©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Characterization of a Nuclear Protein Conferring Brefeldin A Resistance in Schizosaccharomyces pombe(*)

(Received for publication, October 20, 1995; and in revised form, January 3, 1996)

Thomas G. Turi (1)(§) Ulrich W. Mueller (2) Shelley Sazer (2) John K. Rose (1)

From the  (1)Departments of Cell Biology and Pathology, Yale University School of Medicine, New Haven, Connecticut 06510 and the (2)Verna and Marrs McLean Department of Biochemistry, Baylor College of Medicine, Houston, Texas 77030

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

The fungal metabolite brefeldin A disrupts protein secretion and causes the redistribution of the Golgi complex to the endoplasmic reticulum. Previously we isolated six genes that, when present in multiple copies, confer brefeldin A resistance to wild type Schizosaccharomyces pombe. Here we describe the characterization of one of these genes, hba1. This gene encodes an essential protein that shares homology with the mammalian protein RanBP1 and the protein encoded by the Saccharomyces cerevisiae gene YRB1 and contains a peptide motif present in several proteins found within the nuclear pore complex. The protein encoded by hba1 is localized to the nucleus, and it was determined that this protein is phosphorylated in vivo. The characterization of hba1 thus demonstrates a novel mechanism of drug resistance in S. pombe.


INTRODUCTION

A number of pharmacological agents have been used as probes to examine the processes and mechanisms responsible for intracellular protein transport and secretion. One of these compounds, brefeldin A (BFA), (^1)has been used extensively to investigate the underlying mechanisms of both protein transport and also maintenance of intracellular organelles. Addition of BFA to cultured cells results in the rapid inhibition of protein secretion and the redistribution of Golgi proteins and membranes into the endoplasmic reticulum (Lippincott-Schwartz et al., 1989; Doms et al., 1989; Fujiwara et al., 1988). BFA is thought to exert its effects on protein transport and Golgi structure by inhibiting the GDP to GTP exchange on ADP-ribosylation factor (ARF) found on Golgi membranes (Donaldson et al., 1992; Helms and Rothman, 1992). However, more recent data using partially purified ARF guanine nucleotide exchange factor demonstrated that BFA did not inhibit the GDP-GTP exchange reaction (Tsai et al., 1994). Therefore, it is unclear whether the nucleotide exchange on ARF is effected by BFA directly.

We have utilized the fission yeast Schizosaccharomyces pombe in order to identify the target molecule of BFA as well as other proteins capable of conferring BFA resistance. Our previous work has demonstrated that wild type S. pombe is sensitive to the effects of BFA in an analogous manner to that seen in mammalian cells, i.e. inhibition of protein secretion and the disassembly and redistribution of the Golgi complex (Turi et al., 1994). Mutant S. pombe strains that are resistant to BFA were isolated, characterized and found to contain a mutation in either crm1, a gene required for maintaining chromosomal structure, or a second locus termed bar2. In addition, six genes that confer resistance to BFA when present in high copy were also identified (Turi et al., 1994). One of these six genes encoded a homologue of the mammalian transcription factor AP1 termed pap1, while yet another of the six genes encoded a novel multidrug resistance transporter (Turi and Rose, 1995). Here we describe a third gene conferring BFA resistance. The protein encoded by this gene is an essential nuclear phosphoprotein that contains a conserved sequence motif present in proteins that interact with a nuclear GTP-binding protein known as Ran in mammalian cells, or Spi1 and GSP1 in fission and budding yeast, respectively.


MATERIALS AND METHODS

Media, Yeast Strains, and Genetic Methods

S. pombe strain FWP1 (hura4) was grown in YES or in EMM (Mitchinson, 1970). The antibiotic brefeldin A was purchased from Sigma and dissolved in ethanol at a concentration of 10 mg/ml. For genetic analysis, standard methods were followed. S. pombe was transformed by the lithium acetate method (Okazaki et al., 1991).

Restriction Mapping and Subcloning of the hba1 Gene

For restriction mapping, plasmid pBAR2-1 was digested with HindIII, EcoRI, BglII, or pairwise combinations of these enzymes. The DNA restriction fragments were separated on a 1% agarose gel and processed for Southern analysis. The resulting filters were probed with restriction fragments derived from the pBAR2-1 insert that had been radiolabeled via random primer labeling (Feinberg and Vogelstein, 1983).

