Unequal distribution of genes and chromosomes refers to nuclear diversification in the binucleated Giardia intestinalis

The single-celled parasite Giardia intestinalis (Diplomonadida) has two equally sized nuclei in one cell. The nuclei have been considered identical. We have previously shown that they contain different chromosomal sets and proceed through the cell cycle with some asynchrony. Here, we demonstrate by fluorescence in situ hybridization that several genes from chromosome 5 are lost in one of the two nuclei of the WBc6 Giardia line. The missing segment stretches over at least 50 kb near the 5′ chromosome end. In both WB and WBc6 Giardia cell lines, chromosome 5 is trisomic in one nucleus and monosomic in the other nucleus. The described chromosomal deletion has always been observed at the monosomic chromosome in WBc6; however, the deletion was not detected in the parent line WB. The chromosomal segment was thus initially lost after biological cloning of WB, which gave rise to clone WBc6. We show that Giardia is capable of carrying out gene expression from only one nucleus. The two nuclei display a certain level of diversity, making each of them irreplaceable. The doubled karyomastigonts of diplomonads likely have separate functions both in the mastigont/flagellar organization and in chromosomal and gene content. To our knowledge, our results offer the first methodical approach to differentiating the two, so far indistinguishable nuclei.     

Giardia lamblia: autoradiographic analysis of nuclear replication

Giardia lamblia trophozoites, grown in axenic culture, were labeled for various periods of time with [3H]thymidine. After autoradiography, grains were counted over each of the two nuclei in each trophozoite. Analysis of the fraction of trophozoites labeled for each time period resulted in an estimate of a generation time of 15 hr. The DNA synthetic or S phase for a trophozoite in culture was calculated to be 1.8 hr. G1 and G2 periods were determined to be 8.5 and 3 hr, respectively. A comparison of the labeling density between the two nuclei indicated that replication takes place simultaneously in both nuclei for at least 70% of S period. The fraction of asymmetrically labeled trophozoites is consistent with a model in which the nuclei replicate out of phase by 15-30 min, but, due to the small diameter of the nuclei relative to the grain size, the possibility that replication takes place simultaneously in both nuclei of a trophozoite throughout the S phase cannot be ruled out.     

How nuclei of Giardia pass through cell differentiation: semi-open mitosis followed by nuclear interconnection

Differentiation into infectious cysts (encystation) and multiplication of pathogenic trophozoites after hatching from the cyst (excystation) are fundamental processes in the life cycle of the human intestinal parasite Giardia intestinalis. During encystation, a bi-nucleated trophozoite transforms to a dormant tetra-nucleated cyst enveloped by a protective cyst wall. Nuclear division during encystation is not followed by cytokinesis. In contrast to the well-studied mechanism of cyst wall formation, information on nuclei behavior is incomplete and basic cytological data are lacking. Here we present evidence that (1) the nuclei divide by semi-open mitosis during early encystment; (2) the daughter nuclei coming from different parent nuclei are always arranged in pairs; (3) in both pairs, the nuclei are interconnected via bridges formed by fusion of their nuclear envelopes; (4) each interconnected nuclear pair is associated with one basal body tetrad of the undivided diplomonad mastigont; and (5) the interconnection between nuclei persists through the cyst stage being a characteristic feature of encysted Giardia. Based on the presented results, a model of nuclei behavior during Giardia differentiation is proposed.     

Genome ploidy in different stages of the Giardia lamblia life cycle

The early diverging eukaryotic parasite Giardia lamblia is unusual in that it contains two apparently identical nuclei in the vegetative trophozoite stage. We have determined the nuclear and cellular genome ploidy of G. lamblia cells during all stages of the life cycle. During vegetative growth, the nuclei cycle between a diploid (2N) and tetraploid (4N) genome content and the cell, consequently, cycles between 4N and 8N. Stationary phase trophozoites arrest in the G₂ phase with a ploidy of 8N (two nuclei, each with a 4N ploidy). On its way to cyst formation, a G₁ trophozoite goes through two successive rounds of chromosome replication without an intervening cell division event. Fully differentiated cysts contain four nuclei, each with a ploidy of 4N, resulting in a cyst ploidy of 16N. The newly excysted cell, for which we suggest the term 'excyzoite', contains four nuclei (cellular ploidy 16N). In a reversal of the events occurring during encystation, the excyzoite divides twice to form four trophozoites containing two diploid nuclei each. The formation of multiple cells from a single cyst is likely to be one of the main reasons for the low infectious doses of G. lamblia .     

