Extrachromosomal oligomycin-resistant mutants of the petite-negative yeast Kluyveromyces lactis. Properties of mitochondrial ATPase and cross-resistance to inhibitors of phosphoryl transfer reactions

Summary The mitochondrial ATPase from oligomycin-resistant mutants which map on different regions of an extrachromosomal DNA (01 and 011 class mutants) showed an increased resistance to oligomycin and venturicidin when assayed in vitro as compared to the sensitive strains.The resistance to oligomycin of the isolated mitochondrial ATPase from 01 class mutants was higher than that of the 011 class mutants.Cross resistance of the oligomycin-resistant mutants to the antibiotics peliomycin and ossamycin, which also inhibit phosphoryl transfer reactions in mitochondria (Walter et al., 1967), was observed, 01 mutants being more resistant to ossamycin than 011 class mutants. At the concentrations of peliomycin studied, no difference in sensitivity among both groups of oligomycin-resistant mutants could be detected.Mitochondrial respiration and isolated mitochondrial ATPase activity are sensitive to venturicidin, suggesting that the previously observed (Brunner et al., 1977) in vivo venturicidin resistance of K. lactis is probably due to an impairment of the influx of the drug at the level of the plasma membrane.     

Amino acid substitutions in mitochondrial ATPase subunit 9 of Saccharomyces cerevisiae leading to oligomycin or venturicidin resistance

A series of isonuclear oligomycin-resistant mutants of Saccharomyces cerevisiae carrying mutations in the mitochondrial oli1 gene has been studied. DNA sequence analysis of this gene has been used to define the amino acid substitutions in subunit 9 of the mitochondrial ATPase complex. A domain of amino acids involved in oligomycin resistance can be recognized which encompasses residues in each of the two hydrophobic portions of the subunit 9 polypeptide that are thought to span the inner mitochondrial membrane. Certain amino acid substitutions also confer cross-resistance to venturicidin: these residues define an inner domain for venturicidin resistance. The expression of venturicidin resistance resulting from one particular substitution is modulated by nuclear genetic factors.     

Genetic Analysis of Multiple Drug Cross Resistance in SACCHAROMYCES CEREVISIAE: a Nuclear-Mitochondrial Gene Interaction

A mutant of the yeast Saccharomyces cerevisiae, cross resistant to several antibiotics, was isolated in our laboratory and subjected to genetic analysis. Tetrad analysis of diploids obtained from crosses between the resistant mutant and a sensitive wild-type strain suggest that the multiple resistance to the five agents, oligomycin (OLI), rhodamine 6G (RHG), tetracycline (TCN), chloramphenicol (CAP) and cycloheximide (CHX) is determined by a single nuclear gene, ant1, and requires several cytoplasmic genes for expression of resistance to oligomycin, rhodamine 6G and tetracycline. --Vegetatively growing diploid clones derived from the cross ant1 [RHO+] X +[RHO+] show mitotic segregation of two phenotypic classes for the drugs OLI, RHG TCN. Diploids derived from the two reciprocal crosses, ant1 [RHO+] X +[RHO-] and ant1 [RHO-] X +[RHO+], fail to exhibit mitotic segregation. These results are consistent with our hypothesis concerning the involvement of cytoplasmic loci. They suggest, in addition, that these loci are associated with mitochondrial DNA (mtDNA). --Evidence for this association is provided by the demonstration of genetic linkage between the cytoplasmic loci involved in the interaction, RHG-1, TCN-1 and OLI-5, and two well-characterized mitochondrial loci, ERY and CAP. --We have mapped the nuclear ant1 locus 3.3 cM from the centromere-linked gene, leu1, on the same side of the centromere of chromosome VII as leu1. --In the light of these findings, we discuss the claims made by several authors of the episomal nature of mutations similar to the one described here, as well as of the possible involvement of yeast 2 mu DNA in such mutations.     

Genetics of the mammalian oxidative phosphorylation system: characterization of a new oligomycin-resistant Chinese hamster ovary cell line.

