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Metastasis is the cause of death in 90% of cancer-related deaths in men. Melanoma and Non-Small-Cell Lung Cancer (NSCLC) are both tumour types with poor prognosis, lacking appropriate therapeutic possibilities, not least because of their high rate of metastasis. Thus understanding the process of metastasis might unravel therapeutic targets for developing further therapeutic strategies. The generation of a transgenic mouse model expressing B-RafV600E in melanocytes, a mutation that is found in about 60% of all melanoma, would result in an ideal tool to study melanoma progression and metastasis. In this work, a doxycycline-inducible system was constructed for expression of B-RafV600E and transgenic animals were generated, but the expression system has to be improved, since this strategy didn’t give rise to any viable, transgene carrying mice. Furthermore, since it was shown in the work of others that the metastatic behavior of tumour cell lines could be reversed by an embryonic microenvironment and the influence of a tumourigenic microenvironment on melanocytes lead to the acquisition of tumour cell-like characteristics, the question arose, whether B-Raf is as important in melanocyte development as it is in melanoma progression. In this work, the embryonal melanocyte development in B-Raf-deficient and wildtype mouse embryos was examined and there were no differences observed in the localization and number of neural crest stem cells as well as in the localization of the dopachrome-tautomerase positive melanoblasts in the embryos and in cultured neural tube explants. The expression of oncogenic C-Raf in lung epithelial cells has yielded a model for NSCLC giving rise to adenomas lacking spontaneous progression or metastasis. The co-expression of c-Myc in the same cells accelerates the tumour development and gives rise to liver and lymphnode metastases. The expression of c-Myc alone in lung epithelial cells leads to late tumour development with incomplete penetrance. A mutation screen in this work resulted in the observation that a secondary mutation in KRas or LKB1 is necessary for tumour formation in the c-Myc single transgenic animals and suggested metastasis as an early event, since the corresponding metastases of the mutation-prone primary lung tumours were negative for the observed mutations. Furthermore, in this work it was shown that the expression of chicken c-Myc in a non-metastatic NSCLC cell line leads to metastatic clones, showing that c-Myc is sufficient to induce metastasis. Additionally a panel of metastasis markers was identified, that might serve as diagnostic markers in the future.
The transmission of proliferative and developmental signals from activated cell-surface receptors to initiation of cellular responses in the nucleus is synergically controlled by the coordinated action of a diverse set of intracellular signalling proteins. The Ras/Raf/MEK/MAPK signalling pathway has been shown to control the expression of genes which are crucial for the physiological regulation of cell proliferation, differentiation and apoptosis. Within this signalling cascade, the Raf protein family of serine/threonine kinases serves as a central intermediate which connects to many of other signal transduction pathways. To elucidate the signalling functions of the different Raf kinases in motoneurons during development, the expression, distribution and subcellular localization of Rafs in the spinal cord and the facial nucleus in brainstem of mice at various embryonic and postnatal stages were investigated. Moreover, we have investigated the intracellular redistribution of Raf molecules in isolated motoneurons from 13 or 14 day old mouse embryos, after addition or withdrawal of neurotrophic factors to induce Raf kinases activation in vitro. Furthermore, in order to investigate the potential anti-apoptotic function of Raf kinases on motoneurons, we isolated motoneurons from B-raf-/- and c-raf-1-/- mouse embryos and analysed the survival and differentiation effects of neurotrophic factors in motoneurons lacking B-Raf and c-Raf-1. We provide evidence here that all three Raf kinases are expressed in mouse spinal motoneurons. Their expression increases during the period of naturally occurring cell death of motoneurons. In sections of embryonic and postnatal spinal cord, motoneurons express exclusively B-Raf and c-Raf-1, but not A-Raf, and subcellularly Raf kinases are obviously colocalized with mitochondria. In isolated motoneurons, most of the B-Raf or c-Raf-1 immunoreactivity is located in the perinuclear space but also in the nucleus, especially after activation by addition of CNTF and BDNF in vitro. We found that c-Raf-1 translocation from the cytosol into the nucleus of motoneurons after its activation by neurotrophic factors is a distinct event. As a central finding of our study, we observed that the viability of isolated motoneurons from B-raf but not c-raf-1 knockout mice is lost even in the presence of CNTF and other neurotrophic factors. This indicates that B-Raf but not c-Raf-1, which is still present in B-raf deficient motoneurons, plays a crucial role in mediating the survival effect of neurotrophic factors during development. In order to prove that B-Raf is an essential player in this scenario, we have re-expressed B-Raf in mutant sensory and motor neurons by transfection. The motoneurons and the sensory neurons from B-raf knockout mouse which were transfected with exogenous B-raf gene revealed the same viability in the presence of neurotrophic factors as primary neurons from wild-type mice. Our results suggest that Raf kinases have important signalling functions in motoneurons in mouse CNS. In vitro, activation causes redistribution of Raf protein kinases, particularly for c-Raf-1, from motoneuronal cytoplasm into the nucleus. This redistribution of c-Raf-1, however, is not necessary for the survival effect of neurotrophic factors, given that B-raf-/- motor and sensory neurons can not survive despite the presence of c-Raf-1. We hypothesize that c-Raf-1 nuclear translocation may play a direct role in transcriptional regulation as a consequence of neurotrophic factor induced phosphorylation and activation of c-Raf-1 in motoneurons. Moreover, the identification of target genes for nuclear translocated c-Raf-1 and of specific cellular functions initiated by this mechanism awaits its characterization.
