Chloroplast ribosomal protein L32 is encoded in the chloroplast genome

Identification of eukaryotic peptide deformylases reveals universality of N-terminal protein processing mechanisms

The N-terminal protein processing pathway is an essential mechanism found in all organisms. However, it is widely believed that deformylase, a key enzyme involved in this process in bacteria, does not exist in eukaryotes, thus making it a target for antibacterial agents such as actinonin. In an attempt to define this process in higher eukaryotes we have used Arabidopsis thaliana as a model organism. Two deformylase cDNAs, the first identified in any eukaryotic system, and six distinct methionine aminopeptidase cDNAs were cloned. The corresponding proteins were characterized in vivo and in vitro. Methionine aminopeptidases were found in the cytoplasm and in the organelles, while deformylases were localized in the organelles only. Our work shows that higher plants have a much more complex machinery for methionine removal than previously suspected. We were also able to identify deformylase homologues from several animals and clone the corresponding cDNA from human cells. Our data provide the first evidence that lower and higher eukaryotes, as well as bacteria, share a similar N-terminal protein processing machinery, indicating universality of this system.

A ribosomal protein gene (rpl32) from tobacco chloroplast DNA is transcribed from alternative promoters: similarities in promoter region organization in plastid housekeeping genes

Multiple transcriptional start sites have been identified in the tobacco plastid ribosomal protein gene rpl32 by RNA mapping and in vitro capping techniques. A promotor with a canonical -10 Pribnow Box (P1) produces a major transcript in leaf chloroplasts. Transcription is also driven from additional promoters in non-photosynthetic plastids from heterotrophically cultured cells (BY2 line). Among them, a second promoter located downstream (P2) generates the most prominent transcript in this type of cell. The absence of typical plastid promoter motifs upstream of this site and the higher steady-state level of the P2-derived transcript in BY2 cells suggest a distinct modulation of transcription. Mobility shift experiments also seem to indicate the existence of differences in protein-DNA binding between both kinds of plastids with respect to a DNA fragment including the sequence upstream from the P2 starting site. The structure of the rpl32 promoter region is discussed in relation to that of other plastid housekeeping genes encoding elements of the genetic machinery.

Nucleotide sequence of maize chloroplast rpl32: completing the apparent set of plastid ribosomal protein genes and their tentative operon organization

By sequencing the rpl32 gene, we have characterized the apparent complete set of the RP genes in Zea mays plastid genome. Key data for these 21 genes (total of 26 gene copies) and the proteins encoded by them are presented, and the operon organization is discussed on the basis of available transcription data. A nomenclature for the inferred 13 operons is suggested.

Purification and characterization of seven chloroplast ribosomal proteins: evidence that organelle ribosomal protein genes are functional and that NH2-terminal processing occurs via multiple pathways in chloroplasts

Putative genes for 21 ribosomal proteins (RPs) have been identified in the chloroplast DNA of four plants by nucleotide sequencing and homology comparison but few of the gene products have been characterized. Here we report the purification and N-terminal sequencing of seven proteins from the spinach chloroplast ribosome. The data show them to be the homologues of Escherichia coli RPs L20, L32, L33, L36, S12, S16 and S19, and thus support the view that their genes identified in the chloroplast DNA represent functional genes. The initiating methionine residue was not detected in the mature protein in most cases but it was present in S16, indicating that only the formyl group is removed in this case. This result and the previously reported finding of N-methyl alanine at the N-terminus of chloroplast L2 indicate the existence of multiple N-terminal processing pathways in the chloroplast.

Rapid evolution of the plastid translational apparatus in a nonphotosynthetic plant: loss or accelerated sequence evolution of tRNA and ribosomal protein genes

The vestigial plastid genome of Epifagus virginiana (beechdrops), a nonphotosynthetic parasitic flowering plant, is functional but lacks six ribosomal protein and 13 tRNA genes found in the chloroplast DNAs of photosynthetic flowering plants. Import of nuclear gene products is hypothesized to compensate for many of these losses. Codon usage and amino acid usage patterns in Epifagus plastic genes have not been affected by the tRNA gene losses, though a small shift in the base composition of the whole genome (toward A+T-richness) is apparent. The ribosomal protein and tRNA genes that remain have had a high rate of molecular evolution, perhaps due to relaxation of constraints on the translational apparatus. Despite the compactness and extensive gene loss, one translational gene (infA, encoding initiation factor 1) that is a pseudogene in tobacco has been maintained intact in Epifagus.

