Nucleotide sequence, messenger RNA stability ... - ACS Publications

Biochemistry 1991, 30, 1780-1787

1780

Nucleotide Sequence, Messenger RNA Stability, and DNA Recognition Elements of cys- 14, the Structural Gene for Sulfate Permease I1 in Neurospora crassat,$ James S. Ketter,f Gabor Jarai, Ying-Hui Fu, and George A. Marzluf* Departments of Biochemistry and Molecular Genetics, The Ohio State University, Columbus, Ohio 43210 Received September 19, 1990; Revised Manuscript Received November 9, 1990

11, a member of the sulfur regulatory circuit, is presented. The cys-14 gene contains four introns with consensus splice site sequences and is transcribed from four closely spaced initiation sites located approximately 20 bp upstream of the ATG initiation condon. The translated CYS14 protein is composed of 781 amino acids with a molecular weight of 87 037 and contains 12 potential hydrophobic membrane-spanning domains. cys-4 m R N A was found to turn over with a half-life of approximately 15 min, which presumably contributes to the regulation of sulfate permease I1 function. The cys-14 gene is highly expressed, but only in cells subject to sulfur limitation, and is turned on by the positive-acting CYS3 sulfur regulatory protein. Results are presented which show that CYS3 protein binds with higher affinity to D N A fragments which contain two or three tandem copies of a binding site sequence. Analyses of binding site specificity via mutated binding site elements showed that different regions of the partially symmetrical CYS3 binding site are important for recognition ABSTRACT: The complete nucleotide sequence of the cys-14 gene which encodes sulfate permease

by the CYS3 regulatory protein.

T h e sulfur regulatory circuit of the filamentous fungus Neurospora crama is composed of a set of genes which encode enzymes of sulfur metabolism that are only expressed when cellular levels of sulfur become limited. These sulfur catabolic enzymes include aryl sulfatase, choline sulfatase, an extracellular protease, and various permeases which are responsible for the uptake of sulfur metabolites from the environment (Metzenberg & Parson, 1966; Marzluf, 1970, 1972a; Pall, 1971; Hanson & Marzluf, 1975). Sulfur catabolite repression exerts a global, parallel control over the entire set of sulfur catabolic enzymes, and is mediated by at least two control genes. A major positive-acting control genes, cys-3, encodes a regulatory protein which is required to activate the structural genes of the circuit (Marzluf & Metzenberg, 1968; Paietta et al., 1987). The CYS3 protein possesses a !eucine zipper and an adjacent basic region, which together constitute a DNA binding domain (Fu et al., 1989; Fu & Marzluf, 1990). A distinct negative-acting control gene appears to prevent cys-3 expression when cellular levels of sulfur are high (Burton & Metzenberg, 1972). Thus, a cascade of regulatory elements act within the sulfur circuit and include sulfur repression mediated by scon that controls the expression of the cys-3 control gene, which in turn regulates the various structural genes of the entire circuit. N . crassa possesses two distinct sulfate transport systems, which can readily be distinguished by simple biochemical properties, and which appear to be encoded by separate, unlinked genes (Marzluf, 1970). The dual sulfate transport systems are both members of the sulfur circuit and are controlled by sulfur repression and by both the cys-3 and scon control genes. Both sulfate permease species are also developmentally regulated. Sulfate permease I, encoded by the

cys- 13 gene, occurs primarily in conidiospores, whereas permease 11, encoded by cys-14, is mainly found in mycelia (Marzluf, 1970). Interestingly, the sulfate transport systems turn over with a half-life of approximately 2 h, whereas aryl sulfatase, one of the cytoplasmic sulfur catabolic enzymes, appears to be very stable (Marzluf, 1972b). The structural gene for sulfate permease 11, cys-14, has been cloned, and its expressison has been shown to be highly regulated at the level of mRNA accumulation by sulfur repression and by the cys-3 and scon genes (Ketter & Marzluf, 1988). The expression of the related enzyme, aryl sulfatase, has also been found to occur at the level of mRNA accumulation (Paietta, 1989), thus suggesting that the entire set of structural genes of the sulfur circuit is controlled at the transcription level. The cys-3 regulatory protein has been expressed in Escherichia coli and shown to be a sequence-specific DNA binding protein which binds at three distinct sites in the promoter region of cys-14 (Fu & Marzluf, 1990). It is apparent that a detailed characterization of representative structural genes will contribute to our understanding of the operation of the sulfur regulatory circuit. We present here the entire nucleotide sequence of the cys-14 gene and its flanking regions. The cys-14 gene appears to contain 4 introns and to encode a large protein which contains 12 potential helical membrane spanning domains, suggesting that it may reside in the cell membrane and act as a sulfate ion transporter. Studies of the expression and turnover of cys-14 mRNA are also presented which imply that the synthesis of sulfate permease I1 is rapidly modulated when environmental circumstances change. Finally, the results of experiments to define the specificity of CYS-3 binding to the cys-14 promoter DNA recognition elements are reported.

