©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Yeast Proteins Related to the p40/Laminin Receptor Precursor Are Essential Components of the 40 S Ribosomal Subunit (*)

(Received for publication, August 22, 1995; and in revised form, January 31, 1996)

Marina Demianova Timothy G. Formosa (1) Steven R. Ellis (§)

From the Department of Biochemistry, University of Louisville, Louisville, Kentucky 40292 Department of Biochemistry, University of Utah, Salt Lake City, Utah 84132

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

We report here the isolation of two genes from the yeast, Saccharomyces cerevisiae, that encode proteins closely related to mammalian p40/laminin receptor precursors (LRPs). The yeast genes, designated YST1 and YST2, encode proteins with over 95% amino acid sequence identity with one another and over 60% identity with the human p40/laminin receptor precursor. The Yst/p40/37-LRP proteins are also more distantly related to the S2 family of ribosomal proteins. Analysis of the distribution of Yst1 tagged with the c-myc epitope revealed that the Yst proteins are components of the 40 S ribosomal subunit. Disruption of either YST1 or YST2 causes a significant reduction in growth rate, while disruption of both genes is lethal. Compared to wild type, polysome profiles in strains lacking either YST1 or YST2 show a pronounced shift from larger to smaller polysomes. This shift is accompanied by a substantial increase in free 60 S subunits and reduced levels of 40 S subunits. We conclude that the Yst proteins are required for translation and contribute to the assembly and/or stability of the 40 S ribosomal subunit.


INTRODUCTION

A cDNA originally reported to encode the 67-kDa high affinity laminin receptor has also been implicated in the production of an abundant intracellular protein of approximately 37 kDa that is highly conserved in a wide spectrum of eukaryotic cells(1, 2, 3) . The relationship between these two proteins is unclear but it has been proposed that a fraction of the intracellular pool of the 37-kDa protein may serve as a precursor for the 67-kDa laminin receptor(4, 5) . The cDNA encoding the 37-kDa laminin receptor precursor (37-LRP) (^1)is virtually identical to a cDNA encoding a mouse protein, p40, initially identified in a screen for mRNAs under translational control in ascites tumors(6, 7) . A cDNA encoding p40 was also shown to encode an antigen that shows regional specificity in developing mice retinas(8) . This antigen appears to be a conformational isomer of intracellular p40 that has been proposed to play a role in defining the dorsal/ventral axis in developing retinas(9) . Finally, a gene encoding a Drosophila homolog of p40 was shown to complement mutations at the stubarista locus(10) . Certain mutant alleles of Drosophila p40 are zygotic lethals that have been shown to affect oogenesis and imaginal disc development. Together, these data indicate that the 67-kDa laminin receptor may be derived from an abundant intracellular protein, p40/37-LRP, and that p40/37-LRP proteins, apart from their potential role as precursors for laminin receptors, may play important roles in early stages of metazoan development.

Several lines of evidence suggest that p40/37-LRP proteins are components of the protein synthetic machinery. Mammalian, Arabidopsis, and Urechis caupo p40 proteins are polysome associated and appear to be preferentially associated with 40 S ribosomal subunits(3, 11, 12, 13) . The distribution of p40 proteins between free and polysome-associated states has been shown to depend on the age, growth stage, or developmental state of the cells examined(3, 11, 13) . In addition to the physical association of p40 with polysomes, genetic studies in Drosophila suggest that p40 may be a component of the translational machinery. Phenotypes associated with certain alleles of the Drosophila p40 locus are similar to minute phenotypes that are often associated with genes encoding ribosomal components(10) . Finally, Davis et al. (14) showed that p40/37-LRP proteins are structurally related to the S2 family of ribosomal proteins. This relationship has been further strengthened by the identification of an archaebacterial member of this family whose sequence is approximately equidistant in terms of similarity between the eubacterial/organellar S2 proteins and the eukaryotic p40/37-LRP proteins(15) .

We report here the isolation of two genes from the yeast, Saccharomyces cerevisiae, that encode proteins closely related to the p40/37-LRP family of proteins. The yeast genes, designated YST1 and YST2, encode proteins that exhibit over 95% sequence identity with each other, over 60% sequence identity with mammalian p40/37-LRP proteins, and approximately 30% sequence identity with members of the S2 family of ribosomal proteins. Epitope-tagged Yst1 cosediments with 40 S ribosomal subunits, 80 S monosomes, and polysomes during sucrose gradients centrifugation indicating that the Yst proteins are small subunit ribosomal proteins. Disruption of either YST1 or YST2 shows a reduction in growth rate compared to wild type. Cells disrupted in both YST1 and YST2 fail to germinate indicating that Yst function is essential. Relative to wild type, polysome distributions in cells lacking one or the other of the YST genes show a pronounced shift from larger to smaller polysomes. This shift to smaller polysomes in mutant extracts is accompanied by a substantial increase in free 60 S ribosomal subunits and a reduction in the level of free 40 S subunits. The Yst proteins are therefore required for translation and contribute to the assembly and/or stability of 40 S ribosomal subunits.


