Identification of prototype foamy virus Bel1 nuclear localization signal and its corresponding importins / 病毒学报

Bel1, a transactivator of prototype foamy virus (PFV), plays pivotal roles in the replication of PFV. Previous studies have shown that Bel1 bears a nuclear localization signal (NLS), but its amino acid sequence remains unclear and the corresponding importins have not been identified. In this report, we inserted various fragments of Bel1 into an EGFP-GST fusion protein and investigated their subcellular localization by fluorescence microscopy. We found that the 215PRQKRPR221 fragment could direct nuclear localization, which accords with the consensus sequence K(K/R)X(K/R) of monopartite NLS. Point mutation experiments revealed that K218, R219, and R221 are essential for the nuclear localization of Bel1. The results of the GST-pulldown showed that the Bel1 fragment with residues 215-223, which bears the NLS, interacts with KPNA1, KPNA6, and KPNA7. This result suggests that KPNA1, KPNA6, and KPNA7 maybe involved in Bel1 nuclear translocation.

Development of Monoclonal Antibodies Against Human IRF-5 and Their Use in Identifying the Binding of IRF-5 to Nuclear Import Proteins Karyopherin-alpha1 and -beta1

PURPOSE: IRF-5 is a direct transducer of virus-mediated and TLR-mediated signaling pathways for the expression of cytokines and chemokines which form homodimers or heterodimers with IRF-7. However, direct IRF-5-specific monoclonal antibodies (mAbs) are not available at present. These could be used to further evaluate the functions of IRF-5. In this study, we produced and characterized three mouse mAbs to human IRF-5. The binding of IRF-5 to nuclear import proteins was first identified using a mAb. MATERIALS AND METHODS: His-tagged human IRF-5 protein spanning amino acid residues 193- 257 was used as an antigen and three mAbs were produced. The mAbs were tested with ELISA, Western blot analysis (WB), immunofluorescent staining (IF), and immunoprecipitation (IP). In addition, the nuclear import protein which carried phosphorylated IRF-5 was identified using one of these mAbs. RESULTS: MAbs 5IRF8, 5IRF10 and 5IRF24 which reacted with the recombinant His-IRF-5(193-257) protein were produced. All mAbs bound to human IRF-5, but not to IRF-3 or IRF-7. They could be used for WB, IF, and IP studies. The binding of phosphorylated IRF-5 to karyopherin-alpha1 and -beta1 was also identified. CONCLUSION: Human IRF-5-specific mAbs are produced for studying the immunologic roles related to IRF-5. Phosphorylated IRF-5 is transported to the nucleus by binding to nuclear import proteins karyopherin-alpha1 and -beta1.

Deletion of the Importin-alpha Gene in the Breast Cancer Cell

BACKGROUND: BRCA1 (breast-cancer gene 1) is a tumor suppressor gene that accounts for nearly all families of both early onset breast and ovarian cancer and about 45% of families with breast cancer only. Sporadic nonhereditary breast cancer is recognized as the most common form of this malignancy. However, presence of germ-line mutations in the BRCA1 gene of these tumors is an infrequent event. The BRCA1 protein includes a ring domain and an acidic domain, both of which are characteristics of certain transcription factors, as well as two putative nuclear localization signals (NLS) that interact with importin-alpha. The normal BRCA1 protein is located in the nucleus of most breast-cell types whereas the BRCA1 protein of breast cancer cells is aberrantly localized in the cytoplasm. This mislocation of the BRCA1 protein in breast cancer cells may be due to defects in the NLS receptor-mediated pathway for the nuclear import of the BRCA1 gene product. Identification of importin-alpha mutations as a cellular protein responsible for the nuclear import of BRCA1 in breast-cancer cell lines and primary breast cancers is the focus of this investigation. METHODS: A series of 15 surgical samples of breast cancer and 3 samples of breast-cancer cell lines (Hs578T, ZR75-1, MCF-7) was assayed for the presence of the deletion mutant in importin-alpha by using both RT-PCR amplification of importin-alpha transcripts and sequencing analysis. RESULTS: Three of the 15 primary breast cancers and 1 of the 3 breast-cancer cell lines showing deletions in importin-alpha transcripts produced two different truncated transcripts. 1208 bp deletions were observed in transcripts from breast cancer (T-1, T-3) and ZR75-1, which is specified by the nucleotide 251-1458 of the transcript. Another transcript encoded by primary breast cancer (T-2) included a 1312 bp deletion in the nucleotide 61-1372 of the transcript. CONCLUSIONS: The deletions eliminated part of the importin-alpha transcript segment encoding the putative NLS-binding domain but not the importin-beta binding domain, suggesting that these deletion mutants could not bind to NLS of the BRCA1 protein. These results suggest that the composite effects of mislocationof the BRCA1 protein by deletion of the NLS-binding domain in importin-alpha may contribute to tumorigenesis in sporadic breast cancer.