nit-2, the major positive-acting nitrogen regulatory gene of Neurospora crassa, encodes a sequence-specific DNA-binding protein

Cloning and molecular characterization of hxA, the gene coding for the xanthine dehydrogenase (purine hydroxylase I) of Aspergillus nidulans

We have cloned and sequenced the hxA gene coding for the xanthine dehydrogenase (purine hydroxylase I) of Aspergillus nidulans. The gene codes for a polypeptide of 1363 amino acids. The sequencing of a nonsense mutation, hxA5, proves formally that the clones isolated correspond to the hxA gene. The gene sequence is interrupted by three introns. Similarity searches reveal two iron-sulfur centers and a NAD/FAD-binding domain and have enabled a consensus sequence to be determined for the molybdenum cofactor-binding domain. The A. nidulans sequence is a useful outclass for the other known sequences, which are all from metazoans. In particular, it gives added significance to the missense mutations sequenced in Drosophila melanogaster and leads to the conclusion that while one of the recently sequenced human genes codes for a xanthine dehydrogenase, the other one must code for a different molybdenum-containing hydroxylase, possibly an aldehyde oxidase. The transcription of the hxA gene is induced by the uric acid analogue 2-thiouric acid and repressed by ammonium. Induction necessitates the product of the uaY regulatory gene.

Molecular cloning and analysis of nre, the major nitrogen regulatory gene of Penicillium chrysogenum

We have isolated the Penicillium chrysogenum nre gene which is homologous to the major nitrogen regulatory genes areA from Aspergillus nidulans and nit-2 from Neurospora crassa. Overall, nre shows 60% identity to areA and 30% identity to nit-2 at the amino-acid level. The gene encodes a protein of 835 amino-acid residues and contains a single Cys2/Cys2-type zinc finger with an adjacent basic region and a putative acidic activation region. In the DNA-binding domain, 98% of the amino-acid residues are identical in nre, areA and nit-2. The nre gene has been shown to be functional in N. crassa by heterologous complementation of a nit-2 mutant. Growth tests indicated that transformants could utilize nitrate, amino-acids, purines and amides as sole nitrogen sources. Nitrate reductase activity assays performed with transformants demonstrated that nitrogen control was completely normal. Complementation of N. crassa nit-2 mutants with 5'-deletion clones of nre suggests the possible presence of an internal promoter within the coding region. Northern analysis and ribonuclease protection assays of total cellular RNA indicated that nre encodes a 3.2-kb transcript which is reduced in content under conditions of nitrogen repression.

Transcriptional and posttranslational regulation of the general amino acid permease of Saccharomyces cerevisiae

The cellular level and activity of the general amino acid permease, the product of the GAP1 gene of Saccharomyces cerevisiae, are regulated at the level of transcription by two systems, the products of URE2/GLN3 and NIL1 in response to the nitrogen sources of the growth medium and inactivation in response to the presence of glutamine or glutamate. Active permease is phosphorylated. The addition of glutamine causes rapid dephosphorylation and inactivation of the permease with the same kinetics, which is followed by slower disappearance of the protein. These results suggest that inactivation of the permease results from its dephosphorylation.

DNA binding site specificity of the Neurospora global nitrogen regulatory protein NIT2: analysis with mutated binding sites

NIT2, a positive-acting regulatory protein in Neurospora crassa, activates the expression of a series of unlinked structural genes that encode nitrogen catabolic enzymes. NIT2 binding sites in the promoter regions of nit3, alc and lao have at least two GATA sequence elements. We have examined the binding affinity of the NIT2 protein for the yeast DAL5 wild-type upstream activation sequence UASNTR, which contains two GATA elements, and for a series of mutated binding sites, each differing from the wild-type site by a single base. Substitution for individual nucleotides within 5' or 3' sequences that flank the GATA elements had only modest effects upon NIT2 binding. In contrast, nearly all substitutions within the GATA elements almost completely eliminated NIT2 binding, demonstrating the importance of the GATA sequence for NIT2 binding. Four high-affinity binding sites for the NIT2 protein were found within a central region of the nit-2 gene itself.

