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Your search keyword '"Bruter, Alexandra"' showing total 9 results
Start Over Author "Bruter, Alexandra" Journal international journal of molecular sciences
9 results on '"Bruter, Alexandra"'

1. Two Novel Mouse Models of Duchenne Muscular Dystrophy with Similar Dmd Exon 51 Frameshift Mutations and Varied Phenotype Severity.

Author

Baikova, Iuliia P., Ilchuk, Leonid A., Safonova, Polina D., Varlamova, Ekaterina A., Okulova, Yulia D., Kubekina, Marina V., Tvorogova, Anna V., Dolmatova, Daria M., Bakaeva, Zanda V., Kislukhina, Evgenia N., Lizunova, Natalia V., Bruter, Alexandra V., and Silaeva, Yulia Yu.

Subjects
X-linked genetic disorders, DUCHENNE muscular dystrophy, ALTERNATIVE RNA splicing, DYSTROPHIN genes, GENE therapy, FRAMESHIFT mutation
Abstract

Duchenne muscular dystrophy (DMD) is a severe X-linked genetic disorder caused by an array of mutations in the dystrophin gene, with the most commonly mutated regions being exons 48–55. One of the several existing approaches to treat DMD is gene therapy, based on alternative splicing and mutant exon skipping. Testing of such therapy requires animal models that carry mutations homologous to those found in human patients. Here, we report the generation of two genetically modified mouse lines, named "insT" and "insG", with distinct mutations at the same position in exon 51 that lead to a frameshift, presumably causing protein truncation. Hemizygous males of both lines exhibit classical signs of muscular dystrophy in all muscle tissues except for the cardiac tissue. However, pathological changes are more pronounced in one of the lines. Membrane localization of the protein is reduced to the point of absence in one of the lines. Moreover, an increase in full-length isoform mRNA was detected in diaphragms of insG line mice. Although further work is needed to qualify these mutations as sole origins of dissimilarity, both genetically modified mouse lines are suitable models of DMD and can be used to test gene therapy based on alternative splicing. [ABSTRACT FROM AUTHOR]

Published
2025
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5. Physiological and Functional Effects of Dominant Active TCRα Expression in Transgenic Mice

Author

Kalinina, Anastasiia A., primary, Ziganshin, Rustam Kh., additional, Silaeva, Yulia Yu., additional, Sharova, Nina I., additional, Nikonova, Margarita F., additional, Persiyantseva, Nadezda A., additional, Gorkova, Tatiana G., additional, Antoshina, Elena E., additional, Trukhanova, Lubov S., additional, Donetskova, Almira D., additional, Komogorova, Victoria V., additional, Litvina, Marina M., additional, Mitin, Alexander N., additional, Zamkova, Maria A., additional, Bruter, Alexandra V., additional, Khromykh, Ludmila M., additional, and Kazansky, Dmitry B., additional

Published
2023
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6. Limitations of Tamoxifen Application for In Vivo Genome Editing Using Cre/ERT2 System

Author

Ilchuk, Leonid A., primary, Stavskaya, Nina I., additional, Varlamova, Ekaterina A., additional, Khamidullina, Alvina I., additional, Tatarskiy, Victor V., additional, Mogila, Vladislav A., additional, Kolbutova, Ksenia B., additional, Bogdan, Sergey A., additional, Sheremetov, Alexey M., additional, Baulin, Alexandr N., additional, Filatova, Irina A., additional, Silaeva, Yulia Yu., additional, Filatov, Maxim A., additional, and Bruter, Alexandra V., additional

Published
2022
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7. Cyclophilin A as a Pro-Inflammatory Factor Exhibits Embryotoxic and Teratogenic Effects during Fetal Organogenesis.

Author

Kalinina, Anastasiia, Semenova, Maria, Bruter, Alexandra, Varlamova, Ekaterina, Kubekina, Marina, Pavlenko, Natalia, Silaeva, Yulia, Deikin, Alexey, Antoshina, Elena, Gorkova, Tatyana, Trukhanova, Lubov, Salmina, Alla, Novikova, Svetlana, Voronkov, Dmitry, Kazansky, Dmitry, and Khromykh, Ludmila

Subjects
CYCLOPHILINS, PREGNANCY complications, MORPHOGENESIS, BONE growth, EMBRYOLOGY, FETAL brain, FETUS
Abstract

The precise balance of Th1, Th2, and Th17 cytokines is a key factor in successful pregnancy and normal embryonic development. However, to date, not all humoral factors that regulate and influence physiological pregnancy have been completely studied. Our data here pointed out cyclophilin A (CypA) as the adverse pro-inflammatory factor negatively affecting fetal development and associated with pregnancy complications. In different mouse models in vivo, we demonstrated dramatic embryotoxicity and teratogenicity of increased CypA levels during pregnancy. Using generated transgenic models, we showed that CypA overexpression in fetal tissues induced the death of all transgenic fetuses and complete miscarriage. Administration of recombinant human CypA in a high dose to pregnant females during fetal organogenesis (6.5–11.5 dpc) exhibited teratogenic effects, causing severe defects in the brain and bone development that could lead to malformations and postnatal behavioral and cognitive disorders in the offspring. Embryotoxic and teratogenic effects could be mediated by CypA-induced up-regulation of M1 macrophage polarization via activation of the STAT1/3 signaling pathways. Here, we propose secreted CypA as a novel marker of complicated pregnancy and a therapeutic target for the correction of pregnancy complications. [ABSTRACT FROM AUTHOR]

Published
2023
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9. Limitations of Tamoxifen Application for In Vivo Genome Editing Using Cre/ER T2 System.

Author

Ilchuk, Leonid A., Stavskaya, Nina I., Varlamova, Ekaterina A., Khamidullina, Alvina I., Tatarskiy, Victor V., Mogila, Vladislav A., Kolbutova, Ksenia B., Bogdan, Sergey A., Sheremetov, Alexey M., Baulin, Alexandr N., Filatova, Irina A., Silaeva, Yulia Yu., Filatov, Maxim A., and Bruter, Alexandra V.

Subjects
TAMOXIFEN, GENOME editing, DOXYCYCLINE, CHIMERIC proteins, TRANSGENIC mice, PREGNANCY complications, KNOCKOUT mice
Abstract

Inducible Cre-dependent systems are frequently used to produce both conditional knockouts and transgenic mice with regulated expression of the gene of interest. Induction can be achieved by doxycycline-dependent transcription of the wild type gene or OH-tamoxifen-dependent nuclear translocation of the chimeric Cre/ERT2 protein. However, both of these activation strategies have some limitations. We analyzed the efficiency of knockout in different tissues and found out that it correlates with the concentration of the hydroxytamoxifen and endoxifen—the active metabolites of tamoxifen—measured by LC-MS in these tissues. We also describe two cases of Cdk8floxed/floxed/Rosa-Cre-ERT2 mice tamoxifen-induced knockout limitations. In the first case, the standard scheme of tamoxifen administration does not lead to complete knockout formation in the brain or in the uterus. Tamoxifen metabolite measurements in multiple tissues were performed and it has been shown that low recombinase activity in the brain is due to the low levels of tamoxifen active metabolites. Increase of tamoxifen dosage (1.5 fold) and duration of activation (from 5 to 7 days) allowed us to significantly improve the knockout rate in the brain, but not in the uterus. In the second case, knockout induction during embryonic development was impossible due to the negative effect of tamoxifen on gestation. Although DNA editing in the embryos was achieved in some cases, the treatment led to different complications of the pregnancy in wild-type female mice. We propose to use doxycycline-induced Cre systems in such models. [ABSTRACT FROM AUTHOR]

Published
2022
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