Effects of mutations of the initiation nucleotides on hepatitis C virus RNA replication in the cell

Replication of nearly all RNA viruses depends on a virus-encoded RNA-dependent RNA polymerase (RdRp). Our earlier work found that purified recombinant hepatitis C virus (HCV) RdRp (NS5B) was able to initiate RNA synthesis de novo by using purine (A and G) but not pyrimidine (C and U) nucleotides (G. Luo et al., J. Virol. 74:851-863, 2000). For most human RNA viruses, the initiation nucleotides of both positive- and negative-strand RNAs were found to be either an adenylate (A) or guanylate (G). To determine the nucleotide used for initiation and control of HCV RNA replication, a genetic mutagenesis analysis of the nucleotides at the very 5' and 3' ends of HCV RNAs was performed by using a cell-based HCV replicon replication system. Either a G or an A at the 5' end of HCV genomic RNA was able to efficiently induce cell colony formation, whereas a nucleotide C at the 5' end dramatically reduced the efficiency of cell colony formation. Likewise, the 3'-end nucleotide U-to-C mutation did not significantly affect the efficiency of cell colony formation. In contrast, a U-to-G mutation at the 3' end caused a remarkable decrease in cell colony formation, and a U-to-A mutation resulted in a complete abolition of cell colony formation. Sequence analysis of the HCV replicon RNAs recovered from G418-resistant Huh7 cells revealed several interesting findings. First, the 5'-end nucleotide G of the replicon RNA was changed to an A upon multiple rounds of replication. Second, the nucleotide A at the 5' end was stably maintained among all replicon RNAs isolated from Huh7 cells transfected with an RNA with a 5'-end A. Third, initiation of HCV RNA replication with a CTP resulted in a >10-fold reduction in the levels of HCV RNAs, suggesting that initiation of RNA replication with CTP was very inefficient. Fourth, the 3'-end nucleotide U-to-C and -G mutations were all reverted back to a wild-type nucleotide U. In addition, extra U and UU residues were identified at the 3' ends of revertants recovered from Huh7 cells transfected with an RNA with a nucleotide G at the 3' end. We also determined the 5'-end nucleotide of positive-strand RNA of some clinical HCV isolates. Either G or A was identified at the 5' end of HCV RNA genome depending on the specific HCV isolate. Collectively, these findings demonstrate that replication of positive-strand HCV RNA was preferentially initiated with purine nucleotides (ATP and GTP), whereas the negative-strand HCV RNA replication is invariably initiated with an ATP.     

Human hypoxanthine-guanine phosphoribosyltransferase deficiency. The molecular defect in a patient with gout (HPRTAshville)

The genetic basis of hypoxanthine-guanine phosphoribosyltransferase (HPRT) deficiency has been identified by nucleotide sequence analysis of HPRT cDNAs cloned from a patient with gout. A single nucleotide change was identified in two independent clones: an A to G transition at nucleotide 602. Confirmation of a mutation at this site was provided by RNase mapping analysis. The predicted consequence of this transition is an aspartic acid to glycine substitution at amino acid 201. We have designated this variant HPRTAshville. Prior to this report, enzyme activity in HPRTAshville had not been detected by routine assay. Using more sensitive techniques, including an in situ gel assay for HPRT activity, we were able to demonstrate electrophoretic, kinetic, and structural differences between HPRTAshville and normal HPRT. Electrophoretic migration of HPRTAshville has elevated Michaelis constants for 5-phosphoribosyl-1-pyrophosphate and hypoxanthine. Predicted secondary structural alterations may result from the aspartic acid to glycine substitution.     

