Significance Sequences derived from transposable elements (TEs) are abundant in the human genome and can influence gene expression. In normal cells, most TEs are silenced by epigenetic mechanisms such as DNA methylation but, in cancer, normally dormant TEs can become active. We hypothesized that cancer-specific release of epigenetic suppression of TEs could result in gene expression perturbations, which could promote oncogenesis. Using a bioinformatics method, we identified many genes expressed in diffuse large B-cell lymphoma (DLBCL) via activation of TE promoters. Further analysis of one, FABP7 , showed it was expressed in some DLBCL samples through use of a TE promoter. The TE-driven FABP7 transcript encodes a novel isoform of the protein, which is required for optimal DLBCL cell line proliferation.
The fusion peptide of TBEV is a short segment of the envelope protein that mediates viral and host cell membrane fusion at acidic pH. Previous studies on the E protein have shown that mutations at L107 have an effect on fusogenic activity. Structural studies have also suggested that during the fusion process the E protein rearranges to form a trimer. In the present study, a number of short peptides were synthesized, and their structure/activity was examined: (1) monomers consisting of residues 93-113 of the wild-type E protein with Leu at position 107 (WT) and two mutants, namely, L107F and L107T; (2) a monomer consisting of residues 93-113 of the E protein with a C105A mutation (TFPmn); (3) a trimer consisting of three monomers described in (2), linked at the C-terminus via 1 Lys (TFPtr); (4) a monomer consisting of residues 93-113 of the E protein plus six additional Lys at the C-terminus; and (5) a trimer consisting of three monomers described in (3), linked via the side chain of the sixth lysine. The secondary structure content of all peptides was investigated using circular dichroism (CD). Approximately seven of the residues were in beta-strand conformation, in the presence of POPC/POPE/cholesterol. The structures did not depend on pH significantly. The fusogenicity of the peptides was measured by FRET and photon correlation spectroscopy. The data suggest that TFPtr is the most fusogenic at acidic pH and that the mutation from L107 to T reduces activity. Molecular dynamics simulations of WT, L107T, and L107F suggest that this reduction in activity may be related to the fact that the mutations disrupt trimer stability. Finally, tryptophan fluorescence experiments were used to localize the peptides in the membrane. It was found that WT, L107F, TFPmn, and TFPtr could penetrate better into the acyl chain region of the lipids than the other peptides tested. The implications of these results on the fusion mechanism of TBEV E protein will be presented.
The human neuronal apoptosis inhibitory protein (NAIP) gene is no longer principally considered a member of the Inhibitor of Apoptosis Protein (IAP) family, as its domain structure and functions in innate immunity also warrant inclusion in the Nod-Like Receptor (NLR) superfamily. NAIP is located in a region of copy number variation, with one full length and four partly deleted copies in the reference human genome. We demonstrate that several of the NAIP paralogues are expressed, and that novel transcripts arise from both internal and upstream transcription start sites. Remarkably, two internal start sites initiate within Alu short interspersed element (SINE) retrotransposons, and a third novel transcription start site exists within the final intron of the GUSBP1 gene, upstream of only two NAIP copies. One Alu functions alone as a promoter in transient assays, while the other likely combines with upstream L1 sequences to form a composite promoter. The novel transcripts encode shortened open reading frames and we show that corresponding proteins are translated in a number of cell lines and primary tissues, in some cases above the level of full length NAIP. Interestingly, some NAIP isoforms lack their caspase-sequestering motifs, suggesting that they have novel functions. Moreover, given that human and mouse NAIP have previously been shown to employ endogenous retroviral long terminal repeats as promoters, exaptation of Alu repeats as additional promoters provides a fascinating illustration of regulatory innovations adopted by a single gene.
Background:The expression of the activating receptor NKp46/NCR1 is highly restricted to NK cells. Results: RUNX proteins bind identified cis-regulatory element and affect NCR1 expression. Conclusion: NCR1 is regulated by two key proximal cis-regulatory elements and by RUNX factors. Significance: Mapping regulatory components of NCR1 will contribute to a deeper understanding of NK biology.
