The expression of a chimeric soybean beta-tubulin gene in tobacco

A Duplex PCR Assay for Rapid Detection of Phytophthora nicotianae and Thielaviopsis basicola

A duplex PCR method was developed for simultaneous detection and identification of tobacco root rot pathogens Phytophthora nicotianae and Thielaviopsis basicola. The specific primers for P. nicotianae were developed based on its internal transcribed spacer (ITS) regions of ribosomal gene, ras gene and hgd gene, while the specific primers for T. basicola were designed based on its ITS regions and β-tubulin gene. The specificity of the primers was determined using isolates of P. nicotianae, T. basicola and control samples. The results showed that the target pathogens could be detected from diseased tobacco plants by a combination of the specific primers. The sensitivity limitation was 100 fg/μl of pure genomic DNA of the pathogens. This new assay can be applied to screen out target pathogens rapidly and reliably in one PCR and will be an important tool for the identification and precise early prediction of these two destructive diseases of tobacco.

Phosphatase under-producer mutants have altered phosphorus relations

Phosphorus (P) acquisition and partitioning are essential for plant homeostasis. P is available for plant uptake when in its inorganic form (H2PO4-, or Pi), but Pi is often limiting in soils. Plants secrete acid phosphatases (APases) into the apoplastic space, which may be important for obtaining Pi from organic P sources; however, the relative importance of these enzymes for plant P nutrition has yet to be determined. We demonstrate that the root-associated APase pool is increased in Arabidopsis when Pi is limiting and document five APase isoforms secreted from Arabidopsis roots. Previously, we presented the identification of the phosphatase under-producer (pup) mutants, which have decreased in vivo root APase staining when grown under low P conditions. Here, we present the characterization of one of these, pup3, and further studies with pup1. pup3 has 49%, 38%, and 37% less specific APase activity in exudates, roots, and shoots, respectively. Root-associated APase activity is decreased by 16% in pup1 and 25% in pup3, regardless of P treatment. Two APase activity isoforms are reduced in pup3 exudates, and root and shoot isoforms are also affected. One of the two exudate isoforms is recognized by a polyclonal antibody raised to an Arabidopsis purple APase recombinant protein (AtPAP12); however, AtPAP12 transcript levels are unaffected in the mutant. The pup3 mutation was mapped to 68.4 +/- 6.0 centimorgans on chromosome 5. Although P concentrations were not altered in pup1 and pup3 tissues when grown in nutrient solution in which Pi was the sole source of P, the mutants had 10% (pup1) and 17% (pup3) lower shoot P concentrations when grown in a peat-vermiculite mix in which the majority of the total P was present as organic P. Therefore, the pup defects, which include secreted APases, are functionally important for plant P nutrition.

Limited expression of a diverged beta-tubulin gene during soybean (Glycine max [L.] Merr.) development

We examined the developmental expression of a diverged soybean beta-tubulin gene (designated sb-1), which had been cloned and sequenced previously. A probe specific for the sb-1 gene was constructed from the 3' transcribed untranslated sequence. As a control, a more general probe for beta-tubulin genes and their transcripts was constructed from a highly conserved region of the third exon of another soybean beta-tubulin gene, sb-2. Poly(A)+ RNA, extracted from various soybean tissues and organs, was probed alternatively with the sb-1 gene-specific probe and with the generic beta-tubulin probe. Levels of beta-tubulin transcripts recognized by the generic probe differed by a factor of approximately 3 in the different tissues and organs and varied with the state of organ development. Highest levels were found in young, unexpanded leaves and they decreased as leaf maturation occurred. In contrast, transcripts of sb-1 were nearly undetectable in young leaves, and they increased as leaf maturation occurred. Levels of sb-1 transcript were low in all organs of the light-grown plant examined, except the hypocotyl, where they were approximately 10-fold higher. However, the highest levels of sb-1 transcripts were observed in elongating hypocotyls of etiolated seedlings. Exposure of six-day-old etiolated seedlings to light for 12 hours halted further hypocotyl elongation and brought about a dramatic, nearly 100-fold, decrease in the steady-state level of sb-1 transcripts.

Transgenic antibiotic resistance may be differentially silenced in germinating pollen grains

Transgenic tobacco (Nicotiana tabacum L.) plants, carrying the neomycin phosphotransferase (NPT II) gene from E. coli, are resistant to kanamycin when grown from seeds on kanamycin containing medium. Tissue and cell cultures derived from those transformants also express resistance and regenerate complete plantlets in the presence of the antibiotic. This unspecific response to the selective condition has led to the belief that the foreign gene is continuously active or uniformly inducible in all cells of the transgenic plant. However, our experiments show that this view is not true for pollen grains during in vitro germination. Pollen grains isolated from kanamycin resistant tobacco plants carry and transmit the foreign gene but do not express resistance when germinating in vitro. This data presents evidence for differential silencing of a foreign gene in a mature gamete. On the other hand, immature pollen grains (microspores) appear to express resistance. The point of the downregulation of the neomycin transferase gene during pollen maturation is discussed.

