Nuclear activity from F9 embryonal carcinoma cells binding specifically to the enhancers of wild-type polyoma virus and PyEC mutant DNAs.

Although wild-type polyoma virus does not productively infect murine embryonal carcinoma (EC) cells, a number of mutants (PyEC mutants) that do infect undifferentiated EC cells have been isolated. All PyEC mutants have DNA sequence alterations within the enhancer region of the viral genome. This report describes an activity present in nuclear extracts of F9 EC cells which, by "footprint" analyses, binds specifically to a small region of about 20 base pairs (nucleotides 5180-5200) within the subregion of the polyoma enhancer designated as the B or beta element. While no difference in binding of factor was detected between wild-type polyoma enhancer and the enhancers of the PyEC mutants, PyF111 and PyF441, which had been selected for productive infection of F9 cells, definite differences between wild-type and mutants were observed in the digestion patterns of their naked DNAs with either DNAase I or exonuclease III. This difference was restricted to the region around the point mutation (nucleotide 5258) common to these mutant DNAs.     

Point mutation in the polyomavirus enhancer alters local DNA conformation

A point mutation in the enhancer of polyomavirus host range mutant, PyEC F441, permits productive infection of the murine embryonal carcinoma cell line, F9. This mutation at nucleotide position 5258 introduces a local conformational change in naked viral DNA. The effect of all four possible nucleotide sequences at position 5258 on local DNA conformation was analyzed by gel electrophoresis of fragments produced by ligation of synthetic oligonucleotides having these sequences. The results indicated that both the wild-type and the F441 sequences introduced local structural polymorphism that can lead to DNA bending. The wild-type sequence had a greater effect on DNA curvature than the F441 sequence. The two other sequences at nucleotide 5258 did not appear to introduce detectable amounts of DNA curvature.     

Purification from a yeast mutant of mitochondrial F1 with modified beta-subunit. High affinity for nucleotides and high negative cooperativity of ATPase activity

Mitochondrial F1 containing genetically modified beta-subunit was purified for the first time from a mutant of the yeast Schizosaccharomyces pombe. Precipitation by poly(ethylene glycol) allowed us to obtain a very stable and pure enzyme from either mutant or wild-type strain. In the presence of EDTA, purified F1 retained high amounts of endogenous nucleotides: 4.6 mol/mol and 3.7 mol/mol for mutant and wild-type F1, respectively. The additional nucleotide in mutant F1 was ATP; it was lost in the presence of Mg2+, which led to a total of 3.4 mol of nucleotides/mol whereas wild-type F1 retained all its nucleotides. Mutant F1 bound more exogenous ADP than wild-type F1 and the same total nucleotide amount was reached with both enzymes. Kinetics of ATPase activity revealed a much higher negative cooperativity for mutant than for wild-type F1. Bicarbonate abolished this negative cooperativity, but higher concentrations were required for mutant F1. The mutant enzyme was more sensitive than the wild-type one to azide inhibition and ADP competitive inhibition; this indicated stronger interactions between nucleotide and F1 in the mutant enzyme. The latter also showed increased sensitivity to N,N'-dicyclohexylcarbodiimide irreversible inhibition.     

Functionality of mutations at conserved nucleotides in eukaryotic SECIS elements is determined by the identity of a single nonconserved nucleotide.

In eukaryotes, the specific cotranslational insertion of selenocysteine at UGA codons requires the presence of a secondary structural motif in the 3' untranslated region of the selenoprotein mRNA. This selenocysteine insertion sequence (SECIS) element is predicted to form a hairpin and contains three regions of sequence invariance that are thought to interact with a specific protein or proteins. Specificity of RNA-binding protein recognition of cognate RNAs is usually characterized by the ability of the protein to recognize and distinguish between a consensus binding site and sequences containing mutations to highly conserved positions in the consensus sequence. Using a functional assay for the ability of wild-type and mutant SECIS elements to direct cotranslational selenocysteine incorporation, we have investigated the relative contributions of individual invariant nucleotides to SECIS element function. We report the novel finding that, for this consensus RNA motif, mutations at the invariant nucleotides are tolerated to different degrees in different elements, depending on the identity of a single nonconserved nucleotide. Further, we demonstrate that the sequences adjacent to the minimal element, although not required for function, can affect function through their propensity to base pair. These findings shed light on the specific structure these conserved sequences may form within the element. This information is crucial to the design of strategies for the identification of SECIS-binding proteins, and hence the elucidation of the mechanism of selenocysteine incorporation in eukaryotes.     

