Anti-aging Effects of Alu Antisense RNA on Human Fibroblast Senescence Through the MEK-ERK Pathway Mediated by KIF15.

OBJECTIVE: To investigate whether human short interspersed nuclear element antisense RNA (Alu antisense RNA; Alu asRNA) could delay human fibroblast senescence and explore the underlying mechanisms. METHODS: We transfected Alu asRNA into senescent human fibroblasts and used cell counting kit-8 (CCK-8), reactive oxygen species (ROS), and senescence-associated beta-galactosidase (SA-ß-gal) staining methods to analyze the anti-aging effects of Alu asRNA on the fibroblasts. We also used an RNA-sequencing (RNA-seq) method to investigate the Alu asRNA-specific mechanisms of anti-aging. We examined the effects of KIF15 on the anti-aging role induced by Alu asRNA. We also investigated the mechanisms underlying a KIF15-induced proliferation of senescent human fibroblasts. RESULTS: The CCK-8, ROS and SA-ß-gal results showed that Alu asRNA could delay fibroblast aging. RNA-seq showed 183 differentially expressed genes (DEGs) in Alu asRNA transfected fibroblasts compared with fibroblasts transfected with the calcium phosphate transfection (CPT) reagent. The KEGG analysis showed that the cell cycle pathway was significantly enriched in the DEGs in fibroblasts transfected with Alu asRNA compared with fibroblasts transfected with the CPT reagent. Notably, Alu asRNA promoted the KIF15 expression and activated the MEK-ERK signaling pathway. CONCLUSION: Our results suggest that Alu asRNA could promote senescent fibroblast proliferation via activation of the KIF15-mediated MEK-ERK signaling pathway.

[The effects of SV40 PolyA sequence and its AATAAA signal on upstream GFP gene expression and transcription termination].

SV40 PolyA (Simian virus 40 PolyA, also called PolyA) sequence is DNA sequence (240 bp) that possesses the activity of transcription termination and can add PolyA tail to mRNA. PolyA contains AATAAA hexanucleotide polyadenylation signal. Fourteen copies of Alu in sense orientation (Alu14) were inserted downstream of GFP in pEGFP-C1 to construct pAlu14 plasmid, and then HeLa cells were transiently transfected with pAlu14. Northern blot and fluorescence microscope were used to observe GFP RNA and protein expressions. Our results found that Alu tandem sequence inhibited remarkably GFP gene expression, but produced higher-molecular-mass GFP fusion RNA. PolyA and its sequence that was deleted AATAAA signal in sense or antisense orientation were inserted between GFP and Alu tandem sequence in pAlu14. The results showed that all the inserted PolyA sequences partly eliminated the inhibition induced by Alu14. PolyA sequences without AATAAA signal in sense or antisense orientation still induced transcription termination. Antisense PolyA (PolyAas) was divided into four fragments that all are 60 bp long and the middle two fragments were named 2F2R and 3F3R. 2F2R or 3F3R was inserted upstream of Alu tandem sequence in pAlu14. The molecular mass of GFP fusion RNA increased when the copy number of 2F2R increased. 2F2R can support transcription elongation when 2F2R is located upstream of other 2F2R. Nevertheless, 2F2R located upstream of Alu tandem sequence can induce transcription termination. Inserting one copy or 64 copies of 3F3R in upstream of Alu tandem sequence caused the production of lower-molecular-mass GFP RNA.

[Detection and sequence analysis of an imperfect stem-loop structure in cis activating gene element from SV40PolyA].

Our previous studies showed that tandem Alu repeats inhibited GFP gene expression when they were inserted into the downstream of GFP gene in pEGFP-C1 vector and HeLa cells were then transfected transiently. The sequence named 2F2R (second 60 bp from the 5' end of SV40PolyA antisense strand) eliminated the repression of GFP gene expression induced by Alu repeats when 2F2R was inserted between GFP and Alu repeats. In this study the deletion of 2F2R DNA showed that 45R (45 bp in 2F2R 5'end), 30R (30 bp in 2F2R 5' end) and 22R (22 bp in 2F2R 5' end) activated GFP gene expression, and the activating actions of the double tandem sequences were stronger than those of their corresponding single sequences. Secloop (22 bp near the center in 2F2R) and Poly4 (30 bp in 2F2R 3' end) sequences did not activate GFP gene expression. The activating action of 30R-Poly4 sequence formed by ligating 30R with Poly4 by 9 bp was lower than that of 2F2R. The linking base number between two 22R sequences did not influence the GFP gene expression obviously. Sequence 22R (5'-GTGAAAAAAATGCTTTATTTGT-3') contains an imperfect palindrome sequence and may form an imperfect stem-loop structure including a 3nt loop, 3 bp first stem, 2nt bulge, and 3bp second stem. The mutations changing stem-loop structure of 22R influenced the GFP gene activation significantly and neither the excessively stable nor excessively unstable stem-loop structures were in favour of GFP gene activation, which suggested that the suitably imperfect stem-loop structures had something with gene activation.

