<i>PARP1</i> GENE KNOCKOUT SUPPRESSES EXPRESSION OF DNA BASE EXCISION REPAIR GENES-Reference-Cited by-同舟云学术

<i>PARP1</i> GENE KNOCKOUT SUPPRESSES EXPRESSION OF DNA BASE EXCISION REPAIR GENES

Published:2023-05-01 Issue:1 Volume:510 Page:219-224
ISSN:2686-7389
Container-title:Доклады Российской академии наук. Науки о жизни
language:
Short-container-title:Doklady Rossijskoj akademii nauk. Nauki o žizni

Author:

Zakharenko A. L.¹,Malakhova A. A.¹²³,Dyrkheeva N. S.¹,Okorokova L. S.⁴,Medvedev S. P.¹²³,Zakian S. M.¹²³,Kabilov M. R.¹,Tupikin A. A.¹,Lavrik O. I.¹

Affiliation:

1. Institute of Chemical Biology and Fundamental Medicine, Siberian Branch of the Russian Academy of Sciences

2. Federal Research Centre Institute of Cytology and Genetics, Siberian Branch of the Russian Academy of Sciences

3. E.N. Meshalkin National medical research center of the Ministry of Health of the Russian Federation

4. AcademGene LLC

Abstract

The effect of PARP1 knockout in HEK293 cells on the gene expression of DNA base excision repair (BER) proteins was studied. It was shown that the expression of all differentially expressed genes (DEGs) of BER was reduced by knockout. The expression of the DNA glycosylase gene NEIL1, which is considered to be one of the common “hubs” for binding BER proteins, has changed the most. The expression of genes of auxiliary subunits of DNA polymerases δ and ε is also significantly reduced. The PARP1 gene knockout cell line obtained is an adequate cell model for studying the activity of the BER process in the absence of PARP1 and testing drugs aimed at inhibiting repair processes. It has been found for the first time that knockout of the PARP1 gene results in a significant change in the level of expression of proteins responsible for ribosome biogenesis and the functioning of the proteasome.

Publisher

The Russian Academy of Sciences

Reference39 articles.

1. Karpinska A. Quantitative analysis of biochemical processes in living cells at a single-molecule level: a case of olaparib–PARP1 (DNA repair protein) interactions. // 2021. Analyst. V. 146. № 23. P. 7131–7143.

2. Ходырева С.Н., Лаврик О.И. Поли(ADP-рибоза)полимераза 1 – ключевой регулятор репарации ДНК // Молекуляр. биология. 2016. Т. 50. С. 655–673.

3. Xie N., Zhang L., Gao W., et al. NAD + metabolism: pathophysiologic mechanisms and therapeutic potential. // Signal Transduction and Targeted Therapy. 2020. V. 5. № 1. P. 227.

4. Suskiewicz M.J., Palazzo L., Hughes R., Ahel I. Progress and outlook in studying the substrate specificities of PARPs and related enzymes // FEBS J. 2021. V. 288. № 7. P. 2131–2142.

5. Martin-Hernandez K., Rodriguez-Vargas J.M., Schreiber V., et al. Expanding functions of ADP-ribosylation in the maintenance of genome integrity // Cell Dev. Biol. 2017. V. 63 P. 92–101.