MaryAnne Arnoldo scite author profile

Self-incompatibility, the rejection of self pollen, is the most widespread mechanism by which flowering plants prevent inbreeding. In Brassica, the S receptor kinase (SRK) has been implicated in the self-incompatibility response, but the molecular mechanisms involving SRK are unknown. One putative downstream effector for SRK is ARC1, a protein that binds to the SRK kinase domain. Here it is shown that suppression of ARC1 messenger RNA levels in the self-incompatible Brassica napus W1 line is correlated with a partial breakdown of self-incompatibility, resulting in seed production. This provides strong evidence that ARC1 is a positive effector of the Brassica self-incompatibility response.

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Microspore mutagenesis and selection: Canola plants with field tolerance to the imidazolinones

Swanson

Herrgesell

Arnoldo

et al. 1989

Theoret. Appl. Genetics

185

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In vitro microspore mutagenesis and selection was used to produce five fertile double-haploid imidazolinone-tolerant canola plants. The S2 plants of three of the mutants were resistant to at least the field-recommended levels of Assert and Pursuit. One mutant was tolerant to between five and ten times the field-recommended rates of Pursuit and Scepter. Two semi-dominant mutants, representing two unlinked genes, were combined to produce an F1 hybrid which was superior in imidazolinone tolerance to either of the heterozygous mutants alone. Evaluation of the mutants under field conditions indicated that this hybrid and the original homozygous mutants could tolerate at least two times the field-recommended rates of Assert. The field results indicated the mutants were unaffected in seed yield, maturity, quality and disease tolerance. These genes represent a potentially valuable new herbicide resistance system for canola, which has little effect on yield, quality or maturity. The mutants could be used to provide tolerance to several imidazolinones including Scepter, Pursuit and Assert.

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Modification of carbonic anhydrase activity by antisense and over-expression constructs in transgenic tobacco

Majeau

Arnoldo²,

Coleman

1994

Plant Mol Biol

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The activity and location of carbonic anhydrase has been modified by transformation of tobacco with antisense and over-expression constructs. Antisense expression resulted in the inhibition of up to 99% of carbonic anhydrase activity but had no significant impact on net CO2 assimilation. Stomatal conductance and susceptibility to water stress appeared to increase in response to the decline in carbonic anhydrase activity. An over-expression construct designed to increase cytosolic carbonic anhydrase abundance resulted in a significant increase in net activity, a small increase in stomatal conductance but little impact on CO2 assimilation. Chloroplastic carbonic anhydrase activity was enhanced by the expression of an additional construct which targeted the polypeptide to the organelle. The increase in chloroplastic carbonic anhydrase appeared to be accompanied by a concomitant increase in Rubisco activity.

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Evaluation of transgenic canola plants under field conditions

Arnoldo

Baszczynski²,

Bellemare³

et al. 1992

Genome

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Eleven independent transgenic canola (Brassica napus ssp. oleifera L. cv. Westar and Regent) lines were evaluated in the field. The plants carried a neomycin phosphotransferase (NPTII) gene for kanamycin resistance that was introduced via Agrobacterium-mediated transformation. NPTII enzyme assays, Southern blot by hybridizations and progeny analysis, confirmed the stable, heritable integration and expression of the introduced NPTII gene. A number of agronomic characteristics evaluated under field conditions, including maturity yield, and oil and protein content, were all statistically comparable between the transformed and nontransforemd platns. These results indicate that canola can be genetically engineered successfully, and that the Agrobacterium-based transformation system employed does not induced any adverse effects on the intrinsic agronomic and qualitative traits critical to the agricultural industry.

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The S locus glycoprotein and the S receptor kinase are sufficient for self-pollen rejection in Brassica

Cui

Bi²,

Brugière³

et al. 2000

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Self-incompatibility (SI) is one of several mechanisms that have evolved to prevent inbreeding in plants. SI in Brassica is controlled by the polymorphic S locus complex. Two S locus-encoded proteins are coordinately expressed in the stigma epidermis: the cell walllocalized S locus glycoprotein (SLG) and the plasma membraneanchored S receptor kinase (SRK). These proteins are thought to recognize a pollen factor that leads to the rejection of self-pollen. Evidence has accumulated that indicates that both proteins are necessary for the ability of the stigma to inhibit self-pollen. However, it has not been possible to prove this necessity definitively or to demonstrate that these genes are sufficient for this phenotype, because previous attempts to transfer this phenotype via transformation have not been successful. In this study, two overlapping S locus genomic clones, which cover Ϸ55 kilobases of DNA and contain the SLG, SRK, and an anther-expressed gene in the region common to the two, were introduced into a selfcompatible Brassica napus line. The resulting transgenic plants were shown to carry the female part of the SI phenotype, rejecting pollen in a haplotype-specific manner. However, the pollen SI phenotype was not found in any of the transgenic plants. These data show that the SLG and SRK are sufficient for the female side but not the male side of the SI phenotype in Brassica and that there must be an independent pollen S factor encoded outside the cloned region. Self-incompatibility (SI) is one of the mechanisms evolved by higher plants to promote outbreeding and is also a good genetic model to study cell-to-cell communication. In Brassica species, SI is controlled by haplotypes of the S locus complex (1, 2). The control is of the sporophytic type in which the pollen parent genotype determines the phenotype of the pollen (1). When a haplotype in the pollen parent matches that of the pistil, pollen germination is arrested at the stigma surface. Thus, sporophytic SI not only prevents self-fertilization but also prevents crossing between genetically related individuals. The S haplotypes are generally codominant with each other, and SI is dominant over self-compatibility (3, 4).Two genes have been found to be associated with the SI phenotype. The first encodes a secreted S locus glycoprotein (SLG; ref. 5), and the second encodes an S receptor kinase (SRK; ref. 6). The latter protein has a receptor-like domain very similar to SLG, a transmembrane domain, and a kinase domain. Both genes are expressed primarily in stigma papilla cells (5-7). Although some transcripts have been detected in anther tissue, both proteins could be detected only in stigma (8-10). Consistent with this finding, accumulated genetic evidence indicates that expression of both genes in papillar cells is required for the operation of SI (11-17), though recently the necessity of SLG for SI has been questioned (18). Several self-compatible mutant strains of Brassica have been identified in which selfcompatibility is associated with spontaneous ...

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