Kari D. Hagen

Chrysiogenes arsenatis gen. nov., sp. nov., a new arsenate-respiring bacterium isolated from gold mine wastewater.

A new strictly anaerobic bacterium (strain BAL-1T) has been isolated from a reed bed at Ballarat Goldfields in Australia. The organism grew by reducing arsenate [As(V)] to arsenite [As(III)], using acetate as the electron donor and carbon source; acetate alone did not support growth. When BAL-1T was grown with arsenate as the terminal electron acceptor, acetate could be replaced by pyruvate, L- and D-lactate, succinate, malate, and fumarate but not by H2, formate, citrate, glutamate, other amino acids, sugars, or benzoate. When acetate was the electron donor, arsenate could be replaced by nitrate or nitrite but not by sulfate, thiosulfate, or iron oxide. Nitrate was reduced to ammonia via nitrite. The doubling time for growth on acetate (5 mM) plus arsenate (5 mM) or nitrate (5 mM) was 4 h. The G+C content of the DNA is 49 mol%. The 16S rRNA sequence data for the organism support the hypothesis that this organism is phylogenetically unique and at present is the first representative of a new deeply branching lineage of the Bacteria. This organism is described as Chrysiogenes arsenatis gen. nov., sp. nov.

The Unique Cyanobacterial Protein OpcA is an Allosteric Effector of Glucose-6-Phosphate Dehydrogenase in Nostoc punctiforme ATCC 29133

Glucose-6-phosphate dehydrogenase (G6PD), encoded by zwf, is essential for nitrogen fixation and dark heterotrophic growth of the cyanobacterium Nostoc punctiforme ATCC 29133. In N. punctiforme,zwf is part of a four-gene operon transcribed in the orderfbp-tal-zwf-opcA. Genetic analyses indicated thatopcA is required for G6PD activity. To define the role ofopcA, the synthesis, aggregation state, and activity of G6PD in N. punctiforme strains expressing different amounts of G6PD and/or OpcA were examined. A single tetrameric form of G6PD was consistently observed for all strains, as well as for recombinantN. punctiforme His-G6PD purified from Escherichia coli, regardless of the quantity of OpcA present. However, His-G6PD and the G6PD of strain UCD 351, which lacks OpcA, had low affinities for glucose 6-phosphate (G6P) substrate (K m (app) = 65 and 85 mm, respectively) relative to wild-type N. punctiforme G6PD (K m (app) = 0.5 mm). Near wild-type affinities for G6P were observed for these enzymes when saturating amounts of His-OpcA- or OpcA-containing extract were added. Kinetic studies were consistent with OpcA acting as an allosteric activator of G6PD. A role in redox modulation of G6PD activity was also indicated, because thioredoxin-mediated inactivation and reactivation of His-G6PD occurred only when His-OpcA was present.

Genetic Analysis Reveals the Identity of the Photoreceptor for Phototaxis in Hormogonium Filaments of Nostoc punctiforme

In cyanobacterial Nostoc species, substratum-dependent gliding motility is confined to specialized nongrowing filaments called hormogonia, which differentiate from vegetative filaments as part of a conditional life cycle and function as dispersal units. Here we confirm that Nostoc punctiforme hormogonia are positively phototactic to white light over a wide range of intensities. N. punctiforme contains two gene clusters (clusters 2 and 2i), each of which encodes modular cyanobacteriochrome-methyl-accepting chemotaxis proteins (MCPs) and other proteins that putatively constitute a basic chemotaxis-like signal transduction complex. Transcriptional analysis established that all genes in clusters 2 and 2i, plus two additional clusters (clusters 1 and 3) with genes encoding MCPs lacking cyanobacteriochrome sensory domains, are upregulated during the differentiation of hormogonia. Mutational analysis determined that only genes in cluster 2i are essential for positive phototaxis in N. punctiforme hormogonia; here these genes are designated ptx (for phototaxis) genes. The cluster is unusual in containing complete or partial duplicates of genes encoding proteins homologous to the well-described chemotaxis elements CheY, CheW, MCP, and CheA. The cyanobacteriochrome-MCP gene (ptxD) lacks transmembrane domains and has 7 potential binding sites for bilins. The transcriptional start site of the ptx genes does not resemble a sigma 70 consensus recognition sequence; moreover, it is upstream of two genes encoding gas vesicle proteins (gvpA and gvpC), which also are expressed only in the hormogonium filaments of N. punctiforme.