'This research was supported by US. Public Health Service Grant GM-23367 from the National Institutes of Health. *The nucleic acid sequence in this paper has been submitted to GenBank under Accession Number 305321. *Address correspondence to this author of the Department of Biochemistry, The Ohio State University, 484 West 12th Ave., Columbus, OH 43210. Present address: National Institutes of Health, Building 37, Bethesda, MD 20892.

MATERIALS AND METHODS Nested Deletion Subclones. Three DNA fragments of the cys- 14+ gene region were subcloned into pBLUESCRIPT KS(+), and nested deletions were created by first treating the plasmid DNA with two restriction enzymes, one of which leaves a 3' overhang. This DNA was then digested in a controlled fashion using exonuclease 111, followed by treatment with mung bean nuclease, prior to closure with T4 DNA ligase

0006-2960/9 1/0430- 1780$02.50/0

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122 124 127

404 403 402

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223 221 218 2 14 2'3 211 208 205 204 20 1

I : Physical map and DNA sequencing strategy for the cys-14 gene. The boldface arrow under the restriction map of the gene region displays the direction of transcription. The thin arrows reveal the sequencing strategy which employed deletion clones and oligonucleotide primers. At the botton are displayed the three subcloned fragments (2.1,0.7, and 2.9 kb) and deletion subclones derived from them, each with its numerical designation. The bars represent the DNA segment which is present in each of the deletions. Restriction sites: H, HindIII; Xh, Xhol; Xb, Xbal; Sa, Sall; A, AaaI; P, Pstl; Ba, BamHI; e, EcoRI; and Sp, SphI. FIGURE

and subsequent transformation into competent E . coli cells. DNA Sequencing and Primer Extension Mapping. DNA sequencing was accomplished by the dideoxy chain termination method (Sanger et al., 1977) using [ C X - ~ ~ P I ~ and A T Pa modified T7 bacteriophage DNA polymerase, "Sequenase" (U.S. Biochemical Corp.). Nucleotide sequences were read from autoradiograms using a digitizer ("Gel reader") and analyzed by Pustell software (International Biotechnologies). Oligonucleotide primers were synthesized on an Applied Biosystems Model 380B DNA synthesizer. SI nuclease mapping was used to map the 3' end of the cys-14 transcript. A 2.1 -kb band-isolated Sal1 fragment was labeled by fill-in with the Klenow fragment of DNA polymerase and hybridized with mRNA at 55 OC, and mapping was conducted with the procedure of Birk and Sharp (1977). The 5' end of the cys-14 transcript was mapped by primer extension. One hundred nanograms of a primer with the sequence 5'-TTCGTCGGCAGGAATTCC-3' was added to IO pg of poly(A+) RNA in 45 pL of 1.1 X M-MLV reverse transcriptase buffer [ 1 X buffer consists of 50 mM Tris (pH 7.5)/75 mM potassium chloride/ IO mM dithiothreitol/3 mM magnesium chloride]. This mixture was heated to 65 OC for 2 min and then cooled slowly (over 30-60 min) to 30 "C. The mixture was then incubated for another 15 min at 30 OC, followed by the addition of 0.5 pL each of 10 mM dCTP, dGTP, and dTTP, 2.5 pL of [ ( U - ~ ~ P I ~ A and T P200 , units of M-MLV reverse transcriptase. The reaction was allowed to proceed at 37 "C for 25-30 min. The extended primer products were recovered by the addition of 2.5 FL of 1 M NaCl and I30 p L of ethanol, followed by freezing in liquid nitrogen and pelleting in a microfuge. The pellet was redissolved in IO p L of water, and 2 pL was mixed with 2 p L of DNA sequencing loading buffer and analyzed on a 6% denaturing polyacrylamide gel. Screening a XgtlO cDNA Library. Poly(A+) RNA from cells grown under low sulfur conditions (for the derepression

