The Wilhelmine E. Key 1989 invitational lecture. Organization and regulation of the qa (quinic acid) genes in Neurospora crassa and other fungi

In Neurospora crassa, five structural genes and two regulatory genes control the use of quinic acid as a carbon source. All seven genes are tightly linked to form the qa gene cluster. The entire cluster, which has been cloned and sequenced, occupies a continuous DNA segment of 17.3 kb. Three pairs of genes are divergently transcribed, including the two regulatory genes that are located at one end of the cluster and that encode an activator (qa-1F) and a repressor (qa-1S). Three of the structural genes (qa-2, qa-3, and qa-4) encode inducible enzymes that catalyze the catabolism of quinic acid. One structural gene (qa-y) encodes a quinate permease; the function of the fifth gene (qa-x) is still unclear. Present genetic and molecular evidence indicates that the qa activator and repressor proteins and the inducer quinic acid interact to control expression at the transcriptional level of all the qa genes. The activator, the product of the autoregulated qa-1F gene, binds to symmetrical 16 base pair upstream activating sequences located one or more times 5' to each of the qa genes. A conserved 28 amino acid sequence containing a six cysteine zinc binding motif located in the amino terminal region of the activator has been directly implicated in DNA binding. Evidence for other functional domains in the activator and repressor proteins are discussed. Indirect evidence suggests that the repressor is not a DNA-binding protein but forms an inactive complex with the activator in the absence of the inducer.(ABSTRACT TRUNCATED AT 250 WORDS)

DNA sequence, organization and regulation of the qa gene cluster of Neurospora crassa

In Neurospora, five structural and two regulatory genes mediate the initial events in quinate/shikimate metabolism as a carbon source. These genes are clustered in an 18 x 10(3) base-pair region as a contiguous array. The qa genes are induced by quinic acid and are coordinately controlled at the transcriptional level by the positive and negative regulators, qa-1F and qa-1S, respectively. The DNA sequence of the entire qa gene cluster has been determined and transcripts for each gene have been mapped. The qa genes are transcribed in divergent pairs and two types of transcripts are associated with each gene: basal level transcripts that initiate mainly from upstream regions and are independent of qa regulatory gene control, and inducible transcripts that initiate downstream from basal transcripts and are dependent on qa-1F binding to a 16 base-pair sequence. We discuss how both types of transcription relate to the organization of the qa genes as a cluster and how this may impose constraints on gene dispersal.

Expression of qa-1F activator protein: identification of upstream binding sites in the qa gene cluster and localization of the DNA-binding domain

The qa-1F regulatory gene of Neurospora crassa encodes an activator protein required for quinic acid induction of transcription in the qa gene cluster. This activator protein was expressed in insect cell culture with a baculovirus expression vector. The activator binds to 13 sites in the gene cluster that are characterized by a conserved 16-base-pair sequence of partial dyad symmetry. One site is located between the divergently transcribed qa-1F and qa-1S regulatory genes, corroborating prior evidence that qa-1F is autoregulated and controls expression of the qa-1S repressor. Multiple upstream sites located at variable positions 5' to the qa structural genes appear to allow for greater transcriptional control by qa-1F. Full-length and truncated activator peptides were synthesized in vitro, and the DNA-binding domain was localized to the first 183 amino acids. A 28-amino acid sequence within this region shows striking homology to N-terminal sequences from other lower-eucaryotic activator proteins. A qa-1F(Ts) mutation is located within this putative DNA-binding domain.

DNase I hypersensitive sites within the inducible qa gene cluster of Neurospora crassa

DNase I hypersensitive regions were mapped within the 17.3-kilobase qa (quinic acid) gene cluster of Neurospora crassa. The 5'-flanking regions of the five qa structural genes and the two qa regulatory genes each contain DNase I hypersensitive sites under noninducing conditions and generally exhibit increases in DNase I cleavage upon induction of transcription with quinic acid. The two large intergenic regions of the qa gene cluster appear to be similarly organized with respect to the positions of constitutive and inducible DNase I hypersensitive sites. Inducible hypersensitive sites on the 5' side of one qa gene, qa-x, appear to be differentially regulated. Employing these and previously published data, we have identified a conserved sequence element that may mediate the activator function of the qa-1F regulatory gene. Variants of the 16-base-pair consensus sequence are consistently found within DNase I-protected regions adjacent to inducible DNase I hypersensitive sites within the gene cluster.

Rearrangement mutations on the 5' side of the qa-2 gene of Neurospora implicate two regions of qa-1F activator-protein interaction

Transcriptional activation of the Neurospora crassa qa genes normally requires the positive regulatory gene, qa-1F+, whose function is controlled by the inducer quinic acid and by the product of the negative regulatory gene, qa-1S+. The properties of qa-1F+ activator have been examined in transcriptional mutations of the qa-2 structural gene, in which activator-independent transcription of qa-2 (qa-2ai mutants) occurs in strains having a qa-1F- gene. Seven qa-2ai mutants with DNA rearrangements in different 5' regions of qa-2 were analyzed in qa-1F+ strains. In five with rearrangements at position -190 or further upstream, expression of the qa-2 gene was inducible, and induction was accompanied by a change in the initiation site for transcription from position -45, characteristic of constitutive initiation in qa-2ai mutants to position +1, characteristic of the induced wild type. In two mutants with breakpoints at positions -86 and -53, qa-2 transcription initiated from upstream sequences within the rearrangements but not at the +1 site, and qa-2 expression was noninducible. The results indicate that (i) sequences between positions -190 and -86 are required for positive control of initiation at position +1, and (ii) negative control does not require sequences downstream of position -86. Additional evidence suggests that the product of the qa-1F+ gene in the noninduced state may also interact with distal upstream sequences positioned midway between divergently transcribed qa genes.

