Genetic Analysis of Bacteriophage P22 Lysozyme Structure

The suppression patterns of 11 phage P22 mutants bearing different amber mutations in the gene encoding lysozyme (19) were determined on six different amber suppressor strains. Of the 60 resulting single amino acid substitutions, 18 resulted in defects in lysozyme activity at 30 degrees; an additional seven were defective at 40 degrees. Revertants were isolated on the "missuppressing" hosts following UV mutagenesis; they were screened to distinguish primary- from second-site revertants. It was found that second-site revertants were recovered with greater efficiency if the UV-irradiated phage stocks were passaged through an intermediate host in liquid culture rather than plated directly on the nonpermissive host. Eleven second-site revertants (isolated as suppressors of five deleterious substitutions) were sequenced: four were intragenic, five extragenic; three of the extragenic revertants were found to have alterations near and upstream from gene 19, in gene 13. Lysozyme genes from the intragenic revertant phages were introduced into unmutagenized P22, and found to confer the revertant plating phenotype.     

The interaction between aspartic acid 237 and lysine 358 in the lactose carrier of Escherichia coli.

The lacY from Escherichia coli strains 020 and AE43 have been cloned on plasmids which were designated p020-K358T and pAE43-D237N. These lacY mutants contain amino acid substitutions changing Lys-358 to Thr or Asp-237 to Asn, respectively. The charge neutralizing effect of each mutation is associated with a functional defect in melibiose transport which we exploited in order to isolate second site revertants to the melibiose-positive phenotype. Eleven melibiose-positive revertants of p020-K358T were isolated. All contained a second-site mutation converting Asp-237 to a neutral amino acid (8 to Asn, 1 to Gly, and 2 to Tyr). Twelve melibiose-positive revertants of pAE43-D237N were isolated. Two were second-site revertants converting Lys-358 to a neutrally Gln residue, while the remainder directly reverted Asn-237 to the wild-type Asp-237. We conclude that the functional intimate relationship between Asp-237 and Lys-358 suggests that these residues may be closely juxtaposed in three-dimensional space, possibly forming a 'charge-neutralizing' salt bridge.     

Amino acid substitutions in subunit 9 of the mitochondrial ATPase complex of Saccharomyces cerevisiae. Sequence analysis of a series of revertants of an oli1 mit- mutant carrying an amino acid substitution in the hydrophilic loop of subunit 9

This work concerns a biochemical genetic study of subunit 9 of the mitochondrial ATPase complex of Saccharomyces cerevisiae. Subunit 9, encoded by the mitochondrial oli1 gene, contains a hydrophilic loop connecting two transmembrane stems. In one particular oli1 mit- mutant 2422, the substitution of a positively charged amino acid in this loop (Arg39----Met) renders the ATPase complex non-functional. A series of 20 revertants, selected for their ability to grow on nonfermentable substrates, has been isolated from mutant 2422. The results of DNA sequence analysis of the oli1 gene in each revertant have led to the recognition of three groups of revertants. Class I revertants have undergone a same-site reversion event: the mutant Met39 is replaced either by arginine (as in wild-type) or lysine. Class II revertants maintain the mutant Met39 residue, but have undergone a second-site reversion event (Asn35----Lys). Two revertants showing an oligomycin-resistant phenotype carry this same second-site reversion in the loop region together with a further amino acid substitution in either of the two membrane-spanning segments of subunit 9 (either Gly23----Ser or Leu53----Phe). Class III revertants contain subunit 9 with the original mutant 2422 sequence, and additionally carry a recessive nuclear suppressor, demonstrated to represent a single gene. The results on the revertants in classes I and II indicate that there is a strict requirement for a positively charged residue in the hydrophilic loop close to the boundary of the lipid bilayer. The precise location of this positive charge is less stringent; in functional ATPase complexes it can be found at either residue 39 or 35. This charged residue is possibly required to interact with some other component of the mitochondrial ATPase complex. These findings, together with hydropathy plots of subunit 9 polypeptides from normal, mutant and revertant strains, led to the conclusion that the hydrophilic loop in normal subunit 9 extends further than previously suggested, with the boundary of the N-terminal membrane-embedded stem lying at residue 34. The possibility is raised that the observed suppression of the 2422 mutant phenotype in class III revertants is manifested through an accommodating change in a nuclear-encoded subunit of the ATPase complex.     