Nuclear matrix of the most primitive eukaryote Archezoa

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Participation of the adhesive disc during karyokinesis in Giardia lamblia

Evidence is presented for a potential involvement of the adhesive disc on the nucleus division in Giardia lamblia. The trophozoite mitotic nucleus was studied by transmission electron microscopy, freeze-fracture, freeze-substitution and also by immunofluorescence microscopy using anti-tubulin antibodies specific to spindle microtubules and Panotic staining. Prior to cell division the nucleus elongated and a displaced disc fragment, established contact with the nucleus. A progressive nucleus indentation was coincident with the concomitant presence of a disc fragment at the constricted region. One nucleus each time progressively divided until the karyokinesis was finished and two daughter-nuclei were observed. After the first karyokinesis a second karyokinesis takes place following the same procedure. When Giardia gets the four nuclei, cytokinesis occurs. Duplicated basal bodies were seen in between the first and the second karyokinesis. Immunofluorescence microscopy, using a panel of anti-tubulin antibodies, and electron microscopy of cells processed using microtubule stabilizer buffers, or cells fast-frozen and freeze-substituted, did not reveal the presence of a typical spindle. We propose that Giardia lamblia presents an uncommon mitotic behavior where the adhesive disc, a microtubular structure, seems to participate in the karyokinesis process.     

Chromosome-like bodies of dysentery ameba Entamoeba histolytica

Intact and surface stretched amembraneous nuclei of Entamoeba histolytica (Rhizopoda, Lobosea, Entamoebidae) trophozoites were studied by light and electron microscopy. A moderately dense karyosome about 1.5 microns in diameter, localized in the central part of the interphase nucleus, contains the bulk of nuclear DNA. Within the karyosome, beaded and ribbon-like chromatin bodies surrounding a loose fibrillar core are commonly recognized. The peripheral domain of both interphase and several mitotic nuclei is filled with a heterogeneous material similar in its ultrastructure to the nucleolar substance. A wide fibrogranular domain lies between this unusual nucleolus and the karyosome. Rosette-like intranuclear inclusions 0.2-0.4 micron in diameter are often seen in both the fibrogranular and nucleolar domains. At the prophase-metaphase, nearly 50 linear chromosome-like bodies are detected as being in close association with several large beaded and ribbon-like chromatin bodies. At the anaphase-telophase, the chromatin bodies per surface-stretched daughter nucleus of live entamoebae, and in each amembraneous daughter nuclear preparation number nearly 14 and 6, respectively. Besides, in each amembraneous DAPI-stained nucleus a set of 50 or so linear chromosome-like bodies are clearly identified. We infer that the nucleus of E. histolytica contains more than 50 linear chromosomes which at different stages of the cell cycle can unite into several beaded and ribbon-like associations. These form a single moderately dense chromatin karyosome in the central part of the interphase nucleus.     

The Giardia lamblia genome

Giardia lamblia is a protozoan parasite of humans and other mammals that is thought to be one of the most primitive extant eukaryotic organisms. Although distinctly eukaryotic, it is notable for its lack of mitochondria, nucleoli, and perixosomes. It has been suggested that Giardia spp. are pre-mitochondriate organisms, but the identification of genes in G. lamblia thought to be of mitochondrial origin has generated controversy regarding that designation. Giardi lamblia trophozoites have two nuclei that are identical in all ways that have been studied. They are polyploid with at least four, and perhaps eight or more, copies of each of five chromosomes per organism and have an estimated genome complexity of 1.2x10(7)bp of DNA, and GC content of 46%. There is evidence for recombination at the telomeres of some of the chromosomes, and multiple size variants of single chromosomes have been identified within cloned isolates. However, the internal regions of the chromosomes demonstrate no evidence of recombination. For example, there is no evidence for control of vsp gene expression by DNA recombination, and no evidence for rapid mutation in the vsp genes. Single pass sequences of approximately 9% of the G. lamblia genome have already been obtained. An ongoing genome project plans to obtain approximately 95% of the genome by a random approach, as well as a complete physical map using a bacterial artificial chromosome library. The results will facilitate a better understanding of the biology of Giardia spp. as well as their phylogenetic relationship to other primitive organisms.     

