Phosphate biological stability

In plant tissues two major forms of polyprenols are found, e.g. free alcohols and esters with fatty acids. In some species one form is highly dominating. Similarly in animal tissues dolichols and dolichyl esters were described, accompanied by usually small amounts of dolichyl phosphate. Biological role of this latter compound is well established. Dolichyl phosphate is involved as cofactor in biosynthesis of glycoproteins and GPI-anchored proteins [3]. Biological role of free alcohol and its acyl ester has not been defined yet. As the components of biological membranes these compounds modulate membrane properties. Dolichol increases fluidity and permeability and decreases the stability of model membranes [4]. Experiments with polyprenols point to the same direction polyprenols and polyprenyl phosphates increases the fluidity and permeability of model membranes [5], Both polyprenols and dolichols could also serve as a reserve isoprenoid pool utilized by corresponding kinases. 

Tu, A. J., Heller, M. J. Structure and Stability of Metal-Nucleoside Phosphate Complexes, in Metal Ions in Biological Systems Vol. 1 (ed. Sigel, H.), p. 1, Marcel Dekker, Inc. New York 1974... 

Zoungrana et al. (1997) and Norde and Zoungrana (1998) investigated the influence of adsorption on the structure, structure stability and biological activity of a proteolytic enzyme, a -chymotrypsin. The enzyme was adsorbed from 0.01 M phosphate buffer at pH 7.0 and at 22°C onto solid surfaces of different hydrophobicities and morphologies. 

The lower oxidation states are stabilized by soft ligands e.g. CO (Prob. 3). The aquated vanadium ions represent an interesting series of oxidation states. They are all stable with respect to disproportionation and labile towards substitution. They undergo a number of redox reactions with one another, all of which have been studied kinetically. Many of the reactions are [H ]-dependent. There has been recent interest in the biological aspects of vanadium since the discovery that vanadate can mimic phosphate and act as a potent inhibitor (Prob. 4). 

Equation 8.4 predicts that aerobic respiration should release dissolved inorganic nitrogen and phosphorus into seawater in the same ratio that is present in plankton, i.e., 16 1. As shown in Figure 8.3, a plot of nitrate versus phosphate for seawater taken from all depths through all the ocean basins has a slope close to 16 1. Why do both plankton and seawater have an N-to-P ratio of 16 1 Does the ratio in seawater determine the ratio in the plankton or vice versa Current thinking is that the N-to-P ratio of seawater reflects a quasi steady state that has been established and stabilized by the collective impacts of several biological processes controlled by marine plankton. 

A lot of biologic membrane systems and cellular organelles contain kinases, which transfer phosphate groups to proteins, especially to serine, threonine, and tyrosine residues. Self-phosphorylation of enzymes leading to acylphosphates or phosphoamides can be observed, too. With respect to their chemical stability, these phos-phoproteins are classified into acid-stable (alkali labile), hydroxyl-amine-sensitive, and acid labile. 

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