Second-Site Revertants of Escherichia Coli Trp Repressor Mutants

Second-site reversion studies were performed with five missense mutants with defects in the trp repressor of Escherichia coli. These mutants were altered throughout the gene. The same unidirectional mutagen used in the isolation of these mutants, hydroxylamine, was used in reversion studies, to increase the liklihood that the revertants obtained would have second-site changes. Most of the second-site revertants were found to have the same amino acid substitutions detected previously as superrepressor changes. These second-site revertant repressors were more active in vivo than their parental mutant repressors, in the presence or absence of exogenous tryptophan. Apparently superrepressor changes at many locations in this protein can act globally to increase the activity of mutant repressors.     

A Specific Point Mutant at Position 1 of the Influenza Hemagglutinin Fusion Peptide Displays a Hemifusion Phenotype

We showed previously that substitution of the first residue of the influenza hemagglutinin (HA) fusion peptide Gly1 with Glu abolishes fusion activity. In the present study we asked whether this striking phenotype was due to the charge or side-chain volume of the substituted Glu. To do this we generated and characterized six mutants with substitutions at position 1: Gly1 to Ala, Ser, Val, Glu, Gln, or Lys. We found the following. All mutants were expressed at the cell surface, could be cleaved from the precursor (HA0) to the fusion permissive form (HA1-S-S-HA2), bound antibodies against the major antigenic site, bound red blood cells, and changed conformation at low pH. Only Gly, Ala, and Ser supported lipid mixing during fusion with red blood cells. Only Gly and Ala supported content mixing. Ser HA, therefore, displayed a hemifusion phenotype. The hemifusion phenotype of Ser HA was confirmed by electrophysiological studies. Our findings indicate that the first residue of the HA fusion peptide must be small (e.g., Gly, Ala, or Ser) to promote lipid mixing and must be small and apolar (e.g., Gly or Ala) to support both lipid and content mixing. The finding that Val HA displays no fusion activity underscores the idea that hydrophobicity is not the sole factor dictating fusion peptide function. The surprising finding that Ser HA displays hemifusion suggests that the HA ectodomain functions not only in the first stage of fusion, lipid mixing, but also, either directly or indirectly, in the second stage of fusion, content mixing.     

Reversion of an S49 cell cyclic AMP-dependent protein kinase structural gene mutant occurs primarily by functional elimination of mutant gene expression.

The regulatory subunits of cyclic AMP (cAMP)-dependent protein kinase from a dibutyryl cAMP-resistant S49 mouse lymphoma cell mutant, clone U200/65.1, and its revertants were visualized by two-dimensional polyacrylamide gel electrophoresis. Clone U200/65.1 co-expressed electrophoretically distinguishable mutant and wild-type subunits (Steinberg et al., Cell 10:381-391, 1977). In all 48 clones examined, reversion of the mutant to dibutyryl cAMP sensitivity was accompanied by alterations in regulatory subunit labeling patterns. Some spontaneous (3 of 11) and N-methyl-N'-nitro-N-nitrosoguanidine-induced (2 of 11) revertants retained mutant subunits, but these were altered in charge, degree of phosphorylation, or both. The charge alterations were consistent with single amino acid substitutions, suggesting that reversion was the result of second-site mutations in the mutant regulatory subunit allele that restored wild-type function, although not wild-type structure, to the gene product. The majority of spontaneous (8 of 11) and N-methyl-N'-nitro-N-nitrosoguanidine-induced (9 of 11) revertants and all of the revertants induced by ethyl methane sulfonate (14 of 14) and ICR191 (12 of 12) displayed only wild-type subunits. Dibutyryl cAMP-resistant mutants isolated from several of these revertants displayed new mutant but not wild-type subunits, suggesting that the revertant parent expresses only a single, functional regulatory subunit allele. The mutant regulatory subunit allele can, therefore, be modified in two general ways to produce revertant phenotypes: (i) by mutations that restore its wild-type function, and (ii) by mutations that eliminate its function.     

The Neurospora am gene and NADP-specific glutamate dehydrogenase: mutational sequence changes and functional effects--more mutants and a summary

A further series of mutant am alleles, encoding potentially active NADP-specific glutamate dehydrogenase (GDH) and capable of complementation in heterocaryons, have been characterized with respect to both GDH properties and DNA sequence changes. Several mutants previously studied, and some of their same-site or second-site revertants, have also been sequenced for the first time. We present a summary of what is known of the properties of all am mutants that have been defined at the sequence level.     

Suppressor analysis of mutations in the loop 2-3 motif of lactose permease: evidence that glycine-64 is an important residue for conformational changes.

