Co-translational trimerization of the reovirus cell attachment protein.

The reovirus cell attachment protein, sigma1, is a trimer with a 'lollipop' structure. Recent findings indicate that the N-terminal fibrous tail and the C-terminal globular head each possess a distinct trimerization domain. The region responsible for N-terminal trimerization (formation of a triple alpha-helical coiled-coil) is located at the N-terminal one-third of sigma1. In this study, we investigated the temporality and ATP requirement of this trimerization event in the context of sigma1 biogenesis. In vitro co-synthesis of the full-length (FL) and a C-terminally truncated (d44) sigma1 protein revealed a preference for homotrimer over heterotrimer formation, suggesting that assembly at the N-terminus occurs co-translationally. This was corroborated by the observation that polysome-associated sigma1 chains were trimeric as well as monomeric. Truncated proteins (d234 and d294) with C-terminal deletions exceeding half the length of sigma1 were found to trimerize post-translationally. This trimerization did not require ATP since it proceeded normally in the presence of apyrase. In contrast, formation of stable FL sigma1 trimers was inhibited by apyrase treatment. Collectively, our data suggest that assembly of nascent sigma1 chains at the N-terminus is intrinsically ATP independent, and occurs co-translationally when the ribosomes have traversed past the midpoint of the mRNA.     

Adenovirus fiber shaft contains a trimerization element that supports peptide fusion for targeted gene delivery

Adenoviral (Ad) vectors have been widely used in human gene therapy clinical trials. However, their application has frequently been restricted by the unfavorable expression of cell surface receptors critical for Ad infection. Infections by Ad2 and Ad5 are largely regulated by the elongated fiber protein that mediates its attachment to a cell surface receptor, coxsackie and adenovirus receptor (CAR). The fiber protein is a homotrimer consisting of an N-terminal tail, a long shaft, and a C-terminal knob region that is responsible for high-affinity receptor binding and Ad tropism. Consequently, the modification of the knob region, including peptide insertion and C-terminal fusion of ligands for cell surface receptors, has become a major research focus for targeting gene delivery. Such manipulation tends to disrupt fiber assembly since the knob region contains a stabilization element for fiber trimerization. We report here the identification of a novel trimerization element in the Ad fiber shaft. We demonstrate that fiber fragments containing the N-terminal tail and shaft repeats formed stable trimers that assembled onto Ad virions independently of the knob region. This fiber shaft trimerization element (FSTE) exhibited a capacity to support peptide fusion. We showed that Ad, modified with a chimeric protein by direct fusion of the FSTE with a growth factor ligand or a single-chain antibody, delivered a reporter gene selectively. Together, these results indicate that the shaft region of Ad fiber protein contains a trimerization element that allows ligand fusion, which potentially broadens the basis for Ad vector development.     

High-affinity interactions of tumor necrosis factor receptor-associated factors (TRAFs) and CD40 require TRAF trimerization and CD40 multimerization.

Signaling by some TNF receptor family members, including CD40, is mediated by TNF receptor-associated factors (TRAFs) that interact with receptor cytoplasmic domains following ligand-induced receptor oligomerization. Here we have defined the oligomeric structure of recombinant TRAF domains that directly interact with CD40 and quantitated the affinities of TRAF2 and TRAF3 for CD40. Biochemical and biophysical analyses demonstrated that TRAF domains of TRAF1, TRAF2, TRAF3, and TRAF6 formed homo-trimers in solution. N-terminal deletions of TRAF2 and TRAF3 defined minimal amino acid sequences necessary for trimer formation and indicated that the coiled coil TRAF-N region is required for trimerization. Consistent with the idea that TRAF trimerization is required for high-affinity interactions with CD40, monomeric TRAF-C domains bound to CD40 significantly weaker than trimeric TRAFs. In surface plasmon resonance studies, a hierarchy of affinity of trimeric TRAFs for trimeric CD40 was found to be TRAF2 > TRAF3 > TRAF1 and TRAF6. CD40 trimerization was demonstrated to be sufficient for optimal NF-kappaB and p38 mitogen activated protein kinase activation through wild-type CD40. In contrast, a higher degree of CD40 multimerization was necessary for maximal signaling in a cell line expressing a mutated CD40 (T254A) that signaled only through TRAF6. The affinities of TRAF proteins for oligomerized receptors as well as different requirements for degree of receptor multimerization appear to contribute to the selectivity of TRAF recruitment to receptor cytoplasmic domains.     