of sulfur circuit genes) was isolated and uSed for the preparation of a cDNA library in the Ec6RI site of the XgtlO vector. This library represented aFproximately 1O6 clones after amplification, and had a phage titer of approximately 5 X lo9 pfu/mL. Approximately 750 000 plaques were screened at high density. After three rounds of screening, pure plaques of the desired recombinant phage clones were isolated. The cDNA inserts were cloned into the EcoRI site of pBLUESCRIPT and analyzed by DNA sequencing. Dot Blot Analysis. Neurospora crassa total RNA was isolated by the method of Reinert et al. (1981) from wild-type cells grown on media containing either 5 mM methionine (sulfur repression) or 0.25 mM methionine (sulfur derepression), and the poly(A+) RNA was then purified as described (Aviv & Leder, 1972). The blotting of the RNA samples to nitrocellulose membrane and subsequent hybridization were carried out according to Thomas (1980) and White and Bancroft (1982). In Vitro Mutagenesis. In vitro mutagenesis was conducted with the Muta-Gene kit as described by the manufacturer (Bio-Rad, Richmond, CA). Approximately 400 ng (0.4 pmol) of uracil-containing single-stranded DNA was annealed to 5 pmol of phosphorylated mutagenic primer and 2.5 pmol of phosphorylated M13 universal primer in 20 mM Tris-HCI, (pH 7.4)/2 mM magnesium chloride/50 mM sodium chloride, at a final volume of 10 pL. The mixture was heated to 70 OC for 2 min and then incubated at 37 OC for 10 min. The universal primer anneals upstream from the mutagenic primer, and helps to stabilize it when the extending DNA reaches it. The room temperature extension step was increased from 5 to 30 min to allow this stabilization to occur. DNA Mobility Shift Experiments. The CYS3 protein was expressed in E . coli, and gel mobility shift experiments were performed as previously described (Fu & Marzluf, 1990). The DNA fragments were radioactively labeled by filling in recessed ends with the Klenow fragment of DNA polymerase

Ketter et al.

1782 Biochemistry, Vol. 30, No. 7, 1991 A

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1050

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1020

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1670

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1690 a

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1720

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a

1820

1830

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1840

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1930 a

1940 a

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1950 a

1960 a

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Structural Gene of Sulfate Permease 11 1910

1990

1980

Biochemistry, Vol. 30, No. 7, 1991 1783

2000

2010

*

2500

2510

t

t

2520

2540

2530

t t t t Too CCC OOT AT2 "E On: TAC Coc Tpc Oa: (wi WT Cm AAC TAT dc AAC R-p Gly Ile Fhe Val Tyr Arg Fhe Gly Glu Gly Leu Am Tyr Val Aan

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2010 t

2080

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2100

2110

2130 t

2140 t

2150

2160

2110

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2210

2180

2190

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2230

2220

2260

2210 t

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2280

2290

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2300

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2330

2320

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2340

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Arg Arg

2650 t

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2360

t

t

2310

a

2380

2990

a

t

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2620

2630

2640

t

a

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W

2660 t

2610

2680

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2690

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2100

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2120

2110

2140

2730

2750

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2190

2180

2110

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2810

2800

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2350

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2240

t

2250 t

2590

t

t

Arg Pro

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2580

t

2610

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2570

t

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2560

t

2600

2120 t

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coo Aal

2550

2830

2840

2850

t A

t

t A

2900

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2860

2910

2810

t ~

2880

t

t

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2920

2930

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4 2950

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t

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2400

2410 2420 2430 t t t t On3 TU3 AAC OX lW Aa: MCI ax: OOC CXC d A 033 'ET Om Val Ser Asn Arg T r p Ihr Lop Arg Akr Leu Val Ala 9er Oly

2440

t

TIE W T UTC RM Oly Val

2960 t

2910

2980

t mAC-T-E~MCA-TAPXIWM

t

3030 t

3040 t

TmCACCIjATOGATAAT-"AT=

2450

2460

t

t

2410

2480

2490

a

t

t

2990 t

3050

*

3000 t

3010

3020 t

t

3060

3010

3080

t

t

t

3090

*

AC

(w:lu3mCOAmanAAQOn:wmQMAtCCACAM3mmm Asp Ser Leu Arg Ihr Ala Val Gln Arg Qlu A m Him rsS Gly G 4 Val

FIGURE 2: Nucleotide sequence of cys-14 and flanking DNA. The translated CYS14 protein, consisting of 781 amino acids, is shown directly below the nucleotide sequence. The polypurine stretch and pyrimidine-rich stretch in the 5'4anking region are underlined, and the putative TATA box at -90 is boxed. The four transcription start sites (at + I , 8, 12, and 18) and the 3'-termination site at 2992 are indicated by closed circlcs. An ATTTA motif implicated in mRNA stability at 2970 is boxed. The four introns begin at nucleotides +221, +581, + I 169, and

+2101.