A superfamily of transport proteins, which includes the lactose permease of Escherichia coli, contains a highly conserved motif, G-X-X-X-D/E-R/K-X-G-R/K-R/K, in the loops that connect transmembrane segments 2 and 3 and transmembrane segments 8 and 9. Previous analysis of this motif in the lactose permease (A. E. Jessen-Marshall, N. J. Paul, and R. J. Brooker, J. Biol. Chem. 270:16251-16257, 1995) has shown that the conserved glycine residue found at the first position in the motif (i.e., Gly-64) is important for transport function. Every substitution at this site, with the exception of alanine, greatly diminished lactose transport activity. In this study, three mutants in which glycine-64 was changed to cysteine, serine, and valine were used as parental strains to isolate 64 independent suppressor mutations that restored transport function. Of these 64 isolates, 39 were first-site revertants to glycine or alanine, while 25 were second-site mutations that restored transport activity yet retained a cysteine, serine, or valine at position 64. The second-site mutations were found to be located at several sites within the lactose permease (Pro-28 --> Ser, Leu, or Thr; Phe-29 --> Ser; Ala-50 --> Thr, Cys-154 --> Gly; Cys-234 --> Phe; Gln-241 --> Leu; Phe-261 --> Val; Thr-266 --> Iso; Val-367 --> Glu; and Ala-369 --> Pro). A kinetic analysis was conducted which compared lactose uptake in the three parental strains and several suppressor strains. The apparent Km values of the Cys-64, Ser-64, and Val-64 parental strains were 0.8 mM, 0.7 mM, and 4.6 mM, respectively, which was similar to the apparent Km of the wild-type permease (1.4 mM). In contrast, the Vmax values of the Cys-64, Ser-64, and Val-64 strains were sharply reduced (3.9, 10.1, and 13.2 nmol of lactose/min x mg of protein, respectively) compared with the wild-type strain (676 nmol of lactose/min x mg of protein). The primary effect of the second-site suppressor mutations was to restore the maximal rate of lactose transport to levels that were similar to the wild-type strains. Taken together, these results support the notion that Gly-64 in the wild-type permease is at a site in the protein which is important in facilitating conformational changes that are necessary for lactose translocation across the membrane. According to our tertiary model, this site is at an interface between the two halves of the protein.     

Arg-52 in the Melibiose Carrier of Escherichia coli Is Important for Cation-Coupled Sugar Transport and Participates in an Intrahelical Salt Bridge

Arg-52 of the Escherichia coli melibiose carrier was replaced by Ser (R52S), Gln (R52Q), or Val (R52V). While the level of carrier in the membrane for each mutant remained similar to that for the wild type, analysis of melibiose transport showed an uncoupling of proton cotransport and a drastic reduction in Na(+)-coupled transport. Second-site revertants were selected on MacConkey plates containing melibiose, and substitutions were found at nine distinct locations in the carrier. Eight revertant substitutions were isolated from the R52S strain: Asp-19-->Gly, Asp-55-->Asn, Pro-60-->Gln, Trp-116-->Arg, Asn-244-->Ser, Ser-247-->Arg, Asn-248-->Lys, and Ile-352-->Val. Two revertants were also isolated from the R52V strain: Trp-116-->Arg and Thr-338-->Arg revertants. The R52Q strain yielded an Asp-55-->Asn substitution and a first-site revertant, Lys-52 (R52K). The R52K strain had transport properties similar to those of the wild type. Analysis of melibiose accumulation showed that proton-driven accumulation was still defective in the second-site revertant strains, and only the Trp-116-->Arg, Ser-247-->Arg, and Asn-248-->Lys revertants regained significant Na(+)-coupled accumulation. In general, downhill melibiose transport in the presence of Na(+) was better in the revertant strains than in the parental mutants. Three revertant strains, Asp-19-->Gly, Asp-55-->Asn, and Thr-338-->Arg strains, required a high Na(+) concentration (100 mM) for maximal activity. Kinetic measurements showed that the N248K and W116R revertants lowered the K(m) for melibiose, while other revertants restored transport velocity. We suggest that the insertion of positive charges on membrane helices is compensating for the loss of Arg-52 and that helix II is close to helix IV and VII. We also suggest that Arg-52 is salt bridged to Asp-55 (helix II) and Asp-19 (helix I).     

