Abstract

Lactoferrin is a prominent iron-binding protein from human milk, other secretions, and leukocytes and possesses a wide variety of established or proposed biological activities. It is also, with the closely-related serum protein transferrin, part of the team of proteins that regulates the levels of iron, and possibly other metals, in the body fluids of animals. The broad aims of this research are (i) to determine the molecular basis for the biological activities of human lactoferrin, (ii) to address the wider questions of iron homeostasis by extending these structure-function studies to serum transferrin, and (iii) to investigate the structural basis of specificity in these proteins. It will have implications for understanding the control of levels of iron and other trace elements in body fluids, with relevance to diseases of iron overload or deficiency; bodily defense mechanism, especially antibacterial and antioxidant activity; aspects of the biology of human milk and infant health, and the bioavailability of trace elements. The research will use the complementary techniques of x-ray crystallography and site-directed mutagenesis to define the factors that determine metal and anion binding affinity and mechanisms of binding and release, and to probe the versatility of binding and transport by transferrins. It is a logical extension of our previous crystallographic studies of lactoferrin and newly-developed structural work on transferrin; structural knowledge will be used to select targets for mutagenesis and the mutant proteins will be expressed and characterized by x-ray crystallography and solution studies.
Specific aims are: 1. To use mutagenesis and crystallography to analyze the importance of basic residues behind the iron site in influencing iron release. 2. To analyze the roles of the iron ligands and anion binding groups in determining metal an anion affinity and specificity. 3. To determine the structural basis of cooperativity in transferrins by x-ray analysis of molecules with different conformational states and different iron status in the two lobes. 4. To probe the proposed role of lactoferrin as a transcription factor by crystallization and x-ray structural analysis of lactoferrin-DNA complexes. 5. To investigate the versatility of binding by transferrins, by crystallization of complexes with Ru(III) anti-tumor drugs that are reportedly carried by transferrins, and by x-ray analysis of a novel transferrin that binds a potent organic toxin in place of iron. 6. To complete a study of the effects of glycosylation on the structure and function of transferrin.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Type
Research Project (R01)
Project #
5R01HD020859-12
Application #
6181489
Study Section
Biophysical Chemistry Study Section (BBCB)
Program Officer
Grave, Gilman D
Project Start
1987-05-01
Project End
2002-04-30
Budget Start
2000-05-01
Budget End
2002-04-30
Support Year
12
Fiscal Year
2000
Total Cost
$93,848
Indirect Cost

  Institution

Name
University of Auckland
Department
Type
DUNS #
590330247
City
Auckland
State
Country
New Zealand
Zip Code
1010

  Publications

Baker, Heather M; Baker, Edward N (2004) Lactoferrin and iron: structural and dynamic aspects of binding and release. Biometals 17:209-16
Hendrixson, D R; Qiu, J; Shewry, S C et al. (2003) Human milk lactoferrin is a serine protease that cleaves Haemophilus surface proteins at arginine-rich sites. Mol Microbiol 47:607-17
Baker, Heather M; He, Qing-Yu; Briggs, Sara K et al. (2003) Structural and functional consequences of binding site mutations in transferrin: crystal structures of the Asp63Glu and Arg124Ala mutants of the N-lobe of human transferrin. Biochemistry 42:7084-9
Baker, Edward N; Baker, Heather M; Kidd, Richard D (2002) Lactoferrin and transferrin: functional variations on a common structural framework. Biochem Cell Biol 80:27-34
Jameson, Geoffrey B; Anderson, Bryan F; Breyer, Wendy A et al. (2002) Structure of a domain-opened mutant (R121D) of the human lactoferrin N-lobe refined from a merohedrally twinned crystal form. Acta Crystallogr D Biol Crystallogr 58:955-62
Peterson, Neil A; Arcus, Vickery L; Anderson, Bryan F et al. (2002) ""Dilysine trigger"" in transferrins probed by mutagenesis of lactoferrin: crystal structures of the R210G, R210E, and R210L mutants of human lactoferrin. Biochemistry 41:14167-75
Nurizzo, D; Baker, H M; He, Q Y et al. (2001) Crystal structures and iron release properties of mutants (K206A and K296A) that abolish the dilysine interaction in the N-lobe of human transferrin. Biochemistry 40:1616-23
Baker, H M; Mason, A B; He, Q Y et al. (2001) Ligand variation in the transferrin family: the crystal structure of the H249Q mutant of the human transferrin N-lobe as a model for iron binding in insect transferrins. Biochemistry 40:11670-5
MacGillivray, R T; Bewley, M C; Smith, C A et al. (2000) Mutation of the iron ligand His 249 to Glu in the N-lobe of human transferrin abolishes the dilysine ""trigger"" but does not significantly affect iron release. Biochemistry 39:1211-6
Peterson, N A; Anderson, B F; Jameson, G B et al. (2000) Crystal structure and iron-binding properties of the R210K mutant of the N-lobe of human lactoferrin: implications for iron release from transferrins. Biochemistry 39:6625-33

Showing the most recent 10 out of 39 publications