Mycophenolic acid and thiazole adenine dinucleotide inhibition of Tritrichomonas foetus inosine 5'-monophosphate dehydrogenase: implications on enzyme mechanism

Inosine 5'-monophosphate dehydrogenase (IMPDH) catalyzes the oxidation of inosine 5'-monophosphate (IMP) to xanthosine 5'-monophosphate (XMP) with the conversion of NAD to NADH. An ordered sequential mechanism where IMP is the first substrate bound and XMP is the last product released was proposed for Tritrichomonas foetus IMPDH on the basis of product inhibition studies. Thiazole adenine dinucleotide (TAD) is an uncompetitive inhibitor versus IMP and a noncompetitive inhibitor versus NAD, which suggests that TAD binds to both E-IMP and E-XMP. Mycophenolic acid is also an uncompetitive inhibitor versus IMP and noncompetitive versus NAD. Multiple-inhibitor experiments show that TAD and mycophenolic acid are mutually exclusive with each other and with NADH. Therefore, mycophenolic acid most probably binds to the dinucleotide site of T. foetus IMPDH. The mycophenolic acid binding site was further localized to the nicotinamide subsite within the dinucleotide site: mycophenolic acid was mutually exclusive with tiazofurin, but could form ternary enzyme complexes with ADP or adenosine diphosphate ribose. NAD inhibits the IMPDH reaction at concentrations greater than 3 mM. NAD substrate inhibition is uncompetitive versus IMP, which suggests that NAD inhibits by binding to E-XMP. TAD is mutually exclusive with both NAD and NADH in multiple-inhibitor experiments, which suggests that there is one dinucleotide binding site. The ordered mechanism predicts that multiple-inhibitor experiments with XMP and TAD, mycophenolic acid, or NAD should have an interaction constant (alpha) between 0 and 1. However, alpha was greater than 1 in all cases.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystal structure of a ternary complex of Tritrichomonas foetus inosine 5'-monophosphate dehydrogenase: NAD+ orients the active site loop for catalysis

Inosine 5'-monophosphate dehydrogenase (IMPDH) catalyzes the conversion of IMP to XMP with the reduction of NAD(+), which is the rate-limiting step in the biosynthesis of guanine nucleotides. IMPDH is a promising target for chemotherapy. Microbial IMPDHs differ from mammalian enzymes in their lower affinity for inhibitors such as mycophenolic acid (MPA) and thiazole-4-carboxamide adenine dinucleotide (TAD). Part of this resistance is determined by the coupling between nicotinamide and adenosine subsites in the NAD(+) binding site that is postulated to involve an active site flap. To understand the structural basis of the drug selectivity, we solved the X-ray crystal structure of the catalytic core domain of Tritrichomonas foetus IMPDH in complex with IMP and beta-methylene-TAD at 2.2 A resolution. Unlike previous structures of this enzyme, the active site loop is ordered in this complex, and the catalytic Cys319 is 3.6 A from IMP, in the same plane as the hypoxanthine ring. The active site loop forms hydrogen bonds to the carboxamide of beta-Me-TAD which suggests that NAD(+) promotes the nucleophillic attack of Cys319 on IMP. The interactions of the adenosine end of TAD are very different from those in the human enzyme, suggesting the NAD(+) site may be an exploitable target for the design of antimicrobial drugs. In addition, a new K(+) site is observed at the subunit interface. This site is adjacent to beta-Me-TAD, consistent with the link between the K(+) activation and NAD(+). However, contrary to the coupling model, the flap does not cover the adenosine subsite and remains largely disordered.     

Novel amide-based inhibitors of inosine 5'-monophosphate dehydrogenase

A series of novel amide-based small molecule inhibitors of inosine monophosphate dehydrogenase (IMPDH) was explored. The synthesis and the structure-activity relationships (SARs) derived from in vitro studies are described.     