Mutational analysis of primosome assembly sites. II. Role of secondary structure in the formation of active sites

Based on their activity as effectors for the ATPase activity of Escherichia coli replication factor Y and as templates for primosome-directed DNA synthesis, single-point mutations in the L- and H-strand primosome assembly sites from pBR322 DNA have been grouped into four classes (Abarzúa, P., Soeller, W., and Marians, K. (1984) J. Biol. Chem. 259, 14286-14292). In this report, the effect of various ligands on the characteristic activities of primosome assembly site class II mutants has been examined. Both Mn2+ and spermidine can, at low levels, substitute for Mg2+ in the activation of wild-type sites as effectors for factor Y-catalyzed hydrolysis of ATP. Class II mutant sites characteristically require higher levels of these ligands for activation, suggesting that the specific higher order structure of an active primosome assembly site is maintained through base pairing within the single-stranded DNA sequence. This conclusion is supported by the following. 1) Excess levels of the E. coli single-stranded DNA-binding protein can inactivate wild-type sites at 1 mM Mg2+. Either the addition of NaCl to 80 mM or an increase in the Mg2+ concentration to 5 mM protects against this inactivation. Class II mutant sites, however, cannot be stabilized by 80 mM NaCl at 1 mM Mg2+, and only some class II mutants can be stabilized at 5 mM Mg2+. 2) Active second-site revertants, isolated in vivo and in vitro, of inactive primosome assembly sites containing multiple-base substitutions have mutated to restore lost base pairs in the proposed stem and loop structure of the sites.     

Function of the loop residue Thr792 in human DNA topoisomerase II alpha

We studied the mutation effect of one of the putative loop residues Thr792 in human DNA topoisomerase II alpha (TOP2 alpha). Thr792 mutants were expressed from high or low copy plasmids in a temperature sensitive yeast strain deficient in TOP2 (top2-1). When expressed from a high copy plasmid, mutants with small side chains complemented the yeast defect; however, from a low copy plasmid, only wild-type, Ser, and Cys substitution mutants complemented the yeast defect. Interestingly, at the permissive temperature other mutants (e.g., Val, Gly, and Glu substitutions) showed the dominant negative effect to the top2-1 allele, which was not observed by the control alpha 4-helix mutants. T792E mutant was 10-fold less active than wild-type and the T792P had no decatenation activity in vitro. These results suggest that Thr792 in human TOP2 alpha is involved in enzyme catalysis.     

Nuclear and mitochondrial revertants of a yeast mitochondrial tRNA mutant

Summary We isolated revertants capable of respiration from the respiratory deficient yeast mutant, FF1210-6C/ 170, which displays greatly decreased mitochondrial protein synthesis due to a single base substitution at the penultimate base of the tRNA^Asp gene on mitochondrial (mt) DNA. Three classical types of revertant were identified: (1) same-site revertants; (2) intragenic revertants which restore the base pairing in the acceptor stem of the mitochondrial tRNA^Asp; and (3) extragenic suppressors located in nuclear DNA. In addition a fourth type of revertant was identified in which the mutant tRNA^Asp is amplified due to the maintenance of both the original mutant mtDNA and a modified form of the mutant mtDNA in which only a small region around the tRNA^Asp gene is retained and amplified. The latter form resembles the mtDNA in vegetative petite (rho ^-) strains which normally segregates rapidly from the wild-type mtDNA. Each revertant type was characterized genetically and by both DNA sequence analysis of the mitochondrial tRNA^Asp gene and analysis of the quantity and size of RNA containing the tRNA^Asp sequence. These results indicate that the mitochondrial tRNA^Asp of the mutant retains a low level of activity and that the presence of the terminal base pair in tRNA^Asp is a determinant of both tRNA^Asp function and the maintenance of wild-type levels of tRNA^Asp.     

Kinetics of dipeptidyl peptidase IV proteolysis of growth hormone-releasing factor and analogs.

