Biology Reference
In-Depth Information
119. Shults MD, Janes KA, Lauffenburger DA, Imperiali B. A multiplexed homogeneous
fluorescence-based assay for protein kinase activity in cell
lysates.
Nat Methods
2005;
2
:277-83.
120. Lukovi´ E, Gonz´lez-Vera JA, Imperiali B. Recognition-domain focused
chemosensors: versatile and efficient reporters of protein kinase activity.
J Am Chem
Soc
2008;
130
:12821-7.
121. Gonz´lez-Vera JA, Lukovi´ E, Imperiali B. A rapid method for generation of selective
sox-based chemosensors of Ser/Thr kinases using combinatorial peptide libraries.
Bioorg
Med Chem Lett
2010;
19
:1258-60.
122. Lukovic E, Vogel Taylor E, Imperiali B. Monitoring protein kinases in cellular media
with highly selective chimeric reporters.
Angew Chem Int Ed Engl
2009;
48
:6828-31.
123. Stains CI, Lukovi´ E, Imperiali B. A p38
a
-selective chemosensor for use in
unfractionated cell lysates.
ACS Chem Biol
2011;
6
:101-5.
124. Anai T, Nakata E, Koshi Y, Ojida A, Hamachi I. Design of a hybrid biosensor for en-
hanced phosphopeptide recognition based on a phosphoprotein binding domain
coupled with a fluorescent chemosensor.
J Am Chem Soc
2007;
129
:6232-9.
125. Tremblay MS, Lee M, Sames D. A luminescent sensor for tyrosine phosphorylation.
Org Lett
2008;
10
:5-8.
126. Wang Q, Cahill SM, Blumenstein M, Lawrence DS. Self-reporting fluorescent sub-
strates of protein tyrosine kinases.
J Am Chem Soc
2006;
128
:1808-9.
127. Wang Q, Dai Z, Cahill SM, Blumenstein M, Lawrence DS. Light-regulated sampling
of protein tyrosine kinase activity.
J Am Chem Soc
2006;
128
:14016-7.
128. Wang Q, Zimmerman EI, Toutchkine A, Martin TD, Graves LM, Lawrence DS. Mul-
ticolor monitoring of dysregulated protein kinases in chronic myelogenous leukemia.
ACS Chem Biol
2010;
5
:887-95.
129. Sharma V, Agnes RS, Lawrence DS. Deep quench: an expanded dynamic range for
protein kinase sensors.
J Am Chem Soc
2007;
129
:2742-3.
130. Agnes RS, Jernigan F, Shell JR, Sharma V, Lawrence DS. Suborganelle sensing of
mitochondrial cAMP-dependent protein kinase activity.
J Am Chem Soc
2010;
132
:
6075-80.
131. Sun H, Low KE, Woo S, Noble RL, Graham RJ, Connaughton SS, et al. Real-time
protein kinase assay.
Anal Chem
2005;
77
:2043-9.
132. Kikuchi K, Hashimoto S, Mizukami S, Nagano T. Anion sensor-based ratiometric pep-
tide probe for protein kinase activity.
Org Lett
2009;
11
:2732-5.
133. Dai Z, Dulyaninova NG, Kumar S, Bresnick AR, Lawrence DS. Visual snapshots of
intracellular kinase activity at the onset of mitosis.
Chem Biol
2007;
14
:1254-60.
134. Chen CA, Yeh RH, Yan X, Lawrence DS. Biosensors of protein kinase action: from
in vitro
assays to living cells.
Biochim Biophys Acta
2004;
1697
:39-51.
135. Lawrence DS, Wang Q. Seeing is believing: peptide-based fluorescent sensors of pro-
tein tyrosine kinase activity.
Chembiochem
2007;
8
:373-8.
136. Sharma V, Wang Q, Lawrence DS. Peptide-based fluorescent sensors of protein kinase
activity: design and applications.
Biochim Biophys Acta
2008;
1784
:94-9.
137. Haas KL, Franz KJ. Application of metal coordination chemistry to explore and manip-
ulate cell biology.
Chem Rev
2009;
109
:4921-60.
138. Minta A, Kao JPY, Tsien RY. Fluorescent indicators for cytosolic calcium based on
rhodamine and fluorescein chromophores.
J Biol Chem
1989;
264
:8171-8.
139. Sakamoto T, Ojida A, Hamachi I. Molecular recognition, fluorescence sensing, and
biological assay of phosphate anion derivatives using artificial Zn(II)-Dpa complexes.
Chem Commun
2009;
2
:141-52.
140. Allen KN, Imperiali B. Lanthanide-tagged proteins—an illuminating partnership.
Curr
Opin Chem Biol
2010;
14
:247-54.
Search WWH ::
Custom Search