Analysis of the subunit assembly of the typeIC restriction-modification enzyme EcoR124I

Type I restriction-modification (R-M) enzymes are composed of three different subunits, of which HsdS determines DNA specificity, HsdM is responsible for DNA methylation and HsdR is required for restriction. The HsdM and HsdS subunits can also form an independent DNA methyltransferase with a subunit stoichiometry of M2S1. We found that the purified Eco R124I R-M enzyme was a mixture of two species as detected by the presence of two differently migrating specific DNA-protein complexes in a gel retardation assay. An analysis of protein subunits isolated from the complexes indicated that the larger species had a stoichiometry of R2M2S1and the smaller species had a stoichiometry of R1M2S1. In vitro analysis of subunit assembly revealed that while binding of the first HsdR subunit to the M2S1complex was very tight, the second HsdR subunit was bound weakly and it dissociated from the R1M2S1complex with an apparent K d of approximately 2.4 x 10(-7) M. Functional assays have shown that only the R2M2S1complex is capable of DNA cleavage, however, the R1M2S1complex retains ATPase activity. The relevance of this situation is discussed in terms of the regulation of restriction activity in vivo upon conjugative transfer of a plasmid-born R-M system into an unmodified host cell.     

Protein-protein and protein-DNA interactions in the type I restriction endonuclease R.EcoR124I

The type I restriction-modification system EcoR124I recognizes and binds to the split DNA recognition sequence 5'-GAAN(6)RTCG-3'. The methyltransferase, consisting of HsdM and HsdS subunits with the composition M2S, can interact with one or more subunits of the HsdR subunit to form the endonuclease. The interaction of the methyltransferase with HsdR has been investigated by surface plasmon resonance, showing that there are two non-equivalent binding sites for HsdR which differ in binding affinity by at least two orders of magnitude. DNA footprinting experiments using Exonuclease III suggest that the addition of HsdR to the methyltransferase (at a stoichiometry of either 1:1 or 2:1) increases the stability of the resulting DNA-protein complex but does not increase the size of the footprint. More extensive in situ footprinting experiments using copper-phenanthroline on the DNA-protein complexes formed by M2S, R1M2S and R2M2S also show no difference in the detailed cleavage pattern, with approximately 18 nucleotides protected on both strands in each complex. Thus the HsdR subunit(s) of the endonuclease stabilise the interaction of the M2S complex with DNA, but do not directly contribute to DNA binding. In addition, the thymidine nucleotide in the tetranucleotide recognition sequence GTCG is hyper-reactive to cleavage in each case, suggesting that the DNA structure in this region is altered in these complexes.     

Aspartate transcarbamoylase containing circularly permuted catalytic polypeptide chains

Based on the demonstration that active enzyme is formed in vitro and in vivo from polypeptide fragments of the catalytic chains of aspartate transcarbamoylase (ATCase; EC 2.1.3.2) and the evidence that NH2 and COOH termini of wild-type chains are in close proximity, we constructed altered genes to determine whether circularly permuted catalytic chains could fold and assemble into active catalytic trimers. Two slightly different genetic constructs led to the expression in good yield of circularly permuted catalytic chains, which associated in vivo into active trimers. They, in turn, combined in vitro with wild-type regulatory dimers to form ATCase-like molecules. Both polypeptide chains began at residue 235 in a different domain from the NH2 terminus of wild type and had an overlapping sequence of eight residues at the COOH terminus. One had a six-amino-acid linker, and the other had a deletion of four residues. Enzymes containing rearranged chains were similar to their wild-type counterparts in physical properties. Whereas values of Vmax were close to those of wild-type trimers and ATCase, the Km values were more than 10-fold greater. Also the allosteric properties characteristic of wild-type ATCase were lacking in the enzymes containing permuted chains. Denaturation of trimers by urea was reversible, and recovery of activity in both rate and yield was comparable to that of wild-type trimers. The experiments demonstrate that folding of chains into clearly defined domains and the assembly of active, thermodynamically stable oligomers are not dependent on the positions of NH2 and COOH termini; the folded structures are a consequence of the final sequence and not the order of biosynthetic addition of amino acids.     

