Antigen expression from the ribosomal DNA repeat unit of Giardia intestinalis

Ribosomal DNA in the protozoan parasite Giardia duodenalis has a differential chromatin distribution and epigenetic markings across the subunits

Giardia duodenalis is a parasite that causes a large number of diarrheal diseases around the world. It is noteworthy that in a large number of processes, Giardia requires fewer components than other eukaryotes, even without some organelles such as mitochondria and peroxisomes. Despite this, core histones are known to exist in Giardia and epigenetic marks have been found on them, suggesting that they somehow control the expression of certain genes. The regulation of the expression of ribosomal DNA (rDNA) is essential, since it is required to maintain adequate levels of ribosomes and, given the nature of tandem repeat, it is a feasible area to create genomic instability. In Giardia, it is not known how this process occurs, but as in other eukaryotes, it is suggested through various epigenetic mechanisms. Thus, in the present work we seek to identify how chromatin is distributed through the Giardia rDNA and if there were histone marks that could control its expression.

Expression of protein-coding genes embedded in ribosomal DNA

Ribosomal DNA (rDNA) is a specialised chromosomal location that is dedicated to high-level transcription of ribosomal RNA genes. Interestingly, rDNAs are frequently interrupted by parasitic elements, some of which carry protein genes. These are non-LTR retrotransposons and group II introns that encode reverse transcriptase-like genes, and group I introns and archaeal introns that encode homing endonuclease genes (HEGs). Although rDNA-embedded protein genes are widespread in nuclei, organelles and bacteria, there is surprisingly little information available on how these genes are expressed. Exceptions include a handful of HEGs from group I introns. Recent studies have revealed unusual and essential roles of group I and group I-like ribozymes in the endogenous expression of HEGs. Here we discuss general aspects of rDNA-embedded protein genes and focus on HEG expression from group I introns in the nucleolus.

Genotyping Trichomonas vaginalis

A genotyping method has been developed to distinguish each Trichomonas vaginalis isolate and has provided the first genome mapping studies of this protist with an estimated 180Mb genome. The technique was developed using high molecular weight DNA prepared from five laboratory isolates from Australia and USA and 20 clinical isolates from South Africa. Inhibition of the notorious T. vaginalis endogenous nucleases by addition of potent inhibitors was essential to the success of this study. Chromosomal DNA larger than 2.2Mb was macrorestricted to a minimum segment size of approximately 50kb, separated by pulsed field gel electrophoresis and hybridised with a variety of gene probes. Each isolate generated a unique pattern that was distinguished by each of the probes. Four single copy gene probes (fd, hmp35, ibp39 and pfoD) were identified but probes which identified several bands (pfoB and alpha-scs) per isolate were most informative for genotyping. The pyruvate:ferredoxin oxidoreductase B gene probe identified two to seven copies of pfoB (or its closely related homologue pfoA) per genome in different isolates and is an obvious candidate probe to identify epidemiological linkage between infections by this genotyping method. Cleavage of the genomes into smaller fragments failed to distinguish isolates from diverse locations indicating the proximal regions of genes are conserved.

Rearranged subtelomeric rRNA genes in Giardia duodenalis

Giardia duodenalis has linear chromosomes capped with typical eukaryotic repeats [(TAGGG)n], subtelomeric rRNA genes, and telomere gene units. The absence of two closely associated NotI sites in the large-subunit rRNA gene was used as an indicator in hybridizations of one- and two-dimensional NotI-cleaved Giardia chromosome separations that some chromosomes carry only rearranged and, by deduction, nonfunctional rRNA genes.

Ribin, a protein encoded by a message complementary to rRNA, modulates ribosomal transcription and cell proliferation

The control of rRNA transcription, tightly coupled to the cell cycle and growth state of the cell, is a key process for understanding the mechanisms that drive cell proliferation. Here we describe a novel protein, ribin, found in rodents, that binds to the rRNA promoter and stimulates its activity. The protein also interacts with the basal rRNA transcription factor UBF. The open reading frame encoding ribin is 96% complementary to a central region of the large rRNA. This demonstrates that ribosomal DNA-related sequences in higher eukaryotes can be expressed as protein-coding messages. Ribin contains two predicted nuclear localization sequence elements, and green fluorescent protein-ribin fusion proteins localize in the nucleus. Cell lines overexpressing ribin exhibit enhanced rRNA transcription and faster growth. Furthermore, these cells significantly overcome the suppression of rRNA synthesis caused by serum deprivation. On the other hand, the endogenous ribin level correlates positively with the amount of serum in the medium. The data show that ribin is a limiting stimulatory factor for rRNA synthesis in vivo and suggest its involvement in the pathway that adapts ribosomal transcription and cell proliferation to physiological changes.

