Model of the role of SAMHD1 at transcription-replication conflict-derived R-loops. von Kiwon Park (6492266)

“… <p>In normal cells (left), R-loops formed by transcription-replication collision, are resolved by SAMHD1, which allows successful DNA replication and RNA transcription.  …”

Modulating the M−M Distance in Dinuclear Complexes. New Ligand with a 2,2‘-Biphenol Fragment as Key Unit:  Synthesis, Coordination Behavior, and Crystal Structures of Cu(II) and Zn... von Gianluca Ambrosi (1813753)

“… ¹H and ¹³C NMR experiments carried out in aqueous solution, as well as the crystal structures of the dinuclear Cu(II) and Zn(II) species formed in aqueous solution, aided in elucidating the involvement of <b>L</b> and BPH in Zn(II) and Cu(II) stabilization. …”

Geochemical constraints on the tectonic setting of basaltic host rocks to the Windy Craggy Cu-Co-Au massive sulphide deposit, northwestern British Columbia von Jan M. Peter (612716)

“… The co-occurrence of tholeiitic/calc-alkaline arc rocks with alkalic rocks indicates that the LTV (former) and MTV (latter) formed from melts that were influenced to varying degrees by subducted oceanic crust, and likely formed within a back-arc basin setting formed on a rifted oceanic arc.  …”

Table_1_Peripheral Vestibular Dysfunction Is a Common Occurrence in Children With Non-syndromic and Syndromic Genetic Hearing Loss.DOCX von Alicia Wang (11589937)

“… Improved understanding of the molecular physiology of vestibular hair cell dysfunction is important for clinical care as well as research involving vestibular hair cells in model organisms and in vitro models. …”

SsbB stimulates <i>E. coli</i> Topoisomerase I activity. von Samta Jain (170832)

“… Arrow heads indicate the relaxed and supercoiled forms of plasmid.</p> …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces von Jonathan B. Boreyko (1916740)

“… This dynamic defrosting phenomenon is driven by the low contact angle hysteresis of the defrosted meltwater relative to frost on microstructured superhydrophobic surfaces, which forms in the impaled Wenzel state. Dynamic defrosting on nanostructured superhydrophobic surfaces minimizes the time, heat, and gravitational energy required to remove frost from the surface, and is of interest for a variety of systems in cold and humid environments. …”

High-Throughput Sequencing of Six Bamboo Chloroplast Genomes: Phylogenetic Implications for Temperate Woody Bamboos (Poaceae: Bambusoideae) von Yun-Jie Zhang (219281)

“… In phylogenetic analyses, Bambusoideae, Pooideae and Ehrhartoideae formed the BEP clade, yet the internal relationships of this clade are controversial.  …”