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Structure of a putative ancestral protein encoded by a single sequence repeat from a multidomain proteinase inhibitor gene fromNicotiana alata  Martin.

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Presentation on theme: "Structure of a putative ancestral protein encoded by a single sequence repeat from a multidomain proteinase inhibitor gene fromNicotiana alata  Martin."— Presentation transcript:

1 Structure of a putative ancestral protein encoded by a single sequence repeat from a multidomain proteinase inhibitor gene fromNicotiana alata  Martin J Scanlon, Marcus CS Lee, Marilyn A Anderson, David J Craik  Structure  Volume 7, Issue 7, Pages (July 1999) DOI: /S (99)

2 Figure 1 Diagrammatic representation of the domain organisation of NaProPI (the N-terminal signal sequence and the putative C-terminal vacuolar targeting signal have been omitted for clarity). The precursor protein, shown as a linear gene product in the upper part of the diagram, forms a circular ‘bracelet’ structure that is ‘clasped’ by three disulphide bonds (yellow) between the N- and C-terminal repeats. Each repeat (labelled A–F) contains a protease-reactive site (red), which is specific for either chymotrypsin (C1 and C2) or trypsin (T1–4). Cleavage in each of the six linker regions (green) releases six active domains which are the native inhibitors shown on the right of the diagram. aPI1 is the gene product of a single repeat from NaProPI; aPI1 contains portions of the sequence from C1 and C2 which are joined by the five-residue linker sequence EEKKN. Structure 1999 7, DOI: ( /S (99) )

3 Figure 2 NMR data used in structure determination.(a) Summary of the NMR data used for sequence-specific assignment and identification of secondary structure in aPI1. Shaded bars indicate sequential connectivities observed in a 200 ms mixing time NOESY spectrum at 313K and pH 5.8; the height of the bars indicates their strength. Slowly exchanging amide protons are indicated: open circles, amide protons still present 2 h after dissolution in2H2O; half-filled circles, amide protons still present 4 h after dissolution in2H2O; filled circles, amide protons still present 8 h after dissolution in2H2O.3JHNHα coupling constants are indicated: filled squares,3JHNHα > 8; open squares,3JHNHα < 5; half-filled squares, 8 Hz >3JHNHα > 6 Hz. (The figure was produced using the program Vince.)(b) Distribution of intraresidue (white), sequential (light grey), medium (dark grey) and long-range (black) distance constraints as a function of residue number. Structure 1999 7, DOI: ( /S (99) )

4 Figure 3 The solution structure of aPI1.(a) Stereoview of the backbone heavy atoms (N, C, Cα) of the final 20 structures of aPI1 superimposed over theβ-sheet residues. Residues Met1–Ser20 are shown in red, the ‘linker’ residues Glu21–Asn25 are in green and Asp25–Ser54 are in blue. The four disulphide bonds are shown in yellow.(b) Stereoview of the final structures in the same orientation as (a) showing all heavy atoms (coloured magenta) of the well-defined sidechains (Sχ1 > 0.8) in the well-defined (Sφ,ϕ > 0.9) regions of aPI1. The colour scheme is the same as in (a) and for reasons of clarity, residues 1–7 and 19–27 have been omitted from the figure. Structure 1999 7, DOI: ( /S (99) )

5 Figure 4 Schematic diagram of the secondary structural elements of aPI1 showing the NOEs betweenβ strands (double-headed arrows) and the position of proposed hydrogen bonds (broken lines). Structure 1999 7, DOI: ( /S (99) )

6 Figure 5 Secondary shifts for the Hα protons of aPI1 (white bars) and the contiguous native inhibitor C1 (black bars). The positions of the cysteine residues and the disulfide connectivity are illustrated above. Numbers in italics indicate the residue numbering in C1. Structure 1999 7, DOI: ( /S (99) )

7 Figure 6 A comparison of the structures of the contiguous native inhibitor T1, the two-chain inhibitor C2 and aPI1.(a) The molecules are shown as Cα ribbons of the mean structure from each NMR ensemble superimposed over the backbone heavy atoms (N, C, Cα) of theirβ-hairpin regions. The residues are colour-coded: residues Lys35–Ser53 of T1, Lys1A–Ser19A of C2 and Met1–Ser20 of aPI1 are coloured red; Asp1–Ser29 of T1, Arg1B–Ser28B of C2 and Asp26–Ser54 of aPI1 are coloured blue; residues Asp30–Pro34 of T1 and the linker region Glu21–Asn25 of aPI1 are coloured green; and the protease-reactive sites of the inhibitors are shown in purple.(b) A rotation by 90° of the ribbons shown in (a). Structure 1999 7, DOI: ( /S (99) )

8 Figure 7 Cα ribbon diagrams of(a) aPI1 and(b) T1. The ribbons were generated in InsightII using the mean coordinates for the NMR-derived family of structures of aPI1 and T1 (PDB code 1tih). The width of the ribbon is determined by the atomic root mean square (rms) deviation from the mean of the Cα atom position across the family of structures. Residues where the Cα rms < 1 are coloured blue and those where the rms > 1 are coloured green. The termini of both molecules are labelled. Structure 1999 7, DOI: ( /S (99) )

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