Probing pH-dependent functional elements in proteins: modification of carboxylic acid pairs in Trichoderma reesei cellobiohydrolase Cel6A

Two carboxylic acid side chains can, depending on their geometry and environment, share a proton in a hydrogen bond and form a carboxyl-carboxylate pair. In the Trichoderma reesei cellobiohydrolase Cel6A structure, five carboxyl-carboxylate pairs are observed. One of these pairs (D175-D221) is involved in catalysis, and three other pairs are found in, or close to the two surface loops covering the active site tunnel of the catalytic domain. To stabilize Cel6A at alkaline pH values, where deprotonation of the carboxylic acids leads to repulsion of their side chains, we designed two mutant enzymes. In the first mutant, one carboxyl-carboxylate pair (E107-E399) was replaced by a corresponding amide-carboxylate pair (Q107-E399), and in the second mutant, all three carboxyl-carboxylate pairs (E107-E399, D170-E184, and D366-D419) were mutated in a similar manner. The unfolding studies using both intrinsic tryptophan fluorescence and far-ultraviolet circular dichroism spectroscopy at different pH values demonstrate that the unfolding temperature (T(m)) of both mutants has changed, resulting in destabilization of the mutant enzymes at acidic pH and stabilization at alkaline pH. The effect of stabilization seems additive, as a Cel6A triple mutant is the most stable enzyme variant. This increased stability is also reflected in the 2- or 4-fold increased half-life of the two mutants at alkaline pH, while the catalytic rate on cellotetraose (at t = 0) has not changed. Increased operational stability at alkaline pH was also observed on insoluble cellulosic substrates. Local conformational changes are suggested to take place in the active site loops of Cel6A wild-type enzyme at elevated pHs (pH 7), affecting to the end-product spectrum on insoluble cellulose. The triple mutant does not show such pH-dependent behavior. Overall, our results demonstrate that carboxyl-carboxylate pair engineering is a useful tool to alter pH-dependent protein behavior.     

Structures and roles of the polymorphic forms of tobacco mosaic virus. V. Conservation of the abnormally titrating groups in tobacco mosaic virus

The two groups per subunit which titrate with an abnormal pK of about 7 in tobacco mosaic virus Vulgare have also been found in three other naturally occurring strains and two mutants. Possession of these groups, almost certainly carboxyl-carboxylate pairs, therefore appears to be a crucial feature of the virus protein structure, which has been conserved during the evolution of the strains. The residues responsible may be narrowed down to those carboxylic acid residues which are at the same position in all the tobacco mosaic virus variants titrated. Residues 115 and 116 make up one probable pair, while residue 145 and one other, as yet unidentified, make up the second probable pair.     

Structural repeats and evolution of tobacco mosaic virus coat protein and RNA

The three-dimensional structure of the tobacco mosaic virus (TMV) coat protein disk suggests a possible pathway for the early evolution of the virus self-assembly mechanism.The coat protein contains a 2-fold repeated structural pattern in the folding of both its four alpha helices (A,B,C,D), which run alternately forward and back along the radius of the disk, and the four-stranded antiparallel pleated sheet which links these helices to the hydrophobic girdle at the outer rim of the disk. Helices A and B can be approximately superposed on C and D by a screw rotation about a molecular pseudo-dyad axis which lies nearly parallel to the plane of the protein disk. This operation relates 29 pairs of α-carbon positions with a root-mean-square deviation of 1.77 Å. A second pseudo-dyad in the pleated-sheet region relates 14 more atom pairs with a deviation of 2.32 Å and forms a distorted continuation of the relationship between the helices. The helix dyad also relates repeated pairs of functionally important amino acids which take part in intersubunit contacts.We have analysed these structural repeats and tested their significance by comparing them with repeats in other “helix quartet” proteins, cytochrome b⁵ and the hemerythrins, as well as with an irregular helix cluster in thermolysin. TMV is noticeably more repetitive than the others, including hemerythrin which is thought to have evolved by gene duplication.We propose that the primitive TMV coat protein was a dimeric structure of two smaller units paired about a 2-fold axis. Each unit was a pair of helices, linked at the inner radius of the virus rod by a short bend, where the RNA binding site formed, and connected at the outer radius by two short strands of beta sheet. A tandem gene duplication joined the two units and formed the present helix quartet. The flexible loop which now runs into the centre of the virus and connects helix C to helix D developed later. The assembly origin RNA may have evolved from part of the coat protein RNA which codes for this loop.     