The qa repressor gene of Neurospora crassa: wild-type and mutant nucleotide sequences

The qa-1S gene, one of two regulatory genes in the qa gene cluster of Neurospora crassa, encodes the qa repressor. The qa-1S gene together with the qa-1F gene, which encodes the qa activator protein, control the expression of all seven qa genes, including those encoding the inducible enzymes responsible for the utilization of quinic acid as a carbon source. The nucleotide sequence of the qa-1S gene and its flanking regions has been determined. The deduced coding sequence for the qa-1S protein encodes 918 amino acids with a calculated molecular weight of 100,650 and is interrupted by a single 66-base-pair intervening sequence. Both constitutive and noninducible mutants occur in the qa-1S gene and two different mutations of each type have been cloned and sequenced. All four mutations occur within the predicted coding region of the qa-1S gene. This result strongly supports the hypothesis that the qa-1S gene encodes a repressor. All four mutations are located within codons for the last 300 amino acids of the qa-1S protein. The mutations in three of the mutants involve amino acid substitutions, while the fourth mutant, which has a constitutive phenotype, contains a frameshift mutation. The two constitutive mutations occur in the most distal region of the gene, possibly implicating the COOH-terminal region of the qa repressor in binding to its target. The two noninducible mutations occur in a region proximal to the constitutive mutations, possibly implicating this region of the qa repressor in binding the inducer.

Autogenous regulation of the positive regulatory qa-1F gene in Neurospora crassa

In Neurospora crassa, the qa-1F regulatory gene positively controls transcription of all genes in the quinic acid (qa) gene cluster. qa-1F is transcribed at a low, uninduced level but is subject to strong (50-fold), autogenous regulation as well as to control by the negative regulatory gene, qa-1S, and the inducer quinic acid. Cloned qa-1F DNA sequences hybridize to two related mRNAs of 2.9 and 3.0 kilobases. When wild-type (qa-1F+) cultures are transferred to inducing conditions, qa-1F mRNA increases for 4 h, remains somewhat level, and decreases after 8 to 10 h. That this control is autogenous, i.e., that the qa-1F gene controls the synthesis of its own mRNA, is indicated by the presence of approximately the same low level of qa-1F mRNA in poly(A)+ RNA from noninducible qa-1F- mutant cultures under inducing conditions as that observed in uninduced wild-type cultures. The qa-1S gene also regulates the transcription of qa-1F, since a qa-1S- mutant, whether in noninducing or inducing conditions, contains a level of qa-1F mRNA that corresponds to the low level observed in uninduced wild-type cultures. These results corroborate the hypothesis (M. E. Case and N. H. Giles, Proc. Natl. Acad. Sci. USA 72:553-557, 1975; V. B. Patel, M. Schweizer, C. C. Dykstra, S. R. Kushner, and N. H. Giles, Proc. Natl. Acad. Sci. USA 78:5783-5787, 1981; L. Huiet, Proc. Natl. Acad. Sci. USA 81:1174-1178, 1984) that the qa-1F gene encodes an activator protein and acts positively in controlling transcription of itself and the other qa genes.

Gene organization and regulation in the qa (quinic acid) gene cluster of Neurospora crassa

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Structure of a Neurospora RNA polymerase I promoter defined by transcription in vitro with homologous extracts

A Neurospora in vitro transcription system has been developed which specifically and efficiently initiates transcription of a cloned Neurospora crassa ribosomal RNA gene by RNA polymerase I. The initiation site of transcription (both in vitro and in vivo) appears to be located about 850 bp from the 5' end of mature 17S rRNA. However, the primary rRNA transcripts are normally cleaved very rapidly at a site 120-125 nt from the 5' end in vitro and in vivo. The nucleotide sequence surrounding the initiation site has been determined. The region from -16 to +9 exhibits partial homology to the corresponding sequences from a wide variety of organisms including yeast, but the most striking similarity is to the initiation region from Dictyostelium discoideum which displays 73% homology to the Neurospora sequence from -23 to +47. The Neurospora sequences from -96 to +97 have been shown to be sufficient for transcription. This region contains two sequences displaying 8/9 bp matches to elements of the 5S rDNA promoter.

Genetic control of chromatin structure 5' to the qa-x and qa-2 genes of Neurospora

The roles of the qa-1F and qa-1S regulatory genes of Neurospora in modifying the chromatin structure of two qa structural genes have been studied by mapping DNase I hypersensitive sites in qa chromatin isolated from wild-type, qa-1F- (non-inducible) mutants, qa-1Sc (constitutive) mutants, qa-1S- (non-inducible) mutants, and from activator protein-independent mutants of qa-2 (qa-2ai). DNase I hypersensitive sites in the 5' region of the qa-x and qa-2 structural genes increase in number and sensitivity upon induction of transcription with quinic acid. Both qa-1F- and qa-1Sc mutations are associated with alterations in the DNase I sensitivity of the qa-x and qa-2 region, the latter mutations resulting in the common 5'-flanking region of these genes being accessible to DNase I. The qa-1F+ genotype is correlated with increased DNase I cleavage in the -200 to -88 region of qa-2, a region previously implicated in qa-1F regulation of RNA polymerase II access to the qa-2 promoters.

