The C2 Domains of Human Synaptotagmin 1 Have Distinct Mechanical Properties

Synaptotagmin 1 (Syt1) is the Ca⁺² receptor for fast, synchronous vesicle fusion in neurons. Because membrane fusion is an inherently mechanical, force-driven event, Syt1 must be able to adapt to the energetics of the fusion apparatus. Syt1 contains two C2 domains (C2A and C2B) that are homologous in sequence and three-dimensional in structure; yet, a number of observations have suggested that they have distinct biochemical and biological properties. In this study, we analyzed the mechanical stability of the C2A and C2B domains of human Syt1 using single-molecule atomic force microscopy. We found that stretching the C2AB domains of Syt1 resulted in two distinct unfolding force peaks. The larger force peak of ∼100 pN was identified as C2B and the second peak of ∼50 pN as C2A. Furthermore, a significant fraction of C2A domains unfolded through a low force intermediate that was not observed in C2B. We conclude that these domains have different mechanical properties. We hypothesize that a relatively small stretching force may be sufficient to deform the effector-binding regions of the C2A domain and modulate the affinity for soluble N-ethylmaleimide-sensitive factor (NSF) attachment protein receptors (SNAREs), phospholipids, and Ca⁺².     

Partial Metal Ion Saturation of C2 Domains Primes Synaptotagmin 1-Membrane Interactions

Synaptotagmin 1 (Syt1) is an integral membrane protein whose phospholipid-binding tandem C2 domains, C2A and C2B, act as Ca²⁺ sensors of neurotransmitter release. Our objective was to understand the role of individual metal-ion binding sites of these domains in the membrane association process. We used Pb²⁺, a structural and functional surrogate of Ca²⁺, to generate the protein states with well-defined protein-metal ion stoichiometry. NMR experiments revealed that binding of one divalent metal ion per C2 domain results in loss of conformational plasticity of the loop regions, potentially pre-organizing them for additional metal-ion and membrane-binding events. In C2A, a divalent metal ion in site 1 is sufficient to drive its weak association with phosphatidylserine-containing membranes, whereas in C2B, it enhances the interactions with the signaling lipid phosphatidylinositol-4,5-bisphosphate. In full-length Syt1, both Pb²⁺-complexed C2 domains associate with phosphatidylserine-containing membranes. Electron paramagnetic resonance experiments show that the extent of membrane insertion correlates with the occupancy of the C2 metal ion sites. Together, our results indicate that upon partial metal ion saturation of the intra-loop region, Syt1 adopts a dynamic, partially membrane-bound state. The properties of this state, such as conformationally restricted loop regions and positioning of C2 domains in close proximity to anionic lipid headgroups, “prime” Syt1 for cooperative binding of a full complement of metal ions and deeper membrane insertion.     

Comparative Analysis of the Biochemical and Functional Properties of C-Terminal Domains of Autotransporters

