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- Regulation of the catalytic subunits of NADPH oxidase Nox1 and NOX4 in rat mesangial cells (2005)
- The generation of O2- by NADPH oxidaes was mainly attributed to immune cells that kill invading bacteria or cancer cells. But importantly, in the past several years, several homologs of the catalytic subunit gp91phox (Nox2) of the phagocytic NADPH oxidase have been identified in non-immune cells and tissues. Superoxide production derived from NADPH oxidaes has been shown to play a role not only in host defense but also in defined signaling cascades mediating growth and apoptosis. The aim of this work was to study the expression and the regulation of the”new” Nox isoforms in rat renal mesangial cells (MC). In particular the following results were achieved. 1) mRNA’s for both Nox1 and Nox4 were detected by RT-PCR. 2) Nox1 mRNA levels were increased upon exposure to basic fibroblast growth factor (bFGF), platelet-derived growth factor (PDGF) and fetal calf serum (FCS) in a time- and dose-dependent manner. Exposure of MC to bFGF and FCS increased also basal production of reactive oxygen species (ROS) by MC. By contrast, Nox4 mRNA levels were not significantly affected by bFGF treatment, but were markedly down-regulated by PDGF and FCS. 3) To study the regulation of Nox1 on the protein level, an anti-Nox1 antibody was generated and characterized using affinity chromatography. Up-regulation of Nox1 expression by growth factors was confirmed also on the protein level. 4) Based on the already known cDNA sequence for Nox1, the transcriptional start site was determined by the “gene RACE” technique. 2547 bp of the genomic sequence of the 5´-flanking region of the Nox1 gene were cloned and sequenced using the „Genome-Walking“ method. To study the regulation of Nox1 transcription functional Nox1 promoter/luciferase fusions were be established. MC were transiently transfected with different promoter/luciferase constructs and stimulated with growth factors. By measuring luciferase activity it was determined that growth factors induced the Nox1 transcription and that the Nox1 core promoter is sufficient for the activation. 5) By measurement of superoxide radicals and analysis of Nox1 mRNA expression by quantitative RT-PCR (TaqMan) as well as protein level by Western blotting it could be shown that treatment of MC with NO donors inhibited the expression of Nox1 in a time- and dose-dependent manner. Moreover, using activators and inhibitors of the soluble guanylyl cyclase (sGC) it could be shown, that the activation of sGC mediates the effect of NO on Nox1 expression. However, NO had no inhibitory effect on Nox1 promoter activity. Experiments with the inhibitor of transcription, actinomycin D, suggest that NO-mediated regulation of Nox1 is triggered probably via post-transcriptional mechanisms. Nox4 is regulated on the mRNA levels in a similar manner as Nox1. 6) To analyze the sub-cellular localization of the Nox isoforms, coding sequences for Nox1 and Nox4 were fused together with green fluorescent protein into the pEGFP-N1 demonstrated that both isoforms are localized predominantly in the plasma membrane, but also in the perinuclear region and cytoplasm. However, the localization of Nox1 in the plasma membrane was more pronounced. 7) In addition to Nox1 and Nox4, mRNA of the newly identified NOXA1 that is a homolog of the p67phox subunit of NADPH oxidase was detected in MC by RT-PCR.
- Effect of chromatin modeling by histone deacetylase inhibitors (HDIs) on hematopoietic stem cell (HSC) fate (2005)
- Acute myeloid leukemia (AML) is characterized by the accumulation of a large number of abnormal, immature blast cells. Recently, histone deacetylase inhibitors (HDIs) received considerable interest on the ground of their ability to overcome the differentiation block in these leukemic blasts regardless of the primary genetic alteration, an effect achieved either alone or in combination with differentiating agents, such as all-trans retinoic acid (t-RA). Valproic acid (VPA), a potent HDI, is now under clinical evaluation owing to its potent differentiation effect on transformed hematopoietic progenitor cells and leukemic blasts from AML patients. Conversely, in a clinical study by Bug et al., the favorable effects of the combination treatment with t-RA/VPA in advanced acute myeloid leukemia patients were reported to be most likely due to an enhancement of nonleukemic myelopoiesis and the suppression of malignant hematopoiesis rather than enforced differentiation of the leukemic cells. Based on the hypothesis that VPA influences normal hematopoiesis, the effect of chromatin modeling through VPA on HSCs was investigated with respect to differentiation, proliferation as well as self-renewal in the present study. It has been shown that valproic acid increases both proliferation and self-renewal of HSC. It accelerates cell cycle progression of HSC accompanied by a down-regulation of p21cip-1/waf-1. Furthermore, valproic acid inhibits GSK3B by phosphorylation on Ser9 accompanied by an activation of the Wnt signaling pathway as well as by an up-regulation of HoxB4, a target gene of Wnt signaling. Both are known to directly stimulate the proliferation of HSC and to expand the HSC pool. To sum up, valproic acid, a potent histone deacetylase inhibitor known to induce differentiation and/or apoptosis in leukemic blasts, stimulates the proliferation and self-renewal of hematopoietic stem cells. Therefore, the data reported in this study suggest to reconsider the role of histone deacetylase inhibitors from a differentiation inducer to a coadjuvant factor for increasing the response to conventional therapy in acute myeloid leukemia.
