Small Noncoding RNAs Contribute to Sperm Oxidative Stress-Induced Programming of Behavioral and Metabolic Phenotypes in Offspring

Ren, Li; Xin, Yining; Sun, Xiaoxiao; Zhang, Yanwen; Chen, Yingqi; Liu, Suyuan; He, Bin

doi:10.1155/2022/6877283

Cited by 4 publications

(2 citation statements)

References 62 publications

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“…In the human, these sperm-borne epigenetic factors include an intact centriole that will orchestrate cell division in the progeny, a critical enzyme (phospholipase C, zeta) that will initiate calcium oscillations in the ooplasm in order to trigger the developmental process, as well as a range of small non-coding RNA species that will ultimately impact the metabolic and behavioural phenotype of the offspring. [1][2][3] Paternally-mediated disruptions to embryonic development occur when the integrity of the paternal genome is compromised [4][5][6] or when the spermatozoon's repertoire of developmental epigenetic regulators is damaged. 7,8 The evident importance of paternally mediated genetic/epigenetic changes to the long-term health trajectory of the offspring, raises important questions about how such damage arises, how it can be detected and the relative significance of such factors in the etiology of human disease.…”

Section: Introductionmentioning

confidence: 99%

“…The successful initiation of embryogenesis depends, in turn, on the ability of the spermatozoon to deliver to the egg both an appropriately programmed paternal genome and a range of epigenetic factors that will shape the developmental process in response to a variety of metabolic and environmental factors. In the human, these sperm‐borne epigenetic factors include an intact centriole that will orchestrate cell division in the progeny, a critical enzyme (phospholipase C, zeta) that will initiate calcium oscillations in the ooplasm in order to trigger the developmental process, as well as a range of small non‐coding RNA species that will ultimately impact the metabolic and behavioural phenotype of the offspring 1–3 …”

Section: Introductionmentioning

confidence: 99%

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DNA damage in testicular germ cells and spermatozoa. When and how is it induced? How should we measure it? What does it mean?

Aitken

Lewis

2023

Andrology

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This review surveys the causes and consequences of DNA damage in the male germ line from spermatogonial stem cells to fully differentiated spermatozoa. Within the stem cell population, DNA integrity is well maintained as a result of excellent DNA surveillance and repair; however, a progressive increase in background mutation rates does occur with paternal age possibly as a result of aberrant DNA repair as well as replication error. Once a germ cell has committed to spermatogenesis, it responds to genetic damage via a range of DNA repair pathways or, if this process fails, by the induction of apoptosis. When fully‐differentiated spermatozoa are stressed, they also activate a truncated intrinsic apoptotic pathway which results in the activation of nucleases in the mitochondria and cytoplasm; however, the physical architecture of these cells prevents these enzymes from translocating to the nucleus to induce DNA fragmentation. Conversely, hydrogen peroxide released from the sperm midpiece during apoptosis is able to penetrate the nucleus and induce DNA damage. The base excision repair pathway responds to such damage by cleaving oxidized bases from the DNA, leaving abasic sites that are alkali‐labile and readily detected with the comet assay. As levels of oxidative stress increase and these cells enter the perimortem, topoisomerase integrated into the sperm chromatin becomes activated by SUMOylation. Such activation may initially facilitate DNA repair by reannealing double strand breaks but ultimately prepares the DNA for destruction by nucleases released from the male reproductive tract. The abasic sites and oxidized base lesions found in live spermatozoa are mutagenic and may increase the mutational load carried by the offspring, particularly in the context of assisted conception. A variety of strategies are described for managing patients expressing high levels of DNA damage in their spermatozoa, to reduce the risks such lesions might pose to offspring health.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

DNA damage in testicular germ cells and spermatozoa. When and how is it induced? How should we measure it? What does it mean?

Aitken

Lewis

2023

Andrology

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Novel insights into transfer RNA-derived small RNA (tsRNA) in cardio-metabolic diseases

Zhang,

Zhao,

Sun

et al. 2024

Life Sciences

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Ribonuclease Inhibitor 1 (RNH1) Regulates Sperm tsRNA Generation for Paternal Inheritance through Interacting with Angiogenin in the Caput Epididymis

Ma,

Tang,

Zhang

et al. 2024

Antioxidants

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Environmental stressors can induce paternal epigenetic modifications that are a key determinant of the intergenerational inheritance of acquired phenotypes in mammals. Some of them can affect phenotypic expression through inducing changes in tRNA-derived small RNAs (tsRNAs), which modify paternal epigenetic regulation in sperm. However, it is unclear how these stressors can affect changes in the expression levels of tsRNAs and their related endonucleases in the male reproductive organs. We found that Ribonuclease inhibitor 1 (RNH1), an oxidation responder, interacts with ANG to regulate sperm tsRNA generation in the mouse caput epididymis. On the other hand, inflammation and oxidative stress induced by either lipopolysaccharide (LPS) or palmitate (PA) treatments weakened the RNH1-ANG interaction in the epididymal epithelial cells (EEC). Accordingly, ANG translocation increased from the nucleus to the cytoplasm, which led to ANG upregulation and increases in cytoplasmic tsRNA expression levels. In conclusion, as an antioxidant, RNH1 regulates tsRNA generation through targeting ANG in the mouse caput epididymis. Moreover, the tsRNA is an epigenetic factor in sperm that modulates paternal inheritance in offspring via the fertilization process.

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Small Noncoding RNAs Contribute to Sperm Oxidative Stress-Induced Programming of Behavioral and Metabolic Phenotypes in Offspring

Cited by 4 publications

References 62 publications

DNA damage in testicular germ cells and spermatozoa. When and how is it induced? How should we measure it? What does it mean?

DNA damage in testicular germ cells and spermatozoa. When and how is it induced? How should we measure it? What does it mean?

Novel insights into transfer RNA-derived small RNA (tsRNA) in cardio-metabolic diseases

Ribonuclease Inhibitor 1 (RNH1) Regulates Sperm tsRNA Generation for Paternal Inheritance through Interacting with Angiogenin in the Caput Epididymis

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