Autotransporters (ATs) are the largest group of proteins secreted by Gram-negative bacteria and include many virulence factors from human pathogens. ATs are synthesized as large precursors with a C-terminal domain that is inserted in the outer membrane (OM) and is essential for the translocation of an N-terminal passenger domain to the extracellular milieu. Several mechanisms have been proposed for AT secretion. Self-translocation models suggest transport across a hydrophilic channel formed by an internal pore of the β-barrel or by the oligomerization of C-terminal domains. Alternatively, an assisted-translocation model suggests that transport employs a conserved machinery of the bacterial OM such as the Bam complex. In this work we have investigated AT secretion by carrying out a comparative study to analyze the conserved biochemical and functional features of different C-terminal domains selected from ATs of gammaproteobacteria, betaproteobacteria, alphaproteobacteria, and epsilonproteobacteria. Our results indicate that C-terminal domains having an N-terminal α-helix and a β-barrel constitute functional transport units for the translocation of peptides and immunoglobulin domains with disulfide bonds. In vivo and in vitro analyses show that multimerization is not a conserved feature in AT C-terminal domains. Furthermore, we demonstrate that the deletion of the conserved α-helix severely impairs β-barrel folding and OM insertion and thereby blocks passenger domain secretion. These observations suggest that the AT β-barrel without its α-helix cannot form a stable hydrophilic channel in the OM for protein translocation. The implications of our data for an understanding of AT secretion are discussed.The classical autotransporter (AT) family, also known as the type Va protein secretion system, represents the largest group of proteins secreted by Gram-negative bacteria and includes many virulence factors from important human pathogens (10, 17). Bacteria produce AT proteins as large polypeptide precursors, with their virulence activity (e.g., cytotoxins, adhesins, and proteases, etc.) present in a passenger domain flanked by an N-terminal signal peptide (sp) for Sec-dependent translocation across the bacterial inner membrane (IM) and a C-terminal domain of ∼30 to 40 kDa for insertion into the bacterial outer membrane (OM) (see Fig. 2A). A self-translocation model was originally proposed to explain the secretion mechanism of AT proteins across the OM, based mostly on data obtained with the IgA protease (IgAP) from Neisseria gonorrhoeae (43). In this model the C-terminal domain of ATs was supposed to fold in the OM as a β-barrel protein with an internal hydrophilic pore that could be used for the translocation of the passenger domain. The finding that the B subunit of cholera toxin (CtxB) should not have disulfide bonds for its secretion when fused as a heterologous passenger to the C-terminal domain of IgAP (30, 31) indirectly suggests passenger translocation in an unfolded conformation through a narrow channel expected for a β-barrel. Similar observations with the C-terminal domains of IcsA from Shigella flexneri (56) and AIDA-I from Escherichia coli (36) supported this model.Previous work done by our group challenged the original self-translocation model, since a 45-kDa C-terminal fragment of IgAP was shown to form oligomeric ring-shaped complexes with a central hydrophilic pore of ∼2 nm (63). In addition, this C-terminal fragment of IgAP was found to translocate folded immunoglobulin (Ig) domains with disulfide bonds to the bacterial surface, indicating that at least a ∼2-nm pore was being used for passenger secretion (61, 62). These data led us to propose a “multimeric” version of the self-translocation model in which the secretion of the passenger may occur through the central channel assembled by the oligomerization of the C-terminal domains in the OM. Studies with IcsA from S. flexneri (7, 46, 47, 64) and EspP from E. coli (53) also provided evidence indicating that native and heterologous passengers adopt folded or at least partially folded conformations in the periplasm before OM translocation. Conversely, a limited capacity for the translocation of folded native passengers with engineered disulfide bonds has been reported by studies with Hbp from E. coli (23) and pertactin from Bordetella pertussis (24). Crystallographic structures of the C-terminal domains of NalP from Neisseria meningitidis (41) and EspP from E. coli (2) revealed distinct β-barrel folding with 12 amphipathic β-strands and one N-terminal α-helix filling the central hydrophilic pore of the β-barrel. No indication of oligomerization was obtained with the crystallographic data. In addition, the putative protein-conducting channels of the EspP and NalP β-barrels (of ∼1 nm in diameter) were found to be closed due to the presence of the internal α-helix, which would impede the transport of passenger polypeptides (either folded or unfolded) through the reported structures. Thus, an alternative model was proposed for the assisted translocation of ATs (3, 41), in which the protein-conducting channel for secretion across the OM would be provided by the conserved Bam complex. The Bam complex is required for the insertion of β-barrel proteins (32), and the depletion of its essential component BamA (formerly YaeT in E. coli and Omp85 in Neisseria) prevents the insertion of several ATs in the OM (i.e., IcsA and SepA from S. flexneri, AIDA-I and Hbp from E. coli, and BrkA from B. pertussis) (21, 50). BamA was reported to form hydrophilic pores in lipid membranes in vitro (54) and to cross-link in vivo with the passenger domain of a slow-secretion mutant of EspP (19), which supports a role for BamA in translocation.Despite the above-described progress made in our understanding of ATs, their actual molecular mechanism of secretion remains uncertain. This is partially because the reported information is based on studies with different model AT proteins and nonhomogenous experimental approaches used by different laboratories, which sometimes produce data that are difficult to compare or may be conflicting. Here, we report a comparative study to determine conserved biochemical and functional properties found in AT C-terminal domains. Following a uniform experimental approach for six AT C-terminal domains selected from the gammaproteobacteria, betaproteobacteria, alphaproteobacteria, and epsilonproteobacteria, we have investigated their capacities for the secretion of peptides and globular domains, their pore formation and oligomerization properties, and their requirement for an N-terminal α-helix for AT function and C-terminal domain stability. Our results shed light on the secretion mechanism of ATs from the conserved structural features found in their C-terminal domains.     