Amyloid fibril formation from sequences of a natural beta-structured fibrous protein, the adenovirus fiber

Amyloid fibrils are fibrous beta-structures that derive from abnormal folding and assembly of peptides and proteins. Despite a wealth of structural studies on amyloids, the nature of the amyloid structure remains elusive; possible connections to natural, beta-structured fibrous motifs have been suggested. In this work we focus on understanding amyloid structure and formation from sequences of a natural, beta-structured fibrous protein. We show that short peptides (25 to 6 amino acids) corresponding to repetitive sequences from the adenovirus fiber shaft have an intrinsic capacity to form amyloid fibrils as judged by electron microscopy, Congo Red binding, infrared spectroscopy, and x-ray fiber diffraction. In the presence of the globular C-terminal domain of the protein that acts as a trimerization motif, the shaft sequences adopt a triple-stranded, beta-fibrous motif. We discuss the possible structure and arrangement of these sequences within the amyloid fibril, as compared with the one adopted within the native structure. A 6-amino acid peptide, corresponding to the last beta-strand of the shaft, was found to be sufficient to form amyloid fibrils. Structural analysis of these amyloid fibrils suggests that perpendicular stacking of beta-strand repeat units is an underlying common feature of amyloid formation.     

Very fast folding and association of a trimerization domain from bacteriophage T4 fibritin

The foldon domain constitutes the C-terminal 30 amino acid residues of the trimeric protein fibritin from bacteriophage T4. Its function is to promote folding and trimerization of fibritin. We investigated structure, stability and folding mechanism of the isolated foldon domain. The domain folds into the same trimeric beta-propeller structure as in fibritin and undergoes a two-state unfolding transition from folded trimer to unfolded monomers. The folding kinetics involve several consecutive reactions. Structure formation in the region of the single beta-hairpin of each monomer occurs on the submillisecond timescale. This reaction is followed by two consecutive association steps with rate constants of 1.9(+/-0.5)x10(6)M(-1)s(-1) and 5.4(+/-0.3)x10(6)M(-1)s(-1) at 0.58 M GdmCl, respectively. This is similar to the fastest reported bimolecular association reactions for folding of dimeric proteins. At low concentrations of protein, folding shows apparent third-order kinetics. At high concentrations of protein, the reaction becomes almost independent of protein concentrations with a half-time of about 3 ms, indicating that a first-order folding step from a partially folded trimer to the native protein (k=210 +/- 20 s(-1)) becomes rate-limiting. Our results suggest that all steps on the folding/trimerization pathway of the foldon domain are evolutionarily optimized for rapid and specific initiation of trimer formation during fibritin assembly. The results further show that beta-hairpins allow efficient and rapid protein-protein interactions during folding.     

Formation of highly stable chimeric trimers by fusion of an adenovirus fiber shaft fragment with the foldon domain of bacteriophage t4 fibritin

The folding of beta-structured, fibrous proteins is a largely unexplored area. A class of such proteins is used by viruses as adhesins, and recent studies revealed novel beta-structured motifs for them. We have been studying the folding and assembly of adenovirus fibers that consist of a globular C-terminal domain, a central fibrous shaft, and an N-terminal part that attaches to the viral capsid. The globular C-terminal, or "head" domain, has been postulated to be necessary for the trimerization of the fiber and might act as a registration signal that directs its correct folding and assembly. In this work, we replaced the head of the fiber by the trimerization domain of the bacteriophage T4 fibritin, termed "foldon." Two chimeric proteins, comprising the foldon domain connected at the C-terminal end of four fiber shaft repeats with or without the use of a natural linker sequence, fold into highly stable, SDS-resistant trimers. The structural signatures of the chimeric proteins as seen by CD and infrared spectroscopy are reported. The results suggest that the foldon domain can successfully replace the fiber head domain in ensuring correct trimerization of the shaft sequences. Biological implications and implications for engineering highly stable, beta-structured nanorods are discussed.     

