Ikaros sets the threshold for negative B-cell selection by regulation of the signaling strength of the AKT pathway.

Inhibitory phosphatases, such as the inositol-5-phosphatase SHIP1 could potentially contribute to B-cell acute lymphoblastic leukemia (B-ALL) by raising the threshold for activation of the autoimmunity checkpoint, allowing malignant cells with strong oncogenic B-cell receptor signaling to escape negative selection. Here, we show that SHIP1 is differentially expressed across B-ALL subtypes and that high versus low SHIP1 expression is associated with specific B-ALL subgroups. In particular, we found high SHIP1 expression in both, Philadelphia chromosome (Ph)-positive and ETV6-RUNX1-rearranged B-ALL cells. As demonstrated by targeted knockdown of SHIP1 by RNA interference, proliferation of B-ALL cells in vitro and their tumorigenic spread in vivo depended in part on SHIP1 expression. We investigated the regulation of SHIP1, as an important antagonist of the AKT signaling pathway, by the B-cell-specific transcription factor Ikaros. Targeted restoration of Ikaros and pharmacological inhibition of the antagonistic casein kinase 2, led to a strong reduction in SHIP1 expression and at the same time to a significant inhibition of AKT activation and cell growth. Importantly, the tumor suppressive function of Ikaros was enhanced by a SHIP1-dependent additive effect. Furthermore, our study shows that all three AKT isoforms contribute to the pro-mitogenic and anti-apoptotic signaling in B-ALL cells. Conversely, hyperactivation of a single AKT isoform is sufficient to induce negative selection by increased oxidative stress. In summary, our study demonstrates the regulatory function of Ikaros on SHIP1 expression in B-ALL and highlights the relevance of sustained SHIP1 expression to prevent cells with hyperactivated PI3K/AKT/mTOR signaling from undergoing negative selection.

Reduced expression and activity of patient-derived SHIP1 phosphatase domain mutants.

The characterization of dysregulated proteins in cell signaling pathways is important for the development of therapeutic approaches. The PI3K/AKT/mTOR pathway is frequently upregulated in cancer cells and the SH2-containing inositol 5-phosphatase SHIP1 can act as a negative regulator of the PI3K/AKT pathway. In this study, we investigated different patient-derived mutations within the conserved phosphatase domain of SHIP1. We could demonstrate that 2 out of 7 SHIP1-phosphatase domain mutations (G585K and R673Q) possessed reduced protein expression and reduced enzymatic activity in comparison to SHIP1 wild type (WT) protein and two additional mutations (E452K, R551Q) possessed reduced enzymatic activity at a comparable expression level compared to SHIP1 WT in the cell line H1299. The investigated mutations resulted in protein expression levels that were up to 93% lower than those of the SHIP1 WT for SHIP1 mutant R673Q and the enzymatic activity was below the detection limit of the performed phosphatase assay. Whereas the protein level of the R673Q mutant was reduced in comparison to SHIP1 WT the mRNA level was comparable indicating a post-transcriptional regulation. SHIP1 R673Q was rapidly degraded, with a calculated half-life of l.5 h. In addition, SHIP1 R673Q levels were significantly increased by the treatment with the proteasome inhibitor MG-132 in comparison to the DMSO control. Therefore, SHIP1 was confirmed as the target of enhanced proteasomal degradation. Computational analysis of the wild type and mutant protein structures revealed that the loss of the positively charged arginine residue R673 is associated with the loss of two salt bridges to the negatively charged amino acids D617 and E634 leading to an intramolecular instability of the mutated SHIP1 R673Q protein. Six out of seven SHIP1 mutants significantly affected the PI3K/AKT/mTOR pathway in the three cancer cell lines H1299, Reh and Sem. Four out of seven SHIP1 mutants affected phosphorylation of AKT and its target GSK3ß positively compared to SHIP1 WT, whereas a negative effect on the phosphorylation of S6 was found in five out of seven mutants. In general, SHIP1 mutants impacting signal transduction were either associated with decreased SHIP1 activity or SHIP1 expression or both. Overall, the presented results indicate a regulation of the protein expression and activity of SHIP1 by patient-derived mutations in its phosphatase domain.

A toolkit for expression of Strep-tagged enhanced green fluorescent protein concatemers in mammalian cells.

Green fluorescent protein (GFP) and its variants are widely used tools in life sciences. Recently, we and others have used enhanced green fluorescent protein (EGFP) concatemers for determination of nuclear localization signal strength, as natural fluorescence standards and for mapping mobility in living cell nuclei. In this study, we present a molecular toolbox of Strep-tagged EGFP concatemers ranging from 1 to 12 subunits (Addgene plasmids #122488-122499). EGFP concatemers can be easily fused to targeting motifs of any origin by oligonucleotide ligation. Subsequently, we used liposomal transfection for transient expression of EGFP concatemers in eukaryotic cells. We have tested multiple protocols for further processing of the cells and recommend use of formalin or paraformaldehyde/methanol fixation. After usage of these protocols, we were able to detect concatemers by both GFP fluorescence microscopy and αStrep immunomicroscopy. In addition, we observed a more reliable detection of the StrepTag polypeptide (SA-WSHPQFEK) when using αStrepTag antibody instead of StrepTag binding protein. Summing up, we present a toolbox for expression of a wide range of Strep-tagged EGFP concatemers for multiple applications. By use of EGFP fluorescence and/or StrepTag polypeptide, the expressed concatemers can be easily detected in the cell.

