Cellular Senescence and Inflammaging in the Bone: Pathways, Genetics, Anti-Aging Strategies and Interventions
Abstract
:1. Introduction
2. Cellular Senescence and Inflammaging in the Bone
3. Pathways Involved in Senescence and Inflammaging in the Bone
3.1. Cell Cycle Arrest: p16, p21, p53
3.1.1. p16-Rb Pathway
3.1.2. p53-p21 Pathway
3.2. Growth Promotion Pathways—mTOR and, SIRT-1
3.2.1. mTOR
3.2.2. SIRTs
3.3. Reactive Oxygen Species (ROS)-Induced DNA Damage (Type 1 IFN and the STING Pathway)
4. Genetics of Cellular Senescence in the Bone
4.1. Key Genes Associated with SASP
4.2. NGS Studies on Bone Aging
4.3. Potential Pathways to Target in Bone Aging
5. Combatting Senescence in the Bone
5.1. Pharmacological Approaches
5.1.1. Senolytics
5.1.2. Senomorphics
5.1.3. Seno-Inflammation
5.2. Non-Pharmacological Approaches
5.2.1. Materials for Bone Regeneration via Senescence Reduction
5.2.2. Anti-Aging Strategies Using Biologics
5.3. Lifestyle Approaches as Regeneration and Anti-Aging Strategies
Approach | Strategy | Model | Target | Reference |
---|---|---|---|---|
Pharmacological, senolytic | Dasatinib (D) and/or quercetin (Q) | in vitro and in vivo | D- senescent fat progenitors, Q- human endothelial cells and mouse BM MSCs, D + Q—mouse embryonic fibroblasts | [123] |
Pharmacological, senolytic | Dasatinib + Quercetin | in vitro and in vivo | Trabecular and cortical bone in mice | [73] |
Pharmacological, senolytic | ABT263 | In vivo | Senescent bone marrow hematopoietic stem cells in mice | [126] |
Pharmacological, senolytic/senomorphic | Zeldronic acid | In vitro and in vivo | Bone | [185] |
Pharmacological, senomorphic | Ruxolitinib | In vivo | metabolism | [186] |
Non-pharmacological, biomaterial | Shell nacre | In vitro | BM MSCs | [117] |
Non-pharmacological, biomaterial | PEGylated hydrogel with Rapamycin nanomicelles | In vitro and in vivo | BM MSCs | [153] |
Non-pharmacological, biologics | HA v/s PRP in RCT | In vivo | Knee OA | [173] |
Non-pharmacological, biologics | Collagen | In vitro | BM MSCs | [157] |
Non-pharmacological, biologics | PRP | In vitro and in vivo | Injured tendons | [174] |
Lifestyle | Intermittent fasting | In vivo, n = 25 young males | Senescence markers linked with diet and lifestyle | [181] |
Lifestyle | Physical functioning | In vivo, n = 1377 older adults | Senescence biomarkers linked with physical functioning in elderly | [120] |
Lifestyle | Diet + exercise | In vivo, n = 12 young males | Senescent cells in skeletal muscle linked with diet and exercise | [187] |
Lifestyle | Diet + exercise + community | Mixed methods, n = 57 older adults | Nutritional habits and active lifestyle linked with longevity | [182] |
Lifestyle | Sleep deprivation | In vivo, n = 29 older adults | Sleep deprivation linked with senescent markers | [183] |
6. Conclusions, Limitations and Future Directions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Study Summary | NGS Methods | Key Findings | Key Genes with Elevated Expression | Reference |
---|---|---|---|---|
RNA profile expression in eight experimental models of cellular senescence commonly studied. WI-38 and IMR-90 fibroblasts, HUVECs and HAECs were cultured and utilized for downstream sequencing. | RNA seq, Illumina Hiseq 2500 with 2 × 150-bp strategy | 50 elevated and 18 reduced transcripts and the identification of subsets of transcripts (both coding and non-coding) display shared expression patterns across a range of senescent cell models. | SRPX, PURPL (p53 regulator) | [111] |
RNA expression profiling of fibroblasts and their senescence induced by 5-aza identified 3 epigenetically silenced pathways. | Illumina HiSeq 2000; strategy not specified | 5-aza-induced senescence has been closely linked to alterations in the interferon/innate immunity pathway’s gene expression, and during immortalization, important regulators of this pathway are muted. | IL-1α and IL-1β | [112] |
Use of multiple whole-transcriptome datasets, created by the authors or made publicly available, to characterise the heterogeneity of the programmed senescence. | Illumina HiSeq 2000 with 2× 150 bp | Demonstrates that ollowing senescence induction, the senescent phenotype identified for 55 genes at the core of the senescence-associated transcriptome is dynamic, changing at different intervals. | Upregulation of genes associated with G1 DNA damage checkpoint (PLK3 and CCND1) and upregulation of BCL2L2 (negative regulator of apoptosis) | [113] |
Comprehensive analysis of the transcriptome and senolytic responses in a panel of 13 cancer cell lines rendered senescent by two distinct compounds. | HiSeq 2500; single-end 65 bp | Cell lines that were made senescent by two different substances showed that the senescence trigger has less of an impact on the composition of the SASP. The SENCAN gene expression classifier to detect senescence using machine learning was developed. | IL6 and CXCL8 | [114] |
Gene set generation (SenMayo) consisting of 125 previously identified senescence/SASP-associated factors. | HiSeq 2000; strategy not specified | Provided a unique gene set (SenMayo) that can be utilized in bulk and scRNA-seq investigations to detect cells expressing high amounts of senescence/SASP genes. SenMayo rises with aging across tissues and species and is responsive to senescent cell clearance. | CDKN1A/P21Cip1 and several SASP markers such as CCL2 and IL6 showed consistent upregulation with aging | [102] |
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Lawrence, M.; Goyal, A.; Pathak, S.; Ganguly, P. Cellular Senescence and Inflammaging in the Bone: Pathways, Genetics, Anti-Aging Strategies and Interventions. Int. J. Mol. Sci. 2024, 25, 7411. https://doi.org/10.3390/ijms25137411
Lawrence M, Goyal A, Pathak S, Ganguly P. Cellular Senescence and Inflammaging in the Bone: Pathways, Genetics, Anti-Aging Strategies and Interventions. International Journal of Molecular Sciences. 2024; 25(13):7411. https://doi.org/10.3390/ijms25137411
Chicago/Turabian StyleLawrence, Merin, Abhishek Goyal, Shelly Pathak, and Payal Ganguly. 2024. "Cellular Senescence and Inflammaging in the Bone: Pathways, Genetics, Anti-Aging Strategies and Interventions" International Journal of Molecular Sciences 25, no. 13: 7411. https://doi.org/10.3390/ijms25137411
APA StyleLawrence, M., Goyal, A., Pathak, S., & Ganguly, P. (2024). Cellular Senescence and Inflammaging in the Bone: Pathways, Genetics, Anti-Aging Strategies and Interventions. International Journal of Molecular Sciences, 25(13), 7411. https://doi.org/10.3390/ijms25137411