18.2 Proteomics
279
Fig. 18.2 A
two-dimensional gel after
staining
be stained and the gel scanned with a densitometer; the spot density is then propor-
tional to protein abundance. There are some caveats: Membrane proteins with more
than two transmembrane sequences are poorly recovered by the technique; if Superscript 3535S
met/cys is used, one should note that not all proteins contain the same number of
met and cys (but this number is only very weakly correlated with molecular weight);
autoradiography may underestimate the density of weak spots, due to low-intensity
reciprocity failure of the photographic (silver halide) film used to record the presence
of the radionucleides; the commonly used Coomassie blue does not stain all proteins
evenly, although the unevenness appears to be random and hence should not impose
any systematic distortion on the data; rare proteins may not be detected at all; sev-
eral abundant proteins clustered close together may not be distinguishable from each
other; and very small and very large proteins, and those with isoelectric points (pI) at
the extremes of the pH range, will not be properly separated. The molecular weight
and isoelectric point ranges are limited by practical considerations. Typical ranges
are 15 000 less than upper M Subscript normal r Baseline less than 90 00015 000 < Mr < 90 000 and 3 less than< pI less than< 8. Hence, the mostly basic (pI typically in
the range 10–14) 50–70 ribosomal proteins will not be captured, as a notable example
(on the other hand, these proteins are not supposed to vary much from cell to cell,
regardless of conditions, since they are essential proteins for all cells; hence, they
are not considered to be especially characteristic of a particular cell or metabolic
state). Figure 18.2 shows a typical result. Such images are obvious candidates for
refinement using maximum entropy techniques (Sect. 13.5).
Problem.
Write
a
computer
program
for
reconstructing
a
poor-quality
two-dimensional gel electrophoretogram using the principle of maximum entropy.
18.2.2
Column Chromatography
The principle of this method is to functionalize a stationary solid phase (granules of
silica, for example) packed in a column and pass the sample (suspended or dissolved