A leucine tRNA gene adjacent to the QA gene cluster of Neurospora crassa

A single tRNALeu gene has been localized and sequenced from Neurospora crassa. It is located only 375 bp from the qa gene cluster and it is the only tRNA or 5S rRNA gene within this cloned 37 kb region. The gene encodes a tRNALeu with the anti-codon AAG, and unlike the other nuclear eukaryotic tRNALeu (AAG) gene sequenced (from C. elegans), contains an intervening sequence of 27 bp. The Neurospora tRNALeu (AAG) is 84% and 73% homologous respectively to the C. elegans and bovine tRNALeu (AAG), and is 84% homologous to a Drosophila tRNALeu (CAA). However, it is only 65% homologous to a yeast tRNALeu (CAA) and there is little conservation of intervening sequences or V-loop regions. The gene hybridizes to at least 16 other DNA fragments in the Neurospora genome. Its expression does not seem to be linked to that of the qa genes.

Accurate transcription of homologous 5S rRNA and tRNA genes and splicing of tRNA in vitro by soluble extracts of Neurospora

We have developed soluble extracts from Neurospora crassa capable of accurately and efficiently transcribing homologous 5S rRNA and tRNA genes. The extracts also appear to quantitatively end-process and splice the primary tRNA transcripts. Although the extracts could not transcribe a heterologous (yeast) 5S rRNA gene, they did transcribe a yeast tRNALeu gene and slowly process the transcripts. In addition, we have developed a novel strategy for rapidly sequencing uniformly labelled RNAs using base-specific ribonucleases. We have used this procedure to verify the identity of the in vitro transcripts and processing products.

Cis-acting and trans-acting regulatory mutations define two types of promoters controlled by the qa-1F gene of Neurospora

The function of the qa-1F positive regulatory gene of Neurospora has been studied by mapping the initiation sites for transcription of the clustered qa structural genes in wild type, in qa-1F mutants, and in cis-acting activator protein-independent mutants of qa-2 (qa-2ai mutants). Each structural gene under qa-1F control has two to four promoters. The qa-2ai mutations, which include point mutations and small (68-84 bp) duplications 5' to qa-2, allow qa-1F-independent transcription from surrounding qa promoters independently of the orientations and positions (up-stream or downstream) of teh mutations relative to the promoters. However, one subset of promoters was not reactivated by the enhancer-like elements created by these mutations, and qa-1F mutants selectively deficient in the activation of these promoters have been identified. Therefore, the qa-1F regulatory gene appears to control two types of promoters that have different requirements for activation.

Point mutations and DNA rearrangements 5' to the inducible qa-2 gene of Neurospora allow activator protein-independent transcription

Expression of the qa-2 gene of Neurospora crassa normally requires a functional activator protein encoded by qa-1F. Twelve transcriptional mutants of the qa-2 gene have been isolated in qa-1F- strains, and these allow partial expression of qa-2 (1-45% of induced wild type) in the absence of functional activator protein. All 12 mutants have been characterized by genomic (Southern) blot hybridization and the DNAs of 5 have been cloned and sequenced. Eight mutations consist of large DNA rearrangements within a 500-base-pair region 5' to the qa-2 gene. One large rearrangement mutation, located 378 base pairs before the normal site of transcription initiation, causes exceptional levels of qa-2 transcription (45% of induced wild type) from near the normal initiation site. Two of the other four mutations cloned involve tandem duplications (68 and 84 base pairs) of the same upstream region (centered at nucleotide - 145), and two involve "point" mutations (at nucleotides -200 and -95) that closely flank the duplicated region. With one possible exception, none of the mutations appears to involve changes directly associated with RNA polymerase II binding and hence they differ from analogous mutations in comparable prokaryotic systems. The overall results suggest that at least some of the large DNA rearrangement mutations may be acting as upstream activator elements, possibly by juxtaposing enhancer-like sequences, whereas the duplications and point mutations may define a region of qa-2 regulation, for instance at the level of RNA polymerase II access.

Chimeric plasmid that replicates autonomously in both Escherichia coli and Neurospora crassa

A hybrid pBR322 plasmid (designated pDV1001) containing two functional Escherichia coli antibiotic resistance genes (kanr and camr) and a qa-2+ gene from Neurospora crassa transforms N. crassa qa-2- mutants to qa-2+ with a frequency of ca. 5 X 10(-5) per regenerated spheroplast (ca. 100 transformants per microgram of plasmid DNA). This plasmid can replicate autonomously without integrating into the N. crassa genome. The autonomously replicating hybrid plasmid was detected in N. crassa transformants by Southern gel hybridizations. DNA from these transformants can be recovered by retransformation back into E. coli aroD recipients and selection for chloramphenicol resistance. These E. coli transformants complement an aroD mutant. The hybrid plasmid DNA present in the E. coli transformants remains unchanged on the basis of DNA restriction enzyme analyses. The original, nonhomokaryotic N. crassa transformants can be maintained on a selective medium, but there is as yet no evidence that the self-replicating plasmid can be transmitted through meiosis. In addition, the self-replicating plasmid often integrates into the N. crassa genome and then is inherited in a generally stable fashion through meiosis. Our findings suggest that this plasmid, or some derivative of it, will prove useful as a routine shuttle vector for cloning genes in N. crassa.

Characterization of Neurospora crassa catabolic dehydroquinase purified from N. crassa and Escherichia coli

1. Neurospora crassa catabolic dehydroquinase has been purified from N. crassa and Escherichia coli. 2. Protein-sequence and gel-electrophoretic data show that apparently pure, homogeneous native dehydroquinase is a mixture of intact and proteinase-cleaved enzyme monomers. 3. Protein-sequence data and steady-state kinetics show that the catabolic dehydroquinase gene of N. crassa is expressed with fidelity in E. coli.