The kinetics and selectivity of proteolysis of synthetic human growth hormone-releasing factor and analogs by purified human placental dipeptidyl peptidase IV (DPP IV) were studied by HPLC. The initial rates of Ala2-Asp3 cleavage (pH 7.8, 37 degrees C, So = 0.15 mM) were all approx. 5 mumol min-1 mg-1 for the parent hormone, GRF(1-44)-NH2, and the fragments, GRF(1-29)-NH2 and GRF(1-20)-NH2. Lower activities observed for GRF(1-11)-OH, GRF(1-3)-OH, and cyclic lactam analogs indicate S1'-Sn' binding. Assays of [Trp6]-GRF(1-29)-NH2 versus [D-Trp6]-GFR(1-29)-NH2 indicate an S4' binding cavity. Peptides with D-configuration at P2, P1 or P1' and desNH2Tyr1 and N-MeTyr1 analogs of GRF were not cleaved. Catalytic parameters for the P1-substituted analogs [X2,Ala15]-GRF(1-29)-NH2 were found to vary with X as follows, Km: Abu less than Ala less than Pro less than Val less than Ser less than Gly much less than Leu; kcat: Pro greater than Ala greater than Abu greater than Ser greater than Gly much greater than Leu greater than Val; kcat/Km: Abu greater than Pro greater than Ala much greater than Ser greater than Gly = Val much greater than Leu. Km is at a minimum and kcat/Km at a maximum, for a hydrophobic P1 side-chain of about 0.25 nm in length, i.e., the ethyl side-chain of alpha-aminobutyric acid (Abu) is very close to optimal. These results further define the S1 selectivity of DPP IV and may be useful in the design of DPP IV resistant GRF analogs that can be produced by recombinant DNA methods and the design of DPP IV inhibitors.     

Proline mutations induce negative-dosage effects on uptake velocity of the dopamine transporter

Ala and Gly substitutions for Pro 101 (P101) located in transmembrane domain 2 of the dopamine transporter (DAT) abolished transport activity but did not disrupt plasma membrane expression. Due to the high conservation of P101 in all neurotransmitter transporters and the capability of Pro to add flexibility to helices, we hypothesized that P101 contributes to the dynamic feature of substrate translocation. To test this hypothesis, here we analysed transport activity for DAT mutants where this Pro was mutated into different amino acids, including Ser, Val, Leu and Phe. The transmembrane domain 2 helix of P101F, unlike the other mutants, was computationally predicted to have a Van der Waals energy threefold higher than the wild-type helix. P101F mutant expression was consistently disrupted in COS cells. Among all the other mutants that express normally, P101V, with a side-chain size close to that of Pro, restores the transport activity of P101A by sevenfold. Most importantly, P101V, P101L and P101S display negative-dosage effects on dopamine (DA) transport, i.e. the velocity-concentration curve for DA uptake does not show a plateau with increasing [DA] but rather peaks and then goes down. These data support the view that P101 of DAT plays an essential role in DA translocation.     

Lambda repressor mutations that increase the affinity and specificity of operator binding

Intragenic, second-site reversion has been used to identify amino acid substitutions that increase the affinity and specificity of the binding of lambda repressor to its operator sites. Purified repressors bearing the second-site substitutions bind operator DNA from 3 to 600 fold more strongly than wild type; these affinity changes result from both increased rates of operator association and decreased rates of operator dissociation. Three of the revertant substitutions occur in the alpha 2 and alpha 3 DNA binding helices of repressor and seem to increase affinity by introducing new salt-bridges or hydrogen bonds with the sugar-phosphate backbone of the operator site. The fourth substitution alters the alpha 5 dimerization helix of repressor and appears to increase operator affinity indirectly.     

Enhancement of the enzymatic activity of ribonuclease HI from Thermus thermophilus HB8 with a suppressor mutation method

A genetic method for isolating a mutant enzyme of ribonuclease HI (RNase HI) from Thermus thermophilus HB8 with enhanced activity at moderate temperatures was developed. T. thermophilus RNase HI has an ability to complement the RNase H-dependent temperature-sensitive (ts) growth phenotype of Escherichia coli MIC3001. However, this complementation ability was greatly reduced by replacing Asp(134), which is one of the active site residues, with His, probably due to a reduction in the catalytic activity. Random mutagenesis of the gene encoding the resultant D134H enzyme, followed by screening for second-site revertants, allowed us to isolate three single mutations (Ala(12) --> Ser, Lys(75) --> Met, and Ala(77) --> Pro) that restore the normal complementation ability to the D134H enzyme. These mutations were individually or simultaneously introduced into the wild-type enzyme, and the kinetic parameters of the resultant mutant enzymes for the hydrolysis of a DNA-RNA-DNA/DNA substrate were determined at 30 degrees C. Each mutation increased the k(cat)/K(m) value of the wild-type enzyme by 2.1-4.8-fold. The effects of the mutations on the enzymatic activity were roughly cumulative, and the combination of these three mutations increased the k(cat)/K(m) value of the wild-type enzyme by 40-fold (5.5-fold in k(cat)). Measurement of thermal stability of the mutant enzymes with circular dichroism spectroscopy in the presence of 1 M guanidine hydrochloride and 1 mM dithiothreitol showed that the T(m) value of the triple mutant enzyme, in which all three mutations were combined, was comparable to that of the wild-type enzyme (75.0 vs 77.4 degrees C). These results demonstrate that the activity of a thermophilic enzyme can be improved without a cost of protein stability.     

