Giardia duodenalis trophozoites isolated from a parrot (Cacatua galerita) colonize the small intestinal tracts of domestic kittens and lambs.

This study examines the ability of Giardia duodenalis trophozoites, isolated from a wild bird, to colonize the intestinal tracts of companion animals (kittens) and domestic ruminants (lambs). Trophozoites colonized the intestinal tracts of intraduodenally inoculated animals as demonstrated by increasing parasite burdens within the duodenum and jejunum and by fecal passage of cysts within 4 days post-inoculation. The pathogenesis of the trophozoites was further investigated in kittens. In these animals, infection significantly reduced jejunal brush border microvillous length and density, which resulted in a loss of overall epithelial brush border surface area. This injury was associated with the production of diarrhea in four of five infected kittens. These findings indicate that some bird species may carry G. duodenalis that represent a possible health threat to companion animals and livestock. Our results describe the first successful colonization of avian-derived G. duodenalis trophozoites in the small intestines of domestic kittens and lambs.

Drug targets and mechanisms of resistance in the anaerobic protozoa.

The anaerobic protozoa Giardia duodenalis, Trichomonas vaginalis, and Entamoeba histolytica infect up to a billion people each year. G. duodenalis and E. histolytica are primarily pathogens of the intestinal tract, although E. histolytica can form abscesses and invade other organs, where it can be fatal if left untreated. T. vaginalis infection is a sexually transmitted infection causing vaginitis and acute inflammatory disease of the genital mucosa. T. vaginalis has also been reported in the urinary tract, fallopian tubes, and pelvis and can cause pneumonia, bronchitis, and oral lesions. Respiratory infections can be acquired perinatally. T. vaginalis infections have been associated with preterm delivery, low birth weight, and increased mortality as well as predisposing to human immunodeficiency virus infection, AIDS, and cervical cancer. All three organisms lack mitochondria and are susceptible to the nitroimidazole metronidazole because of similar low-redox-potential anaerobic metabolic pathways. Resistance to metronidazole and other drugs has been observed clinically and in the laboratory. Laboratory studies have identified the enzyme that activates metronidazole, pyruvate:ferredoxin oxidoreductase, to its nitroso form and distinct mechanisms of decreasing drug susceptibility that are induced in each organism. Although the nitroimidazoles have been the drug family of choice for treating the anaerobic protozoa, G. duodenalis is less susceptible to other antiparasitic drugs, such as furazolidone, albendazole, and quinacrine. Resistance has been demonstrated for each agent, and the mechanism of resistance has been investigated. Metronidazole resistance in T. vaginalis is well documented, and the principal mechanisms have been defined. Bypass metabolism, such as alternative oxidoreductases, have been discovered in both organisms. Aerobic versus anaerobic resistance in T. vaginalis is discussed. Mechanisms of metronidazole resistance in E. histolytica have recently been investigated using laboratory-induced resistant isolates. Instead of downregulation of the pyruvate:ferredoxin oxidoreductase and ferredoxin pathway as seen in G. duodenalis and T. vaginalis, E. histolytica induces oxidative stress mechanisms, including superoxide dismutase and peroxiredoxin. The review examines the value of investigating both clinical and laboratory-induced syngeneic drug-resistant isolates and dissection of the complementary data obtained. Comparison of resistance mechanisms in anaerobic bacteria and the parasitic protozoa is discussed as well as the value of studies of the epidemiology of resistance.

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.

A dynein heavy chain homologue gene in Hexamita inflata.

A gene encoding an unusually small dynein heavy chain homologue, hDYHH, was cloned from the genome of a free-living diplomonad, Hexamita inflata (Hi). The open reading frame (ORF) of hDYHH is 867bp and encodes a polypeptide of 289 amino acids (aa), hDYHH. hDYHH is homologous to the region around the third P-loop ATP-binding site of several dynein heavy chain polypeptides that are around 4000aa. Northern blot analysis showed that hDYHH is expressed in vivo and that the mRNA length (approximately 1.8kb) is consistent with the gene length (1.67kb). Southern blot analysis indicated that there are hDYHH homologues within the Hi genome, possibly including a longer dynein heavy chain gene. An hDYHH homologue was also identified in Hexamita pusilla (Hp). hDYHH is the first full-length protein-encoding gene cloned from Hexamita.

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.

Drug resistance in Giardia: clinical versus laboratory isolates.

The advantages and limitations of determining mechanisms of drug resistance in Giardia duodenalis laboratory isolates, which have been generated in a number of ways, is weighed against the difficulty of analysing mechanisms in clinical isolates with a large diversity of genetic and expression capabilities. Using isogenic strains to follow changes in enzyme regulation involved in drug resistance, we have been able to assess the full capability of the parasite in developing drug resistance mechanisms. The complementarity of the two approaches, clinical versus laboratory induced drug resistance, and continuing comparison with other organisms, particularly the anaerobic bacteria with which Giardia has strong affiliations, is emphasized. These considerations lead to the study of the population genetics of drug resistance, and strategies critical for rational drug usage, design and therapy.

