| Entry ID |
Original Release date |
Data summary |
Entry Title |
Citation Title |
Authors |
| 30886 |
2021-03-19 |
Chemical Shifts: 1 set
|
Solution NMR Structure of PawL-Derived Peptide PLP-42 |
Structural Characterization of the PawL-Derived Peptide Family, an Ancient Subfamily of Orbitides
|
C D Payne, J S Mylne, K J Rosengren, M F Fisher |
| 30881 |
2021-03-19 |
Chemical Shifts: 1 set
|
Solution NMR Structure of PawL-Derived Peptide PLP-13 |
Structural Characterization of the PawL-Derived Peptide Family, an Ancient Subfamily of Orbitides
|
C D Payne, J S Mylne, K J Rosengren, M F Fisher |
| 30882 |
2021-03-19 |
Chemical Shifts: 1 set
|
Solution NMR Structure of PawL-Derived Peptide PLP-16 |
Structural Characterization of the PawL-Derived Peptide Family, an Ancient Subfamily of Orbitides
|
C D Payne, J S Mylne, K J Rosengren, M F Fisher |
| 30883 |
2021-03-19 |
Chemical Shifts: 1 set
|
Solution NMR Structure of PawL-Derived Peptide PLP-22 |
Structural Characterization of the PawL-Derived Peptide Family, an Ancient Subfamily of Orbitides
|
C D Payne, J S Mylne, K J Rosengren, M F Fisher |
| 30884 |
2021-03-19 |
Chemical Shifts: 1 set
|
Solution NMR Structure of PawL-Derived Peptide PLP-29 |
Structural Characterization of the PawL-Derived Peptide Family, an Ancient Subfamily of Orbitides
|
C D Payne, J S Mylne, K J Rosengren, M F Fisher |
| 30885 |
2021-03-19 |
Chemical Shifts: 1 set
|
Solution NMR Structure of PawL-Derived Peptide PLP-38 |
Structural Characterization of the PawL-Derived Peptide Family, an Ancient Subfamily of Orbitides
|
C D Payne, J S Mylne, K J Rosengren, M F Fisher |
| 30887 |
2021-03-19 |
Chemical Shifts: 1 set
|
Solution NMR Structure of PawL-Derived Peptide PLP-46 |
Structural Characterization of the PawL-Derived Peptide Family, an Ancient Subfamily of Orbitides
|
C D Payne, J S Mylne, K J Rosengren, M F Fisher |
| 30827 |
2021-01-25 |
Chemical Shifts: 1 set
|
Solution NMR structure of the dimeric form of the cyclic plant protein PDP-23 in H2O |
A chameleonic macrocyclic peptide with drug delivery applications
|
A S Jayasena, A Song, B Franke, C D Payne, C Eliasson, C E McAleese, F Hajiaghaalipour, G Vadlamani, J S Mylne, J Zhang, K J Rosengren, M F Fisher, R F Minchin, R J Clark |
| 30828 |
2021-01-25 |
Chemical Shifts: 1 set
|
Solution NMR structure of the monomeric form of the cyclic plant protein PDP-23 in CD3CN/H2O |
A chameleonic macrocyclic peptide with drug delivery applications
|
A S Jayasena, A Song, B F Franke, C D Payne, C Eliasson, C E McAleese, F Hajiaghaalipour, G Vadlamani, J S Mylne, J Zhang, K J Rosengren, M F Fisher, R F Minchin, R J Clark |
| 30829 |
2021-01-25 |
Chemical Shifts: 1 set
|
Solution NMR structure of the cyclic plant protein PDP-23 in SDS micelles |
A chameleonic macrocyclic peptide with drug delivery applications
|
A S Jayasena, A Song, B Franke, C D Payne, C Eliasson, C E McAleese, F Hajiaghaalipour, G Vadlamani, J S Mylne, J Zhang, K J Rosengren, M F Fisher, R F Minchin, R J Clark |
| 30830 |
2021-01-25 |
Chemical Shifts: 1 set
|
Solution NMR structure of the cyclic plant protein PDP-23 in DPC micelles |
A chameleonic macrocyclic peptide with drug delivery applications
|
A S Jayasena, A Song, B Franke, C D Payne, C Eliasson, C E McAleese, F Hajiaghaalipour, G Vadlamani, J S Mylne, J Zhang, K J Rosengren, M F Fisher, R F Minchin, R J Clark |
| 30579 |
2019-04-18 |
Chemical Shifts: 1 set
|
NMR solution structure of vicilin-buried peptide-8 (VBP-8) |
An ancient peptide family buried within vicilin precursors.
|
B Pouvreau, C D Payne, H Schaefer, J S Mylne, J Whelan, J Zhang, K J Rosengren, M F Fisher, N L Taylor, O Berkowitz |
| 30580 |
2019-04-18 |
Chemical Shifts: 1 set
|
NMR solution structure of vicilin-buried peptide-8 (VBP-8) |
An ancient peptide family buried within vicilin precursors.
|
B Pouvreau, C D Payne, H Schaefer, J S Mylne, J Whelan, J Zhang, K J Rosengren, M F Fisher, N L Taylor, O Berkowitz |
| 34122 |
2017-12-11 |
Chemical Shifts: 1 set
|
Solution NMR Structure of the C-terminal domain of ParB (Spo0J) |
The structural basis for dynamic DNA binding and bridging interactions which condense the bacterial centromere.
|
A Butterer, A Koh, C L Pastrana, F Moreno-Herrero, F Sobott, G LM Fisher, H Murray, J A Taylor, M P Crump, M S Dillingham, T D Craggs, V A Higman |
