Activity patterns of proteasome subunits reflect bortezomib sensitivity of hematologic malignancies and are variable in primary human leukemia cells.

Proteasomal proteolysis relies on the activity of six catalytically active proteasomal subunits (beta1, beta2, beta5, beta1i, beta2i and beta5i). Applying a functional proteomics approach, we used a recently developed activity-based, cell-permeable proteasome-specific probe that for the first time allows differential visualization of individual active proteasomal subunits in intact primary cells. In primary leukemia samples, we observed remarkable variability in the amounts of active beta1/1i-, beta2/2i- and beta5/5i-type of subunits, contrasting with their constant protein expression. Bortezomib inhibited beta5- and beta1-type, but to a lesser extend beta2-type of subunits in live primary cells in vitro and in vivo. When we adapted the bortezomib-sensitive human acute myeloid leukemia cell line HL-60 to bortezomib 40 nM (HL-60a), proteasomal activity profiling revealed an upregulation of active subunits, and residual beta1/beta5-type of activity could be visualized in the presence of bortezomib 20 nM, in contrast to control cells. In a panel of cell lines from hematologic malignancies, the ratio between beta2-type and (beta1 + beta5)-type of active proteasomal polypeptides mirrored different degrees of bortezomib sensitivity. We thus conclude that the proteasomal activity profile varies in primary leukemia cells, and that the pattern of proteasomal subunit activity influences the sensitivity of hematologic malignancies toward bortezomib.

Improved sensitivity proteomics by postharvest alkylation and radioactive labelling of proteins.

We describe approaches to improve the detection of proteins by postharvest alkylation and subsequent radioactive labeling with either [3H]iodoacetamide or 125I. Database protein sequence analysis suggested that cysteine is not suitable for detection of the entire proteome, but that cysteine alkylating reagents can increase the number of proteins able to be detected by iodination chemistry. Proteins were alkylated with beta-(4-hydroxyphenyl)ethyl iodoacetamide, or with 1,5-l-AEDANS (the Hudson Weber reagent). Subsequent iodination using the Iodo-Gen system was found to be most efficient. The enhanced sensitivity obtainable by using these approaches is expected to be sufficient for visualization of the lowest copy number proteins from human cells, such as from clinical samples. However, we argue that significantly improved methods of protein separation will be necessary to resolve the large number of proteins expected to be detectable with this sensitivity.

The two subunits of the interleukin-4 receptor mediate independent and distinct patterns of ligand endocytosis.

Interleukin-4 (IL-4) triggers cellular responses by interaction with the bipartite interleukin-4 receptor (IL-4R). IL-4-responsive cells specifically endocytose IL-4. We studied the ligand internalization properties of the human IL-4R and analyzed the specific functions of its two subunits IL-4Ralpha and gammac in this process. IL-4 mutant RY, which binds to IL-4Ralpha but does not recruit gammac into the receptor complex was used as a tool to show that IL-4Ralpha can promote independent ligand uptake in human T cells. Internalization was limited, however, by rapid IL-4 dissociation, suggesting that one important function of gammac in IL-4 endocytosis is to retain the ligand sufficiently long within the ternary receptor complex. We then measured IL-4 internalization by murine Ba/F3 cells that were stably transfected with various human IL-4R constructs. Efficient IL-4 uptake required the cytoplasmic section of the receptor. The intracellular domains of IL-4Ralpha and gammac were responsible for independent endocytosis processes with distinct kinetics. IL-4Ralpha-mediated internalization resulted in long-term intracellular maintainance of IL-4, whereas gammac directed the associated radioligand to intracellular breakdown and rapid release in the form of degraded protein. Mutants of either IL-4R subunit deficient in Janus kinase activation were not impaired in internalization, indicating that IL-4 endocytosis is not functionally connected to signal transduction.

Activation of STAT5 by IL-4 relies on Janus kinase function but not on receptor tyrosine phosphorylation, and can contribute to both cell proliferation and gene regulation.

We have investigated mechanisms and consequences of STAT5 activation through the human IL-4 receptor (IL-4R). By functionally expressing receptor mutants in the murine pro-B cell line Ba/F3, we could show that phosphorylated tyrosine residues within the IL-4R alpha chain are dispensable for IL-4-induced STAT5 activity. However, disruption of a membrane-proximal proline-rich sequence motif ('box1') in either subunit of the bipartite IL-4R abolished not only ligand-induced tyrosine phosphorylation of Janus kinases JAK1 and JAK3, but also IL-4-triggered activation of STAT5 and concomitant cell proliferation. A dominant-negative version of STAT5b, but not of STAT5a, interfered with IL-4-induced DNA synthesis in Ba/F3 cells, suggesting an involvement of STAT5b in the control of cell proliferation through IL-4R. Reporter gene experiments finally showed that transcription from promoters of STAT5 target genes can be specifically induced by challenging cells with IL-4, and that both STAT5a and STAT5b can contribute to IL-4-triggered transcriptional control.

The interleukin-4 receptor activates STAT5 by a mechanism that relies upon common gamma-chain.