Direct assay method for inosine 5'-monophosphate dehydrogenase activity

A rapid microassay method for the accurate measurement of the activity of inosine 5'-monophosphate dehydrogenase in crude tissue extracts was described. [8-14C]IMP and the radioactive products were separated by high-voltage electrophoresis in 0.1 M potassium phosphate buffer, pH 7.0, for 45 min. This separation method provides an analysis of the possible interfering reactions such as the metabolic conversion of the substrate IMP to inosine and adenylosuccinate, and the loss of the product XMP to xanthosine or GMP and to other metabolites. Low blank values were consistently obtained with this method because the XMP spot moves faster than the IMP spot. The major advantages of this assay method are direct measurement of IMP dehydrogenase activity in crude extracts, high sensitivity (with a limit of detection of 5 pmol of XMP production), high reproducibility (less than +/- 3.6%), low blank values (60-80 cpm), speed (2 h per 30 assays), and capability to measure activity in small amounts of tissue (10-50 mg wet wt).     

Species-specific inhibition of inosine 5'-monophosphate dehydrogenase by mycophenolic acid

IMPDH catalyzes the oxidation of IMP to XMP with the concomitant reduction of NAD(+) to NADH. This reaction is the rate-limiting step in de novo guanine nucleotide biosynthesis. Mycophenolic acid (MPA) is a potent inhibitor of mammalian IMPDHs but a poor inhibitor of microbial IMPDHs. MPA inhibits IMPDH by binding in the nicotinamide half of the dinucleotide site and trapping the covalent intermediate E-XMP. The MPA binding site of resistant IMPDH from the parasite Tritrichomonas foetuscontains two residues that differ from human IMPDH. Lys310 and Glu431 of T. foetus IMPDH are replaced by Arg and Gln, respectively, in the human type 2 enzyme. We characterized three mutants of T. foetusIMPDH: Lys310Arg, Glu431Gln, and Lys310Arg/Glu431Gln in order to determine if these substitutions account for the species selectivity of MPA. The mutation of Lys310Arg causes a 10-fold decrease in the K(i) for MPA inhibition and a 8-13-fold increase in the K(m) values for IMP and NAD(+). The mutation of Glu431Gln causes a 6-fold decrease in the K(i) for MPA. The double mutant displays a 20-fold increase in sensitivity to MPA. Pre-steady-state kinetics were performed to obtain rates of hydride transfer, NADH release, and hydrolysis of E-XMP for the mutant IMPDHs. The Lys310Arg mutation results in a 3-fold increase in the accumulation level of E-XMP, while the Glu431Gln mutation has only a minimal effect on the kinetic mechanism. These experiments show that 20 of the 450-fold difference in sensitivity between the T. foetus and human IMPDHs derive from the residues in the MPA binding site. Of this, 3-fold can be attributed to a change in kinetic mechanism. In addition, we measured MPA binding to enzyme adducts with 6-Cl-IMP and EICARMP. Neither of these adducts proved to be a good model for E-XMP.     

Monovalent cation activation in Escherichia coli inosine 5'-monophosphate dehydrogenase

Inosine 5'-monophosphate dehydrogenase (IMPDH) catalyzes the oxidation of inosine 5'-monophosphate (IMP) to xanthosine 5'-monophosphate with the concomitant reduction of NAD to NADH. Escherichia coli IMPDH is activated by K(+), Rb(+), NH(+)(4), and Cs(+). K(+) activation is inhibited by Li(+), Na(+), Ca(2+), and Mg(2+). This inhibition is competitive versus K(+) at high K(+) concentrations, noncompetitive versus IMP, and competitive versus NAD. Thus monovalent cation activation is linked to the NAD site. K(+) increases the rate constant for the pre-steady-state burst of NADH production, possibly by increasing the affinity of NAD. Three mutant IMPDHs have been identified which increase the value of K(m) for K(+): Asp13Ala, Asp50Ala, and Glu469Ala. In contrast to wild type, both Asp13Ala and Glu469Ala are activated by all cations tested. Thus these mutations eliminate cation selectivity. Both Asp13 and Glu469 appear to interact with the K(+) binding site identified in Chinese hamster IMPDH. Like wild-type IMPDH, K(+) activation of Asp50Ala is inhibited by Li(+), Na(+), Ca(2+), and Mg(2+). However, this inhibition is noncompetitive with respect to K(+) and competitive with respect to both IMP and NAD. Asp50 interacts with residues that form a rigid wall in the IMP site; disruption of this wall would be expected to decrease IMP binding, and the defect could propagate to the proposed K(+) site. Alternatively, this mutation could uncover a second monovalent cation binding site.     

