Collaborations
Our collaborations
Introduction
We conceived a model in order to handle questions concerning the following situation:
A bacterial growth is carried out in a bioreactor, continually supplied in substrate.
Bacteria can possess 2 type of plasmids:
- plasmids 1 carry the toxin A gene and the anti-toxin B gene
- plasmids 2 carry the toxin B gene and the anti-toxin A gene
So during the growth each bacterium can have no plasmids, either one type of plasmids, or both types.
The aim of the model is to assess the evolution of plasmids throughout the culture, to determine which parameters can matter in the loss of those plasmids, and to precise what are the probabilities for a bacteria to loose its plasmids during cell division.
As a plasmids can be a disadvantage for growth (energy spent into replicating processes) or a advantage (protection against a toxin) this question is hard to answer. But in this situation, where one type of plasmid can influence on the presence of the other type of plasmid in (and reciprocally) in the same bacteria, the question become too tough to answer and only a mathematical model can resolve such a interrogation!
Equations
Development of the model
In 1967 Fredrickson et al. studied mathematically development of a bacterialpopulation, under the assumptions of a large population of independant bacteriain a well mixed solution of constant volume. The large population ensures thatfor the population the expectation value is a good estimate of the average.The bacteria being independant ensures that the behaviour of each individualdepends only on its internal state z and the conditions c which are the samefor all individuals. The volume is well mixed so the conditions c which are thesame everywhere. The volume is constant so that the population caracteristicscan be evaulated by integration over the volume.
From this starting point they develop a pair of master equations of change
to describe the evolution of the population:
\frac{\partial}{\partial t} W_\mathbf{z} (\mathbf{z},t) + \nabla_\mathbf{z}\cdot[(\beta\cdot\overline{\mathbf{R}}(\mathbf{z},c)W_\mathbf{z}(\mathbf{z},t))]
\\
\\
= 2 \int \sigma (\mathbf{z',c}) p(\mathbf{z,z',c}) W_{\mathbf{Z}}(\mathbf{z'},t)\mathrm{d}v' - (D+\sigma (\mathbf{z,c})) W_{\mathbf{Z}}(\mathbf{z},t)
(1)
\\
\\
\frac{d\mathbf{c}}{dt} = D(\mathbf{c_f} - \mathbf{c} ) + \mathbf{\gamma}\cdotp \int \bar{\mathbf{R}}(\mathbf{z,c}) W_{\mathbf{Z}}(\mathbf{z},t)\mathrm{d}v
(2)
In these equations the various symbols are as follows:
\mathbf{z}
|
Vector for internal state of a bacteria.
|
\mathbf{c}
|
Time dependant vector for conditions.
|
W_\mathbf{z} (\mathbf{z},t)
|
Distribution of bacteria in z, t space.
|
\overline{\mathbf{R}}(\mathbf{z},c)
|
The expected value or the reaction rate vector in z, t space.
|
\sigma (\mathbf{z,c})
|
Rate of fision for bacteria in z, c space.
|
p(\mathbf{z,z',c}))
|
Partitioning probability of generating a child in state z from a parent in state z'.
|
\nabla_\mathbf{z}\cdot\mathbf{V}
|
\sum \frac{\partial}{\partial z_i}\mathbf{V}_i
|
\mathrm{d}v'
|
Integral over state space v'
|
| D
|
Dilution rate of the culture (for femrenters).
|
\beta
|
Stochiometric matrix for cellular substances.
|
\gamma
|
Stochiometric matrix for extra-cellular substances.
|
With these relations:
\dot{\mathbf{V}}(\mathbf{z,c}) = \mathbf{\beta} \cdotp \mathbf{R}(\mathbf{z,c})
The expected internal state change rate vector.
\\ -\mathbf{\gamma} \cdotp \bar{\mathbf{R}}(\mathbf{z,c})
The expected consumation of substances in the environment by a cell in state
z.
Thus for a particular problem in hand it is necessary to chose z and c that represent the state of cells and the media. Then the matrices and functions
\beta, \gamma, \mathbf{R}(\mathbf{z,c}), \sigma (\mathbf{z',c}) and p(\mathbf{z,z',c})
need to be defined for the problem considered. Finally the inital conditions
W_{\mathbf{Z}}(\mathbf{z},t)
and
c_0
and growth conditions D and
c_f
need to be fixed.
