| 1 | Integrative in silico and biochemical analyses demonstrate direct Arl3-mediated ODA16 release from the intraflagellar transport machinery | 2.2 | 3 | Citations (PDF) |
| 2 | Purine nucleosides replace cAMP in allosteric regulation of PKA in trypanosomatid pathogens | 1.6 | 9 | Citations (PDF) |
| 3 | Uncovering structural themes across cilia microtubule inner proteins with implications for human cilia function | 13.7 | 13 | Citations (PDF) |
| 4 | DLG1 functions upstream of SDCCAG3 and IFT20 to control ciliary targeting of polycystin-2 | 5.2 | 7 | Citations (PDF) |
| 5 | Architecture of RabL2‐associated complexes at the ciliary base: A structural modeling perspective | 2.1 | 0 | Citations (PDF) |
| 6 | The
IFT81‐IFT74
complex acts as an unconventional
RabL2 GTPase
‐activating protein during intraflagellar transport | 7.3 | 9 | Citations (PDF) |
| 7 | Analysis of cortical cell polarity by imaging flow cytometry | 3.0 | 2 | Citations (PDF) |
| 8 | Structure of the ciliogenesis-associated CPLANE complex | 10.9 | 30 | Citations (PDF) |
| 9 | Biallelic DAW1 variants cause a motile ciliopathy characterized by laterality defects and subtle ciliary beating abnormalities | 4.2 | 10 | Citations (PDF) |
| 10 | A multi-adenylate cyclase regulator at the flagellar tip controls African trypanosome transmission | 13.7 | 36 | Citations (PDF) |
| 11 | Biochemically validated structural model of the 15‐subunit intraflagellar transport complex IFT‐B | 7.3 | 44 | Citations (PDF) |
| 12 | A Semester-Long Learning Path Teaching Computational Skills via Molecular Graphics in PyMOL | 0.3 | 4 | Citations (PDF) |
| 13 | The ins and outs of the Arf4-based ciliary membrane-targeting complex | 2.1 | 20 | Citations (PDF) |
| 14 | Nse5/6 inhibits the Smc5/6 ATPase and modulates DNA substrate binding | 7.3 | 55 | Citations (PDF) |
| 15 | Ift88, but not Kif3a, is required for establishment of the periciliary membrane compartment | 2.1 | 1 | Citations (PDF) |
| 16 | IFT
proteins interact with
HSET
to promote supernumerary centrosome clustering in mitosis | 5.2 | 33 | Citations (PDF) |
| 17 | Purification and crystal structure of human ODA16: Implications for ciliary import of outer dynein arms by the intraflagellar transport machinery | 5.9 | 16 | Citations (PDF) |
| 18 | Structural insights into the architecture and assembly of eukaryotic flagella | 3.0 | 17 | Citations (PDF) |
| 19 | Akt Regulates a Rab11-Effector Switch Required for Ciliogenesis | 7.7 | 67 | Citations (PDF) |
| 20 | Human IFT52 mutations uncover a novel role for the protein in microtubule dynamics and centrosome cohesion | 2.9 | 28 | Citations (PDF) |
| 21 | Nucleoside analogue activators of cyclic AMP-independent protein kinase A of Trypanosoma | 13.7 | 47 | Citations (PDF) |
| 22 | Binding of IFT22 to the intraflagellar transport complex is essential for flagellum assembly | 7.3 | 49 | Citations (PDF) |
| 23 | Crystal structure of tetrameric human Rabin8 GEF domain | 2.6 | 5 | Citations (PDF) |
| 24 | Membrane association and remodeling by intraflagellar transport protein IFT172 | 13.7 | 35 | Citations (PDF) |
| 25 | Trafficking of ciliary membrane proteins by the intraflagellar transport/BBSome machinery | 5.2 | 154 | Citations (PDF) |
| 26 | Structural basis of outer dynein arm intraflagellar transport by the transport adaptor protein ODA16 and the intraflagellar transport protein IFT46 | 2.2 | 54 | Citations (PDF) |
| 27 | Intraflagellar transport protein IFT52 recruits IFT46 to the basal body and flagella | 2.4 | 43 | Citations (PDF) |
| 28 | IFT proteins spatially control the geometry of cleavage furrow ingression and lumen positioning | 13.7 | 26 | Citations (PDF) |
| 29 | The intraflagellar transport machinery in ciliary signaling | 6.4 | 81 | Citations (PDF) |
| 30 | Intraflagellar transport proteins 172, 80, 57, 54, 38, and 20 form a stable tubulin‐binding
IFT
‐B2 complex | 7.3 | 192 | Citations (PDF) |
| 31 | The Intraflagellar Transport Machinery | 7.2 | 353 | Citations (PDF) |
| 32 | Novel topography of the Rab11-effector interaction network within a ciliary membrane targeting complex | 2.1 | 18 | Citations (PDF) |
| 33 | Structure of Rab11–FIP3–Rabin8 reveals simultaneous binding of FIP3 and Rabin8 effectors to Rab11 | 8.8 | 46 | Citations (PDF) |
| 34 | Mutations in TRAF3IP1/IFT54 reveal a new role for IFT proteins in microtubule stabilization | 13.7 | 98 | Citations (PDF) |
| 35 | Getting tubulin to the tip of the cilium: One IFT train, many different tubulin cargo‐binding sites? | 2.1 | 43 | Citations (PDF) |