Strong inclination toward transition mutation in nucleotide substitutions by poliovirus replicase

A viable insertion mutant of the Sabin strain of type 1 poliovirus was constructed. The mutant carried an insertion sequence of 72 nucleotides at nucleotide position 702 in the 5' non-coding region (742 nucleotides long) of the genome of the Sabin strain. This mutant showed a small-plaque phenotype, as compared with the parental virus. Indeed, the final yield of the mutant in a single cycle of infection was tenfold fewer than that of the parental virus. Many large-plaque variants that are easily generated from the insertion mutant appeared to regain efficient viral replication and have single nucleotide changes. All nucleotide changes observed were limited to within three nucleotides of an AUG sequence in the insertion sequence. The result indicates strongly that the AUG sequence itself in this genome region functions in reducing the plaque size of the parental Sabin type 1 virus. The insertion mutant with a small-plaque phenotype may be the first in vitro mutant of poliovirus whose viability is lowered only by a primary sequence inserted into the 5' non-coding region of the genome. Base substitutions to alter the AUG sequence should largely be the result of errors of the virus-specific replicase, since variants with base substitutions must be subject to only minimum selection pressure. Accordingly, nucleotide sequence analysis of the genome region containing the AUG sequence was performed on a number of genomes of large-plaque variants to investigate types of nucleotide substitutions caused by characteristic errors in RNA replication. Only one transversion mutation was detected in the genomes of 44 independently isolated large-plaque variants with single base changes in the AUG sequence. This result suggests strongly that transition mutations occur predominantly as nucleotide substitutions caused by characteristic errors of poliovirus replicase.     

Rat liver mitochondrial ATP synthase. Effects of mutations in the glycine-rich region of a beta subunit peptide on its interaction with adenine nucleotides

The beta subunit of the rat liver mitochondrial ATP synthase contains a glycine-rich amino acid sequence implicated in binding nucleotides by its similarity to a sequence found in many other nucleotide-binding proteins. A C-terminal three-quarter-length rat liver beta subunit fragment (Glu122 through Ser479), containing this homology region, interacts with adenine nucleotides (Garboczi, D.N., Hullihen, J.H., and Pedersen, P.L. (1988) J. Biol. Chem. 263, 15694-15698). Here we directly test the involvement of the glycine-rich region in nucleotide binding by altering its amino acid sequence through mutation or deletion. Twenty-one mutations within the glycine-rich region of the beta subunit cDNA were randomly generated. Wild-type and mutant beta subunit proteins were purified from overexpressing Escherichia coli strains. The mutant proteins were screened for changes in their interaction with 2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate (TNP-ATP), a fluorescent nucleotide analog. Only one mutant protein bearing two amino acid changes (Gly153----Val, Gly156----Arg) exhibited a fluorescence enhancement higher than that of the wild-type "control." Further analysis of this protein revealed a lower affinity for TNP-ATP (Kd = 10 microM) compared with wild type (Kd = 5 microM). In addition, a mutant from which amino acids Gly149-Lys214 had been deleted was prepared. This mutant protein, which lacks the entire glycine-rich region, also displayed a marked reduction in affinity for TNP-ATP (Kd greater than 60 microM). Prior addition of 0.5 mM ATP significantly reduced the binding of TNP-ATP to both the double and deletion mutants. The altered interaction of nucleotide with both glycine-rich region mutants points to the involvement of this region in the binding site. Further, this work shows that a beta subunit protein that lacks the glycine-rich homology region can still interact with nucleotide, indicating that one or more additional regions of this subunit contribute to the nucleotide binding site.     

Crystal structure of a luteoviral RNA pseudoknot and model for a minimal ribosomal frameshifting motif

To understand the role of structural elements of RNA pseudoknots in controlling the extent of -1-type ribosomal frameshifting, we determined the crystal structure of a high-efficiency frameshifting mutant of the pseudoknot from potato leaf roll virus (PLRV). Correlations of the structure with available in vitro frameshifting data for PLRV pseudoknot mutants implicate sequence and length of a stem-loop linker as modulators of frameshifting efficiency. Although the sequences and overall structures of the RNA pseudoknots from PLRV and beet western yellow virus (BWYV) are similar, nucleotide deletions in the linker and adjacent minor groove loop abolish frameshifting only with the latter. Conversely, mutant PLRV pseudoknots with up to four nucleotides deleted in this region exhibit nearly wild-type frameshifting efficiencies. The crystal structure helps rationalize the different tolerances for deletions in the PLRV and BWYV RNAs, and we have used it to build a three-dimensional model of the PRLV pseudoknot with a four-nucleotide deletion. The resulting structure defines a minimal RNA pseudoknot motif composed of 22 nucleotides capable of stimulating -1-type ribosomal frameshifts.     

Mutagenesis of the 3' nontranslated region of Sindbis virus RNA.

