The enzyme acetolactate synthase (ALS) is the target enzyme for the sulfonylurea and imidazolinone herbicides. We describe the isolation and characterization of the ALS genes from two herbicide‐resistant mutants, C3 and S4‐Hra, of Nicotiana tabacum. There are two distinct ALS genes in tobacco which are 0.7% divergent at the amino acid sequence level. The C3 mutant has a single Pro–Gln replacement at amino acid 196 in one ALS gene. This gene is termed the class I gene and is equivalent to the SuRA locus. The S4‐Hra mutant has two amino acid changes in the other ALS gene. This gene is termed the class II gene or the SuRB locus. The S4‐Hra mutant includes a Pro–Ala substitution at amino acid 196 and a Trp–Leu substitution at amino acid 573. Gene reintroduction experiments have confirmed that these amino acid substitutions are responsible for the herbicide resistance phenotypes. Transgenic plants carrying these genes are highly resistant to sulfonylurea herbicide applications.
A single amino-acid change in the acetolactate synthase (ALS) protein of tobacco confers resistance to the herbicide chlorsulfuron. A deleted, nonfunctional fragment from the acetolactate synthase gene, carrying the mutant site specifying chlorsulfuron resistance plus a closely linked novel restriction site marker, was cloned into a binary vector. Tobacco protoplasts transformed with Agrobacterium tumefaciens carrying this vector yielded chlorsulfuron-resistant colonies. DNA gel blot analysis of DNA from these colonies suggested that in three transformants homologous recombination had occurred between the endogenous ALS gene and the deleted ALS gene present in the incoming T-DNA. Plants were regenerated from these chlorsulfuron-resistant colonies, and in two of the transformants, genetic analysis of their progeny showed that the novel gene segregated as a single Mendelian locus. Possible models for the generation of these recombinant plants are discussed.
A single amino-acid change in the acetolactate synthase (ALS) protein of tobacco confers resistance to the herbicide chlorsulfuron. A deleted, nonfunctional fragment from the acetolactate synthase gene, carrying the mutant site specifying chlorsulfuron resistance plus a closely linked novel restriction site marker, was cloned into a binary vector. Tobacco protoplasts transformed with Agrobacterium tumefaciens carrying this vector yielded chlorsulfuronresistant colonies. DNA gel blot analysis of DNA from these colonies suggested that in three transformants homologous recombination had occurred between the endogenous ALS gene and the deleted ALS gene present in the incoming T-DNA. Plants were regenerated from these chlorsulfuron-resistant colonies, and in two of the transformants, genetic analysis of their progeny showed that the novel gene segregated as a single Mendelian locus. Possible models for the generation of these recombinant plants are discussed.
The endo-beta-1,4-glucanases, or cellulases, of higher plants are cell wall-associated enzymes believed to function in cell wall changes associated with the diverse processes of fruit ripening, organ abscission and cell elongation. We have isolated and characterized cDNA and genomic clones encoding a cellulase, PCEL1, which is abundant in ripening pepper fruit. Genomic analysis indicates that PCEL1 is encoded by a single gene, PCEL1, which belongs to a small, structurally divergent gene family. In ripening fruit, PCEL1 transcription is initiated at two distinct sites which yields overlapping mRNA species of 1.7 and 2.1 kb. High-level accumulation of both transcripts occurs in red fruit, while the 1.7 kb transcript is detected at a much lower level in stem and petiolar tissue. The increase in cellulase activity which is measured during fruit ripening is the product of PCEL1 expression and is tightly coupled to fruit reddening. High-level applications of ethylene serve to enhance the rate of ripening and the accumulation of PCEL1 mRNA. A direct role for ethylene in regulating PCEL1 expression is shown by the exclusive induction, in immature green fruit, of the 1.7 kb transcript in response to prolonged high-level exposure to ethylene--a pattern of expression not observed in fruit development on the vine.
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