Ephrin type-A receptor 2-antisense RNA1/2 promote proliferation and migration of MDA-MB-231 cells through EPHA2-dependent Ras signaling pathway mediated by MAPK8/JNK1, MAPK9/JNK2-NFATC2/NFAT1 and JUND.

Ephrin type-A receptor 2 (EPHA2) is a receptor tyrosine kinase that is overexpressed in a variety of cancers, including breast cancer. EPHA2 expression may be causally related to tumorigenesis; therefore, it is important to understand how EPHA2 expression is regulated. We previously reported that EPHA2 antisense RNA (EPHA2-AS), a natural antisense transcript, is an important modulator of EPHA2 mRNA levels and hence production of EPHA2 protein. EPHA2-AS encodes two splice variants, EPHA2-AS1 and EPHA2-AS2. The two variants are constitutively expressed in a concordant manner with EPHA2 mRNA in human breast adenocarcinoma cell lines and in patient samples, with the highest levels detected in the basal-like/triple-negative molecular subtype of breast cancer cells. In this study, we investigated the mechanism of EPHA2-AS1/2 in triple-negative breast cancer using MDA-MB-231 cells. We performed RNA-seq transcriptome analyses of MDA-MB-231 cells treated with AHCC®, which suppressed expression of EPHA2-AS1/2 and EPHA2 mRNA, and EPHA2-AS1/2-silenced MDA-MB-231 cells. Bioinformatics analyses identified 545 overlapping differentially expressed genes that were significantly up- or down-regulated by these treatments. Subsequent functional enrichment analyses of the overlapping genes in combination with in vitro assays indicated that EPHA2-AS1/2 may promote the proliferation and migration of MDA-MB-231 cells through the EPHA2-dependent Ras signaling pathways mediated by MAPK8/JNK1, MAPK9/JNK2-NFATC2/NFAT1 (proliferation and migration) and JUND (migration). These results thus suggest that EPHA2-AS1/2 may represent a potential molecular target for triple-negative breast cancer treatment.

EPHA2 antisense RNA modulates EPHA2 mRNA levels in basal-like/triple-negative breast cancer cells.

Ephrin type-A receptor 2 (EPHA2) is a receptor tyrosine kinase (RTK), whose over-expression has been observed in a variety of cancers, including breast cancer. EPHA2 expression may be causally related to tumorigenesis; therefore, it is important to understand how EPHA2 gene (EPHA2) expression is regulated. Here, we report that EPHA2 antisense RNA (EPHA2-AS), a natural antisense transcript, is an important modulator of EPHA2 mRNA levels. EPHA2-AS is a ∼1.8 kb long non-coding RNA (lncRNA) with a poly(A) tail that encodes two splice variants, EPHA2-AS1/2. They are constitutively expressed in a concordant manner with EPHA2 mRNA in human breast adenocarcinoma cell lines and in patient samples, with the highest levels detected in the triple-negative breast cancer (TNBC) subtype. The silencing of EPHA2-AS1/2 by a sense oligonucleotide or over-expression of an antisense oligoribonucleotide, which were both designed from the EPHA2 mRNA region (nt 2955-2974) targeted by AS1/2, showed that EPHA2-AS1/2 modulated EPHA2 mRNA levels by interacting with the specific AS1/2-complementary region in the mRNA. The EPHA2-AS1/2 did not prevent microRNAs from acting on the relevant microRNA response elements shared by EPHA2-AS1/2 and EPHA2 mRNA. Our studies demonstrate a crucial role played by EPHA2-AS1/2 in modulating EPHA2 mRNA levels, and hence production of EPHA2 protein, a key oncogenic RTK that contributes to the tumorigenesis of TNBC cells.

A guinea pig IFNA1 gene with antiviral activity against human influenza virus infection.