Functional Role of the N-Terminal Domain of Bacteriophage T4-Gene Product 11

Bacteriophage T4 late gene product 11 (gp11), the three-dimensional structure of which has been solved by us to 2.0 A resolution, is a part of the virus' baseplate. The gp11 polypeptide chain consists of 219 amino acid residues and the functionally active protein is a three-domain homotrimer. In this work, we have studied the role of gp11 N-terminal domain in the formation of a functionally active trimer. Deletion variants of gp11 and monoclonal antibodies recognizing the native conformation of gp11 trimer have been selected. Long deletions up to a complete removal of the N-terminal domain, containing 64 residues, do not affect the gp11 trimerization, but considerably change the protein structure and lead to the loss of its ability to incorporate into the baseplate. However, the deletion of the first 17 N-terminal residues results in functionally active protein that can complete the 11(-)-defective phage particles in in vitro complementation assay. This region of the polypeptide chain is probably essential for gp11-gp10 stable complex formation at the early stages of phage baseplate assembly in vivo. A study of the gp10 deletion variants suggests that the central domain of gp10 trimer is responsible for the interaction with gp11.     

Characterization of the knob domain of the adenovirus type 5 fiber protein expressed in Escherichia coli.

The adenovirus fiber protein is used for attachment of the virus to a specific receptor on the cell surface. Structurally, the protein consists of a long, thin shaft that protrudes from the vertex of the virus capsid and terminates in a globular domain termed the knob. To verify that the knob is the domain which interacts with the cellular receptor, we have cloned and expressed the knob from adenovirus type 5 together with a single repeat of the shaft in Escherichia coli. The protein was purified by conventional chromatography and functionally characterized for its interaction with the adenovirus receptor. The recombinant knob domain bound about 4,700 sites per HeLa cell with an affinity of 3 x 10(9) M-1 and blocked adenovirus infection of human cells. Antibodies raised against the knob also blocked virus infection. By gel filtration and X-ray diffraction analysis of protein crystals, the knob was shown to consist of a homotrimer of 21-kDa subunits. The results confirm that the trimeric knob is the ligand for attachment to the adenovirus receptor.     

Assembly of bacteriophage PRD1 spike complex: role of the multidomain protein P5

The spike structure of bacteriophage PRD1 is comprised of proteins P2, P5, and P31. It resembles the corresponding receptor-binding structure of adenoviruses. We show that purified recombinant protein P5 is an elongated (30 x 2.7 nm; R(h) = 5.5 nm), multidomain trimer which can slowly associate into nonamers. Cleavage of the 340 amino acid long P5 with collagenase yields 2 fragments. The larger, 205 amino acid long C-terminal fragment appears to contain the residues responsible for the trimerization of the protein, whereas the smaller N-terminal part mediates the interaction of P5 with the pentameric vertex protein P31 (24 x 2.5 nm, R(h) = 4.2 nm). In addition, the presence of the N-terminal sequence is required for the formation of the P5 nonamer. The results presented here suggest that P5 and P31 form an elongated adaptor complex at the 5-fold vertexes of the virion which anchors the adsorption protein P2 (21 x 2.5 nm; R(h) = 4.1 nm). Our results also suggest that the P5 trimer forms a substantial part of the viral spike shaft that was previously thought to be composed exclusively of protein P2.     

