BUFFALO, NY — January 5, 2026 — A new #research paper featured as the #cover of Volume 17, Issue 12 of Aging-US was #published on December 22, 2025, titled “A combination of differential expression and network connectivity analyses identifies a common set of RNA splicing and processing genes altered with age across human tissues.”
In this study by Caio M.P.F. Batalha from the University of São Paulo, André Fujita from the University of São Paulo and Kyushu University, and Nadja C. de Souza-Pinto also from the University of São Paulo, researchers investigated how gene activity changes with age across multiple human tissues. They found that many tissues share common aging-related alterations in genes involved in RNA splicing and RNA processing. These findings are important because RNA processing is essential for accurate protein production, and disruptions in this process are linked to aging and disease.
Aging affects all tissues, yet identifying molecular changes that are shared across the body has remained challenging. To address this, researchers moved beyond traditional approaches that focus exclusively on changes in gene expression levels. They also analyzed how genes alter their patterns of interaction within regulatory networks, capturing age-related changes that are not evident from expression data alone.
“Gene expression data (in TPM – transcripts per million) were obtained from the Genotype-Tissue Expression (GTEx) project.”
Using RNA sequencing data from nearly one thousand human donors aged 20 to 70, the research team analyzed eight tissues, including blood, brain, heart, skin, and muscle. The results showed that many aging-related changes become evident only when gene network behavior is considered. When gene expression and network connectivity were analyzed together, a consistent group of genes emerged across tissues, most of which were linked to RNA splicing and RNA processing, key steps in the production of functional proteins.
The study also revealed that these RNA-related genes are highly interconnected at the protein level. Many of them form known protein complexes, including components of the spliceosome, which plays a central role in RNA maturation. With age, the interactions among these genes tend to reorganize in similar ways across tissues, pointing to a shared biological response rather than independent, tissue-specific effects.
In addition to RNA processing, the researchers observed age-related changes in pathways involved in managing damaged RNAs and proteins, including protein degradation, autophagy, and DNA damage response mechanisms. These pathways support cellular quality control and help limit the accumulation of molecular errors that increase with age.
Overall, this study identifies RNA splicing and RNA processing as central, conserved features of human aging across tissues. It also demonstrates that network-based approaches provide a more complete view of the aging transcriptome, offering new insights into age-related biological changes and potential directions for aging research.
DOI - https://doi.org/10.18632/aging.206347
Corresponding author - Nadja C. de Souza-Pinto - nadja@iq.usp.br
Abstract video - https://www.youtube.com/watch?v=A1slKwaSd6g
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BUFFALO, NY — January 5, 2026 — A new #research paper featured as the #cover of Volume 17, Issue 12 of Aging-US was #published on December 22, 2025, titled “A combination of differential expression and network connectivity analyses identifies a common set of RNA splicing and processing genes altered with age across human tissues.”
In this study by Caio M.P.F. Batalha from the University of São Paulo, André Fujita from the University of São Paulo and Kyushu University, and Nadja C. de Souza-Pinto also from the University of São Paulo, researchers investigated how gene activity changes with age across multiple human tissues. They found that many tissues share common aging-related alterations in genes involved in RNA splicing and RNA processing. These findings are important because RNA processing is essential for accurate protein production, and disruptions in this process are linked to aging and disease.
Aging affects all tissues, yet identifying molecular changes that are shared across the body has remained challenging. To address this, researchers moved beyond traditional approaches that focus exclusively on changes in gene expression levels. They also analyzed how genes alter their patterns of interaction within regulatory networks, capturing age-related changes that are not evident from expression data alone.
“Gene expression data (in TPM – transcripts per million) were obtained from the Genotype-Tissue Expression (GTEx) project.”
Using RNA sequencing data from nearly one thousand human donors aged 20 to 70, the research team analyzed eight tissues, including blood, brain, heart, skin, and muscle. The results showed that many aging-related changes become evident only when gene network behavior is considered. When gene expression and network connectivity were analyzed together, a consistent group of genes emerged across tissues, most of which were linked to RNA splicing and RNA processing, key steps in the production of functional proteins.
The study also revealed that these RNA-related genes are highly interconnected at the protein level. Many of them form known protein complexes, including components of the spliceosome, which plays a central role in RNA maturation. With age, the interactions among these genes tend to reorganize in similar ways across tissues, pointing to a shared biological response rather than independent, tissue-specific effects.
In addition to RNA processing, the researchers observed age-related changes in pathways involved in managing damaged RNAs and proteins, including protein degradation, autophagy, and DNA damage response mechanisms. These pathways support cellular quality control and help limit the accumulation of molecular errors that increase with age.
Overall, this study identifies RNA splicing and RNA processing as central, conserved features of human aging across tissues. It also demonstrates that network-based approaches provide a more complete view of the aging transcriptome, offering new insights into age-related biological changes and potential directions for aging research.
DOI - https://doi.org/10.18632/aging.206347
Corresponding author - Nadja C. de Souza-Pinto - nadja@iq.usp.br
Abstract video - https://www.youtube.com/watch?v=A1slKwaSd6g
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How Two Russian Scientists Changed the Way We Understand Aging and Cancer
Aging-US
3 minutes 18 seconds
1 month ago
How Two Russian Scientists Changed the Way We Understand Aging and Cancer
BUFFALO, NY — December 3, 2025 — A new #essay was #published in Volume 17, Issue 11 of Aging-US on November 19, 2025, titled “On the intergenerational transfer of ideas in aging and cancer research: from the hypothalamus according to V.M. Dilman to the mTOR protein complex according to M.V. Blagosklonny.”
