The stoichiometric structure and mass-conservation properties of biochemical pathways gives rise to a series of theorems or relationships between the control coefficients and the control coefficients and elasticities. There are a large number of such relationships depending on the pathway configuration (e.g. linear, branched or cyclic) which have been documented and discovered by various authors. The term theorem has been used to describe these relationships because they can be proved in terms of more elementary concepts. The operational proofs[1] in particular are of this nature.
The most well known of these theorems are the summation theorems for the control coefficients and the connectivity theorems which relate control coefficients to the elasticities. The focus of this page are the connectivity theorems.
When deriving the summation theorems, a thought experiment was conducted that involved manipulating enzyme activities such that concentrations were unaffected but fluxes changed. The connectivity theorems use the opposite thought experiment, that is enzyme activities are changed such that concentrations change but fluxes are unchanged.[1] This is an important observation that highlights the orthogonal nature of these two sets of theorem.[2]
As with the summation theorems, the connectivity theorems can also be proved using more rigorous mathematical approaches involving calculus and linear algebra.[3] [4] [5] Here the more intuitive and operational proofs will be used to prove the connectivity theorems.
Two basic sets of theorems exists, one for flux and another for concentrations. The concentration connectivity theorems are divided again depending on whether the system species
Sn
Sm
\sumi
| J | |
| C | |
| i |
| i | |
| \varepsilon | |
| s |
=0
\sumi
| sn | |
| C | |
| i |
| i | |
| \varepsilon | |
| sm |
=0 n ≠ m
\sumi
| sn | |
| C | |
| i |
| i | |
| \varepsilon | |
| sm |
=-1 n=m
The operational proof for the flux connectivity theorem[1] relies on making perturbations to enzyme levels such that the pathway flux is unchanged but a single metabolite level is changed. This can be illustrated with the following pathway:
\stackrel{v1}{\longrightarrow}S1\stackrel{v2}{\longrightarrow}S2\stackrel{v3}{\longrightarrow}S3\stackrel{v4}{\longrightarrow}
Let us make a change to the rate through
v2
e2
e2
\deltae2
s2,s3
J
s1
Impose a second change to the pathway such that the flux,
J
e2
e3
e3
s2
s1
s3
e2
When
e3
s1
s3
s2
v1
e1
s1
s1
s3
v4
The net result is that
e2
\deltae2
\deltaJ
e3
\deltaJ=0
s2
\deltas2
s1
s3
s2
This thought experiment can be expressed mathematically as follows. The system equations in terms of the flux control coefficients can be written as:
| \deltaJ | |
| J |
=0=
| J | |
| C | |
| 2 |
| \deltae2 | |
| e2 |
+
| J | |
| C | |
| 3 |
| \deltae3 | |
| e3 |
There are only two terms because only
e2
e3
The local change at each step can be written for
v2
v2
0=
| \deltav2 | |
| v2 |
=
| \deltae2 | |
| e2 |
+
| 2 | |
| \varepsilon | |
| 2 |
| \deltas2 | |
| s2 |
0=
| \deltav3 | |
| v3 |
=
| \deltae3 | |
| e3 |
+
| 3 | |
| \varepsilon | |
| 2 |
| \deltas2 | |
| s2 |
Note that
\deltae2/e2
\deltae2/e3
v2
v3
s2
The local equation can be rearranged as:
| \deltae2 | |
| e2 |
| 2 | |
| =-\varepsilon | |
| 2 |
| \deltas2 | |
| s2 |
| \deltae3 | |
| e3 |
| 3 | |
| =-\varepsilon | |
| 2 |
| \deltas2 | |
| s2 |
The right-hand sides can be inserted into the system equation the change in flux:
| 0= | \deltaJ |
| J |
| J | |
| =-\left(C | |
| e2 |
| 2 | |
| \varepsilon | |
| 2 |
| \deltas2 | |
| s2 |
| J | |
| +C | |
| e3 |
| 3 | |
| \varepsilon | |
| 2 |
| \deltas2 | |
| s2 |
\right)
Therefore:
| 0= | \deltas2 |
| s2 |
| J | |
| \left(C | |
| e2 |
| J | |
| \varepsilon | |
| e3 |
| 3\right) | |
| \varepsilon | |
| 2 |
However, by construction of the perturbations,
\deltas2/s2
| J | |
| 0=C | |
| e2 |
| J | |
| \varepsilon | |
| e3 |
| 3 | |
| \varepsilon | |
| 2 |
The operational method can also be used for systems where a given metabolite can influence multiple steps. This would apply to cases such as branched systems or systems with negative feedback loops.
The same approach can be used to derive the concentration connectivity theorems except one can consider either the case that focuses on a single species or a second case where the system equation is written to consider the effect on a distance species.
The flux control coefficient connectivity theorem is the easiest to understand. Starting with a simple two step pathway:
Xo\stackrel{v1}{\longrightarrow}S1\stackrel{v2}{\longrightarrow}X1
where
Xo
X1
v1
v2
We can write the flux connectivity theorem for this simple system as follows:
| J | |
| C | |
| 1 |
| 1 | |
| \varepsilon | |
| 1 |
+
| J | |
| C | |
| 2 |
| 2 | |
| \varepsilon | |
| 1 |
=0
where
| 1 | |
| \varepsilon | |
| 1 |
v1
S1
| 2 | |
| \varepsilon | |
| 1 |
v2
S1
| |||||||
|
=-
| |||||||
|
The equation indicates that the ratio of the flux control coefficients is inversely proportional to the elasticities. That is, a high flux control coefficient on step one is associated with a low elasticity
| 1 | |
| \varepsilon | |
| 1 |
| 2 | |
| \varepsilon | |
| 1 |
This can be explained as follows: If
| 1 | |
| \varepsilon | |
| 1 |
v1