Deletion of mitochondrial DNA bypassing a chromosomal gene needed for maintenance of the killer plasmid of yeast

Strains of Saccharomyces cerevisiae carrying a 1.4 x 10⁶ dalton double-stranded (ds) RNA in virus-like particles (the killer plasmid or virus) secrete a toxin that is lethal to strains not carrying this plasmid (virus). The mak10 gene is one of 24 chromosomal genes (called pets, mak1, mak2,...) that are needed to maintain and replicate the killer plasmid. We report here isolation of spontaneous and induced mutants in which the killer plasmid is maintained and replicated in spite of a defect in the mak10 gene. The bypass (or suppressor) mutations in these strains are in the mitochondrial genome. Respiratory deficiency produced by various chromosomal pet mutations, by chloramphenicol, or by antimycin A, does not bypass the mak10–1 mutation. Several spontaneous mak10–1 killer strains have about 12-fold more of the killer plasmid ds RNA than do wild-type killers. Although the absence of mitochondrial DNA bypasses mak10–1, it does not bypass pets–1, mak1–1, mak3–1, mak4–1, mak5–1, mak6–1, mak7–1, or mak8–1.     

Mutants of the Killer Plasmid of SACCHAROMYCES CEREVISIAE Dependent on Chromosomal Diploidy for Expression and Maintenance

Mutants of the killer plasmid of Saccharomyecs cerevisiae have been isolated that depend upon chromosomal diploidy for the expression of plasmid functions and for replication or maintenance of the plasmid itself. These mutants are not defective in any chromosomal gene needed for expression or replication of the killer plasmid.—Haploids carrying these mutant plasmids (called d for diploid-dependent) are either unable to kill or unable to resist being killed or both and show frequent loss of the plasmid. The wild-type phenotype (K⁺R⁺) is restored by mating the d plasmid-carrying strain with either (a) a wild-type sensitive strain which apparently has no killer plasmid; (b) a strain which has been cured of the killer plasmid by growth at elevated temperature; (c) a strain which has been cured of the plasmid by growth in the presence of cycloheximide; (d) a strain which has lost the plasmid because it carries a mutation in a chromosomal mak gene; or (e) a strain of the opposite mating type which carries the same d plasmid and has the same defective phenotype, indicating that the restoration of the normal phenotype is not due to recombination between plasmid genomes or complementation of plasmid or chromosomal genes.—Sporulation of the phenotypically K⁺R⁺ diploids formed in matings between d and wild-type nonkiller strains yields tetrads, all four of whose haploid spores are defective for killing or resistance or maintenance of the plasmid or a combination of these. Every defective phenotype may be found among the segregants of a single diploid clone carrying a d plasmid. These defective segregants resume the normal killer phenotype in the diploids formed when a second round of mating is performed, and the segregants from a second round of meiosis and sporulation are again defective.     

Genetic structure and regulation of a replicon of plasmid lambdadv.

Strains of Saccharomyces cerevisiae carrying a small double-stranded RNA species (the killer plasmid) secrete a toxin which is lethal only to strains not carrying this plasmid.We have isolated mutants in eight chromosomal genes essential for replication or maintenance of the killer plasmid, called mak1 through mak8. Seven of these genes have been mapped. mak4 and mak5 are on chromosome II; mak1 and mak8 are on chromosome XV; mak3 and mak6 are on chromosome XVI; and mak7 is on chromosome VIII. We have not yet located mak2. Two other chromosomal genes, m and pets, have been shown to be required for replication or maintenance of the killer plasmid.One allele of mak1 results in temperature sensitivity for host growth. Two independent pets isolates also result in the petite phenotype, as well as temperature sensitivity for growth.Wild-type killer strains have been reported to carry two species of doublestranded RNA of 2.5 × 10⁶ and 1.4 × 10⁶ molecular weight (designated L and M, respectively); wild-type non-killers carried only L. We estimate the size of the L and M species at 3.0 × 10⁶ and 1.7 × 10⁶ daltons, respectively. We have also detected a third species of double-stranded RNA of molecular weight 3.8 × 10⁶ (XL) present in all killer and non-killer strains examined.Mutation of any of mak1 through mak8 results in loss of the killer-associated species of double-stranded RNA (M; 1.7 × 10⁶). These mutants retain both the L species (3.0 × 10⁶) and the XL species (3.8 × 10⁶) of double-stranded RNA, and have acquired two new minor RNA species.     