MATERIALS AND METHODS

Yeast and Bacterial Strains

The yeast strains used in this study were W303 (MATa/MATalpha,, ade2-1/ade2-1, can1-100/can1-100, his3-11, 15/his3-11, 15, ura3-1/ura3-1, leu2-3, 112/leu2-3, 112, trp1-1/trp1-1) and 7208-12 (MATa/MATalpha, pep4-3/pep4-3, prb1-1122/prb1-1122, his7/his7, ura3-52/ura3-52, trp1/trp1, can1/can1). Media used in cultivating yeast were: YPD (1% (w/v) yeast extract, 2% (w/v) peptone, 2% (w/v) dextrose), YM-1(16) , and minimal (0.67% (w/v) yeast nitrogen base without amino acids, 2% (w/v) dextrose). Where appropriate, nutrients were added to minimal media in amounts specified by Sherman(17) . Diploids were sporulated in solid SPO media (1% (w/v) potassium acetate, 0.1% (w/v) yeast extract, 0.05% (w/v) dextrose, 2% (w/v) agar), and where appropriate adenine, histidine, uracil, leucine, and tryptophan were added in 25% the amounts used in synthetic complete media. The Escherichia coli strain used in this study was JM101.

Isolation of DNA-binding Proteins

DNA-binding proteins were isolated from a crude nuclear fraction of the yeast S. cerevisiae and used to prepare antibodies. A 2-liter culture of strain 7208-12 was grown to log-phase (2 times 10^7/ml) in YM-1, and the cells were collected by centrifugation (10 min at 6,000 times g). The 6.4-g cell pellet was suspended in 20 ml of Tris-HCl (pH 9.1), 20 mM Na(3)EDTA, 1 M NaCl, 0.1 M 2-mercaptoethanol, and incubated for 10 min at room temperature. The cells were collected by centrifugation (5 min at 4,000 times g), and suspended in 40 ml of 1 M NaCl, 166 mM KH(2)PO(4), 34 mM sodium citrate (pH 5.8). The cells were collected again, suspended in 40 ml of glusulase buffer (10% (w/v) glycerol, 1 M sorbitol, 42 mM KH(2)PO(4), 8 mM sodium citrate (pH 5.8), collected, and suspended in 10 ml of glusulase buffer. 0.3 ml of glusulase solution (105,000 units/ml glucuronidase, 11,500 units/ml sulfatase; DuPont NEN) was added to the suspension, and the mixture was incubated 1 h at 30 °C. The cells were collected by centrifugation for 5 min at 2,000 times g, gently resuspended in 20 ml of glusulase buffer, then collected again. The washed spheroplasts were suspended in 20 ml (2 mM MgCl(2), 0.2% (v/v) Triton X-100, 40 mM Tris-HCl, pH 7.4, 1 mM 2-mercaptoethanol, 5% (w/v) Ficoll 400, 0.5 µg/ml leupeptin, 0.7 µg/ml pepstatin, 0.5 mM phenylmethylsulfonyl fluoride) and lysed with five strokes in a Dounce homogenizer on ice. The suspension was centrifuged for 10 min at 11,000 times g; the pellet contained cellular debris including nuclei and other organelles. This material was extracted with 10 ml of 50 mM Tris-HCl, pH 7.4, 2 mM Na(3)EDTA, 1 mM 2-mercaptoethanol, 2.5 M NaCl, 0.5 µg/ml leupeptin, 0.7 µg/ml pepstatin, and 0.5 mM phenylmethylsulfonyl fluoride, then disrupted with 10 strokes in a Dounce homogenizer on ice. The suspension was centrifuged for 20 min at 16,000 times g. 1.75 g of NaCl, 0.66 g of polyethylene glycol 8000, and 0.44 g of dextran 500 were added to 12.5 ml of the supernatant and mixed gently for 1 h at 4 °C. The mixture was centrifuged for 10 min at 11,000 times g to separate the phases containing protein and nucleic acids. The clear upper phase containing proteins was dialyzed two times against 2 liters each time of DC without glycerol (20 mM Tris-HCl, pH 8.0, 2 mM Na(3)EDTA, 1 mM 2-mercaptoethanol, and 50 mM NaCl; subscripts denote the molarity of NaCl). A slight precipitate was removed by centrifugation (10 min at 11,000 times g), then glycerol was added to 10% (w/v), and the fraction was loaded onto a 5-ml single-stranded DNA cellulose column equilibrated with DC. After washing with the same buffer, the DNA-binding fraction was eluted with DC(2). Protein concentrations in various fractions were estimated using the method of Bradford(18) . Lysed spheroplasts contained about 400 mg of soluble protein, the column load contained about 23.5 mg of protein (5.8% of the total), and the DNA-binding fraction contained about 4.6 mg (1.1% of total, 19% of the column load).

Cloning and Sequencing the Yeast YST1 and YST2 Genes

The DNA-binding protein fraction was dialyzed into DC, then used to inoculate rabbits (two to three injections with 0.3-0.5 mg each injection). Antisera were collected and used to screen a library of yeast genomic sequences in gt11 (provided by M. Snyder, Yale University). The clone containing the YST1 gene was recovered and used to purify antibodies from the total serum. The purified antibodies were used to immunostain immobilized proteins derived from the cytoplasmic or crude nuclear fractions. The anti-Yst antibodies recognized a 30-kDa protein that is enriched in the crude nuclear fraction (data not shown). The insert from this clone was subcloned, and its nucleotide sequence was determined using the dideoxy chain termination method (19) with Sequenase enzyme and protocols (U. S. Biochemical Corp.) after creating nested sets of deletions using the Exo III method(20) . This sequence has been deposited in GenBank originally under the name NAB1A and has since been changed to YST1 (accession no. M88277). The original clone was a fusion of lacZ and YST1 at the unique EcoRI site found downstream of the intron within the YST1 reading frame. We used this fragment to recover the remainder of YST1 using the integration/recovery method (21) .

