posted on 2013-05-15, 00:00authored byMatthew J. Saunders, Wen Liu, Christopher Szent-Gyorgyi, Yi Wen, Zachary Drennen, Alan S. Waggoner, Wilson S. Meng
We
present herein characteristics of a conjugate in which dL5,
a fluorogen activating protein (FAP), and AEAEAKAK, an amphiphilic
peptide, are combined to form a solid-phase fluorescence detection
platform. The FAP dL5 is a covalently linked dimer of two identical
light chain variable fragments which activates the fluorescence of
the fluorogen malachite green (MG). The amphiphilic peptide of sequence
AEAEAKAK is a building block of stimuli-responsive materials that
undergoes sol–gel phase transition at high ionic strengths.
We hypothesize that the novel bifunctional protein containing both
the FAP and the amphiphile, termed dL5_EAK coassembles with the self-assembling
peptide [AEAEAKAK]2 (EAK16-II) to form an insoluble membrane
composite whereby the fluorescence enhancement function of the FAP
domain remains intact. Denaturing polyacrylamide electrophoresis indicated
that greater than 78% of dL5_EAK incorporates into the EAK16-II membrane.
Conversely, less than 32% of dL5 without the EAK sequence associates
with the insoluble fraction of EAK16-II in buffers. Membranes containing
dL5_EAK and EAK16-II exhibited at least 4-fold higher fluorescence
intensity compared to mixtures containing dL5 and EAK16-II. Scanning
electron microscopy revealed the presence of particulates, presumably
FAPs, scattered on the membrane fibrils. The evidence suggests a system
of materials that can be developed into in situ forming
local sensors by immobilizing dL5 into coacervate, on which MG can
be detected. It is envisioned that dL5 membranes can be established
in diseased locales to monitor infiltration and migration of inflammatory
cells marked with antibodies conjugated to MG.