The abundance of sterile transcripts in Giardia lamblia

The protozoan parasite Giardia lamblia synthesizes a diverse and surprisingly abundant array of sterile transcripts unable to code for proteins. Random sampling of cDNAs from two evolutionarily divergent Giardia strains indicates that approximately 20% of cDNAs in the libraries represent polyadenylated sterile transcripts. RNase protection analysis and northern blot hybridization of three sterile transcript loci demonstrated that both the sterile transcript and a complementary mRNA were made in each case, further categorizing these sterile transcripts as antisense transcripts. Investigation of the genomic loci for these same three sterile antisense transcripts showed typical transcription units for the sense transcripts, but still failed to reveal a usable open reading frame for the sterile antisense transcripts. 5'-RACE mapped the transcription start site for one of the sterile antisense transcripts to an AT-rich region, as is typical for GIARDIA: It is unclear whether these sterile transcripts represent errors in transcription or whether they have regulatory functions within the cell, although preliminary investigations failed to reveal evidence for a role in developmental gene regulation. In either case, the presence of such a large pool of sterile antisense transcripts is dramatic evidence of the unusual molecular machinery of the early diverging protist G.lamblia.

Specific detection of Entamoeba histolytica DNA by hemolysin gene targeted PCR

Diagnostic differentiation of pathogenic Entamoeba histolytica from non-pathogenic Entamoeba dispar is of great clinical importance. We have developed and evaluated a new polymerase chain reaction (PCR) assay (haemo-PCR) based on the novel E. histolytica hemolysin gene HLY6. The specificity of this assay was confirmed by analyzing different Entamoeba species, faeces samples, human and bacterial DNA, and digestion of amplification products with appropriate restriction enzymes. The sensitivity was confirmed by serial dilutions of E. histolytica HM-1:IMSS DNA in the excess of human DNA. Totally, 45 clinical samples were analyzed by the haemo-PCR assay including amoebic liver abscess (ALA) fluids from 23 patients suspected for amoebiasis, four faeces samples containing E. histolytica and E. dispar, and positive and negative controls. The results were compared with those obtained with PCRs for cystein-rich surface protein (P30) and small subunit ribosomal RNA (ssu rRNA) genes. The haemo-PCR gave a positive result in 18 (89%) ALA fluids compared with 14 (77%) and five (28%) by PCR for p30, and ssu rRNA, respectively. PCR products were obtained only from specimens containing E. histolytica DNA. The haemo-PCR assay was therefore found to be a valuable diagnostic tool for identification of E. histolytica infections both in faeces and ALA samples.

Isolation, propagation and characterisation of Cryptosporidium

This review consists of 11 papers presented at the Consensus Conference on Cryptosporidium in Water (Parasitology Stream), held in Melbourne, Australia, from 5 to 6th October 1998. The conference was sponsored by the Water Services Association of Australia, the Australian Water and Wastewater Association, and the Collaborative Research Centre for Water Quality and Treatment. The papers summarise the advantages and disadvantages of various contemporary technologies applicable to parasite propagation and biochemical/molecular characterisation. Studies have detected distinct genetic differences between clinical isolates from humans and animals, and it is hoped that comprehensive documentation studies will facilitate the identification of environmental isolates in the not too distant future.

My favorite cell: Giardia

The gut protozoan parasite, Giardia duodenalis, is the best characterized example of the most ancient eukaryotes, which are anaerobic and appear to be primitively amitochondrial. Apart from its obvious medical importance, Giardia is fascinating in its own right. Its prokaryotic-like anaerobic metabolism renders it selectively sensitive to some bacterial drugs, especially the nitroimidazoles, which are activated to form toxic radicals. Other features, including an enzyme that reduces oxygen directly to water, cysteine as the keeper of redox balance, a plasmid, and toxin-like genes are also distinctly prokaryotic-like. But, unlike prokaryotes, Giardia has a sophisticated, highly developed cytoskeleton, bounded nuclei, linear chromosomes capped with telomeric repeats, and telomere positional regulation of gene expression.

