Linear biochemical pathway

Template:Multiple issues A linear biochemical pathway is a chain of enzyme-catalyzed reaction steps where the product of one reaction becomes the substrate for the next reaction. The molecules progress through the pathway sequentially from the starting substrate to the final product. Each step in the pathway is usually facilitated by a different specific enzyme that catalyzes the chemical transformation. An example includes DNA replication, which connects the starting substrate and the end product in a straightforward sequence.

Biological cells consume nutrients to sustain life. These nutrients are broken down to smaller molecules. Some of the molecules are used in the cells for various biological functions, and others are reassembled into more complex structures required for life. The breakdown and reassembly of nutrients is called metabolism. An individual cell contains thousands of different kinds of small molecules, such as sugars, lipids, and amino acids. The interconversion of these molecules is carried out by catalysts called enzymes. For example, the most widely studied bacterium, E. coli strain K-12, is able to produce about 2,338 metabolic enzymes.^[1] These enzymes collectively form a complex web of reactions comprising pathways by which substrates (including nutients and intermediates) are converted to products (other intermediates and end-products).

The figure below shows a four step pathway, with intermediates, ${\displaystyle S_1,S_2,}$ and ${\displaystyle S_3}$. To sustain a steady-state, the boundary species ${\displaystyle X_o}$ and ${\displaystyle X_1}$ are fixed. Each step is catalyzed by an enzyme, ${\displaystyle e_i}$.

Linear pathways follow a step-by-step sequence, where each enzymatic reaction results in the transformation of a substrate into an intermediate product. This intermediate is processed by subsequent enzymes until the final product is synthesized.

A linear pathway can be studied in various ways. Multiple computer simulations can be run to try to understand the pathway's behavior. Another way to understand the properties of a linear pathway is to take a more analytical approach. Analytical solutions can be derived for the steady-state if simple mass-action kinetics are assumed.^[2][3][4] Analytical solutions for the steady-state when assuming Michaelis-Menten kinetics can be obtained^[5][6] but are quite often avoided. Instead, such models are linearized. The three approaches that are usually used are therefore:

• Computer simulation
• Analytical solutions using a linear mathematical model
• Linearization of a non-linear model

It is possible to build a computer simulation of a linear biochemical pathway. This can be done by building a simple model that describes each intermediate through a differential equation. The differential equations can be written by invoking mass conservation. For example, for the linear pathway:

${\displaystyle X_o\stackrel{v_1}{⟶}{S}_1\stackrel{v_2}{⟶}{S}_2\stackrel{v_3}{⟶}{S}_3\stackrel{v_4}{⟶}{X}_1}$

where ${\displaystyle X_o}$ and ${\displaystyle X_1}$ are fixed boundary species, the non-fixed intermediate ${\displaystyle S_1}$ can be described using the differential equation:

${\displaystyle \frac{d{S}_1}{dt}=v_1-v_2}$

The rate of change of the non-fixed intermediates ${\displaystyle S_2}$ and ${\displaystyle S_3}$ can be written in the same way:

${\displaystyle \frac{d{S}_2}{dt}=v_2-v_3}$

${\displaystyle \frac{d{S}_3}{dt}=v_3-v_4}$

To run a simulation the rates, ${\displaystyle v_i}$ need to be defined. If mass-action kinetics are assumed for the reaction rates, then the differential equation can be written as:

${\displaystyle \begin{array}{ccc}{\displaystyle \frac{d{S}_1}{dt}}& =& k_1{X}_o-k_2{S}_1\\ {\displaystyle \frac{d{S}_2}{dt}}& =& k_2{S}_1-k_3{S}_2\\ {\displaystyle \frac{d{S}_3}{dt}}& =& k_3{S}_2-k_4{S}_3\end{array}}$

If values are assigned to the rate constants, ${\displaystyle k_i}$, and the fixed species ${\displaystyle X_o}$ and ${\displaystyle X_1}$the differential equations can be solved.

Computer simulations can only yield so much insight, as one would be required to run simulations on a wide range of parameter values, which can be unwieldy. A generally more powerful way to understand the properties of a model is to solve the differential equations analytically.

Analytical solutions are possible if simple mass-action kinetics on each reaction step are assumed:

${\displaystyle v_i=k_i{s}_{i-1}-k_{-i}{s}_i}$

where ${\displaystyle k_i}$ and ${\displaystyle k_{-1}}$ are the forward and reverse rate-constants, respectively. ${\displaystyle s_{i-1}}$ is the substrate and ${\displaystyle s_i}$ the product. If the equilibrium constant for this reaction is:

${\displaystyle K_{eq}=q_i=\frac{k_i}{k_{-i}}=\frac{s_i}{s_{i-1}}}$

The mass-action kinetic equation can be modified to be:

${\displaystyle v_i=k_i(s_{i-1}-\frac{s_i}{q_i})}$

Given the reaction rates, the differential equations describing the rates of change of the species can be described. For example, the rate of change of ${\displaystyle s_1}$ will equal:

${\displaystyle \frac{d{s}_1}{dt}=k_1(x_0-\frac{s_1}{q_1})-k_2(s_1-\frac{s_2}{q_2})}$

By setting the differential equations to zero, the steady-state concentration for the species can be derived. From here, the pathway flux equation can be determined. For the three-step pathway, the steady-state concentrations of ${\displaystyle s_1}$ and ${\displaystyle s_2}$ are given by:

${\displaystyle \begin{array}{cc}& s_1=\frac{q_1}{q_3}\frac{k_2{k}_3{x}_1+k_1{k}_2{q}_3{x}_o+k_1{k}_3{q}_2{q}_3{x}_o}{k_1{k}_2+k_1{k}_3{q}_2+k_2{k}_3{q}_1{q}_2}\\ & s_2=\frac{q_2}{q_3}\frac{k_1{k}_3{x}_1+k_2{k}_3{q}_1{x}_1+k_1{k}_2{q}_1{q}_3{x}_o}{k_1{k}_2+k_1{k}_3{q}_2+k_2{k}_3{q}_1{q}_2}\end{array}}$

Inserting either ${\displaystyle s_1}$ or ${\displaystyle s_2}$ into one of the rate laws will give the steady-state pathway flux, ${\displaystyle J}$:

${\displaystyle J=\frac{x_o{q}_1{q}_2{q}_3-x_1}{\frac{1}{k_1}{q}_1{q}_2{q}_3+\frac{1}{k_2}{q}_2{q}_3+\frac{1}{k_3}{q}_3}}$

A pattern can be seen in this equation such that, in general, for a linear pathway of ${\displaystyle n}$ steps, the steady-state pathway flux is given by:

${\displaystyle J=\frac{x_o{\displaystyle \prod _{i=1}^n}{q}_i-x_1}{{\displaystyle \sum _{i=1}^n}\frac{1}{k_i}\left({\displaystyle \prod _{j=i}^n}{q}_j\right)}}$

Note that the pathway flux is a function of all the kinetic and thermodynamic parameters. This means there is no single parameter that determines the flux completely. If ${\displaystyle k_i}$ is equated to enzyme activity, then every enzyme in the pathway has some influence over the flux.

Given the flux expression, it is possible to derive the flux control coefficients by differentiation and scaling of the flux expression. This can be done for the general case of ${\displaystyle n}$ steps:

${\displaystyle C_i^J=\frac{\frac{1}{k_i}{\displaystyle \prod _{j=i}^n}{q}_j}{{\displaystyle \sum _{j=1}^n}\frac{1}{k_j}{\displaystyle \prod _{k=j}^n}{q}_k}}$

This result yields two corollaries:

• The sum of the flux control coefficients is one. This confirms the summation theorem.
• The value of an individual flux control coefficient in a linear reaction chain is greater than 0 or less than one: ${\displaystyle 0\le C_i^J\le 1}$

For the three-step linear chain, the flux control coefficients are given by:

${\displaystyle C_1^J=\frac{1}{k_1}\frac{q_1{q}_2{q}_3}{d};C_2^J=\frac{1}{k_2}\frac{q_2{q}_3}{d};C_3^J=\frac{1}{k_3}\frac{q_3}{d}}$

where ${\displaystyle d}$ is given by:

${\displaystyle d=\frac{1}{k_1}{q}_1{q}_2{q}_3+\frac{1}{k_2}{q}_2{q}_3+\frac{1}{k_3}{q}_3}$

Given these results, there are some patterns:

• If all three steps have large equilibrium constants, that is ${\displaystyle q_i\gg 1}$, then ${\displaystyle C_1^J}$ tends to one and the remaining coefficients tend to zero.
• If the equilibrium constants are smaller, control tends to get distributed across all three steps.

With more moderate equilibrium constants, perturbations can travel upstream as well as downstream. For example, a perturbation at the last step, ${\displaystyle k_3}$, is better able to influence the reaction rates upstream, which results in an alteration in the steady-state flux.

An important result can be obtained if all ${\displaystyle k_i}$ are set as equal to each other. Under these conditions, the flux control coefficient is proportional to the numerator. That is:

${\displaystyle \begin{array}{cc}{C}_1^J& \propto q_1{q}_2{q}_3\\ C_2^J& \propto q_2{q}_3\\ C_3^J& \propto q_3\\ \end{array}}$

If it is assumed that the equilibrium constants are all greater than 1.0, as earlier steps have more ${\displaystyle q_i}$ terms, it must mean that earlier steps will, in general, have high larger flux control coefficients. In a linear chain of reaction steps, flux control will tend to be biased towards the front of the pathway. From a metabolic engineering or drug-targeting perspective, preference should be given to targeting the earlier steps in a pathway since they have the greatest effect on pathway flux. Note that this rule only applies to pathways without negative feedback loops.^[7]

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