Characterisation of the subtelomeric regions of Giardia lamblia genome isolate WBC6

Giardia trophozoites are polyploid and have five chromosomes. The chromosome homologues demonstrate considerable size heterogeneity due to variation in the subtelomeric regions. We used clones from the genome project with telomeric sequence at one end to identify six subtelomeric regions in addition to previously identified subtelomeric regions, to study the telomeric arrangement of the chromosomes. The subtelomeric regions included two retroposons, one retroposon pseudogene, and two vsp genes, in addition to the previously identified subtelomeric regions that include ribosomal DNA repeats. The presence of vsp genes in a subtelomeric region suggests that telomeric rearrangements may contribute to the generation of vsp diversity. These studies of the subtelomeric regions of Giardia may contribute to our understanding of the factors that maintain stability, while allowing diversity in chromosome structure.     

Giardia lamblia aurora kinase: a regulator of mitosis in a binucleate parasite

Giardia lamblia is a major cause of diarrhoeal disease worldwide. Since it has no known toxin, the ability of trophozoites to colonise the human small intestine is required for its pathogenesis. Mitosis in this protozoan parasite is a unique challenge because its two equivalent nuclei and complex cytoskeleton must be duplicated and segregated accurately. Giardial mitosis is a complex and rapid event that is poorly understood at the cellular and molecular levels. Higher eukaryotes have one to three members of the highly conserved Ser/Thr aurora kinase (AK) family that regulate key aspects of mitosis and cytokinesis. Giardia has a single AK orthologue (gAK) with 61% similarity to human AK A. In addition to the conserved active site residues, activation loop and destruction-box motifs characteristic of AKs, gAK contains a unique insert near the active site region. We epitope-tagged gAK at its C-terminus and expressed it under its own promoter. During interphase, gAK localises exclusively to the nuclei, but is not phosphorylated as shown by lack of staining with an antibody specific to phosphorylated AK A (pAK). In contrast, during mitosis pAK localises to the basal bodies/centrosomes and co-localises with tubulin to the spindle. During specific stages of mitosis, giardial pAK also localised dynamically to cytoskeletal structures unique to Giardia: the paraflagellar dense rods of the anterior flagella and the median body, whose functions are unknown, as well as to the parent attachment disc. Two AK inhibitors significantly decreased giardial growth and increased the numbers of cells arrested in cytokinesis. These inhibitors appeared to increase microtubule nucleation and cell-ploidy. Our data show that gAK is phosphorylated in mitosis and suggest that it plays an important role in the Giardia cell cycle. The pleiotropic localisation of AK suggests that it may co-ordinate the reorganisation and segregation of tubulin-containing structures in mitosis. We believe this is the first report of a signalling protein regulating cell division in Giardia.     

Nuclear matrix of the most primitive eukaryoteArchezoa

Accumulating evidence suggests that unicellularArchezoa are the most primitive eukaryotes and their nuclei are of significance to the study of evolution of the eukaryotic nucleus. Nuclear matrix is an ubiquitous important structure of eukaryotic nucleus; its evolution is certainly one of the most important parts of the evolution of nucleus. To study the evolution of nuclear matrix, nuclear matrices ofArchezoa are investigated.Giardia lamblia cells are extracted sequentially. Both embedment-free section EM and whole mount cell EM of the extracted cells show that, like higher eukaryotes, this species has a residual nuclear matrix in its nucleus and rich intermediate filaments in its cytoplasm, and the two networks connect with each other to form a united network. But its nuclear matrix does not have nucleolar matrix and its lamina is not as typical as that of higher eukaryotes; Western blotting shows that lamina ofGiardia and two otherArchezoa Entanzoeba invadens andTrichomonas vaginali all contain only one polypeptide each which reacts with a mammalia anti-lamin polyclonal serum and is similar to lamin B (67 ku) of rnammiia in molecular weight. According to the results and references, it is suggested that nuclear matrix is an early acquisition of the eukaryotic nucleus, and it and the “eukaryotic chromatin” as a whole must have originated very early in the process of evolution of eukaryotic cell, and their origin should be an important prerequisite of the origin of eukaryotic nucleus: in the lamin (gene) family, B-type lamins (gene) should be the ancestral typz and that A-type lamins (gene) might derive therefrom.     