Consumerism and health care: the example of fertility treatment

The related vertebrate eye lens polypeptides, betaB2- and gammaB-crystallin, each fold into two similar beta-sheet domains. The main difference is the state of oligomerization resulting from intermolecular domain interactions in the oligomeric beta-crystallins and intramolecular contacts in the monomeric gamma-crystallins. The question arises whether it is possible to create a monomeric gammaB-like betaB2-molecule by protein engineering methods. We wanted to produce such a molecule by circularly permuting the domains of betaB2-crystallin. The new termini were created from the original connecting peptide, and the new linker from stumps of the original extensions, while the rest of the flexible extensions were deleted. As judged by circular dichroism and fluorescence, the permutation causes little change in the structure of the protein. The circularly permuted protein forms dimers as wild-type betaB2-crystallin. On the other hand, cpbetaB2 shows a slightly enhanced stability against urea with a midpoint of transition of 2.1 M urea versus 1.9 M for the wild-type protein lacking N and C-terminal arms, thus indicating stronger domain interactions. To our knowledge this is the first circularly permuted protein which exhibits a higher stability than the corresponding wild-type protein.     

Preference of the recombination sites involved in the formation of extrachromosomal copies of the human alphoid Sau3A repeat family

The human alphoid Sau3A repetitive family DNA is one of the DNA species that are actively amplified to form extrachromosomal circular DNA in several cell lines. The circularization takes place between two of the five approximately 170 bp subunits with an average of 73.1% homology as well as between identical subunits. To investigate the nature of the recombination reaction, we cloned and analyzed the subunits containing recombination junctions. Analysis of a total of 68 junctions revealed that recombination had occurred preferentially at four positions 10-25 (A), 40-50 (B), 85-90 (C) and 135-160 (D) in the 170bp subunit structure. Two regions (B and C) were overlapped with the regions with higher homology between subunits, while other two regions (A and D) cannot be explained solely by the regional homology between the subunits. These regions were located at both junctions of the nucleosomal and the linker region, and overlapped with the binding motifs for alpha protein and CENP-B. Approximately 90% of the recombination occurred between the subunits located next but one (+/- 2 shift), although the frequency of recombination between the adjoining subunits (+/- 1 shift) was approximately 10%.     

Human granulocyte-macrophage colony-stimulating factor receptor signal transduction requires the proximal cytoplasmic domains of the alpha and beta subunits

Human granulocyte-macrophage colony-stimulating factor (GM-CSF) controls the production, maturation, and function of cells in multiple hematopoietic lineages. These effects are mediated by a cell-surface receptor (GM-R) composed of alpha and beta subunits, each containing 378 and 881 amino acids, respectively. Whereas the alpha subunit exists as several isoforms that bind GM-CSF with low affinity, the beta common subunit (beta c) does not bind GM-CSF itself, but acts as a high-affinity converter for GM-CSF, interleukin-3 (IL-3), and IL-5 receptor alpha subunits. The cytoplasmic region of GM-R alpha consists of a membrane-proximal conserved region shared by the alpha 1 and alpha 2 isoforms and a C-terminal variable region that is divergent between alpha 1 and alpha 2. The cytoplasmic region of beta c contains membrane proximal serine and acidic domains. To investigate the amino acid sequences that influence signal transduction by this receptor complex, we constructed a series of cytoplasmic truncation mutants of the alpha 2 and beta subunits. To study these truncations, we stably transfected the IL-3-dependent murine cell line Ba/F3 with wild-type or mutant cDNAs. We found that the wild-type and mutant alpha subunits conferred similar low-affinity binding sites for human GM-CSF to Ba/F3, and the wild-type or mutant beta subunit converted some of these sites to high-affinity; the cytoplasmic domain of beta was unnecessary for this high-affinity conversion. Proliferation assays showed that the membrane-proximal conserved region of GM-R alpha and the serine-acidic domain of beta c are required for both cell proliferation and ligand-dependent phosphorylation of a 93-kD cytoplasmic protein. We suggest that these regions may represent an important signal transduction motif present in several cytokine receptors.     

In search of circular permuted variants of Escherichia coli dihydrofolate reductase

A circularized form of a Cys-free mutant of Escherichia coli dihydrofolate reductase (DHFR) was used to search for a proteolytic site that gave new N- and C-termini on circularized DHFR with enzyme activity. Of the six site-specific proteolytic enzymes tested, three proteases, Achromobacter protease I (lysine-specific endopeptidase), asparaginylendopeptidase, and Staphylococcus aureus V8 protease, cleaved a single site of the circularized DHFR to form circular permuted variants. Twenty-four possible sites for cleavage were found formation of eight circular permuted variants was suggested by results of N-terminal sequence analysis of the linearized proteins isolated by gel filtration in the presence of 5 M guanidine hydrochloride. Mapping of the predicted cleavage sites on the DHFR molecule suggested that they were not all at a specific loop and, therefore, there are many possible circular permuted variants.     

