Fig 5 - by Tiequan Niu (9927917)

HVR1-swap compensatory E1/E2 substitutions typically decrease virus entry dependency on SR-BI. by Christina Holmboe Olesen (11154333)

TNF-α inhibited A549 cell viability, increased paracellular permeability, HIF-1α expression and decreased VASP expression. by Mengjie Tang (602523)

Fig 5 - by Mestewat Simeon (19233200)

Cognitive mechanisms for inferring the meaning of novel signals during symbolisation - Fig 5 by Justin Sulik (4768296)

The radial water maze latency [s (mean ± SEM)] and number of errors (mean ± SEM) of proton irradiated and control rats on Day 1 and Day 2. by Michael T. Williams (357796)

Plot of mean simulated power with 95 percentile (2.5 & 97.5%) for select DNAm differences. by Jacquelyn Y. Taylor (6386456)

ALS Variants of Annexin A11’s Proline-Rich Domain Impair Its S100A6-Mediated Fibril Dissolution by Aman Shihora (16529668)

“…These findings indicate a slower fibril-to-monomer exchange for these ALS variants, resulting in a decreased level of S100A6-mediated fibril dissolution. …”

DnaK inhibits protein synthesis in vivo and in vitro. by Carissa Chan (18310140)

DnaK’s ATPase activity is stimulated by ribosomes and required to reduce protein synthesis. by Carissa Chan (18310140)

Preparations of DnaK protein are pure. by Carissa Chan (18310140)

DnaK does not refold heat-denatured luciferase when incubated in the presence of ribosomes. by Carissa Chan (18310140)

Trigger factor hinders DnaK-mediated reduction of protein synthesis. by Carissa Chan (18310140)

Transcription of a plasmid-borne copy of the <i>mgtC</i> gene from a heterologous promoter reduces protein synthesis. by Carissa Chan (18310140)

Exploration of the connected interface (S100A1/MDM2) section in MDM2. by Deepu Dowarha (5673440)

Subjects:

A Yoga Strengthening Program Designed to Minimize the Knee Adduction Moment for Women with Knee Osteoarthritis: A Proof-Of-Principle Cohort Study by Elora C. Brenneman (795723)

“…A secondary objective was to determine whether the program could improve mobility and fitness, and decrease peak KAM during gait. …”

<i>dnak14</i> mutant harbors a transposon insertion in the <i>dnaK</i> coding region and specifies a truncated DnaK protein. by Carissa Chan (18310140)

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”