1.
The post-PAM interaction of RNA-guided spCas9 with DNA dictates it..
[1878]
|
2.
Structural basis for reversible amyloids of hnRNPA1 elucidates the..
[1480]
|
3.
Different Intermolecular Interactions Drive Nonpathogenic Liquid-L..
[1215]
|
4.
In Vitro Biochemical Assays using Biotin Labels to Study Protein-N..
[1190]
|
5.
T7 replisome directly overcomes DNA damage
[1138]
|
6.
Helicase promotes replication re-initiation from an RNA transcript
[1106]
|
7.
RNase H1 facilitates recombinase recruitment by degrading DNA–RNA..
[972]
|
8.
The structure of a minimum amyloid fibril core formed by necroptos..
[952]
|
9.
Stochastically multimerized ParB orchestrates DNA assembly as unve..
[932]
|
10.
Crystal structures of N-terminally truncated telomerase reverse tr..
[764]
|
11.
The hereditary mutation G51D unlocks a distinct fibril strain tran..
[721]
|
12.
Real-time observation of nucleoplasmin-mediated DNA decondensation..
[630]
|
13.
Proximal single-stranded RNA destabilizes human telomerase RNA G-q..
[606]
|
14.
The nuclear localization sequence mediates hnRNPA1 amyloid fibril ..
[594]
|
15.
Discrete RNA–DNA hybrid cleavage by the EXD2 exonuclease pinpoint..
[568]
|
16.
Single-Molecule Optical-Trapping Techniques to Study Molecular Mec..
[563]
|
17.
Rescuing Replication from Barriers: Mechanistic Insights from Sing..
[550]
|
18.
The convergence of head-on DNA unwinding forks induces helicase ol..
[524]
|
19.
Phase-separated ParB enforces diverse DNA compaction modes and sta..
[506]
|
20.
MOV10L1 binds RNA G-Quadruplex in a structure-specific manner and ..
[499]
|
21.
PCDetection: PolyA-CRISPR/Cas12a-based miRNA detection without PAM..
[488]
|
22.
Single-Molecule Studies Reveal New Replication Reactivation Pathwa..
[481]
|
23.
Dynamics of Staphylococcus aureus Cas9 in DNA target association a..
[468]
|
24.
Enlarged DNA unwinding by Nme2Cas9 permits a broadened base editin..
[467]
|
25.
Single-molecule perspectives on helicase mechanisms and functions
[455]
|
26.
CRISPR-AsCas12f1 couples out-of-protospacer DNA unwinding with exo..
[443]
|
27.
Single-molecule assay guided crRNA optimization enhances specific ..
[435]
|
28.
Human RPA activates BLM's bidirectional DNA unwinding from a nick
[416]
|
29.
Efficient DNA interrogation of SpCas9 governed by its electrostati..
[415]
|
30.
Simultaneous mechanical and fluorescence detection of helicase-cat..
[414]
|
31.
Joint efforts of replicative helicase and SSB ensure inherent repl..
[399]
|
32.
Inhibitor Development for α‑Synuclein Fibril's Disordered Region..
[393]
|
33.
Dynamic phosphorylation of FOXA1 by Aurora B guides post-mitotic g..
[390]
|
34.
RPA transforms RNase H1 to a bidirectional exonuclease for efficie..
[389]
|
35.
Cryo-EM structures reveal variant Tau amyloid fibrils between the ..
[386]
|
36.
α-Synuclein amyloid fibril directly binds to LC3B and suppresses ..
[382]
|
37.
Binding adaptability of chemical ligands to polymorphic α-synucle..
[378]
|
38.
A novel partially open state of SHP2 points to a multiple gear reg..
[372]
|
39.
A Tau PET tracer PBB3 binds to TMEM106B amyloid fibril in brain
[358]
|
40.
The HRDC domain oppositely modulates the unwinding activity of E. ..
[351]
|
41.
Bloom syndrome helicase compresses single-stranded DNA into phase-..
[348]
|
42.
Subtle change of fibrillation condition leads to substantial alter..
[340]
|
43.
Remodeling the conformational dynamics of I-motif DNA by helicases..
[314]
|
44.
Molecular mechanisms of Streptococcus pyogenes Cas9: a single-mole..
[311]
|
45.
Replication protein A plays multifaceted roles complementary to sp..
[259]
|
46.
Conformational Dynamics of Nonenveloped Circovirus Capsid to the H..
[256]
|
47.
Structural mechanism underpinning Thermus oshimai Pif1-mediated G-..
[209]
|
48.
Bridging mechanical properties with atomic structures of polymorph..
[136]
|
49.
Single-molecule insight into α-synuclein fibril structure and mec..
[134]
|
50.
β-Lactoglobulin forms a conserved fibril core that assembles into..
[104]
|
51.
Design and Structural Elucidation of Glycopeptide Fibrils: Emulati..
[48]
|