Phylogenetic relationships among prokaryotic and eukaryotic catalases.

Seventy-four catalase protein sequences, including 29 bacterial, 8 fungal, 7 animal, and 30 plant sequences, were compiled, and 70 were used for phylogenetic reconstruction. The core of the resulting tree revealed unique, separate groups of plant and animal catalases, two groups of fungal catalases, and three groups of bacterial catalases. The only overlap of kingdoms occurred within one branch and involved fungal and bacterial large-subunit enzymes. The other fungal branch was closely linked to the group of animal enzymes. Group I bacterial catalases were more closely related to the plant enzymes and contained such diverse taxa as the Gram-positive Listeria seeligeri, Deinocococcus radiodurans, and gamma-proteobacteria. Group III bacterial sequences were more closely related to fungal and animal sequences and included enzymes from a broad range of bacteria including high- and low-GC Gram positives, proteobacteria, and a bacteroides species. Group II was composed of large-subunit catalases from diverse sources including Gram positives (low-GC Bacilli and high-GC Mycobacteria), proteobacteria, and species of the filamentous fungus Aspergillus. These data can be interpreted in terms of two gene duplication events that produced a minimum of three catalase gene family members that subsequently evolved in response to environmental demands. Horizontal gene transfer may have been responsible for the group II mixture of bacterial and fungal large-subunit catalases.

A tandem array of 5S ribosomal RNA genes in Pythium irregulare.

The 5S ribosomal RNA genes of the oomycete Pythium irregulare exist in tandem arrays unlinked to the rDNA repeat unit. A clone with a 9.2-kb insert containing an array of 5S genes was identified in a lambda genomic library and was characterized by restriction mapping and partial sequencing. The array consisted of 9 apparently identical 5S genes and their spacers in tandem, followed by a diverged 5S-like sequence that is likely to be a pseudogene. This gene arrangement, although almost universal in plants and animals, is rare in fungi and protists.

Diverged 5s rRNA sequences adjacent to 5s rRNA genes in the rDNA of Pythium pachycaule.

The non-transcribed spacer of the ribosomal DNA repeat of Pythium pachycaule was found to exist in two versions, one about 200 bp longer than the other. Both versions contained a conserved 5s rRNA gene in inverted orientation and a diverged copy of the 5s sequence as a tandem repeat, with a spacer of about 180 bp between them. This is the first report of multiple 5s-like sequences in the non-transcribed spacer of the rDNA of any organism. The two diverged 5s sequences differ from each other at nine positions in the 5' half of the sequence, but they have the same central 10-bp deletion and their 3' halves are identical. The diverged sequences, 5s' and 5s'', when aligned with the 5s sequence, have the same base at 63.9 and 58.8% of the positions respectively. The spacers between 5s sequences in both versions were highly conserved. The secondary structures of potential rRNA products of the diverged 5s sequences indicate that they may be pseudogenes. The relationships between the functional 5s gene and the diverged gene copies suggest that the 5s sequence family of P. pachycaule originated by duplication of an ancestral gene, followed by divergence and the introduction of heterogeneity. This work shows the potential for tandemization of 5s genes in the NTS, and may shed light on the evolutionary events that led to the transition from the rDNA-linked 5s genes found in Pythium species with filamentous zoosporangia to the unlinked tandem arrays found in Pythium species with globose zoosporangia.

Unusually compact ribosomal RNA gene cluster in Sphaeronaemella fimicola.

The ribosomal DNA repeat unit of Sphaeronaemella fimicola was found to be a 13.7-kb tandem repeat with a relatively long nontranscribed spacer (NTS) and an unusually compact ribosomal RNA gene cluster. The DNA sequence of an 850-bp PCR amplification product containing the 3' end of the small subunit rRNA (SSrRNA) gene, the 5.8s gene, and the 5' end of the large subunit rRNA (LSrRNA) gene was determined. The putative internal spacers flanking the 5.8s RNA gene could be the shortest yet noted for any fungus, totaling only 102 bases.

The 5S ribosomal RNA gene in Pythium species: two different genomic locations.

The 5S ribosomal RNA (rRNA) genes in eukaryotes may occur either interspersed with the other rRNA genes in the ribosomal DNA (rDNA) repeat, or in separate tandem arrays, or dispersed throughout the genome. In Pythium species and in several related Oomycetes, polymerase chain reaction (PCR) amplification of the nontranscribed spacer (NTS) region with one primer specific for the 5S gene revealed, with several exceptions, that the 5S rRNA gene was present in the rDNA repeat of those species with filamentous sporangia and was absent from the rDNA repeat of those with globose or unknown sporangia. When present, the gene was located approximately 1 kb downstream of the large-subunit rRNA gene and on the strand opposite that on which the other rRNA genes were located. This was confirmed in P. torulosum by sequencing of the gene and its flanking regions. The 5S rRNA genes of P. ultimum were found in tandem arrays outside the rDNA repeat. Evidence of dispersed 5S rRNA sequences was also observed. For many of the species of Pythium having the 5S gene in the NTS, the region between the large-subunit rRNA gene and the 5S gene was found to have length heterogeneity. Oomycetes related to Pythium were also found to have the 5S gene in the NTS, although sometimes in the opposite orientation. This may mean that the presence of the gene in the NTS is ancestral for the Oomycetes and that the absence of the gene in the NTS in those Pythiums with globose sporangia is due to loss of the gene from the rDNA repeat in an ancestor of this group of species. These results favor the view that 5S rRNA gene linkage to the rRNA cistron existed prior to the unlinked arrangement seen in most plants and animals.

A region of heterogeneity adjacent to the 5s ribosomal RNA gene of cereal rusts.