- Role of rho GTPases in migration of stem and progenitor cells (2005)
- Stem cells capable of self-renewal and differentiation into multiple tissues are important in medicine to reconstitute the hematopoietic system after myelo-ablative chemo- or radiotherapy. In the present situation, adult stem cells such as Mesenchymal stem cells (MSC) and Hematopoietic stem cells (HSC) are used for therapeutic purposes. For tissue regeneration and tissue constitution, engraftment of transplanted stem cells is a necessary feature. However, in many instances, the transplanted stem cells reach the tissues with low efficiency. Considering the three-step model of leukocyte extravasation by Springer et al, the rolling, adhesion and transmigration form the three major steps for the transplanted stem cells to enter the desired tissues. One of the molecular switches reported to be involved in these mechanisms are the Rho family GTPases. The present study investigates the role of Rho GTPases in adhesion and migration of stem and progenitor cells. Chemotactic and chemokinetic migration assays, transendothelial migration assays, migration of cells under shear stress, microinjection, retroviral and lentiviral gene transfer methods, oligonucleotide microarray analysis and pull down assays were employed in this study for the elucidation of Rho GTPase involvement in migration and adhesion of stem and progenitor cells. The transmigration assay used for the migration determination of the adherent cell type, MSC, was optimized for the efficient and effective assessment of the migrating cells. The involvement of Rho was found to be critical for stem and progenitor cell migration where inactivation of Rho by C2I-C3 transferase toxin and/or overexpression of C3 transferase cDNA increased the migration rate of Hematopoietic progenitor cells (HPC) and MSC. Moreover, modulation of Rho caused predictable cytoskeletal and morphological changes in MSC. Assessment of Rho GTPase involvement in the interacting partner, the endothelial cells during stem cell migration, revealed that active Rho expression induced E-selectin expression. The increased levels of E-selectin were functionally confirmed by the increased adhesion of progenitor cells (HPC) to the Human umbilical vein endothelial cell (HUVEC) layer. Moreover, inhibition of Rac in the migrating endothelial progenitor cells (eEPC) increased their adhesion to HUVEC correlating with the increased percentage expression of cell surface receptor, CD44 in Rac inactivated eEPC. In conclusion, this study shows that Rho GTPases control the adhesion and migration of stem and progenitor cells, HPC and MSC. Rho inhibition drives the cells to migrate in the blood vessels. The substantial increase in the level of active Rho in endothelial layer, manifested by the E-selectin surface expression assists the better adhesion of stem and progenitor cells to the endothelial layer. Serum factors and growth factors in the physiological system influence the Rho GTPase expression in both migrating stem cells and the barrier endothelial cells. Thus, specific modulation of Rho GTPases in the transplanted stem and progenitor cells could be an interesting tool to improve the migration and homing processes of stem cells for cellular therapy in future.
