SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2099456413> ?p ?o ?g. }

Showing items 1 to 100 of ±170 with 100 items per page.

W2099456413 endingPage "397" @default.
W2099456413 startingPage "387" @default.
W2099456413 abstract "Free-energy (ATP) conservation during product formation is crucial for the maximum product yield that can be obtained, but often overlooked in metabolic engineering strategies. Product pathways that do not yield ATP or even demand input of free energy (ATP) require an additional pathway to supply the ATP needed for product formation, cellular maintenance, and/or growth. On the other hand, product pathways with a high ATP yield may result in excess biomass formation at the expense of the product yield. This mini-review discusses the importance of the ATP yield for product formation and presents several opportunities for engineering free-energy (ATP) conservation, with a focus on sugar-based product formation by Saccharomyces cerevisiae. These engineering opportunities are not limited to the metabolic flexibility within S. cerevisiae itself, but also expression of heterologous reactions will be taken into account. As such, the diversity in microbial sugar uptake and phosphorylation mechanisms, carboxylation reactions, product export, and the flexibility of oxidative phosphorylation via the respiratory chain and H+-ATP synthase can be used to increase or decrease free-energy (ATP) conservation. For product pathways with a negative, zero or too high ATP yield, analysis and metabolic engineering of the ATP yield of product formation will provide a promising strategy to increase the product yield and simplify process conditions." @default.
W2099456413 created "2016-06-24" @default.
W2099456413 creator A5019874774 @default.
W2099456413 creator A5087000945 @default.
W2099456413 creator A5088155093 @default.
W2099456413 creator A5088420553 @default.
W2099456413 date "2012-04-02" @default.
W2099456413 modified "2023-10-16" @default.
W2099456413 title "Energy coupling in Saccharomyces cerevisiae: selected opportunities for metabolic engineering" @default.
W2099456413 cites W1506245646 @default.
W2099456413 cites W1555985610 @default.
W2099456413 cites W1560272301 @default.
W2099456413 cites W1575852352 @default.
W2099456413 cites W1793938508 @default.
W2099456413 cites W1838774522 @default.
W2099456413 cites W1921304878 @default.
W2099456413 cites W1963779083 @default.
W2099456413 cites W1974004653 @default.
W2099456413 cites W1978119727 @default.
W2099456413 cites W1980393312 @default.
W2099456413 cites W1985620503 @default.
W2099456413 cites W1988884687 @default.
W2099456413 cites W1995786397 @default.
W2099456413 cites W1997006104 @default.
W2099456413 cites W2007614233 @default.
W2099456413 cites W2008141632 @default.
W2099456413 cites W2008270905 @default.
W2099456413 cites W2012259041 @default.
W2099456413 cites W2012755097 @default.
W2099456413 cites W2013056827 @default.
W2099456413 cites W2014258732 @default.
W2099456413 cites W2017207712 @default.
W2099456413 cites W2022741035 @default.
W2099456413 cites W2023939290 @default.
W2099456413 cites W2024893143 @default.
W2099456413 cites W2027670426 @default.
W2099456413 cites W2035314369 @default.
W2099456413 cites W2036545186 @default.
W2099456413 cites W2040755946 @default.
W2099456413 cites W2041946854 @default.
W2099456413 cites W2047150231 @default.
W2099456413 cites W2051907932 @default.
W2099456413 cites W2052495667 @default.
W2099456413 cites W2052618584 @default.
W2099456413 cites W2061510626 @default.
W2099456413 cites W2067866461 @default.
W2099456413 cites W2073224639 @default.
W2099456413 cites W2074739228 @default.
W2099456413 cites W2079266069 @default.
W2099456413 cites W2081124819 @default.
W2099456413 cites W2082055828 @default.
W2099456413 cites W2082172840 @default.
W2099456413 cites W2084529529 @default.
W2099456413 cites W2086271348 @default.
W2099456413 cites W2090359197 @default.
W2099456413 cites W2092438050 @default.
W2099456413 cites W2097588241 @default.
W2099456413 cites W2098613540 @default.
W2099456413 cites W2099185000 @default.
W2099456413 cites W2101442503 @default.
W2099456413 cites W2103349249 @default.
W2099456413 cites W2104212924 @default.
W2099456413 cites W2104400230 @default.
W2099456413 cites W2104758612 @default.
W2099456413 cites W2116734717 @default.
W2099456413 cites W2117372239 @default.
W2099456413 cites W2122577863 @default.
W2099456413 cites W2126359414 @default.
W2099456413 cites W2127270784 @default.
W2099456413 cites W2129264537 @default.
W2099456413 cites W2131708560 @default.
W2099456413 cites W2132832829 @default.
W2099456413 cites W2135998024 @default.
W2099456413 cites W2140400928 @default.
W2099456413 cites W2140593338 @default.
W2099456413 cites W2146497852 @default.
W2099456413 cites W2146805069 @default.
W2099456413 cites W2146952447 @default.
W2099456413 cites W2147454875 @default.
W2099456413 cites W2147853672 @default.
W2099456413 cites W2148179602 @default.
W2099456413 cites W2149202606 @default.
W2099456413 cites W2151618686 @default.
W2099456413 cites W2153560677 @default.
W2099456413 cites W2154202277 @default.
W2099456413 cites W2156846812 @default.
W2099456413 cites W2156847800 @default.
W2099456413 cites W2164029680 @default.
W2099456413 cites W2164895073 @default.
W2099456413 cites W2170430632 @default.
W2099456413 cites W2171885622 @default.
W2099456413 cites W2196776755 @default.
W2099456413 cites W2297853161 @default.
W2099456413 cites W3046397622 @default.
W2099456413 cites W4206867804 @default.
W2099456413 doi "https://doi.org/10.1111/j.1567-1364.2012.00799.x" @default.
W2099456413 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/22404754" @default.
W2099456413 hasPublicationYear "2012" @default.