Replication of tobacco mosaic virus RNA

The replication of tobacco mosaic virus (TMV) RNA involves synthesis of a negative-strand RNA using the genomic positive-strand RNA as a template, followed by the synthesis of positive-strand RNA on the negative-strand RNA templates. Intermediates of replication isolated from infected cells include completely double-stranded RNA (replicative form) and partly double-stranded and partly single-stranded RNA (replicative intermediate), but it is not known whether these structures are double-stranded or largely single-stranded in vivo. The synthesis of negative strands ceases before that of positive strands, and positive and negative strands may be synthesized by two different polymerases. The genomic-length negative strand also serves as a template for the synthesis of subgenomic mRNAs for the virus movement and coat proteins. Both the virus-encoded 126-kDa protein, which has amino-acid sequence motifs typical of methyltransferases and helicases, and the 183-kDa protein, which has additional motifs characteristic of RNA-dependent RNA polymerases, are required for efficient TMV RNA replication. Purified TMV RNA polymerase also contains a host protein serologically related to the RNA-binding subunit of the yeast translational initiation factor, eIF3. Study of Arabidopsis mutants defective in RNA replication indicates that at least two host proteins are needed for TMV RNA replication. The tomato resistance gene Tm-1 may also encode a mutant form of a host protein component of the TMV replicase. TMV replicase complexes are located on the endoplasmic reticulum in close association with the cytoskeleton in cytoplasmic bodies called viroplasms, which mature to produce 'X bodies'. Viroplasms are sites of both RNA replication and protein synthesis, and may provide compartments in which the various stages of the virus mutiplication cycle (protein synthesis, RNA replication, virus movement, encapsidation) are localized and coordinated. Membranes may also be important for the configuration of the replicase with respect to initiation of RNA synthesis, and synthesis and release of progeny single-stranded RNA.     

Mechanism of RNA-protein interactions in tobacco mosaic virus: analysis of the pH stability of virus protein complexes with synthetic polynucleotides.

TMV-like RNP complexes were reconstituted from TMV protein and synthetic polynucleotides. Analysis of the pH stability of RNP with polynucleotides containing U, G, or their analogues reveals a correlation between the stability of their structure and the pK values of the bases, and indicates that the -NH-CO-groups of U and G are involved in hydrogen bonding with protein. It is suggested that TMV protein has two U- and one G-specific binding sites which, according to the phase position of the protein subunits relative to the origin of TMV assembly (D. Zimmern (1977), Cell 11, 463) are likely to be organized as UGU. The binding of the A and C residues of RNA with TMV protein is nonspecific. TMV protein groups with pK 6.3, 7.5 and 9.7 were found to be essential in the protein-protein interactions in RNP. A group of the protein with pK 8.2 is also involved in RNP stabilization. Both protein-protein interactions and interactions of protein with RNA phosphate groups were shown to be mediated by a conformational change in the protein induced by base binding. The effect of bases on both types of interactions changes in the order G approximately equal to much greater than A, and incorporation of C in RNP proceeds in a compulsory way at the expense of interaction of the neighbouring nucleotide residues in polynucleotides with protein. The data obtained are used to discuss the principles of the cooperativity of the interactions between TMV components and the mechanism of initiation and elongation in TMV self-assembly.     

Detection of Tobacco mosaic virus and Tomato mosaic virus in pepper and tomato by multiplex RT-PCR

Aims: To develop a highly sensitive and rapid protocol for simultaneous detection and differentiation of Tobacco mosaic virus (TMV) and Tomato mosaic virus (ToMV) in pepper and tomato. In this study, we use the multiplex PCR technique to detect dual infection of these two viruses. Methods and Results: A multiplex RT–PCR method consisting of one‐tube reaction with two primer pairs targeted to replicase genes was developed to simultaneously detect TMV and ToMV in seed samples of pepper and tomato. Specific primers were designed from conserved regions of each of the virus genomes, and their specificity was confirmed by sequencing PCR products. RT–PCR detected up to 10^?6 dilution of total RNA extracted from infected leaves. Multiplex RT–PCR revealed the presence of both TMV and ToMV in three of 18 seed samples of tomato and one of 18 seed samples of pepper. Conclusions: The multiplex PCR assay was a cost effective, quick diagnostic technique, which was helpful in differentiating TMV and ToMV accurately. Significance and Impact of the Study: The multiplex PCR assay described in this study is a valuable tool for plant pathology and basic research studies. This method may facilitate better recognition and distinction of TMV and ToMV in both pepper and tomato.     