The hba1 gene on plasmid pBAR2-1 was localized by subcloning restriction fragments corresponding to the insert into plasmid pFL20 (Losson and Lacroute, 1983). Recombinant plasmids were used to transform wild type S. pombe and BFA resistance examined using a growth or a secretion assay previously described (Turi et al., 1994). Plasmid pBAR2-1H contained a 4.2-kb HindIII fragment that conferred BFA resistance in both assays. To further map the hba1 gene, a 2.7-kb HindIII-EcoRI subfragment of the pBAR2-1 insert was cloned into pFL20 and assayed for BFA resistance.

DNA Sequence Analysis

The nucleotide sequence of the entire 4.2-kb insert of pBAR2-1H was determined using the dideoxy chain termination method using a modified T7 DNA polymerase (Sequenase, U. S. Biochemical Corp.) and synthetic oligonucleotide primers. Additional synthetic oligonuclotide primers were used to extend the sequence of the adjacent open reading frame present within pBAR2-1H. For these sequencing reactions, the original pBAR2-1 plasmid was used as a template. The sequences were assembled and analyzed using Lasergene software (DNAStar, Madison, WI). The hba1 gene present on plasmid pBAR1-2 (Turi et al., 1994) was sequenced utilizing the synthetic primers synthesized for analysis of pBAR2-1H. DNA and protein homology searches were conducted on the EMBL and GenBank data bases.

Epitope Tagging

The DNA sequence encoding the human c-Myc epitope was appended onto the 3` terminus of the hba1 gene by the polymerase chain reaction using plasmid pBAR2-1H as a template. To facilitate cloning, a SmaI restriction site was incorporated upstream of the hba1 start site using the primers ATGCCCCGGGATAATGACCAGCAAAATGGAAAATAAT and CGATGCACGGCATCATTTCTCATC. The c-Myc epitope was introduced onto the 3` terminus with primers GAGCGTTAAGGATAGCCCATTTA and GATCGGATCCTCACAAGTCTTCTTCAGAAATAAGCTTTTGTTCTGCATCTTCTCTTCCACCCTTAGGAAT. The first PCR product was digested with SmaI and PstI and the second PCR product was digested with PstI and BamHI. The two fragments were ligated into pREP4 (Maundrell, 1990) that had been digested with MscI and BamHI. The resulting fusion was confirmed by DNA sequence analysis.

The wild type hba1 gene was also cloned into pREP4 using the 5` PCR product described above digested with SmaI and PstI and mixed with a PstI to EcoRI (made blunt with Klenow fragment of DNA polymerase) restriction fragment of pBAR2-1H containing the 3` half of the hba1 gene. These two fragments were then ligated into the MscI site of pREP4.

Metabolic Labeling and Immunoprecipitation

Cultures were grown for 18 h in EMMP containing 1 mM phosphate (Moreno et al., 1991). The overnight culture were diluted in 35 ml of fresh medium to a density of 1 times 10^6 cells/ml and allowed to grow to a density of 5 times 10^6 cells/ml. The cells were harvested by centrifugation and resuspended in 2 ml of EMMP containing 50 µM phosphate and 1.5 mCi of [P]H(3)PO(4). The cultures were labeled for 3 h at 30 °C.

For immunoprecipitation, the labeled cells were disrupted with glass beads in detergent lysis buffer (Rose and Bergmann, 1983) and immunoprecipitates produced using 100 µl of conditioned medium from 9E10 hybridoma (Evans et al., 1985) followed by 1 µl of a rabbit anti-mouse polyclonal antiserum and fixed Staphylococcus aureus. The immune complexes were washed five times with RIPA (Rose and Bergmann, 1983), one time with 50 mM Tris-HCl, pH 8.0, and one time with Tris containing 100 µg/ml RNase. The samples were subjected to electrophoresis on a 10% polyacrylamide-SDS gel. The gel was soaked in water containing 10 mM ATP for 10 min, dried, and exposed to film.

Indirect Immunofluorescence

Wild type cells containing pREP4, pREP4-hba1, or pREP4-hba1-Myc were grown overnight in EMM in the presence or absence of 1 mM thiamine. Cells were fixed in formaldehyde and processed for immunofluorescence as described (Hagan and Hymes, 1988), except the cells were digested with 1 mg/ml Zymolyase 100T for 5 min. Culture supernatant from the 9E10 hybridoma was used as the primary antibody. An anti-mouse fluorescein isothiocyanate-labeled antibody (Pierce) was used as a secondary antibody.

