Analogy and solution scattering modelling: new structural strategies for the multidomain proteins of complement, cartilage and the immunoglobulin superfamily.

Many immunologically relevant proteins possess multidomain structures. Molecular structures both at the level of the individual domain and that of the intact protein are required for a full appreciation of function and control. Two recently developed structural approaches are reviewed here. Analogy modelling methods are based on the current understanding of many protein structures, and make possible the identification of folds for superfamilies of unknown structures. An integrated multidisciplinary predictive approach has been successfully applied to the von Willebrand factor type A, proteoglycan tandem repeat and factor I/membrane attack complex domains. The available experimental and predictive evidence is assembled in order to identify a known three-dimensional structure related to the unknown one of interest. Neutron and X-ray scattering curve modelling provides information on the full multidomain structure in solution. As scattering curves can be calculated from known atomic structures, the present availability of structures for many domains in conjunction with tight constraints based on these structures and the covalent connections between them results in a small family of allowed best-fit structures for a given scattering curve. The curve-fit procedure can be automated, and whole multidomain structures can be determined to a positional precision of the order of 0.2-1 nm. Such models are informative on the steric accessibility of each domain and their functional activity, and this is illustrated for antibody, cell-surface and complement proteins.

Conserved basic residues in the C-type lectin and short complement repeat domains of the G3 region of proteoglycans.

Aggrecan is the major proteoglycan of the extracellular matrix in cartilage. It contains two N-terminal globular regions, G1 and G2, and one C-terminal globular region, G3. G3 is implicated in the intracellular processing of aggrecan and contains a C-type lectin carbohydrate recognition domain (CRD), frequent occurrences of a C-terminal short complement repeat (SCR) domain, and occasionally an N-terminal epidermal growth factor domain. The CRD and SCR domains in 13 G3 sequences were each subjected to structural analysis. Alignment of 131 sequences from all seven groups in the CRD superfamily defined a consensus length of 136 residues, in which 32% of residues were conserved. Although the G3 CRD sequences agreed with this consensus, they also contained five fully conserved basic residues that are atypical of the CRD superfamily. Homology modelling showed that four of these residues are located on a surface region on the CRD that is separate from the Ca2+-binding residues involved in carbohydrate interactions. One conserved basic residue is identical in position with that of a conserved basic residue that mediates hyaluronate binding in the structurally related proteoglycan tandem repeat (PTR) domain in G1 and in link protein. The alignment of 13 G3 SCR sequences with 101 sequences in the SCR superfamily showed good agreement with conserved residues in the SCR superfamily. There are also five conserved basic residues in the G3 SCR that are atypical of the SCR superfamily, and homology modelling showed that all five were located on one surface of the SCR. It is concluded that both the CRD and SCR domains in G3 possess basic residues that are atypical of their superfamilies and might be related to function, and that the G3 CRD domain shows an evolutionary relationship to the PTR domain in G1.

The protein fold of the hyaluronate-binding proteoglycan tandem repeat domain of link protein, aggrecan and CD44 is similar to that of the C-type lectin superfamily.

Link protein and aggrecan of the extracellular matrix each contain two proteoglycan tandem repeat (PTR) domains that interact with hyaluronate. Consensus secondary structure predictions for 59 PTR sequences and 129 C-type lectin sequences give similar patterns of two alpha-helices and up to seven beta-strands. Protein fold recognition analyses show that the 59 PTR sequences are highly compatible with the C-type lectin crystal structure. The predicted fold consists of a conserved motif formed from an antiparallel beta-sheet flanked by two alpha-helices, the motif being attached to two distinct types of beta-sheet region in the two superfamilies. Arg9 or Lys11 on an exposed loop and up to three other Arg residues in the beta-sheet region are conserved and may form part of a hyaluronate binding site.