Members of the RAF protein kinase family are key regulators of diverse cellular processes. The need for isoform-specific regulation is reflected by the fact that all RAFs not only display a different degree of activity but also perform isoform-specific functions at diverse cellular compartments. Protein-protein-interactions and phosphorylation events are essential for the signal propagation along the Ras-RAF-MEK-ERK cascade. More than 40 interaction partners of RAF kinases have been described so far. Two of the most important regulators of RAF activity, namely Ras and 14-3-3 proteins, are subject of this work. So far, coupling of RAF with its upstream modulator protein Ras has only been investigated using truncated versions of RAF and regardless of the lipidation status of Ras. We quantitatively analyzed the binding properties of full-length B- and C-RAF to farnesylated H-Ras in presence and absence of membrane lipids. While the isolated Ras-binding domain of RAF exhibit a high binding affinity to both, farnesylated and nonfarnesylated H-Ras, the full-length RAF kinases demonstrate crucial differences in their affinity to Ras. In contrast to C-RAF that requires carboxyterminal farnesylated H-Ras for interaction at the plasma membrane, B-RAF also binds to nonfarnesylated H-Ras in the cytosol. For identification of the potential farnesyl binding site we used several fragments of the regulatory domain of C-RAF and found that the binding of farnesylated H-Ras is considerably increased in the presence of the cysteine-rich domain of RAF. In B-RAF a sequence of 98 amino acids at the extreme N terminus enables binding of Ras independent of its farnesylation status. The deletion of this region altered Ras binding as well as kinase properties of B-RAF to resemble C-RAF. Immunofluorescence studies in mammalian cells revealed essential differences between B- and C-RAF regarding the colocalization with Ras. In conclusion, our data suggest that that B-RAF, in contrast to C-RAF, is also accessible for nonfarnesylated Ras in the cytosolic environment due to its prolonged N terminus. Therefore, the activation of B-RAF may take place both at the plasma membrane and in the cytosolic environment. Furthermore, the interaction of RAF isoforms with Ras at different subcellular sites may also be governed by the complex formation with 14-3-3 proteins. 14-3-3 adapter proteins play a crucial role in the activation of RAF kinases, but so far no information about the selectivity of the seven mammalian isoforms concerning RAF association and activation is available. We analyzed the composition of in vivo RAF/14-3-3 complexes isolated from mammalian cells with mass spectrometry and found that B-RAF associates with a greater variety of 14-3-3 proteins than C- and A-RAF. In vitro binding assays with purified proteins supported this observation since B-RAF showed highest affinity to all seven 14-3-3 isoforms, whereas C-RAF exhibited reduced affinity to some and A-RAF did not bind to the 14-3-3 isoforms epsilon, sigma, and tau. To further examine this isoform specificity we addressed the question of whether both homo- and heterodimeric forms of 14-3-3 proteins participate in RAF signaling. By deleting one of the two 14-3-3 isoforms in Saccharomyces cerevisiae we were able to show that homodimeric 14-3-3 proteins are sufficient for functional activation of B- and C-RAF. In this context, the diverging effect of the internal, inhibiting and the activating C-terminal 14-3-3 binding domain in RAF could be demonstrated. Furthermore, we unveil that prohibitin stimulates C-RAF activity by interfering with 14-3-3 at the internal binding site. This region of C-RAF is also target of phosphorylation as part of a negative feedback loop. Using tandem MS we were able to identify so far unknown phosphorylation sites at serines 296 and 301. Phosphorylation of these sites in vivo, mediated by activated ERK, leads to inhibition of C-RAF kinase activity. The relationship of prohibitin interference with 14-3-3 binding and phosphorylation of adjacent sites has to be further elucidated. Taken together, our results provide important new information on the isoform-specific regulation of RAF kinases by differential interaction with Ras and 14-3-3 proteins and shed more light on the complex mechanism of RAF kinase activation.