Anaerobic bacterial metabolism in the ancient eukaryote Giardia duodenalis

The protozoan parasite, Giardia duodenalis, shares many metabolic and genetic attributes of the bacteria, including fermentative energy metabolism which relies heavily on pyrophosphate rather than adenosine triphosphate and as a result contains two typically bacterial glycolytic enzymes which are pyrophosphate dependent. Pyruvate decarboxylation and subsequent electron transport to as yet unidentified anaerobic electron acceptors relies on a eubacterial-like pyruvate:ferredoxin oxidoreductase and an archaebacterial/eubacterial-like ferredoxin. The presence of another 2-ketoacid oxidoreductase (with a preference for alpha-ketobutyrate) and multiple ferredoxins in Giardia is also a trait shared with the anaerobic bacteria. Giardia pyruvate:ferredoxin oxidoreductase is distinct from the pyruvate dehydrogenase multienzyme complex invariably found in mitochondria. This is consistent with a lack of mitochondria, citric acid cycle, oxidative phosphorylation and glutathione in Giardia. Giardia duodenalis actively consumes oxygen and yet lacks the conventional mechanisms of oxidative stress management, including superoxide dismutase, catalase, peroxidase, and glutathione cycling, which are present in most eukaryotes. In their place Giardia contains a prokaryotic H2O-producing NADH oxidase, a membrane-associated NADH peroxidase, a broad-range prokaryotic thioredoxin reductase-like disulphide reductase and the low molecular weight thiols, cysteine, thioglycolate, sulphite and coenzyme A. NADH oxidase is a major component of the electron transport pathway of Giardia which, in conjunction with disulphide reductase, protects oxygen-labile proteins such as ferredoxin and pyruvate:ferredoxin oxidoreductase against oxidative stress by maintaining a reduced intracellular environment. As the terminal oxidase, NADH oxidase provides a means of removing excess H+, thereby enabling continued pyruvate decarboxylation and the resultant production of acetate and adenosine triphosphate. A further example of the bacterial-like metabolism of Giardia is the utilisation of the amino acid arginine as an energy source. Giardia contain the arginine dihydrolase pathway, which occurs in a number of anaerobic prokaryotes, but not in other eukaryotes apart from trichomonads and Chlamydomonas reinhardtii. The pathway includes substrate level phosphorylation and is sufficiently active to make a major contribution to adenosine triphosphate production. Two enzymes of the pathway, arginine deiminase and carbamate kinase, are rare in eukaryotes and do not occur in higher animals. Arginine is transported into the trophozoite via a bacterial-like arginine:ornithine antiport. Together these metabolic pathways in Giardia provide a wide range of potential drug targets for future consideration.

Telomeric organization of a variable and inducible toxin gene family in the ancient eukaryote Giardia duodenalis

Giardia duodenalis is the best-characterized example of the most ancient eukaryotes, which are primitively amitochondrial and anaerobic. The surface of Giardia is coated with cysteine-rich proteins. One family of these proteins, CRP136, varies among isolates and upon environmental stress. A repeat region within the CRP136 family is interchangeable by a cassette-like mechanism, generating further diversity in repeat size, copy number, and sequence. Flanking the 5' region of the CRP136 family is a novel protein kinase gene and an ankyrin homolog, creating a conserved unit. A short spacer separates the ankyrin gene from the variable, tandem array of rDNA gene units at a common breakpoint within the large subunit gene, which is followed by the (TAGGG)n telomeric sequence. Transcriptional up-regulation of the CRP136 family is accompanied by a switch in mRNA length and promoter, of de novo expression, and suggests that CRP136 mRNA induction is under the control of a telomerically regulated position effect, which evolved very early in the eukaryotic lineage.