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 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.

A Giardia duodenalis gene encoding a protein with multiple repeats of a toxin homologue.

A gene, CRP136, from the intestinal protozoan parasite Giardia duodenalis, expressed at a high level in a metronidazole-resistant line, encodes a 136 kDa protein with 23 copies of a 40 amino acid repeat. The protein is cysteine-rich and has the typical membrane-spanning region and CXXC amino acid motifs of a family of Giardia cysteine-rich surface proteins (CRSPs). The repeat unit in CRP136, shares 57% homology with the gene encoding the precursor of the sarafotoxins, a group of snake toxins from the burrowing adder known to cause symptoms similar to those of humans acutely infected with Giardia. The sarafotoxins are low molecular weight sulphydryl cross-linked peptides which are proteolytically cleaved from a precursor polyprotein. CRP136 has homology over the entire length of the sarafotoxin precursor, and the repeats are of the same length. Thus CRP136 represents the first evidence for a potential Giardia toxin. The genomic copy number of CRP136 appears to be the same in both the parent and drug-resistant lines and expression of this gene, and at least one other, is associated with a conserved partial duplication, but not amplification, of one chromosome.

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.

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.

Simian virus 40 infection is not mediated by lysosomal activation.

The uptake of simian virus 40 (SV40) virions to the nucleus, the site of viral replication, proceeds via engulfment at the cytoplasmic membrane and transport in monopinocytotic vesicles through the cytoplasm to the nuclear membrane. In the case of Semliki Forest virus and poliovirus which undergo primary endocytosis in a similar manner, neutralization of the acid pH in these vesicles abolishes viral infectivity. We have examined the effects of the lysosomotropic agents chloroquine and ammonium chloride on the uptake of SV40 and find that neutralization of the acid pH in cellular organelles has no effect on the progress of SV40 infection. Although the initial endocytotic pathway appears similar for the viruses, the vesicular transport of SV40 to the nucleus proceeds, therefore, via an alternative endocytotic compartment which is not inhibited by increasing the endosomal pH.

Transformation of mammalian cells with recombinant DNA directly from Seaplaque agarose.

Transfection of African green monkey kidney cells directly with recombinant DNA excised from, but still present in, Seaplaque agarose after electrophoresis, is described. Efficiencies of transfection increased by 30% when the gel was present compared with transfection in the absence of the agarose. Extraction of the DNA from the gel was not necessary, thereby obviating a purification step and the concomitant losses. To generate recombinant molecules bacterial plasmid sequences are not necessary, thereby reducing considerably the size of the recombinant molecule and removing extraneous and deleterious sequences, e.g., "poison sequences." Linear or circular DNA molecules could be transfected in the melted and diluted agarose with the same ease as in its absence. Hence linear partial ligation products can be excised from the gel after electrophoresis to generate recombinant DNA molecules directly in mammalian cells.

Mammalian cell functions mediating recombination of genetic elements: topological restraints.

In extending the scope of our previous analyses of the functions that mammalian cells engender to recombine elements of genetic information (Upcroft, Carter and Kidson, 1980a and b), I describe the capacity of cells to recognise differentially combinations of open-ended and closed molecules. The frequency of successful recombination, as assayed by the generation of viable SV40 genomes from appropriate substrates, was shown to decrease with the loss of free termini capable of invasion of an homologous DNA duplex and to be influenced by the presence of non-homologous flanking sequences, the length of homology and whether the sequence was internal or terminal. The effect of stabilisation with long homologous regions on recombination over short homologous regions and inter-versus intra-molecular DNA sequence homologies was also investigated.

Mammalian cell function mediating recombination of genetic elements.

Recombination of segments of the SV40 genome by a variety of mechanisms is described. These include the faithful joining of linear segments that have flush termini as opposed to previously described cohesive or resected termini. Lack of involvement of viral proteins has been demonstrated for recombination of segments with homologous overlapping termini, but probably applies also to the other joining reactions. Segments of the genome that have been cleaved in such a manner as to be unable to manufacture any known viral proteins are neutral elements of genetic information, incapable of selection by replication or biological function until recombined. These recombination functions presumably are available to the host cell and any element of genetic information that can be generated in that cell.

Analysis of recombination in mammalian cells using SV40 genome segments having homologous overlapping termini.

Segments of SV40 DNA having homologous overlapping termini recombine to produce viable genomes in monkey cells. Frequencies of recombination on either side of a deletion marker are non-random; replication and palindromes do not appear to be essential. Since recombination involves host enzymes, a suitable system has been devised for analysing host cell recombination functions.