Unterhalb des Interleukin 3 (Il-3) Rezeptors sind zwei Ras-abhängige Signalwege beschrieben, die entweder zur Aktivierung von C-Raf oder von PI3-Kinase (PI3K)/Proteinkinase B (PKB, AKT) führen und Wachstum und Überleben vermitteln. Frühere Untersuchungen des Mechanismus, über den C-Raf Apoptose unterdrückt, zeigten die Notwendigkeit einer Anwesenheit der zytoplasmatischen Kinase an den Mitochondrien. Diese Translokation konnte entweder durch Überexpression des antiapoptotischen Proteins Bcl-2 oder aber durch Fusion der Kinase mit dem mitochondriellen Protein Mas p70 erreicht werden. Aktiviertes mitochondriell gebundenes C-Raf ist nicht in der Lage ERK1 und ERK2 zu aktivieren, vermag aber durch Inaktivierung des proapoptotischen Bcl-2 Familienmitgliedes BAD Apoptose zu unterdrücken. Ungeachtet dieser Ergebnisse deuteten andere genetische und biochemische Untersuchungen auch auf eine Bedeutung der Raf Effektoren MEK und ERK in der Unterdrückung des programmierten Zelltodes hin. Im Rahmen dieser Arbeit wurde daher die Bedeutung von MEK und MEK-abhängigen Signalwegen für das zelluläres Überleben untersucht. Wir nutzten für diese Untersuchungen überwiegend die Il-3 abhängige Zelllinie 23D. MEK war essentiell für das zelluläre Überleben und Wachstum nach Stimulation durch Il-3. Eine konstitutiv aktive MEK1 Mutante verzögerte signifikant das Einsetzen der Apoptose nach Entzug des Wachstumsfaktors, während eine dominant negative Mutante den Zelltod akzelerierte. In der Fibroblastenzelllinie NIH 3T3 unterdrückte eine konstitutiv aktive Mutante von ERK2, ähnlich effektiv wie onkogenes MEK, durch Doxorubicin induzierten Zelltod. Diese Beobachtung lässt auf einen, das Überleben der Zelle vermittelnden, Signalweg von MEK schließen, der zur Aktivierung von ERK führt. Der protektive Effekt von aktiviertem MEK in 32D Zellen wurde durch MEK- und PI3K-abhängige Mechanismen vermittelt. Die dabei beobachtete Aktivierung von PI3K führt zur Phosphorylierung und Aktivierung von AKT. Die Abhängigkeit von MEK und PI3K Signalwegen konnte auch für den Schutz von 32D Zellen vor Apoptose durch onkogenes C-Raf gezeigt werden. Diese Befunde ließen sich ebenso in der Il-3 abhängigen pro-B Zelllinie BaF3 verifizieren, was darauf schließen lässt, dass die Rekrutierung von MEK/ERK im antiapoptotischen Signalweg von aktiviertem Raf ein allgemeingültiger Mechanismus ist. Dass in diesem antiapoptotischen Signalweg von C-Raf auch der PI3K Effektor AKT notwendig ist zeigten weitere Untersuchungen, in denen eine dominant negative Mutante von AKT den protektiven Effekt von aktiviertem C-Raf inhibierte, während eine konstitutiv aktive Form von AKT einen synergistischen Effekt mit C-Raf in der Unterdrückung der Apoptose hatte. Diese Daten zeigen einen, zelluläres Überleben vermittelnden Effekt von Raf, der durch MEK und AKT vermittelt wird.