- Untersuchungen zur Bedeutung des Kern-Zytoplasma Transports für die biologische Funktion zellulärer Proteine (2005)
- The thesis entitled „Investigations on the significance of nucleo-cytoplasmic transport for the biological function of cellular proteins" aimed to unreveal molecular mechanisms in order to improve our understanding of the impact of nucleo-cytoplasmic transport on cellular functions. Within the scope of this work, it could be shown that regulated nucleo-cytoplasmic transport of a subfamily of homeobox transcription factors controlled their intra- and intercellular transport, and thereby influencing also their transcriptional activity. This study describes a novel regulatory mechanism, which could in general play an important role for the ordered differentiation of complex organisms. Besides cis-active transport Signals, also post-translational modifications can influence the localization and biological activity of proteins in trans. In addition to the known impact of phosphorylation on the transport and activity of STAT1, experimental evidence was provided demonstrating that acetylation affected the interaction of STAT1 with NF-kB p65, and subsequently modulated the expression of apoptosis-inducing NF-kB target genes. The impact of nucleo-cytoplasmic transport on the regulation of apoptosis was underlined by showing that the evolutionary conservation of a NES within the anti-apoptotic protein survivin plays an essential role for its dual function in the inhibition of apoptosis and ordered cell division. Since survivin is considered a bona fide cancer therapy target, these results strongly encourage future work to identify molecular decoys that specifically inhibit the nuclear export of survivin as novel therapeutics. In order to further dissect the regulation of nuclear transport and to efficiently identify transport inhibitors, cell-based assays are urgently required. Therefore, the cellular assay Systems developed in this work may not only serve to identify synthetic nuclear export and Import inhibitors but may also be applied in systematic RNAi-screening approaches to identify novel components of the transport machinery. In addition, the translocation based protease- and protein-interaction biosensors can be applied in various biological Systems, in particular to identify protein-protein interaction inhibitors of cancer relevant proteins. In summary, this work does not only underline the general significance of nucleo-cytoplasmic transport for cell biology, but also demonstrates its potential for the development of novel therapies against diseases like cancer and viral infections.
- Role of enhanced stem cell capacities in leukemogenesis (2006)
- Unlimited self-renewal is an absolute prerequisite for any malignancy, and is the ultimate arbiter of the continuous growth and metastasis of tumors. It has been suggested that the self-renewal properties of a tumor are exclusively contained within a small population, i.e., the so-called cancer stem cells. Enhanced self-renewal potential plays a pivotal role in the development of leukemia. My data have shown that APL associated translocation products PML/RARalpha and PLZF/RARalpha increased the replating efficiency of mouse lin-/Sca1+ hematopoietic stem cells (HSCs). This effect is partly mediated by induction of gamma–catenin which is an important mediator of the Wnt signaling pathway and has been shown to be up regulated by the AML associated translocation products(AATPs). Suppression of gamma–catenin by siRNA can abrogate the increased replating efficiency induced by AATPs. Transduction of gamma–catenin in lin-/Sca1+ HSCs led to increased replating efficiency and the expression of stem cell markers Sca1 and c-kit. Additionally it induced accelerated cell cycle progression of mouse bone marrow HSCs. Transduction/transplantation mouse models have shown that ectopic expression of gamma–catenin in HSCs led to acute myeloid leukemia without maturation. These data suggest important roles of Wnt signaling pathway in the leukemogenesis induced by PML/RARalpha, PLZF/RARalpha and AML1/ETO. In contrast to AATPs, CML and Ph+-ALL associated translocation products p185(BCR-ABL) and p210(BCR-ABL) did not affect the self-renewal potential of hematopoietic stem/progenitor cells. However my studies indicated that their reciprocal translocation products p40(ABL/BCR) and p96(ABL/BCR) actually increased the replating efficiency of hematopoietic stem/progenitor cells. The effect is stronger when induced by p96(ABL/BCR) than by p40(ABL/BCR). It is very intriguing that p96(ABL/BCR) can activate Wnt signaling and up regulate the expression of HoxB4. Transduction/transplantation mouse model has shown that p40(ABL/BCR) and p96(ABL/BCR) both have their own leukemogenic potential. Given the fact that leukemic stem cells maintain the growth of tumor and are the origin of relapse, the cure of leukemia is dependent on the eradication of the leukemic stem cell and abrogation of aberrantly regulated self-renewal capability. Both t-RA and As2O3 have been shown to induce complete remission in APL patients with PML/RARalpha translocation product. However, t-RA as a single agent achieves completeremission (CR) but not complete molecular remissions (CMR). Therefore, virtually all patients will experience a relapse within a few months. In contrast to t-RA, As2O3 as a single agent is able to induce CR as well as CMR followed by long-term relapse-free survival in about 50% of APL patients even if relapsed after treatment with t-RA-containing chemotherapy regimens. Nothing is known about the mechanisms leading to the complete different clinical outcomes by the two compounds although both have been shown to induce differentiation of blast cells, proliferation arrest, induction of apoptosis and degradation of PML/RARalpha. We investigated the effect of t-RA and arsenic on PML/RARalpha-expressing cell population with stem cell capacity derived from the APL cell line NB4 as well as Sca1+/lin- murine bone marrow cells. We found that t-RA did not reduce the replating efficiency in PML/RARalpha- and PLZF/RARalpha-infected Sca1+/lincells whereas it selected small compact colonies representing very early progenitor cells. T-RA was unable to reduce the capacity to form colony forming units-spleen (CFU-S) of Sca1+/lin-cells expressing PML/RARalpha, additionally t-RA did not impair the capability of engraftment of NB4 cells in NOD/SCID mouse. On the contrary to t-RA, As2O3 abolished the aberrant self-renewal potential of Sca1+/lin- cells expressing PML/RARalpha. As2O3 not only abolished the replating efficiency of PML/RARalpha positive cells but also completely abrogated the ability of PML/RARalpha-positive HSC to produce CFU-S in vivo. On the contrary to As2O3, t-RA increased the absolute cell number and the percentage of cells in the side population with respect to the whole cell population in NB4 cells. Taken together these data suggest that arsenic but not all-trans retinoic acid overcomes the aberrant stem cell capacity of PML/RARalpha positive leukemic stem cells. My data prove for the first time that there is a direct relationship between the capacity of compounds to effectively target the LSC and their capacity to eradicate the leukemia, and, thereby, to induce complete molecular remission and long-term relapse-free survival. Thus, in order to increase the curative potential of leukemia therapies, future studies need to include the effect of given compounds on the stem cell compartment to determine their ability to eradicate the LSC.