Genetical and biochemical aspects of quinate breakdown in the filamentous fungus Aspergillus nidulans

In the ascomycetous fungus Aspergillus nidulans, the expression of two inducible, contiguous or closely linked genes (qutB and qutC) which encode enzymes for quinate breakdown to protocatechuate, appears to be controlled by the product of a tightly linked third genet (qutA). The qut gene cluster locates on chromosome VIII. The catalytic steps required for this conversion are dehydrogenase, dehydroquinase, and dehydratase, and these activities are induced by the presence of quinate in a similar manner. The dehydroquinase enzyme has been purified and shown to be multimeric, consisting of 20-22 identical subunits of approximately 10,000 MW. The enzyme has a pI value of 5.84, a Km of 5 x 10(-4) M, and an amino acid composition that lacks tryptophan and cysteine. The enzyme also cross-reacts with rabbit antibodies raised against Neurospora crassa catabolic dehydroquinase.

5'-Untranslated sequences of two structural genes in the qa gene cluster of Neurospora crassa

The coding regions of two genes (qa-2 and qa-3) in the qa gene cluster of Neurospora crassa have been localized by nucleotide sequence analysis combined with data on previously determined NH2-terminal amino acid sequences for the proteins that these genes encode. The start point of transcription for each of these genes has been determined by nuclease S1 mapping experiments with poly(A)+RNA isolated from quinic acid-induced cultures of N. crassa. The sequences of approximately 200 nucleotides 5' to the start point of transcription have been compared with each other and with those of other eukaryotes. The results show that neither of these regions for the qa-2 nor the qa-3 genes share any significant homology with sequences apparently conserved in higher eukaryotic promoters (-25 and -70 regions). However, the qa-2 and qa-3 sequences do show homology with each other in these regions. Comparison of the 5'-flanking regions of these Neurospora genes with those of several Saccharomyces cerevisiae genes reveals a number of similarities in the region preceding the translation initiation codons.

Genetic organization and transcriptional regulation in the qa gene cluster of Neurospora crassa

A transcription map of the qa gene cluster of Neurospora crassa has been constructed by using cloned DNA fragments as hybridization probes. The mRNAs encoded in the previously identified qa-2 (3-dehydroquinate hydro-lyase, EC 4.2.1.10), qa-4 (dehydroshikimate dehydratase), qa-3 (quinate:NAD+ 3-oxidoreductase, EC 1.1.1.24), and qa-1 (regulatory protein) genes have been characterized. In addition, mRNAs encoded in two new genes in this cluster (qa-x, qa-y) have been identified. Regulation of this system occurs at the level of transcription and is under the combined control of quinic acid and the qa-1 protein. The qa cluster represents a group of adjacent coding sequences which occupy approximately 18 kilobases in linkage group VII. The expression of the qa-1 gene appears to be constitutive but also autoregulated. mRNAs encoded in genes flanking the qa gene cluster have also been identified.

Genetic regulation of the qa gene cluster of Neurospora crassa: induction of qa messenger ribonucleic acid and dependency on qa-1 function

An in vitro protein-synthesizing system (rabbit reticulocyte) was programmed with total polyadenylated messenger ribonucleic acid from wild type and various mutants in the qa gene cluster of Neurospora crassa. The products of two of the qa genes, quinate dehydrogenase (qa-3+) and dehydroshikimate dehydratase (qa-4+), were identified by specific immunoprecipitation and sodium dodecyl sulfate-slab gel electrophoresis. The results indicated that for both genes induction of a specific enzyme activity by quinic acid depends on the de novo synthesis of a specific polypeptide and on the de novo appearance of specific messenger ribonucleic acid detectable by the in vitro translation assay. Furthermore, the results indicated that the appearance of this messenger ribonucleic acid is under the control of the qa-1 gene. The simplest interpretation of these results appears to be that induction of enzyme activity in the qa system is mediated by events at the transcriptional level.

Identification and characterization of recombinant plasmids carrying the complete qa gene cluster from Neurospora crassa including the qa-1+ regulatory gene

The early reactions in the catabolism of quinic acid in Neurospora crassa are controlled by at least four genes which are clustered on linkage group VII. Three of the loci (qa-2, qa-4, and qa-3) encode enzymes that convert quinic acid to protocatechuic acid. The fourth gene (qa-1) encodes a positive regulatory protein which, in the presence of quinic acid, leads to the de novo synthesis of the other proteins in the qa cluster. This communication describes a series of recombinant plasmids that span 36.5 kilobases of linkage group VII and contain the coding sequences for qa-2, qa-4, qa-3, and the qa-1 regulatory protein. The plasmids were obtained by partial digestion of wild-type N. crassa DNA with EcoRI and ligation into the cosmid cloning vehicle pHC79. Two independently derived plasmids (pMSK331 and pMSK335), each containing 36.5-kilobase inserts, were shown by transformation back into N. crassa to contain the entire qa gene cluster. A preliminary physical organization of the gene cluster is presented. An improved procedure for the transformation of N. crassa with plasmid DNA is also described.

The cloning and analysis of the aroD gene of E. coli K-12

A 5.6-kb PstI fragment containing the structural gene (aroD) for 5-dehydroquinate hydrolyase (DHQase) of Escherichia coli K-12 has been cloned into recombinant plasmid pJKK12. The bacterial fragment contains two Bg/II, one HpaII, one SalI and one XhoI site, but no EcoRI, HindIII or BamHI sites. the DHQase activity extracted from strains harboring pJKK12 had properties identical to those of the enzyme isolated from wild-type E. coli. The native protein appears to be a dimer composed of two 31 500 dalton subunits. aroD6 strains transformed with pJKK12 had an 11-fold and 34-fold increase in activity compared to untransformed wild-type controls grown on L broth and minimal medium, respectively. No increase of dehydroquinase activity was found in polynucleotide phosphorylase deficient strains of E. coli. At least four constitutively expressed genes are encoded on the fragment.