A thioredoxin reductase-class of disulphide reductase in the protozoan parasite Giardia duodenalis

We describe the purification and characterisation of a thioredoxin reductase-like disulphide reductase from the ancient protozoan parasite, Giardia duodenalis. This dimeric flavoprotein contains 1 mol FAD per subunit and had an apparent subunit molecular mass of 35 kDa. The purified enzyme catalysed the NADPH-dependent (Km = 8 microM) reduction of 5,5'-dithio-bis(2-nitrobenzoic acid) to thionitrobenzoate and was unable to utilise NADH as an electron donor. The sulphydryl-active compounds, N-ethylmaleimide, sodium arsenite and Zn2+ ions, strongly inhibited the enzyme suggesting that a thiol component forms part of the active site. Purified enzyme was able to utilise a variety of substrates, including cystine and oxidised glutathione, which suggests that it is a broad-range disulphide reductase, probably accounting for the majority of thiol cycling activity in this organism. While the G. duodenalis enzyme does not require an intermediate electron transport protein, analogous to thioredoxin, for activity, we have identified a candidate carrier protein which enhances DTNB turnover six fold, therefore implying that Giardia contains a thioredoxin-like system. Physical, enzymatic and spectral properties of the G. duodenalis disulphide reductase are also consistent with it being a member of the thioredoxin reductase-class of disulphide reductases. Furthermore, the internal amino acid sequence of a tryptic peptide generated from the purified protein was highly homologous with thioredoxin reductases from other sources. This is the first report of a disulphide reductase to be purified from the anaerobic protozoa and explains the so called "glutathione-induced thiol-reductase activity' previously observed in G. duodenalis.

A novel protein kinase gene family in Giardia duodenalis

Two protein kinase (PK) genes, gPK1 and gPK2, were cloned from the genome of the ancient protozoan parasite, Giardia duodenalis (Gd). Both gPK genes and their products are highly homologous (85% and 77% identical, respectively). gPK1 and gPK2 contain all the motifs characteristic of PK, but they are not highly homologous to other PK and therefore belong to a novel PK gene family. Northern blot analysis showed that the gPK genes are expressed in vivo. Southern blot analysis indicated that there are other homologous PK genes in the Gd genome. gPK1 and gPK2 are the first full-length PK genes cloned from this primitive eukaryote. The unique amino acid (aa) sequences of gPK1 and gPK2 suggest that they are involved in unique biological functions in Gd.

A H2O-producing NADH oxidase from the protozoan parasite Giardia duodenalis

We describe the purification of a H2O-producing NADH oxidase from the protozoan parasite Giardia duodenalis. The enzyme is a monomeric flavoprotein containing flavin adenine dinucleotide in a 1:1 molar ratio with the polypeptide. The NADH oxidase has an apparent molecular mass of 46 kDa and was homogenous as determined by denaturing gel electrophoresis and N-terminal amino acid sequencing. NADPH could substitute for NADH as an electron donor with a K(m) value of 4.2 microM for NADH and 16 microM for NADPH (pH 7.8 at room temperature). With oxygen as the primary electron acceptor under aerobic conditions, the pure enzyme did not produce O.-2 nor H2O2 as stoichiometric products of oxygen reduction, implicating H2O as the end product and obviating the need for superoxide dismutase. The ability to utilise oxygen explains the apparent respiration of the amitochondrial fermentative metabolism of Giardia. Mercurials, flavoantagonists and heavy metals (Cu2+ and Zn2+) inhibited this activity. Under anaerobic conditions the enzyme catalysed electron transfer at lower efficiencies to other electron acceptors including nitroblue tetrazolium, potassium ferricyanide, FAD and FMN, using either NADH or NADPH as electron donors. NADPH, however, was a more efficient electron donor. Cytochrome c was not reduced under any assay conditions used. The enzyme reduced the nitrofuran drugs, furazolidone (an antigiardial) and nitrofurantoin, to their toxic radical forms as determined by EPR. Metronidazole, a nitroimidazole, was not reduced. Pure NADH oxidase did not demonstrate ferredoxin:NAD(P)1 oxidoreductase activity since it could not accept electrons from reduced ferredoxin to regenerate NAD(P)H. The G. duodenalis NADH oxidase may, therefore, function as a terminal oxidase, similar to the mitochondrial cytochrome oxidase, and in the maintenance of an optimum intracellular redox ratio. This report of a flavoenzyme from Giardia places Giardia close to the anaerobic bacteria in evolutionary terms.