Total genomic DNA was isolated from three cereal stem rusts, Puccinia graminis f. sp. tritici, f. sp. secalis, f. sp. avenae, and two cereal leaf rusts, P. recondita f. sp. tritici and P. coronata f. sp. avenae, and analyzed for the presence of heterogeneity in the intergenic region of the ribosomal DNA repeat unit. A 1 kb region of the repeat unit between the 26s and the 5s rRNA genes (IGR-1) was amplified by PCR and was found to be heterogeneous within each isolate and variable in size between races and species. The PCR results were confirmed by Southern blot analysis of native DNA. In an isolate of race C36(48), heterogeneity appeared to be due to variable numbers of 0.1 kb subrepeats in IGR-1. Nine wheat stem rust strains representing nine different races produced a unique pattern of heterogeneity while two different isolates of one race were identical, as were five of another. This may provide a rapid method for race identification in wheat stem rust. Heterogeneity and polymorphism in rye stem rust, oat stem rust, wheat leaf rust, and oat crown rust, was less pronounced than in wheat stem rust. In the course of this work, the 5s rRNA gene was located and its position and orientation within the ribosomal repeat unit was established.

Detection of length heterogeneity in the ribosomal DNA of Pythium ultimum by PCR amplification of the intergenic region.

About one-half of the ribosomal repeat unit of two isolates of Pythium ultimum was amplified by means of the polymerase chain reaction using one primer pair. The amplified region includes a small part of the large subunit ribosomal RNA gene, about half of the small subunit ribosomal RNA gene, and the entire intergenic region. The intergenic region of both isolates of P. ultimum has length heterogeneity due to the presence of subrepeat arrays (Klassen and Buchko 1990). PCR amplification of the heterogeneous target DNA resulted in sets of fragments which accurately reflect the heterogeneity in the target DNA, although there is a preferential amplification of the smaller targets. PCR product sizes ranged from 4.6 to 5.8 kb.

Strain-specific 1.7 kilobase repetitive deoxyribonucleic acid sequence family in Trichinella spiralis.

Eco RI digestion of bulk DNA from Trichinella spiralis P1, an isolate from domestic pig, reveals the presence of families of repetitive sequences. One of the most prominent of these has a monomer size of 1.7 kb, which exists in minimally dispersed direct tandem arrays, with a copy number of about 2800, and represents 2% of the genome. Although there is evidence that the Eco RI site is missing in some of the family members and that a 1.9 kb variant of the sequence also occurs, the family is highly homogeneous. When bulk DNA from other pig isolates (P2, PB1) and two black bear isolates from Pennsylvania (UPB6, UPB8) is probed with a typical member of the 1.7 kb sequence family cloned into pUC9, hybridization is identical in pattern and intensity with self-hybridization, indicating that the 1.7 kb family exists equally in the repetitive fraction of all of these isolates. When blots of bulk DNA from wild carnivore isolates (MSIL, PF1, AF1, AF2, AF3, AF4, SL, TC) are probed with pPRA, no hybridization can be detected. Faint hybridization of the probe to DNA from T. spiralis var. pseudospiralis occurs at 1.7 kb on an Eco RI profile and indicates that the 1.7 kb sequence has been conserved in the course of strain evolution.

Identification and physical characterization of a Col E1 hybrid plasmid containing a catalase gene of Escherichia coli.

A hybrid Escherichia coli: Col E1 plasmid, pLC36-19, containing a catalase gene has been identified in the Clarke and Carbon colony bank. Catalase activity was amplified two- to three-fold in the pLC36-19-containing strain relative to other hybrid-plasmid-containing strains and this activity could be induced three- or four-fold by hydrogen peroxide or ascorbic acid. The plasmid was transferred to a strain chromosomally deficient in catalase synthesis, resulting in a strain with high and inducible levels of catalase. The plasmid was also transferred to a minicell-producing strain and minicells harbouring the plasmid were found to synthesize a labelled protein with a molecular weight of 84 000 characteristic of catalase from E. coli. A catalase activity was also synthesized by the plasmid-containing minicells. Two catalase activities with associated peroxidase activities coded for by the plasmid were separable by polyacrylamide gel electrophoresis and migrated coincident with chromosomally encoded catalase-peroxidase activities. A third catalase activity which did not have an associated peroxidase activity was not coded for by the plasmid. A physical map of the 25.5-kilobase pair plasmid was constructed by restriction nuclease analysis and the relative positions of 38 restriction sites were defined.

Recharacterization of fungal dinucleoside polyphosphate (HS3).

Three polyphosphorylated dinucleosides given the pseudonyms of HS3, HS2, and HS1 that were erroneously described as diguanosine polyphosphates (LéJohn, H. B., Cameron, L. E., McNaughton, D. R. & Klassen, G. R. (1975) Biochem, Biophys, Res, Commun. 66, 460-467) have been repurified and partially recharacterized. They have proved to be extremely complex molecules; chemical (HCl and KOH hydrolysis), physical (ultraviolet-light spectral analysis and ion-exchange chromatography), and enzymic (nucleotide pyrophosphatase and bacterial alkaline phosphatase hydrolysis) studies showed that (i) all three HS compounds are uracil rich and (ii) only HS3 contains a purine nucleoside and glutamate. The partial structure of HS3 was deciphered as a moiety of ADP--sugar X--glutamate (the mode of attachment of glutamate is obscure) that is covalently linked to another moiety composed of UDP, mannitol, and four phosphates. Sugar X had chromatographic characteristics of ribitol, but the chromatographic isolate also contained a ninhydrin-sensitive entity presumed to be an amino group. Sugar X, THEREFore, may be an amino sugar polyol. Only the general chemical compositions of HS2 and HS1 were determined. Each contained two uridines and HS2 had 10 phosphates whereas HS1 had 12.