- The role of oncogenic Cbl mutants in Kit signaling and myeloid transformation (2009)
- Acute myeloid leukemia (AML) is a hematopoietic cell disorder characterized by a block in differentiation and increased proliferation and survival of malignant blasts. Expansion of the malignant cell clone effects the normal production of blood cells and – if left untreated – leads to death. Receptor tyrosine kinases (RTKs) play an important role in the pathogenesis of AML, as they are either often mutated or overexpressed. In normal hematopoiesis, RTK signal termination is tightly controlled, and involves ubiquitination, internalization, endocytosis and degradation. Cbl proteins are E3 ligases and have been shown to ubiquitinate several activated RTKs, including Flt3 and Kit, targeting them for degradation. Recently, several Cbl mutations have been identified: Cbl-R420Q was identified in an AML patient and Cbl-70Z was identified in a mouse lymphoma model. In this thesis work, the role of these Cbl mutants in Kit signaling and in a mouse transplantation model was studied. Cbl mutants (Cbl-R420Q, Cbl-70Z) have the ability to transform the myeloid 32D cell line in cooperation with Kit WT. Cbl mutants along with Kit promoted interleukin-3 (IL3)-independent proliferation and enhanced the cell survival of 32D cells. In contrast, expression of the Cbl mutants alone did not confer IL3-independent growth. Stem cell factor (SCF, the Kit ligand) dependent growth was enhanced in the presence of Cbl mutants and Cbl mutants promoted colonogenic growth in the presence of Kit. Furthermore, Cbl mutants inhibited the ubiquitination of the activated Kit receptor. In addition, Cbl mutants inhibited the endocytosis of the activated Kit receptor. Retroviral expression of Cbl mutants in transplanted bone marrow induced a generalized mastocytosis, a myeloproliferative disease and, in rare care cases, myeloid leukemia. Splenomegaly was observed in the presence of Cbl mutants. Furthermore, mast cells with variable range of infiltration were noticed in all the vital organs (spleen, liver, bone marrow, lung, kidney, heart) of Cbl (mutant) transplanted mice. Almost all recipients of bone marrow cells transduced with Cbl mutants developed a lethal hematologic disorder with a mean latency of 341 days in the Cbl-R420Q group and 395 days in the Cbl-70Z group. This is the first published report on a hematological disease with Cbl mutants in a mouse model. Co-immunoprecipitation studies indicated that Cbl-70Z binds to Kit, even in the absence of Kit ligand. Cbl-R420Q also bound to Kit in the absence of SCF, albeit to a lesser extent. Association of Cbl mutants to Kit was enhanced in the presence of SCF. Signaling studies demonstrated the constitutive activation of Akt and Erk in the presence of Cbl mutants and Kit. In addition, Cbl mutants enhanced the SCF-dependent Kit, Akt and Erk activation. Cbl-70Z, in association with kinase-dead Kit (Kit-KD) or kinase-dead Flt3 (Flt3-KD), conferred IL3-independent growth and survival to the myeloid 32D cell line. Cbl-R420Q provided only a slight growth advantage in the presence of Kit-KD. As demonstrated by pharmacological inhibition studies, Akt activation was necessary for the transformation mediated by Cbl-70Z and Kit-KD / Flt3-KD. Cbl mutants enhanced the Src family kinases (SFKs) activity. The pharmacological inhibition of SFK activity inhibited the proliferation and colonogenic growth. Interaction was found between Cbl-70Z, SFKs and Kit-KD. The SFK member Fyn was identified to bind to Cbl. In addition, kinase activity of SFKs was necessary for binding to Cbl, since SFKs inhibition by PP-2 abolished the binding between the complex-binding partners. Dasatinib and PP-2, both SFK inhibitors, inhibited the Cbl and Akt phosphorylation indicating that Fyn acts upstream of Akt. Inhibition of Kit with imatinib reduced the proliferation of cells overexpressing Kit WT and Cbl-70Z much stronger compared with cells expressing Kit-KD and Cbl-70Z, but much less than the dual KIT/SFK inhibitor dasatinib. This indicated that Kit kinase activity was required but not essential. The data presented in this thesis work implies that both RTK and SFK inhibition may have to be targeted, in order to effectively prevent transformation. In summary, the present thesis work indicates an important role of Cbl, Kit and SFKs in myeloid transformation and deregulated signal transduction.
