TY - JOUR
T1 - Characterizing the N- and C-terminal Small Ubiquitin-like Modifier (SUMO)-interacting Motifs of the Scaffold Protein DAXX
AU - Escobar-Cabrera, E.
AU - Okon, M.
AU - Lau, D.K.W.
AU - Dart, C.F.
AU - Bonvin, A.M.J.J.
AU - McIntosh, L.P.
PY - 2011
Y1 - 2011
N2 - DAXX is a scaffold protein with diverse roles that often
depend upon binding SUMO via its N- and/or C-terminal
SUMO-interacting motifs (SIM-N and SIM-C). Using NMR
spectroscopy, we characterized the in vitro binding properties of
peptide models of SIM-N and SIM-C to SUMO-1 and SUMO-2.
In each case, binding was mediated by hydrophobic and electrostatic
interactions and weakened with increasing ionic strength.
Neither isolated SIM showed any significant paralog specificity,
and the measured M range KD values of SIM-N toward both
SUMO-1andSUMO-2were 4-fold lower than those of SIM-C.
Furthermore, SIM-N bound SUMO-1 predominantly in a parallel
orientation, whereas SIM-C interconverted between parallel
and antiparallel binding modes on an ms to s time scale. The
differences in affinities and binding modes are attributed to the
differences in charged residues that flank the otherwise identical
hydrophobic core sequences of the two SIMs. In addition,
within its native context, SIM-N bound intramolecularly to the
adjacent N-terminal helical bundle domain of DAXX, thus
reducing its apparent affinity for SUMO. This behavior suggests
a possible autoregulatory mechanism for DAXX. The interaction
of a C-terminal fragment ofDAXXwith an N-terminal fragment
of the sumoylated Ets1 transcription factor was mediated
by SIM-C. Importantly, this interaction did not involve any
direct contacts between DAXX and Ets1, but rather was derived
from the non-covalent binding of SIM-C to SUMO-1, which in
turn was covalently linked to the unstructured N-terminal segment
of Ets1. These results provide insights into the binding
mechanisms and hence biological roles of the DAXX SUMOinteracting
motifs.
AB - DAXX is a scaffold protein with diverse roles that often
depend upon binding SUMO via its N- and/or C-terminal
SUMO-interacting motifs (SIM-N and SIM-C). Using NMR
spectroscopy, we characterized the in vitro binding properties of
peptide models of SIM-N and SIM-C to SUMO-1 and SUMO-2.
In each case, binding was mediated by hydrophobic and electrostatic
interactions and weakened with increasing ionic strength.
Neither isolated SIM showed any significant paralog specificity,
and the measured M range KD values of SIM-N toward both
SUMO-1andSUMO-2were 4-fold lower than those of SIM-C.
Furthermore, SIM-N bound SUMO-1 predominantly in a parallel
orientation, whereas SIM-C interconverted between parallel
and antiparallel binding modes on an ms to s time scale. The
differences in affinities and binding modes are attributed to the
differences in charged residues that flank the otherwise identical
hydrophobic core sequences of the two SIMs. In addition,
within its native context, SIM-N bound intramolecularly to the
adjacent N-terminal helical bundle domain of DAXX, thus
reducing its apparent affinity for SUMO. This behavior suggests
a possible autoregulatory mechanism for DAXX. The interaction
of a C-terminal fragment ofDAXXwith an N-terminal fragment
of the sumoylated Ets1 transcription factor was mediated
by SIM-C. Importantly, this interaction did not involve any
direct contacts between DAXX and Ets1, but rather was derived
from the non-covalent binding of SIM-C to SUMO-1, which in
turn was covalently linked to the unstructured N-terminal segment
of Ets1. These results provide insights into the binding
mechanisms and hence biological roles of the DAXX SUMOinteracting
motifs.
U2 - 10.1074/jbc.M111.231647
DO - 10.1074/jbc.M111.231647
M3 - Article
SN - 0021-9258
VL - 286
SP - 19816
EP - 19829
JO - Journal of Biological Chemistry
JF - Journal of Biological Chemistry
IS - 22
ER -