Maize contains a Lon protease gene that can partially complement a yeast pim1-deletion mutant.

We have identified a gene in maize that encodes a product belonging to the Lon protease family. In yeast and mammals, Lon-type proteases catalyze the ATP-dependent degradation of mitochondrial matrix proteins. The maize gene, which we have designated LON1, is predicted to encode a protein with a molecular mass of 97.7 kDa. Lon1p is more similar in sequence to bacterial Lon proteases than to the yeast and human mitochondrial Lon proteases. LON1 transcripts are present in shoots of 4-day-old etiolated maize seedlings, and transcript levels decrease when these seedlings are heat-shocked. LON1 transcripts are also present at comparable levels in leaves and roots of 2-week-old greenhouse-grown seedlings. In yeast, the mitochondrial Lon-type protease, Pim1p, has been implicated in mitochondrial protein turnover, the assembly of mitochondrial enzyme complexes, and mitochondrial DNA maintenance, and it is essential for respiratory function. We show that maize Lon1p can replace the Pim1p function in yeast for maintaining mitochondrial DNA integrity, but not in the assembly of cytochrome a x a3 complexes.

Architecture of the maize mitochondrial atp1 promoter as determined by linker-scanning and point mutagenesis.

Plant mitochondrial promoters are poorly conserved but generally share a loose consensus sequence spanning approximately 17 nucleotides. Using a homologous in vitro transcription system, we have previously shown that an 11-nucleotide sequence within this region comprises at least part of the maize mitochondrial atp1 promoter (W. Rapp and D. Stern, EMBO J. 11:1065-1073, 1992). We have extended this finding by using a series of linker-scanning and point mutations to define the atp1 promoter in detail. Our results show that mutations at positions -12 to +5, relative to the major transcription start site, can decrease initiation rates to between < 10 and 40% of wild-type levels. Some mutations, scattered throughout this region, have lesser effects or no effect. Taken together, our data suggest a model in which the atp1 promoter consists of a central domain extending from -7 to +5 and an upstream domain of 1 to 3 bp that is centered around -11 to -12. Because many mutations within this promoter region are tolerated in vitro, the maize atp1 promoter is distinct from the highly conserved yeast mitochondrial promoters.

A conserved 11 nucleotide sequence contains an essential promoter element of the maize mitochondrial atp1 gene.

To determine the structure of a functional plant mitochondrial promoter, we have partially purified an RNA polymerase activity that correctly initiates transcription at the maize mitochondrial atp1 promoter in vitro. Using a series of 5' deletion constructs, we found that essential sequences are located within--19 nucleotides (nt) of the transcription initiation site. The region surrounding the initiation site includes conserved sequence motifs previously proposed to be maize mitochondrial promoter elements. Deletion of a conserved 11 nt sequence showed that it is critical for promoter function, but deletion or alteration of conserved upstream G(A/T)3-4 repeats had no effect. When the atp1 11 nt sequence was inserted into different plasmids lacking mitochondrial promoter activity, transcription was only observed for one of these constructs. We infer from these data that the functional promoter extends beyond this motif, most likely in the 5' direction. The maize mitochondrial cox3 and atp6 promoters also direct transcription initiation in this in vitro system, suggesting that it may be widely applicable for studies of mitochondrial transcription in this species.

Characterization of soybean vegetative storage proteins and genes.

Soybean vegetative storage proteins (VSPs) were purified and characterized. Anion exchange HPLC resolved partially purified VSPs into fractions containing 27-kD/27-kD and 29-kD/29-kD homodimers and 27-kD/29-kD heterodimers. Reversed-phase HPLC resolved partially purified VSPs into three fractions. One fraction contained only 27-kD VSP and the other two contained 29-kD VSP. The two 29-kD VSP fractions differed with respect to their cyanogen bromide cleavage patterns, an observation that indicated the 29-kD VSPs were heterogeneous. Genomic clones that contained 29-kD VSP genes were also isolated and characterized. One genomic clone contained a complete 29-kD VSP gene and was sequenced. The coding region in the clone contained two introns whose borders had regulatory sequences typical of other eukaryotic genes. Putative polyadenlyation signals were present in the 3'-flanking region of the gene, while putative TATA, CAAT, and enhancer core sequences were found in the 5'-flanking regions. A second genomic clone that was studied contained the 5' regions of two partial 29-kD VSP genes in an inverted linkage. Genomic DNA gel blots showed that the two genes were organized in the same arrangement in the soybean genome.

Escherichia coli K12 mutants defective in the glycine cleavage enzyme system.

Two routes of one-carbon biosynthesis have been described in Escherichia coli K12. One is from serine via the serine hydroxymethyltransferase (SHMT) reaction, and the other is from glycine via the glycine cleavage (GCV) enzyme system. To isolate mutants deficient in the GCV pathway, we used a selection procedure that is based on the assumption that loss of this enzyme system in strains blocked in serine biosynthesis results in their inability to use glycine as a serine source. Mutants were accordingly isolated that grow with a serine supplement, but not with a glycine supplement. Enzyme assays demonstrated that three independently isolated mutants have no detectable GCV enzyme activity. The absence of a functional GCV pathway results in the excretion of glycine, but has no affect on the cell's primary source of one-carbon units, the SHMT reaction. The new mutations, designated gcv, were mapped between the serA and lysA genes on the E. coli chromosome.