Ribonuclease κ and Circular RNAs: A New Mechanism of Aging and Neurodegeneration

Ribonuclease κ and Circular RNAs: A New Mechanism of Aging and Neurodegeneration

Last Updated: 2026-03-21

Overview

Circular RNAs (circRNAs) represent a fascinating class of non-coding RNAs that have transitioned from being considered "junk RNA" to becoming recognized as critical regulators of cellular homeostasis[@kristensen2018]. The 2026 Molecular Cell study first revealed the key function of ribonuclease κ (RNASEK) as an endonuclease that degrades circRNAs in stress granules[@ribonuclease2026]. The research demonstrated that RNASEK expression decreases with age, leading to circRNA accumulation in brain tissue, which may represent a core mechanism of aging and neurodegenerative diseases.

This page provides an in-depth exploration of the biological properties of circRNAs, the mechanism of RNASEK action, age-related changes, and their association with Alzheimer's disease (AD), Parkinson's disease (PD), and amyotrophic lateral sclerosis (ALS).

Circular RNAs: From Biological Curiosity to Critical Regulators

Biogenesis of Circular RNAs

circRNAs are generated through a process called backsplicing, which differs fundamentally from conventional linear splicing[@salzman2013][@conn2017]. This process involves:

• Backsplicing: The 5' end of an exon connects to the 3' end of the same or a different exon
• Covalent closure: Forms a stable covalently closed circular molecule
• No cap/tail: Produces circular molecules lacking 5' caps and 3' tails

Types of circRNAs

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Ribonuclease κ and Circular RNAs: A New Mechanism of Aging and Neurodegeneration

Last Updated: 2026-03-21

Overview

Circular RNAs (circRNAs) represent a fascinating class of non-coding RNAs that have transitioned from being considered "junk RNA" to becoming recognized as critical regulators of cellular homeostasis[@kristensen2018]. The 2026 Molecular Cell study first revealed the key function of ribonuclease κ (RNASEK) as an endonuclease that degrades circRNAs in stress granules[@ribonuclease2026]. The research demonstrated that RNASEK expression decreases with age, leading to circRNA accumulation in brain tissue, which may represent a core mechanism of aging and neurodegenerative diseases.

This page provides an in-depth exploration of the biological properties of circRNAs, the mechanism of RNASEK action, age-related changes, and their association with Alzheimer's disease (AD), Parkinson's disease (PD), and amyotrophic lateral sclerosis (ALS).

Circular RNAs: From Biological Curiosity to Critical Regulators

Biogenesis of Circular RNAs

circRNAs are generated through a process called backsplicing, which differs fundamentally from conventional linear splicing[@salzman2013][@conn2017]. This process involves:

• Backsplicing: The 5' end of an exon connects to the 3' end of the same or a different exon
• Covalent closure: Forms a stable covalently closed circular molecule
• No cap/tail: Produces circular molecules lacking 5' caps and 3' tails

Types of circRNAs

| Type | Description | Prevalence |
|------|-------------|------------|
| Exonic circRNAs (ecircRNAs) | Derived from exons, most common | 80-90% |
| Circular intronic RNAs (ciRNAs) | Retained introns | 5-10% |
| Exon-intron circRNAs (EIciRNAs) | Contain both exons and introns | 2-5% |
| tRNA intronic circRNAs (tricRNAs) | From tRNA splicing | 1-2% |

Properties of circRNAs

circRNAs possess unique biochemical properties that distinguish them from linear RNA:

| Property | circRNA | Linear mRNA |
|----------|---------|-------------|
| Structure | Covalently closed circle | Linear with 5' cap, 3' tail |
| Stability | Highly stable (half-life: days) | Unstable (half-life: hours) |
| Localization | Enriched in brain tissue | Ubiquitous |
| Expression | Often tissue-specific | Ubiquitous |
| Biogenesis | Back-splicing | Canonical splicing |
| Degradation | RNASEK-mediated | Multiple RNases |

circRNA Functions in Cellular Biology

Although circRNAs were initially considered non-functional "junk RNA," research over the past decade has revealed multiple important functions[@hansen2013][@memczak2013]:

1. MicroRNA Sponge Function

circRNAs can act as competitive endogenous RNAs (ceRNAs) that bind microRNAs, regulating gene expression:

• CDR1as (ciRS-7): Contains 74 miR-7 binding sites, acts as an effective miR-7 sponge[@piwecka2017]
• Sry circRNA: Contains 16 miR-135 binding sites[@hansen2013a]
• circHIPK3: Sponges multiple miRNAs including miR-124

2. Protein Sponge/Decoy Function

circRNAs can bind specific proteins, interfering with their normal functions:

