Branched pathways

Template:Short description Branched pathways, also known as branch points (not to be confused with the mathematical branch point), are a common pattern found in metabolism. This is where an intermediate species is chemically made or transformed by multiple enzymatic processes. linear pathways only have one enzymatic reaction producing a species and one enzymatic reaction consuming the species.

Branched pathways are present in numerous metabolic reactions, including glycolysis, the synthesis of lysine, glutamine, and penicillin,^[1] and in the production of the aromatic amino acids.^[2]

In general, a single branch may have ${\displaystyle b}$ producing branches and ${\displaystyle d}$ consuming branches. If the intermediate at the branch point is given by ${\displaystyle s_i}$, then the rate of change of ${\displaystyle s_i}$ is given by:

${\displaystyle {\displaystyle \sum _{i=1}^b}{v}_i-{\displaystyle \sum _{j=1}^d}{v}_j=\frac{d{s}_i}{dt}}$

At steady-state when ${\displaystyle d{s}_i/dt=0}$ the consumption and production rates must be equal:

${\displaystyle {\displaystyle \sum _{i=1}^b}{v}_i={\displaystyle \sum _{j=1}^d}{v}_j}$

Biochemical pathways can be investigated by computer simulation or by looking at the sensitivities, i.e. control coefficients for flux and species concentrations using metabolic control analysis.

A simple branched pathway has one key property related to the conservation of mass. In general, the rate of change of the branch species based on the above figure is given by:

${\displaystyle \frac{d{s}_1}{dt}=v_1-(v_2+v_3)}$

At steady-state the rate of change of ${\displaystyle S_1}$ is zero. This gives rise to a steady-state constraint among the branch reaction rates:

${\displaystyle v_1=v_2+v_3}$

Such constraints are key to computational methods such as flux balance analysis.

Branched pathways have unique control properties compared to simple linear chain or cyclic pathways. These properties can be investigated using metabolic control analysis. The fluxes can be controlled by enzyme concentrations ${\displaystyle e_1}$, ${\displaystyle e_2}$, and ${\displaystyle e_3}$ respectively, described by the corresponding flux control coefficients. To do this the flux control coefficients with respect to one of the branch fluxes can be derived. The derivation is shown in a subsequent section. The flux control coefficient with respect to the upper branch flux, ${\displaystyle J_2}$ are given by:

${\displaystyle C_{e_1}^{J_2}=\frac{{\epsilon }_2}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

${\displaystyle C_{e_2}^{J_2}=\frac{{\epsilon }_3(1-\alpha )-{\epsilon }_1}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

${\displaystyle C_{e_3}^{J_2}=\frac{-{\epsilon }_2(1-\alpha )}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

where ${\displaystyle \alpha }$ is the fraction of flux going through the upper arm, ${\displaystyle J_2}$, and ${\displaystyle 1-\alpha }$ the fraction going through the lower arm, ${\displaystyle J_3}$. ${\displaystyle {\epsilon }_1,{\epsilon }_2,}$ and ${\displaystyle {\epsilon }_3}$ are the elasticities for ${\displaystyle s_1}$ with respect to ${\displaystyle v_1,v_2,}$ and ${\displaystyle v_3}$ respectively.

For the following analysis, the flux ${\displaystyle J_2}$ will be the observed variable in response to changes in enzyme concentrations.

There are two possible extremes to consider, either most of the flux goes through the upper branch ${\displaystyle J_2}$ or most of the flux goes through the lower branch, ${\displaystyle J_3}$. The former, depicted in panel a), is the least interesting as it converts the branch in to a simple linear pathway. Of more interest is when most of the flux goes through ${\displaystyle J_3}$

If most of the flux goes through ${\displaystyle J_3}$, then ${\displaystyle \alpha \to 0}$ and ${\displaystyle 1-\alpha \to 1}$ (condition (b) in the figure), the flux control coefficients for ${\displaystyle J_2}$ with respect to ${\displaystyle e_2}$ and ${\displaystyle e_3}$ can be written:

${\displaystyle C_{e_2}^{J_2}\to 1}$

${\displaystyle C_{e_3}^{J_2}\to \frac{{\epsilon }_2}{{\epsilon }_1-{\epsilon }_3}}$