We previously reported a natural antisense (AS) RNA as an important modulator of human interferon-Alpha1 (IFNA1) mRNA levels. Here, we identified the guinea pig (Cavia porcellus) IFNA1 gene to enable a proof-of-concept experiment to be performed to confirm that the AS-mRNA regulatory axis exerts in vivo control over innate immunity. We selected a guinea pig model system for influenza virus infection because guinea pigs encode a functional Mx1 gene, an important anti-viral effector in the type I interferon pathway. We identified 15 guinea pig IFNA1 gene candidates upon bioinformatic analysis and selected the three candidates with the highest sequence homology to Homo sapiens, Mus musculus and Marmota himalayana IFNA1. The anti-viral activity of guinea pig IFN-Alpha1 protein against influenza virus A/Puerto Rico/8/34- or endomyocarditis virus-infection was then determined for the three gene candidates. We identified cpIFNA1 as the candidate with the highest sequence homologies and best anti-viral effects. cpIFNA1 will enable us to perform a proof-of-concept experiment to verify that IFN-Alpha1 AS increases cpIFNA1 mRNA levels, resulting in inhibition of influenza virus proliferation in vivo.

IFN-Alpha1 antisense RNA represses human influenza A virus growth in a guinea pig system.

We reported a natural antisense (AS) long non-coding RNA as an important modulator of interferon-Alpha1 (IFNA1) mRNA levels. We showed that IFN-Alpha1 AS promotes IFNA1 mRNA stability by transient duplex formation and inhibition of miR-1270-induced mRNA decay. Here, we performed a proof-of-concept experiment to verify that the AS-mRNA regulatory axis exerts in vivo control of innate immunity. We established a model system for influenza virus infection using guinea pig, which encodes a functional MX1 gene for the type I IFN pathway. This system allowed us to investigate the effects of antisense oligoribonucleotides representing functional domains of guinea pig IFN-Alpha1 AS on gpIFNA1 mRNA levels and, consequently, on viral proliferation in the respiratory tract of influenza virus-infected animals. We demonstrated that pulmonary-administered asORNs inhibited the proliferation of the virus in the animals by modulating IFNA1 mRNA levels. These results indicate that, in light of the proposed actions, asORNs may modulate the level of IFNA1 mRNA in vivo, indicating that IFN-Alpha1 AS plays a pivotal role in determining the outcome of type I IFN responses.

Interferon-alpha competing endogenous RNA network antagonizes microRNA-1270.

A new form of circuitry for gene regulation has been identified in which RNAs can crosstalk by competing for shared microRNAs (miRNAs). Such competing endogenous RNAs (ceRNAs) form a network via shared miRNA response elements (MREs) to antagonize miRNA function. We previously reported natural antisense RNA (AS) as an important modulator of interferon-α1 (IFN-α1) mRNA levels by promoting IFN-α1 mRNA stability. We show that IFN-α1 AS forms a ceRNA network with specific IFN-α AS (IFN-α7/-α8/-α10/-α14) and mRNA (IFN-α8/-α10/-α14/-α17) subtypes from the IFN-α gene (IFNA) family to antagonize miRNA-1270 (miR-1270), thereby modulating IFN-α1 mRNA levels. Bioinformatic analysis demonstrated that IFN-α1 AS harbors multiple miR-1270 MREs (MRE-1270s), whose presence was substantiated by miR-1270 overexpression and transfection of antimiR-1270. The antimiR-1270, complementary to the miR-1270 seed region, revealed that IFN-α1 AS likely shares the MRE-1270 with IFN-α1 mRNA and specific IFN-α AS and mRNA subtypes. Subsequent bioinformatic analysis for MRE-1270s showed that IFN-α1 AS and other RNA subtypes shared the 6-mer MRE-1270 site. Further MRE-mapping demonstrated that the total number of MRE-1270s in IFN-α1 AS accounted for approximately 30 % of the miR-1270 population. AntimiR-1270 transfection also caused specific de-repression of five cellular mRNAs, including that of CAPRIN1. These results suggest that IFN-α1 AS, together with specific IFN-α AS and mRNA subtypes, as well as the five cellular mRNAs, participate as competing molecules in the ceRNA network against miR-1270. This coordinated regulatory architecture suggests a vital function for the innate immune system in maintaining precise physiological type I IFN levels via post-transcriptional regulatory mechanisms.