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Polymers and Self Assembly: From Biology to Nanomaterials Poster Session II

39-POS

Board 39

k-Casein from Bovine Milk: From Natural to Pathological Assemblies

Silvia Vilasi

1

, Giacoma C. Rappa

1

, Rita Carrotta

1

, Claudio Canale

2

,

Pier L. San Biagio

1

,

Donatella Bulone

1

.

1

National Research Council, Palermo, Italy,

2

Italian Institute of Technology, Genova, Italy.

Casein is the best-characterised milk protein and, in bovine milk, it constitutes over 70–80% of

total protein content. In milk, casein exists as large micelle-like complex that comprise four

unrelated proteins (αs1-, αs2-, β- and κ-casein) and calcium phosphate. Crucial for the integrity

of the protein complex is the k-casein which is responsible for the steric stability of the casein

micelles through coating of the structure. All the caseins, αs1-, αs2, β- and κ adopt so extremely

open and flexible conformations to be considered full members of the class of intrinsically

disordered proteins (IDPs). However, k casein presents special structural features that may

reflect in different self-association pathways, each one related to a specific function and

biological role. In particular, the presence of the two Cys residues, Cys11 and Cys88, creates a

complex disulphide bonding pattern between κ-casein molecules causing heterogeneous

polymerization. In native environment, the heterogeneous polymers (from monomers to

octamers) further associate through several kinds of interactions in multimeric colloidal systems.

On the other hand, it has been demonstrated that κ-casein is able to form amyloid fibrils both in

vitro and in vivo, and this is probably the principal cause of corpora amylacea (CA) occurring in

calcified stones in mammalian glands.

Here, by using several biophysical methods and bioinformatic tools, we investigated how the

varying of environmental conditions can determine the different k-casein fate: from natural

assembly to pathological amyloid fibrils. Moreover, we demonstrated that the two different self-

association regimes are reached in conditions in which specific interactions, hydrogen bond or

hydrophobic, became predominant on the others.