The occurrence of killer,sensitive, and neutral yeasts in Brazilian Riesling Italico grape must and the effect of neutral strains on killing behaviour

 The occurrence of killer toxins amongst yeasts in Brazilian Riesling Italico grape must was investigated by using the sensitive strain EMBRAPA-26B as a reference strain at 18°C and 28°C. From a total of 85 previously isolated yeasts, 21 strains showed ability to kill the sensitive strain on unbuffered grape must/agar (MA-MB) and 0.1 M citrate/phosphate-buffered yeast extract/peptone/dextrose/agar (YEPD-MB) media both supplemented with 30 mg/l methylene blue. The killer activity of only four yeasts depended on the incubation temperature rather than the medium used. At 28°C, the strains 11B and 53B were not able to show killer action. On the other hand, strains 49B and 84B did not kill the sensitive yeast at 18°C. The killer strain EMBRAPA-91B and a commercial wine killer yeast K-1 were employed to examine the sensitivity of the isolated yeasts on YEPD-MB and MA-MB at 18°C. The sensitivity and neutral characteristics of yeasts were shown to be dependent on the medium and the killer strain. Interactions, including K^- R^-, K^- R⁺ and K⁺ R⁺ strains, simultaneously, have revealed that some K^-R⁺ strains appear to protect the K^- R^- strain against the killer toxin. Sensitive dead cells, although to a less extent, also exhibited similar protection. Kinetic studies have shown that the maximum specific growth rates were higher for the 20B YEPD-MB-sensitive strain (μ_max=0.517 h^-1) than for both the 91B (μ_max=0.428 h^-1) and K-1 (μ_max= 0.466 h^-1) killer strains. The protective capacity of neutral or sensitive cells that contaminate a fermentation, as well as the higher maximum specific growth rate of sensitive yeasts, besides other factors, may preclude the dominance of a killer strain. This protective capacity may also reduce the risk of a sensitive inoculum being killed by wild-type killer yeasts in open non-sterile fermentation. Received: 3 November 1995/Received revision: 11 March 1996/Accepted: 15 April 1996     

Two Chromosomal Genes Required for Killing Expression in Killer Strains of SACCHAROMYCES CEREVISIAE

The killer character of yeast is determined by a 1.4 x 10⁶ molecular weight double-stranded RNA plasmid and at least 12 chromosomal genes. Wild-type strains of yeast that carry this plasmid (killers) secrete a toxin which is lethal only to strains not carrying this plasmid (sensitives). ——— We have isolated 28 independent recessive chromosomal mutants of a killer strain that have lost the ability to secrete an active toxin but remain resistant to the effects of the toxin and continue to carry the complete cytoplasmic killer genome. These mutants define two complementation groups, kex1 and kex2. Kex1 is located on chromosome VII between ade5 and lys5. Kex2 is located on chromosome XIV, but it does not show meiotic linkage to any gene previously located on this chromosome. ——— When the killer plasmid of kex1 or kex2 strains is eliminated by curing with heat or cycloheximide, the strains become sensitive to killing. The mutant phenotype reappears among the meiotic segregants in a cross with a normal killer. Thus, the kex phenotype does not require an alteration of the killer plasmid. ——— Kex1 and kex2 strains each contain near-normal levels of the 1.4 x 10⁶ molecular weight double-stranded RNA, whose presence is correlated with the presence of the killer genome.     

Spore killer, a chromosomal factor in neurospora that kills meiotic products not containing it

Three chromosomal factors called Spore killer (Sk) have been found in wild populations of Neurospora sitophila and N. intermedia. Sk resembles other examples of meiotic drive such as Segregation Distorter in Drosophila, Pollen killer in wheat, and Gamete eliminator in tomato. In crosses heterozygous for Sk, each ascus contains four viable black ascospores and four inviable, undersize, clear ascospores, with second-division segregations infrequent. The survivors contain the killer allele Sk^K, while unlinked markers segregate normally. Reciprocal crosses are identical. When crosses are homozygous for an allele of Sk, all eight ascospores are viable and black in most asci. (Many homozygous crosses have a background level of randomly occurring inviable spores; however, the pattern of 4 viable: 4 small clear ascospores is not found in any of the asci of Sk-homozygous crosses.)——Killer (Sk-1^K) and sensitive (Sk-1^S) alleles occur in about equal numbers among a worldwide sample of N. sitophila strains, following no geographic pattern. No killer allele has been found in N. crassa. Sk-2^K and Sk-3^K, found in N. intermedia, are rare. Most N. intermedia strains are Sk-2^S and Sk-3^S, but some are wholly or partially resistant to one or both of the killer alleles, while not themselves acting as killers. Sk-2^K and Sk-2^R are both specific in conferring resistance to Sk-2^K, but not to Sk-3^K. Likewise Sk-3^K and Sk-3^R are resistant specifically to Sk-3^K, but not to Sk-2^K. Resistance segregates as an allele of Sk^K.——Sk-2 and Sk-3 have been mapped near the centromere of linkage group III after introgression into N. crassa, where crossing over is normally 11% between the proximal III markers acr-2 and leu-1. But crossing over is absent in this region when either of the killer alleles is heterozygous (Sk-2^K x Sk-2^S, Sk-3^K x Sk-3^S and Sk-2^K x Sk-2^R have been examined).     