A new cysteine-rich protein-encoding gene family in Giardia duodenalis

We have cloned a gene, CRP65, from genomic DNA of Giardia duodenalis (Gd) which contains four 228-bp tandem repeat units between a short (48bp) 5' and long (942 bp) 3' non-repeat region. CRP65 encodes a Cys-rich protein (CRP) with the typical transmembrane domain and CXXC amino acid (aa) motif of Gd CRP. Comparison of the nucleotide (nt) and deduced aa sequences of CRP65 and a gene we cloned previously. CRP136, indicates that the genes are highly homologous in the entire non-repeat regions, but not in the repeat regions. The repeat unit of CRP65 was found to be homologous to epidermal growth factor (EGF)-like domains from different proteins. Analysis of Gd genomic DNA showed that there are multiple copies of CRP65 and each copy varies in the number of repeat units, as well as in certain restriction sites in the units. In Gd strain WB-1B, a 2.0-kb transcript encoded by the gene was expressed, while in a metronidazole-resistant line (WB1B-M3) induced from WB-1B, two longer transcripts (5.5 and 7 kb) were expressed. Based on our results, we suggest that there is a unique CRP family in the Gd genome, whose members, including CRP65 and CRP136, carry various repeat units within a highly conserved 'cassette'. CRP65 may be involved in EGF-like interactions with the host proteins.

Mapping variation in chromosome homologues of different Giardia strains

A landmark physical map of the 2-Mb chromosome of the Giardia duodenalis cloned line WB-1B, constructed using randomly cloned, chromosome specific markers, was used to compare the organisation and map order of the equivalent chromosome in other strains. A representative marker from each of the 13 NotI segments of the 2-Mb chromosome was hybridized to NotI cleavages of whole chromosomes of the other strains. Two strains, one isolated from a human, and one from a cat, had the same chromosome hybridization patterns as WB-1B. A strain isolated from a sheep, had one NotI chromosome 5 segment larger than WB-1B. Two additional strains isolated from a calf and a human had significantly different NotI cleavage patterns from the previous strains and shared no similar-sized chromosome NotI segment from their 2Mb chromosome homologues and only one in common with WB-1B. In one strain, two markers from the same WB-1B NotI segment did not hybridize suggesting deletion events have occurred. The order of some NotI segments within the 2Mb chromosome homologue was maintained, as determined from partial NotI chromosome cleavages, while in the most divergent of strains internal chromosome rearrangements and deletions were evident. All but one of the 2Mb WB-1B chromosome markers examined hybridized to a single chromosome band in all strains. Thus, while Giardia chromosomes vary in size, copy number and organisation, some linkage of markers is apparently maintained in isolates from disparate hosts and localities. We have therefore generated a genetic analysis system for Giardia with landmark maps using representative markers to replace the paucity of classical genetic markers and mutants. This approach is being extended to the complete genome.

Biological and genetic analysis of a longitudinal collection of Giardia samples derived from humans

Duodenal aspirates from children investigated for diarrhoea have been examined for the presence of Giardia over an eleven year period, and where possible, in vitro or in vivo Giardia cultures in mice were established. Based on biochemical characteristics of electrophoretic karyotype, RFLP analysis and rDNA hybridization studies of 40 stocks at least two major varieties, or demes, of Giardia have infected the population of South East Queensland and environs during this period. These demes carried different rDNA repeat units and differed markedly in both the electrophoretic karyotype pattern and the molar representation of chromosome bands. From 1983 to 1991 only one deme was documented. The first evidence of a new deme seen in local children occurred in 1991 and was followed by a predominance of this deme in 1993. These 40 stocks do not represent all positive samples. Other stocks established in vivo were not able to be cultured in vitro, and these probably represent other demes. Since all of the stocks established in vivo were not able to be cultured in vitro, and these probably represent other demes. Since all of the stocks were derived from children with similar chronic symptoms it appears that at least two demes of Giardia are pathogenic.

A three nucleotide signature sequence in small subunit rRNA divides human Giardia in two different genotypes

The nucleotide sequence of the 16S rRNA gene and the space DNA region was determined for Giardia duodenalis, obtained from humans in The Netherlands (AMC-4) and Washington State (CM). These rDNA sequences differ from other G. duodenalis isolates (Portland-1 and BRIS/83/HEPU/ 106) both of which have virtually identical rDNA sequences. The most characteristic feature was found close to the 5' end of the 16S rRNA. The Portland-1 -Bris/83/HEPU/ 106 type has GCG in position 22-24, while AMC-4 and CM have AUC in this position. These two sequences, present in an otherwise conserved region of the 16S rRNA, are "signature" sequences, which divide Giardia isolates into two different groups.

