Project 1: Program in Cell Signaling
Our laboratory is studying cellular differentiation and the way this process is regulated by signal transduction.
The main focus is on a cytoplasmic protein-tyrosine kinase (PTK) designated Bruton鈥檚 tyrosine kinase, BTK. BTK belongs to the second largest family of mammalian PTKs, the TEC family (Smith et al., 2001) comprising BTK, BMX (ETK), ITK, TEC and TXK (RLK). BTK is affected in the disease named X-linked agammaglobulinemia (XLA), and was identified as a result of positional cloning (Vetrie et al., 1993). BTK was found to shuttle between the cytoplasm and the nucleus (Mohamed et al., 2000). BTK activates NF-kB signaling and is also regulated by this pathway through its own promoter (Yu et al. 2008).
One approach to understand the signaling process is to investigate structure-function relationships (Hansson et al., 1998 Fig. 1; M谩rquez et al., 2003). Main activities include cell biology, biochemistry, proteomics, imaging, expression profiling, and siRNA technology. In expression profiling studies of the ITK kinase, a unique transcriptome was identified, including the transcription factor PLZF (Blomberg et al., 2009; Raberger et al. 2008). These studies also include research in Drosophila (Hamada-Kawaguchi et al., 2014).
Using proteomics approaches, we have recently identified ankyrin repeat domain protein 54 (ANK54) and 14-3-3z as partners, which regulate BTK nucleo-cytoplasmic shuttling and degradation (Gustafsson et al. 2012, Mohammad et al. 2013). We are currently also studying other proteins, which show functional interaction with BTK, such as AKT.
Recently the translocation-based fusion-protein ITK-SYK causing lymphomas in humans has been investigated (Hussain et al., 2009 and 2013, Fig. 3). Studies related to BTK inhibitors, especially ibrutinib, are also ongoing with a focus on leukemia and lymphoma treatment.
We are also developing new treatment modalities for XLA based on splice-correcting oligonucleotides. Here we have generated humanized, transgenic mice lacking mouse BTK but carrying a splicing-deficient human BTK mutant. We have successfully corrected BTK pre-mRNA in B cells from these mice and restored BTK function in vitro (Bestas et al. manuscript).
Selected references
Blomberg KE, Boucheron N, Lindvall JM, Yu L, Raberger J, Bergl枚f A, et al
BMC Genomics 2009 May;10():233
Gustafsson MO, Hussain A, Mohammad DK, Mohamed AJ, Nguyen V, Metalnikov P, et al
Mol Cell Biol 2012 Jul;32(13):2440-53
Hamada-Kawaguchi N, Nore BF, Kuwada Y, Smith CI, Yamamoto D
Science 2014 Jan;343(6168):294-7
Heinonen JE, Smith CI, Nore BF
FEBS Lett 2002 Sep;527(1-3):274-8
Hussain A, Faryal R, Nore BF, Mohamed AJ, Smith CI
Biochem Biophys Res Commun 2009 Dec;390(3):892-6
Hussain A, Mohammad DK, Gustafsson MO, Uslu M, Hamasy A, Nore BF, et al
J Biol Chem 2013 Mar;288(10):7338-50
Mohamed AJ, Yu L, B盲ckesj枚 CM, Vargas L, Faryal R, Aints A, et al
Immunol Rev 2009 Mar;228(1):58-73
Gustafsson MO, Hussain A, Mohammad DK, Mohamed AJ, Nguyen V, Metalnikov P, et al
Mol Cell Biol 2012 Jul;32(13):2440-53
Mohammad DK, Nore BF, Hussain A, Gustafsson MO, Mohamed AJ, Smith CI
Mol Cell Biol 2013 Aug;33(16):3214-26
Nawaz HM, Kylsten P, Hamada N, Yamamoto D, Smith CI, Lindvall JM
PLoS One 2012 ;7(5):e35640
Raberger J, Schebesta A, Sakaguchi S, Boucheron N, Blomberg KE, Bergl枚f A, et al
Proc Natl Acad Sci U S A 2008 Nov;105(46):17919-24
Sk枚ld AE, Hasan M, Vargas L, Saidi H, Bosquet N, Le Grand R, et al
Blood 2012 Jul;120(4):768-77
Smith CI, Islam TC, Mattsson PT, Mohamed AJ, Nore BF, Vihinen M
Bioessays 2001 May;23(5):436-46
Vetrie D, Vo艡echovsk媒 I, Sideras P, Holland J, Davies A, Flinter F, et al
J Immunol 2012 Apr;188(7):2948-55
Yu L, Mohamed AJ, Simonson OE, Vargas L, Blomberg KE, Bj枚rkstrand B, et al
Blood 2008 May;111(9):4617-26
Yu L, Mohamed AJ, Vargas L, Bergl枚f A, Finn G, Lu KP, et al
J Biol Chem 2006 Jun;281(26):18201-7