NMR Structure of a Monomeric Intermediate on the Evolutionarily Optimized Assembly Pathway of a Small Trimerization Domain

Efficient formation of specific intermolecular interactions is essential for self-assembly of biological structures. The foldon domain is an evolutionarily optimized trimerization module required for assembly of the large, trimeric structural protein fibritin from phage T4. Monomers consisting of the 27 amino acids comprising a single foldon domain subunit spontaneously form a natively folded trimer. During assembly of the foldon domain, a monomeric intermediate is formed on the submillisecond time scale, which provides the basis for two consecutive very fast association reactions. Mutation of an intermolecular salt bridge leads to a monomeric protein that resembles the kinetic intermediate in its spectroscopic properties. NMR spectroscopy revealed essentially native topology of the monomeric intermediate with defined hydrogen bonds and side-chain interactions but largely reduced stability compared to the native trimer. This structural preorganization leads to an asymmetric charge distribution on the surface that can direct rapid subunit recognition. The low stability of the intermediate allows a large free-energy gain upon trimerization, which serves as driving force for rapid assembly. These results indicate different free-energy landscapes for folding of small oligomeric proteins compared to monomeric proteins, which typically avoid the transient population of intermediates.     

A Role for the Sendai Virus P Protein Trimer in RNA Synthesis

The SeV P protein is found as a homotrimer (P₃) when it is expressed in mammalian cells, and trimerization is mediated by a predicted coiled-coil motif which maps within amino acids (aa) 344 to 411 (the BoxA region). The bacterially expressed protein also appears to be trimeric, apparently precluding a role for phosphorylation in the association of the P monomers. I have examined the role of P trimerization both in the protein’s interaction with the nucleocapsid (N:RNA) template and in the protein’s function on the template during RNA synthesis. As with the results of earlier experiments (32), I found that both the BoxA and BoxC (aa 479 to 568) regions were required for stable binding of P to the N:RNA. Binding was also observed with P proteins containing less than three BoxC regions, suggesting that trimerization may be required to permit contacts between multiple BoxC regions and the N:RNA. However, these heterologous trimers failed to function in viral RNA synthesis, indicating that the third C-terminal leg of the trimer plays an essential role in P function on the template. We speculate that this function may involve the movement of P (and possibly the polymerase complex) on the template and the maintenance of processivity.     

Epitopes and hemagglutination binding domain on subgenus B:2 adenovirus fibers.

The adenovirus fiber serves as a ligand between the virus and the host cell receptor and manifests hemagglutination (HA) activity and antigenic domains. We have screened both the antigenic and immunogenic epitopes on the adenovirus fibers of subgenus B:2 by using recombinant fiber proteins (rfibers) expressed in Escherichia coli, synthesized peptides (P1 to P8), and the corresponding antisera. The results indicated that P4 (amino acids [aa] 201 to 220), P5 (aa 231 to 250), and P7 (aa 275 to 295) presented both antigenic and immunogenic epitopes in adenovirus type 11 prototype (Ad11p), Ad34a, and Ad11a fibers. P6 (aa 251 to 270) presented both epitopes in Ad11a fiber but only an antigenic epitope in other fibers. The C-terminal 20 amino acids of the fiber, corresponding to P8, manifested an epitope of low-level immunogenicity. P5, localized at the N-terminal aa 231 to 250, displayed an epitope that reacted with fibers of all the members of subgenus B analyzed. The rfibers of Ad11p and Ad34a displayed HA activity with monkey erythrocytes, though those of Ad11a did not. Mutagenesis of the rfibers revealed that neither the fragment replacements, 11p20211a, llp26011a,and 11a28011p, nor the Ad11p rfiber with the substitutions of Tyr-260-->H (Tyr260H)and Arg279Q displayed HA activity. The Ad11a fiber knob was sensitive to proteolytic digestion, whereas that of Ad11p was resistant. The results demonstrated that the decisive HA binding domain was presented at aa 260 to 280 and was conformation dependent. Nearby amino acids, aa 283 and 284, may also affect the HA function.     

