Life in the Open Ocean. Joseph J. Torres

Life in the Open Ocean - Joseph J. Torres


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indistinguishable from those of the northern temperate species S. argentea. Error bars represent standard deviations. Each point represents an average of Km values determined with at least three different purified LDH preparations from different individuals of each species. Solid portions of the lines connecting the Km values indicate habitat temperature ranges of the species.

      Source: Graves and Somero (1982), figure 3 (p. 103). Reproduced with the permission of John Wiley & Sons, Inc.

      Source: Graves and Somero (1982), table 5 (p. 104). Reproduced with the permission of John Wiley & Sons, Inc.

S. argentea S. lucasana S. ensis
Km of pyruvate at 25 °C 0.34 ± 0.03 mM 0.26 ± 0.02 mM 0.20 ± 0.02 mM
Kcat at 25 °C 893 ± 54 s−1 730 ± 37 s−1 658 ± 19 s−1
Temp. midrange (TM) 18 °C 23 °C 26 °C
Km of pyruvate at TM 0.24 mM 0.24 mM 0.23 mM
Kcat at TM 667 s−1 682 s−1 700 s−1

      What Properties of Enzymes Can Be Changed?

      Curve A has a low Km value; it will always be at or near Vmax. Any need for an increase in activity to support increased metabolic demand cannot be met; the enzyme is already at maximum. A low Km is a fine strategy for an enzyme that does not need to be regulated, such as a digestive enzyme, which is best always functioning at maximum velocity. However, for an enzyme involved in metabolism, which varies from a resting to a highly active state, such a curve would be disastrous. Increases in substrate concentration would not affect its activity, and it would be unable to be regulated. Conversely, a high Km such as that in curve C will have a considerable amount of “reserve capacity” to allow for regulation but will never achieve high velocity and could become a “choke point” for accumulation of metabolites. An enzyme having an intermediate Km, curve B, not only has a substantial fraction of its Vmax at cellular concentrations of substrate but also has considerable ability to respond to increases in substrate concentration before it reaches Vmax. Conclusion: for optimal performance, the enzyme properties and the substrate concentrations available to the enzyme must be complementary.

Schematic illustration of michaelis–Menten saturation kinetics: three types of relationships between reaction velocity and substrate concentration. Schematic illustration of effects of assay temperature on the apparent Michaelis constant of pyruvate (KmPYR) for A4-LDH orthologs.
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