Cellular proliferation, differentiation and survival in response to extracellular signals are controlled by the signal transduction pathway of Ras, Raf and MAP kinase. The Raf proteins are serine/threonine kinases with essential function in growth/differentiation/survival - related signal transduction events. In mammals, three functional (A-, B-, and C-Raf) genes were described. Biochemical studies suggest overlapping and differential utilization of Raf isozymes. However, the frequent co-expression of Raf isozymes and their multiple activators and effectors impedes the full understanding of their specific roles. The elucidation of these roles is important due to the involvement of the Ras/Raf/MEK/MAP kinase cascade in human disorders especially in tumor development and progression. B-Raf was shown to posses the strongest kinase activity among Raf kinases and display antiapoptotic properties. Mice deficient in B-Raf show overall growth retardation and die between E10.5 and E12.5 of vascular defects caused by excessive death of differentiated endothelial cells. To elucidate the redundancy of Raf isozymes during embryonic development and to rescue B-Raf-/- (KO) phenotype, B-Raf alleles were disrupted by introducing A-Raf cDNA under the control of endogenous B-Raf promoter. The resulting BRaf A-Raf/A-Raf (KIN) phenotype depends on genetic background. The living embryos displaying normal development but size reduction were found with low incidence at E12.5d-16.5d. All of them displayed the rescue of vascular system. One adult p20 mouse without any visible defects in development and behavior was obtained. On the other hand, the processes of neurogenesis and neural precursors migration in survived embryos were disturbed which led in some cases to underdevelopment of different brain compartments. TUNEL and cell proliferation (PCNA staining) assays revealed more apoptotic (E13.5d) and less proliferating(E12.5d cells within ventricular and sub-ventricular zones of brain ventricles and in striatum of KIN embryos. In addition, more apoptotic cells were detected in many other tissues of E13.5d and in lung of E16.5d KIN embryos but not in adult KIN mouse. p20 KIN mouse demonstrated reduced fraction of neural precursor cells in sub-granular zone of hippocampus and mature neurons in olfactory bulb. The other processes of neurogenesis were not disturbed in adult KIN animal. Fibroblasts obtained from KIN embryos demonstrated less proliferative ability and were more susceptible to apoptotic stimuli compared to WT. This was accompanied by the reduction of active ERK and Akt required for survival, and with decrease of inactive phosphorylated BAD. The kinetic of both ERK and Akt phosphorylation upon serum stimulation was delayed. All these data indicate that moderate A-Raf kinase activity can prevent the endothelial apoptosis but is not enough to completely rescue the other developmental consequences.
Die heterotetramere Proteinkinase CK2 nimmt aufgrund der großen Anzahl und Diversität ihrer Substrate, sowie aufgrund ihrer Eigenschaft Signalwege miteinander zu vernetzen eine Sonderstellung innerhalb der Kinasen ein. CK2 beeinflusst Proliferation, Differenzierung und Apoptose, Prozesse an denen auch Polyamine und der MAPK-Signalweg beteiligt sind. Eine vor kurzem durchgeführte Arbeit beschreibt die Bindung von CK2 an das Gerüstprotein KSR und die Verstärkung des MAPK-Signalwegs durch Phosphorylierung von Raf-Proteinen in Vertebraten. In dieser Arbeit konnte gezeigt werden, dass CK2 auch in Drosophila mit KSR interagiert und das einzige in Drosophila vorhandene Raf-Potein (DRaf) in vitro phosphoryliert. Im Gegensatz zur Phosphorylierung der humanen B-Raf und C-Raf Proteine an Serin 446 bzw. Serin 338 innerhalb der „negative charge regulatory region“ (N-Region), führten Kinasereaktionen und Massenspektrometrische Untersuchungen zur Identifizierung von Serin 11 als CK2 Phosphorylierungsstelle in DRaf, während ein zu Serin 446 in B-Raf äquivalentes Serin in der N-Region in Drosophila nicht durch CK2 phosphoryliert wird. Durch Überexpression von DRaf sowie von zwei DRaf-Varianten bei denen Serin 11 durch Alanin oder Aspartat substituiert wurde (DRafS11A und DRafS11D) konnte in Zellkulturexperimenten gezeigt werden, dass die Ladung an der Aminosäureposition 11 die Funktion von DRaf beeinflusst, wobei eine negative Ladung an dieser Stelle zur Phosphorylierung und Aktivierung der Effektorkinase Erk führt. Die Phosphorylierung durch CK2 ist unabhängig von regulatorischen Botenstoffen ("second messengers"), wird aber durch Bindung von Polyaminen moduliert. Intrazelluläre Polyamine entstammen zum grossen Teil dem zellulären Aminosäurekatabolismus und beeinflussen die Phosphorylierung von DRaf durch CK2 in vitro, wobei Spermin ein effizienter Inhibitor der Reaktion ist, während die Effekte von Putrescin und Spermidin gering sind. Auch in Drosophila Schneider S2 Zellen und in adulten weiblichen Fliegen hat Spermin