5' proximal regions of Arabidopsis nitrate reductase genes direct nitrate-induced transcription in transgenic tobacco

Nitrate reductase (NR) is the first enzyme in nitrate assimilation, a critical process for plant survival. The regulation of NR gene expression is complex, involving both internal and external factors. Of these, nitrate induction of NR gene expression has been studied most extensively and is well conserved among bacteria, fungi, and higher plants. We are interested in understanding the mechanism of nitrate induction of higher plant NR genes. Here we describe promoter analyses of the 5' flanking regions of the Arabidopsis NR genes, NR1 and NR2, with respect to nitrate induction of gene expression. To facilitate these analyses, a nitrate induction procedure using T1 transgenic tobacco plants was established. Approximately 1.5-kb 5' flanking regions of the two Arabidopsis NR genes (NR1 and NR2) were fused to a reporter gene and its expression in transgenic plants was analyzed. Deletion analyses of these regions show that 238- and 188-bp 5' flanking regions of the NR1 and NR2, respectively, contain sequences responsive to nitrate induction.

Nitrogen, carbon, and pH regulation of extracellular acidic proteases of Aspergillus niger

Aspergillus niger secretes a number of enzymes, including proteases, into its culture fluid. The regulation of the two major acidic extracellular proteases, pepA and pepB, was investigated using Northern analyses. Our data suggest that the regulation of pepA and pepB expression occurs predominantly at the level of mRNA content and that, while they are regulated in a similar manner, differences are also clear in their expression. Both genes were found to be under complex regulatory control. The expression of the two genes could be turned off by the presence of good nitrogen or carbon sources in the media, and external protein sources did not induce expression of either gene under conditions of carbon and nitrogen repression. The pH of the medium also played a major role in their regulation as the expression of both genes was completely turned off under alkaline conditions, even when grown in media lacking good nitrogen and carbon sources but containing proteins. We isolated clones containing 5' non-coding sequences of the pepA gene from a lambda genomic library with a pepA specific probe. Analysis and comparison of the promoter sequences of the pepA and pepB genes revealed that both contain several putative AREA- and CREA-binding sites and they also share an 18-bp-long sequence which is 83% identical in these two genes.

Nitrate reductase of the ascomycetous fungus, Leptosphaeria maculans: gene sequence and chromosomal location

The nitrate reductase (niaD) gene was isolated from the phytopathogenic loculoascomycete Leptosphaeria maculans by screening a genomic DNA library with the Aspergillus nidulans niaD gene. The L. maculans niaD gene is the first protein-encoding gene characterised from this fungus. It encodes a predicted protein of 893 amino acids and contains four putative introns at positions in the gene equivalent to those of four of the six introns in the A. nidulans niaD gene. Mutants defective in niaD and molybdenum cofactor gene(s) of L. maculans have been isolated. Transformation of a L. maculans niaD mutant with a 3.8 kb SacII fragment containing the L. maculans niaD gene restored wild-type growth on nitrate as a sole nitrogen source. The niaD gene is present as a single copy on a chromosome which ranges in size from 2.6 to 2.8 Mb between the different L. maculans isolates examined.

Isolation and characterization of retinoic acid-inducible cDNA clones in F9 cells: one of the early inducible clones encodes a novel protein sharing several highly homologous regions with a Drosophila polyhomeotic protein

To elucidate regulatory mechanisms triggering early mammalian differentiation, 17 retinoic acid (RA)-inducible clones were isolated from 1.4 x 10(5) plaques of cDNA libraries prepared from mouse embryonal carcinoma F9 cells, using the differential plaque hybridization method. Partial nucleotide sequences of these clones demonstrated that ten clones correspond to known genes. Interestingly, only 2 of the 17 clones are among the previously documented up-regulated genes. Therefore, there are many more unidentified genes up-regulated in the course of RA-induced differentiation of F9 cells. As RNAs hybridizable with one of the seven unidentified clones were induced in F9 cells after 3 h of RA treatment, we chose this 'Rae-28' clone as being representative of developmentally up-regulated unidentified clones and its properties were characterized. We determined the Rae-28 cDNA sequence and deduced the RAE-28 protein structure. The deduced RAE-28 protein shared several motifs and highly homologous regions with a Drosophila polyhomeotic protein. As the Drosophila polyhomeotic gene is involved in regulating morphogenesis, the rae-28 gene may participate in regulating early mammalian development.

