SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4387296873> ?p ?o ?g. }

Showing items 1 to 100 of ±147 with 100 items per page.

W4387296873 abstract "The foodborne bacterial pathogen Listeria monocytogenes exhibits remarkable survival capabilities under challenging conditions, severely threatening food safety and human health. The orphan regulator DegU is a pleiotropic regulator required for bacterial environmental adaptation. However, the specific mechanism of how DegU participates in oxidative stress tolerance remains unknown in L. monocytogenes. In this study, we demonstrate that DegU suppresses carbohydrate uptake under stress conditions by altering global transcriptional profiles, particularly by modulating the transcription of the phosphoenolpyruvate-carbohydrate phosphotransferase system (PTS)-related genes, such as ptsH, ptsI, and hprK. Specifically, in the absence of degU, the transcripts of ptsI are significantly upregulated and those of hprK are significantly downregulated in response to copper ion-induced stress. Overexpression of ptsI significantly increases bacterial growth in vitro, while overexpression of hprK leads to a decrease in growth. We further demonstrate that DegU directly senses oxidative stress, downregulates ptsI transcription, and upregulates hprK transcription. Additionally, through an electrophoretic mobility shift assay, we demonstrate that DegU directly regulates the transcription of ptsI and hprK by binding to specific regions within their respective promoter sequences. Notably, the putative pivotal DegU binding sequence for ptsI is located from 38 to 68 base pairs upstream of the ptsH transcription start site (TSS), whereas for hprK, it is mapped from 36 to 124 base pairs upstream of the hprK TSS. In summary, we elucidate that DegU plays a significant role in suppressing carbohydrate uptake in response to oxidative stress through the direct regulation of ptsI and hprK. IMPORTANCE Understanding the adaptive mechanisms employed by Listeria monocytogenes in harsh environments is of great significance. This study focuses on investigating the role of DegU in response to oxidative stress by examining global transcriptional profiles. The results highlight the noteworthy involvement of DegU in this stress response. Specifically, DegU acts as a direct sensor of oxidative stress, leading to the modulation of gene transcription. It downregulates ptsI transcription while it upregulates hprK transcription through direct binding to their promoters. Consequently, these regulatory actions impede bacterial growth, providing a defense mechanism against stress-induced damage. These findings gained from this study may have broader implications, serving as a reference for studying adaptive mechanisms in other pathogenic bacteria and aiding in the development of targeted strategies to control L. monocytogenes and ensure food safety." @default.
W4387296873 created "2023-10-04" @default.
W4387296873 creator A5012513461 @default.
W4387296873 creator A5021770801 @default.
W4387296873 creator A5025588089 @default.
W4387296873 creator A5035253417 @default.
W4387296873 creator A5046548684 @default.
W4387296873 creator A5051200562 @default.
W4387296873 creator A5055896271 @default.
W4387296873 creator A5067766374 @default.
W4387296873 creator A5074999356 @default.
W4387296873 creator A5075256301 @default.
W4387296873 creator A5083141635 @default.
W4387296873 creator A5085140432 @default.
W4387296873 date "2023-10-03" @default.
W4387296873 modified "2023-10-04" @default.
W4387296873 title "DegU-mediated suppression of carbohydrate uptake in <i>Listeria monocytogenes</i> increases adaptation to oxidative stress" @default.
W4387296873 cites W1657477461 @default.
W4387296873 cites W1853627239 @default.
W4387296873 cites W1964985689 @default.
W4387296873 cites W1968934336 @default.
W4387296873 cites W1980960636 @default.
W4387296873 cites W1987427541 @default.
W4387296873 cites W1999574084 @default.
W4387296873 cites W2006479463 @default.
W4387296873 cites W2027847170 @default.
W4387296873 cites W2035026759 @default.
W4387296873 cites W2036449301 @default.
W4387296873 cites W2038683612 @default.
W4387296873 cites W2039116271 @default.
W4387296873 cites W2046266708 @default.
W4387296873 cites W2058920872 @default.
W4387296873 cites W2069480047 @default.
W4387296873 cites W2081457291 @default.
W4387296873 cites W2081501964 @default.
W4387296873 cites W2098544115 @default.
W4387296873 cites W2102355695 @default.
W4387296873 cites W2107277218 @default.
W4387296873 cites W2109580287 @default.
W4387296873 cites W2113084195 @default.
W4387296873 cites W2128473487 @default.
W4387296873 cites W2138331549 @default.
W4387296873 cites W2141883257 @default.
W4387296873 cites W2144360067 @default.
W4387296873 cites W2150415814 @default.
W4387296873 cites W2154630055 @default.
W4387296873 cites W2162953780 @default.
W4387296873 cites W2163610076 @default.
W4387296873 cites W2168177244 @default.
W4387296873 cites W2170551349 @default.
W4387296873 cites W2179438025 @default.
W4387296873 cites W2583623006 @default.
W4387296873 cites W2600586609 @default.
W4387296873 cites W2606757801 @default.
W4387296873 cites W2740942520 @default.
W4387296873 cites W2750506094 @default.
W4387296873 cites W2845591014 @default.
W4387296873 cites W2919853286 @default.
W4387296873 cites W2974980934 @default.
W4387296873 cites W2998065350 @default.
W4387296873 cites W3124778205 @default.
W4387296873 cites W3129532099 @default.
W4387296873 cites W3156413642 @default.
W4387296873 cites W3194737464 @default.
W4387296873 cites W4200125899 @default.
W4387296873 cites W4200130522 @default.
W4387296873 cites W4200454311 @default.
W4387296873 cites W4200495033 @default.
W4387296873 cites W4205394240 @default.
W4387296873 cites W4288081204 @default.
W4387296873 cites W4293052015 @default.
W4387296873 cites W4309719200 @default.
W4387296873 cites W4310962191 @default.
W4387296873 doi "https://doi.org/10.1128/aem.01017-23" @default.
W4387296873 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/37787570" @default.
W4387296873 hasPublicationYear "2023" @default.
W4387296873 type Work @default.
W4387296873 citedByCount "0" @default.
W4387296873 crossrefType "journal-article" @default.
W4387296873 hasAuthorship W4387296873A5012513461 @default.
W4387296873 hasAuthorship W4387296873A5021770801 @default.
W4387296873 hasAuthorship W4387296873A5025588089 @default.
W4387296873 hasAuthorship W4387296873A5035253417 @default.
W4387296873 hasAuthorship W4387296873A5046548684 @default.
W4387296873 hasAuthorship W4387296873A5051200562 @default.
W4387296873 hasAuthorship W4387296873A5055896271 @default.
W4387296873 hasAuthorship W4387296873A5067766374 @default.
W4387296873 hasAuthorship W4387296873A5074999356 @default.
W4387296873 hasAuthorship W4387296873A5075256301 @default.
W4387296873 hasAuthorship W4387296873A5083141635 @default.
W4387296873 hasAuthorship W4387296873A5085140432 @default.
W4387296873 hasConcept C104317684 @default.
W4387296873 hasConcept C127561419 @default.
W4387296873 hasConcept C138885662 @default.
W4387296873 hasConcept C143937172 @default.
W4387296873 hasConcept C179926584 @default.
W4387296873 hasConcept C183978625 @default.
W4387296873 hasConcept C27153228 @default.
W4387296873 hasConcept C2776151105 @default.
W4387296873 hasConcept C2781350384 @default.