That is, ${\displaystyle e_2}$ acquires proportional influence over its own flux, ${\displaystyle J_2}$. Since ${\displaystyle J_2}$ only carries a very small amount of flux, any changes in ${\displaystyle e_2}$ will have little effect on ${\displaystyle S}$. Hence the flux through ${\displaystyle e_2}$ is almost entirely governed by the activity of ${\displaystyle e_2}$. Because of the flux summation theorem and the fact that ${\displaystyle C_{e_2}^{J_2}=1}$, it means that the remaining two coefficients must be equal and opposite in value. Since ${\displaystyle C_{e_1}^{J_2}}$ is positive, ${\displaystyle C_{e_3}^{J_2}}$ must be negative. This also means that in this situation, there can be more than one Rate-limiting step (biochemistry) in a pathway.

Unlike a linear pathway, values for ${\displaystyle C_{e_3}^{J_2}}$and ${\displaystyle C_{e_1}^{J_2}}$ are not bounded between zero and one. Depending on the values of the elasticities, it is possible for the control coefficients in a branched system to greatly exceed one.^[3] This has been termed the branchpoint effect by some in the literature.^[4]

The following branch pathway model (in antimony format) illustrates the case ${\displaystyle J_1}$ and ${\displaystyle J_3}$ have very high flux control and step J2 has proportional control.

   J1: $Xo -> S1; e1*k1*Xo
   J2:  S1 ->; e2*k3*S1/(Km1 + S1)
   J3:  S1 ->; e3*k4*S1/(Km2 + S1)
     
   k1 = 2.5;
   k3 = 5.9; k4 = 20.75
   Km1 = 4; Km2 = 0.02
   Xo =5; 
   e1 = 1; e2 = 1; e3 = 1

A simulation of this model yields the following values for the flux control coefficients with respect to flux ${\displaystyle J_2}$

In a linear pathway, only two sets of theorems exist, the summation and connectivity theorems. Branched pathways have an additional set of branch centric summation theorems. When combined with the connectivity theorems and the summation theorem, it is possible to derive the control equations shown in the previous section. The deviation of the branch point theorems is as follows.

1. Define the fractional flux through ${\displaystyle J_2}$ and ${\displaystyle J_3}$ as ${\displaystyle \alpha =J_2/J_1}$ and ${\displaystyle 1-\alpha =J_3/J_1}$ respectively.
2. Increase ${\displaystyle e_2}$ by ${\displaystyle \delta e_2}$. This will decrease ${\displaystyle S_1}$ and increase ${\displaystyle J_1}$ through relief of product inhibition.^[5]
3. Make a compensatory change in ${\displaystyle J_1}$ by decreasing ${\displaystyle e_1}$ such that ${\displaystyle S_1}$ is restored to its original concentration (hence ${\displaystyle \delta S_1=0}$).
4. Since ${\displaystyle e_1}$ and ${\displaystyle S_1}$ have not changed, ${\displaystyle \delta J_1=0}$.

Following these assumptions two sets of equations can be derived: the flux branch point theorems and the concentration branch point theorems.^[6]

From these assumptions, the following system equation can be produced:

${\displaystyle C_{e_2}^{J_1}\frac{\delta e_2}{e_2}+C_{e_3}^{J_1}\frac{\delta e_3}{e_3}=\frac{\delta J_1}{J_1}=0}$

Because ${\displaystyle \delta S_1=0}$ and, assuming that the flux rates are directly related to the enzyme concentration thus, the elasticities, ${\displaystyle {\epsilon }_{e_i}^v}$, equal one, the local equations are:

${\displaystyle \frac{\delta v_2}{v_2}=\frac{\delta e_2}{e_2}}$

${\displaystyle \frac{\delta v_3}{v_3}=\frac{\delta e_3}{e_3}}$

Substituting ${\displaystyle \frac{\delta v_i}{v_i}}$ for ${\displaystyle \frac{\delta e_i}{e_i}}$ in the system equation results in:

${\displaystyle C_{e_2}^{J_1}\frac{\delta v_2}{v_2}+C_{e_3}^{J_1}\frac{\delta v_3}{v_3}=0}$

