Range: Table - link mg/L
||Bacteria Escherichia coli
||Lendenmann U, Snozzi M, Egli T. Growth kinetics of Escherichia coli with galactose and several other sugars in carbon-limited chemostat culture. Can J Microbiol. 2000 Jan46(1):72-80. doi 10.1139/w99-113 p.79 table 6PubMed ID10696473
||Koch, A.L., and Wang, C.H. 1982. How close to the theoretical diffusion limit do bacterial uptake systems function. Arch. Microbiol. 131: 36–42.PubMed ID6279047
||p.79 caption to table 6(4):"Determined by measuring growth continuously in a 10-cm flow-through cuvette. The first experiment was carried out with batch- [µmax=1.23/h] and the second with chemostat-grown [µmax=0.54/h] cells."
||P.78 left column bottom paragraph:"A comparison of Ks values for individual sugars obtained here (Table 5) with published Michaelis–Menten parameters for uptake of these sugars (Km) or affinity constants for sugar-binding proteins (Kd) (Table 6) show little agreement. Km and Kd values for maltose transport systems were approximately three times higher than Ks for growth. In contrast, Km and Kd values for ribose were 3–5 times smaller than Ks. Only for growth with galactose a clear correlation between the measured Ks value and the high affinity Km and Kd values for the binding-protein system (Mgl) were observed. The range of published Km values for the low-affinity proton-driven galactose permease (GalP) is between 0.7 and 16 mg/L for wild type strains of E. coli (Table 6). For the high-affinity transport system (Mgl) the corresponding value is 0.09 mg/L (Table 6). The Ks value determined in this study for growing cells was similar to the published Km values of the high-affinity galactose transport system, which suggests that during growth in continuous culture, up to a dilution rate of approximately 0.7/h, the binding-protein transport system was mainly responsible for galactose uptake. Unfortunately, [investigators] are not aware of published kinetic data for the utilisation of fructose by E. coli." See notes beneath table