Structure of the fiber head of Ad3, a non-CAR-binding serotype of adenovirus.

Adenoviruses of serotype Ad3 (subgenus B) use a still-unknown host cell receptor for viral attachment, whereas viruses from all other known subgenera use the coxsackie and adenovirus receptor (CAR). The receptor binding domain (head) of the Ad3 fiber protein has been expressed in Escherichia coli inclusion bodies. After denaturation and renaturation using a rapid dilution method, crystals of trimeric head were obtained. The 1.6 A resolution X-ray structure shows a strict conservation of the beta-sheet scaffold of the protein very similar to the head structures of the CAR-binding serotypes Ad2, Ad5, and Ad12. The conformation of the loops is different, with the exception of the AB loop, which forms the center of the interface in the Ad12-CAR complex structure. The structure explains why a mutation in Ad5 of one residue in the AB loop to glutamic acid, as in Ad3, abrogates binding to CAR. It is possible that the Ad3 receptor binding site is nevertheless situated similar to the CAR binding site, although it cannot be excluded that other regions of the relatively hydrophobic head surface may be used.

A peptide from the adenovirus fiber shaft forms amyloid-type fibrils.

The fiber protein of adenovirus consists of a C-terminal globular head, a shaft and a short N-terminal tail. The crystal structure of a stable domain comprising the head plus a part of the shaft of human adenovirus type 2 fiber has recently been solved at 2.4 A resolution [van Raaij et al. (1999) Nature 401, 935-938]. A peptide corresponding to the portion of the shaft immediately adjacent to the head (residues 355-396) has been synthesized chemically. The peptide failed to assemble correctly and instead formed amyloid-type fibrils as assessed by electron microscopy, Congo red binding and X-ray diffraction. Peptides corresponding to the fiber shaft could provide a model system to study mechanisms of amyloid fibril formation.

A triple beta-spiral in the adenovirus fibre shaft reveals a new structural motif for a fibrous protein.

Human adenoviruses are responsible for respiratory, gastroenteric and ocular infections and can serve as gene therapy vectors. They form icosahedral particles with 240 copies of the trimeric hexon protein arranged on the planes and a penton complex at each of the twelve vertices. The penton consists of a pentameric base, implicated in virus internalization, and a protruding trimeric fibre, responsible for receptor attachment. The fibres are homo-trimeric proteins containing an amino-terminal penton base attachment domain, a long, thin central shaft and a carboxy-terminal cell attachment or head domain. The shaft domain contains a repeating sequence motif with an invariant glycine or proline and a conserved pattern of hydrophobic residues. Here we describe the crystal structure at 2.4 A resolution of a recombinant protein containing the four distal repeats of the adenovirus type 2 fibre shaft plus the receptor-binding head domain. The structure reveals a novel triple beta-spiral fibrous fold for the shaft. Implications for folding of fibrous proteins (misfolding of shaft peptides leads to amyloid-like fibrils) and for the design of a new class of artificial, silk-like fibrous materials are discussed.

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.

Thermolabile folding intermediates: inclusion body precursors and chaperonin substrates.

An unexpected aspect of the expression of cloned genes is the frequent failure of newly synthesized polypeptide chains to reach their native state, accumulating instead as insoluble inclusion bodies. Amyloid deposits represent a related state associated with a variety of human diseases. The critical folding intermediates at the juncture of productive folding and the off-pathway aggregation reaction have been identified for the phage P22 tailspike and coat proteins. Though the parallel beta coil tailspike is thermostable, an early intracellular folding intermediate is thermolabile. As the temperature of intracellular folding is increased, this species partitions to inclusion bodies, a kinetic trap within the cell. The earliest intermediates along the in vitro aggregation pathway, sequential multimers of the thermolabile folding intermediates, have been directly identified by native gel electrophoresis. Temperature-sensitive folding (tsf) mutations identify sites in the beta coil domain, which direct the junctional intermediate down the productive pathway. Global suppressors of tsf mutants inhibit the pathway to inclusion bodies, rescuing the mutant chains. These mutants identify sites important for avoiding aggregation. Coat folding intermediates also partition to inclusion bodies as temperature is increased. Coat tsf mutants are suppressed by overexpression of the GroE chaperonin, indicating that the thermolabile intermediate is a physiological substrate for GroE. We suggest that many proteins are likely to have thermolabile intermediates in their intracellular folding pathways, which will be precursors to inclusion body formation at elevated temperatures and therefore substrates for heat shock chaperonins.