Biochemical analysis of the modular enzyme inosine 5'-monophosphate dehydrogenase.

Two prominent domains have been identified in the X-ray crystal structure of inosine-5'-monophosphate dehydrogenase (IMPDH), a core domain consisting of an alpha/beta barrel which contains the active site and an inserted subdomain whose structure is less well defined. The core domain encompassing amino acids 1-108 and 244-514 of wild-type human IMPDH (II) connected by the tetrapeptide linker Ile-Arg-Thr-Gly was expressed. The subdomain including amino acids 99-244 of human wild-type IMPDH (II) was expressed as a His-tagged fusion protein, where the His-tag was removable by enterokinase cleavage. These two proteins as well as wild-type human IMPDH (II), all proteins expressed in Escherichia coli, have been purified to apparent homogeneity. Both the wild-type and core domain proteins are tetrameric and have very similar enzymatic activities. In contrast, the subdomain migrates as a monomer or dimer on a gel filtration column and lacks enzymatic activity. Circular dichroism spectropolarimetry indicates that the core domain retains secondary structure very similar to full-length IMPDH, with 30% alpha-helix and 30% beta-sheet vs 33% alpha-helix and 29% beta-sheet for wild-type protein. Again, the subdomain protein is distinguished from both wild-type and core domain proteins by its content of secondary structure, with only 15% each of alpha-helix and beta-sheet. These studies demonstrate that the core domain of IMPDH expressed separately is both structurally intact and enzymatically active. The availability of the modules of IMPDH will aid in dissecting the architecture of this enzyme of the de novo purine nucleotide biosynthetic pathway, which is an important target for immunosuppressive and antiviral drugs.     

The CBS subdomain of inosine 5'-monophosphate dehydrogenase regulates purine nucleotide turnover

Inosine 5'-monophosphate dehydrogenase (IMPDH) catalyses the rate-limiting step in guanine nucleotide biosynthesis. IMPDH has an evolutionary conserved CBS subdomain of unknown function. The subdomain can be deleted without impairing the in vitro IMPDH catalytic activity and is the site for mutations associated with human retinitis pigmentosa. A guanine-prototrophic Escherichia coli strain, MP101, was constructed with the subdomain sequence deleted from the chromosomal gene for IMPDH. The ATP content was substantially elevated in MP101 whereas the GTP content was slighty reduced. The activities of IMPDH, adenylosuccinate synthetase and GMP reductase were two to threefold lower in MP101 crude extracts compared with the BW25113 wild-type strain. Guanine induced a threefold reduction in the MP101 ATP pool and a fourfold increase in the GTP pool within 10 min of addition to growing cells; this response does not result from the reduced IMPDH activity or starvation for guanylates. In vivo kinetic analysis using 14-C tracers and 33-P pulse-chasing revealed mutation-associated changes in purine nucleotide fluxes and turnover rates. We conclude that the CBS subdomain of IMPDH may coordinate the activities of the enzymes of purine nucleotide metabolism and is essential for maintaining the normal ATP and GTP pool sizes in E. coli .     