In this work, Aleksei G. Golubev from the N.N. Petrov National Medical Research Center of Oncology reflects on the legacy of two influential Russian scientists, Vladimir M. Dilman and his son Mikhail V. Blagosklonny, who each introduced groundbreaking ideas about aging and cancer. Drawing from his own experience working in Dilman’s lab, Golubev explores how their ideas remain deeply relevant to today’s scientific understanding.
The essay connects Dilman’s “elevation theory” with Blagosklonny’s “hyperfunction theory,” two frameworks that challenge the conventional view of aging as a process of decline. Instead, both propose that aging results from continued biological processes that once supported growth but eventually become harmful when left unchecked.
Dilman believed that aging begins with reduced sensitivity in the hypothalamus, a brain region that regulates the body’s balance. This desensitization disrupts metabolism and hormone levels, setting the stage for many chronic illnesses. Decades later, Blagosklonny expanded on this idea at the molecular level. Central to his theory is the mTOR protein complex, which regulates growth and metabolism and is now a major focus in aging research.
Golubev also explores the historical and personal connections between the two scientists. Dilman, an endocrinologist trained in the Soviet Union, and Blagosklonny, a molecular biologist educated during the post-Soviet period, represent two generations shaped by a shared scientific tradition.
“Dilman’s scientific legacy is not as well recognized as it should be, partly due to bias in citation practices.”
The essay also draws attention to a troubling trend in science: the tendency to overlook early contributions, especially from non-Western scholars. Many of Dilman’s insights, such as the connection between high blood sugar, insulin resistance, and cancer, have since been validated by modern tools, yet his work is rarely cited. Golubev points out how citation practices, language barriers, and historical isolation have contributed to this lack of recognition.
Finally, Golubev encourages the scientific community to look back and acknowledge the foundational work that shaped modern aging science. It also highlights the importance of cross-generational knowledge in moving science forward. By tracing the intellectual journey from hormonal regulation in the brain to molecular pathways in cells, this essay demonstrated the relevance of old ideas in a new biological era.
DOI - https://doi.org/10.18632/aging.206338
Corresponding author - Aleksei G. Golubev - lxglbv@rambler.ru
Abstract video - https://www.youtube.com/watch?v=LvrdghTKGws
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Keywords - aging, gerontology, history of science, hyperfunction, mTOR, hypothalamus, cancer, metabolism, immunity
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Aging-US
BUFFALO, NY — January 5, 2026 — A new #research paper featured as the #cover of Volume 17, Issue 12 of Aging-US was #published on December 22, 2025, titled “A combination of differential expression and network connectivity analyses identifies a common set of RNA splicing and processing genes altered with age across human tissues.”
In this study by Caio M.P.F. Batalha from the University of São Paulo, André Fujita from the University of São Paulo and Kyushu University, and Nadja C. de Souza-Pinto also from the University of São Paulo, researchers investigated how gene activity changes with age across multiple human tissues. They found that many tissues share common aging-related alterations in genes involved in RNA splicing and RNA processing. These findings are important because RNA processing is essential for accurate protein production, and disruptions in this process are linked to aging and disease.
Aging affects all tissues, yet identifying molecular changes that are shared across the body has remained challenging. To address this, researchers moved beyond traditional approaches that focus exclusively on changes in gene expression levels. They also analyzed how genes alter their patterns of interaction within regulatory networks, capturing age-related changes that are not evident from expression data alone.
“Gene expression data (in TPM – transcripts per million) were obtained from the Genotype-Tissue Expression (GTEx) project.”
Using RNA sequencing data from nearly one thousand human donors aged 20 to 70, the research team analyzed eight tissues, including blood, brain, heart, skin, and muscle. The results showed that many aging-related changes become evident only when gene network behavior is considered. When gene expression and network connectivity were analyzed together, a consistent group of genes emerged across tissues, most of which were linked to RNA splicing and RNA processing, key steps in the production of functional proteins.
The study also revealed that these RNA-related genes are highly interconnected at the protein level. Many of them form known protein complexes, including components of the spliceosome, which plays a central role in RNA maturation. With age, the interactions among these genes tend to reorganize in similar ways across tissues, pointing to a shared biological response rather than independent, tissue-specific effects.
In addition to RNA processing, the researchers observed age-related changes in pathways involved in managing damaged RNAs and proteins, including protein degradation, autophagy, and DNA damage response mechanisms. These pathways support cellular quality control and help limit the accumulation of molecular errors that increase with age.
Overall, this study identifies RNA splicing and RNA processing as central, conserved features of human aging across tissues. It also demonstrates that network-based approaches provide a more complete view of the aging transcriptome, offering new insights into age-related biological changes and potential directions for aging research.
DOI - https://doi.org/10.18632/aging.206347
Corresponding author - Nadja C. de Souza-Pinto - nadja@iq.usp.br
Abstract video - https://www.youtube.com/watch?v=A1slKwaSd6g
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ResearchGate - https://www.researchgate.net/journal/Aging-1945-4589
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