FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1992474824> ?p ?o ?g. }

• W1992474824 endingPage "158" @default.
• W1992474824 startingPage "145" @default.
• W1992474824 abstract "Abstract There is now consensus that the accumulation of oxidatively modified proteins is cytotoxic and causally related to several age‐related diseases including the amyloid diseases and age‐related cataracts. There is also general agreement that the ubiquitin proteolytic pathway (UPP) provides a quality control mechanism to limit accumulation of modified proteins. We asked if and how oxidative stress is related to the function of the ubiquitin proteolytic pathway, and vice versa, with the objective of obtaining information that can lead to the development of strategies to delay age‐related “amyloid” or “protein precipitation” diseases such as cataracts and age‐related macular degeneration. Elevated levels of ubiquitin conjugates were observed when human, rabbit, bovine, and rat lens, retina, liver cells or tissues were exposed to mild oxidative stress, which was created by exposure to paraquat, diamide, peroxide, light together with lipofuscin, and radiomimetic drugs. The increase in ubiquitin conjugates derived from an increase in substrates as well as by hyperactivation of E1, rather than inactivation of the proteasome. Using a novel glutathiolated substrate, γC‐crystallin, we demonstrated that the UPP shows a previously unrecognized selectivity for such specifically oxidatively modified proteins. Selectivity of the pathway for other oxidatively modified proteins, specifically for protein carbonyls, was indicated in assays that employed the ubiquitin conjugation‐competent, but degradation‐resistant ubiquitin variant K6W‐ubiquitin. These experiments showed that failure to execute ubiquitin‐dependent proteolysis renders cells more susceptible to oxidative‐stress‐related cytotoxicity. Activity of the pathway is regulated in part by cellular redox status, specifically as affected by GSSG. Ubiquitination is enhanced when GSSG/GSH ratios are 0.02–0.15. Since there is potentiation of ubiquitination even when GSSG/GSH ratios are indistinguishable from basal levels, it appears that ubiquitination provides one of the most sensitive indicators of oxidative stress. Ubiquitination is attenuated when GSSG/GSH rises >0.2 and does not occur when GSSG/GSH ⩾ 2.9. The data indicate that inhibition of the pathway, which occurs upon aging, is associated with accumulation rather than the timely degradation of ubiquitin conjugates. They further suggest that if the system fails to keep up with production of substrates, high mass ubiquitin conjugates may accumulate and precipitate in cytotoxic aggregates such as are seen in many age‐related syndromes, including lens cataracts or in lipofuscin and drusen in the aging retina." @default.
• W1992474824 created "2016-06-24" @default.
• W1992474824 creator A5017941291 @default.
• W1992474824 creator A5018729893 @default.
• W1992474824 creator A5059483104 @default.
• W1992474824 creator A5068775517 @default.
• W1992474824 creator A5077006581 @default.
• W1992474824 date "2006-09-01" @default.
• W1992474824 modified "2023-10-16" @default.
• W1992474824 title "Protein Quality Control by the Ubiquitin Proteolytic Pathway: Roles in Resistance to Oxidative Stress and Disease" @default.
• W1992474824 cites W1479851678 @default.
• W1992474824 cites W1482639028 @default.
• W1992474824 cites W1504455862 @default.
• W1992474824 cites W1506520614 @default.
• W1992474824 cites W1522890520 @default.
• W1992474824 cites W1530657831 @default.
• W1992474824 cites W1540889881 @default.
• W1992474824 cites W1592049170 @default.
• W1992474824 cites W168220588 @default.
• W1992474824 cites W1840618761 @default.
• W1992474824 cites W1874751834 @default.
• W1992474824 cites W1874829170 @default.
• W1992474824 cites W1936380547 @default.
• W1992474824 cites W1967493255 @default.
• W1992474824 cites W1975996615 @default.
• W1992474824 cites W1982886439 @default.
• W1992474824 cites W1984119181 @default.
• W1992474824 cites W1991761365 @default.
• W1992474824 cites W1995878478 @default.
• W1992474824 cites W1996164344 @default.
• W1992474824 cites W1997369314 @default.
• W1992474824 cites W1998851985 @default.
• W1992474824 cites W1999921913 @default.
• W1992474824 cites W2004285146 @default.
• W1992474824 cites W2009941252 @default.
• W1992474824 cites W2014765226 @default.
• W1992474824 cites W2017107298 @default.
• W1992474824 cites W2017492499 @default.
• W1992474824 cites W2017658570 @default.
• W1992474824 cites W2020351832 @default.
• W1992474824 cites W2021242983 @default.
• W1992474824 cites W2021605503 @default.
• W1992474824 cites W2024433794 @default.
• W1992474824 cites W2025983577 @default.
• W1992474824 cites W2028646865 @default.
• W1992474824 cites W2034447651 @default.
• W1992474824 cites W2035817557 @default.
• W1992474824 cites W2036939229 @default.
• W1992474824 cites W2039518578 @default.
• W1992474824 cites W2042036635 @default.
• W1992474824 cites W2048085445 @default.
• W1992474824 cites W2048966030 @default.
• W1992474824 cites W2049011147 @default.
• W1992474824 cites W2061132840 @default.
• W1992474824 cites W2061368959 @default.
• W1992474824 cites W2061489149 @default.
• W1992474824 cites W2062145090 @default.
• W1992474824 cites W2063641892 @default.
• W1992474824 cites W2070828755 @default.
• W1992474824 cites W2076696727 @default.
• W1992474824 cites W2082861541 @default.
• W1992474824 cites W2084046697 @default.
• W1992474824 cites W2093643698 @default.
• W1992474824 cites W2094190171 @default.
• W1992474824 cites W2094764240 @default.
• W1992474824 cites W2120793206 @default.
• W1992474824 cites W2135820955 @default.
• W1992474824 cites W2140182533 @default.
• W1992474824 cites W2141217773 @default.
• W1992474824 cites W2149715144 @default.
• W1992474824 cites W2149761960 @default.
• W1992474824 cites W2166081528 @default.
• W1992474824 cites W2169363048 @default.
• W1992474824 cites W2170958514 @default.
• W1992474824 cites W2315293508 @default.
• W1992474824 cites W2329496963 @default.
• W1992474824 cites W2387339264 @default.
• W1992474824 cites W2484220450 @default.
• W1992474824 cites W41320602 @default.
• W1992474824 cites W4253422011 @default.
• W1992474824 doi "https://doi.org/10.1560/a8aa-y8rp-9drw-y8ax" @default.
• W1992474824 hasPublicationYear "2006" @default.
• W1992474824 type Work @default.
• W1992474824 sameAs 1992474824 @default.
• W1992474824 citedByCount "8" @default.
• W1992474824 countsByYear W19924748242012 @default.
• W1992474824 crossrefType "journal-article" @default.
• W1992474824 hasAuthorship W1992474824A5017941291 @default.
• W1992474824 hasAuthorship W1992474824A5018729893 @default.
• W1992474824 hasAuthorship W1992474824A5059483104 @default.
• W1992474824 hasAuthorship W1992474824A5068775517 @default.
• W1992474824 hasAuthorship W1992474824A5077006581 @default.
• W1992474824 hasConcept C104317684 @default.
• W1992474824 hasConcept C134459356 @default.
• W1992474824 hasConcept C181199279 @default.
• W1992474824 hasConcept C185592680 @default.
• W1992474824 hasConcept C186198217 @default.
• W1992474824 hasConcept C25602115 @default.

• next