5,848 research outputs found
FP-GR-INJECTIVE MODULES
In this paper, we give some characterizations of FP-grinjective R-modules and graded right R-modules of FP-gr-injective dimension at most n. We study the existence of FP-gr-injective envelopes and FP-gr-injective covers. We also prove that (1) (ā„gr-FI, gr-FI) is a hereditary cotorsion theory if and only if R is a left gr-coherent ring, (2) If R is right gr-coherent with FP-gr-id(RR) ā¤ n, then (gr-FIn, gr-F nā„) is a perfect cotorsion theory, (3) (ā„gr-FIn, gr-FIn) is a cotorsion theory, where gr-FI denotes the class of all FP-gr-injective left R-modules, gr-FIn is the class of all graded right R-modules of FP-gr-injective dimension at most n. Some applications are given
TRIANGULAR MATRIX REPRESENTATIONS OF SKEW MONOID RINGS
Let R be a ring and S a u.p.-monoid. Assume that there is a monoid homomorphism α : S → Aut (R). Suppose that α is weakly rigid and lR(Ra) is pure as a left ideal of R for every element a ∈ R. Then the skew monoid ring R*S induced by α has the same triangulating dimension as R. Furthermore, if R is a PWP ring, then so is R*S.</p
Radial Spokes-A Snapshot of the Motility Regulation, Assembly, and Evolution of Cilia and Flagella
Propulsive forces generated by cilia and flagella are used in events that are critical for the thriving of diverse eukaryotic organisms in their environments. Despite distinctive strokes and regulations, the majority of them adopt the 9+2 axoneme that is believed to exist in the last eukaryotic common ancestor. Only a few outliers have opted for a simpler format that forsakes the signature radial spokes and the central pair apparatus, although both are unnecessary for force generation or rhythmicity. Extensive evidence has shown that they operate as an integral system for motility control. Recent studies have made remarkable progress on the radial spoke. This review will trace how the new structural, compositional, and evolutional insights pose significant implications on flagella biology and, conversely, ciliopathy
Imaging Ferroelectric Domains via Charge Gradient Microscopy Enhanced by Principal Component Analysis
Local domain structures of ferroelectrics have been studied extensively using
various modes of scanning probes at the nanoscale, including piezoresponse
force microscopy (PFM) and Kelvin probe force microscopy (KPFM), though none of
these techniques measure the polarization directly, and the fast formation
kinetics of domains and screening charges cannot be captured by these
quasi-static measurements. In this study, we used charge gradient microscopy
(CGM) to image ferroelectric domains of lithium niobate based on current
measured during fast scanning, and applied principal component analysis (PCA)
to enhance the signal-to-noise ratio of noisy raw data. We found that the CGM
signal increases linearly with the scan speed while decreases with the
temperature under power-law, consistent with proposed imaging mechanisms of
scraping and refilling of surface charges within domains, and polarization
change across domain wall. We then, based on CGM mappings, estimated the
spontaneous polarization and the density of surface charges with order of
magnitude agreement with literature data. The study demonstrates that PCA is a
powerful method in imaging analysis of scanning probe microscopy (SPM), with
which quantitative analysis of noisy raw data becomes possible
IDENTIFICATION OF SUMOYLATED PROTEINS AND INVESTIGATION OF PROTEIN UBIQUITINATION IN THE NF-ĪŗB PATHWAY
SUMOylation and ubiquitination are important post-translational modifications. While ubiquitination is well known for targeting proteins for degradation, SUMOylation often regulates the intracellular localization of substrates. In the first project of this dissertation, we developed proteomic strategies to identify novel SUMOylated proteins in mammalian cells. In the second project, we investigated the regulation of protein ubiquitination in the NF-ĪŗB signaling pathway in the context of Pagetās disease of bone (PDB).
Identification of SUMOylated proteins has been a challenge because of low abundance of SUMOylation substrates. Here, we utilized a mass spectrometry (MS)-based proteomic approach to identify novel SUMOylated proteins in mammalian cells. Seventy-four unique proteins were commonly identified in the collection of four SUMO-1 plasmids, thus considered candidate SUMOylated proteins. Many of these proteins are associated with the nucleus. The results were validated by confirming SUMOylation of a novel substrate Drebrin and a well known substrate Ran-GAP1. Furthermore, the potential SUMOylation sites in Drebrin have been identified and confirmed using site-directed mutagenesis.
PDB is a disorder characterized by increased bone turnover containing hyperactive osteoclasts. Mutations in Sequestosome 1 (p62) are associated with 40% of familial PDB. P62 is a scaffold protein and plays a critical role in regulating ubiquitination of TRAF family signaling molecules and mediating the activation of NF-ĪŗB by RANK and TNFĪ± ligands. P62 also plays a critical role in shuttling substrates for autophagic degradation. The objective of this project is to determine the effects of PDB-associated p62 mutants on NF-ĪŗB signaling and autophagy. We compared the effect of wild-type (WT) p62 and PDB mutations (A381V, M404V and P392L) on the TNFĪ±-induced NF-ĪŗB signaling using an NF-ĪŗB luciferase assay. Our results show that these p62 mutations increased the NF-ĪŗB signaling. In addition, we found that the PDB mutations did not change the interaction between p62 and the autophagy marker protein LC3. In summary, the PDB mutations in p62 are likely gain-of-function mutations that can increase NF-ĪŗB signaling and potentially contribute to disease progression. Based on the results, we proposed a model to speculate the synergetic role of p62 PDB mutant on NF-ĪŗB signaling and autophagy
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