Nitrogen limitation induces expression of the avirulence gene avr9 in the tomato pathogen Cladosporium fulvum

The avirulence gene avr9 of the fungal tomato pathogen Cladosporium fulvum encodes a race-specific peptide elicitor that induces the hypersensitive response in tomato plants carrying the complementary resistance gene Cf9. The avr9 gene is not expressed under optimal growth conditions in vitro, but is highly expressed when the fungus grows inside the tomato leaf. In this paper we present evidence for the induction of avr9 gene expression in C. fulvum grown in vitro under conditions of nitrogen limitation. Only growth medium with very low amounts of nitrogen (nitrate, ammonium, glutamate or glutamine) induced the expression of avr9. Limitation of other macronutrients or the addition of plant factors did not induce the expression of avr9. The induced expression of avr9 is possibly mediated by a positive-acting nitrogen regulatory protein, homologous to the Neurospora crassa NIT2 protein, which induces the expression of many genes under conditions of nitrogen limitation. The avr9 promoter contains several putative NIT2 binding sites. The expression of avr9 during the infection process was explored cytologically using transformants of C. fulvum carrying an avr9 promoter-beta-glucuronidase reporter gene fusion. The possibility that expression of avr9 in C. fulvum growing in planta is caused by nitrogen limitation in the apoplast of the tomato leaf is discussed.

The Drosophila l(2)35Ba/nocA gene encodes a putative Zn finger protein involved in the development of the embryonic brain and the adult ocellar structures

The Drosophila l(2)35Ba/nocA gene is involved in the development of the adult ocelli and the embryonic head. Mutations in this gene lead to at least two distinct phenotypes. Several larva lethal l(2)35Ba alleles cause both hypertrophy and mislocation of the embryonic supraesophageal ganglion (brain) to the dorsal surface of the embryo. A second class of mutant alleles (nocA) is homozygous viable, but the surviving adults either lack or have greatly reduced ocelli and associated bristles. The l(2)35Ba/nocA gene encodes an approximately 3.0-kb transcript doublet; all l(2)35Ba alleles which have been physically mapped delete or disrupt the transcribed region, whereas all of the viable nocA alleles are caused by gross chromosomal aberrations with breakpoints near the 3'-flanking region of the gene. Several nocA breakpoint alleles downregulate the level of l(2)35Ba/nocA transcripts in adults, and their defective ocellar phenotype also fails to be complemented by the lethal alleles, implying that l(2)35Ba and nocA are different phenotypic manifestations of mutations in the same gene. In the l(2)35Ba mutant embryos, cells from the procephalic lobe which normally migrate over and overlie the supraesophageal ganglion during head involution can become incorporated into the supraesophageal ganglion; many of these misplaced cells, which normally form the frontal sac, also adopt a neuronal fate. Sequence analysis of two full-length l(2)35Ba/nocA cDNAs with distinct polyadenylation sites shows that they encode the same deduced protein of 537 amino acids with a serine- and threonine-rich N-terminal region, two putative zinc finger motifs near the carboxyl terminus, and several alanine-rich domains. Consistent with the observed embryonic phenotype, l(2)35Ba/nocA shows a complex embryonic expression pattern which includes the procephalic lobe.

The Drosophila l(2)35Ba/nocA gene encodes a putative Zn finger protein involved in the development of the embryonic brain and the adult ocellar structures

The Drosophila l(2)35Ba/nocA gene is involved in the development of the adult ocelli and the embryonic head. Mutations in this gene lead to at least two distinct phenotypes. Several larva lethal l(2)35Ba alleles cause both hypertrophy and mislocation of the embryonic supraesophageal ganglion (brain) to the dorsal surface of the embryo. A second class of mutant alleles (nocA) is homozygous viable, but the surviving adults either lack or have greatly reduced ocelli and associated bristles. The l(2)35Ba/nocA gene encodes an approximately 3.0-kb transcript doublet; all l(2)35Ba alleles which have been physically mapped delete or disrupt the transcribed region, whereas all of the viable nocA alleles are caused by gross chromosomal aberrations with breakpoints near the 3'-flanking region of the gene. Several nocA breakpoint alleles downregulate the level of l(2)35Ba/nocA transcripts in adults, and their defective ocellar phenotype also fails to be complemented by the lethal alleles, implying that l(2)35Ba and nocA are different phenotypic manifestations of mutations in the same gene. In the l(2)35Ba mutant embryos, cells from the procephalic lobe which normally migrate over and overlie the supraesophageal ganglion during head involution can become incorporated into the supraesophageal ganglion; many of these misplaced cells, which normally form the frontal sac, also adopt a neuronal fate. Sequence analysis of two full-length l(2)35Ba/nocA cDNAs with distinct polyadenylation sites shows that they encode the same deduced protein of 537 amino acids with a serine- and threonine-rich N-terminal region, two putative zinc finger motifs near the carboxyl terminus, and several alanine-rich domains. Consistent with the observed embryonic phenotype, l(2)35Ba/nocA shows a complex embryonic expression pattern which includes the procephalic lobe.