using one [32P]dNTPin the first or second position. Gels were wrapped in cellophane and exposed to Kodak XAR-5 film with the use of an intensifying screen. RESULTS Nucleotide Sequence of the cys-14+ Gene. Because of the relatively large size of the cys-14' gene region and the particular arrangement of restriction sites within it, three separate fragments of this gene were subcloned for use in creating deletions (Figure I ) . Deletion clones were generated in both orientations with the 2.9-kb fragment, and in one direction for the 0.7-kb middle fragment (Figure 1) and for the 2.1-kb fragment (which was subsequently found to contain only 500 bp of the transcribed region). The initial sequencing was performed by using either the M13 "Universal Primer" or "Reverse Primer", depending on the orientation of a particular clone. A series of primers was synthesized by using these sequence data, corresponding to the nucleotide sequence at various intervals along the DNA. By use of both the deletion subclones and specific primers, the entire sequence was determined twice for each DNA strand. A restriction map for cys- 14 and the location of the deletion subclones and oligonucleotide primers, as well as the overall sequencing strategy, are presented in Figure I . The entire nucleotide sequence of the cys- 14' gene and its flanking regions is presented in Figure 2. Localization and Transcript Mapping of cys-14. Selected nested deletion subclones were employed as radiolabeled probes of a set of identical Northern blots of derepressed poly(A+) RNA. The failure of a particular clone to hybridize to the cys-14' message indicated that it lay entirely outside the

transcribed region. This method allowed a rapid approximate localization of the gene. In this assay, deletion 506 gave a negative result whereas deletion 507 was positive, indicating that the 3' end of the cys-14 transcript lies between these two deletions. Similarly, DNA of deletion 21 8 failed to hybridize with cys-14 mRNA whereas deletion 214 was positive, indicating that the 5' end of the transcript occurs in the region between them (results not shown). These results indicated that the transcribed region was approximately 3 kb in length, which was in good agreement with the size estimated for the cys-14 transcript on Northern blots. The 3' end of the transcript was determined by S1 nuclease mapping using the 2.1-kb Sal1 fragment of the gene region as a probe. Poly(A+) RNA was isolated from wild-type cells grown under either sulfur-repressed or -derepressed conditions. As evident in Figure 3, one intense band of approximately 500 bp is visible in the derepressed RNA lane. A second band of approximately 600 bp is also visible in this lane, and may represent a second, less frequently used polyadenylation site. The probe is visible as a 2.1-kb band. The 5' end of the cys-14 transcript was determined by a primer extension assay. An oligodeoxynucleotide (5'TTCGTCGGCAGGAATTCC) specific to the 5' region of the cys-14 transcript was used as a primer with template RNA from either sulfur-repressed or -derepressed wild-type cells, since only the latter should possess cys-14 mRNA. Figure 3 shows that four strong bands were present only in the lane representing derepressed RNA. All four potential start sites occur at T residues, clustered together 15, 21, 25, and 32 nucleotide bases upstream of the ATG initiation codon (Figure 2).

~

1784 Biochemistry, Vol. 30, No. 7, 1991

Ketter et al.

1 2 3 4 5

1 2 3 4 5

A B C D

2100

506

394

344

298

.-C

E

220 '

200

5,

H L

T A A C A A

C

C A T

T

3'

Transcript mapping. (Left panel) S 1 nuclease mapping of the 3' end of the cys-14transcript. Lanes 1 and 2 show S1 mapping with poly(A+) RNA from sulfur-repressed and -derepressed cells, respectively, using an end-labeled 2.1-kb Sal1 fragment as the probe; lanes 3 and 5, negative controls in which the labeled DNA probe alone was denatured and treated with S1 nuclease; lane 4,probe alone (not denatured) treated with S1 nuclease. The position of molecular weight markcrs is shown to the right. (Right panel) primer extension mapping of the 5' end of the cys-14transcript. Poly(A+) RNA from SUIfur-repressed (H) and derepressed cells (L) was used as template for primer extension as described under Materials and Methods. The four start sites, each corresponding to a T residue, are shown. FIGURE 3:

Isolation and Analysis of cDNA Clones. Approximately 1 50 000 plaques from a Xgt 10 cDNA library were screened with pJSK- 1A'; 12 plaques hybridized to this cys-14-specific probe. Three rounds of screening produced a number of pure phage clones. Purified phage DNAs were digested with EcoRI (to excise the insert DNA) and analyzed on an agarose gel. The clone which possessed the largest insert, 2.4 kb, was selected for subcloning and further analysis. This insert was cloned into pBLUESCRlPT and sequenced. This clone possessed a stretch of approximately 85 deoxyadenylate residues corresponding to a very substantial poly(A) tail. The

0

15

30

60

Time FIGURE 4: Dot blot analysis of cys-14mRNA stability. (Upper panel) RNA samples were blotted to nitrocellulose using a Minifold apparatus. Equal amounts of RNA were loaded in all dots within a row; 8,4,2, or 1 pg in rows A, B, C, and D, respectively. To verify that equal amounts of RNA were loaded, the blot was hybridized with a P-tubulin probe in control experiments (not shown). Lane 1, RNA from uninduced celk served as a negative control; lanes 2-5, RNA isolated from induced cells transferred to S-repression medium for 0, 15,30,and 60 min, respectively. (Lower panel) Kinetics of cys-14 mRNA turnover. Radioactivity within each dot was measured in a scintillation counter, and the average value of the four different RNA amounts for each time point was plotted, yielding a half-time estimated to be 15 min.