Solution and Membrane-Bound Conformations of the Tandem C2A and C2B Domains of Synaptotagmin 1: Evidence for Bilayer Bridging

Synaptotagmin 1 (syt1) is a synaptic vesicle membrane protein that functions as the Ca²⁺ sensor in neuronal exocytosis. Here, site-directed spin labeling was used to generate models for the solution and membrane-bound structures of a soluble fragment of syt1 containing its two C2 domains, C2A and C2B. In solution, distance restraints between the two C2 domains of syt1 were measured using double electron-electron resonance and used in a simulated annealing routine to generate models for the structure of the tandem C2A-C2B fragment. The data indicate that the two C2 domains are flexibly linked and do not interact with each other in solution, with or without Ca²⁺. However, the favored orientation is one where the Ca²⁺-binding loops are oriented in opposite directions. A similar approach was taken for membrane-associated C2A-C2B, combining both distances and bilayer depth restraints with simulated annealing. The restraints can only be satisfied if the Ca²⁺ and membrane-binding surfaces of the domains are oriented in opposite directions so that C2A and C2B are docked to opposing bilayers. The result suggests that syt1 functions to bridge across the vesicle and plasma membrane surfaces in a Ca²⁺-dependent manner.     

Negative Coupling as a Mechanism for Signal Propagation between C2 Domains of Synaptotagmin I

Synaptotagmin I (Syt I) is a vesicle-localized protein implicated in sensing the calcium influx that triggers fast synchronous release of neurotransmitter. How Syt I utilizes its two C2 domains to integrate signals and mediate neurotransmission has continued to be a controversial area of research, though prevalent hypotheses favor independent function. Using differential scanning calorimetry and fluorescence lifetime spectroscopy in a thermodynamic denaturation approach, we tested an alternative hypothesis in which both domains interact to cooperatively disseminate binding information. The free energy of stability was determined for C2A, C2B, and C2AB constructs by globally fitting both methods to a two-state model of unfolding. By comparing the additive free energies of C2A and C2B with C2AB, we identified a negative coupling interaction between the C2 domains of Syt I. This interaction not only provides a mechanistic means for propagating signals, but also a possible means for coordinating the molecular events of neurotransmission.     

Structural and Functional Analysis of Multi-Interface Domains

A multi-interface domain is a domain that can shape multiple and distinctive binding sites to contact with many other domains, forming a hub in domain-domain interaction networks. The functions played by the multiple interfaces are usually different, but there is no strict bijection between the functions and interfaces as some subsets of the interfaces play the same function. This work applies graph theory and algorithms to discover fingerprints for the multiple interfaces of a domain and to establish associations between the interfaces and functions, based on a huge set of multi-interface proteins from PDB. We found that about 40% of proteins have the multi-interface property, however the involved multi-interface domains account for only a tiny fraction (1.8%) of the total number of domains. The interfaces of these domains are distinguishable in terms of their fingerprints, indicating the functional specificity of the multiple interfaces in a domain. Furthermore, we observed that both cooperative and distinctive structural patterns, which will be useful for protein engineering, exist in the multiple interfaces of a domain.     