A new rDNA repeat unit in human Giardia

The rDNA repeat unit from a new human Giardia duodenalis strain shows significant differences from the previously reported G. duodenalis rDNA repeat. Twelve base-pair changes occurred in 490 bp of the SSrRNA gene and new restriction enzyme sites occurred in the LSrRNA gene. The overall length of the rRNA genes is the same but the spacer is 76 bp longer than previously reported. A boundary within the spacers of the two different rDNA units divides a region of 50% homology near the LSrRNA gene from a region of 80% homology toward the SSrRNA gene. This boundary region includes two copies of a 78 bp repeat.

Physical map of a 2 Mb chromosome of the intestinal protozoan parasite Giardia duodenalis

The protozoan parasite, Giardia duodenalis, is regarded as the most primitive eukaryote. The two apparently identical nuclei presumably carry the same chromosomes but the number of different chromosomes in the organism is unknown. A genome map of G. duodenalis is required to resolve this issue and mapping studies were initiated using chromosome 5. This chromosome was estimated to be approximately 2 Mb when Giardia chromosomes were separated by contour-clamped homogeneous electric field gel electrophoresis. A plasmid library of chromosome 5-specific DNA sequences was constructed from gel-extracted chromosome 5 and selected probes were used as markers to identify NotI DNA segments derived from chromosome 5. Fifty-nine unique copy markers were used to identify thirteen NotI segments which ranged in size from 47 kb to 400 kb. The sum of the NotI segments was 1.78 Mb which indicated that most, if not all, of the chromosome was accounted for and that chromosome band 5 of the cloned line WB-1B, used in this study comprised only one chromosome type. The NotI segments were ordered on the map by comparison of hybridization patterns of the markers with partial NotI cleavages of whole chromosomes. Chromosome rearrangements occur readily in Giardia, and in two drug-resistant lines selected for resistance to different drugs, partial conservative duplications of chromosome 5 were observed in addition to the original, full length chromosome 5. Both duplications retained the central region of chromosome 5 but were deleted at different termini resulting in one duplication of 1.5 Mb and the other of 1.3 Mb.(ABSTRACT TRUNCATED AT 250 WORDS)

Two distinct varieties of Giardia in a mixed infection from a single human patient

Twenty-five in vitro cultures of Giardia duodenalis derived from a Brisbane patient were established to assess the genetic heterogeneity of a population. Each of the established lines carried a predominance of one of two distinct varieties of Giardia. The two varieties were heterogeneous by four unambiguous criteria that were representative of the whole genome. These included restriction enzyme polymorphisms, hybridization with the cloned rDNA repeat and with a gene encoding a cysteine-rich surface protein, electrophoretic karyotyping and DNA fingerprinting. Differences between parasites derived from this patient were greater than have been seen between all other established G. duodenalis in vitro cultures from both humans and animals. The cultures were heavily selected such that a single Giardia line carried a predominance of one genotype and was not representative of the entire original population.

Coding of hemolysins within the ribosomal RNA repeat on a plasmid in Entamoeba histolytica

The pathogenesis of amoebic dysentery is a result of cytolysis of the colonic mucosa by the parasitic protozoan Entamoeba histolytica. The cytolysis results in extensive local ulceration and allows the amoeba to penetrate and metastasize to distant sites. Factors involved in this process were defined with three clones that express hemolytic activities in Escherichia coli. These potential amoebic virulence determinants were also toxic to human colonic epithelial cells, the primary cellular targets in amoebal invasion of the large intestine. The coding sequences for the hemolysins were close to each other on a 2.6-kilobase segment of a 25-kilobase extrachromosomal DNA element. The structural genes for the hemolysins were within inverted repeats that encode ribosomal RNAs.