3' end identified by the cDNA corresponds to the region predicted by the 3'Sl nuclease mapping results. The locations of three introns (2, 3, and 4) were positively established by directly comparing the cDNA and genomic sequences. The presence of nonsense codons in all three reading frames as well as an analysis of codon usage bias (International Biotechnologies, Inc./Pustell; data not shown) in the upstream portion of the cys-14' gene indicated the presence of one more intron 5' to the region present in this cDNA clone. We were unable to find a 5' cDNA clone. The position of the putative intron 1 was therefore deduced from a combination of reading frame and splice site consensus data. The positions of the cys-l4+ introns and the predicted amino acid sequence of the sulfate permease I1 protein are given in Figure 2. StabiZity ofcys-14 mRNA. It has been known for some time that the activity of the sulfate transport systems displays turn over, but until now it has not been possible to determine the stability of mRNAs which correspond to the genetically defined permease genes. To examine the stability of the cys-14 mRNA, a dot blot analysis was carried out. Wild-type cells were grown overnight under sulfur-derepressing conditions (low methionine) and then transferred to medium containing high methionine (sulfur repression). Cultures were quickly cooled and harvested at different time points, and mRNA was isolated. In a preliminary experiment, we used hourly intervals; however, no cys-14 message could be detected even after 1 h (data not shown). Then mRNA was isolated from cells that were growing for 0-60 min after transfer. RNA samples were blotted and hybridized with the cDNA of cys-14 (Figure 4). After au-

Biochemistry, Vol. 30, No. 7, 1991 1785

Structural Gene of Sulfate Permease I1 1

2

3

4

5

6

7

8

,---

r----------

!

TTCGCT: GATGCCA~TTCATT;

c

I l l I l l

C A C GTA ATA GTG C A T T A T

CGG GCC

3

2

r FIGURE 5: CYS3 protein binding to DNA fragments with a variable number of binding sites. Mobility shift experiments were conducted with CYS3 protein and labeled DNA fragments as described under Materials and Methods. Lanes 1 and 2, DNA fragment with zero binding sites; lanes 3 and 4, with one binding site; lanes 5 and 6, two binding sites; lanes 7 and 8, three binding sites. Samples in lanes 1, 3, 5 , and 7 lacked CYS3 protein and thus showed the mobility of the free DNA probes. Samples of lanes 2,4,6, and 8 contained CYS3 protcin (0.6 pg).

toradiography, the nitrocellulose was cut into pieces, and the activity of the individual dots was measured in a liquid scintillation counter. The counts obtained were used to calculate the half-life of the mRNA, estimated to be 15 min (Figure 4). Binding of CYS3 Protein to Promoter Elements. The CYS3 protein has been shown to bind to three sites upstream of cys- 14 and to a single site upstream of the cys-3 gene itself (Fu & Marzluf, 1990). Two of the binding sites are approximately 20 bp in length, whereas the other two are twice this length, suggesting that these latter sites actually each constitute two adjacent binding sites. A synthetic 27 bp double-stranded oligonucleotide was synthesized which contains a 19 bp region identical with the proximal CYS3 binding site in the cys- 14 promoter; this 19 bp sequence is protected by the CYS3 protein from DNase I cleavage in vitro (Fu & Marzluf, 1990). It was of interest to determine whether DNA fragments carrying varying numbers of this specific binding site could bind a corresponding number of CYS3 protein molecules and whether fragments having a greater number of binding sites would appear to have a higher affinity for CYS3. The 27 bp oligonucleotide was cloned into the ClaI site of pBLUESCRIPT, and clones were isolated which had zero, one, two, and three tandem copies of this target sequence. Treating these DNAs with BamHI and KpnI yielded fragments carrying different numbers of binding sites. Figure 5 shows the results of mobility shift experiments designed to examine the binding of CYS3 protein to DNA fragments containing different numbers (0, 1, 2, or 3) of binding sites. DNA binding was specific, and clear mobility shifts of these DNA fragments were observed. The number of shifted bands in each case corresponded to the number of binding sites. The control DNA fragment lacking a CYS3 binding site was not shifted. Moreover, the affinity of the CYS3 protein for DNA fragments with either two or three tandem binding sites was considerably greater than with the fragment containing only a single site (Figure 5 ) . Analysis of Mutant Binding Sites. The 19 bp binding site was mutagenized in vitro as described under Materials and Methods to determine which regions of the binding site are important for interaction with the CYS3 protein. Four mutant oligonucleotides were employed, each containing three adjacent bases altered from the sequence of the wild-type binding site. Figure 6 shows the sequences of the four mutant binding sites, compared with the wild-type site.

