132 4.4 Fluorescence Correlation Spectroscopy
b
Using the same assumptions as for part (a), then, from the donor intensity values,
the FRET efficiency before adding ATP is
1 6270
−
counts/6450counts=0.03
Similarly, using the acceptor intensity values,
(5560
5380
−
counts)/(5380counts)=0.03
This is significantly less than 0.5 and therefore “low FRET.” Upon adding ATP,
there is a molecular conformational change, and FRET efficiency can be similarly
calculated using either the donor or acceptor intensity values to be ~0.20, which
is “high” FRET.
A “loose” linkage implies isotropic excitation absorption and emission of the
dye molecules; thus, the size of the displacement during the conformational
change of the FRET pair dye molecules is given by
( .
( / .
.
/
/
5 6
1 0 03
2
1 6
1 6
nm)
1)
(1/0.20
1)
9 nm
×
−
−
−
(
) =
This conformational change is accomplished in 5 ms; therefore, the average
speed is given by
( .2 9
10
5 10 5
10
58
9
3
1
1
×
×
(
) =
×
=
−
−
−
−
−
m)/
5.8
ms
ms
7
µ
c
A “tight” linkage prevents free rotation of the dye molecules; therefore, the
brightness in the absence of FRET (no ATP added) of the molecule is a function
of the projection of the polarization excitation vector onto the respective
dye dipole axis. The fact that the dye brightness values are similar to part
(b) is consistent with a random orientation of the construct on the coverslip
surface, since the dyes themselves cannot undergo free rotation relative to the
molecular complex. Since there is no translational movement, the change in
FRET efficiency must be due to relative rotational movement of the dipole axes
of two dye molecules due to relative rotation between the whole lever arm
and the rest of the molecular complex. If θ is the relative angle between the
acceptor and donor dipole axes, then the E-field from the donor projected onto
the acceptor scales as cos θ; the FRET efficiency scales as the local intensity of
the donor E-field, which scales as the square of the amplitude of the f-field and
thus as cos2 θ. Thus,
cos
0.03/(1 5800/6450)
0.30
2θ =
−
=
indicating θ ≈ 57°.
Thus, the molecular conformational change upon ATP hydrolysis is comprised of both
a translation component and a rotation component of the lever arm, suggesting a
combination of both a “pincer” and a “twister” model.