Iron-regulated ferritin synthesis in animals is dominated by translational control of stored mRNA; ironinduced transcription of ferritin genes, when it occurs, changes the subunit composition of ferritin mRNA and protein and is coupled to translational control. Ferritins in plants and animals have evolved from a common progenitor, based on the simi-
Phytase (myo-inositol-hexakisphosphate phosphohydrolase, EC 3.1.3.8) has been purified from 5-7-day-old maize (Zea mays) seedlings, using a four-step purification procedure. The native protein has a molecular mass of about 76 kDa and is built up from two 38 kDa subunits. The pH and temperature optima of the purified enzyme were respectively 4.8 and 55 degrees C. The apparent Km for phytate was estimated to be 117 microM. Like other acidic phytases, the maize seedling enzyme exhibited a broad affinity for various phosphorylated substrates and especially for penta- and tri-phosphate esters of myo-inositol. The amino acid composition of the h.p.l.c.-purified protein indicated a high hydrophobicity (44% non-polar amino acids). Rabbit antibodies were produced in response to maize seedling phytase. Western-blot analyses clearly demonstrate that the increase of phytase activity observed during the first 7 days of germination corresponded to an accumulation of the protein in maize seedlings. Phytase accumulated essentially in the shoots (mesocotyl plus coleoptiles.
In animal cells specialized for iron storage, iron-induced accumulation of ferritin is known to result from a shift of stored mRNA from the ribonucleoprotein fraction to polysomes. Previous reports with bean leaves suggested that in plants iron induction of ferritin synthesis would result from a regulation at the transcriptional level (F van der Mark, F Bienfait, H van der Ende cultures, the mechanism of regulation of ferritin synthesis in response to iron does not result from recruitment of preexisfing mRNA. They confirm that in plant systems, ferritin synthesis results from increased transcription of the corresponding genes.
During germination, maize seedlings express a phytase able to hydrolyse the large amount of phytin stored in the dry seed. Previous studies allowed purification and characterization of this enzyme as a homodimer of 38 kDa subunits [Laboure, Gagnon and Lescure, Biochem. J. (1993) 295, 413-419]. In the present work, an antibody against the purified maize phytase has been used to screen a maize seedling cDNA expression library. Several positive clones containing an insert of about 1400 bp were isolated. The nucleotide sequence of the insert of one of these clones has been established. This cDNA, called phy S11, was 1335 bp long and contained an open reading frame of 387 amino acids. The sequence of N-terminal residues (23 amino acids) of the purified phytase has been established. These residues are found at positions 19-41 of the amino acid sequence encoded by phy S11. This confirms that this cDNA codes for the maize phytase. The deduced amino acid sequence appears to be very different from those of published Aspergillus niger phytases; however, an homologous region of 33 amino acids was detected. This region of the fungal sequence contains the RHGxRxP consensus motif found in various high molecular mass acid phosphatases and believed to be the acceptor site for phosphate. Expression of the phy S11 cDNA in Escherichia coli allowed the production of the phytase subunit and its assembly to give a protein of the same size as the native phytase. The time course of phy S11 mRNA accumulation during germination showed that no transcript was present in dry seeds. The mRNA accumulated during the first day of germination, to reach a maximum after 2 days (radicle protrusion), and then decreased in young seedlings. Genomic Southern blot analyses suggest the existence of at least two genes and genetic mapping reveals two loci separated by 1 cM on chromosome 3 of maize. The cloning of this first cDNA coding for a plant phytase, will allow the isolation of the corresponding genes and the study of their regulation during germination.
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