Digestion of glycogen by a glucosidase released by Trichomonas vaginalis.

Trichomonas vaginalis is a protozoan parasite that is the causative agent of trichomoniasis, a widespread sexually transmitted disease. In vitro culture of T. vaginalis typically employs a medium supplemented with either maltose or glucose and carbohydrates are considered essential for growth. Although the nature of the carbohydrates utilized by T. vaginalis in vivo is undefined, the vaginal epithelium is rich in glycogen, which appears to provide a source of carbon for the vaginal microbiota. Here, we show that T. vaginalis grows equally well in growth media supplemented with simple sugars or with glycogen. Analysis of conditioned growth medium by thin layer chromatography indicates that growth on glycogen is accompanied by glycogen breakdown to a mixture of products including maltose, glucose, and oligosaccharides. Enzymatic assays with conditioned growth medium show that glycogen breakdown is accomplished via the release of a glucosidase activity having the properties of an α-amylase into the growth medium. Furthermore, we find that released glucosidase activity increases upon removal of carbohydrate from the growth medium, indicating regulation of synthesis and/or secretion in response to environmental cues. Lastly, we show that addition of T. vaginalis glucosidase activity to a growth medium containing glycogen generates sufficient simple sugar to support the growth of lactobacilli which, themselves, are unable to degrade glycogen. Thus, not only does the glucosidase activity likely play an important role in allowing T. vaginalis to secure simple sugars for its own use, it has the potential to impact the growth of other members of the vaginal microbiome.

The antimicrobial effect of boric acid on Trichomonas vaginalis.

BACKGROUND: The treatment options for trichomoniasis are largely limited to nitroimidazole compounds (metronidazole and tinidazole). Few alternatives exist in cases of recalcitrant infections or in cases of nitroimidazole hypersensitivity. Recently, the intravaginal administration of boric acid has been advocated as an alternative treatment of trichomoniasis. However, no in vitro studies are available that directly assess the sensitivity of Trichomonas vaginalis to boric acid. METHODS: We examined the sensitivity of common laboratory strains and recent clinical isolates of T. vaginalis to boric acid. The effect of increasing concentrations of boric acid on parasite growth and viability was determined, and a minimal lethal concentration was reported. The effect of pH on boric acid toxicity was assessed and compared with that of lactic and acetic acid. RESULTS: Boric acid is microbicidal to T. vaginalis, and its antitrichomonal activity is independent of environmental acidification. Unlike acetic acid and lactic acid, boric acid exposure results in growth suppression and lethality over a wide range of pH (5-7) and under conditions that are normally permissible for growth in vitro. CONCLUSIONS: The microbicidal effect of boric acid on T. vaginalis, coupled with its previous clinical use in treating vaginal candidiasis, supports the continued inclusion of boric acid in the therapeutic arsenal for treating trichomoniasis.

Expression and characterization of a ß-fructofuranosidase from the parasitic protist Trichomonas vaginalis.

BACKGROUND: Trichomonas vaginalis, a flagellated protozoan, is the agent responsible for trichomoniasis, the most common nonviral sexually transmitted infection worldwide. A reported 200 million cases are documented each year with far more cases going unreported. However, T. vaginalis is disproportionality under studied, especially considering its basic metabolism. It has been reported that T. vaginalis does not grow on sucrose. Nevertheless, the T. vaginalis genome contains some 11 putative sucrose transporters and a putative ß-fructofuranosidase (invertase). Thus, the machinery for both uptake and cleavage of sucrose appears to be present. RESULTS: We amplified the ß-fructofuranosidase from T. vaginalis cDNA and cloned it into an Escherichia coli expression system. The expressed, purified protein was found to behave similarly to other known ß-fructofuranosidases. The enzyme exhibited maximum activity at pH close to 5.0, with activity falling off rapidly at increased or decreased pH. It had a similar K(m) and V(max) to previously characterized enzymes using sucrose as a substrate, was also active towards raffinose, but had no detectable activity towards inulin. CONCLUSIONS: T. vaginalis has the coding capacity to produce an active ß-fructofuranosidase capable of hydrolyzing di- and trisaccharides containing a terminal, non-reducing fructose residue. Since we cloned this enzyme from cDNA, we know that the gene in question is transcribed. Furthermore, we could detect ß-fructofuranosidase activity in T. vaginalis cell lysates. Therefore, the inability of the organism to utilize sucrose as a carbon source cannot be explained by an inability to degrade sucrose.