Plasmids controlling exclusion of the K2 killer double-stranded RNA plasmid of yeast

Saccharomyces strains of two types (K₁⁺R₁⁺ and K₂⁺R₂⁺) kill each other and K^?R^?-sensitive strains by secreting protein toxins. K₁ killer strains carry a 1.25 × 10⁶ dalton double-stranded RNA plasmid, [KIL-k₁], while K₂ killers have a 1.0 × 10⁶ dalton double-stranded RNA plasmid, [KIL-k₁]. Mating [KIL-k₁] haploids with [KIL-k₂] haploids yields only [KIL-k₁] diploids, that is, [KIL-k₁] excludes [KIL-k₂]. [EXL], a new non-Mendellan genetic element from a nonkiller strain, excludes [KIL-k₂] but does not exclude [KIL-k₂]. A second new non-Mendelian genetic element, called [NEX], when present prevents [EXL] from excluding [KIL-k₂]. [NEX] does not prevent [KIL-k₁] or [KIL-s₁] (a suppressive mutant of [KIL-k₁]) from excluding [KIL-k₂]. A chromosomal gene, called MKT1, is needed for maintenance of [KIL-k₂] if [NEX] is present. In the absence of [NEX], [KIL-k₂] does not need MKT1. [KIL-k₁] does not need MKT1 even if [NEX] is present. [EXL] replication depends on at least the products of MAK1, MAK3, MAK10and PET18. [NEX]replication depends on MAK3 but is independent of MAK4, MAKE, MAK27 and MKT1.     

Conjugal transfer of plasmid and chromosomal markers between strains of Thiobacillus versutus

In experiments on conjugation in Thiobacillus versutus with the use of pTAV1-less strains as recipients, we have proved that the derivative of the wild-type T. versutus cryptic plasmid pTAV1 (107 kb) marked with Tn1721 (Tc^r) transposon demonstrates Tra^- phenotype but can be mobilized for transfer by pSa Tra⁺ broad-host-range helper plasmid at a low frequency. The possibility of chromosomal gene exchange between different auxotrophic and drug-resistant T. versutus mutants has been confirmed. The previously assumed participation of plasmid pTAV1 in the above process must be excluded because conjugal transfer of chromosomal markers can be observed even when two pTAV1-free strains are mated. Formation of some classes of transconjugants can be reasonably explained only when two-directional chromosomal DNA transfer (retrotransfer) is considered. At this stage of our studies we can not propose any hypothesis on the mechanism of chromosomal gene transfer. The possible role of the megaplasmids discovered in T. versutus in chromosome mobilization needs to be elucidated.     

Krb1, a Suppressor of Mak7-1 (a Mutant Rpl4a), Is Rpl4b, a Second Ribosomal Protein L4 Gene, on a Fragment of Saccharomyces Chromosome Xii

The mak7-1 mutant loses the killer toxin-encoding M(1) dsRNA. MAK7 is RPL4A, one of two genes encoding ribosomal protein L4. KRB1 is a dominant suppressor of mak7-1 that is tightly centromere-linked, but not linked to centromere markers of chromosomes I-XVI. Our orthogonal field agarose gel electrophoresis analysis of chromosomal DNA from strains with KRB1 shows a novel band of ~250 kb. This band hybridizes with an RPL4B-specific probe, but not an RPL4A (MAK7)-specific probe. The RPL4B-specific probe also hybridizes to chromosome XII where the original RPL4B is located. KRB1 is meiotically linked to this extra chromosome. Disruption of either the RPL4B gene on chromosome XII or that on the extra chromosome results in loss of the killer phenotype and a decreased concentration of free 60S subunits. Thus, the RPL4B on the extra chromosome is KRB1 and is active. The extra chromosome contains chromosome XII sequence between Lambda 5345 clone (ATCC70558) and Lambda 6639 clone (ATCC71085) of Olson's Lambda library, indicating that KRB1 represents a chromosomal rearrangement involving chromosome XII and explaining the earlier genetic data.     

