The University of Sydney discuss the intricacies of how age influences different varieties of melanoma incidence, prognosis and treatment. On August 17, 2023, their editorial was published in Aging’s Volume 15, Issue 16, entitled, “The effect of age on melanoma incidence and prognosis.”

Understanding Melanoma Subtypes

The researchers point out that while invasive melanoma is at the forefront of discussion, non-invasive “melanoma in situ” (MIS) follows a similar age-related pattern of increase. MIS, often exemplified by lentigo maligna (LM), results from chronic, accumulated exposure to ultraviolet light. The progression from LM to invasive lentigo maligna melanoma (LMM) occurs at an estimated rate of 3.5% per year, with an average transition period of 28.3 years.

Older patients are more prone to another unique subtype known as desmoplastic melanoma, linked to chronic sun exposure and frequently affects the head or neck. While desmoplastic melanomas have a somewhat higher local recurrence rate, the majority of invasive melanomas in elderly patients exhibit features associated with poorer prognosis, including ulceration, higher mitotic rates and increased Breslow thickness.

Melanoma Biopsies & Treatment Options

Patients with high-risk primary melanomas are often recommended for a sentinel lymph node biopsy (SLNB) to assess the presence of metastatic melanoma cells in regional lymph nodes—a pivotal prognostic factor. Strikingly, the likelihood of a positive SLNB result decreases with age. However, as age advances, the risk of death due to melanoma’s spread to distant sites increases, leaving researchers grappling with the mysteries of why these phenomena occur.

Current treatments for SLN-positive melanoma patients include immunotherapy and targeted therapy. Immunotherapy agents like ipilimumab, pembrolizumab and nivolumab have shown promise in treating melanoma. While initial clinical trials excluded the very young and elderly, subsequent non-randomized studies have revealed that these agents are similarly effective in older patients, with comparable adverse event profiles. However, the efficacy of these therapies in children and adolescents remains uncertain.

Targeted therapies focusing on BRAF mutations, including vemurafenib and dabrafenib, have been employed, particularly in younger patients who exhibit a higher prevalence of BRAF positivity. Response rates are significant but often followed by resistance. Interestingly, these therapies appear to exhibit similar efficacy and safety profiles in older patients, offering a glimmer of hope for this demographic.

In older melanoma patients with brain metastases, radiation therapy has historically played a crucial role, offering alternatives to surgical excision. Studies have revealed that both whole-brain radiotherapy and stereotactic radiotherapy are equally effective in patients aged 70-90 as in younger groups. With the advent of immunotherapy and targeted therapies, combining localized radiation with systemic treatment is becoming an option, particularly in older patients, offering the potential for similar benefits as seen in younger cohorts.

Conclusions & Future Directions

The data presented in this editorial underscore a stark reality — melanoma’s impact escalates with age. Patterns of the disease differ significantly in older age groups, with increasing rates of metastasis and death. However, standard forms of melanoma management, including surgery, radiation therapy and newer systemic therapies, have proven to be as effective and safe in older patients as in their younger counterparts. This knowledge serves as a beacon of hope, offering solace and potential avenues for treatment in the face of this disease.

In closing, the critical role of research and continued investigation cannot be overstated. Further exploration of age-related nuances in melanoma will undoubtedly uncover new insights and lead to more tailored and effective treatments for all patients, regardless of their age.

Click here to read the full editorial published in Aging.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

Dry Eyes? It May be Immune Infiltration in Aging Lacrimal Glands

In a new editorial, researchers from Baylor College of Medicine artfully discuss the immune system’s role in dry eye disease. 

The lacrimal gland, found in the upper outer part of the eye’s hollow area, is an important gland that makes tears to protect the eye from infections. It’s split into two parts: one near the inside of the eyelid that can be seen when the eyelid is flipped, and another part with ducts lower in the eye that connects to its counterpart. In their fully functioning status, these ducts release fluid onto the surface of the eye. As humans age (especially women), the lacrimal gland gradually becomes infiltrated by aberrant immune cells and can ultimately lead to an uncomfortable condition known as dry eye disease.

“Burning and redness in the eyes, grittiness and blurry vision make life miserable and currently, eye drops with a variety of lubricant components and in the most severe cases, immunosuppressors, are the only therapies approved for this disease.”

