Orientational control of fimE expression in Escherichia coli.

Phase-variable expression of type 1 fimbriae is, in part, controlled by site-specific DNA inversion of the fim switch in Escherichia coli. Of the two fim recombinases (FimB and FimE) that catalyse the inversion reaction, FimE exhibits a strong bias for phase switching from the ON to the OFF orientation. The specificity associated with fimE is the result of two different mechanisms: (i) FimE exhibits a preference for the invertible element in the ON orientation as substrate for recombination; (ii) the invertible element in the OFF orientation acts in cis to inhibit recombinase activity (orientational control). We show here that the invertible element negatively regulates fimE, even though expression of a fimE-lacZYA transcriptional fusion is unaffected by orientational control. The fimE transcript extends into the invertible region and hence switch ON-specific and switch OFF-specific mRNA contain different sequences. Furthermore, we show that orientational control is suppressed by the insertion of a structured RNA (tRNA(Gly)) between fimE and the fim switch, indicating that the switch OFF-specific mRNA is inactivated by 3' to 5' degradation. Analysis of the fim switch reveals that it contains two inhibitory elements that exert orientational control independently.

Polymorphic open reading frames encoding secretory proteins are located less than 3 kilobases from Theileria parva telomeres.

Polymorphic, multicopy gene families are frequently located in subtelomeric regions of the genomes of parasitic protozoa. Theileria parva telomere-associated (TA) DNA from two chromosomes contained long open reading frames (ORFs) 54% identical at the N-termini, whose 3' ends were 2670 and 2680 bp from the telomeric repeats. Probes derived from these ORFs revealed related sequences close to additional telomeres. The 3' end of an unrelated ORF was approximately 2720 bp from a third telomere. These are among the closest ORFs to telomeres in any organism. Reverse transcription PCR detected transcripts originating within the telomeric multicopy gene family. Additional ORFs, with complex sequence similarities, were located centromeric to the telomere-adjacent ORFs. Transcripts from the schizont stage of T. parva, containing domains with significant amino acid similarity to a 3529 codon ORF located 6900 bp upstream of the telomeric repeats, were mapped to a subtelomeric locus at a fourth telomere. Five telomeric ORFs contained predicted N-terminal signal peptides and one of these signal peptides was functional in a heterologous system. Hybridisation data suggested extensive strain polymorphism between ORFs. Two of the telomere-adjacent ORFs were absent from the genome of a cloned T. parva parasite which can, nonetheless, be passaged through ticks and cattle. T. parva is unusual, among organisms so far studied, in the high density of potential coding sequences located directly adjacent to telomeres and the apparent absence of extensive tracts of repeated sequences within the TA DNA.

Microsequence heterogeneity and expression of the LSU rRNA genes within the two single copy ribosomal transcription units of Theileria parva.

The nucleotide sequences of the large subunit ribosomal RNA coding genes within the two single copy ribosomal DNA transcription units of a cloned Theileria parva isolate from a buffalo were determined. The two LSU rRNA coding units differed by 11 nucleotide substitutions and two deletions of 1 and 6 bp, all located in the 5' end of the LSU coding region. We also observed microsequence heterogeneity between the two buffalo parasite LSU sequences and the previously determined LSU rRNA gene of a T. parva parasite isolated from cattle. At all positions which were variable between the two LSU rRNA coding sequences of the buffalo-derived parasite, either unit 1 or unit 2 matched the LSU rRNA coding sequence of the cattle-derived T. parva parasite in a mosaic pattern. Synthetic oligonucleotides specific for LSU units 1 and 2 of the buffalo T. parva were developed, and used to assay expression of the two units. Both units were expressed in the intra-lymphocytic schizont stage of T. parva. A 2.5-10-fold excess of rRNA derived from LSU unit 1, compared with unit 2, was observed in the schizont stage, the difference being attributable to variation in the level of expression of unit 2. Theileria represents the third genus of Sporozoan protozoa, in addition to Plasmodium and Babesia, exhibiting rRNA coding genes, which are divergent in sequence between different transcription units.

Cloning of telomere-associated DNA using single-specific-primer polymerase chain reaction provides evidence for a conserved sequence directly adjacent to Theileria parva telomeric repeats.

Telomere-associated (TA) DNA sequences of the intracellular protozoan parasite Theileria parva were isolated by a novel strategy using a modified version of single-specific-primer polymerase chain reaction (SSP-PCR). Nucleotide sequences of non-coding TA DNA from three telomeres (6017bp, 2435bp and 4859bp) contained no extensive tracts of repetitive DNA. Long open reading frames (ORFs) were present at the centromeric ends of two of the TA sequences, the 3' ends of the closest ORFs being only 2670bp and 2719bp from the telomeric repeats. There were regions of significant similarity between the nucleotide sequences of the non-coding regions of different telomeres. The longest region of similarity was a virtually identical 1650bp domain, located directly adjacent to the telomeric repeats of two separate telomeres. Comparison of the telomere proximal sequences defined in this study and two additional T. parva telomeres, whose sequences were determined previously, resulted in identification of a single copy 141bp conserved sequence directly adjacent to the telomeric repeats. The conserved sequence is present at all five T. parva telomeres that have been characterised. The only organism currently known to have a single copy conserved sequence located adjacent to the telomeric repeats is another intracellular protozoan, Leishmania braziliensis.