On the mechanism of MgATP-dependent gating of CFTR Cl- channels

CFTR, the product of the gene mutated in cystic fibrosis, is an ATPase that functions as a Cl(-) channel in which bursts of openings separate relatively long interburst closed times (tauib). Channel gating is controlled by phosphorylation and MgATP, but the underlying molecular mechanisms remain controversial. To investigate them, we expressed CFTR channels in Xenopus oocytes and examined, in excised patches, how gating kinetics of phosphorylated channels were affected by changes in [MgATP], by alterations in the chemical structure of the activating nucleotide, and by mutations expected to impair nucleotide hydrolysis and/or diminish nucleotide binding affinity. The rate of opening to a burst (1/tauib) was a saturable function of [MgATP], but apparent affinity was reduced by mutations in either of CFTR's nucleotide binding domains (NBDs): K464A in NBD1, and K1250A or D1370N in NBD2. Burst duration of neither wild-type nor mutant channels was much influenced by [MgATP]. Poorly hydrolyzable nucleotide analogs, MgAMPPNP, MgAMPPCP, and MgATPgammaS, could open CFTR channels, but only to a maximal rate of opening approximately 20-fold lower than attained by MgATP acting on the same channels. NBD2 catalytic site mutations K1250A, D1370N, and E1371S were found to prolong open bursts. Corresponding NBD1 mutations did not affect timing of burst termination in normal, hydrolytic conditions. However, when hydrolysis at NBD2 was impaired, the NBD1 mutation K464A shortened the prolonged open bursts. In light of recent biochemical and structural data, the results suggest that: nucleotide binding to both NBDs precedes channel opening; at saturating nucleotide concentrations the rate of opening to a burst is influenced by the structure of the phosphate chain of the activating nucleotide; normal, rapid exit from bursts occurs after hydrolysis of the nucleotide at NBD2, without requiring a further nucleotide binding step; if hydrolysis at NBD2 is prevented, exit from bursts occurs through a slower pathway, the rate of which is modulated by the structure of the NBD1 catalytic site and its bound nucleotide. Based on these and other results, we propose a mechanism linking hydrolytic and gating cycles via ATP-driven dimerization of CFTR's NBDs.     

Nucleotide sequence of a full-length complementary DNA clone and amino acid sequence of human phenylalanine hydroxylase

A full-length human phenylalanine hydroxylase complementary DNA (cDNA) clone was isolated from a human liver cDNA library, and the nucleotide sequence encoding the entire enzyme was determined. The cDNA clone contains an inserted DNA fragment of 2448 base pairs, including 19 base pairs of poly(A) at the 3' end. The first methionine codon occurs at nucleotide position 223, followed by an open reading frame of 1353 base pairs, encoding 451 amino acids. Translation of the nucleotide sequence in the open reading frame predicts the amino acid sequence of human phenylalanine hydroxylase. The human protein shows a 96% amino acid sequence homology with the corresponding rat enzyme. The determination of the complete primary structure for phenylalanine hydroxylase represents the first among mixed-function oxidases.     

Mg2+ and a key lysine modulate exchange activity of eukaryotic translation elongation factor 1B alpha

To sustain efficient translation, eukaryotic elongation factor B alpha (eEF1B alpha) functions as the guanine nucleotide exchange factor for eEF1A. Stopped-flow kinetics using 2'-(or 3')-O-N-methylanthraniloyl (mant)-GDP showed spontaneous release of nucleotide from eEF1A is extremely slow and accelerated 700-fold by eEF1B alpha. The eEF1B alpha-stimulated reaction was inhibited by Mg2+ with a K(1/2) of 3.8 mM. Previous structural studies predicted the Lys-205 residue of eEF1B alpha plays an important role in promoting nucleotide exchange by disrupting the Mg2+ binding site. Co-crystal structures of the lethal K205A mutant in the catalytic C terminus of eEF1B alpha with eEF1A and eEF1A.GDP established that the lethality was not due to a structural defect. Instead, the K205A mutant drastically reduced the nucleotide exchange activity even at very low concentrations of Mg2+. A K205R eEF1B alpha mutant on the other hand was functional in vivo and showed nearly wild-type nucleotide dissociation rates but almost no sensitivity to Mg2+. These results indicate the significant role of Mg2+ in the nucleotide exchange reaction by eEF1B alpha and establish the catalytic function of Lys-205 in displacing Mg2+ from its binding site.     

