Impact of copy number of distinct SV40PolyA segments on expression of a GFP reporter gene

Combined sense-antisense Alu elements activate the EGFP reporter gene when stable transfection

Alu elements in the human genome are present in more than one million copies, accounting for 10% of the genome. However, the biological functions of most Alu repeats are unknown. In this present study, we detected the effects of Alu elements on EGFP gene expression using a plasmid system to find the roles of Alu elements in human genome. We inserted 5'-4TMI-Alus-CMV promoter-4TMI-Alus (or antisense Alus)-3' sequences into the pEGFP-C1 vector to construct expression vectors. We altered the copy number of Alus, the orientation of the Alus, and the presence of an enhancer (4TMI) in the inserted 5'-4TMI-Alus-CMV promoter-4TMI-Alus (or antisense Alus)-3' sequences. These expression vectors were stably transfected into HeLa cells, and EGFP reporter gene expression was determined. Our results showed that combined sense-antisense Alu elements activated the EGFP reporter gene in the presence of enhancers and stable transfection. The combined sense-antisense Alu vectors carrying four copies of Alus downstream of inserted CMV induced much stronger EGFP gene expression than two copies. Alus downstream of inserted CMV were replaced to AluJBs (having 76% homology with Alu) to construct expression vectors. We found that combined sense-antisense Alu (or antisense AluJB) vectors induced strong EGFP gene expression after stable transfection and heat shock. To further explore combined sense-antisense Alus activating EGFP gene expression, we constructed Tet-on system vectors, mini-C1-Alu-sense-sense and mini-C1-Alu-sense-antisense (EGFP gene was driven by mini-CMV). We found that combined sense-antisense Alus activated EGFP gene in the presence of reverse tetracycline repressor (rTetR) and doxycycline (Dox). Clone experiments showed that Mini-C1-Alu-sense-antisense vector had more positive cells than that of Mini-C1-Alu-sense-sense vector. The results in this paper proved that Alu repetitive sequences inhibited gene expression and combined sense-antisense Alus activated EGFP reporter gene when Alu transcribes, which suggests that Alus play roles in maintaining gene expression (silencing genes or activating genes) in human genome.

Finding of IFNγ gene enhancers and their core sequences

DNA segmentation methods were used to study which fragments of the human IFNγ gene possess enhancer activity. The human IFNγ gene was divided into 240-bp fragments, which were inserted between the GFP gene and the Alu tandem sequence to determine whether the inserted sequences eliminate the inhibition induced by the Alu tandem sequence. We found that five different 240-bp fragments (FUIFN3F3R, IFN4F4R, IFN6F6R, IFN21F21R, and IFN22F22R) and two 60-bp core sequences (IFN6-2F2R and IFN21-3-4F3-4R) derived from the IFNγ gene contain enhancers that can activate the GFP reporter gene. These enhancers may be targets of IFNγ gene expression regulation.

[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.

Effect of mutations in a simian virus 40 PolyA signal enhancer on green fluorescent protein reporter gene expression

Our previous studies have shown that tandem Alu repeats inhibit green fluorescent protein (GFP) gene expression when inserted downstream of the GFP gene in the pEGFP-C1 vector. We found that the 22R sequence (5'-GTGAAAAAAATGCTTTATTTGT-3') from the antisense PolyA (240 bp polyadenylation signal) of simian virus 40, eliminated repression of GFP gene expression when inserted between the GFP gene and the Alu repeats. The 22R sequence contains an imperfect palindrome; based on RNA structure software prediction, it forms an unstable stem-loop structure, including a loop, a first stem, a bulge, and a second stem. Analysis of mutations of the loop length of the 22R sequence showed that the three-nucleotide loop (wild-type, 22R) induced much stronger GFP expression than did other loop lengths. Two mutations, 4TMI (A7→T, A17→T) and 5AMI (A6→T, T18→A), which caused the base type changes in the bulge and in the second stem in the 22R sequence, induced stronger GFP gene expression than 22R itself. Mutation of the bulge base (A17→T), leading to complete complementation of the stem, caused weaker GFP gene expression. Sequences without a palindrome (7pieA, 5'-GTGAAAAAAATG CAAAAAAAGT-3', 7pieT, 5'-GTGTTTTTTTTGCTTTTTTTGT-3') did not activate GFP gene expression. We conclude that an imperfect palindrome affects and can increase GFP gene expression.

[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.