Structure and folding of bacteriophage T4 gene product 9 triggering infection. II. Study Of conformational changes of gene product 9 mutants using monoclonal antibodies

Gene product 9 (gp9) of bacteriophage T4, whose spatial structure we have recently solved to 2.3 A resolution, is a convenient model for studying the folding and oligomerization mechanisms of complex proteins. The gp9 polypeptide chain consists of 288 amino acids forming three domains. Three monomers, packed in parallel, assemble to a functionally active protein. The main aim of this work was to study conformational changes and trimerization of gp9 deletion mutants using monoclonal antibodies (mAbs). We selected a set of mAbs interacting with the amino, middle, and carboxyl regions of the protein, respectively. Eighteen mAbs bind to native as well as to denatured protein, and two mAbs bind to denatured protein only. Using mAbs, we found that deletions of the gp9 N-terminal region result in conformational changes in the middle and C-terminal domains. The study of mAb binding to the CDelta. truncated mutant by competitive ELISA and immunoblotting shows that the C-terminus of the gp9 sequence is essential for protein trimerization and stability. A single point substitution of the Gln282 residue causes formation of a labile trimer that has significant conformational changes in the protein domains. The results of our study show that folding and trimerization of gp9 is a cooperative process that involves all domains of the protein.     

A role for the transmembrane domain in the trimerization of the MHC class II-associated invariant chain.

MHC class II and invariant chain (Ii) associate early in biosynthesis to form a nonameric complex. Ii first assembles into a trimer and then associates with three class II alphabeta heterodimers. Although the membrane-proximal region of the Ii luminal domain is structurally disordered, the C-terminal segment of the luminal domain is largely alpha-helical and contains a major interaction site for the Ii trimer. In this study, we show that the Ii transmembrane domain plays an important role in the formation of Ii trimers. The Ii transmembrane domain contains an unusual patch of hydrophilic residues near the luminal interface. Substitution of these polar residues with nonpolar amino acids resulted in a decrease in the efficiency of Ii trimerization and subsequent class II association. Moreover, N-terminal fragments of Ii were found to trimerize independently of the luminal alpha-helical domain. Progressive C-terminal truncations mapped a homotypic association site to the first 80 aa of Ii. Together, these results implicate the Ii transmembrane domain as a site of trimer interaction that can play an important role in the initiation of trimer formation.     

Crystal Structure and Trimer-Monomer Transition of N-Terminal Domain of EhCaBP1 from Entamoeba histolytica

EhCaBP1 is a well-characterized calcium binding protein from Entamoeba histolytica with four canonical EF-hand motifs. The crystal structure of EhCaBP1 reveals the trimeric organization of N-terminal domain. The solution structure obtained at pH 6.0 indicated its monomeric nature, similar to that of calmodulin. Recent domain-wise studies showed clearly that the N-terminal domain of EhCaBP1 is capable of performing most of the functions of the full-length protein. Additionally, the mode of target binding in the trimer is similar to that found in calmodulin. To study the dynamic nature of this protein and further validate the trimerization of N-terminal domain at physiological conditions, the crystal structure of N-terminal domain was determined at 2.5 Å resolution. The final structure consists of EF-1 and EF-2 motifs separated by a long straight helix as seen in the full-length protein. The spectroscopic and stability studies, like far and near-ultraviolet circular dichroism spectra, intrinsic and extrinsic fluorescence spectra, acrylamide quenching, thermal denaturation, and dynamic light scattering, provided clear evidence for a conversion from trimeric state to monomeric state. As the pH was lowered from the physiological pH, a dynamic trimer-monomer transition was observed. The trimeric state and monomeric state observed in spectroscopic studies may represent the x-ray and NMR structures of the EhCaBP1. At pH 6.0, the endogenous kinase activation function was almost lost, indicating that the monomeric state of the protein, where EF-hand motifs are far apart, is not a functional state.     