Effectiveness of Quiz-Enhanced Videocasts for the Review of Foundational Sciences in the Podiatry Curriculum.

BACKGROUND: Integrated medical curricula commonly require the review of foundational science concepts in the context of clinical applications. A detailed analysis of the Des Moines University second-year medical curricula revealed that such reviews, conducted as hours-long basic science lectures in second-year clinical systems courses, often create undesirable redundancy and can load the curriculum with excessively detailed content. We hypothesized that short, quiz-enhanced videocasts (QEVs) would allow a more focused and efficient review of foundational sciences than traditional lectures. METHODS: Five biochemistry lectures in the second year Des Moines University Doctor of Podiatric Medicine curriculum were reviewed for relevance and redundancy, shortened to 8- to 12-min QEVs and offered to students as an alternative to the respective hours-long lecture. RESULTS: Download data show that students chose content delivery by QEV as frequently as delivery of lectures, with QEV use peaking in the days immediately preceding the exam. Survey comments show that students appreciate the efficiency and flexibility of content delivery by QEV, particularly for focused exam preparation. CONCLUSIONS: We conclude that the review of foundational concepts by means of short, interactive videocasts can reduce redundant and excessively detailed content from integrated curricula. Although the faculty effort for context review, content selection, and videocast production is higher than for the design of a traditional lecture, the end product offers students a much-appreciated opportunity for efficient, focused, and individualized learning.

Multiple glycogen-binding sites in eukaryotic glycogen synthase are required for high catalytic efficiency toward glycogen.

Glycogen synthase is a rate-limiting enzyme in the biosynthesis of glycogen and has an essential role in glucose homeostasis. The three-dimensional structures of yeast glycogen synthase (Gsy2p) complexed with maltooctaose identified four conserved maltodextrin-binding sites distributed across the surface of the enzyme. Site-1 is positioned on the N-terminal domain, site-2 and site-3 are present on the C-terminal domain, and site-4 is located in an interdomain cleft adjacent to the active site. Mutation of these surface sites decreased glycogen binding and catalytic efficiency toward glycogen. Mutations within site-1 and site-2 reduced the V(max)/S(0.5) for glycogen by 40- and 70-fold, respectively. Combined mutation of site-1 and site-2 decreased the V(max)/S(0.5) for glycogen by >3000-fold. Consistent with the in vitro data, glycogen accumulation in glycogen synthase-deficient yeast cells (Δgsy1-gsy2) transformed with the site-1, site-2, combined site-1/site-2, or site-4 mutant form of Gsy2p was decreased by up to 40-fold. In contrast to the glycogen results, the ability to utilize maltooctaose as an in vitro substrate was unaffected in the site-2 mutant, moderately affected in the site-1 mutant, and almost completely abolished in the site-4 mutant. These data show that the ability to utilize maltooctaose as a substrate can be independent of the ability to utilize glycogen. Our data support the hypothesis that site-1 and site-2 provide a "toehold mechanism," keeping glycogen synthase tightly associated with the glycogen particle, whereas site-4 is more closely associated with positioning of the nonreducing end during catalysis.

Glycogen accumulation and degradation by the trichomonads Trichomonas vaginalis and Trichomonas tenax.

Several species of trichomonad have been shown to accumulate significant quantities of glycogen during growth, suggesting an important role for this compound in cell physiology. We provide the first analysis of the changes in glycogen content and glycogen phosphorylase activity that occur during in vitro growth of two trichomonad species: Trichomonas vaginalis and Trichomonas tenax. Both species accumulated glycogen following inoculation into fresh medium and utilized this compound during logarithmic growth. Glycogen phosphorylase activity also varied during growth in a species-specific manner. The expression of phosphorylase genes in T. vaginalis remained constant during growth and thus transcriptional control did not explain the observed fluctuations in phosphorylase activity. After cloning, expression, and purification, two recombinant glycogen phosphorylases from T. vaginalis and one recombinant glycogen phosphorylase from T. tenax had robust activity and, in contrast to many other eukaryotic glycogen phosphorylases, did not appear to be regulated by reversible protein phosphorylation. Furthermore, allosteric regulation, if present, was not mediated by compounds known to impact the activity of better characterized phosphorylases.

