An ALMT1 gene cluster controlling aluminum tolerance at the Alt4 locus of rye (Secale cereale L).

Aluminum toxicity is a major problem in agriculture worldwide. Among the cultivated Triticeae, rye (Secale cereale L.) is one of the most Al tolerant and represents an important potential source of Al tolerance for improvement of wheat. The Alt4 Al-tolerance locus of rye contains a cluster of genes homologous to the single-copy Al-activated malate transporter (TaALMT1) Al-tolerance gene of wheat. Tolerant (M39A-1-6) and intolerant (M77A-1) rye haplotypes contain five and two genes, respectively, of which two (ScALMT1-M39.1 and ScALMT1-M39.2) and one (ScALMT1-M77.1) are highly expressed in the root tip, typically the main site of plant Al tolerance/susceptibility. All three transcripts are upregulated by exposure to Al. High-resolution genetic mapping identified two resistant lines resulting from recombination within the gene cluster. These recombinants exclude all genes flanking the gene cluster as candidates for controlling Alt4 tolerance, including a homolog of the barley HvMATE Al-tolerance gene. In the recombinants, one hybrid gene containing a chimeric open reading frame and the ScALMT1-M39.1 gene each appeared to be sufficient to provide full tolerance. mRNA splice variation was observed for two of the rye ALMT1 genes and in one case, was correlated with a approximately 400-bp insertion in an intron.

Barley beta-D-glucan exohydrolases with beta-D-glucosidase activity. Purification, characterization, and determination of primary structure from a cDNA clone.

Two beta-glucan exohydrolases of apparent molecular masses 69,000 and 71,000 Da have been purified from extracts of 8-day germinated barley grains and are designated isoenzymes ExoI and ExoII, respectively. The sequences of their first 52 NH2-terminal amino acids show 64% positional identity. Both enzymes hydrolyze the (1,3)-beta-glucan, laminarin, but also hydrolyze (1,3;1,4)-beta-glucan and 4-nitrophenyl beta-D-glucoside. The complete sequence of 602 amino acid residues of the mature beta-glucan exohydrolase isoenzyme ExoII has been deduced by nucleotide sequence analysis of a near full-length cDNA. Two other enzymes of apparent molecular mass 62,000 Da, designated betaI and betaII, were also purified from the extracts. Their amino acid sequences are similar to enzymes classified as beta-glucosidases and although they hydrolyze 4-nitrophenyl beta-glucoside, their substrate specificities and action patterns are more typical of polysaccharide exohydrolases of the (1,4)-beta-glucan glucohydrolase type. Both the beta-glucan exohydrolase isoenzyme ExoI and the beta-glucosidase isoenzyme betaII release single glucosyl residues from the nonreducing ends of substrates and proton-NMR shows that anomeric configurations are retained during hydrolysis by both classes of enzyme. These results raise general questions regarding the distinction between polysaccharide exohydrolases and glucosidases, together with more specific questions regarding the functional roles of the two classes of enzyme in germinating barley grain.

Probing the hammerhead ribozyme structure with ribonucleases.

Susceptibility to RNase digestion has been used to probe the conformation of the hammerhead ribozyme structure prepared from chemically synthesised RNAs. Less than about 1.5% of the total sample was digested to obtain a profile of RNase digestion sites. The observed digestion profiles confirmed the predicted base-paired secondary structure for the hammerhead. Digestion profiles of both cis and trans hammerhead structures were nearly identical which indicated that the structural interactions leading to self-cleavage were similar for both systems. Furthermore, the presence or absence of Mg2+ did not affect the RNase digestion profiles, thus indicating that Mg2+ did not modify the hammerhead structure significantly to induce self-cleavage. The base-paired stems I and II in the hammerhead structure were stable whereas stem III, which was susceptible to digestion, appeared to be an unstable region. The single strand domains separating the stems were susceptible to digestion with the exception of sites adjacent to guanosines; GL2.1 in the stem II loop and G12 in the conserved GAAAC sequence, which separates stems II and III. The absence of digestion at GL2.1 in the stem II hairpin loop of the hammerhead complex was maintained in uncomplexed ribozyme and in short oligonucleotides containing only the stem II hairpin region. In contrast, the G12 site became susceptible when the ribozyme was not complexed with its substrate. Overall the results are consistent with the role of Mg2+ in the hammerhead self-cleavage reaction being catalytic and not structural.