372 8.5 Advanced In Silico Analysis Tools
The challenge is often to estimate an accurate value for ID. For purely in vitro assays, indi
vidual dye molecule can be chemically immobilized onto glass microscope coverslip surfaces
to quantify their mean brightness from a population. However, inside living cells, the physical
and chemical environment can often affect the brightness significantly. For example, laser
excitation light can be scattered inside a cellular structure, but also the pH and the presence
of ions such as chloride Cl−, in particular, can affect the brightness of fluorescent proteins in
particular (see Chapter 3).
Thus, it is important for in vivo fluorescence imaging to determine ID in the same native
cellular context. One way to achieve this is to extract the characteristic periodicity in inten
sity of each track, since steplike events occur in the intensity traces of tracks due to integer
multiples of dye molecule photobleaching within a single sampling time window. Fourier
spectral methods are ideal for extracting the underlying periodicity of these step events and
thus estimating ID (Figure 8.8).
Often molecular complexes will exhibit an underlying distribution of stoichiometry
values. Traditional histogram methods of rendering this distribution for subsequent analysis
are prone to subjectivity errors since they depend on the precise position of histogram bin
edges and of the number of bins used to pool the stoichiometry data. A more objective and
robust method involves kernel density estimation (KDE). This is a 1D convolution of the stoi
chiometry data using a Gaussian kernel whose integrated area is exactly 1 (i.e., representing
a single point), and the width is a measure of the experimental error of the data measure
ment. This avoids the risks in particular of using too many histogram bins that suggest
more multimodality in a distribution than really exists or too few bins that may suggest no
multimodality when, in fact, there may well be some (Figure 8.9).
KEY POINT 8.10
KDE can be generally applied to all experimental datasets. If there are significant
difficulties in estimating the experimental error in a given measurement, then you
should probably not be doing that experiment. You may never need to use a histo
gram again!
Sometimes there will be periodicity in the observed experimental stoichiometry distributions
of molecular complexes across a population, for example, due to modality of whole molecular
complexes themselves in tracked spots. Such periodicity can again be determined using basic
Fourier spectral methods.
FIGURE 8.8 Measuring stoichiometry using stepwise photobleaching of fluorophores.
(a) Example of a photobleach trace for a protein component of a bacterial flagellar motor called
FliM labeled with the yellow fluorescent protein YPet, raw data (dots), and filtered data (line)
shown, initial intensity indicated (arrow), with (b) a zoom-in of trace and (c) power spectrum of
the pairwise difference distribution of these photobleaching data, indicating a brightness of a
single YPet molecule of ~1.3 kcounts on the camera detector used on the microscope.