Temperature-sensitive mutations and second-site suppressor substitutions affect folding of the P22 tailspike protein in vitro.

One of the central problems in protein folding is how amino acid sequences within polypeptide chains direct polypeptide chain folding and avoid off-pathway aggregation both in intracellular environments and in the test tube. The tailspike protein of phage P22 is a model system for which genetic analysis has permitted mutational dissection of the role of amino acid positions in the polypeptide chain in directing its in vivo folding. Two classes of mutations that affect intracellular folding and aggregation have been characterized; temperature-sensitive folding (tsf) mutants and second-site suppressors of tsf mutants. Here we report the effects of these mutations on the in vitro refolding and aggregation pathway of the purified proteins. The tsf mutations reduced refolding yields at high temperature and increased aggregation, while second-site suppressors enhanced refolding and inhibited aggregation in the test tube. For both types of mutations, the strength of the effects observed in vitro correlated with their in vivo phenotypes. The results confirm that the mutations act intrinsically on the folding pathway of the tailspike polypeptide and not through accessory proteins.

Amino acid substitutions influencing intracellular protein folding pathways.

Though an increasing variety of chaperonins are emerging as important factors in directing polypeptide chain folding off the ribosome, the primary amino acid sequence remains the major determinant of final conformation. The ability to identify cytoplasmic folding intermediates in the formation of the tailspike endorhamnosidase of phage P22 has made it possible to isolate two classes of mutations influencing folding intermediates-temperature-sensitive folding mutations and global suppressors of tsf mutants. These and related amino acid substitutions in eukaryotic proteins are discussed in the context of inclusion body formation and problems in the recovery of correctly folded proteins.

Global suppression of protein folding defects and inclusion body formation.

Amino acid substitutions at a site in the center of the bacteriophage protein P22 tailspike polypeptide chain suppress temperature-sensitive folding mutations at many sites throughout the chain. Characterization of the intracellular folding and chain assembly process reveals that the suppressors act in the folding pathway, inhibiting the aggregation of an early folding intermediate into the kinetically trapped inclusion body state. The suppressors alone increase the folding efficiency of the otherwise wild-type polypeptide chain without altering the stability or activity of the native state. These amino acid substitutions identify an unexpected aspect of the protein folding grammar--sequences within the chain that carry information inhibiting unproductive off-pathway conformations. Such mutations may serve to increase the recovery of protein products of cloned genes.

Identification of global suppressors for temperature-sensitive folding mutations of the P22 tailspike protein.

Suppressor mutations which alleviate the defects in folding mutants of the P22 gene 9 tailspike protein have recently been isolated (Fane, B. and King, J. (1991) Genetics 127, 263-277). The starting folding defects were in missense polypeptide chains generated by host amino acid insertions at different amber mutant sites. Fragments of genes carrying the amber mutations with and without their independently isolated suppressor mutations were cloned and sequenced. The parental nonsense mutations were located at Q45, K122, E156, W202, W207, Y232, and W365. Their conformational suppressors were single amino acid substitutions at a limited set of sites, V84 greater than A, V331 greater than A, and A334 greater than V. The V331 greater than A or A334 greater than V suppressors were independently recovered starting with different mutant sites suggesting that they acted by some global or general mechanism. When the V331 greater than A and A334 greater than V mutations were crossed into well-characterized temperature-sensitive folding (tsf) mutants at various sites in the tailspike protein, they suppressed all of the eight tsf mutants tested. Since the tsf defects destabilize folding intermediates rather than the native conformation, this result implies that the suppressors act in the folding pathway. Strains carrying the isolated suppressor mutations displayed no obvious phenotypic defect and formed native biologically active tailspikes. Thus, these single amino acid substitutions have striking influences on the efficiency of intracellular chain folding, without causing functional defects in the native protein.

Survey of the folding pathway of a two-domain protein phosphoglycerate kinase.

The role of structural domains as folding units in the folding process which generates an active enzyme, is considered through several studies on phosphoglycerate kinase, a two-domain enzyme which catalyzes the first step of ATP production in glycolysis. The folding pathway was found to be a complex multi-step process, the C-terminal domain being more stable folding first. Inactive species originating from an intermediate in the folding pathway have been identified. Isolated domains recently obtained using genetic engineering are under investigation in our laboratory; this might probably allow to understand the way by which the N-terminal domain reaches its final native conformation and interacts with the other domain.