R-Plasmid Transfer to and from Escherichia coli Strains Isolated from Human Fecal Samples

Strains of Escherichia coli recently isolated from human feces were examined for the frequency with which they accept an R factor (R1) from a derepressed fi⁺ strain of E. coli K-12 and transfer it to fecal and laboratory strains. Colicins produced by some of the isolates rapidly killed the other half of the mating pair; therefore, conjugation was conducted by a membrane filtration procedure whereby this effect was minimized. The majority of fecal E. coli isolates accepted the R factor at lower frequencies than K-12 F⁻, varying from 10⁻² per donor cell to undetectable levels. The frequencies with which certain fecal recipients received the R-plasmid were increased when its R⁺ transconjugant was either cured of the R1-plasmid and remated with the fi⁺ strain or backcrossed into the parental strain. The former suggests the loss of an incompatibility plasmid, and the latter suggests the modification of the R1-plasmid deoxyribonucleic acid (DNA). In general, the fecal R⁺E. coli transconjugants were less effective donors for K-12 F⁻ and heterologous fecal strains than was the fi⁺ K-12 strain, whereas the single strain of Citrobacter freundii examined was generally more competent. Passage of the R1-plasmid to strains of salmonellae reached mating frequencies of 10⁻¹ per donor cell when the recipient was a Salmonella typhi previously cured of its resident R-plasmid. However, two recently isolated strains of Salmonella accepted the R1-plasmid from E. coli K-12 R⁺ or the R⁺E. coli transconjugants at frequencies of 5 × 10⁻⁷ or less.     

D-glucose Stimulates the Na+/K+ Pump in Mouse Pancreatic Islet Cells

To determine the effect of D-glucose on the β-cell Na⁺/K⁺ pump, ⁸⁶Rb⁺ influx was studied in isolated, -cell-rich islets of Umeå-ob/ob mice in the absence or presence of lmM ouabain. D-glucose (20 mM) stimulated the ouabain-sensitive portion of ⁸⁶Rb⁺ influx by 65%, whereas the ouabain-resistant portion was inhibited by 48%. The Na⁺/K⁺ ATPase activity in homogenates of islets of Umeå-ob/ob mice or normal mice was determined to search for direct effects of D-glucose. Thus, ouabain-sensitive ATP hydrolysis in islet homogenates was measured in the presence of different D-glucose concentrations. No effect of D-glucose (3–20 mM) was observed in either ob/ob or normal islets at the optimal Na⁺/K⁺ ratio for the enzyme (135 mM Na⁺ and 20 mM K⁺). Neither D-glucose (3–20 mM) nor L-glucose or 3-O-methyl-D-glucose (20 mM) affected the enzyme activity at a high Na⁺/K⁺ ratio (175 mM Na⁺ and 0.7mM K⁺). Diphenylhydantoin (150 μM) decreased the enzyme activity at optimal Na⁺/K⁺ ratio, whereas 50 μM of the drug had no effect. The results suggest that D-glucose induces a net stimulation the Na⁺/K⁺ pump of β-cells in intact islets and that D-glucose does not exert any direct effect on the Na⁺/K⁺ ATPase activity.     

Genetic and fermentation properties of the K2 killer yeast, Saccharomyces cerevisiae T206

Saccharomyces cerevisiae T206 K⁺R⁺, a K₂ killer yeast, was differentiated from other NCYC killer strains of S. cerevisiae on the basis of CHEF-karyotyping and mycoviral RNA separations. Genomic DNA of strain T206 was resolved into 13 chromosome bands, ranging from approximately 0.2 to 2.2 Mb. The resident virus in strain T206 yielded L and M RNA species of approximately 5.1 kb and 2.0 kb, respectively. In micro-scale vinifications, strain T206 showed a lethal effect on a K^-R^- mesophilic wine yeast. Metabolite accumulation and toxin activity were measured over a narrow pH range of 3.2 to 3.5. Contrary to known fermentation trends, the challenged fermentations were neither stuck nor protracted although over 70% of the cell population was killed. Toxin-sensitive cells showed cytosolic efflux.     

