Human alpha 1-proteinase inhibitor. Crystal structure analysis of two crystal modifications, molecular model and preliminary analysis of the implications for function.

Two closely related crystal structures of alpha 1-proteinase inhibitor modified at the reactive site peptide bond Met358--Ser359 have been analysed. The crystal structure has been obtained from diffraction data at 3 A resolution, with phases originally from isomorphous replacement. The electron density map was substantially improved by cyclic averaging of the electron densities of the two crystal forms and allowed the chain to be traced in terms of the known chemical amino acid sequence. Energy restrained crystallographic refinement was initiated and resulted in conventional R-values of 0.251 for the tetragonal crystal form (6 to 3 A resolution) and 0.247 for the hexagonal crystal form (6 to 3.2 A resolution). The polypeptide chain is almost completely arranged in well-defined secondary structural elements: three beta-sheets and eight alpha-helices. The helices are preferentially formed by the first 150 residues. They are in proximity underneath sheet A. The chain ends Met358 and Ser359 of the nicked species are arranged in strands on opposite ends of the molecule indicating a major structural rearrangement upon modification of the intact inhibitor. It is suggested that the Met358 strand is in a different conformation removed from sheet A and approaches Ser359 in the intact inhibitor species. Glu342, which is exchanged by a lysine in the Z-variant is in a strategic position for such a rearrangement. The three carbohydrate chains of alpha 1-proteinase inhibitor have partly defined electron density close to their attachment sites at asparagine residues. The anti-thrombin and ovalbumin amino acid sequences can be accommodated in the alpha 1 inhibitor molecular structure. The intron-exon junctions of the ovalbumin and the alpha 1-proteinase inhibitor gene are all in surface loops of the mature protein.