Deafl的功能结构域分析和预测

目的分析转录因子Deafl的功能结构域并预测其功能。方法利用现有的数据库和软件对Deafl的转录因子结构域,核定位信号及和输出信号进行分析和预测。结果Deafl含有一个保守的SAND结构域及一个能介导蛋白质一蛋白质相互作用的MYND结构域;有核定位信号和核输出信号;在其N端还有一个富含丙氨酸结构域。结论Deafl除有典型转录因子必需的功能结构域之外,可能还有不止一个结构域能介导与其它蛋白质因子的相互作用,这对Deafl调控外周组织抗原表达至关重要。     

Arabidopsis Synaptotagmin SYT1, a Type I Signal-anchor Protein,Requires Tandem C2 Domains for Delivery to the Plasma Membrane

The correct localization of integral membrane proteins to subcellular compartments is important for their functions. Synaptotagmin contains a single transmembrane domain that functions as a type I signal-anchor sequence in its N terminus and two calcium-binding domains (C₂A and C₂B) in its C terminus. Here, we demonstrate that the localization of an Arabidopsis synaptotagmin homolog, SYT1, to the plasma membrane (PM) is modulated by tandem C2 domains. An analysis of the roots of a transformant-expressing green fluorescent protein-tagged SYT1 driven by native SYT1 promoter suggested that SYT1 is synthesized in the endoplasmic reticulum, and then delivered to the PM via the exocytotic pathway. We transiently expressed a series of truncated proteins in protoplasts, and determined that tandem C₂A-C₂B domains were necessary for the localization of SYT1 to the PM. The PM localization of SYT1 was greatly reduced following mutation of the calcium-binding motifs of the C₂B domain, based on sequence comparisons with other homologs, such as endomembrane-localized SYT5. The localization of SYT1 to the PM may have been required for the functional divergence that occurred in the molecular evolution of plant synaptotagmins.     

Synaptotagmin IV is present at the Golgi and distal parts of neurites

Synaptotagmin IV (SytIV) is an immediate early gene induced by membrane depolarization in PC12 cells and in rat brain. However, little is known about the function of SytIV or the functional relationship between SytIV and SytI, because SytIV has yet to be localized. Here we show that SytIV was localized at the Golgi and distal part of neurites in nerve growth factor-differentiated PC12 cells and cultured hippocampal neurons by immunocytochemistry using an isoform-specific antibody (anti-SytIV). These SytIV signals were not colocalized well with SytI signals. Upon membrane depolarization, SytIV signals were increased at both the Golgi and distal part of neurites within several hours in both types of cells. We further show that the increase of SytIV protein levels results from protein kinase A-dependent gene up-regulation. In hippocampal neurons, SytIV was developmentally regulated. These results suggest that SytIV may play a role at the Golgi and tips of neurites during development and synaptic plasticity.     

Functional Integration of the Conserved Domains of Shoc2 Scaffold

Shoc2 is a positive regulator of signaling to extracellular signal-regulated protein kinases 1 and 2 (ERK1/2). Shoc2 is also proposed to interact with RAS and Raf-1 in order to accelerate ERK1/2 activity. To understand the mechanisms by which Shoc2 regulates ERK1/2 activation by the epidermal growth factor receptor (EGFR), we dissected the role of Shoc2 structural domains in binding to its signaling partners and its role in regulating ERK1/2 activity. Shoc2 is comprised of two main domains: the 21 leucine rich repeats (LRRs) core and the N-terminal non-LRR domain. We demonstrated that the N-terminal domain mediates Shoc2 binding to both M-Ras and Raf-1, while the C-terminal part of Shoc2 contains a late endosomal targeting motif. We found that M-Ras binding to Shoc2 is independent of its GTPase activity. While overexpression of Shoc2 did not change kinetics of ERK1/2 activity, both the N-terminal and the LRR-core domain were able to rescue ERK1/2 activity in cells depleted of Shoc2, suggesting that these Shoc2 domains are involved in modulating ERK1/2 activity.     