Synthesis of human adenovirus type 2 fiber protein in Escherichia coli cells

We have cloned and expressed in Escherichia coli the gene encoding the trimeric fiber protein of human adenovirus type 2. A gene expression system based on bacteriophage T7 RNA polymerase was used. Optimal gene expression was obtained with 1-h induction, at a temperature of 30 degrees C. The synthesized protein constituted about 1% of total host-cell protein. During induction, the growth of bacteria carrying the plasmid containing the fiber gene, was retarded compared with that of bacteria carrying the plasmid without the fiber gene. This toxic effect of fiber protein on bacterial hosts could be diminished by addition of glucose to the medium and by maintaining the pH above 7, thus improving the yield of recombinant fiber protein. The fiber protein produced in E. coli is stable during the course of induction. It is insoluble in buffers at physiological pH, in various salt solutions, and in the presence of nonionic detergents. It can be solubilized in 1% sodium dodecyl sulfate or in urea solutions above 2 M. There are indications that recombinant fiber trimerizes spontaneously, since after the removal of urea by dialysis at pH 8, recombinant fibers runs similarly to native trimeric fiber, on nondenaturing polyacrylamide gels. This trimer has, however, a less compact structure than native Ad2 fiber, since during gel filtration recombinant protein is excluded before native protein. It is also more sensitive to chymotrypsin digestion than native fiber.     

Targeting Adenoviral Vectors by Using the Extracellular Domain of the Coxsackie-Adenovirus Receptor: Improved Potency via Trimerization

Adenovirus binds to mammalian cells via interaction of fiber with the coxsackie-adenovirus receptor (CAR). Redirecting adenoviral vectors to enter target cells via new receptors has the advantage of increasing the efficiency of gene delivery and reducing nonspecific transduction of untargeted tissues. In an attempt to reach this goal, we have produced bifunctional molecules with soluble CAR (sCAR), which is the extracellular domain of CAR fused to peptide-targeting ligands. Two peptide-targeting ligands have been evaluated: a cyclic RGD peptide (cRGD) and the receptor-binding domain of apolipoprotein E (ApoE). Human diploid fibroblasts (HDF) are poorly transduced by adenovirus due to a lack of CAR on the surface. Addition of the sCAR-cRGD or sCAR-ApoE targeting protein to adenovirus redirected binding to the appropriate receptor on HDF. However, a large excess of the monomeric protein was needed for maximal transduction, indicating a suboptimal interaction. To improve interaction of sCAR with the fiber knob, an isoleucine GCN4 trimerization domain was introduced, and trimerization was verified by cross-linking analysis. Trimerized sCAR proteins were significantly better at interacting with fiber and inhibiting binding to HeLa cells. Trimeric sCAR proteins containing cRGD and ApoE were more efficient at transducing HDF in vitro than the monomeric proteins. In addition, the trimerized sCAR protein without targeting ligands efficiently blocked liver gene transfer in normal C57BL/6 mice. However, addition of either ligand failed to retarget the liver in vivo. One explanation may be the large complex size, which serves to decrease the bioavailability of the trimeric sCAR-adenovirus complexes. In summary, we have demonstrated that trimerization of sCAR proteins can significantly improve the potency of this targeting approach in altering vector tropism in vitro and allow the efficient blocking of liver gene transfer in vivo.     

