V-ATPase is a major component of the Golgi complex in the scaly green flagellate Scherffelia dubia.

Highly purified membranes isolated from the Golgi complex of the scaly green flagellate Scherffelia dubia (Chlorophyta) were subjected to Triton X-114 two-phase partitioning. Proteins in the detergent phase were analyzed by 2D gel electrophoresis and a major protein of 66 kD (p66) was N-terminally sequenced. The complete cDNA sequence of p66 was obtained by 3' RACE-PCR and screening of a cDNA library of S. dubia with a PCR probe derived from the 3' RACE. Sequence analysis of the cDNA clone identified p66 as subunit A of V-ATPase. Other major proteins in the isolated Golgi complex were immunoreactive to heterologous antibodies raised against subunit B or the holoenzyme of V-ATPase. A polyclonal (anti-p66) antibody raised against a recombinant, bacterially expressed p66 fusion protein recognized p66 in the isolated Golgi complex in western blots and localized the antigen by immunogold electron microscopy mostly to the scale reticulum but also to the Golgi stack within the Golgi complex. Concanamycin A-sensitive (but bafilomycin A1-insensitive) ATPase activity was present in the isolated Golgi complex, and monensin at 0.5-1 microM reversibly inhibited flagellar regeneration and resulted in swelling of Golgi cisternae. It is concluded that a functional V-ATPase is a major protein of the Golgi complex in S. dubia and is presumably associated with sorting processes at the endocytotic/exocytotic boundary of the Golgi complex.

Group I introns are inherited through common ancestry in the nuclear-encoded rRNA of Zygnematales (Charophyceae).

Group I introns are found in organellar genomes, in the genomes of eubacteria and phages, and in nuclear-encoded rRNAs. The origin and distribution of nuclear-encoded rRNA group I introns are not understood. To elucidate their evolutionary relationships, we analyzed diverse nuclear-encoded small-subunit rRNA group I introns including nine sequences from the green-algal order Zygnematales (Charophyceae). Phylogenetic analyses of group I introns and rRNA coding regions suggest that lateral transfers have occurred in the evolutionary history of group I introns and that, after transfer, some of these elements may form stable components of the host-cell nuclear genomes. The Zygnematales introns, which share a common insertion site (position 1506 relative to the Escherichia coli small-subunit rRNA), form one subfamily of group I introns that has, after its origin, been inherited through common ancestry. Since the first Zygnematales appear in the middle Devonian within the fossil record, the "1506" group I intron presumably has been a stable component of the Zygnematales small-subunit rRNA coding region for 350-400 million years.