A ribozyme gene and an antisense gene are equally effective in conferring resistance to tobacco mosaic virus on transgenic tobacco

Ribozymes of the hammerhead class can be designed to cleave a target RNA in a sequence-specific manner and can potentially be used to specifically modulate gene activity. We have targeted the tobacco mosaic virus (TMV) genome with a ribozyme containing three catalytic hammerhead domains embedded within a 1 kb antisense RNA. The ribozyme was able to cleave TMV RNA at all three target sites in vitro at 25°C. Transgenic tobacco plants were generated which expressed the ribozyme or the corresponding antisense constructs directed at the TMV genome. Six of 38 independent transgenic plant lines expressing the ribozyme and 6 of 39 plant lines expressing the antisense gene showed some level of protection against TMV infection. Homozygous progeny of some lines were highly resistant to TMV; at least 50% of the plants remained asymptomatic even when challenged with high levels of TMV. These plants also displayed resistance to infection with TMV RNA or the related tomato mosaic virus (ToMV). In contrast, hemizygous plants of the same lines displayed only very weak resistance when inoculated with low amounts of TMV and no resistance against high inoculation levels. Resistance in homozygous plants was not overcome by a TMV strain which was altered at the three target sites to abolish ribozyme-mediated cleavage, suggesting that the ribozyme conferred resistance primarily by an antisense mechanism.     

Analysis of pH-dependent elements in proteins: geometry and properties of pairs of hydrogen-bonded carboxylic acid side-chains

A rather frequent but so far little discussed observation is that pairs of carboxylic acid side-chains in proteins can share a proton in a hydrogen bond. In the present article, quantum chemical calculations of simple model systems for carboxyl-carboxylate interactions are compared with structural observations from proteins. A detailed structural analysis of the proteins deposited in the PDB revealed that, in a subset of proteins sharing less than 90% sequence identity, 19% (314) contain at least one pair of carboxylic acids with their side-chain oxygen atoms within hydrogen-bonding distance. As the distance between those interacting oxygen atoms is frequently very short ( approximately 2.55 A), many of these carboxylic acids are suggested to share a proton in a strong hydrogen bond. When situated in an appropriate structural environment (low dielectric constant), some might even form a low barrier hydrogen bond. The quantum chemical studies show that the most frequent geometric features of carboxyl-carboxylate pairs found in proteins, and no or symmetric ligation, are also the most stable arrangements at low dielectric constants, and they also suggest at medium and low pH a higher stability than for isosteric amide-carboxylate pairs. The presence of these pairs in 119 different enzymes found in the BRENDA database is set in relation to their properties and functions. This analysis shows that pH optima of enzymes with carboxyl-carboxylate pairs are shifted to lower than average values, whereas temperature optima seem to be increased. The described structural principles can be used as guidelines for rational protein design (e.g., in order to improve pH or temperature stability).     

Characterization of a putative calcium-binding site in tobacco mosaic virus.

Lead has been used as a substitute for calcium binding to tobacco mosaic virus (TMV). The high atomic number of lead has allowed us to use difference maps from X-ray fiber diffraction data to characterize a calcium-binding site in the virus. The metal ligands are slightly different from those previously believed to bind calcium to TMV, although the binding site is very close to one previously described. Two acetate groups are also bound to the lead atom. There is no significant backbone conformational change in the protein as a result of metal binding; the binding is accomplished by means of relatively small movements in amino acid side chains.     

Complementary oligodeoxynucleotide mediated inhibition of tobacco mosaic virus RNA translation in vitro.

Two different "antisense" oligodeoxynucleotides and their RNA analogues, each complementary to non-overlapping sequences of 51 bases near the 5' end of TMV RNA, inhibit in vitro translation of the genomic RNA in a rabbit reticulocyte lysate. Inhibition is dependent upon complementarity, concentration, and hybridization of the oligomers with TMV RNA. Inhibition is observed at molar ratios of TMV RNA to antisense oligomers as low as 1:1.5. A plateau of inhibition at which 10-25% of the control signal remains is achieved by molar ratios of TMV RNA:antisense DNA or RNA greater than or equal to 1:15. The extent of inhibition is not increased by the simultaneous presence of both complementary fragments. Oligodeoxynucleotides and their RNA analogues identical to the same regions of TMV RNA have no direct effect on translation, however, they can block inhibition by the antisense fragments. Translation of BMV RNA is not affected by any of the oligodeoxynucleotides. Polyacrylamide gel electrophoresis shows translation of TMV p126 is selectively inhibited. We conclude that the observed inhibition of translation is due to direct interference with ribosome function.     