Cloning the quinic acid (aq) gene cluster from Neurospora crassa: identification of recombinant plasmids containing both qa-2+ and qa-3+

A 22.2-kb insert of Neurospora crassa DNA containing at least two of the genes from the inducible catabolic quinic acid pathway has been cloned into the cosmid vehicle pHC79 resulting in a recombinant plasmid, pMSK308. The qa-2+ locus (which encodes catabolic dehydroquinase) is functionally expressed in both Escherichia coli and qa-2 mutants of N. crassa transformed with pMSK308 plasmid DNA. Expression of the qa-3 gene (which encodes quinate dehydrogenase) is only detected upon reintroduction into N. crassa. Results were also obtained which suggested that the qa-4 gene, which maps between qa-2 and qa-3, may also be present on both pMSK308 and the previously described plasmid pVK88. Certain anomalies in the types of N. crassa transformants obtained with pMSK308 plasmid DNA were noted.

Increased expression of a eukaryotic gene in Escherichia coli through stabilization of its messenger RNA

The expression of a cloned eukaryotic gene [catabolic dehydroquinase (3-dehydroquinate hydro-lyase, EC 4.2.1.10) (qa-2+) from Neurospora crassa] is dramatically increased (as much as 100-fold) in Escherichia coli strains deficient in polynucleotide phosphorylase (pnp) (polynucleotide: orthophosphate nucleotidyltransferase, EC 2.7.7.8) and RNase I (rna). The increased expression is controlled primarily by the absence of polynucleotide phosphorylase and appears to be specific for the eukaryotic gene. No increase in the specific activity of either chromosomal or plasmid-borne prokaryotic genes has been observed. In polynucleotide phosphorylase-deficient strains of E. coli the half-life of plasmid (pVK88, ampr qa-2+)-encoded mRNAs increases from 1.0 to 2.8 min. This increase must be due primarily to stabilization of the aq-2 mRNA because no increase in the half-lives of pBR322 vehicle mRNAs was observed in polynucleotide phosphorylase-deficient strains. These results suggest that there are inherent structural differences between prokaryotic and eukaryotic mRNAs.

Efficient transformation of Neurospora crassa by utilizing hybrid plasmid DNA

An efficient transformation system has been developed for Neurospora crassa that uses spheroplasts and pVK88 plasmid DNA. pVK88 is a recombinant Escherichia coli plasmid carrying the N. crassa qa-2(+) gene which encodes catabolic dehydroquinase (3-dehydroquinate hydro-lyase, EC 4.2.1.10) and is part of the qa gene cluster. The recipient strain carries a stable qa-2(-) mutation and an arom-9(-) mutation, thus lacking both catabolic and biosynthetic dehydroquinase activities. Transformants were selected as colonies able to grow in the absence of an aromatic amino acid supplement. These colonies were qa-2(+) and had normal levels of catabolic dehydroquinase. DNA.DNA hybridization evidence with appropriate labeled probes indicates clearly that in some instances transformation involves the integration of bacterial plasmid sequences together with the qa-2(+) gene into the N. crassa genome. On the basis of genetic, enzyme assay, and DNA hybridization data, at least three types of transformation events can be distinguished: (i) replacement of the qa-2(-) gene by the qa-2(+) gene without any effect on the expression of the other genes in the qa cluster, (ii) linked insertion of a normal qa-2(+) gene accompanied by inactivation of the adjacent qa-4(+) gene, and (iii) insertion of a normal qa-2(+) gene at an unlinked site in the N. crassa genome. This newly integrated qa-2(+) genetic material is inherited in a typical Mendelian fashion. A low level of transformation has also been obtained by using linear total N. crassa DNA. Two such qa-2(+) transformants are unlinked to the qa-2(-) gene of the recipient.

Organization of the qa gene cluster in Neurospora crassa: direction of transcription of the qa-3 gene

In Neurospora crassa, the enzyme quinate (shikimate) dehydrogenase catalyzes the first reaction in the inducible quinic acid catabolic pathway and is encoded in the qa-3 gene of the qa cluster. In this cluster, the order of genes has been established as qa-1 qa-3 qa-4 qa-2. Amino-terminal sequences have been determined for purified quinate dehydrogenase from wild type and from UV-induced revertants in two different qa-3 mutants. These two mutants (M16 and M45) map at opposite ends of the qa-3 locus. In addition, mapping data (Caseet al. 1978) indicate that the end of the qa-3 gene specified by M45 is closer to the adjacent qa-1 gene than is the end specified by the M16 mutant site. In one of the revertants (R45 from qa-3 mutant M45), the aminoterminal sequence for the first ten amino acids is identical to that of wild type. The other revertant (R1 from qa-3 mutant M16) differs from wild type at the amino-terminal end by a single altered residue at position three in the sequence. The observed change involves the substitution of an isoleucine in M16-R1 for a proline in wild type. This substitution requires a two-nucleotide change in the corresponding wild-type codon.--The combined genetic and biochemical data indicate that the qa-3 mutants M16 and M45 carry amino acid substitutions near the amino-terminal and carboxyl-terminal ends of the quinate dehydrogenase enzyme, respectively. On this basis we conclude that transcription of the qa-3 gene proceeds from the end specified by the M16 mutant site in the direction of the qa-1 gene. It appears probable that transcription is initiated from a promoter site within the qa cluster, possibly immediately adjacent to the qa-3 gene.

