SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2099851483> ?p ?o ?g. }

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

W2099851483 endingPage "35" @default.
W2099851483 startingPage "35" @default.
W2099851483 abstract "Escherichia coli induces heat shock genes to the temperature up-shift, and changes the metabolism by complicated mechanism. The heat shock response is of practical importance for the variety of applications such as temperature-induced heterologous protein production, simultaneous saccharification and fermentation (SSF) etc. However, the effect of heat shock on the metabolic regulation is not well investigated. It is strongly desired to understand the metabolic changes and its mechanism upon heat shock in practice for the efficient metabolite production by temperature up-shift. In the present research, therefore, we investigated the effect of temperature up-shift from 37 degrees C to 42 degrees C on the metabolism in view of gene expressions.The results of aerobic batch and continuous cultivations of E. coli BW25113 indicate that more acetate was accumulated with lower biomass yield and less glucose consumption rate at 42 degrees C as compared to the case at 37 degrees C. The down- regulation of the glucose uptake rate corresponds to the down-regulation of ptsG gene expression caused by the up-regulation of mlc gene expression. In accordance with up-regulation of arcA, which may be caused by the lower oxygen solubility at 42 degrees C, the expressions of the TCA cycle-related genes and the respiratory chain gene cyoA were down-regulated. The decreased activity of TCA cycle caused more acetate formation at higher temperature, which is not preferred in heterologous protein production etc. This can be overcome by the arcA gene knockout to some extent. The time courses of gene expressions revealed that the heat shock genes such as groEL, dnaK, htpG and ibpB as well as mlc were expressed in much the same way as that of rpoH during the first 10-20 minutes after temperature up-shift. Under microaerobic condition, the fermentation changed in such a way that formate and lactate were more produced due to up-regulation of pflA and ldhA genes while ethanol was less produced due to down-regulation of adhE gene at higher temperature as compared to the case at 37 degrees C.The present result clarified the mechanism of metabolic changes upon heat shock from 37 degrees C to 42 degrees C based on gene expressions of heat shock genes, global regulators, and the metabolic pathway genes. It is recommended to use arcA gene knockout mutant to prevent higher acetate production upon heat shock, where it must be noted that the cell yield may be decreased due to TCA cycle activation by arcA gene knockout." @default.
W2099851483 created "2016-06-24" @default.
W2099851483 creator A5067288478 @default.
W2099851483 creator A5068212867 @default.
W2099851483 date "2008-01-01" @default.
W2099851483 modified "2023-10-17" @default.
W2099851483 title "Effect of temperature up-shift on fermentation and metabolic characteristics in view of gene expressions in Escherichia coli" @default.
W2099851483 cites W1480951920 @default.
W2099851483 cites W1558066527 @default.
W2099851483 cites W1601634511 @default.
W2099851483 cites W1605141624 @default.
W2099851483 cites W1609927813 @default.
W2099851483 cites W1635174795 @default.
W2099851483 cites W1851873120 @default.
W2099851483 cites W1931534490 @default.
W2099851483 cites W1940645698 @default.
W2099851483 cites W1965246206 @default.
W2099851483 cites W1971441722 @default.
W2099851483 cites W1972880328 @default.
W2099851483 cites W1975025949 @default.
W2099851483 cites W1977388184 @default.
W2099851483 cites W1980873743 @default.
W2099851483 cites W1984821361 @default.
W2099851483 cites W1986390248 @default.
W2099851483 cites W1990946544 @default.
W2099851483 cites W1992000554 @default.
W2099851483 cites W1995266840 @default.
W2099851483 cites W1996316886 @default.
W2099851483 cites W1996831855 @default.
W2099851483 cites W2002044386 @default.
W2099851483 cites W2008299970 @default.
W2099851483 cites W2017030483 @default.
W2099851483 cites W2021113302 @default.
W2099851483 cites W2023383733 @default.
W2099851483 cites W2036340151 @default.
W2099851483 cites W2036614401 @default.
W2099851483 cites W2040233624 @default.
W2099851483 cites W2040960801 @default.
W2099851483 cites W2051443873 @default.
W2099851483 cites W2055073505 @default.
W2099851483 cites W2056592058 @default.
W2099851483 cites W2058069757 @default.
W2099851483 cites W2062794778 @default.
W2099851483 cites W2065472522 @default.
W2099851483 cites W2072393954 @default.
W2099851483 cites W2082062328 @default.
W2099851483 cites W2084445751 @default.
W2099851483 cites W2092300510 @default.
W2099851483 cites W2092603929 @default.
W2099851483 cites W2094160282 @default.
W2099851483 cites W2099837468 @default.
W2099851483 cites W2111887028 @default.
W2099851483 cites W2112515687 @default.
W2099851483 cites W2116307528 @default.
W2099851483 cites W2118789593 @default.
W2099851483 cites W2125546186 @default.
W2099851483 cites W2130440450 @default.
W2099851483 cites W2131025983 @default.
W2099851483 cites W2132809900 @default.
W2099851483 cites W2150688068 @default.
W2099851483 cites W2152694732 @default.
W2099851483 cites W2155038624 @default.
W2099851483 cites W2164096594 @default.
W2099851483 cites W2167135535 @default.
W2099851483 cites W2168076793 @default.
W2099851483 cites W2177384235 @default.
W2099851483 cites W2216987090 @default.
W2099851483 cites W2414869702 @default.
W2099851483 cites W2804007336 @default.
W2099851483 doi "https://doi.org/10.1186/1475-2859-7-35" @default.
W2099851483 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/2634768" @default.
W2099851483 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/19055729" @default.
W2099851483 hasPublicationYear "2008" @default.
W2099851483 type Work @default.
W2099851483 sameAs 2099851483 @default.
W2099851483 citedByCount "39" @default.
W2099851483 countsByYear W20998514832012 @default.
W2099851483 countsByYear W20998514832013 @default.
W2099851483 countsByYear W20998514832014 @default.
W2099851483 countsByYear W20998514832015 @default.
W2099851483 countsByYear W20998514832016 @default.
W2099851483 countsByYear W20998514832017 @default.
W2099851483 countsByYear W20998514832018 @default.
W2099851483 countsByYear W20998514832019 @default.
W2099851483 countsByYear W20998514832020 @default.
W2099851483 countsByYear W20998514832021 @default.
W2099851483 countsByYear W20998514832022 @default.
W2099851483 crossrefType "journal-article" @default.
W2099851483 hasAuthorship W2099851483A5067288478 @default.
W2099851483 hasAuthorship W2099851483A5068212867 @default.
W2099851483 hasBestOaLocation W20998514831 @default.
W2099851483 hasConcept C100544194 @default.
W2099851483 hasConcept C104317684 @default.
W2099851483 hasConcept C108305142 @default.
W2099851483 hasConcept C137984847 @default.
W2099851483 hasConcept C143065580 @default.
W2099851483 hasConcept C150194340 @default.
W2099851483 hasConcept C165135838 @default.