A prematriculation intervention to improve the adjustment of students to medical school.

BACKGROUND AND PURPOSE: The transition from a baccalaureate program to a medical curriculum can be a difficult period for some students. Our study asked whether providing students with review materials and a means of assessing their degree of preparedness prior to matriculation influenced actual and perceived performance in 1st-year basic science courses. METHODS: Didactic review materials in basic science subjects encountered in the 1st year were made available to prematriculants online. Access to materials for each subject was contingent upon completion of a pretest. Prematriculants were free to use the materials as they saw fit. Once students matriculated, performance in basic science subjects was compared between those who had accessed the materials and those who had not. Students who accessed the materials were also surveyed to determine if they perceived any benefit from their use. RESULTS: More than half of matriculants chose to access the intervention materials. There was no significant difference in MCAT, prerequisite grade point average, or total grade point average between those students who chose to access the intervention materials and those who did not. Students who accessed the intervention materials reported gains in confidence in their ability to perform well in medical school. Those students who accessed the intervention materials had significantly higher examination scores in an early basic science course than those who did not. CONCLUSIONS: An online prematriculation intervention can provide useful background material to interested students. Access to this material increased performance in a 1st-year basic science course and was perceived as valuable by students.

Spectrophotometric Methods for the Study of Eukaryotic Glycogen Metabolism.

Glycogen is synthesized as a storage form of glucose by a wide array of organisms, ranging from bacteria to animals. The molecule comprises linear chains of α1,4-linked glucose residues with branches introduced through the addition of α1,6-linkages. Understanding how the synthesis and degradation of glycogen are regulated and how glycogen attains its characteristic branched structure requires the study of the enzymes of glycogen storage. However, the methods most commonly used to study these enzyme activities typically employ reagents or techniques that are not available to all investigators. Here, we discuss a battery of procedures that are technically simple, cost-effective, and yet still capable of providing valuable insight into the control of glycogen storage. The techniques require access to a spectrophotometer, operating in the range of 330 to 800 nm, and are described assuming that the users will employ disposable, plastic cuvettes. However, the procedures are readily scalable and can be modified for use in a microplate reader, allowing highly parallel analysis.

GLYCOGEN ACCUMULATION IN TRICHOMONAS IS DRIVEN BY THE AVAILABILITY OF EXTRACELLULAR GLUCOSE.

The parasitic protist Trichomonas vaginalis is the causative agent of trichomoniasis, a highly prevalent sexually transmitted infection. The organism is known to accumulate substantial deposits of the polysaccharide glycogen, which is believed to serve as a store of carbon and energy that can be tapped during periods of nutrient limitation. Such nutrient limitation is likely to occur when T. vaginalis is transmitted between hosts, implying that glycogen may play an important role in the lifecycle of the parasite. Both T. vaginalis glycogen synthase and glycogen phosphorylase, key enzymes of glycogen synthesis and degradation, respectively, have been cloned and characterized, and neither enzyme is subject to the post-translational controls found in other, well-characterized eukaryotic systems. Thus, it is unclear how glycogen metabolism is regulated in this organism. Here we use a glucose limitation/re-feeding protocol to show that the activities of key enzymes of glycogen synthesis do not increase during re-feeding when glycogen synthesis is stimulated. Rather, a simple model appears to operate with glycogen storage being driven by the extracellular glucose concentration.

Cloning and characterization of glycogen branching and debranching enzymes from the parasitic protist Trichomonas vaginalis.