The YST2 gene was isolated using a radiolabeled fragment of the YST1 gene to probe a yeast genomic library (American Type Culture Collection no. 37323). The YST2 gene was subcloned into Bluescript II KS in two fragments: a 1,500-bp HindIII/HindIII 5` fragment and a 2,100-bp HindIII/SalI 3` fragment creating plasmid pMD12. The junction between these two fragments was sequenced in the original clone to assure that they were contiguous. The YST2 gene was subcloned for sequencing by creating nested sets of deletions using an Exo III/mung bean deletion kit from Strategene or by subcloning through selected restriction enzyme sites. Sequencing was carried out by the chain termination method of Sanger et al.(19) . This sequence has been deposited in GenBank originally under the name NAB1B and has since been changed to YST2 (accession no. U33756).

Disruption of YST1 and YST2

The YST1 gene located on a 2.7-kb EcoRV fragment of yeast genomic DNA was inserted into pBluescript KS at the unique EcoRV site. The plasmid with the 5` end of the YST gene oriented toward the SacI site in Bluescript KS was designated pJM8 and the reverse orientation, pJM9. The pJM8 plasmid was digested with BsmI and BstEII, liberating a fragment of 951 bp containing 88% of the YST1 open reading frame. This fragment was replaced by a HindIII fragment containing the yeast URA3 gene after filling in to produce blunt ends on all fragments (designated pJM10). This construct produces an allele denoted yst1-Delta1(::URA3). pJM10 was digested with EcoRI and SnaBI, liberating a fragment of approximately 3.0 kb. The fragment released contains the URA3 gene flanked by approximately 1,000 bp of YST1 sequence at its 5` end and 413 bp at its 3` end. The EcoRI/SnaBI fragment was used to transform the diploid strain W303. Transformants were selected by uracil prototrophy and sporulated, and the resulting tetrads were dissected by micromanipulation. Spores were germinated on YPD media and analyzed for the YST1 disruption by Southern and Northern blot hybridization.

The YST2 gene was disrupted by replacing the bulk of the YST2 open reading frame with the yeast HIS3 gene. The pMD12 plasmid containing YST2 was digested with NruI and HpaI liberating an 849-bp fragment. This fragment was replaced by an 1,800-bp HincII/SmaI fragment containing the HIS3 gene (designated pMD13). This construct produced an allele denoted yst2-Delta1(::HIS3). Cleavage of pMD13 with SspI liberates a fragment of approximately 2,500 bp that contains the HIS3 gene flanked by sequences derived from YST2 at its 5` and 3` ends. The SspI fragment was used to transform W303 cells to histidine prototrophy. Transformants were sporulated, and tetrads were dissected by micromanipulation. Spores were germinated on YPD medium and analyzed for the YST2 disruption by Northern hybridization.

To examine the effect of the disruption of both YST1 and YST2, the diploid strain heterozygous for yst2-Delta1(::HIS3) was transformed with the yst1-Delta1(::URA3) DNA fragment derived from pJM10. Transformants prototrophic for histidine and uracil were sporulated and tetrads dissected by micromanipulation. Spores were germinated on YPD and the segregation of disrupted alleles of YST1 and YST2 was analyzed by prototrophy for uracil or histidine and confirmed when possible by Northern hybridization.

Mapping YST1 and YST2

The YST1 gene was shown by meiotic mapping to be linked to the ADE3 gene on the left arm of chromosome VII (56 tetrads; ADE3-3.8 cM-SER2-1.9 cM-YST1). Hybridization of yeast genomic clone grids confirmed this location and indicated that YST2 is on chromosome XII near SPT8 (YST1 hybridizes to ATCC clone 70361, YST2 hybridizes to clone 70582).

Polysome Analysis

Polysomes were prepared from yeast cell extracts and fractionated on 7-47% sucrose gradients as described by Baim et al.(22) . Centrifugation was for either 5 or 12 h. The longer time was necessary to resolve 40 S ribosomal subunits from soluble components at the top of the gradient. Conditions used to prepare yeast cell extracts under high salt or low magnesium conditions were described by Foiani et al.(23) . Macromolecules in the polysome fractions were precipitated with 10% trichloroacetic acid and washed once with 5% trichloroacetic acid and twice with cold (-20 °C) acetone. The pellets were air dried, suspended in Laemmli sample buffer(24) , and run on SDS-polyacrylamide gels.

Tagging Yst1 with the c-myc Epitope

Oligonucleotide-directed mutagenesis was used to insert the c-myc epitope immediately downstream of the YST1 reading frame in plasmid pJM9. The oligonucleotide used was 5`-ATATCACCTTACTTACAAGTCTTCTTCAGAAATAAGCTTTTGTTCCCACTCGACGTTGTC-3`. The c-myc epitope was the 10-amino acid sequence EQKLISEEDL recognized by the monoclonal antibody 9E10(25) . A 2.7-kb BamHI/SalI fragment containing the YST/c-myc gene was cloned into the yeast shuttle vector pRS315(26) . This construct complements phenotypes linked to the disruption of either YST1, YST2, or both genes indicating that sufficient 5`- and 3`-flanking regions from YST1 were included for expression in yeast and that the epitope-tagged Yst1 protein is functional. The epitope-tagged Yst1 protein was detected by enhanced chemiluminescence using a kit from Amersham Corp. The monoclonal antibody 9E10 was the generous gift of Dr. William W. Young, Department of Biology and Biophysics, University of Louisville.