Gene Disruption

For gene disruption, plasmid pBS(KS)-2-1H (pBS(KS)) containing the 4.2-kb HindIII fragment from pBAR2-1, was digested with SmaI and BglII to excise the coding region of hba1, the termini were made blunt with Klenow fragment of DNA polymerase, and ligated to a 1.8-kb fragment containing the S. pombe ura4 gene from pREP4. The resulting plasmid, pBSDelta2-1hUra, was digested with BamHI and ligated to a 1-kb HpaI-BstXI fragment that had been made blunt and ligated to BamHI linkers. The final plasmid, pBS2-1KO, was digested with XbaI and HindIII to release a 4.8-kb fragment containing the disrupted hba1 gene. This fragment was isolated and used to transform wild type diploid S. pombe. Genomic Southern analysis was performed to determine homologous recombination.

RNA Analysis

RNA isolation and Northern blotting were performed as described previously (Turi et al., 1994). Radiolabeled probes corresponding to the coding regions of hba1, crm1, pap1, leu1a, and hba2 were prepared by the random primer labeling method (Feinberg and Vogelstein, 1983), and the membrane was hybridized overnight with each of these probes. Analysis and quantitation was performed on a Molecular Dynamics PhosphorImager (Sunnyvale, CA).


RESULTS

Isolation of hba1

The isolation of the three Group II plasmids, pBAR1-2, pBAR2-1, and pBAR2-16, capable of conferring brefeldin A resistance has been described previously (Turi et al., 1994). These plasmids contained overlapping genomic DNA inserts that were between 8 and 15 kb. Because plasmid pBAR2-1 contained the smallest insert, it was chosen for further characterization. To localize the gene on pBAR2-1 conferring BFA resistance, this plasmid was digested with several enzymes and the fragments corresponding to the genomic insert were subcloned into pFL20. The resulting plasmids were used to transform wild type S. pombe and BFA resistance assessed in each of the transformants using both a growth and secretion assays. A 4.2-kb HindIII fragment common to all of the original Group II plasmids conferred BFA resistance (Fig. 1).


Figure 1: Restriction mapping of pBAR2-1. Restriction map and subclones from pBAR2-1. The locations of restriction endonuclease sites on the original pBAR2-1 plasmid are indicated as vertical bars (abbreviations are: B, BglII; E, EcoRI; H, HindIII). Each restriction fragment was subcloned into pFL20. The resulting plasmid was used to transform the wild type S. pombe strain FWP1. The ability of each plasmid to confer BFA resistance is shown to the right of each fragment.



The DNA sequence of the 4.2-kb fragment was determined. Two long open reading frames were present within this fragment (diagrammed in Fig. 1). The upstream ORF was complete, while the downstream ORF was truncated at the distal HindIII site. The remaining portion of this second ORF was determined by sequencing directly from plasmid pBAR2-1. To determine which of the two ORFs was capable of conferring the BFA resistance, each gene was individually subcloned into pFL20, transformed into wild type S. pombe, and transformants analyzed as before. Only the complete upstream ORF present on the original 4.2-kb HindIII fragment conferred BFA resistance (data not shown). The nucleotide and and amino acid sequence of this ORF, which we refer to as hba1 for hyperresistance to brefeldin A, is shown in Fig. 2. The hba1 coding sequence begins at nucleotide 612 and terminates at nucleotide 1809. The second ORF, which is referred to as dhb1 for downstream of hba1, begins 1268 nucleotides downstream of the hba1 ORF (sequence not shown, but is included in GenBank accession no. U38783). Comparison of the dhb1 ORF to the GenBank data base failed to detect any significant sequence similarity to any other known protein.


Figure 2: Nucleotide and predicted protein sequence of the hba1 gene. The sequence of the entire pBAR2-1H insert was deduced. Shown is the sequence corresponding to the hba1 gene. The putative nuclear localization sequence is underlined. The complete nucleotide sequences of both hba1 and dhb1 have been deposited in the GenBank/EMBL data base under accession number U38783.