- Characterization of the poxviral 68k ankyrin-like protein (2009)
- Orthopoxviruses are large DNA viruses that replicate within the cytoplasm of infected cells encoding over a hundred different proteins. The orthopoxviral 68k ankyrin‐like protein (68k‐ank) is highly conserved among orthopoxviruses, and this study aimed at elucidating the function of 68k‐ank. The 68k‐ank protein is composed of four ankyrin repeats (ANK) and an F‐box‐like domain; both motifs are known proteinprotein interaction domains. The F‐box is found in cellular F‐box proteins (FBP), crucial components of cellular E3 ubiquitin (Ub) ligases. With yeast‐two‐hybrid screens and subsequent co‐immunoprecipitation analyses, it was possible to identify S‐phase kinase‐associated protein 1a (Skp1a) as a cellular counterpart of 68k‐ank via binding to the F‐box‐like domain. Additionally, Cullin‐1 was co‐precipitated, suggesting the formation of a viral‐cellular SCF E3 Ub ligase complex. Modified Vaccinia virus Ankara (MVA) ‐ being attenuated and unable to replicate in most mammalian cell lines due to a block in morphogenesis – nevertheless, expresses its complete genetic information attributing to its properties as promising vector vaccine. Conservation of 68k‐ank as the only ANK protein encoded by MVA implied a substantial role of this viral factor. Hence, its function in the viral life cycle was assessed by studying a 68k‐ank knock‐out MVA. A mutant phenotype manifested in nonpermissive mammalian cells characterized by a block succeeding viral early gene expression and by a reduced ability of the virus to shutoff host protein synthesis. Studies with MVA encoding a 68k‐ank F‐box‐like domain truncated protein revealed that viral‐cellular SCF complex formation and maintenance of viral gene expression are two distinct, unrelated functions fulfilled by 68k‐ank. Moreover, K1, a well‐described VACV host range factor of the ANK protein family, is able to complement 68k‐ank function. This suggests that gene expression of MVA putatively depends on the ANKs encoded in 68k‐ank. In addition to the important findings in vitro, first virulence studies with the mouse pox agent, ectromelia virus (ECTV) deleted of the 68k‐ank ortholog (C11) suggested that this factor contributes to ECTV virulence in vivo.
