Abstract
In this work, we examine the structure and function of two important human proteins. The first is human kallikrein 6 (hK6), which is a newly identified enzyme in the serine proteinase family that is expressed in the central nervous system. In chapter 2, the X-ray crystal structure of mature, active recombinant human kallikrein 6 at 1.75 Å is presented. This high resolution model provides the first three-dimensional view of one of the human kallikreins and one of only a few structures of serine proteinases predominantly expressed in the central nervous system. Enzymatic and X-ray data provide support for the characterization of human kallikrein 6 as a degradative proteinase with structural features more similar to trypsin than the regulatory kallikreins. In chapter 3, we have re-solved the structure of hK6 to a resolution of 1.56 Å. In addition, a detailed analysis of the preferred substrate specificity of hK6 at the positions P3, P2, P1′, P2′, and P3′ is undertaken using internally quenched fluorescent substrates based on a peptide background sequence of the identified autolysis region. Furthermore, the identified optimized substrate sequence is modeled into the 1.56 Å structure of human kallikrein 6 using docking in order to identify structural aspects of the protein responsible for this preference. The substrate specificity data show that human kallikrein 6 displays little discrimination for particular amino acids at the tested positions with the exception of P2′, where there is a pronounced preference for proline. The second protein studied in this work is human fibroblast growth factor-1 which is a member of the β-trefoil superfold. In chapter 4, a 1.10 Å atomic-resolution x-ray structure of human fibroblast growth factor 1, a member of the β-trefoil superfold, is reported. The FGF-1 structure exhibits numerous core packing defects detectable using a 1.0Å radius probe. In addition to contributing to the relatively low thermal stability of FGF-1, these defects may also permit domain motions within the structure. The availability of refined ADP's permits a translation/libration/ screw (TLS) analysis of putative rigid body domains. The observed rigid body motion in FGF-1 appears related to the ligand-binding functionalities.
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