Expression of Clk^DN in photoreceptors leads to genome-wide changes in TF activity and a widespread decrease in chromatin accessibility. by Juan Jauregui-Lozano (12024868)

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

Notch signaling regulates fused mitochondrial morphology in INPs and muscle cells. by Dnyanesh Dubal (12085942)

Analysis of proliferation in NBs depleted of Opa1 and Marf. by Dnyanesh Dubal (12085942)

Down-regulation of Rfng and overexpression of Lfng or Mfng decreased their ability to promote Th2 subsets but elevated the ability to promote Th1 subsets. by Wen Gu (129075)

Depletion of mitochondrial fusion proteins Opa1 and Marf result in mitochondrial fragmentation. by Dnyanesh Dubal (12085942)

HEWL interacts with dissipated oleic acid micelles, and decreases oleic acid cytotoxicity - Fig 2 by Qin Huang (49441)

Subjects:

HEWL interacts with dissipated oleic acid micelles, and decreases oleic acid cytotoxicity - Fig 4 by Qin Huang (49441)

Subjects:

Proliferation defects in Opa1 depleted type II NB lineages are suppressed by overexpression of Drp1^SD. by Dnyanesh Dubal (12085942)

“…Analysis of percentage of dividing mature INPs in type II NB lineages (D, yellow arrows are Dpn+pH3+) in mCherry RNAi (33 Type II NB lineages,7 brains), Drp1^SD;mCherry RNAi (24,6), <i>opa1</i> (33,6, Drp1^SD;<i>opa1</i> RNAi (26,8), <i>marf</i> RNAi (33,8), Drp1^SD;<i>marf</i> RNAi (15,5). …”

<i>clec-4</i> mutants show a decreased early offspring production. by Barbara Pees (3313560)

HEWL interacts with dissipated oleic acid micelles, and decreases oleic acid cytotoxicity - Fig 3 by Qin Huang (49441)

Subjects:

Nur77 knockdown decreases cell viability and proliferation. by Alexa Tenga (2161780)

“…Cell confluence was averaged, with 4 replicates of each condition; *<i>p</i> < 0.0001. (D) Nur77 mRNA was significantly (<i>p</i> < 0.0001) decreased after transfecting Daoy cells with siNur77. …”