染色质改构因子BRG1降低UV照射引起的细胞凋亡

生命体的遗传物质基础是DNA分子,多种因素可以作用于细胞内的DNA分子,导致多种类型的DNA损伤。若受损的DNA得不到及时和有效的修复,细胞将走向凋亡或发生变异。染色质改构复合物(chromatin remodeling complex)在基因表达调控和DNA复制等方面扮演着重要角色。依赖ATP的染色质改构复合物SWI/SNF的核心亚基Brahma Related Gene1(BRG1)在染色质结构调整和基因转录调控等多个细胞进程中具有重要作用,仅有有限的文献报道BRG1参与到DNA的损伤修复过程。因此,进一步研究与验证BRG1在调控DNA的损伤修复进而挽救细胞凋亡中的作用十分重要。本文通过利用不同强度的UV照射检测细胞凋亡的情况,初步建立了DNA损伤修复的实验体系。将BRG1表达质粒瞬时转染到SW13(BRG1-/-)细胞系中,并利用30J/m2的UV照射,分别在0h、6h和24h检测细胞早期凋亡程度。结果表明,SW13(BRG1-/-)细胞中瞬时表达BRG1可以明显降低由UV照射引起的细胞凋亡,其中UV照射后24h的细胞表现最明显。我们进一步在HeLa细胞中通过瞬时表达BRG1验证了上述结果。由于BRG1通过染色质改构在基因的转录调控、复制和重组等方面起着重要的作用,我们推测BRG1可能通过染色质改构参与了DNA的损伤修复过程,进而影响了细胞凋亡。     

Stimulation of DNA repair and increased light output in response to UV irradiation in Escherichia coli expressing lux genes.

It has previously been suggested that the evolutionary drive of bacterial bioluminescence is a mechanism of DNA repair. By assessing the UV sensitivity of Escherichia coli, it is shown that the survival of UV-irradiated E. coli constitutively expressing luxABCDE in the dark is significantly better than either a strain with no lux gene expression or the same strain expressing only luciferase (luxAB) genes. This shows that UV resistance is dependent on light output, and not merely on luciferase production. Also, bacterial survival was found to be dependent on the conditions following UV irradiation, as bioluminescence-mediated repair was not as efficient as repair in visible light. Moreover, photon emission revealed a dose-dependent increase in light output per cell after UV exposure, suggesting that increased lux gene expression correlates with UV-induced DNA damage. This phenomenon has been previously documented in organisms where the lux genes are under their natural luxR regulation but has not previously been demonstrated under the regulation of a constitutive promoter.