Genetic characterisation of New Zealand and Australian wine yeasts

Twenty five culture wine yeast strains from New Zealand and Australia were examined for killer capability or sensitivity. Eight yeast strains were K ₂ ⁺ killers, six of the K ₂ ⁺ R ₁ ^- R ₃ ⁺ phenotype and two of the K ₂ ⁺ R ₁ ^- R ₃ ^- phenotype. The seventeen sensitive strains were separated into four phenotype classes. The homothallic life cycle was detected in twenty-one strains and one further strain is probably triploid.     

Cytoplasmic Inheritance of a Cell Surface Antigen in the Mouse

Mta is a cell surface antigen of the mouse and serves as a target for specific T killer lymphocytes. Using a killer cell assay, the antigen has been found in 72 strains of laboratory mice and, with one exception, in all tested samples of mice caught in the wild or bred from such, including Mus molossinus, Mus castaneus and Mus spretus. Five strains of rats, non-inbred NMRI mice, most substrains of NZB mice and the closely related strain NZO are negative for Mta. In reciprocal F₁ crosses between several Mta⁺ and two Mta^- strains, the antigen is maternally transmitted; that is, Mta⁺ females bear only positive offspring, whereas Mta^- females bear only negative offspring, regardless of the genotype of the male. Since 34 foster-nursed mice had the Mta type of their genetic mothers, the factor that determines expression of Mta must be transmitted before birth and not via the milk. The cytoplasmic genes of Mta⁺ strains have been combined with the chromosomal genes of Mta^- strains, and vice versa, by repeated backcrossing. All progeny retained the Mta type of their maternal lines. Thus, the Mta type is determined solely by maternal inheritance and is not influenced by chromosomal genes. We found no evidence of incompatibility between the cytoplasmic factors and nuclear genes of Mta^- and Mta ⁺ strains.     

Isolation and characterization of temperature-sensitive mak mutants of Saccharomyces cerevisiae.

The K1 killer plasmid of Saccharomyces cerevisiae is a 1.5-megadalton linear double-stranded ribonucleic acid molecule. Using simplified screening and complementation procedures, we have isolated mutants in three chromosomal genes that are temperature sensitive for killer plasmid maintenance or replication. One of these genes, mak28-1, was located on chromosome X. Two of the temperature-sensitive mutants rapidly lost the wild-type killer plasmid of A364A during spore germination and outgrowth at nonpermissive temperatures, but during vegetative growth, they only lowered the plasmid copy number. These two mutants did not lose two other wild-type K1 killer plasmids, indicating a heterogeneity of the killer plasmids in laboratory yeast strains.     

LAC4 Is the Structural Gene for β-Galactosidase in KLUYVEROMYCES LACTIS

Using genetic and biochemical techniques, we have determined that β-galactosidase in the yeast Kluyveromyces lactis is coded by the LAC4 locus. The following data support this conclusion: (1) mutations in this locus result in levels of β-galactosidase activity 100-fold lower than levels in uninduced wild type and all other lac^- mutants; (2) three of five lac4 mutations are suppressible by an unlinked suppressor whose phenotype suggests that it codes for a nonsense suppressor tRNA; (3) a Lac⁺ revertant, bearing lac4–14 and this unlinked suppressor, has subnormal levels of β-galactosidase activity, and the K_m for hydrolysis of o-nitrophenyl-β, D-galactoside and the thermal stability of the enzyme are altered; (4) the level of β-galactosidase activity per cell is directly proportional to the number of copies of LAC4; (5) analysis of cell-free extracts of strains bearing mutations in LAC4 by two-dimensional acryl-amide gel electrophoresis shows that strains bearing lac4–23 and lac4–30 contain an inactive β-galactosidase whose subunit co-electrophoreses with the wild-type subunit, while no subunit or fragment of the subunit is observable in lac4–8, lac4–14 or lac4–29 mutants; (6) of all lac4 mutants, only those bearing lac4–23 or lac4–30 contain a protein that cross-reacts with anti-β-galactosidase antibody, a finding consistent with the previous result; and (7) β-galactosidase activity in several Lac⁺ revertants of strains carrying lac4–23 or lac4–30 has greatly decreased thermostability.     