einen inhibitorischen, CK2-abhängigen Effekt auf die Aktivierung von Erk. Ausserdem konnte gezeigt werden, dass Putrescin und Spermidin in der Lage sind die Aktivierung von Erk, im Vergleich zu Zellen die nur mit Spermin behandelt wurden, zu erhöhen. Das spricht dafür, dass die Phosphorylierung von DRaf und die davon abhängige Aktivierung von Erk durch CK2 von der Menge und Relation der verschiedenen Polyamine zueinander abhängt. Die Ergebnisse dieser Arbeit lassen den Schluss zu, dass der Polyaminmetabolismus über CK2 mit dem MAPK-Signalweg verknüpft ist. Nachdem Polyamine durch Aminosäurekatabolismus enstehen, kann auf diese Weise der MAPK-Signalweg in Abhängigkeit der Verfügbarkeit zellulärer Aminosäuren reguliert werden. Vorversuche zeigten eine Beeinflussung von Proliferation und Apoptose durch CK2 und Polyamine. Weitere Untersuchungen sind aber nötig um spezifische Einflüsse von Polyaminen und CK2 auf zelluläre Prozesse wie Proliferation, Differenzierung und Apoptose aufzudecken.
In mammals, the RAF family of serine/threonine kinases consists of three members, A-, B- and C-RAF. Activation of RAF kinases involves a complex series of phosphorylations. Although the most prominent phosphorylation sites of B- and C-RAF are well characterized, little is known about regulatory phosphorylation of A-RAF. Using mass spectrometry, we identified here a number of novel in vivo phosphorylation sites in A-RAF. The physiological role and the function of these sites were investigated subsequently by amino acid exchange at the relevant positions. In particular, we found that S432 participates in MEK binding and is indispensable for A-RAF signaling. On the other hand, phosphorylation within the activation segment does not contribute to epidermal growth factor-mediated activation. Regarding regulation of A-RAF activity by 14-3-3 proteins, we show that A-RAF activity is regulated differentially by its C-terminal and internal 14-3-3 binding domain. Furthermore, by use of SPR technique, we found that 14-3-3 proteins associate with RAF in an isoform-specific manner. Of importance, we identified a novel regulatory domain in A-RAF (referred to as IH-segment) positioned between amino acids 248 and 267, which contains seven putative phosphorylation sites. Three of these sites, serines 257, 262 and 264, regulate A-RAF activation in a stimulatory manner. The spatial model of the A-RAF fragment including residues between S246 and E277 revealed a “switch of charge” at the molecular surface of the IH-region upon phosphorylation, suggesting a mechanism in which the high accumulation of negative charges may lead to an electrostatic destabilization of protein/membrane interaction resulting in depletion of A-RAF from the plasma membrane. Activation of B- and C-RAF is regulated by phosphorylation at conserved residues within the negative-charge regulatory region (N-region). Identification of phosphopeptides covering the sequence of the N-region led to the conclusion that, similar to B- and C-RAF, kinase activity of A-RAF is regulated by phosphorylation of the N-region. Abrogation of A-RAF activity by S299A substitution and elevated activity of the A-RAF-Y301D-Y302D mutant confirmed this conclusion. In addition, we studied the role of the non-conserved residues within the N-region in the activation process of RAF kinases. The non-conserved amino acids in positions –3 and +1 relative to the highly conserved S299 in A-RAF and S338 in C-RAF have so far not been considered as regulatory residues. Here, we demonstrate that Y296R substitution in A-RAF led to a constitutively active kinase. In contrast, G300S substitution (mimicking B- and C-RAF) acts in an inhibitory manner. These data were confirmed by analogous mutations in C-RAF. Based on the three-dimensional structure of the catalytic domain of B-RAF, a tight interaction between the N-region residue S339 and the catalytic domain residue R398 was identified in C-RAF and proposed to inhibit the kinase activity of RAF proteins. Furthermore, Y296 in A-RAF favors a spatial orientation of the N-region segment, which enables a tighter contact to the catalytic domain, whereas a glutamine residue at this position in C-RAF abrogates this interaction. Considering this observation, we suggest that Y296, which is unique for A-RAF, is a major determinant of the low activating potency of this RAF isoform. Finally, the residues R359 in A-RAF and R398 in C-RAF, which interact with the N-region, are also involved in binding of phosphatidic acid. Substitution of this conserved arginine by alanine resulted in accumulation of hyper-phosphorylated form of RAF, suggesting that this residue play a crucial role in phosphorylation-mediated feedback regulation of A- and C-RAF. Collectively, we provide here for the first time a detailed analysis of in vivo A-RAF phosphorylation status and demonstrate that regulation of A-RAF by phosphorylation exhibits unique features compared with B- and C-RAF.