- Novel approaches of molecular targeting in Philadelphia chromosome positive leukemia (2009)
- In Philadelphia Chromosome (Ph) positive ALL and CML the fusion between BCR and ABL leads to the BCR/ABL fusion proteins, which induces the leukemic phenotype because of the constitutive activation of multiple signaling pathways down-stream to the aberrant BCR/ABL fusion tyrosine kinase. Targeted inhibition of BCR/ABL by ABL-kinase inhibitors induces apoptosis in BCR/ABL transformed cells and leads to complete remission in Ph positive leukemia patients. However, a large portion of patients with advanced Ph+ leukemia relapse and acquire resistance. Kinase domain (KD) mutations interfering with inhibitor binding represent the major mechanism of acquired resistance in patients with Ph+ leukemia. Tetramerization of BCR/ABL through the N-terminal coiled-coil region (CC) of BCR is essential for the ABL-kinase activation. Targeting the CC-domain forces BCR/ABL into a monomeric conformation, reduces its kinase activity and increases the sensitivity for Imatinib. Here we show that i.) targeting the tetramerization by a peptide representing the Helix-2 of the CC efficiently reduced the autophosphorylation of both WT BCR/ABL and its mutants; ii.) Helix-2 inhibited the transformation potential of BCR/ABL independently of the presence of mutations; iii.) Helix-2 efficiently cooperated with Imatinib as revealed by their effects on the transformation potential and the factor-independence related to BCR/ABL with the exception of mutant T315I. These findings suggest that BCR/ABL harboring the T315I mutation have a transformation potential which is at least partially independent from its kinase activity. Targeted inhibition of BCR/ABL by small molecule inhibitors reverses the transformation potential of BCR/ABL. We definitively proved that targeting the tetramerization of BCR/ABL mediated by the N-terminal coiled-coil domain (CC) using competitive peptides, representing the Helix-2 of the CC, represents a valid therapeutic approach for treating Ph+ leukemia. To further develop competitive peptides for targeting BCR/ABL, we created a membrane permeable Helix-2 peptide (MPH-2) by fusing the Helix-2 peptide with a peptide transduction tag. In this study, we report that the MPH-2: (i) interacted with BCR/ABL in vivo; (ii) efficiently inhibited the autophosphorylation of BCR/ABL; (iii) suppressed the growth and viability of Ph+ leukemic cells; and (iv) was efficiently transduced into mononuclear cells (MNC) in an in vivo mouse model. The T315I mutation confers resistance against all actually approved ABL-kinase inhibitors and competitive peptides. It seems not only to decrease affinity for kinase inhibitors but to confer additional features to the leukemogenic potential of BCR/ABL. To determine the role of T315I in resistance to the inhibition of oligomerization and in the leukemogenic potential of BCR/ABL, we investigated its influence on loss-of-function mutants with regard to the capacity to mediate factor-independence. Thus we studied the effects of T315I on BCR/ABL mutants lacking functional domains in the BCR portion indispensable for the oncogenic activity of BCR/ABL such as the N-terminal coiled coil (CC), the tyrosine phosphorylation site Y177 and the serine/threonine kinase domain (ST), as well as on the ABL portion of BCR/ABL (#ABL-T315I) with or without the inhibitory SH3 (delta SH3-ABL) domain. Here we report that i.) T315I restored the capacity to mediate factor independence of oligomerization_deficient p185BCR/ABL; ii.) resistance of p185-T315I against inhibition of the oligomerization depends on the phosphorylation at Y177; iii.) autophosphorylation at Y177 is not affected by the oligomerization inhibition, but phosphorylation at Y177 of endogenous BCR parallels the effects of T315I; iv.) the effects of T315I are associated with an intact ABL_kinase activity; v.) the presence of T315I is associated with an increased ABL_kinase activity also in mutants unable to induce Y177 phosphorylation of endogenous BCR; vi.) there is no direct relationship between the ABL-kinase activity and the capacity to mediate factor_independence induced by T315I as revealed by the #ABL-T315I mutant, which was unable to induce Y177 phosphorylation of BCR only in the presence of the SH3 domain. In contrast to its physiological counterpart c-ABL, the BCR/ABL kinase is constitutively activated, inducing the leukemic phenotype. The N-terminus of c-ABL (Cap region) contributes to the regulation of its kinase function. It is myristoylated, and the myristate residue binds to a hydrophobic pocket in the kinase domain known as the myristoyl binding pocket in a process called “capping”, which results in an auto-inhibited conformation. Because the cap region is replaced by the N-terminus of BCR, BCR/ABL “escapes” this auto-inhibition. Allosteric inhibition by myristate “mimics”, such as GNF-2, is able to inhibit unmutated BCR/ABL, but not the BCR/ABL that harbors the “gatekeeper” mutation T315I. Here we investigated the possibility of increasing the efficacy of allosteric inhibition by blocking BCR/ABL oligomerization. We demonstrate that inhibition of oligomerization was able not only to increase the efficacy of GNF-2 on unmutated BCR/ABL, but also to overcome the resistance of BCR/ABL-T315I to allosteric inhibition. These results strongly suggest that the response to allosteric inhibition by GNF-2 is inversely related to the degree of oligomerization of BCR/ABL. Taken together these data suggest that the inhibition of tetramerization inhibits BCR/ABL-mediated transformation and can contribute to overcome Imatinib-resistance. The study provides the first evidence that an efficient peptide transduction system facilitates the employ-ment of competitive peptides to target the oligomerization interface of BCR/ABL in vivo. Further the data show that T315I confers additional leukemogenic activity to BCR/ABL, which might explain the clinical behavior of patients with BCR/ABL -T315I-positive blasts. In summary, our observations establish a new approach for the molecular targeting of BCR/ABL and its resistant mutants represented by the combination of oligomerization and allosteric inhibitors.