Novel Structural Components of the Ventral Disc and Lateral Crest in Giardia intestinalis

Giardia intestinalis is a ubiquitous parasitic protist that is the causative agent of giardiasis, one of the most common protozoan diarrheal diseases in the world. Giardia trophozoites attach to the intestinal epithelium using a specialized and elaborate microtubule structure, the ventral disc. Surrounding the ventral disc is a less characterized putatively contractile structure, the lateral crest, which forms a continuous perimeter seal with the substrate. A better understanding of ventral disc and lateral crest structure, conformational dynamics, and biogenesis is critical for understanding the mechanism of giardial attachment to the host. To determine the components comprising the ventral disc and lateral crest, we used shotgun proteomics to identify proteins in a preparation of isolated ventral discs. Candidate disc-associated proteins, or DAPs, were GFP-tagged using a ligation-independent high-throughput cloning method. Based on disc localization, we identified eighteen novel DAPs, which more than doubles the number of known disc-associated proteins. Ten of the novel DAPs are associated with the lateral crest or outer edge of the disc, and are the first confirmed components of this structure. Using Fluorescence Recovery After Photobleaching (FRAP) with representative novel DAP::GFP strains we found that the newly identified DAPs tested did not recover after photobleaching and are therefore structural components of the ventral disc or lateral crest. Functional analyses of the novel DAPs will be central toward understanding the mechanism of ventral disc-mediated attachment and the mechanism of disc biogenesis during cell division. Since attachment of Giardia to the intestine via the ventral disc is essential for pathogenesis, it is possible that some proteins comprising the disc could be potential drug targets if their loss or disruption interfered with disc biogenesis or function, preventing attachment.

Transcriptomic Profiling of High-Density Giardia Foci Encysting in the Murine Proximal Intestine

Giardia is a highly prevalent, understudied protistan parasite causing significant diarrheal disease worldwide. Its life cycle consists of two stages: infectious cysts ingested from contaminated food or water sources, and motile trophozoites that colonize and attach to the gut epithelium, later encysting to form new cysts that are excreted into the environment. Current understanding of parasite physiology in the host is largely inferred from transcriptomic studies using Giardia grown axenically or in co-culture with mammalian cell lines. The dearth of information about the diversity of host-parasite interactions occurring within distinct regions of the gastrointestinal tract has been exacerbated by a lack of methods to directly and non-invasively interrogate disease progression and parasite physiology in live animal hosts. By visualizing Giardia infections in the mouse gastrointestinal tract using bioluminescent imaging (BLI) of tagged parasites, we recently showed that parasites colonize the gut in high-density foci. Encystation is initiated in these foci throughout the entire course of infection, yet how the physiology of parasites within high-density foci in the host gut differs from that of cells in laboratory culture is unclear. Here we use BLI to precisely select parasite samples from high-density foci in the proximal intestine to interrogate in vivo Giardia gene expression in the host. Relative to axenic culture, we noted significantly higher expression (>10-fold) of oxidative stress, membrane transporter, and metabolic and structural genes associated with encystation in the high-density foci. These differences in gene expression within parasite foci in the host may reflect physiological changes associated with high-density growth in localized regions of the gut. We also identified and verified six novel cyst-specific proteins, including new components of the cyst wall that were highly expressed in these foci. Our in vivo transcriptome data support an emerging view that parasites encyst early in localized regions in the gut, possibly as a consequence of nutrient limitation, and also impact local metabolism and physiology.

Robust and stable transcriptional repression in Giardia using CRISPRi

Giardia lamblia is a binucleate protistan parasite causing significant diarrheal disease worldwide. An inability to target Cas9 to both nuclei, combined with the lack of non-homologous end joining and markers for positive selection, has stalled the adaptation of CRISPR/Cas9-mediated genetic tools for this widespread parasite. CRISPR interference (CRISPRi) is a modification of the CRISPR/Cas9 system that directs catalytically inactive Cas9 (dCas9) to target loci for stable transcriptional repression. Using a Giardia nuclear localization signal to target dCas9 to both nuclei, we developed efficient and stable CRISPRi-mediated transcriptional repression of exogenous and endogenous genes in Giardia. Specifically, CRISPRi knockdown of kinesin-2a and kinesin-13 causes severe flagellar length defects that mirror defects with morpholino knockdown. Knockdown of the ventral disc MBP protein also causes severe structural defects that are highly prevalent and persist in the population more than five days longer than transient morpholino-based knockdown. By expressing two gRNAs in tandem to simultaneously knock down kinesin-13 and MBP, we created a stable dual knockdown strain with both flagellar length and disc defects. The efficiency and simplicity of CRISPRi in polyploid Giardia allows for rapid evaluation of knockdown phenotypes and highlights the utility of CRISPRi for emerging model systems.