Interleukin (IL)-4 signaling proceeds via cytoplasmic activation of the Janus kinases JAK1 and JAK3 and the signal transducer and activator of transcription STAT6. We show that the IL-4 receptor, like other cytokine receptor systems utilizing the common receptor gamma-chain (gammac), is also connected to a signaling pathway that involves STAT5. Both STAT5a and STAT5b become tyrosine-phosphorylated and acquire specific DNA-binding properties in response to IL-4 receptor stimulation in the murine pro-B cell line Ba/F3. In preactivated human T cells, STAT5 became activated in an IL-4-dependent fashion as assayed by IL-4-induced STAT5 translocation from the cytoplasm to the cell nucleus and by binding to cognate DNA. Moreover, stimulation of preactivated human T cells by IL-4 led to specific transcriptional up-regulation of STAT5 target genes. IL-4 receptor-mediated STAT5 activation is dependent on the presence of gammac and JAK3 within the receptor complex. In COS-7 cells, the JAK/STAT pathway leading from the IL-4 receptor to STAT5-dependent regulation of a reporter gene relied largely on coexpression of JAK3. In Ba/F3 cells, studies on signal transduction evoked by directed specific receptor homo- or heterodimerization revealed that STAT5 activation can be triggered exclusively by IL-4R heterodimers containing gammac.

Activation of STAT6 is not dependent on phosphotyrosine-mediated docking to the interleukin-4 receptor and can be blocked by dominant-negative mutants of both receptor subunits.

Stimulation of susceptible cells by interleukin-4 leads to activation of signal transducer and activator of transcription (STAT6) through tyrosine phosphorylation and dimerisation, thus directing it to the cell nucleus and rendering it a sequence-specific transcription factor. We functionally reconstituted human interleukin-4 receptor complexes with intracellular truncations of either the alpha or gamma subunits and demonstrate the requirement for elements from both receptor chains for STAT6 activation induced by interleukin-4. By assaying the signalling properties of human interleukin-4-receptor alpha-chain-deletion constructs in both Ba/F3 cells and COS-7 cells, we show that all its cytoplasmic tyrosine residues can be removed without affecting the capability of the receptor complex to trigger STAT6 function with regard to tyrosine phosphorylation, DNA binding, and specific gene transcription. The activation of both STAT6 and janus kinase 1 (JAK1) by the interleukin-4 receptor was completely abolished by disruption of the membrane-proximal 'box1' motif in the interleukin-4 receptor alpha chain. Our results indicate a redundant role of the previously defined phosphotyrosine-containing STAT6 docking site and suggest a mechanism of immediate activation of STAT6 by receptor-associated janus kinase(s). In addition, we demonstrate that dominant negative versions of both interleukin-4 receptor subunits are able to block interleukin-4 induced signalling via STAT6.

Receptor-associated constitutive protein tyrosine phosphatase activity controls the kinase function of JAK1.

Exposure of cells to protein tyrosine phosphatase (PTP) inhibitors causes an increase in the phosphotyrosine content of many cellular proteins. However, the level at which the primary signaling event is affected is still unclear. We show that Jaks are activated by tyrosine phosphorylation in cells that are briefly exposed to the PTP inhibitor pervanadate (PV), resulting in tyrosine phosphorylation and functional activation of Stat6 (in addition to other Stats). Mutant cell lines that lack Jak1 activity fail to support PV-mediated [or interleukin 4 (IL-4)-dependent] activation of Stat6 but can be rescued by complementation with functional Jak1. The docking sites for both Jak1 and Stat6 reside in the cytoplasmic domain of the IL-4 receptor alpha-chain (IL-4Ralpha). The glioblastoma-derived cell lines T98G, GRE, and M007, which do not express the IL-4Ralpha chain, fail to support Stat6 activation in response to either IL-4 or PV. Complementation of T98G cells with the IL-4Ralpha restores both PV-mediated and IL-4-dependent Stat6 activation. Murine L929 cells, which do not express the gamma common chain of the IL-4 receptor, support PV-mediated but not IL-4-dependent Stat6 activation. Thus, Stat6 activation by PV is an IL-4Ralpha-mediated, Jak1-dependent event that is independent of receptor dimerization. We propose that receptor-associated constitutive PTP activity functions to down-regulate persistent, receptor-linked kinase activity. Inhibition or deletion of PTP activity results in constitutive activation of cytokine signaling pathways.

Comparison of the transactivation domains of Stat5 and Stat6 in lymphoid cells and mammary epithelial cells.

