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In particular, I can use it to investigate how I can achieve the best possible yield of a
product (the “sinks”, see above) with starting products (the “sources”), for example if I
want to biotechnologically produce citric acid for the kitchen or nanocellulose for trans
parent displays – to give a well-known and a very modern example. Similarly, I can now
compare all the metabolic possibilities for one organism with various other organisms and
in this way see what peculiarities are present or even what diversions and alternatives one
organism has and the other does not. You can also see in this way that different strains of
bacteria, such as meningococci, use different pathways to achieve the same rate of growth,
allowing both a pathogenic, disease-causing lifestyle and a more benign lifestyle with
greater effort on amino acid synthesis but less aggressiveness against the human host
(Ampattu et al. 2017).
It is important to validate the modelled (and thus only predicted) metabolic differences
by further experimental data. Since individual errors are corrected by the metabolic flux
network model (in a metabolic flux, all enzymes must work together at the same rate), data
such as RT-PCR measurements on the mRNA expression of metabolically active enzymes
can also be used, for example. These mRNA measurements are “indirect” because only the
mRNA is measured and not the protein or enzyme activity; however, this works well in
practice, with only 5–10% error for fluxes from a network of 30–100 enzymes, as con
firmed by metabolite measurements (Cecil et al. 2011, 2015). Examples of applications
include the changing lifestyle of chlamydiae (bacteria) during infection (as elementary
bodies and subsequently as reticular bodies; Yang et al. 2019) or the mutual metabolic and
regulatory responses to infection events in fungal infections of fungus and host (Srivastava
et al. 2019).
This is particularly interesting if I want to use it for medical purposes, for example to
develop an antibiotic. Then I am interested in the metabolic pathways that as many bacte
ria as possible have in common, but which are absent in the sick person and can therefore
be blocked by the antibiotic without endangering the sick person, but at the same time
killing all bacteria that have this metabolic pathway.
The flux calculations also open up the possibility of identifying individual enzymes that
are particularly critical for the survival of the bacteria (because the failure of a particular
enzyme affects, for example, all flux modes that provide an essential cofactor for the bac
terium and not just a few). This may also help in finding new drugs against insidious fun
gal infections. One can also re-examine the detailed effects of an antibiotic with gene
expression analyses and a calculation of the resulting metabolite fluxes as well as single
metabolite measurements (Cecil et al. 2011; YANAsquare program). This then helps to
find new drugs against multidrug-resistant staphylococci, for example (Cecil et al. 2015).
At present, we also want to link the different modelling levels (Chaps. 1, 2, 3, 4 and 5)
more intensively in order to better protect plants against drought stress and infections, for
example by identifying key enzymes that have an alternative regulatory function (e.g.
aconitase, which, in addition to its metabolic function in the citric acid cycle, also regu
lates IRE in mRNAs, see Sect. 2.2) and alter regulation favourably for drought stress or
resistance to infection.
4 Modeling Metabolism and Finding New Antibiotics