The beta-tubulin gene family of Arabidopsis thaliana: preferential accumulation of the beta 1 transcript in roots

The genome of Arabidopsis thaliana (L.) Heynh. was shown to contain a beta-tubulin gene family consisting of at least seven distinct genes and/or pseudogenes. Genomic clones of five different beta-tubulin genes and/or pseudogenes have been isolated and partially characterized. The complete nucleotide sequence of one A. thaliana beta-tubulin gene, designated beta 1, has been determined. A comparison of the predicted amino acid sequence of the A. thaliana beta 1-tubulin with the predicted sequences of beta-tubulins of animals and protists indicated that this plant beta-tubulin shows a high degree of homology with other beta-tubulins. However, the beta 1-tubulin contains a novel single amino acid insertion at position 41. The A. thaliana beta 1-tubulin gene is transcribed, as shown by RNA blot hybridization and S1 nuclease analyses. A 3'-noncoding gene-specific probe was used to examine the expression of the beta 1-tubulin gene in leaves, roots, and flowers by blot hybridization analyses of total RNA isolated from these tissues. The results showed that the transcript of the beta 1 gene accumulates predominantly in roots, with low levels of transcript in flowers, and barely detectable levels of transcript in leaves. A second genomic clone was shown to contain two essentially identical beta-tubulin coding sequences in direct tandem orientation and separated by 1 kb.

Developmental modulation of tubulin protein and mRNA levels during somatic embryogenesis in cultured carrot cells

The number of cortical microtubules (MTs) increases considerably as cultured carrot (Daucus carota L.) cells initiate and progress through somatic embryogenesis. The basis for this increase in MT number was investigated. A radioimmune assay was used to show that tubulin-protein per cell first decreased as the undifferentiated cells initiated embryonic development, but subsequently increased approximately fivefold between the globular and torpedo/plantlet stages. The increase during the torpedo/plantlet stage was correlated with the increase in cell size that occurred during the latter stages of embryogenesis. The cellular levels of tubulin mRNA were determined by Northern blot analysis, using labeled probes derived from soybean α- and β-tubulin genomic sequences, cloned in the vectors pSP64 and pSP65. This analysis demonstrated that the levels of tubulin-gene transcripts varied with the tubulin-protein levels. Cell-free translation of polyadenylated RNA, followed by immunoprecipitation with an anti-tubulin antiserum, established that these transcripts represented functional tubulin mRNA. These results indicate that MT formation in early embryogenesis is controlled by factors other than the availability of tubulin, but that MT formation later in embryogenesis is coordinated with concomitant changes in tubulin-gene transcription and in the size of the total tubulin-heterodimer pool.

The isolation, characterization and sequence of two divergent β-tubulin genes from soybean (Glycine max L.)

Two divergent β-tubulin genes (designated Sβ-1 and Sβ-2) were isolated by screening a soybean genomic library with a Chlamydomonas reinhardtii β-tubulin cDNA probe. Restriction fragment analysis of the clones recovered, and of soybean genomic DNA, indicated that these represent two unique classes of structurally different β-tubulin genes in the soybean genome. However, it is possible that unidentified members of these classes or additional highly divergent classes of β-tubulin genes (thus far undetected) exist in the soybean genome. The Sβ-1 and Sβ-2 genomic clones were sequenced, revealing that both are potentially functional genes which would encode β-tubulins of 445 and 449 amino acids, respectively. A comparison of their derived amino acid sequences with β-tubulins from several organisms showed that they are most homologous to Chlamydomonas β-tubulin (85-87%), with lesser degrees of homology to β-tubulins of vertebrate species (79-83%), Trypanosoma brucei (80-81%) and Saccharomyces cerevisiae (66-68%). The amino acid sequences of Sβ-1 and Sβ-2 are as divergent from each other as they are from the Chlamydomonas β-tubulin. The amino acids at the diverged positions in Sβ-2 are nearly all conservative substitutions while in Sβ-1, 18 of the 69 substitutions were non-conservative. Both soybean β-tubulin genes contain two introns in exactly the same positions. The first soybean intron is located in the same position as the third intron of the Chlamydomonas β-tubulin genes. Codon usage in the two soybean β-tubulins is remarkably similar (D (2)=0.87), but differs from codon usage in other soybean genes.