Mutational analysis of the zippering reaction during flavivirus membrane fusion

The current model of flavivirus membrane fusion is based on atomic structures of truncated forms of the viral fusion protein E in its dimeric prefusion and trimeric postfusion conformations. These structures lack the two transmembrane domains (TMDs) of E as well as the so-called stem, believed to be involved in an intra- and intermolecular zippering reaction within the E trimer during the fusion process. In order to gain experimental evidence for the functional role of the stem in flavivirus membrane fusion, we performed a mutagenesis study with recombinant subviral particles (RSPs) of tick-borne encephalitis virus, which have fusion properties similar to those of whole infectious virions and are an established model for viral fusion. Mutations were introduced into the stem as well as that part of E predicted to interact with the stem during zippering, and the effect of these mutations was analyzed with respect to fusion peptide interactions with target cells, E protein trimerization, trimer stability, and membrane fusion in an in vitro liposome fusion assay. Our data provide evidence for a molecular interaction between a conserved phenylalanine at the N-terminal end of the stem and a pocket in domain II of E, which appears to be essential for the positioning of the stem in an orientation that allows zippering and the formation of a structure in which the TMDs can interact as required for efficient fusion.     

Unfolding studies of human adenovirus type 2 fibre trimers. Evidence for a stable domain.

Adenovirus fibres are trimeric proteins that protrude from the 12 fivefold vertices of the virion and are the cell attachment organelle of the virus. They consist of three segments: an N-terminal tail, which is noncovalently attached to the penton base, a thin shaft carrying 15 amino acid pseudo repeats, and a C-terminal globular head (or knob) which recognizes the primary cell receptor. Due to their exceptional stability, which allows easy distinction of native trimers from unfolded forms and folding intermediates, adenovirus fibres are a very good model system for studying folding in vivo and in vitro. To understand the folding and stability of the trimeric fibres, the unfolding pathway of adenovirus 2 fibres induced by SDS and temperature has been investigated. Unfolding starts from the N-terminus and a stable intermediate accumulates that has the C-terminal head and part of the shaft structure (shown by electron microscopy). The unfolded part can be digested away using limited proteolysis, and the precise digestion sites have been determined. The remaining structured fragment is recognized by monoclonal antibodies that are specific for the trimeric globular head and therefore retains a native trimeric structure. Taken together, our results indicate that adenovirus fibres carry a stable C-terminal domain, consisting of the knob with five shaft-repeats.     

Human adenovirus serotypes 3 and 5 bind to two different cellular receptors via the fiber head domain.

The adenovirus fiber protein is responsible for attachment of the virion to cell surface receptors. The identity of the cellular receptor which mediates binding is unknown, although there is evidence suggesting that two distinct adenovirus receptors interact with the group C (adenovirus type 5 [Ad5]) and the group B (Ad3) adenoviruses. In order to define the determinants of adenovirus receptor specificity, we have carried out a series of competition binding experiments using recombinant native fiber polypeptides from Ad5 and Ad3 and chimeric fiber proteins in which the head domains of Ad5 and Ad3 were exchanged. Specific binding of fiber to HeLa cell receptors was assessed with radiolabeled protein synthesized in vitro, and by competition analysis with baculovirus-expressed fiber protein. Fiber produced in vitro was found as both monomer and trimer, but only the assembled trimers had receptor binding activity. Competition data support the conclusion that Ad5 and Ad3 interact with different cellular receptors. The Ad5 receptor distribution on several cell lines was assessed with a fiber binding flow cytometric assay. HeLa cells were found to express high levels of receptor, while CHO and human diploid fibroblasts did not. A chimeric fiber containing the Ad5 fiber head domain blocked the binding of Ad5 fiber but not Ad3 fiber. Similarly, a chimeric fiber containing the Ad3 fiber head blocked the binding of labeled Ad3 fiber but not Ad5 fiber. In addition, the isolated Ad3 fiber head domain competed effectively with labeled Ad3 fiber for binding to HeLa cell receptors. These results demonstrate that the determinants of receptor binding are located in the head domain of the fiber and that the isolated head domain is capable of trimerization and binding to cellular receptors. Our results also show that it is possible to change the receptor specificity of the fiber protein by manipulation of sequences contained in the head domain. Modification or replacement of the fiber head domain with novel ligands may permit adenovirus vectors with new receptor specificities which could be useful for targeted gene delivery in vivo to be engineered.