Conservation of mass dictates ${\displaystyle \delta J_1=\delta J_2+\delta J_3}$ since ${\displaystyle \delta J_1=0}$ then ${\displaystyle \delta v_2=-\delta v_3}$. Substitution eliminates the ${\displaystyle \delta v_3}$ term from the system equation:

${\displaystyle C_{e_2}^{J_1}\frac{\delta v_2}{v_2}-C_{e_3}^{J_1}\frac{\delta v_2}{v_3}=0}$

Dividing out ${\displaystyle \frac{\delta v_2}{v_2}}$ results in:

${\displaystyle C_{e_2}^{J_1}-C_{e_3}^{J_1}\frac{v_2}{v_3}=0}$

${\displaystyle v_2}$ and ${\displaystyle v_3}$ can be substituted by the fractional rates giving:

${\displaystyle C_{e_2}^{J_1}-C_{e_3}^{J_1}\frac{\alpha }{1-\alpha }=0}$

Rearrangement yields the final form of the first flux branch point theorem:^[6]

${\displaystyle C_{e_2}^{J_1}(1-\alpha )-C_{e_3}^{J_1}\alpha =0}$

Similar derivations result in two more flux branch point theorems and the three concentration branch point theorems.

${\displaystyle C_{e_2}^{J_1}(1-\alpha )-C_{e_3}^{J_1}(\alpha )=0}$

${\displaystyle C_{e_1}^{J_2}(1-\alpha )+C_{e_3}^{J_2}(\alpha )=0}$

${\displaystyle C_{e_1}^{J_3}(\alpha )+C_{e_2}^{J_3}=0}$

${\displaystyle C_{e_2}^{S_1}(1-\alpha )+C_{e_3}^{S_1}(\alpha )=0}$

${\displaystyle C_{e_1}^{S_1}(1-\alpha )+C_{e_3}^{S_1}=0}$

${\displaystyle C_{e_1}^{S_1}(\alpha )+C_{e_2}^{S_1}=0}$

Following the flux summation theorem^[7] and the connectivity theorem^[8] the following system of equations can be produced for the simple pathway.^[9]

${\displaystyle C_{e_1}^{J_1}+C_{e_2}^{J_1}+C_{e_3}^{J_1}=1}$

${\displaystyle C_{e_1}^{J_2}+C_{e_2}^{J_2}+C_{e_3}^{J_2}=1}$

${\displaystyle C_{e_1}^{J_3}+C_{e_2}^{J_3}+C_{e_3}^{J_3}=1}$

${\displaystyle C_{e_1}^{J_1}{\epsilon }_s^{v_1}+C_{e_2}^{J_1}{\epsilon }_s^{v_2}+C_{e_3}^{J_1}{\epsilon }_s^{v_3}=0}$

${\displaystyle C_{e_1}^{J_2}{\epsilon }_s^{v_1}+C_{e_2}^{J_2}{\epsilon }_s^{v_2}+C_{e_3}^{J_2}{\epsilon }_s^{v_3}=0}$

${\displaystyle C_{e_1}^{J_3}{\epsilon }_s^{v_1}+C_{e_2}^{J_3}{\epsilon }_s^{v_2}+C_{e_3}^{J_3}{\epsilon }_s^{v_3}=0}$

Using these theorems plus flux summation and connectivity theorems values for the concentration and flux control coefficients can be determined using linear algebra.^[6]

${\displaystyle C_{e_1}^{J_2}=\frac{{\epsilon }_2}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

${\displaystyle C_{e_2}^{J_2}=\frac{{\epsilon }_3(1-\alpha )-{\epsilon }_1}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

${\displaystyle C_{e_3}^{J_2}=\frac{-{\epsilon }_2(1-\alpha )}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

${\displaystyle C_{e_1}^{S_1}=\frac{1}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

${\displaystyle C_{e_1}^{S_1}=\frac{-\alpha }{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

${\displaystyle C_{e_3}^{S_1}=\frac{-(1-\alpha )}{{\epsilon }_2\alpha +{\epsilon }_3(1-\alpha )-{\epsilon }_1}}$

• Control coefficient (biochemistry)
• Elasticity coefficient
• Metabolic control analysis