Respiration in the cysts and trophozoites of Giardia muris

Cysts and trophozoites of the parasitic protozoon Giardia muris both showed respiratory activity but respiration in cysts was only 10 to 20% that of trophozoites. The O2 dependence of respiration in cysts and trophozoites showed O2 maxima above which respiration decreased. The O2 concentration at which the respiration rate was greatest was higher for cysts than trophozoites. The effects of various inhibitors on cyst and trophozoite respiration suggested that flavoproteins and quinones play some role in respiration. The substrate specificities and the effects of inhibitors on G. muris trophozoites were similar to those observed for Giardia lamblia. Metronidazole, the drug most commonly used in the treatment of giardiasis completely inhibited respiration and motility in trophozoites; however, it had no effect on either respiration or viability in cysts. Menadione, a redox cycling naphthoquinone, stimulated then completely inhibited respiration in cysts and trophozoites; a complete loss of cyst viability or trophozoite motility was also observed. The effects of menadione on G. muris may indicate that redox cycling compounds have potential as chemotherapeutic agents for the treatment of giardiasis.     

Distribution of rDNA in the nucleus of Giardia lamblia: detection by Ag-I silver stain.

Previous investigations have proved that diplomonads have primitive cell nuclei and lack a nucleolus. We determined the distribution of ribosomal DNA (rDNA) in diplomonad nuclei that lacked a nucleolus. Giardia lamblia was used as the experimental organism with Euglena gracilis as the control. The distribution of rDNA was demonstrated indirectly by the modified Ag-I silver technique that can indicate specifically the nucleolus organizing region (NOR) by both light and electron microscopy. In ultrathin sections of silver stained Euglena cells, all silver grains were concentrated in the fibrosa of the nucleolus, while no silver grains were found in the cytoplasm, nucleoplasm, condensed chromosomes or pars granulosa of the nucleus. In the silver stained Giardia cells, no nucleolus was found, but a few silver grains were scattered in the nucleus. This suggests that the rDNA of Giardia does not form an NOR-like structure and that its nucleus is in a primitive state.     

The nuclei of <Emphasis Type="Italic">Giardia lamblia</Emphasis>—new ultrastructural observations

Giardia lamblia is a parasite possessing a complex cytoskeleton and an unusual morphology of bearing two nuclei. Here, the interphasic nuclei of trophozoites, using field emission scanning electron microscopy, routine scanning and transmission electron microscopy, immunocytochemistry, and 3D reconstruction, are presented. An approach using plasma-membrane extraction allowed the observation of the two nuclei still attached in their original positions. The observations are as follows: (1) Giardia nuclei and cytoskeleton were studied in demembranated cells by routine scanning electron microscopy and field emission; (2) both nuclei are anchored to basal bodies of the anterior flagella and to the descending posterior-lateral and ventral flagella, at the right and left nuclei, respectively, in cells attached by its ventral disc; (3) this attachment occurs by proteinaceous links, which were labeled by anti-actin and anti-centrin but not by anti-dynein or anti-tubulin antibodies; (4) fibrilar connections between the nuclei and the disc were also observed; and (5) nuclei exhibited a pendular movement when living cells were treated with cytochalasin, although the nuclei were still connected by their anterior region. Our analysis indicated that the nuclei have a defined position, and fibrils perform an anchoring system. This raises the possibility of a mechanism for nuclei-fidelity migration during mitosis.     

Axenic culture and characterization of Giardia ardeae from the great blue heron (Ardea herodias)

Trophozoites of Giardia ardeae were obtained from the great blue heron (Ardea herodias) and established in axenic culture using the TYI-S-33 medium. The generation time in culture for G. ardeae was 22-25 hr, which was 3-fold longer than for Giardia duodenalis (WB strain). A morphological comparison of trophozoites in the original intestinal isolate to those grown in culture revealed that they were identical for the following characteristics: a pyriform-shaped body, a ventral adhesive disc with a deep notch in the posterior border, teardrop-shaped nuclei, pleomorphism in median body structure ranging from a round-oval appearance (Giardia muris type) to that of a clawhammer (G. duodenalis type), and a single caudal flagellum on the right side (as viewed dorsally) with the left one being rudimentary. Analysis of the chromosomal migration patterns was performed by orthogonal-field-alternation gel electrophoresis and demonstrated that the pattern for G. ardeae was distinctly different from that for G. duodenalis (Portland 1-CCW strain). Bacterial symbionts were seen attached to trophozoites in the original isolate but could not be detected in cultured trophozoites using scanning electron microscopy, fluorescence light microscopy using the Hoechst 33258 dye for DNA localization, or by standard microbiological techniques using nonselective media for growing aerobic or anaerobic bacteria. This study demonstrated that avian-derived Giardia could be grown in axenic culture; based on morphological criteria and chromosomal migration patterns, that G. ardeae should be considered a distinct species; and that rationale for determining Giardia spp., based on median body structure alone, should no longer be considered adequate for classification at the species level.     