A set of enhanced green fluorescent protein concatemers for quantitative determination of nuclear localization signal strength.

Regulated transport of proteins between nucleus and cytoplasm is an important process in the eukaryotic cell. In most cases, active nucleo-cytoplasmic protein transport is mediated by nuclear localization signal (NLS) and/or nuclear export signal (NES) motifs. In this study, we developed a set of vectors expressing enhanced GFP (EGFP) concatemers ranging from 2 to 12 subunits (2xEGFP to 12xEGFP) for analysis of NLS strength. As shown by in gel GFP fluorescence analysis and αGFP Western blotting, EGFP concatemers are expressed as fluorescent full-length proteins in eukaryotic cells. As expected, nuclear localization of concatemeric EGFPs decreases with increasing molecular weight. By oligonucleotide ligation this set of EGFP concatemers can be easily fused to NLS motifs. After determination of intracellular localization of EGFP concatemers alone and fused to different NLS motifs we calculated the size of a hypothetic EGFP concatemer showing a defined distribution of EGFP fluorescence between nucleus and cytoplasm (n/c ratio = 2). Clear differences of the size of the hypothetic EGFP concatemer depending on the fused NLS motif were observed. Therefore, we propose to use the size of this hypothetic concatemer as quantitative indicator for comparing strength of different NLS motifs.

A toolkit for graded expression of green fluorescent protein fusion proteins in mammalian cells.

Green fluorescent protein (GFP) and GFP-like proteins of different colors are important tools in cell biology. In many studies, the intracellular targeting of proteins has been determined by transiently expressing GFP fusion proteins and analyzing their intracellular localization by fluorescence microscopy. In most vectors, expression of GFP is driven by the enhancer/promoter cassette of the immediate early gene of human cytomegalovirus (hCMV). This cassette generates high levels of protein expression in most mammalian cell lines. Unfortunately, these nonphysiologically high protein levels have been repeatedly reported to artificially alter the intracellular targeting of proteins fused to GFP. To cope with this problem, we generated a multitude of attenuated GFP expression vectors by modifying the hCMV enhancer/promoter cassette. These modified vectors were transiently expressed, and the expression levels of enhanced green fluorescent protein (EGFP) alone and enhanced yellow fluorescent protein (EYFP) fused to another protein were determined by fluorescence microscopy and/or Western blotting. As shown in this study, we were able to (i) clearly reduce the expression of EGFP alone and (ii) reduce expression of an EYFP fusion protein down to the level of the endogenous protein, both in a graded manner.

Human inositol 1,4,5-trisphosphate 3-kinase isoform B (IP3KB) is a nucleocytoplasmic shuttling protein specifically enriched at cortical actin filaments and at invaginations of the nuclear envelope.

Recent studies have shown that inositol 1,4,5-trisphosphate 3-kinase isoform B (IP3KB) possesses important roles in the development of immune cells. IP3KB can be targeted to multiple cellular compartments, among them nuclear localization and binding in close proximity to the plasma membrane. The B isoform is the only IP3K that is almost ubiquitously expressed in mammalian cells. Detailed mechanisms of its targeting regulation will be important in understanding the role of Ins(1,4,5)P(3) phosphorylation on subcellular calcium signaling and compartment-specific initiation of pathways leading to regulatory active higher phosphorylated inositol phosphates. Here, we identified an exportin 1-dependent nuclear export signal ((134)LQRELQNVQV) and characterized the amino acids responsible for nuclear localization of IP3KB ((129)RKLR). These two targeting domains regulate the amount of nuclear IP3KB in cells. We also demonstrated that the localization of IP3KB at the plasma membrane is due to its binding to cortical actin structures. Intriguingly, all three of these targeting activities reside in one small polypeptide segment (amino acids 104-165), which acts as a multitargeting domain (MTD). Finally, a hitherto unknown subnuclear localization of IP3KB could be demonstrated in rapidly growing H1299 cells. IP3KB is specifically enriched at nuclear invaginations extending perpendicular between the apical and basal surface of the nucleus of these flat cells. Such nuclear invaginations are known to be involved in Ins(1,4,5)P(3)-mediated Ca(2+) signaling of the nucleus. Our findings indicate that IP3KB not only regulates cytoplasmic Ca(2+) signals by phosphorylation of subplasmalemmal and cytoplasmic Ins(1,4,5)P(3) but may also be involved in modulating nuclear Ca(2+) signals generated from these nuclear envelope invaginations.