Tobacco chloroplast ribosomes contain a homologue of E. coli ribosomal protein L28

The genes for ribosomal proteins L28 and L33 constitute an operon (rpmBG) in E. coli, but in plant chloroplasts L33 is encoded by the chloroplast DNA and L28 seems to be encoded by the nuclear genome. A 15 kDa protein was isolated from the 50 S subunit of tobacco chloroplast ribosomes and its N-terminal amino acid sequence was determined. A cDNA for this protein was cloned and analyzed. The cDNA encodes a 151 amino acid protein consisting of a predicted transit-peptide of 74 amino acids and a mature protein of 77 amino acids. The mature protein is homologous to E. coli L28, hence we named it chloroplast L28 (CL28). This is the first report on the presence of an E. coli L28-like protein in another organism.

Nuclear-encoded chloroplast ribosomal protein L27 of Nicotiana tabacum: cDNA sequence and analysis of mRNA and genes

A tobacco (Nicotiana tabacum cv. Petite Havana) leaf cDNA library was constructed in the expression vector lambda gt11. Immunological and nucleic acid hybridization screening yielded several cDNAs encoding an M(r) 19,641 precursor to an M(r) 14,420 mature protein which is homologous to Escherichia coli ribosomal protein L27. One cDNA (L27-1; 882 nucleotides long) contains 104 bp of 5'-noncoding sequence, 51 codons for a transit peptide, 128 codons for the predicted mature L27 polypeptide, and 241 bp of 3'-noncoding sequence, including the poly(A)29 tail. A beta-galactosidase-L27 fusion protein was bound to nitrocellulose filters, expressed, and used as an affinity matrix to purify monospecific antibody to L27 protein from an antiserum of rabbits immunized with 50S chloroplast ribosomal proteins. Using this monospecific antibody, protein L27 was identified among HPLC-purified tobacco chloroplast ribosome 50S subunit proteins. The predicted amino terminus of the mature L27 protein was confirmed by partial sequencing of the HPLC-purified L27 protein. The mature L27 protein has 66%, 61%, 56%, and 48% amino acid sequence identity with the L27-type ribosomal proteins of Bacillus subtilis, E. coli, Bacillus stearo-thermophilus, and yeast mitochondria (MRP7), respectively, in the homologous overlapping regions. The transit peptide of tobacco chloroplast ribosomal protein L27 has 41% amino acid sequence similarity with the MRP7 mitochondrial targeting sequence. Tobacco chloroplast L27 protein also has a 40 amino acid long carboxyl-terminal extension (compared to its bacterial counterparts) which is similar to the corresponding portion of yeast MRP7.(ABSTRACT TRUNCATED AT 250 WORDS)

Combination of in vitro capping and ribonuclease protection improves the detection of transcription start sites in chloroplasts

A primary transcript from the chloroplast rpl32 gene was labelled at its 5' end using a capping enzyme and [alpha-32P]GTP followed by hybridization to a cold RNA probe. A RNase protection assay gave a clear protected band and its initiation site of transcription could thus be estimated, which had not been possible by using DNA probes. The combination of in vitro capping and RNase protection is an excellent method for mapping transcription initiation sites on the chloroplast genome and shows a high improvement relative to the DNA-employing strategies.

Active transcription from a promoter positioned within the coding region of a divergently oriented gene: the tobacco chloroplast rpl32 gene

A new transcription unit has been identified and characterized in the small single-copy region of tobacco chloroplast DNA. A primary transcript (1550 nucleotides) spanning the entire transcription unit contains no significant open reading frames (ORFs), other than ORF55, recently identified as the gene encoding the ribosomal protein CL32 (rpl32). The leader sequence extends 1101 nucleotides from the rpl32 initiation codon. Primer extension and in vitro capping experiments in combination with ribonuclease protection assays, revealed a promoter situated more than 322 bp inside the coding region of ndhF, which is divergently oriented with respect to rpl32. A canonical Pribnow-box is found just upstream of the transcription start site, but a typical -35 motif was not detected. This is the first internal divergent promoter to be characterized in the chloroplast genome.