木聚糖酶分子的结构区域

多数木聚糖酶分子中含有多个功能区域,这些区域包括催化区、纤维素结合区、木聚糖结合区、连接序列、重复序列、热稳定区、Ｃｅｌｕｌｏｓｏｍｅ－Ｄｏｃｋｉｎｇ区及其它未知功能的非催化区,它们担负着不同的生物功能,不同来源的木聚糖酶分子的功能区域之间同源性或高或低。     

Functional and Biochemical Analysis of the Chlamydia trachomatis Ligase MurE

Chlamydiae are unusual obligately intracellular bacteria that do not synthesize detectable peptidoglycan. However, they possess genes that appear to encode products with peptidoglycan biosynthetic activity. Bioinformatic analysis predicts that chlamydial MurE possesses UDP-MurNAc-l-Ala-d-Glu:meso-diaminopimelic acid (UDP-MurNAc-l-Ala-d-Glu:meso-A₂pm) ligase activity. Nevertheless, there are no experimental data to confirm this hypothesis. In this paper we demonstrate that the murE gene from Chlamydia trachomatis is capable of complementing a conditional Escherichia coli mutant impaired in UDP-MurNAc-l-Ala-d-Glu:meso-A₂pm ligase activity. Recombinant MurE from C. trachomatis (MurE_Ct) was overproduced in and purified from E. coli in order to investigate its kinetic parameters in vitro. By use of UDP-MurNAc-l-Ala-d-Glu as the nucleotide substrate, MurE_Ct demonstrated ATP-dependent meso-A₂pm ligase activity with pH and magnesium ion optima of 8.6 and 30 mM, respectively. Other amino acids (meso-lanthionine, the ll and dd isomers of A₂pm, d-lysine) were also recognized by MurE_Ct. However, the activities for these amino acid substrates were weaker than that for meso-A₂pm. The specificity of MurE_Ct for three possible C. trachomatis peptidoglycan nucleotide substrates was also determined in order to deduce which amino acid might be present at the first position of the UDP-MurNAc-pentapeptide. Relative k_cat/K_m ratios for UDP-MurNAc-l-Ala-d-Glu, UDP-MurNAc-l-Ser-d-Glu, and UDP-MurNAc-Gly-d-Glu were 100, 115, and 27, respectively. Our results are consistent with the synthesis in chlamydiae of a UDP-MurNAc-pentapeptide in which the third amino acid is meso-A₂pm. However, due to the lack of specificity of MurE_Ct for nucleotide substrates in vitro, it is not obvious which amino acid is present at the first position of the pentapeptide.Chlamydiae cause serious respiratory tract and genital infections in humans (9). They are obligately intracellular gram-negative bacteria, with a unique biphasic development cycle. Elementary bodies (EBs) are the infectious form of the organism and invade susceptible host cells. Once internalized, EBs differentiate into reticulate bodies (RBs), which have the capacity to divide (39, 40). The RBs are fragile and pleomorphic, whereas EBs are comparatively rigid and stable (19, 39). After repeated cycles of binary fission, the RBs differentiate into EBs, and the host cell lyses, releasing infectious EBs (1).In contrast to the vast majority of eubacteria, chlamydiae lack detectable amounts of peptidoglycan (PG), an essential polymer. PG is a giant macromolecule composed of alternating N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) residues cross-linked by short peptides. It determines the shape of bacteria, protects the cell from lysis due to internal osmotic pressure, and also plays a role in cell division. However, PG has not been detected in EBs (14, 20) or RBs (5).Although chlamydiae appear to lack PG, they contain penicillin-binding proteins and are sensitive to antibiotics that inhibit PG synthesis (5, 40). The Chlamydia trachomatis genome contains most of the genes coding for proteins involved in, or associated with, PG synthesis (54). Chlamydial MurA, MurC-Ddl, and the MurC domain of the latter fusion protein are active in vitro and complement Escherichia coli mutants deficient in the respective enzymes (23, 32, 33). Furthermore, proteomic analysis reveals that the murE gene product, which was assigned as UDP-MurNAc-l-Ala-d-Glu:meso-diaminopimelic acid ligase (UDP-MurNAc-l-Ala-d-Glu:meso-A₂pm ligase), is expressed in RBs (52).MurE ligases catalyze the addition of the third amino acid residue to the peptide chain of PG. This residue, generally a diamino acid, is usually meso-A₂pm for gram-negative bacteria and bacilli, and l-lysine for gram-positive bacteria, although other amino acids (for example, l-ornithine, meso-lanthionine, ll-A₂pm, l-diaminobutyric acid, or l-homoserine) occur in certain species (6, 50, 57). In many organisms, the third residue of the peptide chain participates in PG cross-linking; consequently, the MurE enzyme is highly specific for the relevant amino acid so as to avoid incorporation of incorrect amino acids into the macromolecule, which could result in deleterious morphological changes and cell lysis (35). Crystallization of MurE from E. coli (MurE_Ec) has permitted analysis of the structural basis for this high specificity (22). Sequence alignments of different MurE orthologues have also revealed the specific consensus sequences DNPR and D(D/N)P(N/A) located in the binding pockets for meso-A₂pm and l-Lys, respectively (11, 17). Chlamydia trachomatis MurE (MurE_Ct) possesses the DNPR motif, which suggests that it adds meso-A₂pm (17). However, there are no experimental data to confirm this prediction.In this paper we report for the first time the overproduction and purification of MurE_Ct, as well as a detailed investigation of its in vivo and in vitro biochemical properties. These studies contribute to our understanding of the nature and properties of the PG biosynthetic enzymes in chlamydiae and do indeed suggest that MurE_Ct has meso-A₂pm ligase activity.     

