SARS-CoV-2 mutants mediate robust cell-cell fusion. by Prerna Arora (821926)

Gene expression analysis of T3-regulated genes <i>Dio1</i>, <i>Gsta2</i> and <i>Ucp2</i> in the liver and <i>Hcn2</i>, <i>Atp2a2</i>, <i>Myh6 and Myh7</i> in heart of vehicle treat... by Soledad Bárez-López (607514)

Mutations at S1/S2 site reduce SARS-CoV-2 S cleavage. by Prerna Arora (821926)

Expression of TAP38 in <i>tap38</i> mutant, TAP38 overexpressor, and WT plants. by Mathias Pribil (254032)

“…Additionally, decreasing levels of WT thylakoids were loaded in the lanes indicated as 0.5× WT and 0.25× WT. …”

Characterization of agro-industrial residues. by Pitchanun Sinsukudomchai (14716950)

“…The thermal properties obtained by differential scanning calorimetry revealed a decrease in crystallinity for all biocomposites, with 100 wt% PHB displaying the highest values, whereas 100 wt% esterified PALF-MCC laurate showed no crystallinity. …”

K_ATP channel activity in pancreatic β-cells from WT and ERβ−/− mice in presence of 1 nM BPA. by Sergi Soriano (184947)

“…<p>A, BPA at 1 nM decreased K_ATP channel activity in pancreatic β-cells from WT mice. …”

<i>PHO5</i> AS elongation affects <i>PHO5</i> gene expression <i>via</i> histone acetylation. by Ana Novačić (8373573)

The early endosomal membranes are enriched with PE in yeast and plant cells. by Kai Xu (122914)

Number of TH-positive cells in the retina of WT and MT₁^−/− (A) and DA and DOPAC levels measured in WT and MT₁^−/− in DD. by Anamika Sengupta (344856)

MCP-1-deficiency decreased CD11c-expressing cells via impairing the production of ROS and decreased activation of PLCγ2, Akt, and ERK upon M-CSF stimulation in BMM. by Woon-Ki Kim (447798)

“…<p>BMMs from WT (open bar) and MCP-1-KO mice (oblique-lined bar) were incubated in the presence of M-CSF (30 ng/ml) with U73122 (10 µM), Akt inhibitor IV (0.3 µM), PD098059 (5 µM), DPI (50 nM), NAC (3 mM), or H₂O₂ (300 µM) for 4 d (A). *, <i>P</i><0.05; ***, <i>P</i><0.001 compared with vehicle-treated WT cells. …”

Western-blot and BN-PAGE analyses of brain mitochondria from WT and AOX mice. by Riyad El-Khoury (104865)

“…<p>A, Western-blot analyses of the steady state of different RC complexes (CI, NDUFA12; CII, SDHA; CIII, Core1; CIV, Cox1 and, CV, ß-ATPase) of mitochondria extracted from 11 organs from four WT and four AOX mice. B, RC complexes (I, III, IV and V) from three different organs, highly (brain), mildly (heart) and weakly (liver) expressing the AOX, were quantified as a ratio to complex II with no significant difference being observed between WT and AOX mice. …”

Atrial and ventricular connexins and sodium channel genes expression levels in wt and Ts65Dn mice. by Matthieu Raveau (160575)

“…Mean±sem with Student t-test <i>P</i>-values, N = 7 and 5 for Ts65Dn and wt respectively.</p>…”

Percent live fetuses after LPS90 and LPS250 compared with Wt controls. by Maide Ozen (6551636)

“…<p>Intraperitoneal administration of LPS at a dose of 250 μg/kg at E16.5 resulted in a significant decrease in the percentage of live fetuses compared with GA-matched Wt controls. …”

STC-NC analysis measures a reduction in the RF center size for both ON and ON-OFF cells during WT development. by Donald R. Cantrell (239233)

“…Following standard ANCOVA analysis, the parallel condition was enforced after demonstrating that the slopes of the lines of best fit through the two data sets were not significantly different and that P25 had smaller RF sizes than P18 for WT ON cells ( p = 4×10⁻⁵ in ANCOVA test).…”