DNA recognition by the NIT2 nitrogen regulatory protein: importance of the number, spacing, and orientation of GATA core elements and their flanking sequences upon NIT2 binding

NIT2, a global positive-acting regulatory protein in Neurospora crassa, activates the expression of a series of unlinked structural genes in the nitrogen regulation circuit. NIT2 binding sites in the promoter region of the nit-3, alc, and lao genes are very different in sequence context except for the presence of at least two copies of a GATA core sequence. Changing a single nucleotide of only one of two closely spaced GATA core elements abolished NIT2 binding, demonstrating their importance for NIT2 binding. The effect of altering the number, orientation, or spacing of paired GATA elements and the importance of 5'- and 3'-flanking sequences upon NIT2 binding were examined. Strong binding sites for a NIT2-beta GAL fusion protein appear to contain at least two GATA elements, which can have varied spacing but must be within a certain effective distance, approximately 30 bp, of each other. Surprisingly, the orientation of GATA elements and their flanking sequences have only modest effects upon NIT2 binding.

Nitrogen regulation in fungi

Nitrogen regulation has been extensively studied in fungi revealing a complex array of interacting regulatory genes. The general characterisation of the systems in Aspergillus nidulans and Neurospora crassa shall be briefly described, but much of this paper will concentrate specifically on the recent molecular characterisation of areA, the principle regulatory gene from A. nidulans which mediates nitrogen metabolite repression. Three areas shall be explored in detail, firstly the DNA binding domain, which has been characterised extensively by both molecular and genetic analysis. Secondly we shall report recent analysis which has revealed the presence of related DNA binding activities in A. nidulans. Finally we shall discuss the mechanism by which the nitrogen state of the cell is monitored by the areA product, in particular localisation of the domain within the areA product which mediates the regulatory response within the protein.

A GATA family transcription factor is expressed along the embryonic dorsoventral axis in Drosophila melanogaster

The GATA transcription factors are a family of C4 zinc finger-motif DNA-binding proteins that play defined roles in hematopoiesis as well as presumptive roles in other tissues where they are expressed (e.g., testis, neuronal and placental trophoblast cells) during vertebrate development. To investigate the possibility that GATA proteins may also be involved in Drosophila development, we have isolated and characterized a gene (dGATAa) encoding a factor that is quite similar to mammalian GATA factors. The dGATAa protein sequence contains the two zinc finger DNA-binding domain of the GATA class but bears no additional sequence similarity to any of the vertebrate GATA factors. Analysis of dGATAa gene transcription during Drosophila development revealed that its mRNA is expressed at high levels during early embryogenesis, with transcripts first appearing in the dorsal portion of the embryo just after cellularization. As development progresses, dGATAa mRNA is present at high levels in the dorsal epidermis, suggesting that dGATAa may be involved in determining dorsal cell fate. The pattern of expression in a variety of dorsoventral polarity mutants indicates that dGATAa lies downstream of the zygotic patterning genes decapentaplegic and zerknullt.

urbs1, a gene regulating siderophore biosynthesis in Ustilago maydis, encodes a protein similar to the erythroid transcription factor GATA-1

Ustilago maydis secretes ferrichrome-type siderophores, ferric-ion-binding compounds, in response to iron starvation. TA2701, a non-enterobactin-producing, non-ferrichrome-utilizing mutant of Salmonella typhimurium LT-2, was employed as a biological indicator in a novel screening method to isolate three N-methyl-N'-nitro-N-nitrosoguanidine-induced U. maydis mutants defective in the regulation of ferrichrome-type siderophore biosynthesis. These mutants displayed a constitutive phenotype; they produced siderophores in the presence of iron concentrations that would typically repress siderophore synthesis in wild-type strains. A 4.8-kb fragment of U. maydis genomic DNA capable of restoring normal regulation of siderophore biosynthesis in the constitutive mutants was identified. This segment of DNA contains an intronless open reading frame that specifies a protein of 950 amino acids containing two finger motifs similar to those found in the erythroid transcription factor GATA-1. Disruption of this open reading frame in a wild-type strain gave rise to cells that produced siderophores constitutively. Genetic studies indicated that the disruption mutation was allelic to the chemically induced mutations, confirming that the structural gene for a regulator rather than a suppressor gene had been cloned. Northern (RNA) analysis of the gene revealed a 4.2-kb transcript that is expressed constitutively at low levels in wild-type cells. The data support the hypothesis that this gene, which we designate urbs1 (Ustilago regulator of biosynthesis of siderophores), acts directly or indirectly to repress biosynthesis of siderophores in U. maydis.