Objective-MEIS1 is a Hox cofactor known for its role in development and strongly linked to normal and leukemic hematopoiesis. Although previous studies have focused on identifying protein partners of MEIS1 and its transcriptionaly regulated targets, little is known about the upstream transcriptional regulators of this tightly regulated gene. Understanding the regulation of MEIS1 is important toward the understanding of normal hematopoiesis and leukemogenesis.Materials and Methods-Here we describe our studies focusing on the evolutionary conserved putative MEIS1 promoter region. Phylogenetic sequence analysis followed and reporter assays in MEIS1 expressing (K562) and non-expressing (HL60) leukemic cell line models were used to identify key regulatory regions and potential transcription factor binding sites within the candidate promoter region followed by functional and expression studies of one identified regulator in both cell lines and primary human cord blood and leukemia samples. Results-The chromatin status of MEIS1 promoter region is associated with MEIS1 expression.Truncation and mutation studies coupled with reporter assays revealed that a conserved ETS family member binding site located 289bp upstream of the annotated human MEIS1 transcription start site (AHTSS) is required for promoter activity. Of the three ETS family members tested, only ELF1 was enriched on the MEIS1 promoter as assessed by both electrophoretic mobility shift assay (EMSA) and chromatin immunoprecipitation (ChIP) experiments in K562. This finding was confirmed in MEIS1 expressing primary human samples. Moreover, siRNA -mediated knockdown of ELF1 in K562 cells was associated with a decreased MEIS1 expression.Conclusions-We conclude that the ETS transcription factor ELF1 is an important positive regulator of MEIS1 expression.
Stochastic expression is a hallmark of the Ly49 family that encode the main MHC class-I-recognizing receptors of mouse natural killer (NK) cells. This highly polygenic and polymorphic family includes both activating and inhibitory receptor genes and is one of genome's fastest evolving loci. The inhibitory Ly49 genes are expressed in a stochastic mono-allelic manner, possibly under the control of an upstream bi-directional early promoter and show mono-allelic DNA methylation patterns. To date, no studies have directly addressed the transcriptional regulation of the activating Ly49 receptors. Our study shows differences in DNA methylation pattern between activating and inhibitory genes in C57BL/6 and F1 hybrid mouse strains. We also show a bias towards bi-allelic expression of the activating receptors based on allele-specific single-cell RT–PCR in F1 hybrid NK cells for Ly49d and Ly49H expression in Ly49h+/− mice. Furthermore, we have identified a region of high sequence identity with possible transcriptional regulatory capacity for the activating Ly49 genes. Our results also point to a likely difference between NK and T-cells in their ability to transcribe the activating Ly49 genes. These studies highlight the complex regulation of this rapidly evolving gene family of central importance in mouse NK cell function.
The mouse gene for the natural killer (NK) cell-activating receptor Nkg2d produces two protein isoforms, NKG2D-S and NKG2D-L, which differ by 13 amino acids at the N-terminus and have different signalling capabilities. These two isoforms are produced through differential splicing, but their regulation has not been investigated. In this study, we show that rat Nkg2d has the same splicing pattern as that of the mouse, and we mapped transcriptional start sites in both species. We found that the splice forms arise from alternative promoters and that the NKG2D-L promoter is derived from a rodent B1 retrotransposon that inserted before mouse–rat divergence. This B1 insertion is associated with loss of a nearby splice acceptor site that subsequently allowed creation of the short NKG2D isoform found in mouse but not human. Transient reporter assays indicate that the B1 element is a strong promoter with no inherent lymphoid tissue-specificity. We have also identified different binding sites for the ETS family member GABP within both the mouse and rat B1 elements that are necessary for high-promoter activity and for full Nkg2d-L expression. These findings demonstrate that a retroelement insertion has led to gene-regulatory change and functional diversification of rodent NKG2D.
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