- Role of SOCS proteins in FLT3-ITD and BCR/ABL mediated leukemogenesis (2010)
- Acute myeloid/lymphoid leukemia is a fatal hematological malignancy characterized by accumulation of nonfunctional, immature blasts, which interferes with the production of normal blood cells. Activating mutations of receptor tyrosine kinases are common genetic lesions in leukemia. FLT3-ITD is a frequent activating mutation found in AML patients, leading to uncontrolled proliferation of leukemic blasts. FLT3-ITD directly activates STAT5, leading to the induction of STAT5 target gene expression like PIM kinases and SOCS genes. STAT5 and PIM kinases have been shown to play a crucial role in the FLT3-ITD mediated transformation. On the other hand, the role of SOCS proteins in FLT3-ITD mediated transformation has not been studied to date. SOCS proteins are part of a negative feedback mechanism that controls Jak kinases downstream of cytokine receptors. One of the SOCS family members, SOCS1 has been reported to suppress oncogenecity of several activating kinases implicated in hematologic malignancies. In this thesis the role of these SOCS proteins in FLT3-ITD mediated transformation (in vitro) and leukemogenesis (in vivo) is systematically explored. Expression of FLT3-ITD in cell lines of myeloid (32D) and lymphoid (Ba/F3) origin, led to CIS, SOCS1 and SOCS2 expression. FLT3-ITD expression in primary murine bone marrow stem/progenitor cells led to a 59 fold induction of SOCS1 expression. Furthermore, FLT3-ITD positive AML cell lines (MV4-11, MOLM-13) show kinase dependent CIS, SOCS1, and SOCS3 expression. Importantly SOCS1 is highly expressed in AML patients with FLT3-ITD compared to healthy individuals. SOCS1 protein was expressed in FLT3-ITD transduced murine bone marrow stem cells and SOCS1 expression was abolished with kinase inhibition in MOLM-13 cell line. In conclusion, SOCS1 was highly regulated by FLT3-ITD in myeloid, lymphoid cell lines, in bone marrow stem/progenitors and in AML patient samples. SOCS1 co-expression did not affect FLT3-ITD mediated signaling and proliferation, but abolished IL-3 mediated proliferation and protected 32D cells from interferon-α and interferon-γ mediated growth inhibition. FLT3-ITD expressing 32D cells showed diminished STAT1 activation in response to interferons (α and γ). Alone, SOCS1 strongly inhibited cytokine induced colony formation of bone marrow stem and progenitors, but not FLT3-ITD induced colony formation. Most importantly, in the presence of growth inhibitory interferon-γ, SOCS1 co-expression with FLT3-ITD led to increased colony formation compared to FLT3-ITD alone. Taken together, FLT3-ITD induced and exogenously expressed SOCS1, shielded cells from external cytokines, signals, while not affecting FLT3-ITD induced proliferation/signaling. In further experiments the in vivo effects of SOCS1 were studied in a bone marrow transplantation model. SOCS1 bone marrow transplants were unable to engraft/proliferate in mice. FLT3-ITD was shown to induce a myeloproliferative disease. Both control (empty vector), SOCS1 transplanted mice were normal and did not show any disease phenotype. FLT3-ITD alone and SOCS1 co-expressing FLT3-ITD developed either myeloproliferative disease or acute lymphoblastic leukemia with equal distribution. SOCS1 co-expression with FLT3-ITD led to a decreased latency. Mice transplanted with FLT3-ITD alone and SOCS1 co-expressing FLT3-ITD displayed enlarged spleens, liver and hypercellular bone marrow indicating infiltration of leukemic cells. Mice were also anemic and showed decreased platelet counts. Importantly SOCS1 co-expression particularly shortened the latency of myeloproliferative disease but not of acute lymphoblastic leukemia. In summary, in the context of FLT3-ITD, SOCS1 acts as a ‘conditional oncogene’ and cooperates with FLT3-ITD in the development of myeloproliferative disease. With these data we propose the following model: FLT3-ITD induces SOCS gene expression, which shields cells against proliferation and differentiation signals from cytokines, while not affecting FLT3-ITD mediated proliferative signals. This leaves cells under the dictate of FLT3-ITD thereby contributing to leukemogenesis. Similar to FLT3-ITD, BCR/ABL (P190) (an oncogenic fusion kinase often found in acute lymphoblastic leukemia) induces SOCS gene expression in K562 and long-term cultured cells from patients with acute lymphoblastic leukemia. SOCS1 co-expression does not affect BCR/ABL mediated proliferation while abrogating IL-3 mediated proliferation. These findings suggest that SOCS proteins may play a general co-operative role in the context of oncogenes which aberrantly activate STAT3/5 independently of JAK kinases. This study reveals a novel molecular mechanism of FLT3-ITD mediated leukemogenesis and suggests SOCS genes as potential therapeutic targets.