Murine DNA polymerase alpha fills gaps to completion in a direct assay. Altered kinetics of de novo DNA synthesis at single nucleotide gaps

DNA polymerase alpha was studied in a direct gap-filling assay. Using a defined template, DNA synthesis was primed from the M13 17-mer universal primer and blocked by an oligonucleotide hybridized 56 nucleotides downstream of the primer. DNA polymerase alpha filled this gap to completion. A time course of the reaction showed that in 50% of the substrate molecules, gaps were filled to completion within 10 min. In another 35% of the molecules the final nucleotide was lacking after 10 min. This nucleotide was added at a reduced rate, and was not incorporated into all of the molecules even after 6 h. The reduced rate of incorporation of the final nucleotide is reflected in an increased Km for de novo incorporation of one nucleotide at a single nucleotide gap (0.7 microM), as opposed to the Km for de novo incorporation of one nucleotide into singly primed M13 DNA (0.18 microM). DNA polymerase alpha purified from murine cells infected with the parvovirus minute virus of mice, and HeLa cell DNA polymerase alpha 2, exhibited the same kinetics of gap filling as did DNA polymerase alpha purified from uninfected Ehrlich ascites murine tumor cells. T4 DNA polymerase filled gaps to completion in this assay. Escherichia coli DNA polymerase I Klenow fragment quantitatively displaced the downstream oligonucleotide, and extended nascent DNA chains for an additional 100 nucleotides. Nicks and single-nucleotide gaps produced in gap-filling reactions by murine DNA polymerase alpha and T4 DNA polymerase were sealed by T4 DNA ligase.     

Replacement of Bovine Mitochondrial DNA by a Sequence Variant within One Generation

Inheritance of mitochondrial DNA (mtDNA) in Holstein cattle was characterized by pedigree analysis of nucleotide sequence variation. mtDNA was purified from leukocytes of 174 individuals representing 35 independent maternal lineages, and analyzed for nucleotide sequence variation by characterization of restriction fragment length polymorphism and direct sequence determination. These data revealed 11 maternal lineages in which leukocytes from some individuals seemingly were homoplasmic for the reference mtDNA sequence at nucleotide 364, whereas those from other individuals were homoplasmic for a sequence variant at this position. Both alternative alleles were detected in all branches of these 11 lineages, suggesting that mutation at nucleotide 364 and fixation of the variant sequence occurred frequently in independent events. Thirteen instances were detected of mother-daughter pairs in which leukocytes of each of the two animals seemingly were homoplasmic for a different allele at nucleotide 364, demonstrating the bovine mitochondrial genome can be replaced completely by a nucleotide sequence variant within a single generation. The two alternative sequences seemingly arose de novo at similar frequency, ruling out replicative advantage or other selective bias as the explanation for rapid fixation of mutations at nucleotide 364. Another instance of intralineage sequence variation was detected at nucleotide 5602. This variation was detected in only one of the lineages examined, and evidently arose within three generations.     

The role of specific amino acid residues in the active site of Escherichia coli DNA polymerase I on translesion DNA synthesis across from and past an N-2-aminofluorene adduct

Understanding how carcinogenic DNA adducts compromise accurate DNA replication is an important goal in cancer research. A central part of these studies is to determine the molecular mechanism that allows a DNA polymerase to incorporate a nucleotide across from and past a bulky adduct in a DNA template. To address the importance of polymerase architecture on replication across from this type of bulky DNA adduct, three active-site mutants of Escherichia coli DNA polymerase I (Klenow fragment) were used to study DNA synthesis on DNA modified with the carcinogen N-2-aminofluorene (AF). Running-start synthesis studies showed that full-length synthesis past the AF adduct was inhibited for all of the mutants, but that this inhibition was substantially less for the F762A mutant. Single nucleotide extension and steady-state kinetic experiments showed that the Y766S mutant displayed higher rates of insertion of each incorrect nucleotide relative to WT across from the dG-AF adduct. This effect was not observed for F762A or E710A mutants. Similar experiments that measured synthesis one nucleotide past the dG-AF adduct revealed an enhanced preference by the F762A mutant for dG opposite the T at this position. Finally, synthesis at the +1 and +2 positions was inhibited to a greater extent for the Y766S and E710A mutants compared with both the WT and F762A mutants. Taken together, this work is consistent with the model that polymerase geometry plays a crucial role in both the insertion and extension steps during replication across from bulky DNA lesions.     