BINDING SITE FIGURE 6:

Mutant CYS3 binding sites. (Upper panel) The wild-type 19 bp CYS3 binding site is displayed above the substituted bases for each of the four mutated binding sites. CAT motifs are underlined or overlined, and 6 bp homology blocks at each end are enclosed by dashed lines. Solid circles indicate the presumed center of symmetry. (Lower panel) The binding of CYS3 protein to DNA fragments containing each of the binding sites is displayed as a percentage of that observed with the wild-type site. These results were obtained by densitometric analysis of the fraction of the DNA fragment which was shifted in each case, normalized to that obtained with the wild-type binding site.

t

2

3 --

1

t

4

tb

0.6 3

0 0.6

3

0 0.6 3 Om6 3

0 0.6

3

0 0.6 3

PROTEIN FIGURE 7: Mobility shift assays with CYS3 protein and mutated binding sites. Standard shift assays were conducted by incubating CYS3 protein with DNA fragments containing a single copy of the wild-type and each of the four mutant binding sites shown in Figure 6. The identity of the binding sites is shown above each lane, and the amount of CYS3 protein used in each sample is shown below each lane. Mutants 1 and 2 and a wild-type standard were run in one gel, and a separate gel was utilized for mutants 3 and 4 and a wild-type standard. The same amount of each probe was loaded in each lane, and the (+) probe without cys-3 protein runs at the same position as found with the four mutant probes (not shown). JIS

The results of CYS3 protein binding assays with the wildtype and mutant DNA binding sites are shown in Figure 7. It is important not to conduct binding assays with too high a protein concentration, because even a weak binding site could become fully occupied and thus appear to be nearly equivalent to the wild-type site, e.g., which did occur to some extent when 3 pg of CYS3 protein was used (Figure 7). The CYS3 protein concentration used (0.6 pg) for comparison of the binding sites is within the most sensitive range of the saturation curve (not shown). It is obvious that the CYS3 protein has considerably less affinity for DNA fragments containing mutant binding sites than those with a wild-type site. The mobility shift experiments shown in Figure 7 were quantitated by densito-

1186 Biochemistry, Vol. 30, No. 7, 1991

Ketter et al. (137)

122)

/ NH2

FIGURE 8: Postulated secondary structure and membrane localization of the CYS14 protein. The 12 putative membrane-spanning helices are represented as cylinders. The number of amino acid residues in other segments of the protein is shown in parentheses. The CYS14 protein has been demonstrated by immunochemical studies to be localized in the membrane fraction of the cells (Jarai and Marzluf, unpublished results).

metric scanning. These data are displayed in Figure 6 and reveal that all four mutant sites show reduced binding by CYS3 in comparison to a wild-type site, although the mutant binding sites clearly differ substantially from each other in binding affinity. DISCUSSION We report here the complete nucleotide sequence of the cys- 14 gene. The cys-14 gene appears to be transcribed from 4 closely spaced start sites located 15-32 nucleotide bases upstream of an ATG initiation codon. A possible TATA box (TATATAT) is situated 90 bp upstream of the first start site, a distance typical of fungal genes (Hahn et al., 1985). The cys-14 gene possesses 4 introns of 162, 87, 72, and 58 bases, each with a Neurospora consensus 5' and 3' splice site and internal branch point sequences. The size and distribution of these introns resemble those of the @-tubulingene of N. crassa, which contains 6 introns ranging from 57 to 240 bases in length (Orbach et al., 1986). A number of potentially significant features are found in the nucleotide sequence of cys-14. A stretch of 26 bases consisting entirely of purine residues occurs from nucleotides -258 to -233, and a pyrimidine-rich stretch occurs at -2 17 to -204. Such features are found in other Neurospora genes, but their function, if any, has not been established, although they may play a role in producing bent DNA structures (Satchwell et al., 1986) or in excluding nucleosomes (Morse & Simpson, l988), thus possibly affecting cys-14 expression. A possible CAAT box is found at -140 and could contribute to the high level of expression of cys-14 which occurs during sulfur derepression. The cys-14 mRNA is approximately 3 k B in length and contains untranslated regions of approximately 30 and 234 bases at its 5' and 3' end, respectively. Mutants of cys-14 gene are deficient in sulfate permease 11, but it has remained unclear whether this gene encoded a membrane transporter protein or in some other way contributed to the sulfate transport system. The cys-14 gene appears

