Characterization and expression of chitinase and 1,3-beta-glucanase genes in cotton.

We have isolated cDNA clones representing mRNAs encoding chitinase and 1,3-beta-glucanase in cotton (Gossypium hirsutum L.) leaves. The chitinase clones were sequenced and found to encode a 28,806 Da protein with 71% amino acid sequence similarity to the SK2 chitinase from potato (Solanum tuberosum). The 1,3-beta-glucanase clones encoded a 37,645 Da protein with 57.6% identity to a 1,3-beta-glucanase from soybean (Glycine max). Northern blot analyses showed that chitinase mRNA is induced in plants treated with ethaphon or salicylic acid, whereas the levels of 1,3-beta-glucanase mRNA are relatively unaffected. Southern blots of cotton genomic DNA and genomic clones indicated chitinase is encoded by a small gene family of which two members, Chi 2;1 and Chi 2;2, were characterized. These genes share 97% sequence identity in their transcribed regions. The genes were found to have three exons which are 309, 154 and 550 bp long, and two introns 99 and 154 bp in length. The 5'-flanking regions of Chi 2;1 and Chi 2;2 exhibit a large degree of similarity and may contain sequences important for gene response to chemical agents and fungal attack.

Characterization and expression of metallothionein-like genes in cotton.

We have characterized cotton (Gossypium hirsutum L.) genes encoding type 1 metallothionein-like proteins that are highly expressed in roots. Little or no expression of these genes was detected in other organs and tissues. The deduced amino acid sequences have a high degree of similarity with type 1 metallothionein-like proteins from other plants, including a central hydrophobic domain flanked by conserved cysteine-rich motifs. The type 1 metallothionein-like genes of cotton are encoded by a small gene family. One gene (MT1-A) was analyzed in detail and found to have three exons which are 52, 83 and 397 bp long, and two introns 130 and 1042 bp in length. Three of the type 1 metallothionein-like genes are organized in a tandom array, and the 5'-flanking regions of these genes share a high degree of sequence similarity. Two of the clustered genes (MT1-A and MT1-B) are expressed at about equal levels in roots and use the same transcription start site. A 640 bp promoter fragment from the MT1-A gene was sufficient to direct expression of beta-glucuronidase (GUS) in transformed cotton roots. The expression was highest near the root tip.

Organization, inheritance and expression of acetohydroxyacid synthase genes in the cotton allotetraploid Gossypium hirsutum.

The acetohydroxyacid synthase (AHAS) gene family of the cotton AD allotetraploid Gossypium hirsutum has been cloned and characterized. We have identified six different AHAS genes from an analysis of genomic clones and Southern blots of genomic DNA. Four of the six genes are organized as tandem pairs, in which the genes are separated by only 2-3 kb. Conservation of restriction fragment length polymorphisms between G. hirsutum and A-genome and D-genome-containing diploid cottons was sufficient to assign the single genes in clones A5 and A19 to the A and D subgenomes, respectively. Each diploid genome has one tandem pair, but in these cases we could not make specific subgenomic assignments. DNA and deduced amino acid sequences were determined for the A5 and A19 genes, and an AHAS cDNA clone isolated from a leaf library. The sequence of the A19 gene matches that of the cDNA clone, while the A5 gene is 97.8% similar. The four genes comprising the tandem pairs are much less similar to the cDNA clone. The deduced amino acid sequences of the mature polypeptides encoded by the A5 and A19 genes are collinear with the housekeeping forms of AHAS from Arabidopsis thaliana, Nicotiana tabacum and Brassica napus. The constitutive expression of A5 and A19 was confirmed with RNase protection assays and northern blots. We conclude that these genes encode the main housekeeping forms of AHAS in G. hirsutum. Among the four AHAS genes comprising the two tandem pairs, at least two are functional. These genes exhibit either low-level constitutive expression (one or both of the 'downstream' genes of each pair), or highly specific expression in reproductive tissue (one or both of the 'upstream' genes of each pair). The AHAS gene family of G. hirsutum is more complex than that of other plants so far examined.

Expression of maize phosphoenolpyruvate carboxylase in transgenic tobacco : effects on biochemistry and physiology.