The properties of a new type of oligomycin-resistant Chinese hamster ovary (CHO) cell line (Olir 2.2) are described in this paper. Olir 2.2 cells were approximately 50,000-fold more resistant to oligomycin than were wild-type CHO cells when tested in glucose-containing medium, but only 10- to 100-fold more resistant when tested in galactose-containing medium. Olir 2.2 cells grew with a doubling time similar to that of wild-type cells both in the presence or absence of oligomycin. Oligomycin resistance in Olir 2.2 cells was stable in the absence of drug. In vitro assays indicated that there was approximately a 25-fold increase in the resistance of the mitochondrial ATPase to inhibition by oligomycin in Olir 2.2 cells, with little change in the total ATPase activity. The electron transport chain was shown to be functional in Olir 2.2 cells. Olir 2.2 cells were cross-resistant to other inhibitors of the mitochondrial ATPase (such as rutamycin, ossamycin, peliomycin, venturicidin, leucinostatin, and efrapeptin) and to other inhibitors of mitochondrial functions (such as chloramphenicol, rotenone, and antimycin). Oligomycin resistance was expressed codominantly in hybrids between Olir 2.2 cells and wild-type cells. Cross-resistance to ossamycin, peliomycin, chloramphenicol, antimycin, venturicidin, leucinostatin, and efrapeptin was also expressed codominantly in hybrids. Fusions of enucleated Olir 2.2 cells with wild-type cells and characterization of the resulting cybrid clones indicated that resistance to oligomycin and ossamycin results from a mutation in both a nuclear gene and a cytoplasmic gene. Cross-resistance to efrapeptin, leucinostatin, venturicidin, and antimycin results from a mutation in only a nuclear gene.     

Oligomycin-resistant mitochondrial ATPase from mouse fibroblasts.

Fourteen oligomycin-resistant LM(TK-) clones were isolated following the mutagenesis of minicells. In the absence of oligomycin, the mutants grew with population doubling times similar to that of the wild type (1 day). In 3 or 5 microgram oligomycin/ml the doubling times of the mutants were 1.2-2.5 days. Both stable and unstable classes were represented among the oligomycin-resistant mutants. Mitochondrial ATPase activities of the mutants were 1.3-1130 times more resistant to oligomycin than the wild type. The mitochondrial ATPase of OLI 14 was found to be bound firmly to the mitochondrial membrane, showed no alteration in the pH optimum compared to wild-type, and exhibited increased resistance to DCCD and venturicidin. These results are consistent with the conclusion that oligomycin resistance in these mutants results from altered mitochondrial ATPase.     

Nuclear-extranuclear interactions affecting oligomycin resistance in Aspergillus nidulans.

Summary The extranuclear mitochondrial oligomycin-resistant mutation ofAspergillus nidulans, (oliA1), was transferred asexually into four nuclear oligomycin-resistant strains of different phenotypes. In all four cases, the possession of the nuclear plus extranuclear mutation led to an increase in the in vivo level of oligomycin resistance. In two cases, the altered cytochrome spectrum and impaired growth ability determined by (oliA1) were suppressed by the nuclear mutations. In the third case, the in vitro oligomycin resistance of the double mutant ATPase was dramatically increased above that of either of the component single mutant strains, indicating a synergystic interaction between the nuclear and extranuclear gene products. In the fourth case, the double mutant became cold-sensitive.A new extranuclear mitochondrial oligomycin-resistant mutation (oliB332) is described. This mutant is phenotypically similar to, though not identical with, (oliA1) but is separable by recombination.A range of nuclear oligomycin-resistant mutants have been mapped. Despite presenting five distinctly different phenotypes, they all map at the same locus.     

Modification and Inheritance of Pleiotropic Cross Resistance and Collateral Sensitivity in SACCHAROMYCES CEREVISIAE

