Zimm–Bragg model

In statistical mechanics, the Zimm–Bragg model is a helix-coil transition model that describes helix-coil transitions of macromolecules, usually polymer chains. Most models provide a reasonable approximation of the fractional helicity of a given polypeptide; the Zimm–Bragg model differs by incorporating the ease of propagation (self-replication) with respect to nucleation. It is named for co-discoverers Bruno H. Zimm and J. K. Bragg.

Helix-coil transition models

Helix-coil transition models assume that polypeptides are linear chains composed of interconnected segments. Further, models group these sections into two broad categories: coils, random conglomerations of disparate unbound pieces, are represented by the letter 'C', and helices, ordered states where the chain has assumed a structure stabilized by hydrogen bonding, are represented by the letter 'H'.^[1]

Thus, it is possible to loosely represent a macromolecule as a string such as CCCCHCCHCHHHHHCHCCC and so forth. The number of coils and helices factors into the calculation of fractional helicity, ${\displaystyle \theta \ }$ , defined as

${\displaystyle \theta ={\frac {\left\langle i\right\rangle }{N}}}$ 

where

${\displaystyle \left\langle i\right\rangle \ }$  is the average helicity and

${\displaystyle N\ }$  is the number of helix or coil units.

Zimm–Bragg

Dimer sequence	Statistical weight
${\displaystyle ...CC...\ }$	${\displaystyle 1\ }$
${\displaystyle ...CH...\ }$	${\displaystyle \sigma s\ }$
${\displaystyle ...HC...\ }$	${\displaystyle \sigma s\ }$
${\displaystyle ...HH...\ }$	${\displaystyle \sigma s^{2}\ }$

The Zimm–Bragg model takes the cooperativity of each segment into consideration when calculating fractional helicity. The probability of any given monomer being a helix or coil is affected by which the previous monomer is; that is, whether the new site is a nucleation or propagation.

By convention, a coil unit ('C') is always of statistical weight 1. Addition of a helix state ('H') to a previously coiled state (nucleation) is assigned a statistical weight ${\displaystyle \sigma s\ }$ , where ${\displaystyle \sigma \ }$  is the nucleation parameter and ${\displaystyle s\ }$  is the equilibrium constant

${\displaystyle s={\frac {[H]}{[C]}}}$ 

Adding a helix state to a site that is already a helix (propagation) has a statistical weight of ${\displaystyle s\ }$ . For most proteins,

${\displaystyle \sigma \ll 1<s\ }$ 

which makes the propagation of a helix more favorable than nucleation of a helix from coil state.^[2]

From these parameters, it is possible to compute the fractional helicity ${\displaystyle \theta \ }$ . The average helicity ${\displaystyle \left\langle i\right\rangle \ }$  is given by

${\displaystyle \left\langle i\right\rangle =\left({\frac {s}{q}}\right){\frac {dq}{ds}}}$ 

where ${\displaystyle q\ }$  is the partition function given by the sum of the probabilities of each site on the polypeptide. The fractional helicity is thus given by the equation

${\displaystyle \theta ={\frac {1}{N}}\left({\frac {s}{q}}\right){\frac {dq}{ds}}}$ 

Statistical mechanics

The Zimm–Bragg model is equivalent to a one-dimensional Ising model and has no long-range interactions, i.e., interactions between residues well separated along the backbone; therefore, by the famous argument of Rudolf Peierls, it cannot undergo a phase transition.

The statistical mechanics of the Zimm–Bragg model^[3] may be solved exactly using the transfer-matrix method. The two parameters of the Zimm–Bragg model are σ, the statistical weight for nucleating a helix and s, the statistical weight for propagating a helix. These parameters may depend on the residue j; for example, a proline residue may easily nucleate a helix but not propagate one; a leucine residue may nucleate and propagate a helix easily; whereas glycine may disfavor both the nucleation and propagation of a helix. Since only nearest-neighbour interactions are considered in the Zimm–Bragg model, the full partition function for a chain of N residues can be written as follows

${\displaystyle {\mathcal {Z}}=\left(0,1\right)\cdot \left\{\prod _{j=1}^{N}\mathbf {W} _{j}\right\}\cdot \left(1,1\right)}$ 

where the 2x2 transfer matrix W_j of the jth residue equals the matrix of statistical weights for the state transitions

${\displaystyle \mathbf {W} _{j}={\begin{bmatrix}s_{j}&1\\\sigma _{j}s_{j}&1\end{bmatrix}}}$ 

The row-column entry in the transfer matrix equals the statistical weight for making a transition from state row in residue j − 1 to state column in residue j. The two states here are helix (the first) and coil (the second). Thus, the upper left entry s is the statistical weight for transitioning from helix to helix, whereas the lower left entry σs is that for transitioning from coil to helix.

See also

• Alpha helix
• Lifson–Roig model
• Random coil
• Statistical mechanics

References

1. Samuel Kutter; Eugene M. Terentjev (16 October 2002). "Networks of helix-forming polymers". European Physical Journal E. 8 (5). EDP Sciences: 539–47. arXiv:cond-mat/0207162. Bibcode:2002EPJE....8..539K. doi:10.1140/epje/i2002-10044-x. PMID 15015126. S2CID 39981396.
2. Ken A. Dill; Sarina Bromberg (2002). Molecular Driving Forces – Statistical Thermodynamics in Chemistry and Biology. Garland Publishing, Inc. p. 505.
3. Zimm, BH; Bragg JK (1959). "Theory of the Phase Transition between Helix and Random Coil in Polypeptide Chains". Journal of Chemical Physics. 31 (2): 526–531. Bibcode:1959JChPh..31..526Z. doi:10.1063/1.1730390.