Constitutive expression in Escherichia coli of the Neurospora crassa structural gene encoding the inducible enzyme catabolic dehydroquinase

In Neurospora crassa the qa-2 gene, which encodes catabolic dehydroquinase, is under positive control exerted by the inducer quinic acid and an activator protein encoded in the closely linked qa-1 gene. In order to determine if this regulatory mechanism is maintained when the qa-2 gene is cloned on a recombinant plasmid and expressed in Escherichia coli, molecular cloning experiments have been performed using DNA isolated from a qa-1+ (inducible), a qa-1C (constitutive) and two qa-1 (non-inducible) strains of N. crassa. The results demonstrate that the level of expression of the qa-2 gene in E. coli is completely independent of the mutational state of the qa-1 gene. Moreover, the level of expression of the cloned qa-2 gene was unaffected by either an intracellularly produced inducer of catabolic dehydroquinase or by the general procaryotic positive effector, the CAP factor. The weight of evidence thus supports the conclusion that transcription of the N. crassa qa-2 gene in E. coli does not require the qa-1 activator protein and thus is not controlled by the same mecahnism which functions in N. crassa.

Purification of the arom multienzyme aggregate from Euglena gracilis

The arom multienzyme complex that catalyzes steps two through six in the prechorismate polyaromatic amino acid biosynthetic pathway has been purified up to 2000-fold from Euglena gracilis. The native arom aggregate has a molecular weight of approx. 249 000 based on a sedimentation coefficient of 9.5 and Stokes radius of 60 angstrom. A comparison between the arom aggregates of Neurospora crassa and Euglena gracilis and the possible phylogenetic relationships between the organisms are discussed.

Transcription and translation in E. coli of hybrid plasmids containing the catabolic dehydroquinase gene from Neurospora crassa

Two hybrid plasmids which carry the gene for Neurospora crassa catabolic dehydroquinase (C-DHQase) and complement an aroD6 (dehydroquinase-deficient) auxotroph of Escherichia coli have been analyzed. One of these contains a 2.9 kilobase (kb) fragment cloned in the HindIII site of plasmid pBR322 (pVK57) and the other contains a 6.8 kb fragment cloned in the PstI site (pVK88). Restriction enzyme mapping of these plasmids has demonstrated that the 2.9 kb fragment is totally contained within the 6.8 kb fragment. When the polarity of either the HindIII fragment or PstI fragment was reversed with respect to pBR322 no effect was observed on either the ability of the hybrid to complement an aroD- auxotroph or on the level of C-DHQase activity. In vivo transcription of plasmid pVK88 in both orientations was analyzed by RNA-DNA hybridization and by the techniques developed by Southern (1975). Approx. 40% of the plasmid-directed transcription occurred from the cloned PstI fragment and 60--70% of these N. crassa transcripts were encoded by the 2.9 kb HindIII fragment. The Southern technique allowed a further localization of the region of most extensive transcription to a 1.8 kb HindIII-EcoRI fragment. Biochemical analysis revealed that the C-DHQase protein produced by strains harboring pVK57 and pVK88 in either orientation was identical to the N. crassa enzyme. Furthermore, when these plasmids were segregated into minicells and labeled with 14C amino acids, the C-DHQase protein was synthesized at a level comparable to other plasmid-encoded proteins. Taken together, these experiments demonstrate that transcription is efficiently initiated in E. coli from a site on the cloned N. crassa DNA and that the resulting C-DHQase mRNA is efficiently and accurately translated.

Genetical and biochemical characterization of QA-3 mutants and revertants in the QA gene cluster of Neurospora crassa

The qa-3 gene, one of the four genes in the qa gene cluster, encodes quinate (shikimate) dehydrogenase (quinate: NAD oxidoreductase, ER 1.1.1.24), the first enzyme in the inducible quinic acid catabolic pathway in Neurospora crassa. Genetic analyses have localized 26 qa-3 mutants at 11 sites on the aq-3 genetic map on the basis of prototroph frequencies. Certain mutants, e.g., 336-3-10 and 336-3-3, are located at opposite ends of the qa-3 gene. Data from four-point crosses (qa-1s mutant 124 X five different qa-3 mutants in triple mutants qa-3, qa-4, qa-2) indicate the following orientation of the qa-3 gene within the qa cluster; qa-1, qa-3 mutant 336-3-10 ("left" end) qa-3 mutant 336-3-3 ("right" end), qa-4, qa-2. Ultraviolet-induced revertants have been obtained from 14 of the qa-3 mutants. The revertable mutants fall into two major classes: those that revert by changes either at the same site or at a second site within the qa-3 gene, and those that revert by unlinked suppressor mutations. The intragenic revertants can be further distinguished by quantative and/or qualitative differences in their quinate dehydrogenase activities. Some revertants with activities either equivalent to or less than wild type produce a thermostable enzyme, and others an enzyme which is thermolabile in vitro at 35 degrees. A concentration of quinic acid or shikimic acid as low as 50 micron protects the enzyme markedly from heat inactivation. The genetic organization and the orientation of the qa-3 gene are discussed with respect to its direction of transcription and to the possible localization of a promoter (initiator) region(s) within the qa gene cluster.