Circular permutation of betaB2-crystallin changes the hierarchy of domain assembly

The betagamma-crystallins form a superfamily of eye lens proteins comprised of multiple Greek motifs that are symmetrically organized into domains and higher assemblies. In the betaB2-crystallin dimer each polypeptide folds into two similar domains that are related to monomeric gamma-crystallin by domain swapping. The crystal structure of the circularly permuted two-domain betaB2 polypeptide shows that permutation converts intermolecular domain pairing into intramolecular pairing. However, the dimeric permuted protein is, in fact, half a native tetramer. This result shows how the sequential order of domains in multi-domain proteins can affect quaternary domain assembly.     

Low-bandwidth telemedicine for remote orthotic assessment

The 1,3-1,4-beta-glucanases from Bacillus macerans and Bacillus licheniformis, as well as related hybrid enzymes, are stable proteins comprised of one compact jellyroll domain. Their structures are studied in an effort to reveal the degree of redundancy to which the three-dimensional structure of protein domains is encoded by the amino acid sequence. For the hybrid 1,3-1,4-beta-glucanase H(A16-M), it could be shown recently that a circular permutation of the sequence giving rise to the variant cpA16M-59 is compatible with wildtype-like enzymatic activity and tertiary structure (Hahn et al., Proc. Natl. Acad. Sci. USA 91:10417-10421, 1994). Since the circular permutation yielding cpA16M-59 mimicks that found in the homologous enzyme from Fibrobacter succinogenes, the question arose whether de novo circular permutations, not guided by molecular evolution of the 1,3-1,4-beta-glucanases, could also produce proteins with native-like fold. The circularly permuted variants cpA16M-84, cpA16M-127, and cpA16M-154 were generated by PCR mutagenesis of the gene encoding H(A16-M), synthesized in Escherichia coli and shown to be active in beta-glucan hydrolysis. CpA16M-84 and cpA16M-127 were crystallized in space groups P2(1) and P1, respectively, and their crystal structures were determined at 1.80 and 2.07 A resolution. In both proteins the main parts of the beta-sheet structure remain unaffected by the circular permutation as is evident from a root-mean-square deviation of main chain atoms from the reference structure within the experimental error. The only major structural perturbation occurs near the novel chain termini in a surface loop of cpA16M-84, which becomes destabilized and rearranged. The results of this study are interpreted to show that: (1) several circular permutations in the compact jellyroll domain of the 1,3-1,4-beta-glucanases are tolerated without radical change of enzymatic activity or tertiary structure, (2) the three-dimensional structures of simple domains are encoded by the amino acid sequence with sufficient redundancy to tolerate a change in the sequential order of secondary structure elements along the sequence, and (3) the native N-terminal region is not needed to guide the folding polypeptide chain toward its native conformation.     

A single-headed dimer of Escherichia coli ribosomal protein L7/L12 supports protein synthesis

During protein synthesis, the two elongation factors Tu and G alternately bind to the 50S ribosomal subunit at a site of which the protein L7/L12 is an essential component. L7/L12 is present in each 50S subunit in four copies organized as two dimers. Each dimer consists of distinct domains: a single N-terminal ("tail") domain that is responsible for both dimerization and binding to the ribosome via interaction with the protein L10 and two independent globular C-terminal domains ("heads") that are required for binding of elongation factors to ribosomes. The two heads are connected by flexible hinge sequences to the N-terminal domain. Important questions concerning the mechanism by which L7/L12 interacts with elongation factors are posed by us in response to the presence of two dimers, two heads per dimer, and their dynamic, mobile properties. In an attempt to answer these questions, we constructed a single-headed dimer of L7/L12 by using recombinant DNA techniques and chemical cross-linking. This chimeric molecule was added to inactive core particles lacking wild-type L7/L12 and shown to restore activity to a level approaching that of wild-type two-headed L7/L12.     

Role of the CCAAT-binding protein CBF/NF-Y in transcription

The CCAAT motif is one of the common promoter elements present in the proximal promoter of numerous mammalian genes transcribed by RNA polymerase II. CBF (also called NF-Y and CP1) consists of three different subunits and interacts specifically with the CCAAT motif. In each CBF subunit, the segment needed for formation of the CBF-DNA complex is conserved from yeast to human and, interestingly, the conserved segment of two CBF subunits, CBF-A and CBF-C, are homologous to the histone-fold motif of eukaryotic histones and archaebacterial histone-like protein HMf-2. The histone fold motifs of CBF-A and CBF-C interact with each other to form a heterodimer that associates with CBF-B to form a heterotrimeric CBF molecule, which then binds to DNA.     