Synthesis of the tobacco mosaic virus in blocked spreading of infection

The possibility of infection of tobacco upper leaves with tobacco mosaic virus (TMV) was examined in experiments where the inoculum was imbibed through the cut stem. The inoculum used were: a) a preparation of a virus-specific informosome-like ribonucleoproteins (vRNP) isolated from TMV-infected plants; b) a TMV preparation; or c) a mixture of TMV and vRNP. Multiplication of TMV in upper leaves was observed in neither of the variants; nevertheless in the vascular tissue and/or probably in adjoining parenchymal cells, two kinds of RNA were synthesized: of mol. w. (1.1--1.3) X 10(6) and (0.6--0.8) X 10(6). These RNA were not found in healthy plants in the presence of actinomycin D. The synthesis of genomic TMV RNA is suppressed under these conditions. Thus, some kind of abortive TMV infection takes place under the condition of experimental inoculation of plants through a cut stem. Molecular hybridization with the DNA of recombinant plasmid containing a nucleotide sequence complementary to the 3'-portion of genomic TMV RNA proves that short RNAs synthesized under the abortive infection conditions are TMV-specific. The experiments with differential temperature treatment of N-gene-containing plants under abortive infection conditions suggest that necrotization is not necessarily induced by genomic TMV RNA synthesis.     

Molecular cloning of the Harvey sarcoma virus circular DNA intermediates. II. Further structural analyses.

Three species of unintegrated supercoiled Harvey sarcoma virus DNA (6.6, 6.0, and 5.4 kilobase pairs) have been molecularly cloned from Harvey sarcoma virus-infected cells. On the basis of restriction enzyme analyses, the 6.6- and 6.0-kilobase pair viral DNAs contain two and one copies, respectively, of a 650-base pair DNA segment which contains sequences present at the 3' and 5' termini of the viral genome. R-loop structures formed between Moloney leukemia virus RNA and the cloned Harvey sarcoma virus DNA indicated that about 500 base pairs of the 650-base pair repeating segment was complementary to the 3' end of the viral RNA. During amplification in the Escherichia coli host, some recombinants containing the 6.6- or the 6.0-kilobase pair Harvey sarcoma virus DNA insert acquired or lost the complete 650-base pair DNA segment. These changes occurred in both recA+ and recA- E. coli.     

Validation of microtubule-associated Tobacco mosaic virus RNA movement and involvement of microtubule-aligned particle trafficking

Functional studies of Tobacco mosaic virus (TMV) infection using virus derivatives expressing functional, dysfunctional, and temperature-sensitive movement protein (MP) mutants indicated that the cell-to-cell transport of TMV RNA is functionally correlated with the association of MP with microtubules. However, the role of microtubules in the movement process during early infection remains unclear, since MP accumulates on microtubules rather late in infection and treatment of plants with microtubule-disrupting agents fails to strongly interfere with cell-to-cell movement of TMV RNA. To further test the role of microtubules in TMV cell-to-cell movement, we investigated TMV strain Ni2519, which is temperature-sensitive for movement. We demonstrate that the temperature-sensitive defect in movement is correlated with temperature-sensitive changes in the localization of MP to microtubules. Furthermore, we show that during early phases of recovery from non-permissive conditions, the MP localizes to microtubule-associated particles. Similar particles are found in cells at the leading front of spreading TMV infection sites. Initially mobile, the particles become immobile when MP starts to accumulate along the length of the particle-associated microtubules. Our observations confirm a role for microtubules in the spread of TMV infection and associate this role with microtubule-associated trafficking of MP-containing particles in cells engaged in the cell-to-cell movement of the TMV genome.     

Visualization of alpha-helices in tobacco mosaic virus by cryo-electron microscopy

We have used tobacco mosaic virus (TMV) as a test specimen, in order to develop techniques for the analysis of high-resolution structural detail in electron micrographs of biological assemblies with helical symmetry. It has previously been shown that internal details of protein structure can be visualized by processing electron micrographs of unstained specimens of extended two-dimensional crystalline arrays. However, the techniques should in principle be applicable to other periodic specimens, such as assemblies with helical symmetry. We show here that data to spacings better than 10 A can be retrieved from electron images of frozen hydrated TMV. The three-dimensional computed map agrees well with that derived from X-ray diffraction and shows the two pairs of alpha-helices forming the core of the coat subunit, the C alpha-helix and the viral RNA. The results demonstrate that it is possible to determine detailed internal structure in helical particles.     