For the problem in hand, plasmid maintenance during growth with 2 different plasmids, and attempting to find a simple solution to the problem we propose a 3 variable internal state vector:
$$\mathbf{z} = \begin{bmatrix} z_0 \\ z_1 \\ z_2 \end{bmatrix} = \begin{bmatrix}\textrm{Cell maturity} \\ \textrm{count of plasmid 1} \\ \textrm{count of plasmid 2} \end{bmatrix}$$ \\
In this internal state vector
v0
is a mesure of the growth of the bacteria,encompassing such things as size, number of chromosomes and mass,
v1
and
v2
represent the number of copies of each plasmid. For the external conditions wepropose simply the substrate concentration S. The maturity has a minimumvalue of 1 and must increase to 2 before division can occur.
For the rates of change of the internal state vector then we propose for the bacterial maturity to extend the development presented in Shene et al. [?] to include 2 plasmids and incorporate cell maturity as a state variable. This gives:
\dot{z}_0 (\mathbf{z},S) = \mu = \mu _{max} \frac{S}{K_S+S} \frac{K_{z_1}}{K_{z_1}+z_1^{m_1}} \frac{K_{z_2}}{K_{z_2}+z_2^{m_2}} \\
(3)
Here
\mu _{max}
is the maximum growth rate
hr^{-1}: $\mu (\mathbf{z,S})
the growth rate ;
K_S
is the Monod constant in g/l for the substrate;
K_{z_1}
is the inhibition constant for plamid number 1 in (plasmids per cell)
^{m_1}
, and
m_1
the Hill coefficient for the cooperativity of inhibition.
K_{z_2}
and
m_2
represent the same parameters for plasmid 2.
For plasmid replication rate we propose, again following Shene et al. [?], the empirical relationship :
\dot{z}_1 (\mathbf{z},S) = k_1 \frac{\mu (\mathbf{z},S)}{K_1 + \mu (\mathbf{z},S)} ( z_{1_{max}} - z_1 ) if z_1 \geq 1.0 or \dot{z}_1 (\mathbf{z},S) = 0 if 0.0 \leq z_1 < 1.0
(4)
This relation, and equivalent one for plasmid number 2
\dot{z}_2 (\mathbf{z,S})
is designed to satisfy the boundary conditions of no reproduction if there is less than 1 plasmid in the cell, and a maximum copy number of
z_{1_{max}}
. This introduces the parameters
k_1
and
K_1
which are respectively the plasmid replication rate (in
hr^{-1}
) and the inhibition constant (also in
hr^{-1}
).
The inhibition constant reduces plasmid replication rate at slower growth rates.
Notice that here we have directly defined
\bar{\dot{\mathbf{V}}}(\mathbf{z,c})
rather than
\beta
and
\bar{\mathbf{R}}(\mathbf{z,c})
.
For the growth yield we propose :
\gamma \cdotp \bar{\mathbf{R}}(\mathbf{z,c}) = \alpha \mu(\mathbf{z},S)
(5)
Where alpha is the growth yield in
g/l/cell
. The remaining functions and parameters in equations 1 and 2 are the division rate
\sigma (\mathbf{z,c})
and the partitioning 2 function
p(\mathbf{z,z',c})
. There is less consensus in the litterature for an at least empirically appropriate form for these equations. To remain simple we propose:
\sigma (\mathbf{z,c}) = \sigma \times H[2.0] = 0 if z_0 < 2.0 \\ \sigma (\mathbf{z,c}) = \sigma \times H[2.0] = \sigma if z_0 \geq 2.0
(6)
Here we assume that there is a fixed rate of division
\sigma
once cells are big enough to divide (
H[]
is the Heaviside function).
p(\mathbf{z,z',c}) = p(z_0,z'_0) \times p(z_1,z'_1) \times p(z_2,z'_2)
(7)
p(z_0,z'_0) = \delta_{z_0,\frac{z'_0}{2}} = 1 if z_0 = z'_0/2.0 \\
p(z_0,z'_0) = \delta_{z_0,\frac{z'_0}{2}} = 0 if z_0 \ne z'_0/2.0.
(8)
p(z_1,z'_1) = 0.5^{z'_1} \begin{pmatrix} z_1 \\ z'_1 \\ \end{pmatrix} = 0.5^{z'_1} \frac{z'_1 !}{(z'_1-z_1)! z_1 !}
(9)
In these equations we assume that the partitioning of the three internal state variables are independant.
That cells divide exactly in half, that is the maturity parameter is exactly halved when the cells divide
(
\delta
is a Kronecker delta function).
That the two plasmids segregate independantly and as individual plasmids according to a binomial distribution.