Is the continuity of the domains required for the correct folding of a two-domain protein?

The role of domains in protein folding has been widely studied and discussed. Nevertheless, it is not clear whether the continuity of the domains in a protein is an essential requirement in determining the folding pathway. Previous studies have shown that the isolated structural domains of the two-domain monomeric enzyme, yeast phosphoglycerate kinase (yPGK), are able to fold independently into a quasinative structure, but they neither reassociate nor generate a functional enzyme [Minard, P., Hall, L., Betton, J. M., Missiakas, D., & Yon, J. M. (1989) Protein Eng. 3, 55-60; Fairbrother, W. J., Bowen, D., Hall, L., Williams, R. J. P. (1989) Eur. J. Biochem. 184, 617-625; Missiakas, D., Betton, J. M., Minard, P., & Yon, J. M. (1990) Biochemistry 29, 8683-8689]. In the present work, two circularly permuted variants of the yPGK gene were constructed. The natural adjacent chain termini were directly connected and the new extremities were created within the N-domain (at residues 71 and 72) or the C-domain (at residues 291 and 292), respectively. These two proteins were overexpressed and purified. They exhibit 14% and 23% of the wild-type enzyme activity, respectively. The two mutants fold in a compact conformation with slight changes in the secondary and tertiary structure probably related to the presence of a heterogeneous population of molecules. The unfolding studies reveal a large decrease in stability. From the present data it appears that, although the circular permutations induce some perturbations in the structure and stability of the protein, the continuity of the domains is not required for the protein to reach a native-like and functional structure.     

The structure of an insect parvovirus (Galleria mellonella densovirus) at 3.7 A resolution

BACKGROUND: Parvoviruses infect vertebrates, insects and crustaceans. Many arthropod parvoviruses (densoviruses) are highly pathogenic and kill approximately 90% of the host larvae within days, making them potentially effective as selective pesticides. Improved understanding of densoviral structure and function is therefore desirable. There are four different initiation sites for translation of the densovirus capsid protein mRNA, giving rise to the viral proteins VP1 to VP4. Sixty copies of the common, C-terminal domain make up the ordered part of the icosahedral capsid. RESULTS: The Galleria mellonella densovirus (GMDNV) capsid protein consists of a core beta-barrel motif, similar to that found in many other viral capsid proteins. The structure most closely resembles that of the vertebrate parvoviruses, but it has diverged beyond recognition in many of the long loop regions that constitute the surface features and intersubunit contacts. The N termini of twofold-related subunits have swapped their positions relative to those of the vertebrate parvoviruses. Unlike in the vertebrate parvoviruses, in GmDNV there is no continuous electron density in the channels running along the fivefold axes of the virus. Electron density corresponding to some of the single-stranded DNA genome is visible in the crystal structure, but it is not as well defined as in the vertebrate parvoviruses. CONCLUSIONS: The sequence of the glycine-rich motif, which occupies each of the channels along the fivefold axes in vertebrate viruses, is conserved between mammalian and insect parvoviruses. This motif may serve to externalize the N-terminal region of the single VP1 subunit per particle. The domain swapping of the N termini between insect and vertebrate parvoviruses may have the effect of increasing capsid stability in GmDNV.     

Effects of lysine-to-glycine mutations in the ATP-binding consensus sequences in the AddA and AddB subunits on the Bacillus subtilis AddAB enzyme activities

The N-terminal regions of both subunits AddA and AddB of the Bacillus subtilis AddAB enzyme contain amino acid sequences, designated motif I, which are commonly found in ATP-binding enzymes. The functional significance of the motif I regions was studied by replacing the highly conserved lysine residues of the regions in both subunits by glycines and by examination of the resulting mutant enzymes with respect to their enzymatic properties. This study shows that the mutation in subunit AddB hardly affected the ATPase, helicase, and exonuclease activities of the AddAB enzyme. However, the mutation in subunit AddA drastically reduced these activities, as well as the kcat for ATP hydrolysis. The apparent Km for ATP in ATP hydrolysis did not significantly deviate from that of the wild-type enzyme. These results suggest that the lysine residue in motif I of subunit AddA of the AddAB enzyme is not essential for the binding of the nucleotide but has a role in ATP hydrolysis, which is required for the exonuclease and helicase activities of the enzyme.