In a well-written new editorial paper, researchers Claudia M. Trujillo-Vargas and Cintia S. de Paiva from the Department of Ophthalmology at Baylor College of Medicine artfully discuss their recent studies which shed light on the immune system’s role in dry eye disease. On August 11, 2023, their editorial was published in Aging’s Volume 15, Issue 15, entitled, “Our search of immune invaders in the aged lacrimal gland.”

Editorial Summary

The authors write that their research group has been dedicated to investigating the changes that occur in the lacrimal gland due to aging and focus on immunopathological alterations. Due to limited human samples, their studies have centered on understanding the infiltration of lymphocytes, specifically B and T cells, in aged mice’s lacrimal glands. This infiltration has been linked to increased dysfunction of the ocular surface. 

“In the search of mechanisms that can counteract the effects of the overwhelming immune infiltration, we started characterizing one of the main players of immune tolerance, the thymic-derived T regulatory cells (Tregs).”

The researchers and their team have a particular interest in thymic-derived T regulatory cells (Tregs), which play a key role in immune tolerance. Paradoxically, in the aged glands, these Tregs, while exhibiting markers for their suppressive function, display heightened differentiation, infiltrate the tissue, produce inflammatory cytokines, and demonstrate impaired suppressive capabilities. When transferred to immunodeficient recipients, these dysfunctional Tregs replicate lacrimal gland pathology. 

Aged lacrimal glands contain highly differentiated CD4+ T cells of the Th1 and Th17 phenotypes, which exhibit exhaustion and immunopathological features. This environment hampers Tregs’ ability to suppress immune responses. There’s also an increase in naïve CD4+ T cells and IgD+ B cells, suggesting a unique environment for the recruitment of inexperienced immune cells in the gland.

Ectopic lymphoid structures, resembling those found in aged tissues, are observed in the lacrimal gland, potentially contributing to immune dysregulation. Despite the concept of immune cells being unwelcome invaders, the lacrimal gland relies on immune cell influx for surveillance purposes, as it is highly vascularized. Nonetheless, with age, immune cell infiltration intensifies, accompanied by fibrosis, duct issues and gland atrophy. Interestingly, antigen-presenting cells diminish, adding to the peculiar immune environment.

In their running analogy to the movie “Men in Black,” the researchers explain that they are seeking effective therapies, akin to the “noisy crickets,” to combat this pathological immune infiltration. They’re investigating differentially expressed genes in the aged gland, focusing on Tregs expressing Il1r2, CD81 and Tbx21, and B cells showing increased CD79a/b expression. The researchers are also exploring the gut microbiota’s role in ocular barrier disruption and dry eye disease in mice. This could lead to more cost-effective microbial treatments for dry eye disease in humans. However, the effectiveness of these therapies in impeding lymphocyte infiltration in aged lacrimal glands remains uncertain.

Conclusions & Future Directions

In conclusion, their editorial provides valuable insights into the role of the lacrimal gland in the immune system and how it could be used to develop new treatments for dry eyes and other age-related eye diseases. The authors’ research has shown that aged lacrimal glands are infiltrated not only by highly differentiated B but also T cells. This landscape is associated with increased ocular surface dysfunction. The authors suggest that this information could be used to develop new therapies for age-related eye diseases.

Considering the rising pollution and screen dependence in the past decade, the researchers predict an increase in severely damaged lacrimal glands in the elderly. This environment could foster the development of ectopic lymphoid structures, potentially leading to a higher prevalence of dry eye disease. As such, interventions will be required to mitigate the immune damage to the lacrimal gland. Ultimately, protecting the lacrimal glands from the consequences of immune dysregulation is a critical goal.

“Unquestionably, more than ‘fancy sunglasses’ would be needed to hinder the ‘carbonizing’ immune damage in the gland. Thus, Yes! We certainly need to protect our lacrimal glands from the scum of our own immune universe!”

Click here to read the full editorial published in Aging.

Aging is an open-access, traditional, peer-reviewed journal that has published high-impact papers in all fields of aging research since 2009. All papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

Navigating the Frailty Factor in Atrial Fibrillation Management

In a new editorial, researchers discuss the impact of frailty on clinical decision-making in managing patients with atrial fibrillation and the prescription of oral anticoagulants.