Preliminary X-ray crystallographic analysis of Tritrichomonas foetus inosine-5′-monophosphate dehydrogenase

Inosine-5′-monophosphate dehydrogenase (IMPDH) from the protozoan parasite Tritrichomonas foetus has been expressed in E. coli and crystallized. Crystals were grown to 0.1 mm in each dimension in 18 to 72 h using ammonium sulfate and low-molecular-weight polyethylene glycols. The crystals belong to the cubic space group P432 with unit cell edge = 157.25 Å. The enzyme is a homotetramer with each monomer having a molecular weight of 55,534 Da. There is one monomer per asymmetric unit, based on a volume/mass ratio of 2.7 ų/Da and self-rotation analysis. The crystals are adequately stable to allow a complete data set to be collected from a single crystal. Complete native data sets have been collected to 2.3 Å resolution at 4°C using synchrotron radiation. High-quality complete data extending to 3.0 Å resolution have been collected from crystals of four putative derivatives, and the data appear to be isomorphous with that of the native crystals in each case. Efforts to solve the derivatives for use in MIR phasing are underway. © 1995 Wiley-Liss, Inc.     

Targeted disruption of the inosine 5'-monophosphate dehydrogenase type I gene in mice

Inosine 5'-monophosphate dehydrogenase (IMPDH) is the critical, rate-limiting enzyme in the de novo biosynthesis pathway for guanine nucleotides. Two separate isoenzymes, designated IMPDH types I and II, contribute to IMPDH activity. An additional pathway salvages guanine through the activity of hypoxanthine-guanine phosphoribosyltransferase (HPRT) to supply the cell with guanine nucleotides. In order to better understand the relative contributions of IMPDH types I and II and HPRT to normal biological function, a mouse deficient in IMPDH type I was generated by standard gene-targeting techniques and bred to mice deficient in HPRT or heterozygous for IMPDH type II. T-cell activation in response to anti-CD3 plus anti-CD28 antibodies was significantly impaired in both single- and double-knockout mice, whereas a more general inhibition of proliferation in response to other T- and B-cell mitogens was observed only in mice deficient in both enzymes. In addition, IMPDH type I(-/-) HPRT(-/0) splenocytes showed reduced interleukin-4 production and impaired cytolytic activity after antibody activation, indicating an important role for guanine salvage in supplementing the de novo synthesis of guanine nucleotides. We conclude that both IMPDH and HPRT activities contribute to normal T-lymphocyte activation and function.     

Crystal structure of Tritrichomonas foetus inosine monophosphate dehydrogenase in complex with the inhibitor ribavirin monophosphate reveals a catalysis-dependent ion-binding site

Inosine monophosphate dehydrogenase (IMPDH) catalyzes the rate-limiting step in GMP biosynthesis. The resulting intracellular pool of guanine nucleotides is of great importance to all cells for use in DNA and RNA synthesis, metabolism, and signal transduction. The enzyme binds IMP and the cofactor NAD(+) in random order, IMP is converted to XMP, NAD(+) is reduced to NADH, and finally, NADH and then XMP are released sequentially. XMP is subsequently converted into GMP by GMP synthetase. Drugs that decrease GMP synthesis by inhibiting IMPDH have been shown to have antiproliferative as well as antiviral activity. Several drugs are in use that target the substrate- or cofactor-binding site; however, due to differences between the mammalian and microbial isoforms, most drugs are far less effective against the microbial form of the enzyme than the mammalian form. The high resolution crystal structures of the protozoan parasite Tritrichomonas foetus IMPDH complexed with the inhibitor ribavirin monophosphate as well as monophosphate together with a second inhibitor, mycophenolic acid, are presented here. These structures reveal an active site cation identified previously only in the Chinese hamster IMPDH structure with covalently bound IMP. This cation was not found previously in apo IMPDH, IMPDH in complex with XMP, or covalently bound inhibitor, indicating that the cation-binding site may be catalysis-dependent. A comparison of T. foetus IMPDH with the Chinese hamster and Streptococcus pyogenes structures reveals differences in the active site loop architecture, which contributes to differences in cation binding during the catalytic sequence and the kinetic rates between bacterial, protozoan, and mammalian enzymes. Exploitation of these differences may lead to novel inhibitors, which favor the microbial form of the enzyme.     