A meiotic segregant (oli^PR1) was isolated with a phenotype of multiple cross resistance and collateral sensitivity. Strain oli^PR1 has increased sensitivity to ethidium bromide, dequalinium chloride, acriflavin, paromomycin and neomycin, and increased resistance to oligomycin, rutamycin, venturicidin, triethyltin bromide, antimycin, carbonylcynamide-m-chlorophenylhydrazone, tetra-N-butylammonium bromide, dibenzyldimethylammonium chloride, triphenylmethylphosphonium bromide, chloramphenicol, carbomycin, tetracycline, triton-X-165 and cycloheximide. Single gene inheritance of the cross resistance and collateral sensitivity was shown by 2:2 parental ditype segregation and reversion of the complete phenotype by a spontaneous revertant. The locus conferring the oli^PR1 phenotype was mapped 11.7 units from an unspecified centromere. Antibiotic resistance showed incomplete dominance, with the level of hybrid resistance dependent upon the inhibitor tested. Resistant diploids that produced four resistant ascospores were the result of mitotic recombination prior to meiosis. A partial revertant phenotype (sensitive to all inhibitors except oligomycin, antimycin and carbonylcyanide-m-chlorophenylhydrazone) was shown to be due to a single nuclear gene causing partial suppression of oli^PR1. Anaerobic pretreatment, 37° and 0.5 M KCl were observed to reduce the growth of oli^PR1 when challenged with seven diverse inhibitors (antimycin, carbonylcyanide-m-chlorophenylhydrazone,-chloramphenicol, cycloheximide, oligomycin, triethyltin bromide, and triphenylmethylphosphonium bromide). Resistance to cycloheximide was not altered by the [rho—] state. A revertant of oli^PR1 (sensitive to the above inhibitors but resistant to ethidium bromide, paromycin and neomycin) showed anaerobic and temperature sensitization to ethidium bromide, paromomycin and neomycin. Continuous monitoring of oxygen uptake by the revertant after anaerobic pretreatment revealed that anaerobiosis sensitized respiratory adaptation of the revertant to neomycin. It is proposed that oli^PR1 is a mutation resulting in the alteration of plasma membrane premeability to many diverse inhibitors.     

A cytoplasmic gene for partial suppression of a nuclear pleiotropic respiratory deficient mutant in the petite negative yeast Schizosaccharomyces pombe

Summary The nuclear pleiotropic respiratory-deficient mutant pet1 (previously M126) exhibits cytochromes aa₃ and b deficiencies accompanied by loss of the oligomycin-sensitivity of the mitochondrial ATPase. The mutant pet1, unable to grow on glycerol, exhibits in addition sensitivity of Antimycin A of the growth on glucose. The latter phenotypic trait symbolized by ANA^S-D, exhibits a high frequency (2 to 4×10^-5) of spontaneous suppression into Antimycin A-resistant strains. Mutagenesis with MnCl₂ increases by a factor of 10² the frequency of ANA^R-D derivatives. This suppression is partial since none of the suppressed strains is able to grow on glycerol even when respiratory functions and cytochromes activities are restored as in the pet1 [SUP2] strain. In the latter strain it is concluded that the extralocus suppressor gene [SUP2] is responsible for the ANA^R-D trait. Tetrad analysis in a cross homozygous for pet1 demonstrates a non-Mendelian segregation pattern for the SUP2 suppressor gene. In stable diploids, homozygous for pet1, the [SUP2] suppressor exhibits a mitotic segregation pattern. Furthermore the transmission of the [SUP2] gene is decreased by ethidium bromide treatment. Therefore, the [SUP2] suppressor gene responsible for partial suppression of the nuclear pleiotropic phenotype in mutant pet1 is of cytoplasmic heredity.     

Extra-chromosomal inheritance of rhodamine 6G resistance in Saccharomyces cerevisiae.

Summary Rhodamine 6G was found to be a specific inhibitor of aerobic growth of yeast, having no effect on fermentative growth. A single step spontaneous mutant of S. cerevisiae resistant to rhodamine 6G was isolated, which showed cross-resistance to the ATPase inhibitors venturicidin and triethyltin, to the uncoupler 1799, to bongkrekic acid and to cycloheximide, but not to oligomycin or to the inhibitors of mitochondrial protein synthesis, chloramphenicol and erythromycin. The genetic analysis of this mutant showed that both nuclear and cytoplasmic (but apparently not mitochondrial) factors may be involved in the determination of the mutation. The behaviour is discussed as a possible function for 2 micron circular (omicron) DNA.     

Increased Spontaneous Mitotic Segregation in Mms-Sensitive Mutants of SACCHAROMYCES CEREVISIAE

Methyl methanesulfonate (MMS)-sensitive mutants of Saccharomyces cerevisiae belonging to four different complementation groups, when homozygous, increase the rate of spontaneous mitotic segregation to canavanine resistance from heterozygous sensitive (canr/+) diploids by 13-to 170-fold. The mms8-1 mutant is MMS and X-ray sensitive and increases the rate of spontaneous mitotic segregation 170-fold. The mms9-1 and mms13-1 mutants are sensitive to X rays and UV, respectively, in addition of MMS, and increase the rate of spontaneous mitotic segregation by 13-fold and 85-fold, respectively. The mutant mms21-1 is sensitive to MMS, X rays and UV and increases the rate of spontaneous mitotic segregation 23-fold.     