A purified ferredoxin from Giardia duodenalis

A ferredoxin has been purified to homogeneity from the ancient protozoan parasite Giardia duodenalis. As far as we know, this is the first electron transport protein to be characterised from the organism. The ferredoxin exhibits absorption maxima at 296 and 406 nm with molar absorption coefficients of epsilon 296 = 16,650 +/- 240 M-1 cm-1 and epsilon 406 = 13,100 +/- 370 M-1 cm-1 respectively. The A406/A296 ratio ranged over 0.78-0.82. The molecular mass of the apoprotein calculated by mass spectrometry was 5730 +/- 100Da and the minimum molecular mass by amino acid analysis was 5926Da. There were four cysteine residues/molecule protein but no methionine, arginine, histidine or tyrosine. The absence of these latter residues is consistent with the amino acid content of most ferredoxins. The N-terminal amino acid sequence exhibited greatest similarity to Desulfovibrio gigas ferredoxin II and indicated the potential to coordinate an iron-sulfur cluster. There were 3.21 +/- 0.41 mol sulfide and 2.65 +/- 0.06 mol iron/mol protein. Electron paramagnetic resonance studies of this protein have indicated the presence of an iron-sulfur centre consistent with those of known ferredoxins. Ferredoxin serves as a biological electron acceptor from giardial pyruvate dehydrogenase with metronidazole as a terminal electron acceptor. Such a pathway may serve as a possible mechanism for the reductive activation of metronidazole in this parasite. A second ferredoxin has been purified to homogeneity, but at this stage there is insufficient material to fully characterise this protein. No other low-molecular-mass electron transport proteins have been identified in Giardia under the growth conditions described.

The 3' terminal region of a gene encoding a cysteine-rich surface protein in Giardia duodenalis

DNA derived from chromosome band 3 of the cloned Giardia duodenalis line, WB-1B was used to construct a cloned library in E. coli. One of these clones, C3/23, has been identified as the 3' coding region of a G. duodenalis cysteine-rich variable surface protein (CRVSP) gene by homology with other published CRVSPs and also contains 720 bp of the 3' flanking region. The sequence of C3/23, was derived from genomic DNA independently of cDNA, or expression copies of the CRVSP genes. The 3' flanking region is not homologous to the 3' untranslated regions of published CRVSPs which probably reflects its genomic origin. Subclones of C3/23 were used to show that the 3' flanking region was conserved in all strains examined in this study and was repeated many times in the genome. The 3' flanking repeats were located on three chromosome bands and were not always associated with the coding sequence of C3/23 which was represented, although not equally, on all chromosome bands. The highly conserved nature of the 3' flanking region and its multiple representation in the genome emphasize the probable role of this sequence in the localization or regulation of expression of the CRVSPs in G. duodenalis.

Chromosomal duplication in Giardia duodenalis

Strains of Giardia duodenalis from diverse parts of the world have three or four chromosomal bands in the range of 650-800 kb as defined by field inversion gel electrophoresis. The extra chromosome band in this range defined a group of strains which are geographically distinct from other strains missing this band. The cloned line WB-1B has three chromosome bands in this size range and chromosome band 3 was used to construct a library of chromosome-specific probes. In some strains examined, including BRIS/83/HEPU/106, a subset of these WB-1B probes hybridized to chromosome band 3 and to the extra chromosome band 4, indicating a partial duplication of chromosome 3 in BRIS/83/HEPU/106. This duplication was estimated to be at least 500 kb when the sizes of NotI chromosome segments which hybridized with chromosome band 3-specific probes were added. A second subset of WB-1B chromosome 3-specific probes hybridized to a fifth chromosome of strain BRIS/83/HEPU/106, in the size range 650-800 kb, which was not visible by ethidium bromide staining. The two subsets of WB-1B probes hybridized to a variety of chromosome combinations in this size range in other Giardia strains and included apparent reversal of chromosome 3 and 4 mobility as well as identification of other minor chromosomes. These data indicate that chromosome band 3 of the line WB-1B is a cluster of at least two different chromosomes that cannot be electrophoretically separated but genetic rearrangements in other strains allow separation of linkage groups carried by chromosome band 3 of WB-1B.(ABSTRACT TRUNCATED AT 250 WORDS)

The nucleotide sequence of the entire ribosomal DNA operon and the structure of the large subunit rRNA of Giardia muris

The total nucleotide sequence of the rDNA of Giardia muris, an intestinal protozoan parasite of rodents, has been determined. The repeat unit is 7668 basepairs (bp) in size and consists of a spacer of 3314 bp, a small-subunit rRNA (SSU-rRNA) gene of 1429, and a large-subunit rRNA (LSU-rRNA) gene of 2698 bp. The spacer contains long direct repeats and is heterogeneous in size. The LSU-rRNA of G. muris was compared to that of the human intestinal parasite Giardia duodenalis, to the bird parasite Giardia ardeae, and to that of Escherichia coli. The LSU-rRNA has a size comparable to the 23S rRNA of E. coli but shows structural features typical for eukaryotes. Some variable regions are typically small and account for the overall smaller size of this rRNA. The structure of the G. muris LSU-rRNA is similar to that of the other Giardia rRNA, but each rRNA has characteristic features residing in a number of variable regions.