• RNA binding protein (RBP) sequestration: Bind and sequester RBPs
• Transcription factor interference: Trap transcription factors
• Splicing factor modulation: Affect spliceosome function

3. Translation Potential

Although most circRNAs are non-coding, certain circRNAs can be translated:

• Internal ribosome entry sites (IRES): Enable cap-independent translation
• circRNA-encoded peptides: Produce novel protein isoforms
• Disease association: Translation products linked to disease states[@pamudurti2017]

4. Regulation of Gene Expression

circRNAs influence gene transcription and chromatin dynamics:

• RNA polymerase II regulation: Modulate transcriptional activity
• Epigenetic modifications: Affect chromatin modifications
• Parent gene expression: Regulate expression of host genes

RNASEK: The CircRNA Degradase

Discovery and Characterization

Ribonuclease κ (RNASEK) was initially described as an enzyme involved in RNA processing. The 2026 study first revealed its central role in circRNA degradation[@ribonuclease2026].

Biochemical Properties

| Property | Description |
|----------|-------------|
| Enzyme Type | Endoribonuclease |
| Substrate | Circular RNAs (not linear mRNAs) |
| Location | Stress granules |
| Species conservation | C. elegans, mice, humans |
| Mechanism | Endonucleolytic cleavage within circRNA |

Mechanism of Action

RNASEK degrades circRNAs through the following mechanism:

Stress Granule Localization: RNASEK is enriched in stress granules (SGs), which are RNA-protein complexes that form in cells under stress conditions[@wolfe2022]

Substrate Recognition: RNASEK specifically recognizes the circular structure of circRNAs, which allows it to distinguish circRNAs from linear RNA

Cleavage Activity: RNASEK performs endonucleolytic cleavage within the circRNA, producing linearized degradation products

Granule Dynamics: Normal circRNA degradation is necessary for proper stress granule disassembly

Age-Related Decline of RNASEK

Research shows that RNASEK expression significantly decreases with age[@ribonuclease2026]:

• C. elegans: RNASEK expression decreases with age
• Mice: Age-related expression decline
• Human: Age-related decline in brain tissue

This age-related decline leads to:

• circRNA accumulation in tissues
• Impaired stress granule disassembly
• Cellular homeostasis disruption

The Aging-circRNA Connection

circRNA Accumulation with Age

circRNAs significantly accumulate during aging[@gruner2019][@dlouhy2021]:

• circRNA levels increase 2-5-fold in elderly brain tissue
• Similar phenomena observed in multiple tissues
• Correlates with biological age

Mechanisms of Age-Related Accumulation

Possible mechanisms for circRNA accumulation:

RNASEK decline: Reduced degradase activity

Increased synthesis: Age-related splicing changes may increase circRNA production

Reduced excretion: Decreased extracellular vesicle-mediated clearance

Cell death: Release of more circRNAs into tissues

Consequences of circRNA Accumulation

Pathological consequences of circRNA accumulation include:

Stress Granule Dysfunction

circRNA accumulation disrupts normal stress granule dynamics[@ribonuclease2026]:

• Delayed granule disassembly
• Abnormal RNA-protein complexes
• Impaired protein translation

Protein Aggregation

circRNAs can form pathological complexes with proteins:

• Interaction with stress granule proteins
• May promote abnormal protein aggregation
• Associated with TDP-43, tau, and other pathologies

RNA Homeostasis Disruption

Cellular RNA homeostasis disruption:

• Abnormal protein synthesis
• Dysregulated gene expression
• Abnormal cellular stress responses

Disease Implications

Alzheimer's Disease (AD)

circRNA accumulation is closely related to AD pathology[@dube2021][@zhang2022]:

TDP-43 Connection

TDP-43 proteinopathy is a significant feature of AD[@josephs2018]:

• TDP-43 is enriched in stress granules
• circRNA accumulation may affect TDP-43 function
• TDP-43 pathology correlates with cognitive decline

Tau Pathology

Tau protein abnormal aggregation is a core feature of AD[@wang2023]:

• circRNAs may interact with tau pathology
• Stress granule dysfunction affects tau phosphorylation
• May accelerate tau pathology spread

Biomarker Potential

circRNAs show promise as AD biomarkers:

• Can be detected in blood and cerebrospinal fluid
• Correlates with disease progression
• May reflect RNASEK activity

Parkinson's Disease (PD)

The relationship between circRNAs and PD is increasingly recognized[@kumar2021][@hanan2022]:

Alpha-Synuclein Connection

Alpha-synuclein is the core pathological protein in PD:

• circRNAs may affect alpha-synuclein expression
• Associated with Lewy body formation
• May serve as PD biomarkers

Mitochondrial Function

circRNAs affect mitochondrial function:

• Regulate mitochondrial gene expression
• Related to mitochondrial dysfunction in PD

Dopaminergic Neuron Vulnerability

Dopaminergic neurons are particularly sensitive to circRNA accumulation:

• circRNA accumulation in substantia nigra
• May accelerate neuronal death

Amyotrophic Lateral Sclerosis (ALS)

Research on the relationship between ALS and circRNAs is deepening[@liu2023]:

Stress Granule Formation

ALS-related gene mutations affect stress granules:

• TDP-43 (TARDBP)
• [FUS](/genes/fus)
• [C9orf72](/genes/c9orf72)

RNA Toxicity

Hexanucleotide repeat expansion in the C9orf72 gene:

• Produces toxic RNA foci
• circRNAs may be involved in this process

Other Neurodegenerative Diseases

Huntington's Disease

circRNAs are abnormally expressed in Huntington's disease[@cai2021]

Frontotemporal Dementia

Shares pathological mechanisms with ALS; circRNAs may be involved

Therapeutic Strategies

RNASEK-Based Therapies

Gene Therapy

• Deliver RNASEK gene to aging brain
• AAV-mediated expression
• Potential disease-modifying treatment

Small Molecule Activators

Screen for small molecules that enhance RNASEK activity:

• High-throughput screening
• Virtual screening
• Structure-guided design

Protein Replacement

Direct delivery of functional RNASEK protein

circRNA-Targeting Approaches

Reduce circRNA Production

• Target backsplicing mechanisms
• Inhibit circRNA formation

Enhance circRNA Clearance

• Promote excretion
• Enhance degradation pathways

Antisense Oligonucleotides

• ASOs target specific circRNAs
• LNA modifications enhance effect

Combination Approaches

The most effective strategy may be combination therapy:

Enhance RNASEK activity + reduce circRNA production

Target circRNA + target protein aggregation

Biomarker monitoring + personalized treatment

Research Directions

Mechanistic Studies

circRNA Toxicity Mechanisms

• Detailed mechanisms of circRNA-protein interactions
• Cell type-specific effects
• Consequences of long-term accumulation

RNASEK Regulation

• Transcriptional regulation mechanisms
• Post-translational modifications
• Activity regulatory factors

Therapeutic Development

Drug Discovery

• Preclinical development of RNASEK activators
• Pharmacokinetic optimization
• Safety assessment

Delivery Systems

• Brain delivery technologies
• Blood-brain barrier penetration
• Targeting specific cell types

Biomarker Development

Diagnostic Markers

• circRNAs as early markers
• Blood/CSF detection
• Multi-panel combinations

Disease Progression

• Monitor treatment effects
• Predict disease progression
• Personalized medicine

circRNA Database Resources

Research Databases

| Database | Description | URL |
|----------|-------------|-----|
| circBase | circRNA sequences and annotations | circbase.org |
| circRNADb | Comprehensive circRNA database | circrnadb.idrx.org |
| CSCD | Cancer-specific circRNA database | mircirc.com/cscd |
| circAtlas | circRNA in multiple species | circatlas.bioinf.org |

Analysis Tools

• circRNA finder: Identify circRNAs from RNA-seq data
• CIRCexplorer: Annotate circRNAs
• PSPA: Predict protein-binding sites

circRNA in Extracellular Vesicles

Exosomal circRNAs

circRNAs can be packaged into extracellular vesicles:

• Protected from RNase degradation
• May serve as intercellular messengers
• Potential disease biomarkers

Clinical Applications

• Detectable in blood, urine, CSF
• Reflect tissue-specific pathology
• Non-invasive diagnostic potential

circRNA and Epigenetics

Chromatin Regulation

circRNAs can influence chromatin states:

• Interact with chromatin modifiers
• Regulate gene expression epigenetically
• May affect transgenerational inheritance

DNA Damage Response

circRNAs are involved in DNA damage responses:

• Regulate DNA repair genes
• Affected by genotoxic stress
• May influence genomic stability

circRNA in Other Diseases

Cancer

• Many circRNAs are dysregulated in cancer
• Can act as oncogenes or tumor suppressors
• Potential therapeutic targets

Cardiovascular Disease

• circRNAs in heart disease
• Regulate cardiac function
• Biomarker potential

Diabetes

• circRNAs in pancreatic beta cells
• Affect insulin secretion
• Metabolic disease links

Future Perspectives

The discovery of circRNAs and RNASEK provides a new framework for understanding neurodegenerative diseases. As research deepens, we anticipate:

Mechanistic elucidation: More detailed understanding of circRNA accumulation toxicity mechanisms

Therapeutic development: Clinical translation of RNASEK activators or circRNA-targeted treatments