The library used to isolate hba1 on pBAR2-1 was constructed from a S. pombe strain possessing a dominant mutation within the bar2 gene, which itself confers BFA resistance. It was possible that the hba1 allele isolated may have contained a mutation. We therefore determined the sequence of hba1 from plasmid pBAR1-2. This plasmid was isolated from a library constructed from a strain harboring a bar1/crm1 mutation in a wild type background, and it would be expected that the hba1 allele isolated from this strain be wild type. Comparison of the hba1 sequence from pBAR1-2 and pBAR2-1 determined that the two sequences were identical, demonstrating that the gene isolated from pBAR2-1 was wild type.

Primary Structure of hba1

The ORF of hba1 potentially encodes a protein of 399 amino acids. Using this deduced amino acid sequence, a search of the GenBank and EMBL data bases showed that this ORF encoded a novel protein. The proteins within the data bases showing the greatest degree of sequence similarity to Hba1p were the Saccharomyces cerevisiae CST20 gene product (Ouspenski et al., 1995), subsequently renamed YRB1 (Dingwall et al., 1995), and human RanBP1. These proteins interact with the yeast and mammalian Ras-like nuclear proteins GSP1 and Ran in their GTP-bound state. Both proteins possessed 29% identity (54% overall similarity) to hba1p (Fig. 3).


Figure 3: Comparison of amino acid sequence of hba1, CST20, and RanBP1. Amino acids that are identical between all three proteins and denoted by the solid boxes. Hatched boxes denote amino acid residues in which a conservative replacement has been substituted in one of the proteins. The putative nuclear localization domain of Hba1 is located between residues 191 and 214. The sequence data used were taken from Coutavas et al. (1993; accession number L25255) and Ouspenski et al. (1995; accession number X65925).



Several proteins in addition to RanBP1 and YRB1 were also found to have significant similarity to the COOH-terminal half of Hba1p. These proteins included the S. cerevisiae genes NUP2 and an ORF present on Chromosome IX with sequence similarity to NUP2 (NUP2-like), a Caenorhabditis elegans ORF (Fig. 4) and three human proteins, two of which were identified by screening a hippocampal expression library with [P]GTP-Ran (Beddow et al., 1995) and the other by hybridization with murine RanBP1 (Bischoff et al., 1995). The latter of the three human RanBP homologues, subsequently identified and renamed RanBP2 (Yokayama et al., 1995), contains two homology domains and is similar in structure to the C. elegans ORF. The region of similarity between all these proteins is centered around two potential leucine zippers that have been predicted in RanBP1 (Coutavas et al., 1993).


Figure 4: A conserved motif found in Ran-binding proteins is present in Hba1p. The region of sequence similarity between Hba1p and Ran-binding proteins is shown. The protein sequences were aligned with the Megaalign program of DNAstar. Sequences used were S. pombe hba1, S. cerevisiae proteins encoded by the CTS20, NUP2, and NUP2-like genes, the mouse RanBP-1 (L25255), C. elegans open reading frame F59A2 (which contains both a NH(2)-terminal and COOH-terminal motif), the human gene RanBPX (which also contains two motifs: a and b) (X83617), and the human AB1 (U19240) and AB2 (U19248) genes. Closed circles denote amino acid residues that are identical in all the aligned proteins; open circles denote residues that are highly conserved between the aligned proteins.



Nuclear Localization of Hba1p

Of the previously identified proteins that are similar to Hba1p and contain the RanBP domain, several are localized to the nuclear membrane and the others are cytosolic. To determine the subcellular localization of Hba1p, we performed indirect immunofluorescence using a hba1 gene, which had an epitope of the human c-Myc protein appended to the COOH terminus. This construct and the wild type hba1 gene were expressed in wild type S. pombe under the control of the thiamine repressable nmt1 promoter (Maundrell, 1990). With cells grown in the presence of thiamine, no immunofluorescence could be detected in pREP4 (vector alone), hba1, or hba1-myc transformed cells (data not shown) using a monoclonal antibody specific for the c-Myc epitope. In contrast, cells transformed with the hba1-myc construct and grown in the absence of thiamine showed intense nuclear staining using the anti-c-Myc mAb, while pREP4 and hba1 transformed showed no nuclear staining (Fig. 5). The Hba1-Myc protein conferred BFA resistance to wild type S. pombe only in the absence of thiamine, suggesting that the fusion protein was functionally active and transported to the correct cellular organelle.