The expression of maize (Zea mays) phophoenolpyruvate carboxylase (PPC) gene constructions was studied in transgenic tobacco plants (Nicotiana tabacum). Where transcription was under the control of a maize PPC gene promoter, a low level of aberrantly large PPC transcript was detected. Analysis of this PPC transcript indicated that transcription initiation occurs upstream of the normal site. Despite the aberrant transcription initiation, expression of the PPC transcript was still light-regulated. Higher levels of maize PPC transcript of the correct size were obtained with a chimeric gene construction containing a tobacco (Nicotiana plumbaginifolia) chlorophyll a/b binding protein gene promoter. The PPC activities in the leaves of these transgenic plants were up to twofold higher than those of nontransformed plants. Two forms of PPC with different kinetic properties were identified in leaf extracts of the transgenic plants: one form with a high apparent K(m) for phosphoenolpyruvate (maize isozyme), and a second form exhibiting a low apparent K(m) (tobacco isozyme). Biochemical analyses of these plants indicated that the transgenic plants had significantly elevated levels of titratable acidity and malic acid. These biochemical differences did not produce any significant physiological changes with respect to photosynthetic rate or CO(2) compensation point.

Organ-specific transcripts of different size and abundance derive from the same pyruvate, orthophosphate dikinase gene in maize.

Analyses of genomic DNA and clones indicate that the pyruvate, orthophosphate dikinase (PPDK; ATP: pyruvate, orthophosphate phosphotransferase, EC 2.7.9.1) gene family of maize (Zea mays L. subsp. mays, line B73) contains two members. Restriction site and DNA sequence comparisons between PPDK genomic and leaf cDNA clones have revealed which gene encodes the isozyme involved in C4 photosynthesis. The region flanking the 5' end of this gene contains two 30-base-pair (bp) repetitive elements that may be involved in its light-regulated expression. Sequence analysis of genomic and leaf cDNA clones has also shown that the entire 7.3-kDa PPDK chloroplast transit peptide is encoded in the 436-bp first exon. Northern blot experiments with probes specific for the first exon and the 3' end of the gene showed that the smaller PPDK transcripts in roots and etiolated leaves [3.0 kilobases (kb) vs. the 3.5-kb green leaf transcript] lack the sequence encoding the chloroplast transit peptide. In addition, results from cDNA library screens have confirmed that the root transcript is approximately 50-fold less abundant than the green leaf transcript. Finally, sequence comparisons among cDNA clones from green leaves and roots and genomic clones representing both members of the PPDK gene family demonstrate that the green leaf transcript encoding the C4 isozyme and the root transcript are derived from the same gene.

Structure and expression of the maize gene encoding the phosphoenolpyruvate carboxylase isozyme involved in C4 photosynthesis.

We have determined the structure of the maize (Zea mays L. subsp.mays line B73) nuclear gene encoding the phosphoenolpyruvate (PEP) carboxylase isozyme involved in C4 photosynthesis. The gene is 5.3 kb long and has ten exons that range in size from 85 to 999 bp. The nine introns vary from 97 to 872 bp. The sequence of 663 bp of 5'-flanking and 205 bp of 3'-flanking DNA is reported along with the entire gene sequence. Several short repetitive sequences were found in the 5'-flanking DNA that have characteristics similar to elements important in the light regulation of pea genes encoding the small subunit of ribulose 1,5-bisphosphate carboxylase. In addition, some 5'-flanking sequence similarities were found in a comparison with other light-regulated genes from maize and wheat.The level of DNA sequence variation among different PEP carboxylase alleles is similar to the allelic variation observed for several other maize nuclear genes. The data suggest modern maize variaties have retained much of the genetic variation present in their ancestral forms.Finally, accumulation of transcripts encoding the PEP carboxylase isozyme involved in C4 photosynthesis is quite high in several structures besides leaves, including inner leaf sheaths, tassels and husks. This indicates that expression of this gene is not leaf-specific and may not necessarily be coupled to the development of Kranz anatomy.

Genomic and cDNA clones for maize phosphoenolpyruvate carboxylase and pyruvate,orthophosphate dikinase: Expression of different gene-family members in leaves and roots.

