DNA Structure / Chapter 1: |
Chemical composition and primary structure / 1.1: |
Spatial geometry and secondary structure / 1.2: |
Forces stabilizing secondary structure / 1.3: |
Polymorphism / 1.4: |
Tertiary structure / 1.5: |
Approximate models of DNA structure / 1.6: |
Experimental methods of studying DNA structure / 1.7: |
DNA Dynamics / Chapter 2: |
General picture of the internal mobility / 2.1: |
Twisting and bending motions / 2.2: |
Dynamics of bases / 2.3: |
Dynamics of sugar-phosphate backbone / 2.4: |
Conformational transitions / 2.5: |
Motions associated with local strand separation / 2.6: |
Approximate models of DNA dynamics / 2.7: |
Experimental methods of studying DNA dynamics / 2.8: |
DNA Functioning / Chapter 3: |
Physical aspects of DNA functioning / 3.1: |
Intercalation / 3.2: |
DNA-protein recognition / 3.3: |
Gene expression / 3.4: |
Regulation of gene expression / 3.5: |
Replication / 3.6: |
Linear Theory of DNA / Chapter 4: |
The main mathematical models / 4.1: |
Statistics of linear excitations / 4.2: |
Scattering problem / 4.3: |
Linear theory and experiment / 4.4: |
Nonlinear Theory of DNA: Ideal Dynamical Models / Chapter 5: |
Nonlinear mathematical modeling: general principles and restrictions / 5.1: |
Nonlinear rod-like models / 5.2: |
Nonlinear double rod-like models / 5.3: |
Nonlinear models of higher levels / 5.4: |
Nonlinear Theory of DNA: Non-Ideal Models / Chapter 6: |
Effects of environment / 6.1: |
Effects of inhomogeneity / 6.2: |
DNA Structure / Chapter 1: |
Chemical composition and primary structure / 1.1: |
Spatial geometry and secondary structure / 1.2: |
Forces stabilizing secondary structure / 1.3: |
Polymorphism / 1.4: |
Tertiary structure / 1.5: |