Saint Petersburg/Algebra

From 2007.igem.org

< Saint Petersburg
Revision as of 08:33, 11 October 2007 by Alexej (Talk | contribs)

Bistable behaviour of two repressors, mutually reperssing each other

Main page Previous page - Model Formulation

Algebraic analysis of stabilty

Graphical analysis and numeric modeling are obvious, but the algebraic solution is the most powerful for describing the modes of the behavior of the system, and finding optimal parameters. The system (III) may be reduced to one equation with one response variable:

F (X; P, Q, J, n, m) = 0 (IVa)

In our case the system will yield:

Spb eqn 010.gif (IVb)

If we solve this equation for X, we will get all the stationary points for the system (III). Although the response X could be found only in few limited cases, stability analysis for our model could be performed in the most general case.

Fisrt we will find the bifurcation set. P, Q and J form the control space of the system (m and n are considered to be static parameters, as they are innate to the design and are not easily changed). Bifurcation set is the set of points in the control space, where the number of stationary points (system responses) change abruptly. That is the points where the roots of the equation (IV) has order higher than 1. In other words, bifurcation points are the points of discontinuity of partial derivatives dX/dp (p - any parameter in F). There is a well-known expression for parametric functions:

Spb eqn 012.gif

As our model is continious with respect to its parameters (linear with respect to P, Q, J) a derivative dX/dp only becomes discontinuous when dF/dX = 0. So the bifurcation set is given by the system:

Spb eqn 014.gif

In our case the expression yields:

Spb eqn 016.gif (V)

In our case the system may be solved algebraically for the (P,Q) (J, P) and (J, Q) cross-sections. For the solution, that we omit for its clumsiness (thanks to math software), it is important that X, P, Q and J are significantly positive, and m and n are larger or equal to 1. It is required in several cases to state, that (Z1/N)N = Z. The solutions are given in parametric form P=P(X; J), Q=Q(X; J) with X as a parametric variable. X may not be excluded in general case, but the cross sections of bifurcation set may be now plotted easily for any P, Q and J.

The results

Here we will discuss only the (P, Q) cross section. Two other cross sections could be viewed by following the links below Fig 2. In (P, Q) cross section the bifuraction set is given by the following expression:

Spb eqn 018.gif

To obtain the bifurcation curve here one should plot the second parameter versus the first, varying X from 0 to P+J. The bifurcation curves for various m and n and no input signal provided are presented in Fig 2.

Bifurc PQ1.gif

Figure 2. Bufurcation sets of cross-repressor system for various and equal cooperativity indices. The area of hysteretic behaviour for m=n=2 is filled with green.

(J, P)-cross section. Behaviour of the system at fixed efficiency Q of the out-of-phase operator.

(J, Q)-cross section. Behaviour of the system at fixed efficiency P of the in-phase operator.

The bifurcation set has a typical cusp geometry. The two lines, leaving the cusp are the two fold catastrophes (they will be real folds if we visualize the response surface). In the region outside the cusp the system is monostable and the response is solely defined by the values of parameters (quasi-stationary). The system (III) has only one positive solution. Inside the cusp the system is bistable. Three roots for system (III) exist, one of them correspond to unstable saddle point – transition state. The dynamic system (II) has to have hysteresis – the responce will depend on the previous history of the process. The amplitude of hysteresis increase rapidly as we get deeper into the cusp region.

The cusp point (the catastrophe itself) deserves some additional words. If we enter the bifurcation set through the cusp point, the number of roots will change from 1 to 3, that is two roots will arise simultaneously (so called pitchfork). With respect to dynamic behaviour, it means that the state of the system will become undetermined. In the cusp point X is the third order root of F. This is the clue point for finding the cusp position. In this point both dP/dX and dQ/dX become zero simultaneously, making d2X/dp1dp2 discontinuous.

In general case, the cusp tip in (P,Q) cross-section of the control space is located at X, given by equation:

Spb eqn 020.gif

It could not be generally solved. But at J = 0 it could be solved and the cusp position is given by algebraic expression:

Spb eqn 022.gif

There are 3 important findings for J = 0

1. The cusp exists only if m*n>1. At m or n close to 1 the cusp is very narrow, the hysteresis is weak, and could be found only at large P and Q

2. At large m and n the cusp becomes wide and blunt, and asymptotically coincides the quadrant (P>1, Q>1). The latter corresponds to ideal invertors with infinite cooperativities. The hysteresis amplitude is very strong and approaches dynamic range (0, P)

3. The changes of position of the bifurcation set with respect to J become less significant as m*n increase. That is the behavior of the system is most “catastrophic” at intermediate values of m*n (There is a general principle in catastrophe theory stating, that the behavior of the system is more catastrophic when the cusps are sharp).

For the selection of P0 and Q0 parameters for the desired device we will consider several cases. (P0 and Q0 are the “efficiencies” of the repressors, that should be used in the device). The positions of the points and typical response curves are shown on figures 3 and 4.


I. The (P0, Q0) point is outside the cusp region at all J. This case corresponds to single-value device without hysteresis. If the point is located “below” the cusp catastrophe (Ia) the response may be significantly nonlinear. If it is located “sideways”, the response is monotonous and almost linear. The latter device could hardly have some practical importance.

II. The (P0, Q0) point is inside the cusp region at all available J, so that hysteresis always exist. This device is of no practical importance, as either of its states is maintained infinitely and could not be changed.

III. The (P0, Q0) point is inside the cusp region at J = 0, but exits it at some J1. This case corresponds to full trigger. It will switch to certain state, when J exceeds J1 and will maintain this state at J = 0 and all other positive J. We cannot switch the full trigger back using J input. To do so, we must provide another (reset) input. In our system this could be an addenda to the second equation in (I) similar to J.

IV. The (P0, Q0) point is initially outside the cusp region, but it is crossed by both folds of the cusp, while J increases. This case corresponds to a comparator, if the point is located close to the cusp and the hysteresis is narrow (IVa), or Schmitt trigger if the hysteresis is wide (IVb).