Pal Maliga

The small, versatile pPZP family of Agrobacterium binary vectors for plant transformation

The newpPZP Agrobacterium binary vectors are versatile, relatively small, stable and are fully sequenced. The vectors utilize the pTiT37 T-DNA border regions, the pBR322bom site for mobilization fromEscherichia coli toAgrobacterium, and the ColE1 and pVS1 plasmid origins for replication inE. coli and inAgrobacterium, respectively. Bacterial marker genes in the vectors confer resistance to chloramphenicol (pPZP100 series) or spectinomycin (pPZP200 series), allowing their use inAgrobacterium strains with different drug resistance markers. Plant marker genes in the binary vectors confer resistance to kanamycin or to gentamycin, and are adjacent to the left border (LB) of the transferred region. A lacZ α-peptide, with the pUC18 multiple cloning site (MCS), lies between the plant marker gene and the right border (RB). Since the RB is transferred first, drug resistance is obtained only if the passenger gene is present in the transgenic plants.

The two RNA polymerases encoded by the nuclear and the plastid compartments transcribe distinct groups of genes in tobacco plastids

The plastid genome in photosynthetic higher plants encodes subunits of an Escherichia coli‐like RNA polymerase (PEP) which initiates transcription from E.coli σ70‐type promoters. We have previously established the existence of a second nuclear‐encoded plastid RNA polymerase (NEP) in photosynthetic higher plants. We report here that many plastid genes and operons have at least one promoter each for PEP and NEP (Class II transcription unit). However, a subset of plastid genes, including photosystem I and II genes, are transcribed from PEP promoters only (Class I genes), while in some instances (e.g. accD) genes are transcribed exclusively by NEP (Class III genes). Sequence alignment identified a 10 nucleotide NEP promoter consensus around the transcription initiation site. Distinct NEP and PEP promoters reported here provide a general mechanism for group‐specific gene expression through recognition by the two RNA polymerases.

Identification of a functional respiratory complex in chloroplasts through analysis of tobacco mutants containing disrupted plastid ndh genes

The plastid genomes of several plants contain homologues, termed ndh genes, of genes encoding subunits of the NADH:ubiquinone oxidoreductase or complex I of mitochondria and eubacteria. The functional significance of the Ndh proteins in higher plants is uncertain. We show here that tobacco chloroplasts contain a protein complex of 550 kDa consisting of at least three of the ndh gene products: NdhI, NdhJ and NdhK. We have constructed mutant tobacco plants with disrupted ndhC, ndhK and ndhJ plastid genes, indicating that the Ndh complex is dispensible for plant growth under optimal growth conditions. Chlorophyll fluorescence analysis shows that in vivo the Ndh complex catalyses the post‐illumination reduction of the plastoquinone pool and in the light optimizes the induction of photosynthesis under conditions of water stress. We conclude that the Ndh complex catalyses the reduction of the plastoquinone pool using stromal reductant and so acts as a respiratory complex. Overall, our data are compatible with the participation of the Ndh complex in cyclic electron flow around the photosystem I complex in the light and possibly in a chloroplast respiratory chain in the dark.

Progress towards commercialization of plastid transformation technology

Tobacco chloroplasts are ready to be tested as a platform for the expression of recombinant proteins on a commercial scale. They hold the promise of reproducible yields of 5-25% of total soluble cellular protein in leaves and reliability has been achieved through refinement of an expression toolkit that includes vectors, recently developed expression cassettes and systems for marker gene removal. Implementation of plastid transformation technology in other crops, however, has met with difficulty and has delayed agronomic applications.

Plastid transformation in arabidopsis thaliana

Abstract Plastid transformation is reported in Arabidopsis thaliana following biolistic delivery of transforming DNA into leaf cells. Transforming plasmid pGS31A carries a spectinomycin resistance (aadA) gene flanked by plastid DNA sequences to target its insertion between trnV and the rps12/7 operon. Integration of aadA by two homologous recombination events via the flanking ptDNA sequences and selective amplification of the transplastomes on spectinomycin medium yielded resistant cell lines and regenerated plants in which the plastid genome copies have been uniformly altered. The efficiency of plastid transformation was low: 2 in 201 bombarded leaf samples. None of the 98 plants regenerated from the two lines were fertile.

Kanamycin resistance as a selectable marker for plastid transformation in tobacco

We report on a novel chimeric gene that confers kanamycin resistance on tobacco plastids. The kan gene from the bacterial transposon Tn5, encoding neomycin phosphotransferase (NPTII), was placed under control of plastid expression signals and cloned between rbcL and ORF512 plastid gene sequences to target the insertion of the chimeric gene into the plastid genome. Transforming plasmid pTNH32 DNA was introduced into tobacco leaves by the biolistic procedure, and plastid transformants were selected by their resistance to 50 μg/ml of kanamycin monosulfate. The regenerated plants uniformly transmitted the transplastome to the maternal progeny. Resistant clones resulting from incorporation of the chimeric gene into the nuclear genome were also obtained. However, most of these could be eliminated by screening for resistance to high levels of kanamycin (500 μg/ml). Incorporation of kan into the plastid genome led to its amplification to a high copy number, about 10000 per leaf cell, and accumulation of NPTII to about 1% of total cellular protein.