Specific cessation of minus-strand RNA accumulation at an early stage of tobacco mosaic virus infection.

The time course of accumulation of viral plus-strand RNAs (genomic RNA and subgenomic mRNA for the coat protein) and minus-strand RNA in tobacco protoplasts synchronously infected with tobacco mosaic virus (TMV) RNA was examined. In protoplasts infected with the wild-type TMV L RNA, the plus and minus strands accumulated differently not only in quantity but also in the outline of kinetics. The time courses of accumulation of the genomic RNA and coat protein mRNA were similar: they became detectable at 2 or 4 h postinoculation (p.i.), and their accumulation increased until 14 to 18 h p.i. The accumulation rate reached the maximum at about 4 h p.i. and then gradually decreased. In contrast, accumulation of the minus-strand RNA ceased at 6 to 8 h p.i., at which time the plus-strand accumulation was already about 100 times greater and still continued vigorously. This specific halt of minus-strand accumulation was not caused exclusively by encapsidation of the genomic RNA, because a similar halt was observed upon infection with a deletion mutant that lacks the 30K and coat protein genes. Upon infection with a mutant that could not produce the 130K protein (one of the two proteins that are thought to be involved in viral RNA replication), the accumulation levels of both plus and minus strands were lower than that of the parental wild-type virus. Given these observations, possible mechanisms of TMV replication are discussed.     

Global defects in the expression and function of the low density lipoprotein receptor (LDLR) associated with two familial hypercholesterolemia mutations resulting in misfolding of the LDLR epidermal growth factor-AB pair

The low density lipoprotein (LDL) receptor is a modular protein involved in the endocytosis of cholesterol-rich lipoproteins from the circulation. Mutations to the receptor result in familial hypercholesterolemia, and over 60 of these occur in the calcium-binding epidermal growth factor-like domain pair. Two selected mutations in this region (G322S and R329P) were introduced into the domain pair and analyzed by in vitro refolding. Both exhibited differing levels of protein misfolding with R329P being the most pronounced. Solution NMR studies of the mutant domain pairs after purification established that a fraction of protein maintains a native-like fold and that this fraction contains two intact calcium-binding sites. An in vivo analysis of intact receptors containing these binding sites showed significantly reduced cell-surface expression compared with the native LDL receptor levels, again with R329P showing the most severe decrease. The sum of these results suggests that either local changes in structure or domain misfolding may be associated with the mutations. There is also the possibility that the misfolding of the calcium-binding epidermal growth factor-like pair region is propagated to other regions of the intact receptor, resulting in more global defects. Surprisingly, for both mutants, those full-length receptors that fold and reach the cell surface retain the ability to bind LDL and release the ligand upon exposure to low pH. This analysis provides significant insight into the protein defect resulting from each of the two mutations and allows their classification to be 2B (partially transport-defective). The results also highlight a range of misfolding defects that may be associated with familial hypercholesterolemia and may enable the prediction of the consequences of homologous disease-causing mutations to other proteins.     

Self-assembly of tobacco mosaic virus: the role of an intermediate aggregate in generating both specificity and speed

The tobacco mosaic virus (TMV) particle was the first macromolecular structure to be shown to self-assemble in vitro, allowing detailed studies of the mechanism. Nucleation of TMV self-assembly is by the binding of a specific stem-loop of the single-stranded viral RNA into the central hole of a two-ring sub-assembly of the coat protein, known as the 'disk'. Binding of the loop onto its specific binding site, between the two rings of the disk, leads to melting of the stem so more RNA is available to bind. The interaction of the RNA with the protein subunits in the disk cause this to dislocate into a proto-helix, rearranging the protein subunits in such a way that the axial gap between the rings at inner radii closes, entrapping the RNA. Assembly starts at an internal site on TMV RNA, about 1 kb from its 3'-terminus, and the elongation in the two directions is different. Elongation of the nucleated rods towards the 5'-terminus occurs on a 'travelling loop' of the RNA and, predominantly, still uses the disk sub-assembly of protein subunits, consequently incorporating approximately 100 further nucleotides as each disk is added, while elongation towards the 3'-terminus uses smaller protein aggregates and does not show this 'quantized' incorporation.