to encode a large protein comprised of 781 amino acids with a molecular weight of 87037. Analysis of the translated CYS14 protein indicated that it contains 10-12 hydrophobic regions, each with a length of at least 20 amino acids, which may constitute helical membrane-spanning domains (Figure 8). In this respect, it is similar to other carrier proteins (Bell et al., 1986; Kaback, 1987; Maiden et al., 1987). The sequences of 2 other carrier proteins of Neurospora have recently been reported, a 590-residue phosphate permease (Mann et al., 1989) and a putative quinic acid permease of 537 amino acids (Geever et al., 1989). Both of these carrier proteins also appear to possess a secondary structure with 12 membranespanning helices (Mann et al., 1989; Geever et al., 1989). The CYS14 protein is larger than these other two carrier proteins and appears to have longer amino- and carboxy-terminal segments that extend beyond the portions of the protein anchored within the membrane. A relatively long hydrophilic domain occurs between the last two membrane domains, similiar to an even longer domain between the eighth and ninth membrane-spanning helices of the phosphate carrier protein (Mann et al., 1989). Recent immunochemical studies have demonstrated that the CYS 14 protein is indeed highly localized within the membrane fraction of N. crassa cells (Jarai and Marzluf, unpublished results). The CYS14 protein contains a number of possible phosphorylation sites and at least potential glycosylation sites. A search of the NBRF data base failed to locate any proteins with extensive homology to CYS14, although the ribose transporter protein of E . coli (Bell et al., 1986) has a stretch of 13 amino acids with 70% homology; these homologous regions occur in the amino terminus of each protein, although their function, if any, is unknown. The sulfate transport systems of N . crassa turn over with a functional half-life of approximately 2 h. In contrast, aryl sulfatase, a sulfur metabolic enzyme, whose synthesis is regulated in a parallel fashion to that of the sulfate permeases, appears to be very stable (Marzluf, 1972b). Uptake of me-

Biochemistry, Vol. 30, No. 7 , 1991 1787

Structural Gene of Sulfate Permease I1 tabolites represents a first point at which control of an entire metabolic pathway could be exerted, and thus permease species may be highly regulated at several levels, e.g., synthesis, function, and stability. We showed here that the cys-14 mRNA, which encodes sulfate permease 11, turns over with a half-life of approximately 15 min. This relatively rapid turnover of mRNA ensures that synthesis of the permease stops quickly when sulfur repression is established. Mammalian messenger RNAs which exhibit rapid turnover frequently contain one or more copies of an AUUUA motif which mediates mRNA instability (Shaw & Kamen, 1986). The nontranslated 3’ region of cys-14 mRNA contains 1 copy of this motif approximately 25 nucleotides upstream from the polyadenylation site, although it is unknown whether such an element confers messenger instability in filamentous fungi. The cys-3 regulatory gene controls the expression of the entire set of structural genes of the sulfur circuit. The CYS3 protein, which contains a DNA binding domain composed of a leucine zipper and an adjacent basic region, binds to three sites upstream of the cys-14 gene and to a single site upstream of its own structural gene (Fu & Marzluf, 1990). Two of these binding sites are approximately 20 bp in length whereas the other two are twice as long, perhaps comprising two adjacent binding sites. We showed here that DNA fragments which contain two or three of the short binding elements in tandem repeats (whose sequence was dictated by the proximal site upstream of cys- 14) appear to bind a corresponding number of CYS3 molecules as revealed by multiple shifted bands. The DNA fragments with two or three tandemly repeated elements also clearly possess a greater affinity for CYS3 than does a fragment with a single binding site. These results may thus explain the clear size differences observed for natural CYS3 binding sites and the fact that a DNA with one of the longer binding elements showed greater affinity for CYS3 than did a fragment with a short element (Fu & Marzluf, 1990). In order to examine what regions of a binding site were important for binding of the CYS3 regulatory protein, we compared four mutant binding sites with a wild-type site. Each mutated site had three adjacent bases altered with purines replaced by pyrimidines, and vice-versa, with the expectation that such changes might have an obvious effect upon CYS3 binding. The substituted bases span most of the binding site, as defined by DNase I protection studies, and were designed to examine elements of the apparent imperfect dyad (Figure 6). I t is clear that the two halves of the partial dyad within the binding site are not equivalent. Mutants 1 and 2 occur on the right side of the center of symmetry and cause a relatively small decrease in binding by CYS3. Mutants 3 and 4, on the other hand, show stronger effects, particularly mutant 4, with which more than 99% of the binding by CYS3 has been lost. Thus, the nucleotide bases in the homology block which were altered in binding site mutant 4 are very important for CYS3 binding to the proximal element upstream of cys-14. Each of the CYS3 binding sites contains at least one and usually several CAT sequences, which were suggested to comprise a core binding sequence (Fu & Marzluf, 1990). Mutants 2 and 3 each alter a single CAT sequence, but on opposite sides of the apparent center of symmetry, and they retain 10%(mutant 3) or 18% (mutant 2) of the wild-type level of CYS3 binding. Thus, these two regions are nearly equivalent and are important for CYS3 binding although a change in either CAT motif does not lead to a complete loss of Cys3 protein binding. It should be noted that mutant 2 resulted in generation of a CAT motif in the lower strand but caused the loss of symmetry. The various binding elements recognized