| 36 | Structural basis for membrane targeting of the BBSome by ARL6 | 8.8 | 86 | Citations (PDF) |
| 37 | Crystal structure of aChlamydomonas reinhardtiiflagellar RabGAP TBC-domain at 1.8 Å resolution | 2.6 | 5 | Citations (PDF) |
| 38 | Crystal structures of IFT70/52 and IFT52/46 provide insight into intraflagellar transport B core complex assembly | 5.4 | 128 | Citations (PDF) |
| 39 | Intraflagellar transport complex structure and cargo interactions | 5.0 | 105 | Citations (PDF) |
| 40 | Crystal structure of the invertebrate bifunctional purine biosynthesis enzyme PAICS at 2.8 Å resolution | 2.6 | 6 | Citations (PDF) |
| 41 | Atomic resolution structure of human α-tubulin acetyltransferase bound to acetyl-CoA | 7.5 | 46 | Citations (PDF) |
| 42 | Structural Studies of Ciliary Components | 4.1 | 72 | Citations (PDF) |
| 43 | Architecture and function of IFT complex proteins in ciliogenesis | 2.4 | 184 | Citations (PDF) |
| 44 | Crystal structure of the intraflagellar transport complex 25/27 | 7.3 | 111 | Citations (PDF) |
| 45 | Biochemical Mapping of Interactions within the Intraflagellar Transport (IFT) B Core Complex | 2.2 | 78 | Citations (PDF) |
| 46 | RNA channelling by the eukaryotic exosome | 5.2 | 70 | Citations (PDF) |
| 47 | The Yeast Exosome Functions as a Macromolecular Cage to Channel RNA Substrates for Degradation | 33.7 | 233 | Citations (PDF) |
| 48 | Crystal structure and stereochemical studies of KD(P)G aldolase from Thermoproteus tenax | 2.6 | 14 | Citations (PDF) |
| 49 | Structural organization of the RNA-degrading exosome | 6.4 | 44 | Citations (PDF) |
| 50 | Structure of the Active Subunit of the Yeast Exosome Core, Rrp44: Diverse Modes of Substrate Recruitment in the RNase II Nuclease Family | 13.3 | 179 | Citations (PDF) |
| 51 | Chapter 20 Expression, Reconstitution, and Structure of an Archaeal RNA Degrading Exosome | 2.1 | 12 | Citations (PDF) |
| 52 | RNA channelling by the archaeal exosome | 5.2 | 114 | Citations (PDF) |
| 53 | The Exosome and the Proteasome: Nano-Compartments for Degradation | 33.7 | 72 | Citations (PDF) |
| 54 | The Crystal Structure of the Exon Junction Complex Reveals How It Maintains a Stable Grip on mRNA | 33.7 | 390 | Citations (PDF) |
| 55 | Characterization of native and reconstituted exosome complexes from the hyperthermophilic archaeon Sulfolobus solfataricus | 2.5 | 52 | Citations (PDF) |
| 56 | A single subunit, Dis3, is essentially responsible for yeast exosome core activity | 8.8 | 401 | Citations (PDF) |
| 57 | The archaeal exosome core is a hexameric ring structure with three catalytic subunits | 8.8 | 205 | Citations (PDF) |
| 58 | RNA polyadenylation in Archaea: not observed in
Haloferax
while the exosome polynucleotidylates RNA in
Sulfolobus | 5.2 | 85 | Citations (PDF) |
| 59 | Mechanism of the Schiff Base Forming Fructose-1,6-bisphosphate Aldolase: Structural Analysis of Reaction Intermediates‡ | 2.4 | 68 | Citations (PDF) |
| 60 | Structural Basis of 3′ End RNA Recognition and Exoribonucleolytic Cleavage by an Exosome RNase PH Core | 13.3 | 106 | Citations (PDF) |
| 61 | Structural Basis of Allosteric Regulation and Substrate Specificity of the Non-Phosphorylating Glyceraldehyde 3-Phosphate Dehydrogenase from Thermoproteus tenax | 4.1 | 52 | Citations (PDF) |
| 62 | Structure and Function of a Regulated Archaeal Triosephosphate Isomerase Adapted to High Temperature | 4.1 | 33 | Citations (PDF) |
| 63 | Evolutionary markers in the (β/α)8-barrel fold | 5.8 | 35 | Citations (PDF) |
| 64 | Crystal Structure of an Archaeal Class I Aldolase and the Evolution of (βα)8 Barrel Proteins | 2.2 | 49 | Citations (PDF) |
| 65 | Phosphoproteomics reveals that Parkinson's disease kinase LRRK2 regulates a subset of Rab GTPases | 1.6 | 978 | Citations (PDF) |
| 66 | Systematic proteomic analysis of LRRK2-mediated Rab GTPase phosphorylation establishes a connection to ciliogenesis | 1.6 | 441 | Citations (PDF) |
| 67 | Crystal structure of intraflagellar transport protein 80 reveals a homo-dimer required for ciliogenesis | 1.6 | 38 | Citations (PDF) |
| 68 | Moving proteins along in the cilium | 1.6 | 3 | Citations (PDF) |
| 69 | A WDR35-dependent coat protein complex transports ciliary membrane cargo vesicles to cilia | 1.6 | 41 | Citations (PDF) |
| 70 | Purine nucleosides replace cAMP in allosteric regulation of PKA in trypanosomatid pathogens | 1.6 | 0 | Citations (PDF) |
| 71 | Myristoylated Neuronal Calcium Sensor-1 captures the preciliary vesicle at distal appendages | 1.6 | 2 | Citations (PDF) |
| 72 | Intraflagellar transport: How kinesin motors hook onto their trains | 3.6 | 0 | Citations (PDF) |
