Table of contents
September 2007, Volume 14 No 9 pp787-877
About the coverEditorial
Losing half our scientific capacity - p787
doi:10.1038/nsmb0907-787
Full Text - Losing half our scientific capacity | PDF (217 KB) - Losing half our scientific capacity
News and Views
RNA polymerase II transcription in living color - pp788 - 790
Angus I Lamond & Jason R Swedlow
doi:10.1038/nsmb0907-788
Full Text - RNA polymerase II transcription in living color | PDF (186 KB) - RNA polymerase II transcription in living color
See also: Article by Darzacq et al.
When it comes to couple(r)s, do opposites attract? - pp790 - 792
Sharsti Sandall & Arshad Desai
doi:10.1038/nsmb0907-790
Full Text - When it comes to couple(r)s, do opposites attract? | PDF (693 KB) - When it comes to couple(r)s, do opposites attract?
Chloride finds its place in the transport cycle - pp792 - 794
Susan G Amara
doi:10.1038/nsmb0907-792
Full Text - Chloride finds its place in the transport cycle | PDF (324 KB) - Chloride finds its place in the transport cycle
X chromosome exposé - p794
Sabbi Lall
doi:10.1038/nsmb0907-794
Full Text - X chromosome exposé | PDF (117 KB) - X chromosome exposé
Research highlights - p795
doi:10.1038/nsmb0907-795
Full Text - Research highlights | PDF (125 KB) - Research highlights
Articles
In vivo dynamics of RNA polymerase II transcription - pp796 - 806
Xavier Darzacq, Yaron Shav-Tal, Valeria de Turris, Yehuda Brody, Shailesh M Shenoy, Robert D Phair & Robert H Singer
doi:10.1038/nsmb1280
Abstract - | Full Text - In vivo dynamics of RNA polymerase II transcription | PDF (1,406 KB) - In vivo dynamics of RNA polymerase II transcription | Supplementary information
See also: News and Views by Lamond & Swedlow
Molecular basis of messenger RNA recognition by the specific bacterial repressing clamp RsmA/CsrA - pp807 - 813
Mario Schubert, Karine Lapouge, Olivier Duss, Florian C Oberstrass, Ilian Jelesarov, Dieter Haas & Frédéric H-T Allain
doi:10.1038/nsmb1285
PDB code
3D view
Abstract - | Full Text - Molecular basis of messenger RNA recognition by the specific bacterial repressing clamp RsmA/CsrA | PDF (793 KB) - Molecular basis of messenger RNA recognition by the specific bacterial repressing clamp RsmA/CsrA | Supplementary information
Release of autoinhibition of ASEF by APC leads to CDC42 activation and tumor suppression - pp814 - 823
Natalia Mitin, Laurie Betts, Marielle E Yohe, Channing J Der, John Sondek & Kent L Rossman
doi:10.1038/nsmb1290
PDB code
3D view
Abstract - | Full Text - Release of autoinhibition of ASEF by APC leads to CDC42 activation and tumor suppression | PDF (1,251 KB) - Release of autoinhibition of ASEF by APC leads to CDC42 activation and tumor suppression | Supplementary information
Lsm proteins bind and stabilize RNAs containing 5' poly(A) tracts - pp824 - 831
Naomi Bergman, Karen C M Moraes, John R Anderson, Bozidarka Zaric, Christian Kambach, Robert J Schneider, Carol J Wilusz & Jeffrey Wilusz
doi:10.1038/nsmb1287
Abstract - | Full Text - Lsm proteins bind and stabilize RNAs containing 5' poly(A) tracts | PDF (505 KB) - Lsm proteins bind and stabilize RNAs containing 5' poly(A) tracts
MRE11–RAD50–NBS1 and ATM function as co-mediators of TRF1 in telomere length control - pp832 - 840
Yili Wu, Shujie Xiao & Xu-Dong Zhu
doi:10.1038/nsmb1286
Abstract - | Full Text - MRE11–RAD50–NBS1 and ATM function as co-mediators of TRF1 in telomere length control | PDF (543 KB) - MRE11–RAD50–NBS1 and ATM function as co-mediators of TRF1 in telomere length control | Supplementary information
F1-ATPase rotates by an asymmetric, sequential mechanism using all three catalytic subunits - pp841 - 846
Takayuki Ariga, Eiro Muneyuki & Masasuke Yoshida
doi:10.1038/nsmb1296
Abstract - | Full Text - F1-ATPase rotates by an asymmetric, sequential mechanism using all three catalytic subunits | PDF (478 KB) - F1-ATPase rotates by an asymmetric, sequential mechanism using all three catalytic subunits | Supplementary information
Crystal structure of human DGCR8 core - pp847 - 853
Sun Young Sohn, Won Jin Bae, Jeong Joo Kim, Kyu-Hyeon Yeom, V Narry Kim & Yunje Cho
doi:10.1038/nsmb1294
PDB code
3D view
Abstract - | Full Text - Crystal structure of human DGCR8 core | PDF (694 KB) - Crystal structure of human DGCR8 core | Supplementary information
Structural dynamics in the gating ring of cyclic nucleotide–gated ion channels - pp854 - 860
Justin W Taraska & William N Zagotta
doi:10.1038/nsmb1281
Abstract - | Full Text - Structural dynamics in the gating ring of cyclic nucleotide–gated ion channels | PDF (755 KB) - Structural dynamics in the gating ring of cyclic nucleotide–gated ion channels | Supplementary information
The refined structure of nascent HDL reveals a key functional domain for particle maturation and dysfunction - pp861 - 868
Zhiping Wu, Matthew A Wagner, Lemin Zheng, John S Parks, Jacinto M Shy, III, Jonathan D Smith, Valentin Gogonea & Stanley L Hazen
doi:10.1038/nsmb1284
Abstract - | Full Text - The refined structure of nascent HDL reveals a key functional domain for particle maturation and dysfunction | PDF (962 KB) - The refined structure of nascent HDL reveals a key functional domain for particle maturation and dysfunction | Supplementary information
Brief Communications
The Arabidopsis LHP1 protein colocalizes with histone H3 Lys27 trimethylation - pp869 - 871
Xiaoyu Zhang, Sophie Germann, Bartlomiej J Blus, Sepideh Khorasanizadeh, Valerie Gaudin & Steven E Jacobsen
doi:10.1038/nsmb1283
Abstract - | Full Text - The Arabidopsis LHP1 protein colocalizes with histone H3 Lys27 trimethylation | PDF (584 KB) - The Arabidopsis LHP1 protein colocalizes with histone H3 Lys27 trimethylation | Supplementary information
YY1 functions with INO80 to activate transcription - pp872 - 874
Yong Cai, Jingji Jin, Tingting Yao, Aaron J Gottschalk, Selene K Swanson, Su Wu, Yang Shi, Michael P Washburn, Laurence Florens, Ronald C Conaway & Joan W Conaway
doi:10.1038/nsmb1276
Abstract - | Full Text - YY1 functions with INO80 to activate transcription | PDF (238 KB) - YY1 functions with INO80 to activate transcription | Supplementary information
An iron-sulfur domain of the eukaryotic primase is essential for RNA primer synthesis - pp875 - 877
Sebastian Klinge, Judy Hirst, Joseph D Maman, Torsten Krude & Luca Pellegrini
doi:10.1038/nsmb1288
Abstract - | Full Text - An iron-sulfur domain of the eukaryotic primase is essential for RNA primer synthesis | PDF (988 KB) - An iron-sulfur domain of the eukaryotic primase is essential for RNA primer synthesis | Supplementary information