Peter Metcalf scite author profile

Cypoviruses and baculoviruses are notoriously difficult to eradicate because the virus particles are embedded in micrometre-sized protein crystals called polyhedra. The remarkable stability of polyhedra means that, like bacterial spores, these insect viruses remain infectious for years in soil. The environmental persistence of polyhedra is the cause of significant losses in silkworm cocoon harvests but has also been exploited against pests in biological alternatives to chemical insecticides. Although polyhedra have been extensively characterized since the early 1900s, their atomic organization remains elusive. Here we describe the 2 A crystal structure of both recombinant and infectious silkworm cypovirus polyhedra determined using crystals 5-12 micrometres in diameter purified from insect cells. These are the smallest crystals yet used for de novo X-ray protein structure determination. We found that polyhedra are made of trimers of the viral polyhedrin protein and contain nucleotides. Although the shape of these building blocks is reminiscent of some capsid trimers, polyhedrin has a new fold and has evolved to assemble in vivo into three-dimensional cubic crystals rather than icosahedral shells. The polyhedrin trimers are extensively cross-linked in polyhedra by non-covalent interactions and pack with an exquisite molecular complementarity similar to that of antigen-antibody complexes. The resulting ultrastable and sealed crystals shield the virus particles from environmental damage. The structure suggests that polyhedra can serve as the basis for the development of robust and versatile nanoparticles for biotechnological applications such as microarrays and biopesticides.

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The crystal structure of the Leishmania major surface proteinase leishmanolysin (gp63)

Schlagenhauf

1998

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The unexpected metzincin features of the leishmanolysin structure suggest that the metzincin fold may be more widespread than indicated by sequence homologies amongst existing metzincin zinc proteinases. The similarity of the active-site structure to previously well characterized metzincin class zinc proteinases should aid the development of specific inhibitors. These inhibitors might be used to determine the function of leishmanolysin in the insect and during mammalian infection, and may aid the development of drugs for human leishmaniasis.

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Two crystal structures for cathepsin D: the lysosomal targeting signal and active site.

1993

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Two crystal structures are described for the lysosomal aspartic protease cathepsin D (EC 3.4.23.5). The molecular replacement method was used with X‐ray diffraction data to 3 A resolution to produce structures for human spleen cathepsin D and for bovine liver cathepsin D complexed with the 6‐peptide inhibitor pepstatin A. The lysosomal targeting region of cathepsin D defined by previous expression studies [Barnaski et al. (1990) Cell, 63, 281–219] is located in well defined electron density on the surface of the molecules. This region includes the putative binding site of the cis‐Golgi phosphotransferase which is responsible for the initial sorting step for soluble proteins destined for lysosomes by phosphorylating the carbohydrates on these molecules. Carbohydrate density is visible at both expected positions on the cathepsin D molecules and, at the best defined position, four sugar residues extend towards the lysosomal targeting region. The active site of the protease and the active site cleft substrate binding subsites are described using the pepstatin inhibited structure. The model geometry for human cathepsin D has rms deviations from ideal of bonds and angles of 0.013 A and 3.2 degrees respectively. For bovine cathepsin D the corresponding figures are 0.014 A and 3.3 degrees. The crystallographic residuals (R factors) are 16.1% and 15.8% for the human and inhibited bovine cathepsin D models respectively. The free R factors, calculated with 10% of the data reserved for testing the models and not used for refinement, are 25.1% and 24.1% respectively.

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Structure-based targeting of bioactive proteins into cypovirus polyhedra and application to immobilized cytokines for mammalian cell culture

et al. 2009

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Multiple functions of pro‐parts of aspartic proteinase zymogens

et al. 1994

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The importance of aspartic proteinases in human pathophysiology continues to initiate extensive research. With burgeoning information on their biological functions and structures, the traditional view of the role of activation peptides of aspartic proteinases solely as inhibitors of the active site is changing. These peptide segments, or pro-parts, am deemed important for correct folding, targeting, and control of the activation of aspartic proteinase zymogens. Consequently, the primary structures of pro-parts reflect these functions. We discuss guidelines for formation of hypotheses derived from comparing the physiological function of aspartic proteinases and sequences of their pro-parts.

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Peter Metcalf

The molecular organization of cypovirus polyhedra

The crystal structure of the Leishmania major surface proteinase leishmanolysin (gp63)

Two crystal structures for cathepsin D: the lysosomal targeting signal and active site.

Structure-based targeting of bioactive proteins into cypovirus polyhedra and application to immobilized cytokines for mammalian cell culture

Multiple functions of pro‐parts of aspartic proteinase zymogens

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