The Cys319 loop modulates the transition between dehydrogenase and hydrolase conformations in inosine 5'-monophosphate dehydrogenase

X-ray crystal structures of enzyme-ligand complexes are widely believed to mimic states in the catalytic cycle, but this presumption has seldom been carefully scrutinized. In the case of Tritrichomonas foetus inosine 5'-monophosphate dehydrogenase (IMPDH), 10 structures of various enzyme-substrate-inhibitor complexes have been determined. The Cys319 loop is found in at least three different conformations, suggesting that its conformation changes as the catalytic cycle progresses from the dehydrogenase step to the hydrolase reaction. Alternatively, only one conformation of the Cys319 loop may be catalytically relevant while the others are off-pathway. Here we differentiate between these two hypotheses by analyzing the effects of Ala substitutions at three residues of the Cys319 loop, Arg322, Glu323, and Gln324. These mutations have minimal effects on the value of k(cat) (≤5-fold) that obscure large effects (>10-fold) on the microscopic rate constants for individual steps. These substitutions increase the equilibrium constant for the dehydrogenase step but decrease the equilibrium between open and closed conformations of a mobile flap. More dramatic effects are observed when Arg322 is substituted with Glu, which decreases the rates of hydride transfer and hydrolysis by factors of 2000 and 130, respectively. These experiments suggest that the Cys319 loop does indeed have different conformations during the dehydrogenase and hydrolase reactions as suggested by the crystal structures. Importantly, these experiments reveal that the structure of the Cys319 loop modulates the closure of the mobile flap. This conformational change converts the enzyme from a dehydrogenase into hydrolase, suggesting that the conformation of the Cys319 loop may gate the catalytic cycle.     

A mutational analysis of the active site of human type II inosine 5'-monophosphate dehydrogenase

The oxidation of IMP to XMP is the rate-limiting step in the de novo synthesis of guanine ribonucleotides. This NAD-dependent reaction is catalyzed by the enzyme inosine monophosphate dehydrogenase (IMPDH). Based upon the recent structural determination of IMPDH complexed to oxidized IMP (XMP*) and the potent uncompetitive inhibitor mycophenolic acid (MPA), we have selected active site residues and prepared mutants of human type II IMPDH. The catalytic parameters of these mutants were determined. Mutations G326A, D364A, and the active site nucleophile C331A all abolish enzyme activity to less than 0.1% of wild type. These residues line the IMP binding pocket and are necessary for correct positioning of the substrate, Asp364 serving to anchor the ribose ring of the nucleotide. In the MPA/NAD binding site, significant loss of activity was seen by mutation of any residue of the triad Arg322, Asn303, Asp274 which form a hydrogen bonding network lining one side of this pocket. From a model of NAD bound to the active site consistent with the mutational data, we propose that these resides are important in binding the ribose ring of the nicotinamide substrate. Additionally, mutations in the pair Thr333, Gln441, which lies close to the xanthine ring, cause a significant drop in the catalytic activity of IMPDH. It is proposed that these residues serve to deliver the catalytic water molecule required for hydrolysis of the cysteine-bound XMP* intermediate formed after oxidation by NAD.     