Nuclear-encoded chloroplast ribosomal protein L12 of Nicotiana tabacum: characterization of mature protein and isolation and sequence analysis of cDNA clones encoding its cytoplasmic precursor

Poly(A)+ mRNA isolated from Nicotiana tabacum (cv. Petite Havana) leaves was used to prepare a cDNA library in the expression vector lambda gt11. Recombinant phage containing cDNAs coding for chloroplast ribosomal protein L12 were identified and sequenced. Mature tobacco L12 protein has 44% amino acid identity with ribosomal protein L7/L12 of Escherichia coli. The longest L12 cDNA (733 nucleotides) codes for a 13,823 molecular weight polypeptide with a transit peptide of 53 amino acids and a mature protein of 133 amino acids. The transit peptide and mature protein share 43% and 79% amino acid identity, respectively, with corresponding regions of spinach chloroplast ribosomal protein L12. The predicted amino terminus of the mature protein was confirmed by partial sequence analysis of HPLC-purified tobacco chloroplast ribosomal protein L12. A single L12 mRNA of about 0.8 kb was detected by hybridization of L12 cDNA to poly(A)+ and total leaf RNA. Hybridization patterns of restriction fragments of tobacco genomic DNA probed with the L12 cDNA suggested the existence of more than one gene for ribosomal protein L12. Characterization of a second cDNA with an identical L12 coding sequence but a different 3'-noncoding sequence provided evidence that at least two L12 genes are expressed in tobacco.

Small single-copy region of plastid DNA in the non-photosynthetic angiosperm Epifagus virginiana contains only two genes. Differences among dicots, monocots and bryophytes in gene organization at a non-bioenergetic locus

We have determined the nucleotide sequence of a 7 kb (1 kb = 10(3) base-pairs) region that includes the entire small single-copy region (SSC) of the plastid genome of Epifagus virginiana, a non-photosynthetic, parasitic flowering plant. The SSC (4.8 kb) is considerably smaller than those of photosynthetic plants due to the complete deletion of all photosynthetic, chlororespiratory and ribosomal protein genes. This leaves only two genes: a protein gene of 1738 codons whose product is unlikely to be involved in bioenergetic processes and a leucine tRNA gene (trn(LUAG)). Both genes span junctions between the inverted repeat and the SSC, with the consequence that the terminal 20 base-pairs of the repeat is transcribed in both directions and functions both as the 3' end of the tRNA gene and as an internal segment of orf1738. We find that the region of tobacco plastid DNA homologous to Epifagus orf1738 contains a single open reading frame (ORF) of 1901 codons rather than the three ORFs of 1244, 273 and 228 codons originally reported. However, we confirm that the equivalent region of the bryophyte Marchantia contains two genes (1068 and 464 codons) corresponding to the N and C-terminal portions of the dicot protein. In contrast, rice plastid DNA contains a severely truncated pseudogene at this locus.

Ins and outs of plastid genome evolution

Recent findings have established cracks in the straight-laced image of the plastid genome as a molecule whose sole function is photosynthesis and whose gene content is highly conserved. Genes for numerous non-photosynthetic functions have been identified. Algal plastid genomes contain many genes with no homologs in angiosperms, and the recent transfer of genes from the plastid to the nuclear genome has been described. Wholesale abandonment of genes encoding photosynthetic and gene-expression functions has occurred in the plastid genomes of a non-green plant and alga. The origins of plastid DNA, its use in phylogenetic studies, and the origins of plastid introns are also reviewed.

The chloroplast gene for ribosomal protein CL23 is functional in tobacco

Chloroplast rpl23 loci potentially coding for a polypeptide homologous to the E. coli L23 ribosomal protein are frame-shifted in spinach and several other plants, indicating that these loci are pseudogenes. In tobacco, rpl23 constitutes a continuous open reading frame of 93 codons and its transcript initiates at least 66 bp upstream from the initiation codon. The N-terminal amino acid sequence of a 13 kDa protein from the 50 S subunit of tobacco chloroplast ribosomes matches that derived from the tobacco rpl23 locus. This shows that rpl23 is a functional gene in tobacco.