Natural and synthetic diastereoisomeric (?)-3′,4′,7-trihydroxyflavan-3,4-diols

1. Rhodesian copalwood (Guibourtia coleosperma) contains three diastereo-isomeric leuco-fisetinidins. These consist of the (−)-2,3-cis–3,4-cis (2R,3R,4R) and (−)-2,3-cis–3,4-trans (2R,3R,4S) 3′,4′,7-trihydroxyflavan-3,4-diols, and the third was shown to be a 2,3-trans–3,4-cis isomer by means of paper ionophoresis. 2. There occurrence in similar proportions as tannin precursors also in the tropical hardwoods G. tessmannii and G. demeusii implies a close taxonomic relationship between these, and with G. coleosperma. 3. Epimerization of the natural (−)-3′,4′,7- trihydroxy-2,3-trans-flavan-3,4-trans-diol affords a mixture from which the (−)-2,3-cis–3,4-cis isomer was separated readily, but the (−)-2,3-trans–3,4-cis isomer was obtained with difficulty. These were formed by epimerization of the (−)-2,3-trans–3,4-trans isomer at C-2 and C-4, and at C-4, respectively.     

Poleta, Polzeta and Rev1 together are required for G to T transversion mutations induced by the (+)- and (-)-trans-anti-BPDE-N2-dG DNA adducts in yeast cells

Benzo[a]pyrene is an important environmental mutagen and carcinogen. Its metabolism in cells yields the mutagenic, key ultimate carcinogen 7R,8S,9S,10R-anti-benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide, (+)-anti-BPDE, which reacts via its 10-position with N²-dG in DNA to form the adduct (+)-trans-anti-BPDE-N²-dG. To gain molecular insights into BPDE-induced mutagenesis, we examined in vivo translesion synthesis and mutagenesis in yeast cells of a site-specific 10S (+)-trans-anti-BPDE-N²-dG adduct and the stereoisomeric 10R (−)-trans-anti-BPDE-N²-dG adduct. In wild-type cells, bypass products consisted of 76% C, 14% A and 7% G insertions opposite (+)-trans-anti-BPDE-N²-dG; and 89% C, 4% A and 4% G insertions opposite (−)-trans-anti-BPDE-N²-dG. Translesion synthesis was reduced by ~26–37% in rad30 mutant cells lacking Polη, but more deficient in rev1 and almost totally deficient in rev3 (lacking Polζ) mutants. C insertion opposite the lesion was reduced by ~24–33% in rad30 mutant cells, further reduced in rev1 mutant, and mostly disappeared in the rev3 mutant strain. The insertion of A was largely abolished in cells lacking either Polη, Polζ or Rev1. The insertion of G was not detected in either rev1 or rev3 mutant cells. The rad30 rev3 double mutant exhibited a similar phenotype as the single rev3 mutant with respect to translesion synthesis and mutagenesis. These results show that while the Polζ pathway is generally required for translesion synthesis and mutagenesis of the (+)- and (−)-trans-anti-BPDE-N²-dG DNA adducts, Polη, Polζ and Rev1 together are required for G→T transversion mutations, a major type of mutagenesis induced by these lesions. Based on biochemical and genetic results, we present mechanistic models of translesion synthesis of these two DNA adducts, involving both the one-polymerase one-step and two-polymerase two-step models.     

Rescue of Na+ Affinity in Aspartate 928 Mutants of Na+,K+-ATPase by Secondary Mutation of Glutamate 314

The Na⁺,K⁺-ATPase binds Na⁺ at three transport sites denoted I, II, and III, of which site III is Na⁺-specific and suggested to be the first occupied in the cooperative binding process activating phosphorylation from ATP. Here we demonstrate that the asparagine substitution of the aspartate associated with site III found in patients with rapid-onset dystonia parkinsonism or alternating hemiplegia of childhood causes a dramatic reduction of Na⁺ affinity in the α1-, α2-, and α3-isoforms of Na⁺,K⁺-ATPase, whereas other substitutions of this aspartate are much less disruptive. This is likely due to interference by the amide function of the asparagine side chain with Na⁺-coordinating residues in site III. Remarkably, the Na⁺ affinity of site III aspartate to asparagine and alanine mutants is rescued by second-site mutation of a glutamate in the extracellular part of the fourth transmembrane helix, distant to site III. This gain-of-function mutation works without recovery of the lost cooperativity and selectivity of Na⁺ binding and does not affect the E₁-E₂ conformational equilibrium or the maximum phosphorylation rate. Hence, the rescue of Na⁺ affinity is likely intrinsic to the Na⁺ binding pocket, and the underlying mechanism could be a tightening of Na⁺ binding at Na⁺ site II, possibly via movement of transmembrane helix four. The second-site mutation also improves Na⁺,K⁺ pump function in intact cells. Rescue of Na⁺ affinity and Na⁺ and K⁺ transport by second-site mutation is unique in the history of Na⁺,K⁺-ATPase and points to new possibilities for treatment of neurological patients carrying Na⁺,K⁺-ATPase mutations.