Team:Aberdeen Scotland/parameters/invest 1

Contents 1 Dissociation Constants 1.1 Introduction 1.2 Discontinuity 2 Discussion 2.1 Our new estimations for Kd 2.2 References

Dissociation Constants

Introduction

Our model uses hill kinetics; we have three repression hill functions of the form:

It has one activation hill function of the form:

And one repression / induction hill function of the form

Where β is the maximal transcription rate, [X] is the concentration of protein X and K_d is the dissociation constant for molecule X to the operator in question. Similarly, [S] is the concentration of the inducer - S - and K_s is the dissociation constant for the inducer to the repressor, X. K_d is defined as follows:

Where k_off and k_on are the on and off rates in the equation

K_d has a more biologically meaningful definition however, it is the concentration of X at which the operator will be repressed 50% of the time.

Discontinuity

The units of K_d are usually given in M, the molarity, or moles-per-litre. Our model works with the exact number of molecules so we may convert our K_d values into molecules-per-cell. This is achieved as follows:

Where the volume of the cytoplasm of the cell is 6.7×10^-16 litres

This conversion constant of Avogadro’s number multiplied by the cytoplasm volume is ~ 402000000 (402 million).

The problem with this is that most dissociation constants found in the literature equate to a value of molecules per cell that is less than 1. Clearly in a cell with 10 plasmids and therefore 10 operators 1 molecule could not repress all of them!

Below is a table of conflicting information we found. This is an extract from the ETHZ Wiki [6] with the new column of the value in molecule- per-cell added.

Parameter	Value	Molecules per cell	Description
KLacI	0.1 - 1 [pM] OR 800 [nM]	0.00004-0.0004 molecules OR 322 molecules	LacI repressor dissociation constant
KIPTG	1.3 [µM]	522 molecules	IPTG-LacI repressor dissociation constant
KtetR	179 [pM]	0.07 molecules	TetR repressor dissociation constant
KcI	8 [pM] OR 50 [nM]	0.003 molecules OR 20 molecules	cI repressor dissociation constant
KHSL	0.09 - 1 [µM]	402 molecules	HSL-LuxR activator dissociation constant

And here are the other parameters we found in the literature

Parameter	Value	Molecules per cell	Description	Reference
KLacI	~1*10 -12 M OR ~1.8*10-12 M	0.0004 molecules OR 0.00072 molecules	Dissociation constant for LacI to LacO DNA site	[1][2]
KIPTG	1*10-6 M	402 molecules	Dissociation constant for IPTG to LacI	[3]
KtetR	(5.6 ± 2) × 10-9 M OR 1.53*10-8 M	2.25 molecules OR 6.1506 molecules	Dissociation constant for TetR to TetO	[4][5]
KcI	50 * 10-9 M	20 molecules	Dissocitation constant for cI to DNA site	[6]

Discussion

Upon further investigation we have concluded that the majority of K_d values found in papers were unrealistically low for the following reasons:

1. Most K_d values are measured in-vitro, which yields a low measurement since the conditions of the reaction - most notably the salt concentration and pressure - are completely different than in an E.coli cell. The salt concentration affects the reaction significantly since it lowers the electrostatic affinity of the protein to the operon. We know from Thermodynamics that pressure and temperature will change reaction kinetics and hence the in vitro experiments will have different reaction rates and hence different K_d values than would be found in the cell.

2. We have found measurements of K_d values which have been done in conditions which try to replicate in vivo conditions. These K_d values are better, but also infeasibly low, since they do not take into account non-specific DNA binding and cell pressure.

3. In our model, we describe concentrations in terms of molecules-per-cell, instead of moles-per-litre. Upon converting the K_d values from moles-per-lire to molecules-per-cell we found that a great deal the K_d values we found were less than 1 molecule per cell. This implies that less than one protein (LacI, TetR etc.) is required to half the overall production. This is physically irrepresentative for a number of reasons, including the fact that the probability that one protein molecule will collide with a single operon in the cell at the correct angle is close to zero.

We consulted with Prof. Peter McGlynn of the Institute of Medical Sciences in Aberdeen, who agreed with our analysis of the K_d values and introduced the idea of non-specific DNA binding. He showed us a PhD thesis from one of his students, Bryony Payne, from 2006. In this thesis a far more direct and accurate measurement of the LacO repression was made. It stated that 340 tetramers of LacI were required to fully repress the LacO operon. From this value, we estimated the K_d value for the LacO operon to be 700 molecules-per-cell.

Our new estimations for K_d

Starting our estimation from Prof. Mcglynn’s PhD student Bryony Payne; 2006, we are given that 340 LacI tetramers completely repress a promoter. Hence roughly 120 tetramers will give half repression. Assuming the tetramers are stable this gives a value of K_LacI , K_d for LacI to LacO, of 4×170 or K_LacI ~ 700.

For the LacI IPTG complex formation, we estimated K_IPTG ~1200 using [7] and our value of K_LacI above. TetR to TetO seems to have a lower affinity to each other than LacI to LacO. However, the in vitro values suggest that TetR binds still with a strong affinity to TetR. Thus the K_TetR value was roughly estimated to be up to 10 times K_LacI. The in vitro values for cI to its operon seem to suggest that the in vivo K_cI value is in the same order of magnitude, but possibily smaller, than K_TetR.

So we now have:

K_LacI = 700 molecules per cell

K_cI = 7000 molecules per cell

K_TetR = 7000 molecules per cell

References

[1] Mitchel Lewis (2005) The Lac repressor. C. R. Biologies 328 (2005) 521–548

[2] Falcon C.M and Matthews K.S. (2000) Operator DNA sequence Variation Enhances High Affinity Binding by Hinge Helix Mutants of Lactose Repressor Protein. Biochemistry. 39, 11074-11084

[3] Uri Alon, An introduction to systems Biology, p244

[4] Nucleic Acids Res. 2004; 32(2): 842–847. Two mutations in the tetracycline repressor change the inducer anhydrotetracycline to a corepressor Annette Kamionka, Joanna Bogdanska-Urbaniak, Oliver Scholz, and Wolfgang Hillen*

[5] Volume 272, Number 11, Issue of March 14, 1997 pp. 6936-6942, The Role of the Variable Region in Tet Repressor for Inducibility by Tetracycline, Christian Berens , Dirk Schnappinger and Wolfgang Hillen

[6] http://parts.mit.edu/igem07/index.php?title=ETHZ/Parameters

[7] Detailed map of a cis-regulatory input function – Y. Setty*,†, A. E. Mayo*,†, M. G. Surette‡, and U. Alon*,†,§

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