Figure 5: Localization of Hba1p in S. pombe. Indirect immunofluorescence was performed on wild type S. pombe transformed with vector control (pREP4) or with a vector containing the hba1 gene (pREP4-HBA1) or the hba1 gene with the human c-Myc epitope appended to the carboxyl terminus (pREP4-HBA1-Myc) under the control the nmt1 promoter. Panels on the left correspond to 4`,6-diamidino-2-phenylindole, dihydrochloride-stained nuclei. Panels on the right correspond to fluorescence observed when the cells are stained with the anti-c-Myc monoclonal antibody 9E10 and a fluorescein isothiocyanate-labeled secondary antibody. Immunofluorescence was performed as described by Hagan and Hyams(1988), except that spheroplasting was terminated when approximately 50% of the cells became refractory.



To exclude mislocalization by the Myc epitope, we appended the Myc epitope onto the carboxyl terminus of the cytoplasmic protein Obr1 and expressed this construct using the nmt1 promoter (Toda et al. 1992; Turi et al., 1994). The Obr1-Myc fusion was localized throughout the cytoplasm with no evidence of nuclear staining (data not shown). These results demonstrate that the nuclear localization of Hba1p is not due to the presence of the Myc tag. Examination of the deduced Hba1p sequence identified a possible bipartite nuclear localization signal located between residues 191 and 214, which contains the sequence KKFAAGTAVETESGSGKEKENDKK ( Fig. 2and 3).

Hba1p Is a Phosphoprotein

To examine the biochemical properties of Hba1p, we utilized the c-Myc epitope-tagged construct under the control of the nmt1 promoter. Wild type cells transformed with pREP4, pREP4-hba1, or pREP4-hba1-Myc were grown for 18 h either in the presence of thiamine to repress expression or in the absence of the vitamin to induce expression. Equivalent numbers of cells from each overnight culture were transferred to fresh media and metabolically labeled with [S]methionine for 30 min. After the labeling period, the cells were disrupted, immunoprecipitated with the anti-c-Myc monoclonal antibody 9E10, and the precipitates analyzed by SDS-polyacrylamide gel electrophoresis. In the absence of thiamine, no proteins were precipitated in either vector alone or in the wild type Hba1-transformed strain. In the strain possessing the Hba1-c-Myc construct a broad, diffuse band migrating at approximately 70 kDa was observed in addition to two lower molecular mass bands of 28 and 30 kDa (Fig. 6A). The predicted molecular mass of Hba1 with the appended c-Myc epitope was 41 kDa. Thus, Hba1 migrates aberrantly. A likely explanation for the aberrant migration pattern of Hba1 is this protein contains a large number of charged residues. The lower molecular weight proteins are most likely proteolytic cleavage products of the native Hba1 protein, which are detectable on immunoblots by anti-c-Myc antibody (data not shown).


Figure 6: In vivo metabolic labeling of Hba1p. A, immunoprecipitates of S. pombe extracts that had been labeled with [S]methionine. B, immunoprecipitates of S. pombe extracts that had been labeled with [P]H(3)PO(4). For both experiments, S. pombe was transformed with pREP4 alone or either hba1 or hba1-c-Myc under the control of the nmt1 promoter. Cultures were grown for 18 h in the absence of thiamine to induce expression from the nmt1 promoter. The two faster migrating bands in each of the hba1-c-Myc transformants represent degradation products of Hba1p (data not shown).



To further investigate the nature of the Hba1p doublet, we repeated the metabolic labeling experiment with [P]orthophosphate to determine whether the observed heterogeneity was due to post-translational modification such as phosphorylation. Derepressed strains transformed with vector alone, Hba1, or Hba1-c-Myc were metabolically labeled for 3 h with [P]orthophosphate, immunoprecipitated, and analyzed by SDS-PAGE as before. In vector alone and Hhba1-transformed cells, no signal was detected. In contrast, a single phosphoprotein of approximately 70 kDa was detected in addition to the two lower molecular mass labeled proteolytic products of 28 and 30 kDa (Fig. 6B). These results demonstrate that Hba1 is a nuclear phosphoprotein.

hba1 Is Essential for Viability

To determine if hba1 was essential, we constructed strains deleted for hba1. Null mutants were created by deleting the entire hba1 coding region and replacing it with ura4. The deletion construct was used to transform diploid S. pombe and targeted replacements were verified by Southern analysis. After conversion of h/h parent into h/h, the diploid was induced to sporulate. Very few of the disrupted heterozygous diploids successfully completed meiosis, yielding four spore asci compared to the untransformed parental strain. Because of the poor sporulation of the hba1 disrupted diploid, random spore analysis was performed rather than tetrad dissection. Of the germinated spores no ura segregants were obtained. These results indicate that hba1 is required for viability.