RESULTS

Isolation and Characterization of Yeast YST Genes

In an effort to identify proteins involved in DNA metabolism in the yeast S. cerevisiae, a general class of DNA-binding proteins was isolated and used as a heterogeneous group of antigens. The antibodies produced were used to screen an expression library to identify the genes encoding the DNA-binding proteins. One of these genes, which we originally called NAB1 (Nucleic Acid Binding protein 1) and subsequently changed to YST1 (Yeast S Two) was found to encode a 30-kDa protein that was enriched in the low speed centrifugation pellet after hypotonic lysis of spheroplasts. This fraction contains large, insoluble portions of cells, including cell walls, nuclei, and mitochondria. Under the gentle extraction conditions used for the preparation of nuclei, a substantial number of ribosomes are detected in the crude nuclear fraction as judged by the presence of a large number of small basic proteins observed by two-dimensional gel electrophoresis (data not shown).

The nucleotide sequence of YST1 revealed two adjacent open reading frames separated by a region containing consensus 5`-donor, lariat, and 3`-acceptor sequences, suggesting a gene interrupted by a single intron (Fig. 1, top). The inferred spliced message encodes a protein of 252 amino acids with a predicted molecular mass of 28 kDa. A deletion of the second exon of the YST1 gene was constructed and introduced into diploid yeast cells. This mutation is marked with the URA3 gene and should prevent expression of 88% of YST1 open reading frame (Fig. 1, top). A fragment containing the disrupted YST1 gene was transformed into the diploid strain W303 and transformants selected by uracil prototrophy. Transformants were sporulated and the resulting tetrads dissected. Spores prototrophic for uracil grew more slowly than the uracil auxotrophs indicating that disruption of the yeast YST1 gene conferred a modest reduction in growth rate (data not shown, but see Fig. 3and Fig. 5).


Figure 1: Organization of the YST1 and YST2 genes. Open boxes represent the YST1 and YST2 open reading frames. Putative introns interrupting the open reading frames are shown with angled lines. Sequences at the splice sites encoded by YST1 and YST2 genes that conform to the yeast 5`- donor and 3`-acceptor (upper line) and branch point (lower line) consensus sequences (36) are shown below the intron in each gene. Slashes indicate exon/intron boundaries. Dashed lines represent 5`- and 3`-flanking regions that have either not been sequenced or were not deposited in the data base. Restriction enzyme sites used in cloning and gene disruptions are listed below each gene.




Figure 3: Tetrad analysis of the effects of the disruption of the YST1 and YST2 genes. A diploid strain heterozygous at both YST loci, YST1/yst1-Delta1(::URA3) and YST2/yst2-Delta1(::HIS3), was sporulated and tetrads dissected. Individual spores were grown on YPD medium at 30 °C. Numbers refer to different tetrads.




Figure 5: Growth curves of YST-disrupted strains complemented with plasmid-borne alleles of YST1 and YST2. Panel A, open circles, YST2-disrupted strain transformed with pRS315 vector alone; crosses, YST1-disrupted strain transformed with pRS315; closed triangles, wild-type strain transformed with pRS315; open triangles, YST1-strain transformed with pRS315 containing the YST1 gene; closed circles, YST2-disrupted strain transformed with pRS315 containing the YST1 gene. Panel B, same as panel A except strains designated by the closed circles and open triangles were transformed pRS315 containing the YST2 gene. Lines were drawn using a least squares regression fit (Slide Write Plus).



DNA and RNA hybridization analyses indicated that YST1 is not unique and suggested that cells with the disrupted YST1 allele were expressing Yst protein from a second locus (data not shown, but see Fig. 4). Using a YST1 fragment as a hybridization probe, we cloned a second gene closely related to YST1. The second gene also has an open reading frame capable of coding for a protein of 252 amino acids that appears to be interrupted with a single intron located at the same relative position as the intron in the YST1 gene (Fig. 1, bottom). The two genes show over 90% sequence identity at the nucleotide level and 95% identity in deduced amino acid sequence (Fig. 2). We have named the second locus YST2.


Figure 4: Northern analysis of YST1/2 mRNA levels in wild-type and disrupted strains. Total yeast RNA was prepared and fractionated on formaldehyde gels as described under ``Materials and Methods.'' RNA was transferred to Zetaprobe (Bio-Rad) membrane and hybridized with a nick-translated probe derived from the YST1 gene. RNA was derived from strains that were: lane 1, disrupted in YST1; lane 2, disrupted in YST2; lane 3, wild type for YST1 and YST2.




Figure 2: Alignment of primary structures deduced for the Yst1 and Yst2 proteins with human p40/37-LRP and Mrp4. Amino acids are represented by the one-letter code. Dashes in the Yst2 sequence indicate identities with Yst1. Dashes in the p40/37-LRP sequence show identities with both Yst1 and Yst2. Dashes in Mrp4 indicate identities with Yst1, Yst2, and p40/37-LRP. Asterisks below the alignments indicate identities between Mrp4 and at least one of the other proteins. Blank spaces represent gaps in the alignment. Superscripts specify codon numbers relative to the initiation codon for each gene. The Mrp4 protein has an amino-terminal extension of 170 amino acids relative to the region of homology with the other proteins shown here.