Studies in Fertilization of Fokienia

Material of Fokienia hodginsii was collected in 1964 from Fengyangshan (alt. 1000–1400 M) in Lungchuan county, Chekiang province. This paper deals with the fertilization in Fokienia. It includs the structure of male and female gametes as wed1 as the process of fusion of their nuclei and cytoplasm respectively. The division of the spermatogenous cell of Fokienia occurred by the end of June (1964) and two sperms similar in shape and size were formed when pollen tube reached the top of archegonia. Two equalsperms look like two hemispherical bodies conjoined togather. The sperm possesses cell wall and is about 65 μ in diameter. Its nucleus is rather large and about 45–50 μ in diameter. There is a nucleolus in the nucleus. Outside the nucleus the dense cytoplasm forms the deep colored zone, some 10 μ in thickness. This zone is separated from the nucleus by a narrow perinuclear zone, and from the plasmalemma by a marginal zone. The perinuclear zone is about 2 μ thick, and the mariginal zone is from 3 to 4 μ thick. Both zones have transparent cytoplasm. When the archegonium is formed, the central cell has a small nucleus which is located below the neck ceils. At the middle of June (1964), the central cell divides to form the ventral nucleus and the egg nucleus. The egg nucleus sites primarily at the upper part of archegoninm and has only one nucleolus. Then the egg nucleus increases gradually in sim and moves to the central part of the archegoninm. In mature archegonium there are usually 4–5, rarely 6–7 nucleoli in the egg nucleus, each of them is about 15 μ in diameter. The egg cell in Fokienia hodginsii is about 500 in length. The female nucleus is larger than the male one. After egg cell matures, its cytoplasm increases gradually, while the central vacuole decreases gradually and almost disappears completely after fertilization. It is interesting to note that there are 1–2 dense cytoplasm masses at the upper or lower part of egg nucleus. The shape of the mass is similar to that of the egg nucleus but no membrane is formed. These cytoplasm masses are about 50–70 μ in diameter in some cases. The fertilization of Fokienia took place at the end of June when the growing tip of pollen tube had reached the top of the archegoninm. Then the neck cells become disorganized and degenerated. It is possible that all the cytoplasmic contents of pollen tubes are released into the archegoninm. Before fertilization, the cytoplasm around the sperms and sterile cell and tube nucleus are in front of these two sperms. Then the sperms separate from each other and come down into the cytoplasm of the egg. When the mede nucleus contacts with the egg nucleus, both become flattened along their contact surface. Then the nuclear membranes of both sperm and egg nuclei become ultimately disintegrated. Thus the fusion process is complete. However, it is nia, though the opposite is the case in an exceptional example. When the sperm nucleus passes into the cytoplasm of egg cell, its cytopasm is released inside the archegonium along with it. During the course of fusion of the male and female nuclei, tile fertilized nucleus is surrounded by both female and male cytoplasm. Thus the male cytoplasm along with the peripheral cytoplasm of the egg cell invests the two nuclei lying in contact and forms a dense neocytoplasm. When the zygote divides, the neoeytoplasm is full of the starch grains and a dense cytoplasm sheath is formed. After fertilization, the fused nucleus moves toward the base of the egg cell. It seems that the movement of the fused nucleus is not a simple mechanical movement but turned over repeatedly toward the base of the arehegonium. Sometimes the position of the sperm and egg nuclei makes a turn of 180. At the same time the track of the fertilized egg nucleus with vacuoles in the archegonium may be traced. After zygote moves into basal part of the archegonium, first intranuclear mitosis occurs. The nuclear envelop of zygote disappears gradually at the telophase of the first mitosis. Then division of the free nuclei of proembryo follows. From fertilization to the stage of proembryo formation, the second sperm may sometimes enter into the cytoplasm of the egg cell. Mitosis of the second sperm nucleus may take place in the upper part of the archegonium. In addition, there are often several supernmnerary nuclei (as many as 7–8 in number) in the same egg cell. These nuclei are also surrounded by dense cytoplasm. They may persist for some time and be recognizable at somewhat later stages of the proembryo or even after the elongated suspensors are formed. In some cases, there are some cell groups above the upper tier of proembryo. These cell groups are also surrounded by dense cytoplasm. Either the supernumerary nuclei or cells are surrounded by the dense cytoplasm. Probably they are derived from the mitosis or amitosis of the second sperm. Investigations on submicroscopic structures of sperm and egg in relation to the fertilization of Cupressaceae have been carried out extensively during the last decade. The fate of male cytoplasm has been debated for a long time and this problem attracted attention again in the nineteen seventies. At last the concept of neocytoplasm has been established soundly based upon the information from observation of electron microphotographs. The neocytoplasm is also visible under the light microscope though the components are not recognizable. The sperms of Fokienia are similar to those of Cupressus funebris, Juniperus communis, Sabina virginiana, Tetraclinis articulata, Chamaecyparis pisifera as well as the genus Thujopsis and others. Two sperms are all effective in fertilization and this is the common phenomenon of the family Gupressaceae.     

