Maize high chlorophyll fluorescent 60 mutation is caused by an Ac disruption of the gene encoding the chloroplast ribosomal small subunit protein 17.

The maize mutation high chlorophyll fluorescence 60-muTable 1 (hcf60-m1), generated through Activator (Ac) tagging, has insufficient photosynthetic electron transport. Here we show that the Hcf60 gene encodes a protein with substantial amino acid similarity to plant plastid and bacterial ribosomal small subunit protein 17 (RPS17) proteins. The lack of detectable HCF60 transcripts in mutant leaves, and insertion of the transposed Ac element 17 bp upstream of the start of translation in the mutated locus, suggest that little if any RPS17 is produced. The mutant phenotype is consistent with reduced plastid translation. Seedling lethal hcf60-m1 plants display temperature and light-dependent chlorophyll deficiencies, a depletion of plastid rRNA pools, and few high-molecular-weight polysomal complexes. Growth under moderate light conditions (27 degrees C, 100 microE m-2 sec-1) allows for substantial chlorophyll accumulation in mutant leaves, yet the number of functional photosystem II complexes appears low. Nevertheless, the presence of a limited but intact C4 system indicates that some plastid translation occurs.

BUNDLE SHEATH DEFECTIVE2, a novel protein required for post-translational regulation of the rbcL gene of maize.

The Bundle sheath defective2 (Bsd2) gene is required for ribulose-1, 5-bisphosphate carboxylase/oxygenase (Rubisco) accumulation in maize. Using a Mutator transposable element as a molecular probe, we identified a tightly linked restriction fragment length polymorphism that cosegregated with the bsd2-conferred phenotype. This fragment was cloned, and sequences flanking the Mutator insertion were used to screen a maize leaf cDNA library. Using a full-length cDNA clone isolated in this screen, we show that an abundant 0.6-kb transcript could be detected in wild-type plants but not in bsd2-m1 plants. This 0.6-kb transcript accumulated to low levels in plants carrying an allele derived from bsd2-m1 that conditions a less severe mutant phenotype. Taken together, these data strongly suggest that we have cloned the Bsd2 gene. Sequence analysis of the full-length cDNA clone revealed a chloroplast targeting sequence and a region of homology shared between BSD2 and the DnaJ class of molecular chaperones. This region of homology is limited to a cysteine-rich Zn binding domain in DnaJ believed to play a role in protein-protein interactions. We show that BSD2 is targeted to the chloroplast but is not involved in general photosynthetic complex assembly or protein import. In bsd2 mutants, we could not detect the Rubisco protein, but the chloroplast-encoded Rubisco large subunit transcript (rbcL) was abundant and associated with polysomes in both bundle sheath and mesophyll cells. By characterizing Bsd2 expression patterns and analyzing the bsd2-conferred phenotype, we propose a model for BSD2 in the post-translational regulation of rbcL in maize.

Cellular differentiation in the maize leaf is disrupted by bundle sheath defective mutations.

The mature maize leaf is characterised by a series of parallel veins that are surrounded by concentric rings of bundle sheath (BS) and mesophyll (M) cells. To identify genes that control cellular differentiation patterns in the leaf, we have isolated a group of mutations that specifically disrupt the differentiation of a single cell type. In maize bundle sheath defective (bsd) mutants, C4 photosynthetic development is perturbed in BS cells while M cells appear to develop normally. Two mutants, bsd1 and bsd2, have been characterised in detail. Analysis of these mutants, and the corresponding Bsd1 and Bsd2 genes is providing an insight into cellular processes regulating photosynthetic cell type differentiation in maize.

The Ac-st2 element of maize exhibits a positive dosage effect and epigenetic regulation.