A search of the GenBank data base indicated that the Yst proteins are closely related to the p40/37-LRP family of proteins(27) . The Yst proteins are also more distantly related to the S2 family of ribosomal proteins found in eubacteria and organelles, suggesting that Yst/p40/37-LRP proteins are eukaryotic members of the S2 family of proteins. Members of the S2 family have also been identified in archaebacteria, indicating that the S2 family of proteins evolved prior to the divergence of the three major lines of descent(15) . Fig. 2shows the alignment of the Yst proteins with the human p40/37-LRP protein and the yeast mitochondrial ribosomal protein Mrp4. The Yst proteins show over 60% sequence identity with human p40/37-LRP over 201 amino acids spanning the bulk of the three proteins (Fig. 2). The Yst and p40/37-LRP proteins diverge at their amino and carboxyl termini where the human protein also has a carboxyl-terminal extension of 42 amino acids. Fig. 2also shows the alignment of the Yst/p40/37-LRP proteins with Mrp4, a member of the S2 family of ribosomal proteins (14) . The Mrp4 protein has approximately 30% sequence identity with at least one of the other proteins shown in Fig. 2. Overall, the four proteins have 23% sequence identity. This level of identity is similar to comparisons between other homologous ribosomal proteins found in both eubacteria and eukaryotes(28) .

We have disrupted YST2 alone and in combination with the YST1 disruption. The bulk of the YST2 reading frame was deleted and replaced by the HIS3 gene. A fragment containing the disrupted YST2 gene was transformed into the diploid yeast strain W303 and transformants were selected by histidine prototrophy. Transformants were sporulated and the resulting tetrads dissected. Histidine prototrophy segregated with a slow growth phenotype indicating that just as for YST1, disruption of YST2 is tolerated, but has an impact on growth rate (data not shown, but see Fig. 3and Fig. 5).

The diploid yeast strain heterozygous for the YST2 disruption was transformed with a disrupted copy of YST1 to assess the effects of the disruption of both YST genes. Transformants were sporulated and tetrads dissected. Representative results from the growth of individual spores on YPD are shown in Fig. 3. Examination of colony size in spores from tetrads 2, 5, 6, and 7 suggests four distinct growth rates. The fastest growing spores were auxotrophic for both uracil and histidine, suggesting that they contained wild-type YST1/2 alleles. The two intermediate sized colonies were prototrophic for either uracil or histidine. The larger colony was prototrophic for uracil and auxotrophic for histidine, indicating that it was disrupted in YST1 but wild type for YST2. The smaller colony was prototrophic for histidine and auxotrophic for uracil indicating that it contained a disrupted allele of YST2 and a wild-type allele of YST1. The fourth spore in each of these tetrads did not germinate. The inviable spores were presumably disrupted in both YST1 and YST2, suggesting that disruption of both YST genes is lethal. Tetrad 4, on the other hand, gave two colonies and two nonviable spores. In this tetrad, the cells that grew were both auxotrophic for uracil and histidine, indicating they had wild-type alleles of YST1/2. We assume that the nonviable spores were disrupted in both YST genes. Tetrads 1 and 3 showed four spores with intermediate growth rates. In tetrad 1 the four viable spores were auxotrophic for either uracil or histidine, indicating that they were disrupted in one or the other YST gene. One of the colonies derived from tetrad 3 was prototrophic for both uracil and histidine, but was eventually shown to be a mixed population of cells. Overall, the examination of 124 spores revealed no viable double mutants, whereas, 31 would have been expected by chance.

The segregation pattern of the YST1 and YST2 alleles in Fig. 3suggested that the two genes were unlinked. This was confirmed by mapping the YST1 and YST2 genes either genetically or by hybridization to a genomic clone grid library. YST1 hybridized to ATCC clone 70361 and maps near ADE3 on the left arm of chromosome VII, whereas YST2 hybridized to ATCC clone 70582 and maps near SPT8 on chromosome XII (data not shown).

Disruption of the YST genes was confirmed by Northern hybridization analysis. Northern analysis revealed that the two YST genes encode mRNAs that differ in size by approximately 150 bases with the YST2 gene encoding the larger of the two mRNAs (Fig. 4). The observation that in wild-type cells the hybridization signals for the two mRNAs are comparable even though the probe was derived from YST1 suggests that the steady-state levels of YST2 mRNAs might be somewhat higher than for the YST1 mRNA. This might explain why the disruption of YST2 causes a more severe reduction in growth rate than does the disruption of YST1; the Yst proteins are functionally equivalent, but YST2 makes a greater contribution to the pool of Yst molecules. Alternatively, since the two Yst proteins differ in primary structure in several positions it is possible that the two proteins may only partially overlap in function with one or the other or both proteins also having unique functional characteristics that contribute differentially to growth rate.

To examine the extent to which the functions of the two Yst proteins overlap, we asked whether each of the YST genes could complement phenotypes linked to the disruption of the other. Strains harboring disrupted alleles of either YST1 or YST2 were transformed with wild-type copies of either YST1 or YST2 cloned into the low copy number vector pRS315(26) . Fig. 5shows that plasmid-borne copies of YST1 or YST2 are able to complement the growth defects associated with disruptions in either gene. These data suggest that the two Yst proteins have largely overlapping functions during growth on rich media. However, we cannot rule out the possibility that the two proteins may have distinct functions under growth conditions that were not examined here.

