Team:UC Berkeley/Modeling

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Holin - inner membrane-bound proteins that when complexed with other holin proteins, create holes in the membrane that allow lysozyme access to the periplasm.   
Holin - inner membrane-bound proteins that when complexed with other holin proteins, create holes in the membrane that allow lysozyme access to the periplasm.   
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Antiholin - inner membrane-bound protein that binds to and inactivates holin to produce a holin-antiholin dimer. This dimer becomes active after holin forms enough pores in the plasma membrane to cause a loss of proton motive force between the periplasm and the cytosol.
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Antiholin - inner membrane-bound protein that binds to and inactivates holin,  producing an inactive holin-antiholin dimer. This dimer becomes active after holin forms enough pores in the plasma membrane to cause a loss of proton motive force between the periplasm and the cytosol.
Lysozyme - once holin forms pores in the inner membrane, lysozyme enters the periplasm and degrades peptidoglycan, resulting in cell lysis.
Lysozyme - once holin forms pores in the inner membrane, lysozyme enters the periplasm and degrades peptidoglycan, resulting in cell lysis.

Revision as of 00:00, 30 October 2008

Modeling

Introduction

The holin-lysozyme phage lysis device consists of three protein;

Holin - inner membrane-bound proteins that when complexed with other holin proteins, create holes in the membrane that allow lysozyme access to the periplasm.

Antiholin - inner membrane-bound protein that binds to and inactivates holin, producing an inactive holin-antiholin dimer. This dimer becomes active after holin forms enough pores in the plasma membrane to cause a loss of proton motive force between the periplasm and the cytosol.

Lysozyme - once holin forms pores in the inner membrane, lysozyme enters the periplasm and degrades peptidoglycan, resulting in cell lysis.

Holinantiholin1.jpg

Governing Equations

Our holin-lysozyme lysis device consists of holin and lysozyme under an inducible promoter and antiholin under a constitutive promoter. For more information on our lysis device, click here [[1]].

The kinetics of our phage lysis device was modeled to help our team gain an insight into the behavior of our system. The below equations describe our system

Cdb1.jpg

Where PH and PAH represent the mRNA promoter strengths, γmRNA,H and γmRNA,AH represent the degradation rates for holin and antiholin respectively and γ represents the protein degradation rate. kH and kAH represent the rate constants for holin and antiholin formation. and kc and ku represent the coupling and uncoupling rates for the holin-antiholin dimer.

Transfer Function and Dimensionless Parameters

At steady state,

Cdb2.jpg

By making this assumption, the system of equations can be simplified into the following transfer function

Cdb3.jpg

Where the system can be divided into three dimensionless parameters which describe the behavior of the holin-antiholin dimer and the holin and antiholin proteins.

Cdb4.jpg

These dimensionless numbers can assist in the optimization of lysis device design because they describe the important parameters in the system.

For example, ΩH consists of the rate constants for the formation of holin mRNA and the holin protein divided by their degradation rates. Strong promoters on holin will increase the value of ΩH, while high protein degradation rates will decrease ΩH.

ΩAH describes the constants and degradation rates for anti-holin.

Φ describes the importance of the coupling and uncoupling rates of holin-antiholin dimer as well as the degradation rate of the dimer.

Graphs

Physiologically relevant values for ΩH, ΩAH and Φ were estimated based on rate constants for similar proteins. This system was input into MatLab to produce the following graph. Since there is a degree of uncertainty in these estimates, the graph spans several orders of magnitude above and below our estimated values. For the MatLab code used to produce these graphs, please click here html:Matlab code.

Cdb5.jpg

The literature indicates that at the time of lysis, cells infected with λ phage have approximately 1000 holin proteins. Therefore, the critical concentration of holin (Hc) was set at 1000 holin proteins per cell.

The horizontal line at y=1 represents the critical holin concentration needed induce lysis. If the system produces more than the critical concentration of holin (>1000 free holin proteins), lysis is expected to occur.

As one would expect by looking at the dimensionless value for holin (omega H), as the strength of the holin promoter increases, the amount of holin at steady state increases.

The graph also shows that the system is not very sensitive to small amounts of antiholin. Larger amounts of antiholin push the system equilibrium to the left and would require a stronger promoter on holin or a weaker binding interaction between holin and antiholin to reach critical concentration. This is supported by the observation that in a system with no antiholin, lysis can occur with holin under a weaker promoter.

Varying Φ, the dimensionless parameter that describes the coupling and uncoupling behavior of the holin-antiholin dimer, reveals that when the binding of holin-antiholin is stronger, a stronger promoter is required to reach the critical holin concentration.

Conclusions

Since several phage systems and many promoters are currently in use, understanding the important parameters of the system allows one to choose appropriate promoters and phage proteins to optimize lysis behavior.