Accumulation of D1 polypeptide in tobacco plastids is regulated via the untranslated region of the psbA mRNA.

The plastid psbA mRNA is present in all tissues, while the encoded 32 kDa D1 protein of photosystem II accumulates tissue‐specifically and in response to light. To study the regulation of D1 accumulation, a chimeric uidA gene encoding beta‐glucuronidase (GUS) under control of the psbA 5′‐ and 3′‐regulatory regions (224 and 393 bp, respectively), was integrated into the tobacco plastid genome. A high level of GUS accumulation in leaves and the lack of GUS in roots, with uidA mRNA present in both tissues, indicated tissue‐specific accumulation of the chimeric gene product. Light‐regulated accumulation of GUS in seedlings was shown. (i) Light‐induced accumulation (100‐fold) of GUS in etiolated cotyledons was accompanied by only a modest increase in mRNA levels. (ii) Inhibition of GUS synthesis was observed in cotyledons when light‐grown seedlings were transferred to the dark, with no reduction in mRNA levels. Tissue‐specific and light‐regulated accumulation of GUS indicates that D1 accumulation is controlled via cis‐acting regulatory elements in the untranslated region of the psbA mRNA. We propose that in tobacco, control of translation initiation is the primary mechanism regulating D1 protein accumulation.

Engineering the plastid genome of higher plants

The plastid genome of higher plants is an attractive target for engineering because it provides readily obtainable high protein levels, the feasibility of expressing multiple proteins from polycistronic mRNAs and gene containment through the lack of pollen transmission. A chloroplast-based expression system that is suitable for the commercial production of recombinant proteins in tobacco leaves has been developed recently. This expression system includes vectors, expression cassettes and site-specific recombinases for the selective elimination of marker genes. Progress in expressing proteins that are biomedically relevant, in engineering metabolic pathways, and in manipulating photosynthesis and agronomic traits is discussed, as are the problems of implementing the technology in crops.

CHLOROPLAST MRNA 3'-END PROCESSING BY A HIGH MOLECULAR WEIGHT PROTEIN COMPLEX IS REGULATED BY NUCLEAR ENCODED RNA BINDING PROTEINS

In the absence of efficient transcription termination correct 3′‐end processing is an essential step in the synthesis of stable chloroplast mRNAs in higher plants. We show here that 3′‐end processing in vitro involves endonucleolytic cleavage downstream from the mature terminus, followed by exonucleolytic processing to a stem‐loop within the 3′‐untranslated region. These processing steps require a high molecular weight complex that contains both endoribonucleases and an exoribonuclease. In the presence of ancillary RNA binding proteins the complex correctly processes the 3′‐end of precursor RNA. In the absence of these ancillary proteins 3′‐end maturation is prevented and plastid mRNAs are degraded. Based on these results we propose a novel mechanism for the regulation of mRNA 3′‐end processing and stability in chloroplasts.

The use of cytoplasmic streptomycin resistance: Chloroplast transfer from Nicotiana tabacum into Nicotiana sylvestris, and Isolation of their somatic hybrids

SummaryLeaf protoplasts of Nicotiana tabacum SR1 (2n=4x=48) treated with iodoacetate (10 mM; 25 C; 30 min) and consequently unable to divide, and untreated leaf protoplasts of Nicotiana sylvestris (2n=2x=24) were fused using polyethylene glycol (PEG). The SR1 line is resistant to streptomycin because of a maternally inherited mutation, and has streptomycin-insensitive chloroplast ribosomes.After 1 month of growth in the absence of streptomycin protoplast-derived calli were plated into selective medium (1,000 μg ml-1 streptomycin) and the resistant clones were isolated. Out of 106 PEG-treated protoplasts (1:1 mixture of parental types) 137 resistant (green) clones were obtained, whereas in the same number of parental cells, not subjected to fusion induction, no resistant callus was found.At least four plants were regenerated from each of the clones. The regenerates were identified as somatic hybrids (H), N. sylvestris (Ns) or N. tabacum (Nt) by looking at esterase and peroxidase isoenzymes and morphology. The three types of regenerates were distributed amongst the clones as follows: H only (105 clones); Ns (16 clones); Ns+H (6 clones); Nt only (3 clones); Nt+H (6 clones); Nt+Ns (1 clone). The high proportion of hybrid regenerates indicates that nuclear fusion has occured in the overwhelming majority of the heterokaryocytes. Cytoplasmic mutations in combination with inactivation by iodoacetate, therefore, are suitable markers to produce somatic hybrids. Segregation of nuclei after fusion resulted in new combinations of organelles and nuclei, the final outcome being the transfer of resistant chloroplasts into N. sylvestris, some of which have the original diploid (2n=24) chromosome number. Data suggest that segregants were in most cases obtained from multiple fusions. Streptomycin resistance was inherited maternally in the N. sylvestris (six clones) tested and the hybrid (three clones) regenerates.