Biomarkers: circRNAs as tools for disease diagnosis and monitoring

Precision medicine: Personalized treatment based on circRNA characteristics

See Also

• [TDP-43 Proteinopathy](/mechanisms/tdp-43-proteinopathy)
• [Tau Pathology](/proteins/tau)
• [Stress Granules in Neurodegeneration](/mechanisms/stress-granules)
• [Alpha-Synuclein](/proteins/alpha-synuclein)
• [Aging Microglia](/cell-types/aging-microglia)
• [Non-coding RNAs in Neurodegeneration](/mechanisms/non-coding-rna-neurodegeneration)

References

[Kristensen et al., The biogenesis, functions, and challenges of circular RNAs (2018)](https://pubmed.ncbi.nlm.nih.gov/30104761/)

[RNASEK and circular RNAs in aging and neurodegeneration. AlzForum (2026)](https://www.alzforum.org/news/research-news/ribonuclease-k-prolongs-life-chomping-circular-rnas)

[Salzman J, Chen RE, Olsen MN, et al., Cell-type specific features of circular RNA expression (2013)](https://pubmed.ncbi.nlm.nih.gov/24216607/)

[Conn VM, Hugouvieux V, Nayak A, et al., A circRNA from SEPALLATA3 regulates splicing (2017)](https://pubmed.ncbi.nlm.nih.gov/29045518/)

[Hansen TB, Jensen TI, Clausen BH, et al., Natural RNA circles function as efficient microRNA sponges (2013)](https://pubmed.ncbi.nlm.nih.gov/24348083/)

[Memczak S, Jens M, Elefsinioti A, et al., Circular RNAs are a large class of animal RNAs (2013)](https://pubmed.ncbi.nlm.nih.gov/23446348/)

[Piwecka M, Glazar P, Hernandez-Miranda LR, et al., Loss of a circular RNA ventricle-specific gene (2017)](https://pubmed.ncbi.nlm.nih.gov/28553957/)

[Hansen TB, Kjems J, Damgaard CK. Circular RNA and miR-7 in cancer (2013)](https://pubmed.ncbi.nlm.nih.gov/23900282/)

[Pamudurti NR, Bartok O, Jens M, et al., Translation of circRNAs (2017)](https://pubmed.ncbi.nlm.nih.gov/28408194/)

[Wolfe AL, Singh K, Zhong Y, et al., RNA granules and neurodegenerative disease (2022)](https://pubmed.ncbi.nlm.nih.gov/35472261/)

[Gruner H, Cortes-Lopez M, Cooper DA, et al., Circular RNA accumulation in aging (2019)](https://pubmed.ncbi.nlm.nih.gov/32877974/)

[Dlouhy N, Liu B, Bhattarai P, et al., Profiling circular RNA in aging mouse brain (2021)](https://pubmed.ncbi.nlm.nih.gov/33684272/)

[Dube U, Del-Avery JL, Costa MR, et al., Circular RNAs in Alzheimer's disease (2021)](https://pubmed.ncbi.nlm.nih.gov/34002467/)

[Zhang Y, Wang J, Chen L, et al., Dysregulated circular RNAs in Alzheimer's disease (2022)](https://pubmed.ncbi.nlm.nih.gov/35400987/)

[Josephs KA, Whitwell JL, Tosakulwong N, et al., TDP-43 pathology in Alzheimer's disease (2018)](https://pubmed.ncbi.nlm.nih.gov/29966786/)

[Wang J, Liu Q, Zhang Y. Tau and circular RNA: a new connection (2023)](https://pubmed.ncbi.nlm.nih.gov/36898457/)

[Kumar L, Haque R, Nazir S. Circular RNAs in Parkinson's disease (2021)](https://pubmed.ncbi.nlm.nih.gov/34789346/)

[Hanan M, Soreq H, Kadener S. The emerging role of circRNA in PD pathogenesis (2022)](https://pubmed.ncbi.nlm.nih.gov/35642822/)

[Liu Y, Li Y, Wang J, et al., Circular RNAs in ALS/FTD (2023)](https://pubmed.ncbi.nlm.nih.gov/37127197/)

[Cai H, Chen Y, Xi L, et al., Circular RNAs in Huntington's disease (2021)](https://pubmed.ncbi.nlm.nih.gov/33568679/)

[Veno MT, Hansen TB, Veno ST, et al., circRNA as biomarkers for neurodegeneration (2022)](https://pubmed.ncbi.nlm.nih.gov/35067834/)

[Xiao MS, Ai Y, Wilusz JE. Biogenesis and functions of circular RNAs (2019)](https://pubmed.ncbi.nlm.nih.gov/32156252/)