Giardia's ventral disc is hyperstable and composed of over 80 disc-associated proteins

Giardia is a common protistan parasite that causes diarrheal disease worldwide. Motile trophozoites colonize the small intestine, attaching to the villi with the ventral disc, a unique and complex microtubule (MT) organelle. Attachment to the host epithelium allows Giardia to resist peristalsis during infection of the host gastrointestinal tract. Despite our emerging view of the complexity of ventral disc architecture, we are still in the very preliminary stages of understanding how specific structural elements contribute to disc stability or generate forces for attachment. The ventral disc is a large, dome-shaped, spiral MT array decorated with microribbon-crossbridge protein complexes (MR-CB) that extend upward into the cytoplasm. Using a new high salt method for disc biochemical fractionation followed by shotgun proteomic analyses and validation by GFP-tagging, we identified 54 new disc-associated proteins (DAPs). Of 87 DAPs confirmed to date, 54 localize only to the disc, and the remainder localize to additional structures such as the flagella, basal bodies, or median body. Almost one third of DAPs lack any homology to proteins in other eukaryotes and another one third simply contain ankyrin repeat domains. Many DAPs localize to specific structural regions of the disc, including the ventral groove region and disc margin. We also demonstrate that the disc is a stable structure lacking canonical MT dynamic instability and show that the disc structure and composition remain intact after detergent extraction in up to 2M potassium chloride. Future genetic, biochemical, and functional analyses of DAPs will be central toward understanding disc architecture, assembly and dynamics.Giardia is a common protistan parasite that causes diarrheal disease worldwide. Motile trophozoites colonize the small intestine, attaching to the villi with the ventral disc, a unique and complex microtubule (MT) organelle. Attachment to the host epithelium allows Giardia to resist peristalsis during infection of the host gastrointestinal tract. Despite our emerging view of the complexity of ventral disc architecture, we are still in the very preliminary stages of understanding how specific structural elements contribute to disc stability or generate forces for attachment. The ventral disc is a large, dome-shaped, spiral MT array decorated with microribbon-crossbridge protein complexes (MR-CB) that extend upward into the cytoplasm. To find additional disc-associated proteins (DAPs), we used a modified method for disc biochemical fractionation in high salt followed by shotgun proteomic analyses and validation by GFP-tagging. Using this method in conjunction with an ongoing subcellular localization screen, we identified 54 new DAPs. Of the 87 DAPs confirmed to date, 54 localize only to the disc, and the remainder localize to additional structures including the flagella, basal bodies, or median body. Almost one third of the known DAPs lack any homology to proteins in other eukaryotes and another one third simply contain ankyrin repeat domains. Many DAPs localize to specific structural regions of the disc, including the ventral groove region and disc margin. Lastly, we show that spiral singlet MT array comprising the disc is hyperstable and lacks dynamic instability, and we attribute these unique properties to the presence of both novel DAPs as well conserved MAPs and MIPs that are known to stabilize ciliary doublet and triplet MTs.Giardia is a common protistan parasite that causes diarrheal disease worldwide. Motile trophozoites colonize the small intestine, attaching to the villi with the ventral disc, a complex microtubule (MT) organelle. Attachment is required for infection as it allows Giardia to resist peristalsis. Parallel, uniformly spaced MTs spiral to form a domed structure, with one overlap zone between the upper and lower portions, and the ventral groove region extending over the ventral flagella. The MT spiral is coated with novel microribbon-crossbridge protein complexes (MR-CB) that extend up to 400 nm into the cytoplasm. The highly ordered lateral crest lies outside the disc margin at the disc periphery, and forms a seal in early staged of parasite attachment. The disc is a hyperstable structure in that drugs that normally affect MT dynamic instability have no effect on ventral disc microtubules and no turnover of any disc-associated protein has been reported. Here we show that much of the ventral disc structure remains intact after detergent extraction in up to 2M potassium chloride. Using a new method of disc biochemical fractionation in high salt with shot-gun proteomic analysis of the disc, we identified and confirmed 55 new disc-associated protein (DAPs), bringing the current total of DAPs to 87. While close to 30 DAPs also localize with flagella, 54 DAPs localize specifically to the disc. Most also localize to specific structural regions of the disc such as the ventral groove or disc margin. Despite our developing understanding of the complexity of ventral disc architecture, we are still in the very preliminary stages of understanding the and composition and contribution of specific structural elements in generating the forces for attachment and stability. Future genetic, biochemical, and functional analyses of DAPs will be central toward understanding not only disc architecture and assembly, but also the overall disc conformational dynamics that promote host attachment.

‘Disc-o-Fever’: Getting Down with Giardia’s Groovy Microtubule Organelle

Protists have evolved a myriad of highly specialized cytoskeletal organelles that expand known functional capacities of microtubule (MT) polymers. One such innovation - the ventral disc - is a cup-shaped MT organelle that the parasite Giardia uses to attach to the small intestine of its host. The molecular mechanisms underlying the generation of suction-based forces by overall conformational changes of the disc remain unclear. The elaborate disc architecture is defined by novel proteins and complexes that decorate almost all disc MT protofilaments, and vary in composition and conformation along the length of the MTs. Future genetic, biochemical, and functional analyses of disc-associated proteins will be central toward understanding not only disc architecture and assembly, but also the overall disc conformational dynamics that promote attachment.