urbs1, a gene regulating siderophore biosynthesis in Ustilago maydis, encodes a protein similar to the erythroid transcription factor GATA-1

Ustilago maydis secretes ferrichrome-type siderophores, ferric-ion-binding compounds, in response to iron starvation. TA2701, a non-enterobactin-producing, non-ferrichrome-utilizing mutant of Salmonella typhimurium LT-2, was employed as a biological indicator in a novel screening method to isolate three N-methyl-N'-nitro-N-nitrosoguanidine-induced U. maydis mutants defective in the regulation of ferrichrome-type siderophore biosynthesis. These mutants displayed a constitutive phenotype; they produced siderophores in the presence of iron concentrations that would typically repress siderophore synthesis in wild-type strains. A 4.8-kb fragment of U. maydis genomic DNA capable of restoring normal regulation of siderophore biosynthesis in the constitutive mutants was identified. This segment of DNA contains an intronless open reading frame that specifies a protein of 950 amino acids containing two finger motifs similar to those found in the erythroid transcription factor GATA-1. Disruption of this open reading frame in a wild-type strain gave rise to cells that produced siderophores constitutively. Genetic studies indicated that the disruption mutation was allelic to the chemically induced mutations, confirming that the structural gene for a regulator rather than a suppressor gene had been cloned. Northern (RNA) analysis of the gene revealed a 4.2-kb transcript that is expressed constitutively at low levels in wild-type cells. The data support the hypothesis that this gene, which we designate urbs1 (Ustilago regulator of biosynthesis of siderophores), acts directly or indirectly to repress biosynthesis of siderophores in U. maydis.

Regulation of ammonium ion assimilation enzymes in Neurospora crassa nit-2 and ms-5 mutant strains

In Neurospora crassa the nit-2 and nmr-1 (ms-5) loci represent the major control genes encoding regulatory proteins that allow the coordinated expression of various systems involved with the utilization of a secondary nitrogen source. In this paper we examined the effect of the nit-2 and ms-5 (nmr-1 locus) mutations on the regulation of the ammonium assimilation enzymes, glutamine synthetase and glutamate dehydrogenase, which are regulated by the products of these genes; however, glutamate synthase is not so regulated. Glutamine synthetase and glutamate dehydrogenase levels are also regulated by the amino nitrogen content. We present evidence that the ms-5 and glnr strains, which behave very similarly in their resistance to glutamine repression, are different and map in different loci.

Amino-acid substitutions in the zinc finger of NIT2, the nitrogen regulatory protein of Neurospora crassa, alter promoter element recognition

NIT2, the major nitrogen regulatory protein of Neurospora crassa mediates nitrogen catabolite derepression of the structural genes which specify enzymes of nitrogen catabolism. The promoter of the structural gene for L-amino acid oxidase, a nitrogen-regulated enzyme, was found to contain two NIT2 binding sites, each with two copies of a GATA core consensus sequence. Site-directed mutagenesis was employed to create amino-acid substitutions within the single zinc-finger region of NIT2, which serves as the DNA-binding domain. The affect of those mutations upon NIT2 function in vivo in the activation of three separate structural genes was examined by transformation assays and relevant enzyme activities, and DNA-binding activity in vitro was determined by gel band mobility-shift assays. It was shown that specific amino-acid residues within the zinc-finger loop region of NIT2 are important for DNA-binding activity, whereas other residues influence the specificity of DNA binding. Mutant NIT2 proteins were obtained which retain DNA-binding activity and alter the specificity of DNA recognition, thus allowing a distinction between related DNA elements.