Stat (signal transducers and activators of transcription) and Jak (Janus kinases) proteins are central components in the signal transduction events in hematopoietic and epithelial cells. They are rapidly activated by various cytokines, hormones, and growth factors. Upon ligand binding and cytokine receptor dimerization, Stat proteins are phosphorylated on tyrosine residues by Jak kinases. Activated Stat proteins form homo- or heterodimers, translocate to the nucleus, and induce transcription from responsive genes. Stat5 and Stat6 are transcription factors active in mammary epithelial cells and immune cells. Prolactin activates Stat5, and interleukin-4 (IL-4) activates Stat6. Both cytokines are able to stimulate cell proliferation, differentiation, and survival. We investigated the transactivation potential of Stat6 and found that it is not restricted to lymphocytes. IL-4-dependent activation of Stat6 was also observed in HC11 mammary epithelial cells. In these cells, Stat6 activation led to the induction of the beta-casein gene promoter. The induction of this promoter was confirmed in COS7 cells. The glucocorticoid receptor was able to further enhance IL-4-induced gene transcription through the action of Stat6. Deletion analysis of the carboxyl-terminal region of Stat6 and recombination of this region with a heterologous DNA binding domain allowed the delimitation and characterization of the transactivation domain of Stat6. The potencies of the transactivation domains of Stat5, Stat6, and viral protein VP16 were compared. Stat6 had a transactivation domain which was about 10-fold stronger than that of Stat5. In pre-B cells (Ba/F3), the transactivation domain of Stat6 was IL-4 regulated, independently from its DNA binding function.

Homodimerization of interleukin-4 receptor alpha chain can induce intracellular signaling.

The possible role of homodimerization events in intracellular signal transduction triggered by the bipartite human interleukin-4 receptor was addressed. We generated cell lines functionally expressing derivatives of the two receptor subunits alpha and gamma, which allow for a specific and background-free experimental induction of intracellular homo- and heterodimers. A heterodimer of alpha and gamma released an intracellular signal, whereas a gamma-gamma homodimer did not. Unexpectedly, we found the intracellular domain of interleukin-4 receptor alpha chain to evoke cell proliferation and activation of tyrosine kinase Jak1 as well as of transcription factor Stat6 upon homodimerization. Both recruitment of the common gamma chain and activation of kinase Jak3 were shown to be dispensible for these processes.

A chemiluminescence-based method for the detection and quantification of antigen-antibody interactions on the surface of eukaryotic cells.

Enhanced chemiluminescence was applied to detect the binding of monoclonal antibodies to surface antigens on intact cells. The fast and simple assay is performed in the microtiter scale and thus allows for the simultaneous processing of a large number of samples with a sensitivity comparable to conventionally used techniques such as cytometry or Western blot analysis. In two model experiments, we demonstrate (a) the detection of a heterologously expressed cytokine receptor subunit on the surface of suspension cells and (b) the screening of hybridoma clones for the production of antibodies specifically recognizing surface antigens on a tumor cell line. Moreover, the assay is shown to be suitable for the determination of antibody affinities and of antibody binding sites per cell.

Different human interleukin-4 mutants preferentially activate human or murine common receptor gamma chain.

Interleukin-4 (IL-4) shows species-specific activity due to species-restricted interaction with the IL-4 receptor alpha (IL-4R alpha) chain. The second subunit of a functional IL-4 receptor, the common gamma chain (gamma c), is more promiscuous, since human IL-4 is able to activate IL-4 receptor complexes containing either human or murine common gamma receptor chain (gamma c). We have stably transfected factor-dependent mouse cells of myeloid and lymphoid origin with combinations of human IL-4R alpha and gamma c derivatives. In these cell lines, both human and murine gamma c receptors as well as IL-4R alpha chains from both species are simultaneously expressed. Both versions of gamma c readily form ternary complexes with either human IL-4 and human IL-4R alpha or murine IL-4 and murine IL-4R alpha. Due to distinct ligand-binding properties of human and murine gamma c, the two receptor complexes can be activated preferentially by different mutant variants of human IL-4. The contribution of murine common gamma chain to human IL-4-induced signal transduction is suppressed by an inhibitory antibody directed to the extracellular domain of the mouse gamma c. We present evidence that the two IL-4R complexes functionally interfere with each other and compete for response-limiting signalling components.

Species-specific agonist/antagonist activities of human interleukin-4 variants suggest distinct ligand binding properties of human and murine common receptor gamma chain.

Interleukin-4 (IL-4) is a pleiotropic cytokine eliciting various responses in target cells upon binding to its receptor. Activation of the IL-4 receptor probably involves interaction of the ligand with both the IL-4 receptor alpha subunit (IL-4R alpha) and the common gamma chain (c gamma). Although human and murine IL-4 receptor alpha chains are specific for IL-4 from the same species, murine c gamma can form a signal-competent complex with human IL-4R alpha (hIL-4R alpha) and human IL-4 (hIL-4). We have generated a hIL-4 responsive murine myeloid cell line (FDC-4G) expressing a chimera comprising the extracellular domain of human IL-4R alpha and the intracellular domain of human granulocyte colony-stimulating factor receptor (hG-CSFR). This hybrid receptor was shown to form a complex with hIL-4 and the murine c gamma-chain. Biological activities of human IL-4 variants on murine FDC-4G cells and on the human erythroleukemic cell line TF-1 displayed a strikingly different pattern. Single amino acid replacements at two different positions in the C-terminal helix of hIL-4, the region of the previously defined "signaling site," lead to an inverse agonist/antagonist behavior of the resulting cytokines in the two cellular systems. From these findings we conclude that upon formation of the activated IL-4 receptor complex murine and human c gamma interact with hIL-4 in a geometrically different fashion.