BAD (Bcl-2 antagonist of cell death, Bcl-2 associated death promoter) is a pro-apoptotic member of the Bcl-2 protein family that is regulated by phosphorylation in response to survival factors. Although much attention has been devoted to the identification of phosphorylation sites in murine BAD (mBAD), little data are available with respect to phosphorylation of human BAD (hBAD) protein. In this work, we investigated the quantitative contribution of BAD targeting kinases in phosphorylating serines 75, 99 and 118 of hBAD (Chapter 3.1). Our results indicate that RAF kinases phosphorylate hBAD in vivo at these established serine residues. RAF-induced phosphorylation of hBAD was not prevented by MEK inhibitors but could be reduced to control levels by use of the RAF inhibitor Sorafenib (BAY 43-9006). Consistently, expression of active RAF suppressed apoptosis induced by hBAD and the inhibition of colony formation caused by hBAD could be prevented by RAF. In addition, using surface plasmon resonance technique we analyzed the direct consequences of hBAD phosphorylation by RAF with respect to complex formation of BAD with 14-3-3 proteins and Bcl-XL. Phosphorylation of hBAD by active RAF promotes 14-3-3 protein association, whereby the phosphoserine 99 represents the major binding site. Furthermore, we demonstrate in this work that hBAD forms channels in planar bilayer membranes in vitro. This pore-forming capacity is dependent on phosphorylation status and interaction with 14-3-3 proteins. Additionally, we show that hBAD pores possess a funnel-shaped geometry that can be entered by ions and non-charged molecules up to 200 Da (Chapter 3.2). Since both lipid binding domains of hBAD (LBD1 and LBD2) are located within the C-terminal region, we investigated this part of the protein with respect to its structural properties (Chapter 3.3). Our results demonstrate that the C-terminus of hBAD possesses an ordered β-sheet structure in aqueous solution that adopts helical disposition upon interaction with lipid membranes. Additionally, we show that the interaction of the C-terminal segment of hBAD with the BH3 domain results in the formation of permanently open pores, whereby the phosphorylation of serine 118 proved to be necessary for effective pore-formation. In contrast, phosphorylation of serine 99 in combination with 14-3-3 association suppresses formation of channels. These results indicate that the C-terminal part of hBAD controls hBAD function by structural transitions, lipid binding and phosphorylation. Using mass spectrometry we identified in this work, besides the established in vivo phosphorylation sites at serines 75, 99 and 118, several novel hBAD phosphorylation sites (serines 25, 32/34, 97, 124 and 134, Chapter 3.1). To further analyze the regulation of hBAD function, we investigated the role of these newly identified phosphorylation sites on BAD-mediated apoptosis. We found that in contrast to the N-terminal phosphorylation sites, the C-terminal serines 124 and 134 act in an anti-apoptotic manner (Chapter 3.4). Our results further indicate that RAF kinases and PAK1 effectively phosphorylate BAD at serine 134. Notably, in the presence of wild type hBAD, co-expression of survival kinases, such as RAF and PAK1, leads to a strongly increased proliferation, whereas substitution of serine 134 by alanine abolishes this process. Furthermore, we identified hBAD serine 134 to be strongly involved in survival signaling in B-RAF-V600E containing tumor cells and found phosphorylation of this residue to be crucial for efficient proliferation in these cells. Collectively, our findings provide new insights into the regulation of hBAD function by phosphorylation and its role in cancer signaling.