Nuclear mutations conferring oligomycin resistance in Neurospora crassa.

Mutants of Neurospora crassa have been isolated that are highly resistant to inhibition by oligomycin, an inhibitor of mitochondrial ATPase activity. Dixon plots (Dixon, M., and Webb, E.C. (1964) Enzymes, 2nd Ed, pp. 328-330, Academic Press, New York) of oligomycin inhibition curves of the parent strain and the resistant mutants are linear, indicating that oligomycin interacts at a single site within the ATPase complex. The Ki values obtained from the mutants vary from 150 to 900 times greater than the Ki obtained for the parent strain. The parent strain and the oligomycin-resistant mutants are also inhibited by bathophenanthroline, a lipophilic chelating agent that inhibits F1 ATPase activity. Dixon plots of bathophenanthroline inhibition curves are also linear and Ki values obtained are all approximately equal. Crosses of the oligomycin-resistant mutants to the oligomycin-sensitive parent strain show a mendelian segregation of the resistance characteristic. These data show that mutations leading to oligomycin resistance in Neurospora are due to alterations in nuclear genes.     

DNA sequence analysis of the oli1 gene reveals amino acid changes in mitochondrial ATPase subunit 9 from oligomycin-resistant mutants of Saccharomyces cerevisiae

The nucleotide sequence of the oli1 gene encoding mitochondrial ATPase subunit 9 (76 amino acids) has been determined for five oligomycin-resistant mutants of Saccharomyces cerevisiae. Three of the mutations affect amino acids in the vicinity of the glutamic acid residue 59 at which dicylohexyl carbodiimide binds. Two other mutations lead to substitution of amino acid 23, which would lie very close to residue 59 in the folded hairpin conformation that this protein is thought to adopt in the inner mitochondrial membrane. The apposition of residues 23 and those adjacent to residue 59, lying respectively in the two hydrophobic membrane-spanning arms of subunit 9, is considered to constitute an oligomycin-binding domain. By consideration of the amino acid substitutions in those mutants cross-resistant to venturicidin, a domain of resistance for venturicidin is defined to lie within the oligomycin-binding domain, also centered on residues 23 and 59. These data also clarify the genetic recombination behaviour of alleles previously defined to form part of the oli3 locus (mutants characterized by resistance to both oligomycin and venturicidin) together with alleles defined to form part of the oli1 locus (mutants not cross-resistant to venturicidin). The oli1 and oli3 loci can now be seen to form two overlapping extended groups within the oli1 gene, with sequenced oli3 mutations being as far apart as 125 nucleotides within the subunit 9 coding region of 231 nucleotides.     

Single nuclear gene inherited cross resistance and collateral sensitivity to 17 inhibitors of mitochondrial function in S. cerevisiae

Summary Previous tetrad analyses defined a yeast strain (332-7c) as containing a single nuclear gene (11.8 map units from the centromere) conferring resistance to oligomycin. Resistance to 18 additional inhibitors of mitochondrial function (Table 1) was determined on (i) ascospore isolates from tetrads segregating 2 resistant: 2 sensitive for oligomycin (Table 2) and (ii), spontaneously derived sensitive isolates of the oligomycin resistant strain (Tables 3 and 4). The observed pattern of resistance suggests that the gene for resistance to oligomycin also results in (i) cross resistance to rutamycin, venturicidin, triethyltin bromide, antimycin A, carbonylcyanide m-chlorophenylhydrazone, tetra-N-butylammonium bromide, dibenzyl-dimethylammonium chlorop and tetracycline and (ii), collateral sensitivity to paromomycin, neomycin, dequalinium chloride, ethidium bromide and acriflavin.     

Genetic control of mitotic crossing-over in yeasts. III. Induction by 8-methoxypsoralen and long-wave UV irradiation (lambda=365 nm)