Synaptotagmin IV regulates dense core vesicle (DCV) release in LbetaT2 cells

Synaptotagmins (Syts) are calcium-binding proteins which are conserved from nematodes to humans. Fifteen Syts have been identified in mammalian species. Syt I is recognized as a Ca²⁺ sensor for the synchronized release of synaptic vesicles in some types of neurons, but its role in the secretion of dense core vesicles (DCVs) remains unclear. The function of Syt IV is of particular interest because it is rapidly up-regulated by chronic depolarization and seizures. Using RNAi-mediated gene silencing, we have explored the role of Syt I and IV on secretion in a pituitary gonadotrope cell line. Downregulation of Syt IV clearly reduced Ca²⁺-triggered exocytosis of dense core vesicles (DCVs) in LβT2 cells. Syt I silencing, however, had no effect on vesicular release.     

Mechanism for Calcium Ion Sensing by the C2A Domain of Synaptotagmin I

The C2A domain is one of two calcium ion (Ca(2+))- and membrane-binding domains within synaptotagmin I (Syt I), the identified Ca(2+) sensor for regulated exocytosis of neurotransmitter. We propose that the mechanistic basis for C2A's response to Ca(2+) and cellular function stems from marginal stability and ligand-induced redistributions of protein conformers. To test this hypothesis, we used a combination of calorimetric and fluorescence techniques. We measured free energies of stability by globally fitting differential scanning calorimetry and fluorescence lifetime spectroscopy denaturation data, and found that C2A is weakly stable. Additionally, using partition functions in a fluorescence resonance energy transfer approach, we found that the Ca(2+)- and membrane-binding sites of C2A exhibit weak cooperative linkage. Lastly, a dye-release assay revealed that the Ca(2+)- and membrane-bound conformer subset of C2A promote membrane disruption. We discuss how these phenomena may lead to both cooperative and functional responses of Syt I.     