Mechanism of DNA replication fidelity for three mutants of DNA polymerase I: Klenow fragment KF(exo+), KF(polA5), and KF(exo-)

Inhibition of the pre-steady-state burst of nucleotide incorporation by a single incorrect nucleotide (nucleotide discrimination) was measured with the Klenow fragment of DNA polymerase I [KF(exo+)]. For the eight mispairs studied on three DNA sequences, only low levels of discrimination ranging from none to 23-fold were found. The kinetics of dNTP incorporation into the 9/20-mer at low nucleotide concentrations was also determined. A limit of greater than or equal to 250 s-1 was placed on the nucleotide off-rate from the KF(exo+)-9/20-dTTP complex in accord with nucleotide binding being at equilibrium in the overall kinetic sequence. The influence of the relatively short length of the 9/20-mer on the mechanism of DNA replication fidelity was determined by remeasuring important kinetic parameters on a 30/M13-mer with high homology to the 9/20-mer. Pre-steady-state data on the nucleotide turnover rates, the dATP(alpha S) elemental effect, and the burst of dAMP misincorporation into the 30/M13-mer demonstrated that the kinetics were not affected by the length of the DNA primer/template. The effects on fidelity of two site-specific mutations, KF(polA5) and KF(exo-), were also examined. KF(polA5) showed an increased rate of DNA dissociation and a decreased rate of polymerization resulting in less processive DNA synthesis. Nevertheless, with at least one misincorporation event, that of dAMP into the 9/20-mer, KF(polA5) displays an increased replication fidelity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic exchange versus genetic differentiation in a medium-sized inversion of Drosophila: the A2/Ast arrangements of Drosophila subobscura

Chromosomal inversion polymorphism affects nucleotide variation at loci associated with inversions. In Drosophila subobscura, a species with a rich chromosomal inversion polymorphism and the largest recombinational map so far reported in the Drosophila genus, extensive genetic structure of nucleotide variation was detected in the segment affected by the O(3) inversion, a moderately sized inversion at Muller's element E. Indeed, a strong genetic differentiation all over O(3) and no evidence of a higher genetic exchange in the center of the inversion than at breakpoints were detected. In order to ascertain, whether other polymorphic and differently sized inversions of D. subobscura also exhibited a strong genetic structure, nucleotide variation in 5 gene regions (P236, P275, P150, Sxl, and P125) located along the A(2) inversion was analyzed in A(st) and A(2) chromosomes of D. subobscura. A(2) is a medium-sized inversion at Muller's element A and forms a single inversion loop in heterokaryotypes. The lower level of variation in A(2) relative to A(st) and the significant excess of low-frequency variants at polymorphic sites indicate that nucleotide variation at A(2) is not at mutation-drift equilibrium. The closest region to an inversion breakpoint, P236, exhibits the highest level of genetic differentiation (F(ST)) and of linkage disequilibrium (LD) between arrangements and variants at nucleotide polymorphic sites. The remaining 4 regions show a higher level of genetic exchange between A(2) and A(st) chromosomes than P236, as revealed by F(ST) and LD estimates. However, significant genetic differentiation between the A(st) and A(2) arrangements was detected not only at P236 but also in the other 4 regions separated from the nearest breakpoint by 1.2-2.9 Mb. Therefore, the extent of genetic exchange between arrangements has not been high enough to homogenize nucleotide variation in the center of the A(2) inversion. A(2) can be considered a typical successful inversion of D. subobscura according to its relative length. Chromosomal inversion polymorphism of D. subobscura might thus cause the genome of this species to be highly structured and to harbor different gene pools that might contribute to maintain adaptations to particular environments.     

Genetic characterization of Sabin types 1 and 3 poliovaccine virus following serial passage in the human intestinal tract.