by CYS3 have different nucleotide sequences, perhaps not surprisingly since CYS3 is a global regulatory protein which turns on different structural genes to different extents. The results presented here represent only a beginning in understanding the precise manner by which the CYS3 protein activates gene expression. ACKNOWLEDGMENTS We thank Richard Swenson and Jane Tolley, Ohio State Biochemical Instrument Center, who prepared the oligonucleotides used in this work.

REFERENCES Aviv, H., & Leder, P. (1972) Proc. Natl. Acad. Sci. U.S.A. 69, 1408-1412. Bell, A. W., Buckel, S. D., Groarke, J. M., Hope, J. N., Kingsley, D. H., & Hermodson, M. A. (1986) J . Biol. Chem. 261, 7652-7658. Birk, A. J., & Sharp, P. A. (1977) Cell 12, 721-732. Burton, E. G., & Metzenberg, R. L. (1 972) J . Bacteriol. 109, 140-1 5 1. Fu, Y. H., & Marzluf, G. A. (1990) J . Biol. Chem. 265, 11942-1 1947. Fu, Y. H., Paietta, J. V., Mannix, D. G., & Marzluf, G. A. (1989) Mol. Cell. Biol. 9, 1120-1 127. Geever, R. F., Huiett, L., Baum, J. A,, Tyler, B. M., Patel, V. B., Rutlege, B. J., Case, M. E., & Giles, N. H. (1989) J . Mol. Biol. 207, 15-34. Hahn, W., Hoar, E. T., & Guarente, L. (1985) Proc. Natl. Acad. Sci. U.S.A.82, 8562-8566. Hanson, M. A., & Marzluf, G. A. (1975) Proc. Natl. Acad. Sci. U.S.A.72, 1240-1244. Kaback, H. R. (1987) Biochemistry 26, 2071-2076. Ketter, J. S., & Marzluf, G. A. (1988) Mol. Cell. Biol. 8, 1504-1 508. Maiden, M. C., Davis, E. O., Baldwin, S. A., Moore, D. C. M., & Henderson, P. J. (1987) Nature 325, 641-643. Mann, B. J., Bowman, B. J., Grotelueschen, J., & Metzenberg, R. L. (1989) Gene 83, 281-289. Marzluf, G. A. (1970) Arch. Biochem. Biophys. 138,254-263. Marzluf, G. A. (1972a) Biochem. Genet. 7 , 219-233. Marzluf, G. A. (1972b) Arch. Biochem. Biophys. 150, 7 14-724. Marzluf, G. A,, & Metzenberg, R. L. (1968) J . Mol. Biol. 33, 423-437. Metzenberg, R. L., & Parson, J. W. (1966) Proc. Natl. Acad. Sci. U.S.A.55, 629-635. Morse, R. H., & Simpson, R. T. (1988) Cell 54, 285-287. Orbach, M. J., Porro, E. B., & Yanofsky, C. (1986) Mol. Cell. Biol. 6, 2452-26412. Paietta, J. V. (1989) Mol. Cell. Biol. 9, 3630-3637. Paietta, J. V., Akins, R. A., Lambowitz, A. M., & Marzluf, G. A. (1987) Mol. Cell. Biol. 7 , 2506-251 1. Pall, M. L. (1971) Biochim. Biophys. Acta 233, 201-214. Reinert, W. R., Patel, V. B., & Giles, N. H. (1 98 1 ) Mol. Cell. Biol. 1, 829-835. Sanger, F., Nicklen, S., & Coulson, A. R. (1 977) Proc. Natl. Acad. Sci. U.S.A.74, 5463-5467. Satchwell, S . C., Drew, H. R., & Travers, A. A. (1986) J . Mol. Biol. 191, 659-675. Shaw, G., & Kamen, R. (1986) Cell 46, 659-667. Thomas, P. S. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 5201-5205. White, B. A., & Bancroft, F. C. (1982) J . Biol. Chem. 257, 8569-8572.