Low and high temperature asymmetric forms of pig kidney and rabbit muscle phosphofructokinases and reversible, temperature-dependent transitions.

Previous viscometric studies from this laboratory (Johnson, C. S., Vogtmann, L., and Deal, W. C., Jr. (1976) Biochem. Biophys. Res. Commun.73, 391–395) have shown that at 3.5 ° C, pig kidney phosphofructokinase (PFK) is markedly asymmetric and rabbit muscle PFK is moderately asymmetric. The present viscometric and ultracentrifugal studies show that both enzymes are also asymmetric at near-physiological temperatures, that both exist in high-temperature and low-temperature forms, and that the high-temperature forms of both are less asymmetric and more dissociated than the low-temperature forms. The risults also show that the transitions from low- to high-temperature forms are reversible if the exposure to 35 °C is short enough that no irreversible chemical modification occurs. For pig kidney PFK, intrinsic viscosity values of 34.0, 25.6, and 13.8 ml/g were obtained at 3.5, 20 and 35 °C, respectively, whereas rabbit muscle PFK yielded values of 6.9, 6.2, and 5.2 ml/g at the corresponding temperatures. These data clearly show a decrease in asymmetry with increase in temperature. However, both enzymes are still asymmetric at the higher temperature, inasmuch as most globular macromolecules have intrinsic viscosity values in the range of 3 to 4 ml/g, regardless of molekular weight. Studies from 1 to 45 ° C at a fixed protein concentration (4.8 mg/ml) showed that pig kidney PFK has reduced viscosity values of 51.0 ml/g (low-temperature form) and 20.4 ml/g (high-temperature form) in plateau regions of the viscosity graph at the temperature extremes; the mid-point of the transition between the two forms is at about 22–24 °C. Rabbit muscle PFK at 4.2 mg/ml reproducibly gave corresponding reduced viscosity values of 6.9 and 4.8 ml/g for the low- and high-temperature forms, respectively; the transition mid-point between the two forms is at about 16 °C. The first reported sedimentation velocity studies of rabbit muscle PFK at near-physiological temperature (35 °C) show that with near-physiological protein concentration (1.25 mg/ml), the enzyme is in a much more dissociated form, s_20,w(weight average) = 14. 5 S; s_20,w(peak leading edge) = 17 S, than that previously reported at lower temperatures, s_20,w(fastest peak) = 23–30 S. Similarly, the first sedimentation studies on the pig kidney enzyme indicate a lower sedimentation coefficient at 35 ° C (s^0.39%_20,w = 48 S) than at 3.5 ° C(65 S).     

Evidence for diet partitioning among three coexisting native freshwater fishes in South Africa's Cape Fold Ecoregion

The partitioning of limited resources commonly explains how different species can coexist within the same ecological community. In this 2010 study, the diets of three coexisting freshwater fishes (Cape galaxias Galaxias zebratus, n = 27; Cape kurper Sandelia capensis, n = 60; Breede River redfin Pseudobarbus burchelli, n = 77) were characterised and compared in three headwater streams in South Africa's Cape Fold Ecoregion using gut contents and stable isotope analyses. These data were analysed to ascertain whether the three species exploit distinct trophic niches. Both approaches provided evidence that these species occupy different trophic niches, though with some overlap. However, dietary differences among sites were not consistent and were probably influenced by site-specific factors like resource availability. Pseudobarbus burchelli had a broader niche breadth at Tierkloof Stream than the other two species, but not at Waaihoek or Tierstel Streams. Our results also suggest that P. burchelli consumed a more omnivorous diet than do the other two species, whereas S. capensis occupied a higher trophic position than the other two species and consumed vertebrates. Our findings suggest that these species occupy non-equivalent feeding niches in Cape Fold Ecoregion headwater streams, and that diet partitioning might facilitate their coexistence in these systems.     

Syntheses and β‐adrenergic binding affinities of (R)‐ and (S)‐fluoronaphthyloxypropanolamines

The β‐adrenergic receptors mediate several physiological processes including heart rate (β₁), bronchodilation (β₂), and lipolysis (β₃). Therefore, selectivity is important for a possible therapeutic agent acting via these receptors. Aryloxypropanolamines are β‐receptor agonists or antagonists, depending on the aryl group and its substituents. We therefore hypothesized that fluorine substitution on the aromatic ring in this class could lead to significant biological effects because of the unique chemical characteristics of fluorine. Because the target compound has a chiral center, we set out to synthesize the two enantiomers so that effects of stereochemistry on biological activity could be evaluated. Syntheses of the enantiomers were performed starting with commercially available fluoronaphthalene and subsequent use of the chiral synthon (2R)‐ or (2S)‐glycidyl 3‐nitrobenzenesulfonate, depending on the desired enantiomer. High‐pressure liquid chromatography (HPLC) methods were used to characterize %ee. Each enantiomer was synthesized. They exhibited nanomolar binding activities on β‐adrenergic receptors. The (S)‐enantiomer was found to be up to 310 times more potent than the (R). It was also found to be about five‐fold more selective for β₂‐ than for β₁‐receptors. The current report demonstrates the importance of stereochemistry for the fluoroaromatic β‐receptor ligands. Chirality 11:144–148, 1999. © 1999 Wiley‐Liss, Inc.