Purification and characterization of 3-dehydroshikimate dehydratase, an enzyme in the inducible quinic acid catabolic pathway of Neurospora crassa

3-Dehydroshikimate dehydratase catalyzes the third reaction in the inducible quinic acid catabolic pathway of Neurospora crassa and is encoded in the qa-4 gene of the qa gene cluster. As part of continuing genetic and biochemical studies concerning the organization and regulation of this gene cluster, 3-dehydroshikimate dehydratase has been purified and characterized biochemically. The enzyme was purified 1650-fold using the following techniques: 1) (NH4)2SO4 fractionation; 2) ion exchange chromatography on DEAE-cellulose; 3) gel filtration on Sephadex G-100; 4) ion exchange chromatography on Cellex QAE (quaternary aminoethyl); and 5) hydroxylapatite chromatography. 3-Dehydroshikimate dehydratase is a monomer with a molecular weight of about 37,000 and a sedimentation coefficient of 3.27 S. It has a Km value of 5.9 X 10(-4) and an average isoelectric point of 4.92. The purified enzyme is extremely sensitive to thermal denaturation but can be significantly stabilized by Mg2+ ions. The purified enzyme also exhibits maximal catalytic activity only when assayed in the presence of certain divalent cations, e.g. magnesium. The NH2-terminal residue of 3-dehydroshikimate dehydratase is proline, and its alpha-amino group is unblocked.

Purification and characterization of quinate (shikimate) dehydrogenase, an enzyme in the inducible quinic acid catabolic pathway of Neurospora crassa

The bifunctional enzyme quinate (shikimate) dehydrogenase (quinate: NAD+ oxidoreductase, EC 1.1.1.24), which catalyzes the first reaction in the inducible quinic acid catabolic pathway of Neurospora crassa, has been purified to homogeneity. The enzyme is a monomer of 41000 daltons with an s20,w = 2.94 S. However, electrophoresis under non-denaturing conditions revealed three protein species, which have both quinate and shikimate dehydrogenase activities. The enzyme, with a single binding site for both substrates, has a Km of 0.37 mM for quinate and of 1.18 mM for shikimate, although the V is about 3-fold higher with shikimate. Essential sulphydryl groups which were not localized in the active site were detected. Thermal stability of the enzyme was greatly enhanced by low concentrations of quinate, shikimate, NADH, or by high ionic strength.

Proof of de novo synthesis of the qa enzymes of Neurospora crassa during induction

In Neurospora crassa three inducible enzymes are necessary to catabolize quinic acid to protocatechuic acid. The three genes encoding these enzymes are tightly linked on chromosome VII near methionine-7 (me-7). This qa cluster includes a fourth gene, qa-1, which encodes a regulatory protein apparently exerting positive control over transcription of the other three qa genes. However, an alternative hypothesis is that the qa-1 protein simply activates preformed polypeptides derived from the three structural genes. The use of density labeling with D(2)O demonstrated conclusively that the qa enzymes are synthesized de novo only during induction on quinic acid. Native catabolic dehydroquinase (5-dehydroquinate dehydratase; 5-dehydroquinate hydro-lyase, EC 4.2.1.10) (a homopolymer of ca 22 identical subunits) has a density of 1.2790 g/cm(3) as determined by centrifugation in a modified cesium chloride density gradient. Growth in H(2)O followed by induction in 95% D(2)O shifts the density of the enzyme to 1.3130 g/cm(3), indicating de novo synthesis during induction. In the reciprocal experiment, i.e., growth in 80% D(2)O followed by induction in either 95% D(2)O or H(2)O, the densities of catabolic dehydroquinase were 1.3135 and 1.2800 g/cm(3), respectively. Because growth on D(2)O does not affect the density of the H(2)O-induced enzyme, there can be no significant synthesis of catabolic dehydroquinase prior to induction. Similar results were obtained for a second qa enzyme, quinate dehydrogenase (quinate:NAD(+) oxidoreductase, EC 1.1.1.24). Thus, induction of two qa enzymes involves de novo protein synthesis, not enzyme activation or assembly.

Expression in Escherichia coli K-12 of the structural gene for catabolic dehydroquinase of Neurospora crassa

The inducible quinic acid catabolic pathway of Neurospora crassa is controlled by four genes, the qa cluster which includes structural genes qa-2, qa-3, qa-4 for three enzymes and a regulatory gene, qa-1. In this paper we report the molecular cloning of at least the qa-2 gene which encodes the catabolic dehydroquinase (5-dehydroquinate hydro-lyase, EC 4.2.1.10). Endo.R.HindIII restriction endonuclease fragments of N. crassa DNA from a qa-1(c) (constitutive) mutant and of Escherichia coli plasmid pBR322 DNA were ligated in vitro and used to transform an aroD6 (5-dehydroquinate hydrolyase deficient) strain of E. coli K12. The recombinant plasmid (pVK55) isolated from one AroD(+) transformant (SK1518) contained, in addition to pBR322, two N. crassa HindIII fragments with molecular weights of 2.3 x 10(6) and 1.9 x 10(6). Derivatives of SK1518 cured of plasmid DNA were phenotypically Amp(s) and AroD(-). These cured strains, retransformed with pVK55, were phenotypically Amp(R) and AroD(+). Strains transformed with pVK55 possessed 5-dehydroquinate hydrolyase activity but no activity was present in any AroD(-) strain. The enzyme extracted from strains containing the recombinant plasmid was identical to N. crassa catabolic dehydroquinase by the criteria of heat stability, ammonium sulfate fractionation, immunological crossreactivity, molecular weight, and purification characteristics. This identity demonstrates that the N. crassa qa-2(+) gene is carried by the recombinant plasmid and is apparently transcribed and translated with complete fidelity. Furthermore, subunit assembly of the N. crassa polypeptides also occurs in E. coli, because the catabolic dehydroquinase is a multimer composed of approximately 20 identical subunits.