Concerted evolution at a multicopy locus in the protozoan parasite Theileria parva: extreme divergence of potential protein-coding sequences.

Concerted evolution of multicopy gene families in vertebrates is recognized as an important force in the generation of biological novelty but has not been documented for the multicopy genes of protozoa. A multicopy locus, Tpr, which consists of tandemly arrayed open reading frames (ORFs) containing several repeated elements has been described for Theileria parva. Herein we show that probes derived from the 5'/N-terminal ends of ORFs in the genomic DNAs of T. parva Uganda (1,108 codons) and Boleni (699 codons) hybridized with multicopy sequences in homologous DNA but did not detect similar sequences in the DNA of 14 heterologous T. parva stocks and clones. The probe sequences were, however, protein coding according to predictive algorithms and codon usage. The 3'/C-terminal ends of the Uganda and Boleni ORFs exhibited 75% similarity and identity, respectively, to the previously identified Tpr1 and Tpr2 repetitive elements of T. parva Muguga. Tpr1-homologous sequences were detected in two additional species of Theileria. Eight different Tpr1-homologous transcripts were present in piroplasm mRNA from a single T. parva Muguga-infected animal. The Tpr1 and Tpr2 amino acid sequences contained six predicted membrane-associated segments. The ratio of synonymous to nonsynonymous substitutions indicates that Tpr1 evolves like protein-encoding DNA. The previously determined nucleotide sequence of the gene encoding the p67 antigen is completely identical in T. parva Muguga, Boleni, and Uganda, including the third base in codons. The data suggest that concerted evolution can lead to the radical divergence of coding sequences and that this can be a mechanism for the generation of novel genes.

Genetic fingerprinting of Theileria parva using a telomeric DNA probe.

A cloned Theileria parva telomeric DNA sequence, designated pTpUtel, was used to characterize T. parva stocks and clones by hybridization to EcoRI-digested DNA. Eight of the nine T. parva stocks tested were discriminated by the telomeric restriction-fragment-length polymorphisms (RFLPs). Two isolates derived from buffalo 7014 by tick feeding on different occasions were also differentiated using the probe. The probe gave comparable results on purified piroplasm or schizont-infected lymphocyte DNA and did not cross-hybridize with uninfected bovine DNA. The telomeric restriction pattern of a cloned T. parva parasite remained identical after four passages through ticks and cattle. The telomeric sequence therefore represents a useful additional tool for analysis of theileriosis epidemiology.

Characterisation of the telomeres at opposite ends of a 3 Mb Theileria parva chromosome.

Bacteriophage lambda clones containing Theileria parva genomic DNA derived from two different telomeres were isolated and the nucleotide sequences of the telomeric repeats and adjacent telomere-associated (TAS) DNA were determined. The T.parva telomeric repeat sequences, a tandem array of TTTTAGGG or TTTAGGG interspersed with a few variant copies, showed a high degree of sequence identity to those of the photosynthetic algae Chlamydomonas reinhardtii (97% identity) and Chlorella vulgaris (87.7% identity) and the angiosperm Arabidopsis thaliana (84.4% identity). Unlike most organisms which have been studied, no significant repetitive sequences were found in the nucleotide sequences of TAS DNA located centromere-proximal to the telomeric repeats. Restriction mapping and hybridisation analysis of lambda EMBL3 clones containing 16 kilobases of TAS DNA derived from one telomere suggested that they did not contain long regions of repetitive DNA. The cloned TAS DNAs were mapped to T.parva Muguga genomic SfiI fragments 8 and 20, which are located at opposite ends of the largest T.parva chromosome. A 126 bp sequence located directly centromere-proximal to the telomeric repeats was 94% identical between the two cloned telomeres. The conserved 126 bp sequence was present on all T.parva Muguga telomeric SfiI fragments.

Theileria: improved species discrimination using oligonucleotides derived from large subunit ribosomal RNA sequences.

