RNase Activities Are Reduced Concomitantly with Conservation of Total Cellular RNA and Ribosomes in O2-Deprived Seedling Roots of Maize.

The effect of O2 deprivation on the activities of RNases and levels of total cellular RNA and ribosomes in seedling roots of maize (Zea mays L.) was investigated. Sodium dodecyl sulfate-polyacrylamide gels containing RNA were used to distinguish RNase isoenzymes by apparent molecular mass. Since O2 deprivation causes a decrease in cytosolic pH from approximately pH 7.4 to 6.4 and an elevation in cytosolic Ca2+, RNase levels were examined in the physiological range of cytosolic pH and in the presence of Ca2+, Mg2+, Zn2+, ethylenediaminetetracetate, or ethyleneglycol-bis([beta]-aminoethyl ether)-N,N[prime]-tetraacetic acid. The activity of a number of RNases present in aerobic roots was reduced in response to O2 deprivation. Several RNases with a pH optimum of 6.4 were rapidly down-regulated by O2 deprivation. Spectrophotometric assay of extracts revealed that RNase activity was higher at pH 6.4 than at 7.2, and ethylenediaminetetracetate-insensitive RNase activity decreased in response to O2 deprivation. The decrease in RNase activity was correlated with no loss of total cellular RNA or ribosomes, despite a 4-fold decrease in run-on transcription of rRNA in isolated nuclei. Regulation of RNase activity may facilitate the conservation of nontranslating ribosomes and poorly translated mRNAs during O2 deprivation.

Synonymous codon usage in Zea mays L. nuclear genes is varied by levels of C and G-ending codons.

A multivariate statistical method called correspondence analysis was used to examine the codon usage of one-hundred-and-one nuclear genes of maize (Zea mays L.). Forty percent of the variation in codon usage was due to bias toward G or C-ending versus A or U-ending codons. Differences in levels of G-ending codons showed the weakest correlation with the major codon usage bias. The bias toward C or U versus A or G in the silent third nucleotide position of synonymous codons accounted for approximately 10% of the variation in codon usage. The G+C content of the silent third nucleotide position of coding regions was not strongly correlated with G+C content of introns. Codon usage was strongly biased toward codons ending in G or C for a number of highly expressed genes including most light-regulated chloroplast proteins, ABA-induced proteins, histones, and anthocyanin biosynthetic enzymes. Codon usage of genes encoding storage proteins and regulatory proteins, such as transposases, kinases, phosphatases and transcription factors, was more random than that of genes encoding cytosolic enzymes with similar bias toward G or C-ending codons. Codon usage in maize may reflect both regional bias on nucleotide composition and selection on the silent third nucleotide position.