Prevalence of Giardia spp. in beaver and muskrat populations in northeastern states and Minnesota: detection of intestinal trophozoites at necropsy provides greater sensitivity than detection of cysts in fecal samples.

Surveys of the prevalence of the intestinal protozoan Giardia spp. in animal populations have relied almost exclusively on the detection of cysts in fecal samples. We have determined the prevalence of Giardia spp. in beaver and muskrat populations in four northeastern states and Minnesota by using both the detection of trophozoites in mucosal scrapings from live-trapped animals at necropsy and the detection of cysts in fecal samples collected from kill-trapped animals. In muskrats the prevalence of Giardia infection was 36.6% by cyst detection in fecal samples (n = 790) from kill-trapped animals and 95.9% in live-trapped muskrats when the intestinal contents were analyzed for the presence of trophozoites (n = 219). Similarly, in beavers, Giardia infection was 9.2% by cyst detection in fecal samples (n = 662) from kill-trapped beavers and 13.7% in live-trapped animals examined for the presence of intestinal trophozoites (n = 302). The detection of trophozoites in mucosal scrapings from live-trapped animals consistently yielded a significantly higher prevalence for both muskrats and beavers than did the method based on detection of cysts in the fecal samples. The prevalence of Giardia infection in juvenile and adult live-trapped muskrats was similar (92.5 and 94.4%, respectively), but the prevalence in juvenile live-trapped beavers (23.2%) was significantly greater than that seen in the adult animals (12.6%). No difference in Giardia prevalence on the basis of sex was seen in either animal species. Regional variation, often statistically significant, was seen in the prevalence of Giardia in beavers in the northeastern states and Minnesota, but was not detected for muskrats.     

Prevalence of Giardia spp. in beaver and muskrat populations in northeastern states and Minnesota: detection of intestinal trophozoites at necropsy provides greater sensitivity than detection of cysts in fecal samples

Surveys of the prevalence of the intestinal protozoan Giardia spp. in animal populations have relied almost exclusively on the detection of cysts in fecal samples. We have determined the prevalence of Giardia spp. in beaver and muskrat populations in four northeastern states and Minnesota by using both the detection of trophozoites in mucosal scrapings from live-trapped animals at necropsy and the detection of cysts in fecal samples collected from kill-trapped animals. In muskrats the prevalence of Giardia infection was 36.6% by cyst detection in fecal samples (n = 790) from kill-trapped animals and 95.9% in live-trapped muskrats when the intestinal contents were analyzed for the presence of trophozoites (n = 219). Similarly, in beavers, Giardia infection was 9.2% by cyst detection in fecal samples (n = 662) from kill-trapped beavers and 13.7% in live-trapped animals examined for the presence of intestinal trophozoites (n = 302). The detection of trophozoites in mucosal scrapings from live-trapped animals consistently yielded a significantly higher prevalence for both muskrats and beavers than did the method based on detection of cysts in the fecal samples. The prevalence of Giardia infection in juvenile and adult live-trapped muskrats was similar (92.5 and 94.4%, respectively), but the prevalence in juvenile live-trapped beavers (23.2%) was significantly greater than that seen in the adult animals (12.6%). No difference in Giardia prevalence on the basis of sex was seen in either animal species. Regional variation, often statistically significant, was seen in the prevalence of Giardia in beavers in the northeastern states and Minnesota, but was not detected for muskrats.