Poliovirus isolates types 1 and 3 were obtained from five and seven successive passages respectively, in infants who had been fed monovalent OPV in two separate clinical trials conducted in 1960. The purpose of these trials was to answer the question how much the vaccine virus would revert to its original neurovirulent phenotype following multiplication in the intestinal tract. Human passages were performed either by contact exposure or by feeding the excreted virus while the infants were maintained in isolation. Several virus isolates were obtained at each passage level. Infants participating in both studies showed no symptoms of disease. Antigenic studies (McBride, van Wezel) and protein analysis (PAGE) of the isolates, reported earlier from this laboratory, had shown that the isolates remained vaccine-like, although isolates from the later passages revealed some differences. Monkey neurovirulence test results showed that for both types 1 and 3 viruses the loss of attenuation of the vaccine strain upon passage was gradual, although the loss was faster for type 3. Examination of the oligonucleotide maps demonstrated that the oligonucleotide configuration of the isolates remained the same as for the vaccine strain but there was an increase of individual spot differences with increasing passage. The nucleotide sequence analysis of selected regions of the virus genomes revealed that there was no change from a G to A in nucleotide 480 of type 1 isolates; however, nucleotide 476 changed from a U to an A in type 1 passages 3, 4 and 5. Conversely, for type 3 the change of nucleotide 472 from a U to a C changed at the early first passage (4 days following administration of OPV), and remained a C in the six following passages; type 3 nucleotide 2034 did not change in the first passage from a U to a C, but it became a C in all further passages tested. The nucleotide changes mentioned for both virus types remained stable in successive passages. However, there was another nucleotide change for type 3 from a U to a C at position 1973 only for passages 5 and 6 which reverted to a U for passages 7L and 7LL. Study of selected human passage virus strains could further contribute to the identification of the critical nucleotides that are responsible for the attenuation of these two polio types of vaccine viruses.     

DNA sequence analysis of the dnaK gene of Escherichia coli B and of two dnaK genes carrying the temperature-sensitive mutations dnaK7(Ts) and dnaK756(Ts).

The DNA sequence of the dnaK gene of Escherichia coli was analyzed. The nucleotide sequence of the wild-type dnaK gene of E. coli B differed from that of E. coli K-12 in 15 bp, none of which altered the amino acid sequence. Two temperature-sensitive dnaK mutations were examined by cloning and sequence analyses. Results showed that one dnaK mutation, dnaK7(Ts), was a one-base substitution of T for C at nucleotide position 448 in the open reading frame yielding an amber nonsense codon. The other mutation, dnaK756(Ts), consisted of base substitutions (A for G) at three nucleotide positions, 95, 1364, and 1403, in the open reading frame resulting in an aspartic acid codon in place of a glycine codon.     

Variability of milk fat globule membrane protein gene between cattle and riverine buffalo.

A study on butyrophilin (BTN) gene was conducted to detect variability at nucleotide level between cattle and buffalo. Hae III PCR-RFLP was carried out in crossbred cattle and it revealed polymorphism at this locus. Three genotypes namely, AA, BB and AB and two alleles were observed with frequencies 0.78, 0.17, 0.04 and 0.87, 0.13, respectively. The sequences of different cattle, buffalo and sheep breeds have been reported in the EMBL gene bank with accession numbers: AY491468 to AY491475. The nucleotides, which have been substituted from allele A to B, were found to be C to G (71st nucleotide), C to T (86th nucleotide), A to T (217th nucleotide), G to A (258th nucleotide), A to C (371st nucleotide) and C to T (377th nucleotide). The nucleotide substitution at 71st, 86th and 377th position of the fragment were expected to be a silent mutation where as nucleotide changes at 217th, 258th and 371st positions were expected to be substituted by lysine with arginine, valine with isoleucine and leucine with proline in allele B. The differences of nucleotides and amino acids between cattle, buffalo and sheep breeds have been revealed and on the basis of nucleotide as well as protein variability the phylogenetic diagram have been developed indicating closeness between cattle and buffalo.     

Structural analysis of the pilE region of Neisseria gonorrhoeae P9

We have determined the nucleotide sequence of an expressed structural pilus gene (pilE) derived from Neisseria gonorrhoeae strain P9-2. Detailed analysis of nucleotide sequences upstream from pilE revealed a silent, truncated pilin gene segment that was linked to families of DNA elements (RS1 and RS3) that have previously been identified at the major silent pilin gene locus (pilS1) and at pilE of the independently isolated N. gonorrhoeae strain MS11ms. A nucleotide sequence downstream from pilE was reminiscent of the recognition sequences of several recombinases, including Tn3 tnpR product (resolvase), suggesting a possible role for site-specific events in the recombinational modulation of pilus expression.     