Atrial fibrillation (AF) is a type of heart arrhythmia that occurs when the ​​heart’s electrical signals become irregular. This condition can increase the risk of stroke and heart failure, and becomes more common in older adults. Frailty is another condition that coincides with aging. Frailty encompasses an accumulation of deficits and can be defined as decreased physical function and resilience. For a significant proportion of the elderly population, both of these conditions coexist. This convergence can lead to additional health issues and further complicate the clinical landscape for aging individuals. 

“The impact of frailty on outcomes has not been previously well characterized in populations with AF.”

Studies on frailty and its overall impact on patients with AF are needed. In a new editorial paper, researchers Stephanie L. Harrison, Søren P. Johnsen and Gregory Y.H. Lip from Liverpool John Moores University and Liverpool Heart and Chest Hospital discuss some of the existing studies assessing frailty and AF in terms of patient outcomes and clinical decision-making. The researchers also discuss recommendations for clinical management of AF and frailty patients and include suggestions for future studies. On July 19, 2023, their editorial was published in Aging’s Volume 15, Issue 14, entitled, “The impact of frailty on the management of atrial fibrillation.”

Oral Anticoagulants for AF With Frailty: Yay or Nay?

Oral anticoagulants (OACs) are often prescribed to AF patients, as OACs aid in reducing blood clots and the risk of stroke. However, frailty patients are more susceptible to falls and therefore, more susceptible to bleeding risk. The prevention of blood clots is less than ideal for wound healing and can lead to impaired tissue repair, increased risk of infection and prolonged recovery times. Has frailty status impacted clinical decision-making when it comes to the prescription of OACs for AF patients?

“The impact of frailty on clinical decision making for managing patients with AF such as the prescription of oral anticoagulants (OACs) is unclear.”

In an effort to begin answering this question, the authors of this editorial reviewed a number of studies on frailty and AF. Some cross-sectional analyses revealed a significant association between frailty status and the prescription of OACs, while other studies found no such association. The authors explain that these dueling results may be due to differences in study populations, the tools/methods used to assess frailty and the timing of when the studies were conducted. The prescription of anticoagulants increased when a new class of OACs was introduced to the market.

Non-vitamin K antagonist oral anticoagulants (NOACs) were first introduced in the early 2010s. They are a class of drugs with significant advantages over traditional OACs, including less off-target effects, more predictable pharmacokinetics and a more targeted mechanism of action — making them a safer option for use in combination with other drugs. Notably, certain NOACs have specific reversal agents available, which can be used to rapidly reverse their anticoagulant effect in case of emergency. International guidelines recommended their use as a first-line treatment to reduce the risk of stroke in AF patients.

“Frailty alone should not be reason to withhold oral anticoagulation in patients with AF. In patients with frailty, the benefits of oral anticoagulation outweigh the small absolute risk of bleeding [6].”

Conclusions & Future Directions

The authors close the editorial by stating that additional research is needed to understand how frailty impacts clinical decision-making for the management of atrial fibrillation. They strongly suggest that frailty not be the sole reason AF patients are not prescribed potentially life-saving oral anticoagulants. There are more sensitive options available today, such as NOACs, that can potentially mitigate the drawbacks of anticoagulants for people with frailty. The authors also emphasize that pre-frailty assessments should be conducted for AF patients in order to reduce treatment risk and optimize the management of this condition.

“Assessment of pre-frailty in patients with AF and the development of strategies to address potentially modifiable components of pre-frailty to reduce the risk of frailty progression could have important implications to optimize care.”

Click here to read the full editorial published in Aging.

Aging is an open-access, peer-reviewed journal that has been publishing high-impact papers in all fields of aging research since 2009. These papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

Exploring the Impact of Cognitive Reserve on Cognitive Resilience

In a new editorial, researchers discuss their recent study investigating the effect that cognitive reserve has on brain integrity and cognitive resilience.

Why do some individuals maintain cognitive abilities throughout their lifespan and others do not? The better question may be: How can certain individuals preserve their cognitive abilities and delay the onset of dementia despite the presence of significant neuropathologies that would otherwise suggest cognitive decline? This question remains unanswered.

“What contributes to this ‘resilience’ [3], that is why some successfully cope with progressive neuropathology while others cannot tolerate the same level of neurodegeneration, is not fully understood.”

This unanswered question has driven researchers to consider the idea of “cognitive reserve.” The rather new concept of cognitive reserve suggests that certain factors, such as engaging in education, mental stimulation and challenging activities, can create a buffer against cognitive decline and delay the onset of cognitive impairment or dementia. Researchers continue to study cognitive reserve to better understand its mechanisms and potential implications for maintaining brain health and designing effective interventions.