Partial nucleotide sequences of large subunit ribosomal RNA (LSU rRNA) coding genes of Theileria parva and T. taurotragi were determined. Alignment of the T. parva and T. taurotragi sequences revealed species-specific regions within the LSU rRNA genes. A major species-variable region, located between the first and second conserved secondary structure domains of LSU rRNA, was identified. The sequence of the major species-variable region was determined for T. annulata, T. buffeli, and an unclassified Theileria species isolated from buffalo. Species-specific oligonucleotides complementary to LSU rRNA sequences were designed for five species of Theileria. The oligonucleotide probes discriminated between Theileria species when hybridized to amplified parasite LSU rRNA genes or directly to parasite rRNA. Three species-specific oligonucleotides derived from nonoverlapping sequences were developed for each of T. parva and T. taurotragi. A simplified procedure was developed in which T. parva- and T. taurotragi-specific oligonucleotides were used to discriminate the two species under nonstringent hybridization and washing conditions. Use of the nonstringent conditions also increased the sensitivity of target detection. Comparison of Theileria species-specific oligonucleotides derived from large subunit and small subunit rRNA genes demonstrated that, for closely related species, probes derived from LSU rRNA sequences had improved specificity.

Cloning and characterisation of a repetitive DNA sequence from Theileria mutans: application as a species-specific probe.

Repetitive DNA sequences were isolated from a Theileria mutans genomic library by screening with T. mutans total DNA. DNA sequence analysis demonstrated that a section of one of the clones contained a complex series of overlapping perfect repeats ranging between 99 and 20 bp in size. The T. mutans repetitive sequence did not contain large open reading frames (ORFs), unlike T. parva Tpr repetitive DNA sequences. When used as a hybridisation probe the repetitive sequence revealed restriction-fragment-length polymorphisms (RFLPs) between the EcoRI-digested DNAs of two T. mutans stocks. The T. mutans repetitive probe gave a signal with 1 ng of purified T. mutans piroplasm DNA and detected T. mutans sequences in whole-blood DNA isolated from an experimentally infected animal when the piroplasm parasitaemia was equal to or above 0.4%. Oligonucleotide primers derived from the repetitive sequence allowed more sensitive detection of T. mutans DNA by polymerase chain reaction (PCR) amplification. Using the PCR, T. mutans DNA was amplified from an experimentally infected animal with a parasitaemia of < 0.1%.

Theileria parva: detection of genomic polymorphisms by polymerase chain reaction amplification of DNA using arbitrary primers.

Genomic DNA fingerprints were generated from Theileria parva piroplasm DNA by polymerase chain reaction amplification using arbitrary decamers as primers. Four of 12 primers tested generated amplified fragments which were polymorphic between different T. parva stocks or clones. Hybridization of radiolabeled total amplification products to Southern blots of T. parva piroplasm and uninfected bovine DNA confirmed that none of the amplified fragments were derived from any contaminating bovine DNA which may have been present in small quantities. Polymorphic DNA fragments were reproducibly amplified from independent DNA preparations made from cloned parasites. Individual amplified DNA fragments were gel purified and shown to hybridize to size-polymorphic EcoRI fragments in T. parva genomic DNA. Hybridization of individual amplified fragments to total fingerprints, generated using the same arbitrary primer, demonstrated that a single primer detected at least three independent genomic polymorphisms in T. parva DNA.

Discrimination between six species of Theileria using oligonucleotide probes which detect small subunit ribosomal RNA sequences.

The complete small subunit ribosomal RNA (srRNA) gene of Theileria parva was cloned and sequenced. Two primers were designed which permitted the specific amplification of part of the Theileria srRNA gene from Theileria-infected cell line samples which were predominantly (> 95%) bovine DNA. The sequence of the central (variable) region of the srRNA genes of T. annulata, T. taurotragi, T. mutants and two unidentified parasites referred to as Theileria sp. (buffalo) and Theileria sp. (Marula) were obtained. An alignment of the sequences was generated from which 6 oligonucleotide probes, corresponding to species-specific regions, were designed. These probes were demonstrated to provide unequivocal identification of each of the 6 species either by direct detection of parasite srRNA or by hybridization to amplified parasite srRNA genes. The probes were not able to distinguish buffalo-derived T. parva, the causal agent of Corridor disease, from cattle-derived T. parva, the causal agent of East Coast fever.

Detection of polymorphisms among Theileria parva stocks using repetitive, telomeric and ribosomal DNA probes and anti-schizont monoclonal antibodies.