The effect of phosphate on the unfolding-refolding of phosphoglycerate kinase induced by guanidine hydrochloride.

Phosphate ions were found to stabilize the native structure of phosphoglycerate kinase without modifying the folding pathway. The transition curves obtained from different signals: enzyme activity, ellipticity at 220 nm and fluorescence intensity at 336 nm (excitation at 292 nm) are shifted to smaller guanidine hydrochloride cm values in the absence of phosphate. The kinetic characteristics are qualitatively similar, unfolding rate constants being slightly smaller in the presence of phosphate. The mechanism by which the native structure of phosphoglycerate kinase is stabilized by phosphate probably occurs upon specific phosphate binding to the nucleotide beta- or gamma-phosphate binding site of nucleotides.

Quasi-irreversibility in the unfolding-refolding transition of phosphoglycerate kinase induced by guanidine hydrochloride.

The reversibility of the unfolding-refolding transition of horse muscle phosphoglycerate kinase, induced by guanidine hydrochloride (Gdn X HCl), was studied using the regain of enzyme activity as a probe of the native structure. An irreversibility in the reactivation process was detected when the protein was incubated in a critical concentration of denaturant (0.7 +/- 0.1 M Gdn X HCl). This apparent irreversibility was observed for the unfolding process (N----D) as well as for the refolding process (D----N). The formation of the trough followed biphasic kinetics at 23 degrees C, the first phase obeying a first-order reaction corresponded to an isomerization of an intermediate; the second phase, protein-concentration-dependent, was suppressed by lowering the temperature to 4 degrees C. The structural properties of the inactive species were studied; all the beta structures were recovered, but about 29% of the helical structures remained unfolded, and two SH groups were buried. Simulated kinetics were compared with the experimental results and were used to extend the minimum folding scheme previously proposed from equilibrium and kinetic studies [Betton et al. (1984) Biochemistry 23, 6654-6661; Betton et al. (1985) Biochemistry 24, 4570-4577]. The intermediates trapped under these conditions were structured but devoid of catalytic activity. Taking into account the structural properties of these species, the nature of the interactions involved in their formation and stabilization is discussed.

Kinetic studies of the unfolding-refolding of horse muscle phosphoglycerate kinase induced by guanidine hydrochloride.

The kinetics of the unfolding and refolding of horse muscle phosphoglycerate kinase were studied with three different signals: fluorescence emission intensity at 336 nm (excitation at 292 nm), ellipticity at 220 nm, and enzyme activity. The results corroborate the conclusion on the existence of intermediates in the folding pathway obtained from equilibrium studies. Kinetic studies showed at least two phases of refolding, as revealed by fluorescence as well as by circular dichroism measurements. During the fast phase, an intermediate was formed with a fluorescence intensity higher than that of the native protein, but devoid of enzyme activity. The fluorescence emission spectrum of this intermediate was determined. Only the slow phase was detected for the unfolding process; it was not attributable to proline isomerization. Several models were assumed, and simulated kinetics derived from these models were compared with the experimental results. A plausible one accounting for most of the data is proposed.

Unfolding-refolding transition of a hinge bending enzyme: horse muscle phosphoglycerate kinase induced by guanidine hydrochloride.

The unfolding-refolding transition of horse muscle phosphoglycerate kinase induced by guanidine hydrochloride was studied under equilibrium conditions using four different signals: fluorescence intensity at 336 nm, UV difference absorbance at 286 and 292 nm, ellipticity at 220 nm, and enzyme activity. From the following arguments, we found that the process deviates from a two-state model and intermediates are significantly populated even at equilibrium: (1) the noncoincidence of the transition curves and (2) the asymmetry of the transition curve obtained from CD measurements. From these different data and the thermodynamic analysis, it was suggested that the two domains of the horse muscle phosphoglycerate kinase refold independently of one another with different equilibrium constants, the most favorable constant referring to the folding of the C-terminal domain which contains all tryptophans.

GuHC1 induced unfolding-folding transition of a hinge-bending protein: horse muscle phosphoglycerate kinase.

The unfolding-folding transition of phosphoglycerate kinase induced by GuHC1 was studied at equilibrium. Various signals were used to follow the transition: fluorescence emission, difference spectra, circular dichroism and enzymatic activity. The non-coincidence of transition curves obtained from different structural parameters indicate a deviation from a two-state process. The view that structural domains behave as independent "folding units" is critically discussed.