Keratin intermediate filament structure. Crosslinking studies yield quantitative information on molecular dimensions and mechanism of assembly.

One of the major obstacles to solving the full three-dimensional structure of keratin intermediate filaments (KIF) is the determination of the exact mode(s) of alignment of nearest-neighbor molecules; this in turn requires precise information of the lengths of the non-alpha-helical linker segments within the coiled-coil alpha-helical heterodimer molecule. In this study, we have induced lysine-lysine and cysteine-cysteine crosslinks between keratin intermediate filament molecules in small assembly-competent oligomers, isolated them and then characterized the natures and locations of the crosslinks. Of more than 100 found, 21 quantitatively major crosslinks were used to obtain the relative axial alignments of rod domain segments by least-squares fitting methods. Three dominant modes of alignment were found. In each case the molecules are antiparallel with the first involving molecules in approximate register (stagger = -0.2 nm), the second involving molecules staggered so as to bring the 1B segments into approximate alignment (stagger = -16.1 nm), and the third involving molecules staggered so as to bring the 2B segments into approximate alignment (stagger = 28.2 nm). In addition, the data enable quantitative estimates to be made for the first time of the lengths of the non-coiled-coil segments (L1 = 2.5 nm, L12 = 1.6 nm, L2 = 0.8 nm), and the total length of the rod domain (46.0 nm). Alignment of molecules according to these parameters permits construction of a two-dimensional surface lattice which displays a 1.6 nm (10 or 11 residue) overlap between similarly directed molecules. Together, the data predict six important overlapping sequence regions that recur about 16 times per 46 nm of filament length. Interestingly, synthetic peptides corresponding to these sequences, singly or in combination, significantly interfere with keratin filament structural integrity. These results thus represent the most significant set of structural constraints for KIF yet available and provide insights into how disease-causing mutations disrupt filaments and their organization in cells.