In a new editorial paper, researchers Monica E. Nelson, Ross Andel and Jakub Hort from the University of South Florida’s​​ School of Aging Studies discussed the outcomes, lessons and future implications of their previous 2022 study. The team examined the influence of cognitive reserve proxies on the relationship between brain integrity and cognition. On July 14, 2023, their editorial was published in Aging’s Volume 15, Issue 13, entitled, “Cognitive reserve, neuropathology, and progression towards Alzheimer’s disease.”

Cognitive Reserve’s Effect on Brain Integrity and Cognitive Performance

In their 2022 study, a total 570 older adult participants were assessed from the Czech Brain Aging Study (a longitudinal cohort study from two memory clinics in the Czech Republic). Most of the participants (n = 457) were without dementia (including those with subjective cognitive decline and amnestic mild cognitive impairment) and the remaining participants were with dementia syndrome (n = 113). The researchers examined the influence of education and occupational position (cognitive reserve proxies) on the relationship between the participants’ hippocampal or total gray matter volume and cognitive performance. Measurements included brain volume, executive control, language, memory, attention/working memory, and visuospatial skills.

“[…] we assessed the inter-link between cognitive reserve, neuropathology, and cognitive functioning among participants with subjective cognitive decline, mild cognitive impairment, and dementia.”

The team found that the association between brain volume and cognitive performance varies based on cognitive reserve. Findings showed that a higher education and occupational position magnified the associations between brain volume and cognitive performance in participants without dementia. In participants with dementia, higher education decreased the associations between brain volume and visuospatial skills. Overall, the results showed that cognitive reserve affects the relationship between brain volume and cognitive performance, with greater cognitive reserve related to a stronger link before dementia diagnosis and a weaker link after.

Future Directions 

In their subsequent editorial, the researchers were forthcoming about limitations of this study and addressed key opportunities for future studies. Limitations were identified as the use of a relatively homogeneous sample population, the absence of the use of biomarkers in diagnosis and the cross sectional design. Cross-sectional studies may not fully capture disease-related changes in neuropathology and could present a distorted view of the linkages between cognitive reserve, neuropathology and cognitive outcomes. The authors advocate for conducting longitudinal studies to track how cognitive reserve operates in individuals as they progress from normal to dementia. 

Additionally, the team wrote that future studies would be improved by investigating a range of Alzheimer’s disease biomarkers, such as beta-amyloid and tau, individually and together, to understand how they influence the associations between cognitive reserve, brain health and cognition. Different biomarkers may lead to varied results in how cognitive reserve moderates these associations. And finally, future studies should also assess older adults across the cognitive spectrum to determine when cognitive reserve is protective against brain health decline and neuropathology, and when its effectiveness diminishes. Some researchers have suggested a U-shaped relationship to explain mixed findings in different studies.

“Even though our study represents one of the first to come from Eastern Europe [4], future work should be conducted in additional populations, representing geographic, racial, and socioeconomic diversity.”

Implications

The potential impact of this research may be important, as it could lead to the development of effective interventions and strategies to preserve cognitive abilities and delay the onset of dementia. By gaining a deeper understanding of cognitive reserve and its mechanisms, we can take steps to promote brain health throughout life, potentially reducing the burden of dementia on individuals, communities and society overall.

As research continues in this field, it is clear that cognitive reserve holds great promise for unlocking the secrets of cognitive resilience and paving the way for healthier aging and improved quality of life for older adults. By addressing the limitations of current studies and exploring new avenues of investigation, we move closer to finding answers to the vital question of how some individuals maintain their cognitive abilities despite the presence of significant neuropathologies, while others do not.

“By assessing cognitive reserve in distinct populations, a more complete understanding of how cognitive reserve relates to neuropathology and cognition and whether these associations may be affected by distinct macro-level contextual differences among populations can be established. Disentangling these complex relationships may provide a critical step in reducing the impact of dementia on society.”

Click here to read the full editorial published by Aging.

Aging is an open-access, peer-reviewed journal that has been publishing high-impact papers in all fields of aging research since 2009. These papers are available to readers (at no cost and free of subscription barriers) in bi-monthly issues at Aging-US.com.

Click here to subscribe to Aging publication updates.

For media inquiries, please contact [email protected].

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