Gluten is a protein network that emerges when gliadins and glutenins are hydrated and subjected to mechanical energy (mixing/kneading) or thermal energy (heating). Its “strength” (tenacity/elasticity and ability to withstand stress) depends on two families of interactions:
1 – Covalent disulfide bonds (S–S).
These are the most “structural” cross-links. In glutenins (especially HMW-GS and LMW-GS), intermolecular disulfide bonds build polymers (often referred to as GMP / glutenin macropolymer) that provide the elastic backbone of the network.
2 – Non-covalent interactions (hydrophobic, hydrogen bonds, ionic interactions).
They are weaker but extremely numerous and “modulate” the network: they contribute to cohesion, viscosity, reorganization, and the response to hydration/temperature/solvents. Many studies show that changes in secondary structure and non-covalent interactions accompany (and sometimes amplify) the effects of disulfide bonds.
A key point:
the network is not static. During processing, thiol–disulfide exchange reactions (–SH/–S–S–) occur that remodel network connectivity: more opportunities to form/reorganize S–S bonds → generally a “stronger” and/or more resilient network.
Practical implications for dough
From an operational standpoint, gluten strength does not depend only on the genetic potential of the flour, but also on how the system is “set up” to express and organize its intermolecular bonds.
Adequate hydration:
Water acts as a plasticizer and allows proteins to move, interact, and realign. Hydration levels that are too low limit network formation; higher hydration promotes molecular mobility and bond reorganization, making gluten more extensible.
Mixing energy:
Mechanical action facilitates contact between protein chains and accelerates thiol–disulfide exchange reactions. Insufficient mixing leads to an incomplete network; excessive energy, on the other hand, can cause bond breakage and excessive reorganization, with a loss of structure.
Resting time:
Rest phases (autolyse, bulk fermentation) allow non-covalent interactions and disulfide bonds to redistribute toward more stable configurations, improving the balance between elasticity and extensibility.
Chemical conditions:
pH, salts, and the presence of oxidizing or reducing agents directly influence the equilibrium between –SH groups and –S–S– bridges, thereby modulating cross-link density within the network.