The protist Trichomonas vaginalis is an obligate parasite of humans and the causative agent of trichomoniasis, a common sexually transmitted infection. The organism has long been known to accumulate glycogen, a branched polymer of glucose, and to mobilize this reserve in response to carbohydrate limitation. However, the enzymes required for the synthesis and degradation of glycogen by T. vaginalis have been little studied. Previously, we characterized T. vaginalis glycogen synthase and glycogen phosphorylase, the key enzymes of glycogen synthesis and degradation, respectively. We determined that their regulatory properties differed from those of well-characterized animal and fungal enzymes. Here, we turn our attention to how glycogen attains its branched structure. We first determined that the glycogen from T. vaginalis resembled that from a related organism, T. gallinae. To determine how the branched structure of T. vaginalis glycogen arose, we identified open reading frames encoding putative T. vaginalis branching and debranching enzymes. When the open reading frames TVAG_276310 and TVAG_330630 were expressed recombinantly in bacteria, the resulting proteins exhibited branching and debranching activity, respectively. Specifically, recombinant TVAG_276310 had affinity for polysaccharides with long outer branches and could add branches to both amylose and amylopectin. TVAG_330630 displayed both 4-α-glucanotransferase and α1,6-glucosidase activity and could efficiently debranch phosphorylase limit dextrin. Furthermore, expression of TVAG_276310 and TVAG_330630 in yeast cells lacking endogenous glycogen branching or debranching enzyme activity, restored normal glycogen accumulation and branched structure. We now have access to the suite of enzymes required for glycogen synthesis and degradation in T. vaginalis.

The subcellular localization of yeast glycogen synthase is dependent upon glycogen content.

The budding yeast, Saccharomyces cerevisiae, accumulates the storage polysaccharide glycogen in response to nutrient limitation. Glycogen synthase, the major form of which is encoded by the GSY2 gene, catalyzes the key regulated step in glycogen storage. Here, we utilized Gsy2p fusions to green fluorescent protein (GFP) to determine where glycogen synthase was located within cells. We demonstrated that the localization pattern of Gsy2-GFP depended upon the glycogen content of the cell. When glycogen was abundant, Gsy2-GFP was found uniformly throughout the cytoplasm, but under low glycogen conditions, Gsy2-GFP localized to discrete spots within cells. Gsy2p is known to bind to glycogen, and we propose that the subcellular distribution of Gsy2-GFP reflects the distribution of glycogen particles. In the absence of glycogen, Gsy2p translocates into the nucleus. We hypothesize that Gsy2p is normally retained in the cytoplasm through its interaction with glycogen particles. When glycogen levels are reduced, Gsy2p loses this anchor and can traffic into the nucleus.

Glycogen synthase from the parabasalian parasite Trichomonas vaginalis: An unusual member of the starch/glycogen synthase family.

Trichomonas vaginalis, a parasitic protist, is the causative agent of the common sexually-transmitted infection trichomoniasis. The organism has long been known to synthesize substantial glycogen as a storage polysaccharide, presumably mobilizing this compound during periods of carbohydrate limitation, such as might be encountered during transmission between hosts. However, little is known regarding the enzymes of glycogen metabolism in T. vaginalis. We had previously described the identification and characterization of two forms of glycogen phosphorylase in the organism. Here, we measure UDP-glucose-dependent glycogen synthase activity in cell-free extracts of T. vaginalis. We then demonstrate that the TVAG_258220 open reading frame encodes a glycosyltransferase that is presumably responsible for this synthetic activity. We show that expression of TVAG_258220 in a yeast strain lacking endogenous glycogen synthase activity is sufficient to restore glycogen accumulation. Furthermore, when TVAG_258220 is expressed in bacteria, the resulting recombinant protein has glycogen synthase activity in vitro, transferring glucose from either UDP-glucose or ADP-glucose to glycogen and using both substrates with similar affinity. This protein is also able to transfer glucose from UDP-glucose or ADP-glucose to maltose and longer oligomers of glucose but not to glucose itself. However, with these substrates, there is no evidence of processivity and sugar transfer is limited to between one and three glucose residues. Taken together with our earlier work on glycogen phosphorylase, we are now well positioned to define both how T. vaginalis synthesizes and utilizes glycogen, and how these processes are regulated.

Purification and identification of amylases released by the human pathogen Trichomonas vaginalis that are active towards glycogen.