[RNA responsible for conferring a DNase I sensitive structure on albumin gene in assembled chromatin].

Although the set of genes is virtually the same in all tissues,differential gene expression is appeared in cells of different kinds. Differentiation and ageing are associated with regulation of gene expression that is a fundamental mechanism in eukaryotic development and survival. The sensitivity to DNase I of actively transcribed genes seems to be a general phenomenon. The purpose of the study is to test whether RNAs obtained from different organs or cells can enhance susceptibility of albumin gene to DNase I digestion in BALB/c mouse brain chromatin assembled.RNAs extracted from rat liver, lung, kidney, brain, tRNA from yeast and synthesized RNAs (23 nt completed with mouse alb gene) were added to a system of chromatin reconstitution that was achieved by dialysis from high ionic strength solution. Assembled chromatin was digested with DNase I (12.5 microg/mL) at 20 degrees for 1 min, then PCR assay was used to detect the level of albumin gene digested. PCR products (1200 bp) were run on a 6% polyacylamide gel and analyzed by silver stain assay. RNAs from different organs and synthesized RNAs all increased the sensitivity of albumin gene to DNase I attack in mouse assembled chromatin. The effect was more obvious in liver and lung RNAs than in kidney and brain ones. tRNA from yeast did not enhance the sensitivity of albumin gene to DNase I digestion. RNA increased albumin gene sensitivity to DNase I in a dose-dependent manner. We report here for the first time that RNAs can enhance susceptibility of albumin gene to DNase I digestion. The effect is associated with RNA sources or sequences. It is generally agreed that the formation of gene sensitivity to DNase I, by unfolding of a tightly packed chromatin fiber, is the first step in gene activation, then RNAs that recognize complementary DNA sequences may be the specific factors that affect DNA supercoiling and determine the sensitivity of gene to DNase I digestion. Here we describes "RNA Population Gene Activating Model" that gives a logical interpretation of events leading to expression of specific genes during normal development and differentiation, in the same time,explains ageing and oncogenesis. Gene expression in eukaryotic cells requires two level regulations. The first may be controlled by RNAs that locate complementary regions within the genomes and make these regions loosened potentially, and the second is mainly involved in sequence specific and nonspecific proteins by which genomic regions bound by RNAs are unfolded. In eukaryotic cells, RNA fragments cleaved from all transcripts mix together to form "RNA populations" in which the majority is intron RNA. Every type of RNA fragments and its homologous sequences act as a group to form certain concentration in which repetitive sequences are more effective. If it is considered that there are many groups of RNA fragments in a particular cell,then different groups of RNA fragments are presented in dissimilar cell types of differentiation. Between DNA replication and nucleosome formation, RNA fragments in nuclear liquid will compete with DNA for binding to complement regions, then the chromatin regions bound to RNA can not be wrapped to form typical nucleosomes. After DNA doubles and is divided into 2 cells, these regions containing atypical nucleosomes become loose by function of non-histone. Transcriptionally active regions of chromatin are loose conformation but loosened regions are not always transcriptionally active. In every division, cells suffer in the described procedure that genes express RNAs, then RNAs recognize and imprint DNA. There are different RNA populations in different cells so that they imprint different genes, which is the primary mechanism by which same genes have expression distinctness. Since loosened genes are similar to bacterial operator system, factors in environment around cells play roles in inducing different gene expression to form different RNA population, which is the primary reason of cell differentiation. RNA population produced by certain impressions in genome can not imprint to form the same ones, otherwise immortal cells will be emerged, so that this program also controls ageing and oncogenesis.