A total of 21 Theileria parva stocks from 6 countries were characterized using T. parva repetitive and ribosomal DNA probes, a Plasmodium berghei telomeric oligonucleotide and a panel of anti-schizont monoclonal antibodies (MAbs). Hybridization of the repetitive DNA probe to Southern blots of EcoRI-digested T. parva DNA revealed 20 different restriction fragment patterns among DNA samples isolated from infections initiated using 16 parasite stocks. The panel of anti-schizont MAbs defined 8 different profiles among schizont-infected lymphoblastoid cell-cultures infected with the same 16 T. parva stocks. Many stocks, which were differentiated by the repetitive DNA probe, could not be distinguished using the anti-schizont MAbs. A cloned T. parva small subunit ribosomal RNA (SSUrRNA) gene probe separated 17 T. parva stocks into 2 groups, exhibiting either 1 or 2 restriction fragments, when hybridized to EcoRI-digested T. parva DNA. When hybridized to PvuII-digested DNA from 8 T. parva stocks, the ribosomal probe identified 4 groups with similar restriction fragment patterns. A synthetic oligonucleotide derived from a P. berghei telomeric sequence hybridized to 7 or 8 size-polymorphic restriction fragments in the EcoRI-digested DNA of most T. parva stocks. The telomeric and ribosomal probes defined the same 4 groups among 8 T. parva stocks as assessed by similarities in restriction fragment patterns. Based on the comparison of repetitive DNA sequences from the T. parva Uganda and Muguga stocks, a synthetic oligonucleotide was developed which distinguished the DNA of the T. parva Uganda stock from that of 4 other T. parva stocks on a positive/negative basis.

Detection of a carrier state in Theileria parva-infected cattle by the polymerase chain reaction.

Two sets of oligonucleotide primers, one derived from a repetitive sequence and the other from the gene encoding a 67 kDa sporozoite antigen of Theileria parva, were used to amplify parasite DNA from the blood of T. parva-infected carrier cattle using the polymerase chain reaction (PCR). PCR amplification products were obtained from 15 carrier cattle infected with one of 4 different T. parva stocks. Successful amplifications were performed using DNA from 2 cattle infected with T. p. parva Pemba Mnarani, 10 cattle infected with T. p. parva Marikebuni, 2 cattle infected with T. p. bovis Boleni and 1 animal infected with T. p. lawrencei 7014. No amplification products were obtained from any of 7 cattle which had been infected with the T. p. parva Muguga stock. A synthetic oligonucleotide, which hybridized specifically to T. p. parva Marikebuni DNA among 6 T. parva stocks tested, was designed using sequence data from within the region of the T. parva genome amplified by the repetitive sequence primers. The oligonucleotide was used to probe PCR products and to increase the sensitivity and specificity of carrier animal detection. Southern blot analysis using a T. parva repetitive sequence probe demonstrated the existence of restriction fragment length polymorphisms between parasites isolated from T. p. parva Marikebuni-infected carrier cattle. The use of the PCR and other methods of carrier animal detection are discussed.

Infection of bovine T cell clones with genotypically distinct Theileria parva parasites and analysis of their cell surface phenotype.

Different stocks and stabilates within a stock of Theileria parva were analysed for genotypic differences and for their effect on the expression of host cell surface antigens following infection of BoT8+ T lymphocyte clones. The parasites were characterized in vitro by hybridization of T. parva-specific DNA probes to Southern blots of endonuclease-digested DNA from the infected T cell clones. Phenotypic changes in the host lymphoblastoid cells before and after infection were examined using lineage-specific monoclonal antibodies which reacted with the differentiation antigens BoT2, BoT4, Bo6, BoT8 and a null cell marker on bovine T cells. Expression of Class I and Class II major histocompatibility complex (MHC) antigens on the cell populations was also assessed. Results of this study indicate that genotypically different parasites exist among and within T. parva stabilates and that the expression of Bo6, BoT8 and the null cell marker was differentially altered by infection with parasites from different stocks or from different stabilates of the same stock. Expression of Class II antigens was significantly increased after infection. Moreover, clones that were derived from the same cell line but had genotypically distinct T. parva parasites, also showed differences in expression of Bo6 and BoT8 and the null cell marker.

DNA probes detect genomic diversity in Theileria parva stocks.

Different stocks of Theileria parva were analysed for restriction fragment length polymorphisms by agarose gel electrophoresis, orthogonal-field-alternation gel electrophoresis (OFAGE) and Southern hybridization with DNA probes. Polymorphisms seen with DNA from purified piroplasms of different T. parva stocks, after digestion with restriction enzymes, were more clearly apparent with OFAGE than with standard agarose gel electrophoresis. Genomic differences between these theilerial parasites were investigated further using three DNA probes, which were selected from a genomic library of T. parva (Muguga) piroplasm DNA cloned in lambda gt11. All three clones hybridized to T. parva DNA in preparations from schizont-infected bovine lymphoblastoid cells and to DNA from intraerythrocytic piroplasms. These probes did not, however, hybridize under high stringency conditions to DNA prepared from uninfected bovine lymphoblasts, T. mutans piroplasms, or bovine lymphoblasts infected with T. annulata or T. taurotragi. The five Kenyan stocks of T. parva that were tested showed characteristic hybridization patterns with these DNA probes. Our results show that DNA probes can be used to distinguish selected stocks of T. parva by hybridization to DNA either from intraerythrocytic piroplasms taken from infected cattle, or from isolates of schizont-infected bovine lymphoblastoid cells that are maintained continuously in vitro.