We have isolated cDNA clones for the maize leaf enzymes phosphoenolpyruvate (P-ePrv) carboxylase [orthophosphate:oxaloacetate carboxy-lyase (phosphorylating) EC 4.1.1.31] and pyruvate,orthophosphate (Prv,P(i)) dikinase (ATP:pyruvate,orthophosphate phosphotransferase, EC 2.7.9.1) by exploiting the light-inducibility and large size of the mRNAs (3.5 kilobases) that encode the two enzymes. The clones were identified by hybrid-selection and immunoprecipitation assays. From a maize genomic library, two different types of genomic clones were screened with both the P-ePrv carboxylase and the Prv,P(i) dikinase cDNA clones. Information from these genomic clones and genome blots indicates that the P-ePrv carboxylase gene family has at least three members and the Prv,P(i) dikinase family at least two. Transcripts for both enzymes were detected in green leaves, etiolated leaves, and roots. The results show that the P-ePrv carboxylase mRNAs in green leaves and roots are encoded by different genes. Whereas the P-ePrv carboxylase mRNAs in all three tissues appear to be the same size, the Prv,P(i) dikinase mRNA in green leaves is about 0.5 kilobases longer than the Prv,P(i) dikinase mRNAs in etiolated leaves and roots. It is possible that all these Prv,P(i) dikinase transcripts are encoded by one gene, and the size differences may correspond to the presence or absence of a sequence encoding a chloroplast transit peptide.

Comparison of sea urchin and human mtDNA: evolutionary rearrangement.

Clones of full-length mtDNA have been isolated from a Strongylocentrotus franciscanus recombinant DNA library by screening a cDNA clone of cytochrome oxidase subunit 1 mRNA. Restriction fragment cross-hybridization analysis shows the following difference in gene arrangement between sea urchin and human mtDNA. The 16S rRNA and cytochrome oxidase subunit 1 genes are directly adjacent in sea urchin mtDNA. These two genes are separated in human and other mammalian mtDNAs by the region containing unidentified reading frames 1 and 2. In spite of the difference in gene order, gene polarity appears to have been conserved. We conclude that the difference in gene order reflects a rearrangement that took place in the sea urchin lineage since sea urchins and mammals last shared a common ancestor.

Transcripts of three mitochondrial genes in the RNA of sea urchin eggs and embryos.

cDNA clones representing mitochondrial 16 S rRNA, and mRNAs for cytochrome oxidase I and an unidentified reading frame were used to measure the prevalence and stability of these transcripts in gastrula stage embryos. The 16 S rRNA is the most prevalent embryo poly(A) RNA, and is synthesized about four times more rapidly than is the mRNA for cytochrome oxidase. The relative prevalence of the two mRNAs is largely determined by their turnover rates.

Mitochondrial DNA sequences in the nuclear genome of Strongylocentrotus purpuratus.

Two sea urchin embryo complementary DNA clones representing mitochondrial 16 S ribosomal RNA and cytochrome oxidase subunit I messenger RNA have been characterized. The cloned cDNAs are colinear with sea urchin mitochondrial DNA, and their identification is based on cross-hybridization with known restriction fragments of human mitochondrial DNA, and on nucleotide sequence determinations. The mitochondrial cDNA clones also displayed an unexpected reaction with specific genomic DNA sequences in gel blot hybridizations. Genomic phage lambda recombinants containing sequences hybridizing with the mitochondrial clones were isolated and the arrangement of these sequences was determined. The genomic region studied contains a sequence homologous with the 3' end of the mitochondrial 16 S rRNA gene, flanked on one side by what is possibly a complete copy of the cytochrome oxidase subunit I gene, and on the other by a duplication of a fragment of this gene. The nucleotide sequence divergence between the mitochondrial and nuclear homologues of the cytochrome oxidase subunit I gene varies for different regions of the gene, from about 13% to 25%, while there is about 8% sequence divergence between nuclear and mitochondrial versions of the 3' 16S rRNA sequence. The structure of the genomic mitochondrial sequence homologues indicates that during sea urchin evolution there occurred a germ-line transposition of a fragment of the mitochondrial genome into the nuclear DNA, followed by rearrangements and single nucleotide substitutions.

Evolution of sea urchin non-repetitive DNA.

New methods have been applied to the determination of single copy DNA sequence differences between the sea urchin species Strongylocentrotus purpuratus, S. franciscanus, S. drobachiensis, and Lytechinus pictus. The thermal stability of interspecies DNA duplexes was measured in a solvent (2.4 M tetraethylammonium chloride) that suppresses the effect of base composition on melting temperature. The lengths of duplexes were measured after digestion with S1 nuclease and correction made for the effect of length on thermal stability. The degree of base substitution that has occurred in the single copy DNA during sea urchin evolution is significantly larger than indicated by earlier measurements. We estimate that 19% of the nucleotides of the single copy DNA are different in the genomes of the two sea urchin congeners, S. purpuratus, and S. franciscanus, which apparently diverged only 15 to 20 million years ago.