Energy metabolism in Saccharomyces cerevisiae. Effect of progressive starvation on respiration and pyridine nucleotide reduction linked to ethanol oxidation in intact cells

The progressive effects of aerobic starvation on endogenous and ethanol-linked respiration and pyridine nucleotide reduction have been studied in the yeast Saccharomyces cerevisiae. Three distinct phases of pyridine nucleotide reduction were observed when ethanol was added to unstarved yeast: an initial phase of rapid reduction and accelerating respiration (A); a steady-state phase of reduction with maximal respiration (B); a final phase of rapid reduction at anaerobiosis (C).During the first 5 hr of aeration, the steady-state Phase B was replaced by a phase of slow pyridine nucleotide reduction, while Phases A and C were unaffected. During this period, both endogenous pyridine nucleotide reduction and endogenous respiration decreased sharply.Between 5 and 22 hr of aeration, the endogenous level of reduced pyridine nucleotide declined further, while endogenous respiration remained unchanged. Concurrently, the extent of the Phase A reduction doubled.The addition of ethanol to aerobic, unstarved yeast stimulated a rapid pyridine nucleotide reduction, with further reduction occurring at anaerobiosis. Under anaerobic conditions, the addition of ethanol to unstarved yeast caused little further reduction of pyridine nucleotide. Two hours of starvation decreased the extent of the endogenously supported anaerobic reduction and correspondingly increased the ethanol-induced reduction. These results suggest that, in unstarved yeast, reducing equivalents derived from ethanol under aerobic conditions and those derived from endogenous carbohydrate under anaerobic conditions have access to the same pool of pyridine nucleotide. With starvation, this pool becomes accessible to ethanol-derived (or ethanol-mobilized) reducing equivalents under anaerobic conditions.     

Nonequivalence of the nucleotide binding domains of the ArsA ATPase

The arsRDABC operon of Escherichia coli plasmid R773 encodes the ArsAB pump that catalyzes extrusion of the metalloids As(III) and Sb(III), conferring metalloid resistance. The catalytic subunit, ArsA, is an ATPase with two homologous halves, A1 and A2, connected by a short linker. Each half contains a nucleotide binding domain. The overall rate of ATP hydrolysis is slow in the absence of metalloid and is accelerated by metalloid binding. The results of photolabeling of ArsA with the ATP analogue 8-azidoadenosine 5'-[alpha-(32)P]-triphosphate at 4 degrees C indicate that metalloid stimulation correlates with a >10-fold increase in affinity for nucleotide. To investigate the relative contributions of the two nucleotide binding domains to catalysis, a thrombin site was introduced in the linker. This allowed discrimination between incorporation of labeled nucleotides into the two halves of ArsA. The results indicate that both the A1 and A2 nucleotide binding domains bind and hydrolyze trinucleotide, even in the absence of metalloid. Sb(III) increases the affinity of the A1 nucleotide binding domain to a greater extent than the A2 nucleotide binding domain. The ATP analogue labeled with (32)P at the gamma position was used to measure hydrolysis of trinucleotide at 37 degrees C. Under these catalytic conditions, both nucleotide binding domains hydrolyze ATP, but hydrolysis in A1 is stimulated to a greater degree by Sb(III) than A2. These results suggest that the two homologous halves of the ArsA may be functionally nonequivalent.     

A point mutation within the replicase gene differentially affects coronavirus genome versus minigenome replication

During the construction of the transmissible gastroenteritis virus (TGEV) full-length cDNA clone, a point mutation at position 637 that was present in the defective minigenome DI-C was maintained as a genetic marker. Sequence analysis of the recovered viruses showed a reversion at this position to the original virus sequence. The effect of point mutations at nucleotide 637 was analyzed by reverse genetics using a TGEV full-length cDNA clone and cDNAs from TGEV-derived minigenomes. The replacement of nucleotide 637 of TGEV genome by a T, as in the DI-C sequence, or an A severely affected virus recovery from the cDNA, yielding mutant viruses with low titers and small plaques compared to those of the wild type. In contrast, T or A at position 637 was required for minigenome rescue in trans by the helper virus. No relationship between these observations and RNA secondary-structure predictions was found, indicating that mutations at nucleotide 637 most likely had an effect at the protein level. Nucleotide 637 occupies the second codon position at amino acid 108 of the pp1a polyprotein. This position is predicted to map in the N-terminal polyprotein papain-like proteinase (PLP-1) cleavage site at the p9/p87 junction. Replacement of G-637 by A, which causes a drastic amino acid change (Gly to Asp) at position 108, affected PLP-1-mediated cleavage in vitro. A correlation was found between predicted cleaving and noncleaving mutations and efficient virus rescue from cDNA and minigenome amplification, respectively.