Distribution of Epitope-tagged Yst1 in Cell Extracts Fractionated by Sucrose Gradient Centrifugation

Mammalian, Arabidopsis, and U. caupo p40/37-LRP proteins have been shown to be polysome-associated and preferentially associated with 40 S ribosomal subunits(3, 11, 12, 13) . To determine if the Yst proteins had a similar distribution, we examined the distribution of epitope-tagged Yst1 in cell extracts fractionated by sucrose gradient centrifugation. Yst1 was tagged with the human c-myc epitope, which is recognized by the monoclonal antibody 9E10, as described under ``Materials and Methods.'' The epitope-tagged Yst1 complements phenotypes linked to the disruption of either or both YST genes indicating that it is functional (data not shown). Fig. 6, lane 2, shows that the 9E10 antibody recognizes a protein with an apparent molecular mass of approximately 30 kDa in YST1-disrupted cells transformed with epitope-tagged YST1 on a low copy number plasmid. This protein is of the size predicted for epitope-tagged Yst1. A weaker signal in this size range is found in extracts from cells transformed with YST1 alone (Fig. 6, lane 1). This weak signal corresponds to an abundant protein in whole cell extracts that cross-reacts with either the primary or secondary antibody. When cell extracts are fractionated by differential centrifugation, virtually all of the epitope-tagged Yst1 is found in the ribosomal pellet (lane 4), whereas the abundant cross-reacting protein is localized to the soluble fraction (lane 3).


Figure 6: Distribution of epitope-tagged Yst1 in extracts fractionated by differential centrifugation. Cell extracts were prepared by disrupting cells with glass beads using conditions outlined by Baim et al.(22) . Lanes 1 and 2 contain equal amounts of cell extracts derived from cells transformed with pRS315 plasmids harboring either the YST1 gene or the YST1 gene with the c-myc tag. Extracts from cells transformed with YST1/c-myc fusion were fractionated by centrifugation for 30 min at 75,000 rpm in a TLA100.2 rotor. The ribosomal pellet was suspended in buffer equal to that of the supernatant. Equal amounts of each fraction were loaded in lanes 3 and 4. Proteins were fractionated by SDS-polyacrylamide gel electrophoresis, transferred to nitrocellulose, and blotted with the monoclonal antibody 9E10. The 9E10 antibody recognizes epitope EQKLISEEDL derived from human c-myc(25) .



To analyze the distribution of epitope-tagged Yst1 among ribosomal components, extracts were fractionated by sucrose gradient centrifugation. Fig. 7, panel A, shows that the epitope-tagged Yst1 is found in several regions of the gradient. The bulk of the epitope-tagged Yst1 is distributed in a broad peak that coincides with polysomes. Epitope-tagged Yst1 is also found in a peak that coincides with 80 S monosomes. Finally, there appears to be a small amount of epitope-tagged Yst1 in a region of the gradient that coincides with 40 S subunits. In this gradient 40 S subunits appear as a shoulder to the main absorbance peak which corresponds to the soluble fraction. To better evaluate the apparent association of epitope-tagged Yst1 with 40 S subunits, gradients were run for a longer time to separate the small ribosomal subunits from the soluble fraction. Fig. 7, panel B, shows after the longer centrifugation time 40 S subunits are clearly resolved from the soluble fraction and that the epitope-tagged Yst1 protein cosediments with 40 S subunits. Signals found in soluble fractions appear to be from the abundant cross-reacting proteins although we cannot rule out a small amount of the epitope-tagged Yst1 protein in this region of the gradient.


Figure 7: Distribution of epitope-tagged Yst1 in extracts fractionated by sucrose gradient centrifugation. Except where noted, extracts were prepared and fractionated by sucrose gradient centrifugation as described by Baim et al.(22) . Gradients were fractionated and the absorbance at 254 nm was monitored using an ISCO model 185 density gradient fractionator and a UA-5 absorbance detector. Fraction 1 represents the top of each gradient. Aliquots of each fraction were precipitated with trichloroacetic acid, run on SDS-polyacrylamide gels, transferred to nitrocellulose and blotted with the monoclonal antibody 9E10. Blots are shown below the absorbance tracings. Panel A, centrifugation was for 5 h at 22,000 rpm in an SW28.1 rotor. Panel B, same as panel A except that centrifugation was for 12 h.



Loss of Yst Proteins Alter Polysome Profiles

While several studies have reported that p40/37-LRP proteins are associated with ribosomal components, none of these studies addressed whether they are necessary for protein synthesis. To determine if the loss of yeast Yst protein influences translation rates we examined polysome distributions in strains disrupted in either YST1 or YST2. Fig. 8, panel A, shows that polysome profiles from the strain disrupted in YST2 differs substantially from wild type. Relative to wild type, there is a shift from larger to smaller polysomes. Similar results were obtained for strains disrupted in YST1 but they were less pronounced than with YST2 (data not shown). In addition to the shift in polysomes, extracts from the disrupted strains also have higher steady-state levels of 60 S ribosomal subunits. Assessment of 40 S subunit levels in these gradients is complicated since they run as a shoulder to the major absorbance peak at the top of the gradient. Therefore, gradients were run for longer periods of time to resolve 40 S subunits. Fig. 8, panel B, shows that the amount of free 40 S subunits are reduced in extracts from the strain disrupted in YST2 relative to wild type. However, the 60-80 S region of this gradient shows a rather unusual shape with a shoulder between the 60 and 80 S peaks. This shoulder may be the consequence of the sedimentation-induced dissociation of 80 S monosomes(29) . Foiani et al. (23) have shown that inactive 80 S couples can be distinguished from 80 S couples engaged in translation by their sensitivity to dissociation by high salt. Fig. 8, panel C, shows gradients run for extended periods of time in high salt. Under these conditions, 40 S subunits can be detected in extracts from disrupted strains but are still reduced in amount relative to wild-type extracts. To more specifically address the overall reduction in 40 S subunits in the mutant strains, extracts were prepared and gradients run under conditions of low magnesium ion concentration where polysomes and 80 S monosomes dissociate into 40 and 60 S subunits(23) . Fig. 8, panel D, shows that relative to wild type 40 S subunits in extracts from strains disrupted in YST2 are reduced by 20 to 35%.


