Crystal Structure of Canine and Bovine Granulocyte-Colony Stimulating Factor (G-CSF)

Abstract

The crystal structures of recombinant canine and bovine granulocyte colony stimulating factor (G-CSF) have been determined by X-ray crystallography, using molecular replacement with recombinant human G-CSF as a model. G-CSF is a member of the cytokine family of glycoproteins that stimulate the differentiation and proliferation of blood cells. Human, bovine and canine G-CSF all have a molecular mass of about 19 kDa and share an amino acid sequence identity of about 80%. Two crystal forms of canine G-CSF have been solved. Form I recombinant canine G-CSF (rcG-CSFI; space group C2) contains one molecule in the asymmetric unit while form II canine G-CSF (rcG-CSFII; space group P21) has two molecules in the asymmetric unit and bovine G-CSF (rbG-CSF; space group P 212121) contains one molecule in the asymmetric unit. rcG-CSFI has been refined to an R factor of 20·7% with data to 2·3 Å resolution and rcG-CSFII has been refined to an R factor of 19·3% with data to 2·2 Å resolution. rbG-CSF has been refined to an R factor of 21·3% with data to 1·7 Å resolution. The structure of human, canine and bovine G-CSF is an antiparallel 4-α-helical bundle with up-up-down-down connectivity. With the exception of one highly exposed loop (residues 66 to 74), the human, canine and bovine structures are very similar to each other. Using our series of G-CSF crystal structures we developed a function that describes the probability that a particular residue position (i) contributes to a G-CSF receptor binding site based on two principles, (1) high sequence conservation in the primary sequence of human, bovine, canine and murine G-CSF and (2) conservation of high solvent accessibility in the human, bovine and canine crystal structures. On the basis of this probability function as well as a comparison of G-CSF to the crystal structure of human growth hormone (hGH) complexed with the extracellular domain of the human growth hormone receptor (hGHbp), residues that contribute to potential G-CSF receptor binding sites are identified.