A glycosyltransferase with a length-controlling activity as a mechanism to regulate the size of polysaccharides.

Cyclic beta-1,2-glucans (CbetaG) are osmolyte homopolysaccharides with a cyclic beta-1,2-backbone of 17-25 glucose residues present in the periplasmic space of several bacteria. Initiation, elongation, and cyclization, the three distinctive reactions required for building the cyclic structure, are catalyzed by the same protein, the CbetaG synthase. The initiation activity catalyzes the transference of the first glucose from UDP-glucose to a yet-unidentified amino acid residue in the same protein. Elongation proceeds by the successive addition of glucose residues from UDP-glucose to the nonreducing end of the protein-linked beta-1,2-oligosaccharide intermediate. Finally, the protein-linked intermediate is cyclized, and the cyclic glucan is released from the protein. These reactions do not explain, however, the mechanism by which the number of glucose residues in the cyclic structure is controlled. We now report that control of the degree of polymerization (DP) is carried out by a beta-1,2-glucan phosphorylase present at the CbetaG synthase C-terminal domain. This last activity catalyzes the phosphorolysis of the beta-1,2-glucosidic bond at the nonreducing end of the linear protein-linked intermediate, releasing glucose 1-phosphate. The DP is thus regulated by this "length-controlling" phosphorylase activity. To our knowledge, this is the first description of a control of the DP of homopolysaccharides.

Gene organization and transcription analysis of the Agrobacterium tumefaciens glycogen (glg) operon: two transcripts for the single phosphoglucomutase gene.

The gene organization and transcription of the Agrobacterium glg operon differ from those in other bacteria. Agrobacterium tumefaciens A348 contains a 9.1-kb gene cluster harboring genes for glycogen metabolism. The nucleotide sequence and gene organization of a region containing ADP-glucose pyrophosphorylase (glgC), glycogen synthetase (glgA), and phosphoglucomutase (pgm) genes have been previously described (A. Uttaro and R. A. Ugalde, Gene 150:117-122, 1994). In this work we report that the glycogen phosphorylase (glgP) and branching enzyme (glgB) genes are located immediately upstream of this region. The complete nucleotide sequences of the glgP and glgB genes were obtained, and mutants were constructed by targeted insertional mutagenesis with a kanamycin cassette. Enzymatic assays and reverse transcription PCR carried out with the wild type and with glgP and glgB mutants, as well as primer extension experiments and beta-galactosidase fusions, revealed that this region containing five open reading frames (glgPBCA and pgm) is transcribed unidirectionally as a single operon under the control of a promoter located upstream of the glycogen phosphorylase gene (glgP). An alternative transcript was identified starting 168 bp upstream of an internal ATG start codon of the pgm gene, which is translated as a 71-amino-acid-shorter Pgm protein which complements in vivo a pgm mutant. This alternative transcript has a promoter with the motif TATCAAN5G, identified in octopine Ti plasmid as an autoinducible TraR promoter. This promoter is >200 times more efficient in A. tumefaciens than in Escherichia coli, as judged by the level of enzymatic activity of a lacZ-pgm fusion.

Myophosphorylase deficiency: an unusually severe form with myoglobinuria.

Myophosphorylase deficiency (McArdle disease) is characterized by exercise intolerance that usually starts in childhood. Severe cramps and myoglobinuria are rarely problems in children. We describe an 8-year-old boy with exercise-induced myoglobinuria; he was homozygous for the mutation most commonly encountered in patients with typical McArdle disease.