The lethal effect of 8-methoxypsoralen (8-MOP) plus 365 nm light has been studied in haploid radiosensitive strains of Saccharomyces cerevisiae. The diploid of wild type and the diploid homozygous for the rad2 mutation (this mutation blocks the excision of UV-induced pyrimidine dimers) were more resistant to the lethal effect of 8-MOP plus 365 nm light than the haploid of wild type and rad2 haploid, respectively. The diploid homozygous for rad54 mutation (the mutation blocks the repair of double-strand breaks in DNA) was more sensitive than haploid rad54. The method of repeated irradiation allowed to study the capacity of radiosensitive diploids to remove monoadducts induced by 8-MOP in DNA. This process was very effective in diploids of wild type and in the rad54 rad54 diploid, while the rad2 rad2 diploid was characterized by nearly complete absence of monoadduct excision. The study of mitotic crossing over and mitotic segregation in yeast diploids, containing a pair of complementing alleles of the ade2 gene (red/pink) has shown a very high recombinogenic effect of 8-MOP plus 365 nm light. The rad2 mutation slightly increased the frequency of mitotic segregation and mitotic crossing over. The rad54 mutation decreased the frequency of mitotic segregation and entirely suppressed mitotic crossing over. The method of repeated irradiation showed that the cross-links, but not monoadducts, are the main cause of high recombinogenic effect of 8-MOP plus 365 nm light. The possible participation of different repair systems in recombinational processes induced by 8-MOP in yeast cells is discussed.     

Nuclear and extranuclear inheritance of oligomycin resistance in Aspergillus nidulans

Summary A number of spontaneously-occurring, stable oligomycin-resistant mutants have been isolated in Aspergillus nidulans. Genetic characterisation showed that while most of the mutants examined were nuclear, one mutant was extranuclear as judged by several criteria. While the nuclear mutants showed no abnormalities on drug-free medium, the extranuclear mutant exhibited impaired growth ability. This character never segregated from the oligomycin-resistance character in any of the genetic experiments carried out, and appeared to be a secondary effect of the same mutation. The extranuclear genetic element coding for the oligomycin-resistance character was unable to co-exist in a stable fashion within the same mycelium as the wild type element, and they tended to segregate into sectors consisting almost wholly of one type or the other. The nuclear mutants showed incomplete dominance in heterozygous diploids, segregating fully resistant homozygous areas. All nuclear mutants mapped on linkage group VII.     

Studies on energy-linked reactions: isolation, characterisation and genetic analysis of trialkyl-tin-resistant mutants of Saccharomyces cerevisiae.

Mutants of Saccharomyces cerevisiae resistant to triethyl tin sulphate have been isolated and are cross-resistant to other trialkyl tin salts. Triethyl-tin-resistant mutants fall into two general phenotypic classes: class 1 and class 2. Class 1 mutants are cross-resistant to a variety of inhibitors and uncoupling agents which affect mitochondrial membranes (oligomycin, ossamycin, valinomycin, antimycin, erythromycin, chloramphenicol, '1799', tetrachlorotrifluoromethyl benzimidazole carbonylcyanide-m-chlorophenylhydrazone and cycloheximide). Class 2 mutants are specifically resistant to trithyl tin and the uncoupling agent "1799' [bis-(hexafluoroacetonyl)-acetone]. Triethyl tin at neutral pH values is a specific inhibitor of mitochondrial energy conservation reactions and prevents growth on oxidisable substrates such as glycerol and ethanol. Triethyl-tin-resistant mutants grow normally on glucose and ethanol in the presence of triethyl tin (10 muM). Biochemical studies indicate that the mutation involves a modification of the triethyl tin binding site on the mitochondrial inner membrane, probably the ATP-synthetase complex. Triethyl tin resistance/sensitivity in yeast is determined by cytoplasmic (mitochondrial) and nuclear genes. The mutants fall into a nuclear and a cytoplasmic (mitochondrial) class corresponding to the phenotypic cross-resistance classes 1 and 2. In the cytoplasmic mutants the triethyl tin resistance segregates mitotically and the resistance determinat is deleted by the action of ethidium bromide during petite induction. Recombination studies indicate that the triethyl tin mutations are not allelic with the other mitochondrial mutations at the loci RI, RIII and OLI. This indicates that the binding or inhibitory sites of oligomycin and triethyl tin are not identical and that the triethyl tin binding site is located on a different mitochondrial gene product to those which are involved in oligomycin binding. Interaction and cooperative effects between different binding sites on the mitochondrial inner membrane have been demonstrated in studies of the effect of the insertion of the TETr phenotype into mitochondrial oligomycin-resistant mutants and provide an experimental basis for complementation studies at the ATP-synthetase level.     

Studies on energy-linked reactions: isolation and properties of mitochondrial venturicidin-resistant mutants of Saccharomyces cerevisiae.