BFA Resistance Conferred by hba1 Is Independent of the crm1 Regulatory Pathway

Previously we have determined that resistance to BFA was dependent upon alteration in the crm1 regulatory pathway (Turi et al., 1994). A mutation within the negative regulatory protein crm1 or overexpression of the transcription factor pap1 was sufficient to confer BFA resistance. Furthermore, we have identified a multidrug resistance-like transporter, hba2, which was negatively regulated by crm1 (Turi and Rose, 1995). Mutations within crm1 or overexpression of hba2 from a multicopy plasmid was sufficient to confer BFA resistance. To determine if crm1 participated in regulation of hba1, we examined expression of hba1 in isogenic wild type and crm1 mutant strains. Total RNA was isolated from each strain, fractionated and transferred to nitrocellulose, and hybridized with either crm1, hba1, pap1, or leu1a as a control for loading. Of the genes examined, only pap1 showed an increase in expression in the crm1 mutant (data not shown). Furthermore, hba1 was undetectable even with prolonged exposure.

To determine if overexpression of hba1 affected message levels of any of the known genes conferring BFA resistance, Northern analysis was performed using total RNA isolated from a wild type strain transformed with a multicopy plasmid containing hba1 (pBAR2-1H) or vector alone. The resulting blot was hybridized with probes for hba1, hba2, crm1, pap1, and leu1a as a control for loading. As shown in Fig. 7, a weak hba1 signal could be detected only in the strain overexpressing this gene from the high copy plasmid pHBA1 (pBAR2-1H). No change in either hba2, crm1, or pap1 was detected in the strain overexpressing hba1. These results suggest that BFA resistance conferred by hba1 is independent of the crm1 regulatory pathway.


Figure 7: Overexpression expression of hba1 and its effects on other BFA resistance conferring genes. Ten micrograms of total RNA isolated from wild type S. pombe transformed with either pFL20 or pHBA1 (pBAR2-1H). RNA was fractionated on a 1% agarose gel and transferred to nitrocellulose. The filter was hybridized with a probe specific for hba1, hba2, crm1, pap1, and leu1a.




DISCUSSION

In this report we describe the characterization of hba1, a S. pombe gene conferring brefeldin A resistance. In the initial screen for genes conferring BFA resistance, plasmids encoding hba1 were the second most frequently isolated clones (Turi et al., 1994), suggesting that overexpression of Hba1p is an efficient mechanism of resistance. Plasmids containing hba1 confer high levels of BFA resistance in a growth assay and only moderate levels of resistance in a secretion assay. This difference in the levels of resistance presumably reflects the transient nature of the secretion assay, i.e. examination of resistance within a 30-min period versus extended periods (several hours).

The hba1 gene encodes a nuclear protein essential for S. pombe viability. Initial characterization of Hba1p yielded several unexpected results. Although the Hba1-c-Myc fusion protein was expected to migrate with a mobility of 41 kDa, the observed mobility for this protein was approximately 70 kDa. The aberrant mobility of Hba1p can be partially explained by its charged nature. At pH 7.0, 134 of the 399 amino acids are charged yielding a net overall charge of -4.2 (pI = 5.9).

A second possible contributing factor to the aberrant mobility of Hba1p is posttranslational modification. Immunopreciptation of the c-Myc epitope-tagged Hba1p after [S]methionine labeling yielded a broad heterogeneous band. Labeling with [P]orthophosphate determined Hba1p to be a phosphoprotein.

A clue to the function of Hba1p may reside in its homology to proteins that interact with the nuclear low molecular weight GTP-binding protein Ran. This GTP-binding protein and its exchange factor, RCC1, have been implicated in several nuclear functions including nuclear import and export, regulation of the cell cycle, and maintenance of chromatin and nuclear structure (Dasso, 1993; Sazer and Nurse, 1994; Demeter et al., 1995). The hba1 gene product contains a 57-amino acid segment that is highly conserved in Ran-binding proteins (RanBPs), as well as a protein of the nuclear pore complex, and several other proteins of unknown function (Hartmann and Görlich, 1995). RanBP1 has been demonstrated to maintain Ran in the GTP-bound state or to act as a costimulator of GTP hydrolysis depending on the absence or presence of Ran-GTPase activating protein (Bischoff et al., 1995). Mutation of the first conserved glutamine, analogous to residue 266 of Hba1p, has been shown to reduce the binding of RanBP1 to Ran, suggesting a critical role for this domain in protein-protein interaction (Beddow et al., 1995).