A cDNA clone from which infectious RNA can be transcribed was used to construct 42 site-specific mutations in the 3' nontranslated region of the Sindbis virus genome. The majority of these mutations were made in the 3'-terminal 19-nucleotide conserved sequence element and consisted of single nucleotide substitutions or of small (1 to 8) nucleotide deletions. An attempt was made to recover mutant viruses after transfection of SP6-transcribed RNA into chicken cells. In most cases, viable virus was recovered, but almost all mutants grew more poorly than wild-type virus when tested under a number of culture conditions. In the case of mutations having only a moderate effect, the virus grew as well as the wild type but was slightly delayed in growth. Mutations having a more severe effect led to lower virus yields. In many cases, virus growth was more severely impaired in mosquito cells than in chicken cells, but the opposite phenotype was also seen, in which the mutant grew as well as or better than the wild type in mosquito cells but more poorly in chicken cells. One substitution mutant, 3NT7C, was temperature sensitive for growth in chicken cells and severely crippled for growth in mosquito cells. Insertion mutations were also constructed which displaced the 19-nucleotide element by a few nucleotides relative to the poly(A) tail. These mutations had little effect on virus growth. Deletion of large regions (31 to 293 nucleotides long) of the 3' nontranslated region outside of the 19-nucleotide element resulted in viruses which were more severely crippled in mosquito cells than in chicken cells. From these results, the following principles emerge. (i) The entire 3' nontranslated region is important for efficient virus replication, although there is considerable plasticity in this region in that most nucleotide substitutions or deletions made resulted in viable virus and, in some cases, in virus that grew quite efficiently. Replication competence was particularly sensitive to changes involving the C at position 1, the A at position 7, and a stretch of 9 U residues punctuated by a G at position 14. (ii) The panel of mutants examined collectively deleted the entire 3' nontranslated region. Only mutants in which 8 nucleotides in the 3' terminal 19 nucleotides had been deleted or in which the 3' terminal C was deleted were nonviable. Although the 3' terminal C was essential for replication, it could be displaced by at least 7 nucleotides from its 3' terminal position adjacent to the poly(A) tract.(ABSTRACT TRUNCATED AT 400 WORDS)     

Isolation and characterization of polyoma virus mutants which grow in murine embryonal carcinoma and trophoblast cells.

Mouse trophoblast cell lines established from cultured midterm placenta and a cell line obtained from cultured blastocyst resemble trophectoderm cells. These cells are resistant to infection by wild-type polyoma virus. We have isolated six polyoma virus mutants capable of growing in trophoblast cell lines. Restriction enzyme analyses and marker rescue experiments revealed that the genetic changes necessary for the growth of these mutants ( PyTr mutants) in trophoblast cells were located in a regulatory region of the genome between the origin of viral DNA replication and the region encoding the viral structural proteins. PyTr mutants are, therefore, similar to PyEC mutants, described by others, which are able to grow in embryonal carcinoma cell lines such as F9 or PCC4. The nucleotide sequence of two independently obtained PyTr mutants has an identical 26-bp deletion from nucleotide 5131 to 5156. This deleted region is replaced by either the sequence GGGA or by viral DNA sequences that flank this deletion. PyECF9 mutants grow well in trophoblast and trophectoderm cells, but PyTr mutants do not grow in F9 or PCC4 cells.     

Role of nucleotide sequences of loxP spacer region in Cre-mediated recombination

The Cre recombinase mediates precise site-specific recombination between a pair of loxP sequences through an intermediate containing Holiday junction. The recombination junction in the loxP sequence is located within the asymmetric 8-nucleotide spacer region. To examine the role of each nucleotide sequence of the spacer region in the recombination process, we synthesized a complete set of 24 loxP spacer mutants with single-base substitutions and 30 loxP spacer mutants with double-base substitutions. Each synthesized loxP mutant was ligated at both ends of a linear DNA or to one end of a DNA-containing wild-type loxP at the other end and their recombination efficiencies were analyzed with an in vitro system. The sequence identity of the right two nucleotides and left four nucleotides in the central six bases of the spacer region was found to be essential for formation and resolution, respectively, of the intermediate product. Furthermore, even when homology was maintained, the recombination efficiencies were lower than that of wild-type loxP and varied among mutants. Based on this knowledge, we identified two loxP mutants with double-base substitutions, mutants 5171 and 2272, which recombine efficiently with an identical mutant but not with the other mutant or wild-type loxP.     

Human adenovirus 2 temperature-sensitive mutant 112 contains three mutations in the protein IIIa gene

The temperature-sensitive (ts) mutant 112 of human adenovirus 2 is defective in the late stage of virus maturation. The region of functional mutation has been localised by marker rescue. It was observed that the ts mutation can be rescued by the left-hand part of the wild-type gene (nucleotides 12,301-12,891). By nucleotide sequencing, two mutations, both C to T (at position 12,386 and 12,741), were found in this region. The first one, in the glycine 20 codon, is silent, whereas the second changes alanine 145 to valine. A third mutation, which changed C to A (nucleotide 13,613), was identified in the right-hand part of the gene, resulting in the replacement of alanine-436 by threonine.