Characterization and in vitro translation of polyadenylated messenger ribonucleic acid from Neurospora crassa

Ribonucleic acid (RNA) extracted from Neurospora crassa has been fractionated by oligodeoxythymidylic acid [oligo(dT)]-cellulose chromatography into polyadenylated messenger RNA [poly(A) mRNA] and unbound RNA. The poly(A) mRNA, which comprises approximately 1.7% of the total cellular RNA, was further characterized by Sepharose 4B chromatography and polyacrylamide gel electrophoresis. Both techniques showed that the poly(A) mRNA was heterodisperse in size, with an average molecular weight similar to that of 17S ribosomal RNA (rRNA). The poly(A) segments isolated from the poly(A) mRNA were relatively short, with three major size classes of 30, 55, and 70 nucleotides. Gel electrophoresis of the non-poly(A) RNA indicated that it contained primarily rRNA and 4S RNA. The optimal conditions were determined for the translation of Neurospora mRNA in a cell-free wheat germ protein-synthesizing system. Poly(A) mRNA stimulated the incorporation of [14C]leucine into polypeptides ranging in size from 10,000 to 100,000 daltons. The RNA that did not bind to oligo(dT)-cellulose also stimulated the incorporation of [14C]leucine, indicating that this fraction contains a significant concentration of mRNA which has either no poly(A) or very short poly(A) segments. In addition, the translation of both poly(A) mRNA and unbound mRNA was inhibited by 7-methylguanosine-5'-monophosphate (m7G5'p). This is preliminary evidence for the existence of a 5'-RNA "cap" on Neurospora mRNA.

Isolation and characterization of nuclei from Neurospora crassa

A procedure was developed for isolating nuclei from either the conidial or germinated conidial growth phase of Neurospora crassa. A frozen conidial suspension was lysed by passage through a French pressure cell, and the nuclei were freed from the broken cells by repeated homogenization in an Omni-Mixer. Pure nuclei were obtained from the crude nuclear fraction by density banding in a Ludox gradient. The final nuclear yield was 20 to 30%. The nuclei had a deoxyribonucleic acid (DNA):ribonucleic acid (RNA):protein ratio of 1:3.5:7 and were active in RNA synthesis. The nuclei, stained with the DNA stain 4,6-diamidino-2-phenylindole, appeared under fluorescence microscopy as bright blue spheres, 1 micron in diameter, essentially free from cytoplasmic attachments. Chromatin extracted from the nuclei in a 70 to 75% yield by dissociation with 2 M sodium chloride and 5 M urea had a DNA:RNA:protein ratio of 1:1.05:1.7. Chromatin reconstituted from this preparation exhibited a level of RNA polymerase template activity lower than that of pure Neurospora DNA, but the maximum level of reconstitution obtained was only 10%. Fractionation of Neurospora chromatin on hydroxylapatite separated the histones from the chromatin acidic proteins. The normal complement of histone proteins was present in both the reconstituted and dissociated chromatin preparations. The acidic protein fraction exhibited a variety of bands on sodium dodecyl sulfate gel electrophoresis ranging in molecular weight from 15,000 to 70,000. The gel pattern was much more complex for total dissociated chromatin than for reconstituted chromatin.

Characterization of qa-2 mutants of Neurospora crassa by genetic, enzymatic, and immunological techniques

Genetic and complementation mapping studies using 20 qa-2 mutants defective for catabolic dehydroquinase indicate that the qa-2 gene encodes a single polypeptide chain and is the structural gene for catabolic dehydroquinase, a 220,000-molecular-weight protein composed of identical 10,000-molecular-weight subunits. Many qa-2 mutants are capable of reversion, but no evidence has yet been obtained for nonsense mutations in this gene. The biochemical consequences of the mutations in two complementing qa-2 strains (M239 and M204) have been determined. Both mutants have extremely low levels of catalytic activity and form a heterocaryon with about 4% of the wild-type activity. As assayed by immunological cross-reactivity, mutant M239 and the heterocaryon have nearly wild-type levels of native-molecular-weight catabolic dehydroquinase protein, whereas M204 has no detectable amount of this protein. Thus it is concluded that M239 has a mutation at or near the catalytic site which reduces the activity 10,000-fold but has little or no influence on the formation of the native multimeric structure. In contrast, M204 apparently has a mutation that severely inhibits aggregation and may have only a minor effect on the inherent potential for catalytic conversion at the reactive site. The heterocaryon would appear to form a mixed multimer with the monomeric subunits from M239 providing the aggregated structure and those from M204, the catalytically active moiety.

Gene order in the qa gene cluster of Neurospora crassa

Four different types of crosses have been used to establish the order of the four genes in the qa gene cluster of Neurospora crassa, which encode the following proteins involved in the inducible catabolism of quinic acid: a regulatory (activator) protein (qa-1), catabolic dehydroquinase (qa-2), quinate dehydrogenase (qa-3), and dehydroshikimate dehydrase (qa-4). The four crosses involved (1) the ordering of the four qa genes relative to the closely-linked me-7 locus; (2) the ordering of the three other qa genes relative to a qa-1S mutant; (3) the use of a three factor cross--qa-3 X qa-4 qa-2 and (4) the use of four factor crosses--qa-1S X qa-3 qa-4 qa-2. The results of all four types of crosses agree in establishing an apparently definitive proximal to distal order, within the right arm of linkage group VII, i.e., qa-1 qa-3 qa-4 qa-2 me-7. The significance of a definitive establishment of the gene order within the qa cluster for an understanding of the organization and mechanism of genetic regulation in this cluster is discussed.