These assumptions are probably the most suspect in the model.
This initial version of the model has no contention, that is
z_1
and
z_2
do not influence the growth rate
\mu
.
In order to develop the model for the system envisaged this needs to be introduced.
Substituting into the equations 1 and 2 we obtain:
\frac{\partial}{\partial t} W_{\mathbf{Z}}(\mathbf{z},t)
+ [\nabla_{\mathbf{Z}} \cdotp \bar{\dot{\mathbf{Z}}}(\mathbf{z},S)] W_{\mathbf{Z}}(\mathbf{z},t)
+ \sum_i \bar{\dot{z_i}} \times \frac{\partial}{\partial z_i} W_{\mathbf{Z}}(\mathbf{z},t)\\
= 2 \sigma \int_{z'_0>2.0} \delta_{z_0,\frac{z'_0}{2}} \times 0.5^{z'_1+z'_2} \times \begin{pmatrix} z_1 \\ z'_1 \\ \end{pmatrix} \times \begin{pmatrix} z_2 \\ z'_2 \\ \end{pmatrix} \times
W_{\mathbf{Z}}(\mathbf{z'},t)\mathrm{d}v' \\
- (D+\sigma H[2.0] W_{\mathbf{Z}}(\mathbf{z},t))
(10)
\frac{d\mathbf{c}}{dt}
= D(c_f - c ) - \alpha \int \mu (\mathbf{z},S) W_{\mathbf{Z}}(\mathbf{z},t)\mathrm{d}vv
(11)
Objectives
The aim of studying the behaviour of this model is to investigate how growth conditions
D, S_f
and time modulate the development of the population in state space
W_{\mathbf{Z}}(\mathbf{z},t)
. In particular we are interested in finding how the number of bacteria without plasmids
W_{\mathbf{Z}}([z_0,0,0],t)
in the culture progresses, and how this depends on the various parameters in the model.
Proposition: Adding contention
We need to introduce a modification to equation 3 (the state dependant growth rate) in which the equilibrium between
z_1
and
z_2
features.
This modification is to take into account that each toxin should be inhibited by anti-toxin for maximal growth.
A possibility is that we consider that for each toxin anti-toxin pair:
\begin{itemize}
\item the genes produce toxin at a constant rate dependant on the number of copies
k_1\times z_1
,
\item the anti-toxin genes produce anti-toxin at a rate dependant on the number of copies
k_2\times z_2
,
\item anti-toxin instantly and irreversible kills the toxin in a stochiometric manner.
\item undestroyed toxin disappears at a constant rate, by dilution and other pathways
k_3
,
\item the concentration of toxin is at a dynamic steady state, i.e. the rates of production and disappearance are equal.
\item growth in inhibited in an exponential manner by free toxin with a characteristic
IC_{50}
.
\end{itemize}
This model of toxin anti-toxin interaction takes into account the bacteriostatic nature of most such toxins,
and the presence of measurable
IC_{50}
values.
Clearly a more realsitic model would need to take into account cell volume, protein synthesis rates etc.
Nevertheless, this simple model gives:\\
Progamming code
Code de françois à ajouter
Results
METTRE LES COURBE
In order to help the iGEM team Bordeaux, we had to read the paper « Dynamics of plasmid transfer on surfaces » and collect and organize some data about their experiments on plasmids transfer. Thanks to this, the iGEM team Bordeaux can compare those results to their own computaionnal results.
The iGEM team Pretoria 2016 hepled us focusing on the socio-economic and political issues facing the current platinum sector, including the Marikana strikes.
★ ALERT!
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Delete this box in order to be evaluated for this medal. See more information at <a href="https://2016.igem.org/Judging/Evaluated_Pages/Instructions"> Instructions for Evaluated Pages </a>.
Sharing and collaboration are core values of iGEM. We encourage you to reach out and work with other teams on difficult problems that you can more easily solve together.
Which other teams can we work with?
You can work with any other team in the competition, including software, hardware, high school and other tracks. You can also work with non-iGEM research groups, but they do not count towards the iGEM team collaboration silver medal criterion.
In order to meet the silver medal criteria on helping another team, you must complete this page and detail the nature of your collaboration with another iGEM team.
Here are some suggestions for projects you could work on with other teams:
- Improve the function of another team's BioBrick Part or Device
- Characterize another team's part
- Debug a construct
- Model or simulating another team's system
- Test another team's software
- Help build and test another team's hardware project
- Mentor a high-school team