- TK.007: a novel, optimized HSVtk-variant for suicide gene therapy (2010)
- Suicide genes have been broadly used in gene therapy. They can serve as safety tools for conditional elimination of infused cells or for directed tumor therapy. To date, the Herpes simplex virus thymidine kinase/ ganciclovir (HSVtk/GCV) system is the most prominent and the most widely used suicidegene/prodrug combination. Despite its promising performance, the system displays limitations, which include relatively slow killing kinetics and toxicity of the prodrug GCV. Consequently, several groups have either developed new suicide-gene/prodrug combinations or attempted to improve the established HSVtk/GCV suicide system. The present study also aimed towards optimization of the HSVtk/GCV system. To do so, a novel, codon-optimized point mutant (A168H) of HSVtk was developed. The novel mutant was named TK.007. It was extensively tested for its efficiency in two relevant settings: (1) control of severe graft-versus-host disease (GvHD) after adoptive immunotherapy with Tlymphocytes, and (2) direct elimination of targeted tumor cells. TK.007 was compared to the broadly used wild-type, splice-corrected scHSVtk and to a codon-optimized HSVtk (coHSVtk) not bearing the above point mutation. (1) For experiments related to the adoptive immunotherapy approach, HSVtkvariants were expressed from a γ-retroviral MP71 vector as a fusion construct with the selection and marker gene tCD34. Expression levels for TK.007 in transduced lymphoid and myeloid cell lines were significantly higher at initial transduction and over a 12 week period compared to the commonly used scHSVtk and coHSVtk indicating reduced toxicity of TK.007. Killing kinetics of transduced cell lines (PM1 and K562) and primary human T cells were significantly faster for TK.007 in comparison to scHSVtk and coHSVtk in vitro. In vivo-functionality of TK.007 was assessed in an allogeneic transplantation model. T cells derived from C57BL/6J.Ly5.1 donor mice were transduced with MP71 vectors expressing scHSVtk or TK.007. Transduced cells were selected and transplanted into Balb/c Rag2-/- γ-/- immune-deficient recipient mice. Acute, severe GvHD occurred and was effectively abrogated in all mice transplanted with TK.007- transduced T cells, and in five out of six mice transplanted with scHSVtk-transduced cells. In a slightly modified quantitative allogeneic transplantation mouse model, significantly faster and more efficient in vivo killing was demonstrated for TK.007 as compared to scHSVtk, especially at low doses of GCV. (2) In order to assess TK.007 functionality in cells derived from solid tumors, HSVtk-variants were expressed from lentiviral gene ontology (LeGO) vectors in combination with an eGFP/neo-opt selection cassette. Transduced and selected tumor cell lines that derived from several tissues were eliminated at significantly lower GCV doses and to higher extents when transduced with TK.007 compared to scHSVtk. Moreover, a significantly stronger bystander effect of TK.007 was demonstrated. The superior in vitro efficiency of TK.007 was confirmed in an in vivo subcutaneous xenograft mouse model for glioblastoma in NOD/SCID mice. Mice transplanted with TK.007 transduced cells stayed tumor-free after treatment with different GCV-doses. On the contrary, mice of the scHSVtk group either demonstrated only transiently reduced tumor growth in the low-dose GCV group (10 mg/kg) compared to the control groups or suffered from relatively fast relapses after initial tumor shrinking in the standarddose (50 mg/kg) GCV group. As a result, all mice in the scHSVtk group died from vigorous tumor growth. In summary, in two different applications for suicide gene therapy the present study has demonstrated superior functional performance of the novel suicide gene TK.007 as compared to the broadly used wild-type scHSVtk. Differences became particularly pronounced at low doses of GCV. It can be concluded that the new TK.007-gene represents a promising alternative to the commonly used scHSVtk for gene therapeutic applications.