Conidial alkaline phosphatase from Neurospora crassa.

An alkaline phosphatase was purified from conidia of a Neurospora crassa wild type strain. The M(r) of the purified native enzyme was estimated as ca 145,000 and 110,000 by gel filtration, in the presence and absence of magnesium ions, respectively. A single polypeptide band of M(r) 36,000 was detected by SDS-PAGE, suggesting that the native enzyme was a tetramer of apparently identical subunits. Conidial alkaline phosphatase was an acidic protein (pl = 4.0 +/- 0.1), with 40% carbohydrate content. Optimal pH was affected by substrate concentration and magnesium ions. Low concentrations of calcium ions (0.1 mM) had slight stimulatory effects, but in excess (5 mM) caused protein aggregates with decreased activity. The enzyme specificity against different substrates was compared with those reported for constitutive or Pi-repressible alkaline phosphatases produced by N. crassa. The results suggested that the conidial alkaline phosphatase represented a different class among other such enzymes synthesized by this organism.

Alkaline phosphatase from rat osseous plates: purification and biochemical characterization of a soluble form.

A soluble form of an alkaline phosphatase obtained from rat osseous plates was purified 204-fold with a yield of 24.3%. The purified enzyme showed a single protein band of Mr 80,000 on SDS-PAGE and an apparent molecular weight of 163,000 by gel filtration on Sephacryl S-300 suggesting a dimeric structure for the soluble enzyme. The specific activity of the enzyme at pH 9.4 in the presence of 2 mM MgCl2 was 19,027 U/mg and the hydrolysis of p-nitrophenyl phosphate (K0.5 = 92 microM) showed positive cooperativity (n = 1.5). The purified enzyme showed a broad substrate specificity, however, ATP, bis(p-nitrophenyl) phosphate and pyrophosphate were among the less hydrolyzed substrates assayed. Surprisingly the enzyme was not stimulated by cobalt and manganese ions, in contrast with a 20-25% stimulation observed for magnesium and calcium ions. Zinc ions exerted a strong inhibition on p-nitrophenylphosphatase activity of the enzyme. This paper provides a simple experimental procedure for the isolation of a soluble form of alkaline phosphatase which is induced by demineralized bone matrix during endochondral ossification.

Further evidence of dimer-tetramer transition in hemoglobin from Liophis miliaris.

Liophis miliaris hemoglobins in the stripped form exhibit a high oxygen affinity, a small alkaline Bohr effect, a pronounced organic polyphosphate effect and a pH-dependent Hill coefficient, close to 2 below pH 7.5 and near 1 at higher pHs. Molecular weight determinations indicate 2 forms, a dimeric form of MW 32000 d. and a tetrameric form of about 64000 d. The deoxyhemoglobin is tetrameric. Ion-exchange chromatography shows two components which may bind to each other being eluted as a single component of MW 32000 d. The oxygen alkaline Bohr effect observed for the stripped hemoglobin may be explained by the transition from the tetramer to the dimer during oxygen addition experiments. The phenomenon appears to be unique among animals. beta-Chain sequencing determinations show that abnormal human hemoglobin with similar properties has a glutamic acid residue substituted at the alpha 1-beta 2 interface by valine in snake hemoglobin.

Further evidence of dimer-tetramer transition in hemoglobin from Liophis miliaris

Liophis miliaris hemoglobins in the stripped form exhibit a high oxigen affinity, a small alkaline Bohr effect, a pronounce organic polyphosphate effect and a pH-dependent Hill coefficient, close to 2 below pH 7.5 and near 1 at higher pHs. Molecular weight determinations indicate 2 forms, a dimeric form of MW 32000 d. and a tetrameric form of about 64000 d. The deoxyhemoglobin is tetrameric. Ion-exchange chromatography shows two components which may bind to each other being eluted as a single component of MW 32000 d. The osygen alkaline Bohr effect observed for the stripped hemoglobin may be explained by the transition from the tetramer to the dimer during oxygen addition experiments. The phenomenon appears to be unique among animals. ß-Chain sequencing determinations show that abnormal human hemoglobin with similar properties has a glutamic acid residue substituted at the alfa1-ß2 interface by valine in snake hemoglobin