Retinal isoforms of inosine 5'-monophosphate dehydrogenase type 1 are poor nucleic acid binding proteins

The RP 10 form of autosomal dominant retinitis pigmentosa (adRP) is caused by mutations in the widely expressed protein inosine 5′-monophosphate dehydrogenase type 1 (IMPDH1). These mutations have no effect on the enzymatic activity of IMPDH1, but do perturb the association of IMPDH1 with nucleic acids. Two newly discovered retinal-specific isoforms, IMPDH1(546) and IMPDH1(595), may provide the key to the photoreceptor specificity of disease [S.J. Bowne, Q. Liu, L.S. Sullivan, J. Zhu, C.J. Spellicy, C.B. Rickman, E.A. Pierce, S.P. Daiger, Invest. Ophthalmol. Vis. Sci. 47 (2006) 3754-3765]. Here we express and characterize the normal IMPDH1(546) and IMPDH1(595), together with their adRP-linked variants, D226N. The enzymatic activity of the purified IMPDH1(546), IMPDH1(595) and the D226N variants is indistinguishable from the canonical form. The intracellular distribution of IMPDH1(546) and IMPDH1(595) is also similar to the canonical IMPDH1 and unaffected by the D226N mutation. However, unlike the canonical IMPDH1, the retinal specific isoforms do not bind significant fractions of a random pool of oligonucleotides. This observation indicates that the C-terminal extension unique to the retinal isoforms blocks the nucleic acid binding site of IMPDH1, and thus uniquely regulates protein function within photoreceptors.     

Differential splicing of Pneumocystis carinii f. sp. carinii inosine 5'-monophosphate dehydrogenase pre-mRNA

Inosine 5'-monophosphate dehydrogenase (IMPDH) is a rate-limiting enzyme in guanine nucleotide metabolism that has drawn attention as a drug target in several organisms. Pneumocystis carinii f. sp. carinii IMPDH mRNA (GeneBank Accession No: U42442) previously identified from cultured organisms yielded a predicted amino acid sequence about 70 amino acids shorter at the amino terminus than IMPDH from other species. Recent research has shown that the amino terminal region is important for enzyme activity, suggesting that the previous putative P. carinii IMPDH might not represent full length, functional enzyme. To test this hypothesis, RT-PCR was performed with total RNA isolated from P. carinii f. sp. carinii. Three IMPDH splicing variants were found and splicing preference was observed: P. carinii isolated from infected rat lung contained primarily splicing variant one (introns two and four deleted), but organisms from spinner flask culture contained primarily splicing variant three (all four introns deleted). Importantly, splicing variant one (GeneBank Accession No: AF196975) contained an open reading frame for 529 amino acids, a size comparable to that of other eukaryotic IMPDH forms. The other variants contained the same open reading frame (454 amino acids) previously reported. Sequence analysis and complementation studies suggest variant one represents the full length, catalytically active form of P. carinii IMPDH. The differential splicing of the enzyme may reflect a mechanism by which the organism regulates the expression of IMPDH in response to environmental stresses.     

Pyrimidine metabolism in Tritrichomonas foetus

The pyrimidine metabolism of Tritrichomonas foetus (KV 1) was studied using whole cells and cell homogenates. Pyrimidines and pyrimidine nucleosides were readily incorporated into nucleic acids. Orotate and aspartate were not incorporated into pyrimidine bases. Enzymes of the pyrimidine salvage pathway (i.e., thymidine and uridine phosphorylases and uridine kinase) were detected in trophozoite homogenates, but the activities of de novo pyrimidine synthesis enzymes (i.e., carbamoylphosphate synthase, aspartate transcarbamoylase, dihydroorotase and dihydroorotate dehydrogenase) were below the level of detection in these same homogenates. The evidence presented supports the proposal that T. foetus is incapable of synthesizing pyrimidines de novo but is capable of salvaging preformed pyrimidines and pyrimidine nucleosides from the growth medium and that enzymes of this parasite's pyrimidine salvage pathway are not organelle-associated.     

Vaccination strategies against Tritrichomonas foetus

Immunoprophyloxis for bovine trichomoniosis has been a priority because of the high prevalence o f the disease, the considerable economic loss due to the infection and the lack of approved chemotherapeutic agents. The commercial availability of first-generation vaccines provides hope not only for even more effective immunization regimens far this disease, but also for other protozoal infections and for sexually transmitted diseases (STDs) caused by a wide variety of infectious agents. At present, efficacious vaccines for protozoal diseases and for STDs are rare. Since information gained on immunization against Tritrichomonas foetus may have broad significance for control of these two classes of infection,it is important to explore the biological basis of protection against this protozoal infection of the reproductive tract In this paper, Lynette Corbeil reviews data on host-parasite relationships in bovine trichomoniasis as a basis for developing vaccine strategies.     