A novel derivative of the maize transposable element Ac, termed Ac-st2, that displays a positive dosage effect in maize has been identified. Although identical in sequence to other Ac elements, increasing the copy number of the element in the endosperm results in earlier and more frequent Ds excision. Ac-st2 autonomously transposes and catalyzes somatic excision of Ds elements. Germinal transpositions of either Ac-st2 or Ds, however, were not observed. The Ac-st2 phenotype includes a reduction in Ac transcript accumulation that is associated with increased methylation at specific sites in the promoter region of the major transcriptional start site within Ac (ORFa). This element differs from metastable (cycling) Ac derivatives in that Ac-st2 conditions a uniform transposition pattern throughout endosperm and plant development. Ac-st2 undergoes frequent increases in activity after its association with an active Ac element. This change in activity correlates with reduced levels of methylation in the ORFa promoter region. Using a competitive PCR assay, Ac transcript accumulation was followed through endosperm development. From these data, a model is proposed to explain the patterns of variegation associated with both "wild type" active Ac and Ac-st2 elements.

bundle sheath defective2, a Mutation That Disrupts the Coordinated Development of Bundle Sheath and Mesophyll Cells in the Maize Leaf.

Within the maize leaf primordium, coordinated cell division and differentiation patterns result in the development of two morphologically and biochemically distinct photosynthetic cell types, the bundle sheath and the mesophyll. The bundle sheath defective2-mutable1 (bsd2-m1) mutation specifically disrupts C4 differentiation in bundle sheath cells in that the levels of bundle sheath cell-specific photosynthetic enzymes are reduced and the bundle sheath chloroplast structure is aberrant. In contrast, mesophyll cell-specific enzymes accumulate to normal levels, and the mesophyll cell chloroplast structure is not perturbed. Throughout mutant leaf development, the large and small subunits of ribulose bisphosphate carboxylase are absent; however, both rbcL and RbcS transcripts accumulate. Moreover, chloroplast-encoded rbcL transcripts accumulate ectopically in mesophyll cells. Although the bundle sheath cell chloroplast structure deteriorates rapidly when plants are exposed to light, this deterioration is most likely a secondary effect resulting from cell-specific photooxidative damage. Therefore, we propose that the Bsd2 gene plays a direct role in the post-transcriptional control of rbcL transcript accumulation and/or translation, both in bundle sheath and mesophyll cells, and an indirect role in the maintenance of bundle sheath cell chloroplast structure.

Leaf permease1 gene of maize is required for chloroplast development.

Adjacent bundle sheath and mesophyll cells cooperate for carbon fixation in the leaves of C4 plants. Mutants with compromised plastid development should reveal the degree to which this cooperation is obligatory, because one can assay whether mesophyll cells with defective bundle sheath neighbors retain C4 characteristics or revert to C3 photosynthesis. The leaf permease1-mutable1 (lpe1-m1) mutant of maize exhibits disrupted chloroplast ultrastructure, preferentially affecting bundle sheath choroplasts under lower light. Despite the disrupted ultrastructure, the metabolic cooperation of bundle sheath and mesophyll cells for C4 photosynthesis remains intact. To investigate this novel mutation, the Activator transposon-tagged allele and cDNAs corresponding to the Lpe1 mRNA from wild-type plants were cloned. The Lpe1 gene encodes a polypeptide with significant similarity to microbial pyrimidine and purine transport proteins. An analysis of revertant sectors generated by Activator excision suggests that the Lpe1 gene product is cell autonomous and can be absent up to the last cell divisions in the leaf primordium without blocking bundle sheath chloroplast development.

Somatic inactivation and reactivation of Ac associated with changes in cytosine methylation and transposase expression.

Several metastable Ac alleles at the maize p locus were identified that produced novel pericarp variegation patterns. From the transmission analysis of pericarp sectors, we show that Ac inactivation is a somatic process. Ac excision from P and transactivation of an unlinked Ds was delayed or absent in plants with metastable Ac alleles. These decreases in Ac activity were correlated to increases in cytosine methylation at specific sites near the start of Ac transcription (open reading frame a; ORFa) and at sites in some flanking P sequence. Reactivation of inactive alleles was accompanied by decreased methylation of Ac and P sequences. Using a competitive polymerase chain reaction assay, steady state levels of ORFa transcript were quantitatively compared among the various metastable alleles. We propose that changes in the methylation profile of Ac correspond to changes in Ac activity through the differential accumulation of Ac transcript.