The parasitic protist Trichomonas vaginalis is the causative agent of the sexually transmitted infection trichomoniasis. In the laboratory, T. vaginalis is typically cultured in a serum-containing medium with maltose or glucose as the carbon source. The nature of the carbohydrates used by the organism in the environment of its host is unclear. However, the vagina contains substantial amounts of glycogen, which is believed to provide a growth substrate for the vaginal microbiota. We have shown previously that T. vaginalis releases glucosidases that are active towards glycogen into its environment. Here we purify and identifying these glucosidases. Using ammonium sulfate precipitation and precipitation with ethanol/glycogen, we purified glucosidase activity from conditioned growth medium, achieving over 300-fold enrichment. Maltose was released when glycogen was incubated with the glucosidase preparation, indicating that a ß-amylase was present. However, after prolonged incubation, small quantities of larger products including maltotriose were obtained. Liquid chromatography and tandem mass spectrometry showed that the glucosidase preparation contained three proteins, the major component being a putative ß-amylase encoded by the TVAG_080000 open reading frame. Lesser amounts of two putative α-amylases, encoded by the TVAG_178580 and TVAG_205920 open reading frames, were also present. We cloned and expressed the TVAG_080000 open reading frame and found that the recombinant protein was capable of digesting glycogen, releasing exclusively maltose. We conclude that T. vaginalis releases a variety of amylases into its growth environment and is well equipped to utilize the glycogen found in the vagina as a source of essential carbohydrates.

Biochemical characterization of Neurospora crassa glycogenin (GNN), the self-glucosylating initiator of glycogen synthesis.

Glycogenin acts in the initiation step of glycogen biosynthesis by catalyzing a self-glucosylation reaction. In a previous work [de Paula et al., Arch. Biochem. Biophys. 435 (2005) 112-124], we described the isolation of the cDNA gnn, which encodes the protein glycogenin (GNN) in Neurospora crassa. This work presents a set of biochemical and functional studies confirming the GNN role in glycogen biosynthesis. Kinetic experiments showed a very low GNN K(m) (4.41 microM) for the substrate UDP-glucose. Recombinant GNN was produced in Escherichia coli and analysis by mass spectroscopy identified a peptide containing an oligosaccharide chain attached to Tyr196 residue. Site-directed mutagenesis and functional complementation of a Saccharomyces cerevisiae mutant strain confirmed the participation of this residue in the GNN self-glucosylation and indicated the Tyr198 residue as an additional, although less active, glucosylation site. The physical interaction between GNN and glycogen synthase (GSN) was analyzed by the two-hybrid assay. While the entire GSN was required for full interaction, the C-terminus in GNN was more important. Furthermore, mutation in the GNN glucosylation sites did not impair the interaction with GSN.

Analysis of respiratory mutants reveals new aspects of the control of glycogen accumulation by the cyclin-dependent protein kinase Pho85p.

The PHO85 gene of Saccharomyces cerevisiae encodes a cyclin-dependent protein kinase that can interact with 10 different cyclins (Pcls). In conjunction with Pcl8p and Pcl10p, Pho85p phosphorylates and regulates glycogen synthase. Respiratory-deficient strains, such as coq3 mutants, have reduced glycogen stores and contain hyperphosphorylated and inactive glycogen synthase. We show here that pho85 coq3 mutants have dephosphorylated and active glycogen synthase yet do not maintain glycogen reserves. In contrast, deletion of PCL8 and PCL10 in the coq3 mutant background partially restores glycogen accumulation. This suggested the existence of inputs from Pho85p into glycogen storage, independent of Pcl8p and Pcl10p, and acting antagonistically.

Glycogen storage and degradation during in vitro growth and differentiation of Giardia intestinalis.