Figure 8: Polysome profiles from wild-type and YST2-disrupted strains. Extracts were prepared and fractionated as described in Fig. 7. Dashed lines, wild-type extracts; solid lines, extracts from a YST2-disrupted strain. Panel A, centrifugation was for 5 h at 22,000 rpm. Panel B, centrifugation was for 12 h at 22,000 rpm. Panel C, extracts were adjusted to 0.8 M NaCl and layered onto gradients made in 0.7 M NaCl(23) . Centrifugation conditions were as described for panel B. Panel D, extracts were prepared and fractionated under low Mg conditions(23) . Centrifugation conditions were as described for panel B.




DISCUSSION

We report here the isolation and characterization of two yeast genes, YST1 and YST2, that encode members of the S2 family of ribosomal proteins and are homologous to genes encoding p40/37-LRP proteins in a number of eukaryotic organisms. Yst/p40/37-LRP proteins are highly conserved, exhibiting over 60% sequence identity between yeast and humans. The mammalian p40/37-LRP proteins have been implicated in diverse processes, from playing a role in defining the dorsal/ventral axis in the developing mouse retina (9) to serving as a precursor for the 67-kDa laminin receptor(4) . Despite their importance, little is known regarding the specific function of p40/37-LRP proteins in these processes. The results reported here demonstrate that the yeast Yst proteins are essential components of 40 S ribosomal subunits. In addition, we show that these proteins are required for translation and contribute to the assembly and/or stability of the 40 S subunit.

Based largely on observations that p40/37-LRP proteins cosediment with ribosomal components during fractionation through sucrose gradients, several studies suggested that p40/37-LRP proteins from mammals and plants were components of the translational machinery(3, 11, 12, 13) . In these experiments the p40/37-LRP proteins were found in fractions containing polysomes and in earlier regions of gradients containing monosomes and individual ribosomal subunits. In addition, a significant amount of the total p40/37-LRP protein was found in fractions containing soluble proteins. Treatments that disrupted polysomes in Arabidopsis and mammalian extracts led to somewhat different conclusions regarding localization of p40/37-LRP protein. The Arabidopsis p40 protein appeared to be preferentially associated with 40 S subunits after polysome disruption, while the mammalian p40 protein appeared to be distributed in particles larger and more heterogeneous than 40 S subunits. While the nature of these larger particles was unclear, at least a fraction of the mammalian p40 protein appears to be associated with 40S subunits, since Tohgo et al. (12) showed that purified preparations of mammalian 40 S subunits contained p40/37-LRP protein.

Consistent with the view that members of the Yst/p40/37-LRP family of proteins are ribosomal components is the observation that the YST genes share two properties with genes known to encode ribosomal proteins in yeast. First, the yeast genome contains two virtually identical YST genes. While redundant genes are generally uncommon in S. cerevisiae, almost half of the ribosomal proteins are encoded by duplicated genes(30) . Second, the YST genes each appear to contain an intron, another phenomenon that is relatively rare in yeast but prevalent in genes encoding ribosomal proteins. While these characteristics are not unique to genes encoding ribosomal proteins, they are consistent with a role in translation(31) .

Both physical and functional properties of the Yst proteins also indicate that they are ribosomal components. Garrels et al. (32) found that Yst proteins are abundant in yeast whole cell extracts. Moreover, they reported that the Yst proteins were physically associated with ribosomes. Our data confirm this association and extend it by showing that the Yst proteins are components of the 40 S ribosomal subunit. Furthermore, our studies are the first to demonstrate that the association of a member of the Yst/p40/37-LRP with ribosomes is of functional importance rather than a fortuitous association. Disruption of either of the YST genes has a pronounced effect on polysome profiles. Relative to wild type, strains lacking one or the other of the Yst proteins have fewer 40 S subunits and polysomes but show a pronounced increase in the level of free 60 S subunits. Similar effects on the relative amount and distribution of ribosomal subunits have been reported for disruptions in genes coding for other small subunit ribosomal proteins in yeast(33, 34, 35) . The reduction in 40 S subunits and polysomes seen in strains disrupted in either YST1 or YST2 is physiologically relevant, since these strains have decreased growth rates relative to wild type and cells lacking both YST genes are inviable.

Garcia-Hernandez et al. (3) have pointed out that the Arabidopsis p40/37-LRP protein has certain characteristics in common with the acidic class of ribosomal proteins. These properties include an acidic isoelectric point, distribution between ribosome-associated and soluble states, and physiological and developmental control over the distribution of p40/37-LRP protein between these two states. Similar properties have also been reported for the mouse and U. caupo p40 proteins(11, 13) . Like their counterparts, the Yst proteins have acidic isoelectric points: Yst1 = 4.67, Yst2 = 4.7(32) . In contrast to the results reported for mammalian, U. caupo, and Arabidopsis p40/37-LRP proteins, there did not appear to be a significant fraction of soluble Yst proteins in yeast cell extracts. However, we examined the distribution of Yst proteins only in extracts from log phase cells, so it is possible that, under other growth conditions, the amount of soluble Yst protein may be different. In this regard it is worth noting that the distribution of Arabidopsis p40/37-LRP protein between soluble and ribosome-associated states has been reported to be influenced by growth parameters; young, actively growing cell cultures contain relatively low amounts of soluble protein compared with older cultures(3) . Clearly, more studies are necessary in yeast cells before a definitive statement can be made regarding the distribution of Yst proteins between soluble and ribosome-associated states.