Venturicidin is a specific inhibitor of aerobic growth of yeast and has no effect on fermentative growth, a result which is consistent with its known mode of action on mitochondrial oxidative phosphorylation. Venturicidin-resistant mutants of Saccharomyces cerevisiae have been isolated and form two general classes: class 1, nuclear mutants which are resistant to a variety of mitochondrial inhibitors and uncouplers, and class 2, mitochondrial mutants of phenotype VENR OLYR and VENR TETR in vivo. VENR OLYR mutants show a high degree of resistance to venturicidin and oligomycin at the whole cell and mitochondrial ATPase level but, in contrast, no resistance at the mitochondrial level is observed with VENR TETR mutants. Venturicidin resistance/sensitivity can be correlated with two binding sites on mitochondrial ATPase, one of which is common to the oligomycin binding site and the other is common to the triethyl tin binding site. Biochemical genetic studies indicate that two mitochondrial genes specify venturicidin resistance/sensitivity and that the mitochondrial gene products are components of the mitochondrial ATPase complex.     

Diverse effects of beta-tubulin mutations on microtubule formation and function

We have used in vitro mutagenesis and gene replacement to construct five new cold-sensitive mutations in TUB2, the sole gene encoding beta-tubulin in the yeast Saccharomyces cerevisiae. These and one previously isolated tub2 mutant display diverse phenotypes that have allowed us to define the functions of yeast microtubules in vivo. At the restrictive temperature, all of the tub2 mutations inhibit chromosome segregation and block the mitotic cell cycle. However, different microtubule arrays are present in these arrested cells depending on the tub2 allele. One mutant (tub2-401) contains no detectable microtubules, two (tub2-403 and tub2-405) contain greatly diminished levels of both nuclear and cytoplasmic microtubules, one (tub2-104) contains predominantly nuclear microtubules, one (tub2-402) contains predominantly cytoplasmic microtubules, and one (tub2-404) contains prominent nuclear and cytoplasmic microtubule arrays. Using these mutants we demonstrate here that cytoplasmic microtubules are necessary for nuclear migration during the mitotic cell cycle and for nuclear migration and fusion during conjugation; only those mutants that possess cytoplasmic microtubules are able to perform these functions. We also show that microtubules are not required for secretory vesicle transport in yeast; bud growth and invertase secretion occur in cells which contain no microtubules.     

Modification of chromosome instability in Aspergillus nidulans

Strains of Aspergillus nidulans with a chromosome segment in duplicate show instability at mitosis; their colonies produce faster-growing sectors which arise from nuclei with spontaneous deletions in either duplicate segment. In an attempt to probe the deletion process, the effects of mutations causing sensitivity to UV treatment, and those of manganous ions, have been studied in strains carrying either Dp(I,II) or Dp(III,VIII). For comparison, the effects of Mn2+ on balanced and unbalanced diploids have also been examined. The uvsE allele, which decreases intragenic mitotic crossing over in diploids, increased deletion frequency in strains with either duplication. The uvsB allele, which increases intragenic mitotic crossing over in diploids, increased deletion frequency only in Dp(I,II) strains; in addition, by causing early mitotic crossing over between the homologous segments, it produced some novel deletion products. Mn2+ substantially decreased the deletion frequency in Dp(I,II) strains and decreased mitotic crossing over in diploids; it had no effect on Dp(III,VIII) strains. The results suggest that in haploid duplication strains there are two classes of spontaneous DNA lesions, recombinogenic and non-recombinogenic, both of which, failing repair, lead to deletion.     

Mutations in the ATP-binding domain affect the subcellular distribution of mitotic centromere-associated kinesin (MCAK)

Mitotic centromere-associated kinesin (MCAK) is important for anaphase chromosome segregation. MCAK is diffusely localized to both the cytoplasm and the nucleus during interphase. At prophase MCAK is recruited to mitotic centromeres. It is associated with centromeres throughout mitosis and then returns to exhibiting a diffuse nuclear and cytoplasmic localization during interphase. MCAK has several predicted nuclear localization sequences. The subcellular distribution of expressed deletion constructs of GFP-MCAK suggest that the nucleocytoplasmic ratio of MCAK protein is dependent on a balance between several predicted nuclear localization sequences (NLS) and a putative nuclear exclusion sequence (NES) in the amino-terminal region of MCAK. Amino acid substitutions in the ATP-binding domain of the MCAK motor affect nuclear localization, which, in turn, influences the degree of centromere binding.