Guanidine derivatives rescue the Arg418Ala mutation of Tritrichomonas foetus IMP dehydrogenase

IMP dehydrogenase (IMPDH) catalyzes the oxidation of inosine 5'-monophosphate (IMP) to xanthosine 5'-monophosphate (XMP) and the reduction of NAD(+). The reaction involves formation of an E-XMP covalent intermediate; hydrolysis of the E-XMP intermediate is rate-limiting and requires the enzyme to adopt a closed conformation. Arg418 appears to act as the base that activates water for the hydrolysis reaction [Guillen-Schlippe, Y. V., and Hedstrom, L. (2005) Biochemistry 44, 11700-11707]. Deprotonation of Arg418 also stabilizes the closed conformation. Here we show that guanidine derivatives rescue the activity of the Arg418Ala variant. Amines and imidazole do not rescue. The rescue reaction appears to be saturable, with the values of K(R) ranging from 40 to 400 mM. The value of k(rescue) for the best rescue agents approaches the value of k(cat) for the reaction of the wild-type enzyme. Guanidine derivatives also rescue the activity of the Arg418Ala/Tyr419Phe variant. Multiple-inhibitor experiments suggest that the guanidine derivatives do not restore the equilibrium between open and closed conformations. Therefore, rescue agents must accelerate the hydrolysis of the E-XMP intermediate. The rate of the rescue reaction increases with an increase in pH, consistent with the hypothesis that the reaction involves neutral guanidine. A solvent D(2)O isotope effect is observed at low concentrations of the rescue agent, consistent with rate-limiting transfer of a proton from water. The value of k(cat) (rescue)/K(R)(base) correlates with the pK(a) of the guanidine derivative (Bronsted coefficient beta approximately 1). These results suggest that proton transfer from water to guanidine is almost complete in the transition state.     

Sialic acid-specific lectin-mediated adhesion of Tritrichomonas foetus and Tritrichomonas mobilensis

Tritrichomonas foetus is an obligate parasite of the bovine urogenital tract producing infection associated with inflammatory changes, abortion, and infertility, Tritrichomonas mobilensis was isolated from squirrel monkey colon, and symptoms involve diarrheal complications. Both tritrichomonads produced hemagglutinins with the properties of sialic acid-specific lectins. Assays on the adherence of these protozoans to Chinese hamster ovary (CHO) cells and to bovine cervical and monkey colon mucus were performed to assess the function of the lectins in adhesion. Sialic acid at concentration as low as 2 mM inhibited the adhesion to CHO cells, less effectively to the mucus. Predigestion with Clostridium perfringens sialidase prevented the adhesion to both epithelial cells and the mucus. Inhibition of endogenous sialidases with 2,3-dehydro-2-deoxy-NeuAc increased the adhesion of T. mobilensis to CHO cells. Specific anti-T. foetus lectin (TFL) and anti-T. mobilensis lectin (TML) antibodies inhibited adhesion of the trichomonads to the epithelial cells and to the mucus. TFL histochemistry disclosed the presence of lectin ligands on keratinized vaginal epithelia, cervical mucosa, and mucin and on endometrial glands and their secretions. TML histochemistry showed reactivity with the luminal membranes of colonic glandular epithelium and less with the colonic mucin. Both lectins bound to the surface membrane of CHO cells. Anti-lectin antibodies showed granular cytoplasmic and strong membrane localization of the lectins in both tritrichomonads. Although the 2 tritrichomonads have different habitats, the results indicate that both these protozoa use lectins with sialic acid specificity for adhesion to mucosal surfaces.