Giardia intestinalis is the causative agent of human giardiasis, a common diarrheal illness worldwide. Despite its global distribution and prevalence, many questions regarding its basic biology and metabolism remain unanswered. In this study, we examine the accumulation and degradation of glycogen, an important source of stored carbon and energy, during the in vitro growth and differentiation of G. intestinalis . We report that, as G. intestinalis progresses through its growth cycle, cultures of trophozoites accumulate glycogen during the lag and early logarithmic phases of growth and then utilize this compound during their remaining logarithmic growth. As cultures enter the stationary phase of growth, they re-accumulate glycogen stores. The activity of glycogen phosphorylase, an enzyme involved in glycogen metabolism, also varied throughout in vitro trophozoite growth. During the in vitro induction of trophozoite differentiation into water-resistant cyst forms, the cultures initially accumulated stores of glycogen which diminished throughout transition to the cyst form. This observation is suggestive of a role for glycogen in the differentiation process. These studies represent the first thorough analysis of changes in glycogen content and glycogen phosphorylase activity during G. intestinalis growth and differentiation.

Regulation of glycogen metabolism in yeast and bacteria.

Microorganisms have the capacity to utilize a variety of nutrients and adapt to continuously changing environmental conditions. Many microorganisms, including yeast and bacteria, accumulate carbon and energy reserves to cope with the starvation conditions temporarily present in the environment. Glycogen biosynthesis is a main strategy for such metabolic storage, and a variety of sensing and signaling mechanisms have evolved in evolutionarily distant species to ensure the production of this homopolysaccharide. At the most fundamental level, the processes of glycogen synthesis and degradation in yeast and bacteria share certain broad similarities. However, the regulation of these processes is sometimes quite distinct, indicating that they have evolved separately to respond optimally to the habitat conditions of each species. This review aims to highlight the mechanisms, both at the transcriptional and at the post-transcriptional level, that regulate glycogen metabolism in yeast and bacteria, focusing on selected areas where the greatest increase in knowledge has occurred during the last few years. In the yeast system, we focus particularly on the various signaling pathways that control the activity of the enzymes of glycogen storage. We also discuss our recent understanding of the important role played by the vacuole in glycogen metabolism. In the case of bacterial glycogen, special emphasis is placed on aspects related to the genetic regulation of glycogen metabolism and its connection with other biological processes.

Regulation of yeast glycogen phosphorylase by the cyclin-dependent protein kinase Pho85p.

Yeast accumulate glycogen in response to nutrient limitation. The key enzymes of glycogen synthesis and degradation, glycogen synthase, and phosphorylase, are regulated by reversible phosphorylation. Phosphorylation inactivates glycogen synthase but activates phosphorylase. The kinases and phosphatases that control glycogen synthase are well characterized whilst the enzymes modifying phosphorylase are poorly defined. Here, we show that the cyclin-dependent protein kinase, Pho85p, which we have previously found to regulate glycogen synthase also controls the phosphorylation state of phosphorylase.

GNN is a self-glucosylating protein involved in the initiation step of glycogen biosynthesis in Neurospora crassa.

The initiation of glycogen synthesis requires the protein glycogenin, which incorporates glucose residues through a self-glucosylation reaction, and then acts as substrate for chain elongation by glycogen synthase and branching enzyme. Numerous sequences of glycogenin-like proteins are available in the databases but the enzymes from mammalian skeletal muscle and from Saccharomyces cerevisiae are the best characterized. We report the isolation of a cDNA from the fungus Neurospora crassa, which encodes a protein, GNN, which has properties characteristic of glycogenin. The protein is one of the largest glycogenins but shares several conserved domains common to other family members. Recombinant GNN produced in Escherichia coli was able to incorporate glucose in a self-glucosylation reaction, to trans-glucosylate exogenous substrates, and to act as substrate for chain elongation by glycogen synthase. Recombinant protein was sensitive to C-terminal proteolysis, leading to stable species of around 31kDa, which maintained all functional properties. The role of GNN as an initiator of glycogen metabolism was confirmed by its ability to complement the glycogen deficiency of a S. cerevisiae strain (glg1 glg2) lacking glycogenin and unable to accumulate glycogen. Disruption of the gnn gene of N. crassa by repeat induced point mutation (RIP) resulted in a strain that was unable to synthesize glycogen, even though the glycogen synthase activity was unchanged. Northern blot analysis showed that the gnn gene was induced during vegetative growth and was repressed upon carbon starvation.