Members of the acidic class of ribosomal proteins are widely distributed in nature and are found in multiple copies in large ribosomal subunits. These proteins have been linked to the ribosomal GTPase center and are important for the association of soluble factors with ribosomes(36, 37) . Some of these proteins, while not absolutely required for protein synthesis, have been shown to promote optimal ribosome function both in vivo and in vitro(37) . The P0 acidic protein, in contrast, is essential(38) . P0 appears to mediate the interaction of the other members of the acidic class of ribosomal proteins with subunits and may also be necessary for other aspects of 60 S function.

While the Yst/p40/37-LRP proteins have certain characteristics in common with the acidic class of ribosomal proteins, there are also substantial differences. In contrast to the acidic proteins of the 60 S subunit, the Yst/p40/37-LRP proteins are components of the 40 S subunit. Moreover, unlike the acidic proteins of the 60 S subunit that play a key role in elongation, our results indicate that the Yst proteins likely influence initiation rather than elongation rates, since we see a dramatic shift to smaller polysomes in strains disrupted in the YST genes. While part of this decrease in initiation is likely the result of a reduction in 40 S subunits, 40 S subunits that are not polysome-associated in the disrupted strains have distinctive properties that suggest that they may also be defective in initiation. Extracts from strains disrupted in YST2 have no free 40 S subunits but instead contain a new peak that migrates between the 60 S subunits and 80 S monosomes. This new peak, which is not observed in wild-type extracts, may be a consequence of sedimentation induced dissociation of 80 S couples(29) . The appearance of the new peak in disrupted extracts suggests that it may be composed of ribosomal subunits with distinctive properties. These properties may be linked to a decreased initiation rate since the new peak can be dissociated into ribosomal subunits under high salt conditions known to selectively dissociate inactive 80 S couples that accumulate in cells blocked in initiation(23) . Whether the 40 S subunits present in the new peak contain Yst protein is not known.

A potential functional parallel between the Yst/p40/37-LRP proteins and the acidic proteins of the 60 S subunit is their association with soluble factors. As noted above, the acidic ribosomal proteins appear to play an important role in the association of soluble factors such as EF2 with elongating ribosomes(37) . Interestingly, mammalian p40 protein is found as a contaminant in purified preparations of eIF-4A, suggesting that these two proteins may interact(11, 39) . In this respect there is an intriguing parallel between p40 and its bacterial homolog, E. coli ribosomal protein S2 (Eco S2). A mutation in the rpsB gene coding for Eco S2 is suppressed in a dosage-dependent manner by a member of the DEAD-box family of proteins, a family which also includes eIF-4A(40) . Whether these physical and genetic linkages with DEAD-box proteins relate to the function of p40 and Eco S2 proteins in translation must await further studies.

In addition to their role in protein synthesis, mammalian p40/37-LRP proteins also appear to function as precursors for the 67-kDa high affinity laminin receptor. The basis for recruiting p40/37-LRP proteins to the cell surface to function in this capacity has not been established but it may be linked to their nucleic acid-binding properties. Guo et al. (41) have shown that the region of p40/37-LRP thought to bind laminin also binds heparin. They proposed that p40/37-LRP may contribute to the function of the 67-kDa laminin receptor by interacting with heparin found tightly associated with laminin molecules. Furthermore, they proposed that since many components of the protein synthetic machinery interact with nucleic acids and many nucleic acid-binding proteins have been shown to interact with heparin, these binding properties might contribute to the interaction of the 67-kDa laminin receptor with laminin/heparin complexes. The results reported here showing that the Yst proteins bind to a DNA cellulose column are consistent with the possibility that they may be nucleic acid binding proteins, lending support to the hypothesis that members of the p40/37-LRP family of proteins may contribute to the function of the 67-kDa laminin receptor via their ability to interact with nucleic acids. Recent observations indicate that the recruitment of members of the Yst/p40/37-LRP family to the cell surface to function as laminin receptors is not restricted to mammals and that this may be an important route by which pathogenic fungi such as Candida albicans and Pneumocystis carinii interact with basement membranes in their hosts(42, 43) .


FOOTNOTES

*
This work was supported in part by United States Public Health Service Grant GM40632, and grants from the University of Louisville Medical Research Committee and the Jewish Hospital Foundation (to S. R. E.). 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) M88277 [GenBank](YST1) and U33756 [GenBank](YST2).

§
To whom correspondence should be addressed. Tel.: 502-852-5222; Fax: 502-852-6222; SRELLI01{at}ULKYVM.LOUISVILLE.EDU.

(^1)
The abbreviations used are: 37-LRP, 37-kDa laminin receptor precursor; bp, base pair(s); kb, kilobase pair(s).


ACKNOWLEDGEMENTS

We thank Jeff Miles for assistance in sequencing and plasmid constructions, and Lee Hartwell for supporting the initial stages of the cloning of YST1.


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