Structural and Functional Analysis of Transmembrane Segment IV of the Salt Tolerance Protein Sod2

Sod2 is the plasma membrane Na⁺/H⁺ exchanger of the fission yeast Schizosaccharomyces pombe. It provides salt tolerance by removing excess intracellular sodium (or lithium) in exchange for protons. We examined the role of amino acid residues of transmembrane segment IV (TM IV) (¹²⁶FPQINFLGSLLIAGCITSTDPVLSALI¹⁵²) in activity by using alanine scanning mutagenesis and examining salt tolerance in sod2-deficient S. pombe. Two amino acids were critical for function. Mutations T144A and V147A resulted in defective proteins that did not confer salt tolerance when reintroduced into S. pombe. Sod2 protein with other alanine mutations in TM IV had little or no effect. T144D and T144K mutant proteins were inactive; however, a T144S protein was functional and provided lithium, but not sodium, tolerance and transport. Analysis of sensitivity to trypsin indicated that the mutations caused a conformational change in the Sod2 protein. We expressed and purified TM IV (amino acids 125–154). NMR analysis yielded a model with two helical regions (amino acids 128–142 and 147–154) separated by an unwound region (amino acids 143–146). Molecular modeling of the entire Sod2 protein suggested that TM IV has a structure similar to that deduced by NMR analysis and an overall structure similar to that of Escherichia coli NhaA. TM IV of Sod2 has similarities to TM V of the Zygosaccharomyces rouxii Na⁺/H⁺ exchanger and TM VI of isoform 1 of mammalian Na⁺/H⁺ exchanger. TM IV of Sod2 is critical to transport and may be involved in cation binding or conformational changes of the protein.     

Biochemical and Immunological Characterization of Truncated Fragments of the Receptor-Binding Domains of C. difficile Toxin A

Clostridium difficile is an emerging pathogen responsible for opportunistic infections in hospitals worldwide and is the main cause of antibiotic-associated pseudo-membranous colitis and diarrhea in humans. Clostridial toxins A and B (TcdA and TcdB) specifically bind to unknown glycoprotein(s) on the surface of epithelial cells in the host intestine, disrupting the intestinal barrier and ultimately leading to acute inflammation and diarrhea. The C-terminal receptor-binding domain (RBD) of TcdA, which is responsible for the initial binding of the toxin to host glycoproteins, has been predicted to contain 7 potential oligosaccharide-binding sites. To study the specific roles and functions of these 7 putative lectin-like binding regions, a consensus sequence of TcdA RBD derived from different C. difficile strains deposited in the NCBI protein database and three truncated fragments corresponding to the N-terminal (residues 1–411), middle (residues 296–701), and C-terminal portions (residues 524–911) of the RBD (F1, F2 and F3, respectively) were designed and expressed in Escherichia coli. In this study, the recombinant RBD (rRBD) and its truncated fragments were purified, characterized biologically and found to have the following similar properties: (a) are capable of binding to the cell surface of both Vero and Caco-2 cells; (b) possess Toll-like receptor agonist-like adjuvant activities that can activate dendritic cell maturation and increase the secretion of pro-inflammatory cytokines; and (c) function as potent adjuvants in the intramuscular immunization route to enhance immune responses against weak immunogens. Although F1, F2 and F3 have similar repetitive amino acid sequences and putative oligosaccharide-binding domains, they do not possess the same biological and immunological properties: (i) TcdA rRBD and its fragments bind to the cell surface, but only TcdA rRBD and F3 internalize into Vero cells within 15 min; (ii) the fragments exhibit various levels of hemagglutinin (HA) activity, with the exception of the F1 fragment, which demonstrates no HA activity; and (iii) in the presence of alum, all fragments elicit various levels of anti-toxin A-neutralizing antibody responses, but those neutralizing antibodies elicited by F2 did not protect mice against a TcdA challenge. Because TcdA rRBD, F1 and F3 formulated with alum can elicit immune protective responses against the cytotoxicity of TcdA, they represent potential components of future candidate vaccines against C. difficile-associated diseases.