Nitric Oxide Oxidatively Nitrosylates Ni(I) and Cu(I) <i>C</i>-Organonitroso Adducts by Stefan Wiese (1626535)

“…[Me₂NN]Cu(NCMe) reacts with 0.5 equiv of ArNO in ether to give the dinuclear adducts {[Me₂NN]Cu}₂(μ-η²:η¹-ONAr) (<b>2a</b> and <b>2b</b>), which exhibit η² and η¹ bonding of the ArNO moiety with separate [Me₂NN]Cu fragments possessing N−O distances of 1.375(6) Å (<b>2a</b>) and 1.368(2) Å (<b>2b</b>). …”

Nitric Oxide Oxidatively Nitrosylates Ni(I) and Cu(I) <i>C</i>-Organonitroso Adducts by Stefan Wiese (1626535)

“…[Me₂NN]Cu(NCMe) reacts with 0.5 equiv of ArNO in ether to give the dinuclear adducts {[Me₂NN]Cu}₂(μ-η²:η¹-ONAr) (<b>2a</b> and <b>2b</b>), which exhibit η² and η¹ bonding of the ArNO moiety with separate [Me₂NN]Cu fragments possessing N−O distances of 1.375(6) Å (<b>2a</b>) and 1.368(2) Å (<b>2b</b>). …”

Nitric Oxide Oxidatively Nitrosylates Ni(I) and Cu(I) <i>C</i>-Organonitroso Adducts by Stefan Wiese (1626535)

“…[Me₂NN]Cu(NCMe) reacts with 0.5 equiv of ArNO in ether to give the dinuclear adducts {[Me₂NN]Cu}₂(μ-η²:η¹-ONAr) (<b>2a</b> and <b>2b</b>), which exhibit η² and η¹ bonding of the ArNO moiety with separate [Me₂NN]Cu fragments possessing N−O distances of 1.375(6) Å (<b>2a</b>) and 1.368(2) Å (<b>2b</b>). …”

Nitric Oxide Oxidatively Nitrosylates Ni(I) and Cu(I) <i>C</i>-Organonitroso Adducts by Stefan Wiese (1626535)

“…[Me₂NN]Cu(NCMe) reacts with 0.5 equiv of ArNO in ether to give the dinuclear adducts {[Me₂NN]Cu}₂(μ-η²:η¹-ONAr) (<b>2a</b> and <b>2b</b>), which exhibit η² and η¹ bonding of the ArNO moiety with separate [Me₂NN]Cu fragments possessing N−O distances of 1.375(6) Å (<b>2a</b>) and 1.368(2) Å (<b>2b</b>). …”

Nitric Oxide Oxidatively Nitrosylates Ni(I) and Cu(I) <i>C</i>-Organonitroso Adducts by Stefan Wiese (1626535)

“…[Me₂NN]Cu(NCMe) reacts with 0.5 equiv of ArNO in ether to give the dinuclear adducts {[Me₂NN]Cu}₂(μ-η²:η¹-ONAr) (<b>2a</b> and <b>2b</b>), which exhibit η² and η¹ bonding of the ArNO moiety with separate [Me₂NN]Cu fragments possessing N−O distances of 1.375(6) Å (<b>2a</b>) and 1.368(2) Å (<b>2b</b>). …”

Nitric Oxide Oxidatively Nitrosylates Ni(I) and Cu(I) <i>C</i>-Organonitroso Adducts by Stefan Wiese (1626535)

“…[Me₂NN]Cu(NCMe) reacts with 0.5 equiv of ArNO in ether to give the dinuclear adducts {[Me₂NN]Cu}₂(μ-η²:η¹-ONAr) (<b>2a</b> and <b>2b</b>), which exhibit η² and η¹ bonding of the ArNO moiety with separate [Me₂NN]Cu fragments possessing N−O distances of 1.375(6) Å (<b>2a</b>) and 1.368(2) Å (<b>2b</b>). …”