The S. cerevisiae genes GSP1, PRP20, and YRB1 encode homologues of Ran, RCC1, and RanBP1. In the fission yeast S. pombe, spi1 and pim1 encode homologues of Ran and RCC1. A Spi1-binding protein (Sbp1) with homology to RanBP1 has recently been identified. (^2)(^3)This leaves the possibility that hba1 encodes a second Spi1-binding protein. However, using a yeast two-hybrid system with Hba1p and Spi1p, we have not been able to detect interaction between the two proteins. (^4)Additional evidence that Hba1p may not interact with Spi1p is supported by the results of an experiment in which Spi1p[P]GTP was used to probe yeast cell extracts. No interacting proteins were identified with a molecular mass similar to that predicted for Hba1 (Coutavas et al., 1993), (^5)yet this protein overlay assay was able to detect an interaction with S. cerevisiae RanBP (YRB1) (Ouspenski et al. 1995). It is possible that Hba1p interacts with a different as yet unidentified S. pombe nuclear GTPase or that the interaction with Spi1p may not have been detected using the two-hybrid system for technical reasons or by the protein overlay due to low level expression or the inability of the protein to renature into its active conformation.

Previously we have identified two additional S. pombe nuclear proteins, encoded by crm1 and pap1, which are capable of conferring BFA resistance (Turi et al., 1994). The pap1 gene encodes the S. pombe homologue of the mammalian AP1 transcription factor (Toda et al., 1991). Transcriptional regulation by pap1 is negatively regulated by the gene product of crm1 (Toda et al., 1992; Shimanuki et al., 1995). Because these two proteins regulate transcription of other genes responsible for conferring drug resistance, we determined if these genes affected hba1 transcription and also if overexpression of hba1 effected transcription of known genes involved in drug resistance. Neither crm1 or pap1 effected hba1 expression. Of the known genes capable of conferring BFA resistance when overexpressed, expression of these markers was not increased in the presence of elevated levels of hba1. Indeed, expression of hba2, a multidrug resistance transporter capable of conferring BFA resistance, was decreased in cells containing elevated levels of hba1. These results suggest that hba1 mediates BFA resistance via an undefined pathway. While the exact mechanism by which hba1 confers BFA resistance is unclear, the isolation of this gene which encodes a nuclear protein belonging to the RanBP family of proteins, has potentially expanded the role of RanBP-like proteins. Thus, through a combined genetic and biochemical approach, one may identify both the cellular function of hba1 and determine its role in BFA resistance.


FOOTNOTES

*
This study was supported in part by National Institutes of Health (NIH) Predoctoral Training Grant AG00183 (to U. W. M.), NIH Postdoctoral Grant GM15502-02 (to T. G. T.), NIH Grants PO1 AI24345 (to J. K. R.) and GM49119, and Robert A. Welch Foundation Grant Q-1226 (to S. S.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBank(TM)/EMBL Data Bank with accession number(s) U38783[GenBank].

§
To whom correspondence should be addressed. Current address: Dept. of Molecular Sciences, Pfizer Inc., Groton, CT 06340. Tel.: 203-441-6924; Fax: 203-441-3783.

(^1)
The abbreviations used are: BFA, brefeldin A; ARF, ADP-ribosylation factor; kb, kilobase(s); PCR, polymerase chain reaction; ORF, open reading frame; PAGE, polyacrylamide gel electrophoresis; RanBP, Ran-binding protein.

(^2)
X. He and S. Sazer, unpublished observation.

(^3)
N. Hayashi and T. Nishimoto, personal communication.

(^4)
T. G. Turi and J. K. Rose, unpublished observation.

(^5)
I. I. Ouspenski, personal communication.


ACKNOWLEDGEMENTS

We thank S. Degar, C. Strick, and D. Stern for valuable advice and critical review of the manuscript prior to submission and X. He, N. Hayashi, and T. Nishimoto for sharing results prior to publication.


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