Bioinformatics An Introduction 4th Edition (Jeremy Ramsden)

23.14 Metabolic Regulation

335

Table 23.1 Some examples of metabolic coding

Condition

Symbol

Domain

Glucose deﬁciency

cAMP

Starvation response

N-deﬁciency

ppGpp

Stringent response

Redox level

NADH

DNA transcription

StartFraction d bold upper X Over d t EndFraction equals bold upper N bold v comma^d^X

dt ⁼^Nv^,

(23.22)

where the “stoicheiometry matrix” bold upper NN speciﬁes how each process depends on the

metabolites. Metabolic control theory (MCT) is concerned with solutions to Eq.

(23.22) and their properties. The dynamical system is generally too complicated for

explicit solutions to be attempted, ⁴³and numerical solutions are of little use unless

one knows more of the parameters (enzyme rate coefﬁcients) and can measure more of

the variables than are generally available at present. Hence, much current discussion

about metabolism centres on qualitative features. Some are especially noteworthy: It

is well known, from numerous documented examples, that large changes in enzyme

concentration may cause negligible changes in ﬂux through pathways of which they

are a part. Metabolic networks are truly many-component systems, as discussed in

Chap. 12, and, hence, the concept of feedback, so valuable in dealing with systems

of just two components, is of little value in understanding metabolic networks.

Problem. Writebold upper XX andbold vv in Eq. (23.22) as column matrices andbold upper NN as anm times rm × r matrix.

Construct, solve, and discuss an explicit example with only two or three metabolites

and processes.

23.14.2

The Metabolic Code

It is apparent that certain molecules mediating intracellular function (e.g., cAMP)

are ubiquitous in the cell (see Table 23.1). Tomkins (1975) has pointed out that these

molecules are essentially symbols encoding environmental conditions. The domain

of these symbols is deﬁned as the metabolic responses controlled by them. Note that

the symbols are metabolically labile and are not chemically related to molecules

promoting their accumulation. The concept applies to both within and without cells.

Cells affected by a symbol may secrete a hormone, which circulates (e.g., via the

blood) to another cell, where the hormone signal is decoded—often back into the

same symbol.

43 But see Wolkenhauer et al. (2005).