Codon usage in Giardia lamblia

A codon usage table for the intestinal parasite Giardia lamblia was generated by analysis of the nucleotide sequences of eight genes comprising 3,135 codons. Codon usage revealed a biased use of synonymous codons with a preference for NNC codons (42.1%). The codon usage of G. lamblia more closely resembles that of the prokaryote Halobacterium halobium (correlation coefficient r = 0.73) rather than that of other eukaryotic protozoans, i.e. Trypanosoma brucei (r = 0.434) and Plasmodium falciparum (r = -0.31). These observations are consistent with the view that G. lamblia represents the first line of descent from the ancestral cells that first took on eukaryotic features.

A gene associated with cell division and drug resistance in Giardia duodenalis

A 3000 bp cDNA insert (G6/1) from Giardia duodenalis, cloned into Escherichia coli is located on chromosome 3 of Giardia stocks which have 3 chromosomes detectable by field-inversion gel electrophoresis in the range 650-800 kb and on chromosome 3 and/or 4 of stocks with 4 chromosomes in this size range. The loss of this sequence from chromosome 4 but not chromosome 3 was associated with the induction of drug resistance in a previously sensitive laboratory stock. G6/1 appears to represent a single copy gene in Giardia as determined by hybridization of the probe to cleaved genomic DNA. Furthermore, the sequences flanking at least 12 kb of G6/1 are the same when G6/1 appears on both chromosomes 3 and 4. The cDNA encodes a protein associated with the nuclei of trophozoites during some stages of growth of the parasite. In a non-dividing culture, the antigen is associated with the nuclei of about 30% of trophozoites and fewer in a dividing culture. Three Giardia stocks with obvious chromosome rearrangements, which grow poorly and fail to divide normally, apparently lack the DNA sequence G6/1.

DNA fingerprinting of the human intestinal parasite Giardia intestinalis with hypervariable minisatellite sequences

Individual isolates of the Giardia duodenalis group of protozoan intestinal parasites were identified by DNA fingerprinting with hypervariable minisatellite sequences. A morphologically identical parasite is found in some forty different animal species. Although the species name intestinalis is reserved for the human isolates, electrophoretic karyotyping suggests that most duodenalis isolates fall into the same species grouping. Distinction based upon morphology, restriction endonuclease cleavage of genomic DNA or isoenzyme analysis has not been adequate to identify individual strains. The successful use of hypervariable sequences in the identification of individual human genomes encouraged us to examine the use of these same sequences for the possible identification of parasite isolates. We initially use as a fingerprinting probe the genome of the bacteriophage M13, which has repeated sequences recognising homologous hypervariable sequences in the human genome. The M13 probe recognises a weakly homologous set of hypervariable sequences in Giardia. The number of informative bands is comparable to those seen in mammals, since the lower molecular weight bands are also useful. There is considerable divergence in the sequences of individual Giardia minisatellites. Some cloned Giardia hypervariable sequences are more homologous to M13 than they are to each other. Similar results were observed with the hypervariable repeat sequences 3' to the human alpha-globin gene when they were used as a probe to distinguish Giardia isolates. The poly(dA-dC).poly(dG-dT) probe which recognises frequent TG tracts in a number of organisms also detects a few variable bands amidst a hybridisation background in the Giardia genome. Thus Giardia isolates which could not be distinguished by restriction endonuclease cleavage, antibody typing or isoenzyme analysis have been identified by DNA fingerprinting procedures. Detailed analysis of strain movement, resurgence, variation, host range and drug resistance is now possible. Similar families of sequences may be widespread in lower eukaryotes and useful for generating individual specific fingerprints. A procedure for detecting individual parasites is also presented. Since Giardia is regarded as the most ancient eukaryote before the occurrence of symbiosis with purple non-sulphur bacteria to generate mitochondria, the identification of hypervariable sequences in the Giardia genome should also aid in understanding the mechanism of generation and evolution of these sequences.