DNA damage induction in bone marrow cells of mice after farnesenes and 2,5-dimethylpyrazine sniffing

Eugene V. Daev; Даев Евгений Владиславович; Victoria A. Mamontova; Мамонтова Виктория Андреевна; Timofey S. Glinin; Глинин Тимофей Сергеевич

doi:10.17816/ecogen16347-54

DNA damage induction in bone marrow cells of mice after farnesenes and 2,5-dimethylpyrazine sniffing

Authors: Daev E.V.¹, Mamontova V.A.¹, Glinin T.S.¹
Affiliations:
1. Saint Petersburg State University
Issue: Vol 16, No 3 (2018)
Pages: 47-54
Section: Genetic toxicology
URL: https://bakhtiniada.ru/ecolgenet/article/view/9022
DOI: https://doi.org/10.17816/ecogen16347-54
ID: 9022

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Abstract

Background. Pheromones are an important regulatory link of synecological contacts in numerous animal species. Chemo-signaling participates in establishing of population social structure, it regulates different types of behavior, changes hormonal state and maturation rate, etc. It also can affect the genetic material expression and integrity.

Material and methods. Groups of adult males of CBA/Lac/Sto/Rap strain were exposed to volatile chemosignals (mixture of α- and β-farnesenes or 2,5-dime thylpyrazine) for 2 or 24 hours. Bone marrow cells were prepared for single cell gel electrophoresis (comet assay test). Content of DNA in comet cells were analyzed. In case of 24 hours exposure bone marrow cells were fixed also for ana-telophase analysis.

Results. It is shown that exposures with farnesenes or 2,5-DMP both damage genetic material of bone marrow cells. It also followed by induction of mitotic aberration frequency. Simultaneous exposure with all chemosignals does not increase damaging effect.

Conclusion. Chemosignals which serve as stress-pheromones in mice decrease also the integrity of genetic material in bone marrow cells of recipients. It could be a mechanism of pheromonal impact on density and space-genetic structure of mouse populations.

Keywords

pheromones, farnesenes, 2,5-dimethylpyrazine, bone marrow, mice, alkaline comet assay, chromosome aberrations

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About the authors

Eugene V. Daev

Saint Petersburg State University

Author for correspondence.
Email: mouse_gene@mail.ru
ORCID iD: 0000-0003-2036-6790
SPIN-code: 8926-6034
Scopus Author ID: 6701779129
ResearcherId: D-1165-2013

PhD, ScD, Professor, Department of Genetics and Biotechnology

Russian Federation, 7/9, Universitetskaya embankment, Saint-Petersburg, 199034

Victoria A. Mamontova

Saint Petersburg State University

Email: vicktory.shubina@gmail.com

Undergraduate, Department of Genetics and Biotechnology

Russian Federation, 7/9, Universitetskaya embankment, Saint-Petersburg, 199034

Timofey S. Glinin

Saint Petersburg State University

Email: t.glinin@gmail.com

Postgraduate, Department of Genetics and Biotechnology

Russian Federation, 7/9, Universitetskaya embankment, Saint-Petersburg, 199034

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2. Fig. 1. Frequency distribution of bone marrow cells with different DNA content in comet tails after 2 hrs exposures of CBA mouse males with different chemosignals or acrylamide injection (f ± 99% CI). I – Control; II – exposure to corresponding chemosignal (1 – Farnesenes; 2 – DMP; 3 – both farnesenes and DMP); III – acrylamide injection. Vertical lines are F0.5 points (see table 1)

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3. Fig. 2. Frequency distribution of bone marrow cells with different DNA content in comet tails after 24 hrs exposures of CBA mouse males with different chemosignals (f ± 99% CI). I – Control; II – exposure to corresponding chemosignal (1 – Farnesenes; 2 – DMP; 3 – both farnesenes and DMP). Black zones show where confidence intervals are not overlapping. The rest symbols are the same as in Fig. 1

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