Isolation and characterization of Escherichia coli birA intragenic suppressors

Summary The biotin (bio) operon in Escherichia coli is negatively regulated by BirA, a bifunctional protein with both repressor and biotin-activating functions. Twenty-five heatresistant revertants of three temperature-sensitive birA alleles (birA 85, bir A 104 and bir A 879) were isolated and categorized into five growth and six repression classes. The revertants appear to increase biotin activation by raising the specific activity of BirA and/or, increasing the number of enzyme molecules. The 19 bir A 85 revertants displayed a broad range of activity for both enzyme and repressor functions, and may represent intragenic second-site suppressor mutations. The bir A 85 revertants included a novel class of bio superrepressor mutations. Repressor titration experiments suggested that many of the bir A 85 revertants increase BirA concentrations above wild-type levels because the repressors were not competed from the chromosomal bio operator by multicopy bio operator plasmids. The majority of the bir A 104 revertants resulted in both wild-type repressor and enzyme activity; they are possibly true revertants in which the amino acid residue altered by the bir A 104 mutation has been substituted by the wild-type or a chemically similar amino acid.     

Simian virus 40 mutant T antigens with relaxed specificity for the nucleotide sequence at the viral DNA origin of replication.

Base substitution of the ori region of simian virus 40 leads to plaque morphology mutants with markedly decreased DNA replication. Second-site mutations within the simian virus 40 T antigen gene suppress the plaque phenotype and replication defect of base-substituted ori mutants. Two second-site mutations have been mapped to a small segment of the T antigen gene, just beyond the distal splice junction. DNA sequence analysis revealed a single missense change in this segment of the T antigen gene of each of these second-site revertants, leading to a change in codon 157 in one case and codon 166 in the other. The mutant T antigens displayed relaxed specificity for the ori signal, i.e., they can function with several variously modified ori sequences, including those with small nucleotide deletions or insertions that are inactive for replication when coupled with wild-type T antigen. Thus a region of T antigen has been identified that appears to be intimately involved in vivo in binding to the ori sequence to initiate viral DNA replication.     

Modification of Asn374 of nsP1 suppresses a Sindbis virus nsP4 minus-strand polymerase mutant

Our recent study (C. L. Fata, S. G. Sawicki, and D. L. Sawicki, J. Virol. 76:8632-8640, 2002) found minus-strand synthesis to be temperature sensitive in vertebrate and invertebrate cells when the Arg183 residue of the Sindbis virus nsP4 polymerase was changed to Ser, Ala, or Lys. Here we report the results of studies identifying an interacting partner of the region of the viral polymerase containing Arg183 that suppresses the Ser183 codon mutation. Large-plaque revertants were observed readily following growth of the nsP4 Ser183 mutant at 40 degrees C. Fifteen revertants were characterized, and all had a mutation in the Asn374 codon of nsP1 that changed it to either a His or an Ile codon. When combined with nsP4 Ser183, substitution of either His374 or Ile374 for Asn374 restored wild-type growth in chicken embryo fibroblast (CEF) cells at 40 degrees C. In Aedes albopictus cells at 34.5 degrees C, neither nsP1 substitution suppressed the nsP4 Ser183 defect in minus-strand synthesis. This argued that the nsP4 Arg183 residue itself is needed for minus-strand replicase assembly or function in the mosquito environment. The nsP1 His374 suppressor when combined with the wild-type nsP4 gave greater than wild-type levels of viral RNA synthesis in CEF cells at 40 degrees C ( approximately 140%) and in Aedes cells at 34.5 degrees C (200%). Virus producing nsP1 His374 and wild-type nsP4 Arg183 made more minus strands during the early period of infection and before minus-strand synthesis ceased at about 4 h postinfection. Shirako et al. (Y. Shirako, E. G. Strauss, and J. H. Strauss, Virology 276:148-160, 2000) identified amino acid substitutions in nsP1 and nsP4 that suppressed mutations that changed the N-terminal Tyr of nsP4. The nsP4 N-terminal mutants were defective also in minus-strand synthesis. Our study implicates an interaction between another conserved nsP1 region and an internal region, predicted to be in the finger domain, of nsP4 for the formation or activity of the minus-strand polymerase. Finally, the observation that a single point mutation in nsP1 results in minus-strand synthesis at greater than wild-type levels supports the concept that the wild-type nsP sequences are evolutionary compromises.