A tobacco cDNA clone encoding a GATA-1 zinc finger protein homologous to regulators of nitrogen metabolism in fungi

In higher plants, the expression of the nitrate assimilation pathway is highly regulated. Although the molecular mechanisms involved in this regulation are currently being elucidated, very little is known about the trans-acting factors that allow expression of the nitrate and nitrite reductase genes which code for the first enzymes in the pathway. In the fungus Neurospora crassa, nit-2, the major nitrogen regulatory gene, activates the expression of unlinked structural genes that specify nitrogen-catabolic enzymes during conditions of nitrogen limitation. The nit-2 gene encodes a regulatory protein containing a single zinc finger motif defined by the C-X2-C-X17-C-X2-C sequence. This DNA-binding domain recognizes the promoter region of N. crassa nitrogen-related genes and fragments derived from the tomato nia gene promoter. The observed specificity of the binding suggests the existence of a NIT2-like homolog in higher plants. PCR and cross-hybridization techniques were used to isolate, respectively, a partial cDNA from Nicotiana plumbaginifolia and a full-length cDNA from Nicotiana tabacum. These clones encode a NIT2-like protein (named NTL1 for nit-2-like), characterized by a single zinc finger domain, defined by the C-X2-C-X18-C-X2-C amino acids, and associated with a basic region. The amino acid sequence of NTL1 is 60% homologous to the NIT2 sequence in the zinc finger domain. The Ntl1 gene is present as a unique copy in the diploid N. plumbaginifolia species. The characteristics of Ntl1 gene expression are compatible with those of a regulator of the nitrate assimilation pathway, namely weak nitrate inducibility and regulation by light.

Recognition of specific nucleotide bases and cooperative DNA binding by the trans-acting nitrogen regulatory protein NIT2 of Neurospora crassa

The NIT2 nitrogen regulatory protein of Neurospora is a DNA binding protein which contains a single Cys2/Cys2 type finger motif followed immediately by a highly basic region. Several different approaches were employed to identify nucleotides which appear to be in contact with NIT2 in the DNA-protein complex. Methylation interference and missing contact analyses with the promoter DNA fragment of the L-amino acid oxidase gene showed that all three purines in both of two GATA core sequences and the single adenine residue in each of the complementary TATC sequences were in intimate contact with NIT2. Modification or loss of the three purine residues located between the two GATA core sequences also significantly reduced NIT2 binding, whereas alteration of purines which flank the binding element showed only minor effects. Chemical modification of all six thymine bases in the two GATA and TATC complement core sequences also strongly affected NIT2 binding. High affinity NIT2 binding sites appear to contain at least two GATA core sequences, with single GATA sequences acting only as weak binding sites. Mobility shift experiments with the DNA fragment upstream of nit-3, the structural gene for nitrate reductase, revealed two DNA-NIT2 protein complexes. In complex I, which is formed first, NIT2 was bound to a pair of GATA sites located at -180. In complex II, the paired GATA sites at -180 plus a single GATA site at -290 were all occupied by NIT2. A DNA fragment containing only the single -290 GATA element bound NIT2 very weakly. The affinity of this single GATA for NIT2 was ten to twenty times greater when it was situated on the same DNA fragment with the distant paired GATA elements than when alone.

DNA-binding specificity of GATA family transcription factors

GATA-binding proteins constitute a family of transcription factors that recognize a target site conforming to the consensus WGATAR (W = A or T and R = A or G). Here we have used the method of polymerase chain reaction-mediated random site selection to assess in an unbiased manner the DNA-binding specificity of GATA proteins. Contrary to our expectations, we show that GATA proteins bind a variety of motifs that deviate from the previously assigned consensus. Many of the nonconsensus sequences bind protein with high affinity, equivalent to that of conventional GATA motifs. By using the selected sequences as probes in the electrophoretic mobility shift assay, we demonstrate overlapping, but distinct, sequence preferences for GATA family members, specified by their respective DNA-binding domains. Furthermore, we provide additional evidence for interaction of amino and carboxy fingers of GATA-1 in defining its binding site. By performing cotransfection experiments, we also show that transactivation parallels DNA binding. A chimeric protein containing the finger domain of areA and the activation domains of GATA-1 is capable of activating transcription in mammalian cells through GATA motifs. Our findings suggest a mechanism by which GATA proteins might selectively regulate gene expression in cells in which they are coexpressed.

DNA-binding specificity of GATA family transcription factors

GATA-binding proteins constitute a family of transcription factors that recognize a target site conforming to the consensus WGATAR (W = A or T and R = A or G). Here we have used the method of polymerase chain reaction-mediated random site selection to assess in an unbiased manner the DNA-binding specificity of GATA proteins. Contrary to our expectations, we show that GATA proteins bind a variety of motifs that deviate from the previously assigned consensus. Many of the nonconsensus sequences bind protein with high affinity, equivalent to that of conventional GATA motifs. By using the selected sequences as probes in the electrophoretic mobility shift assay, we demonstrate overlapping, but distinct, sequence preferences for GATA family members, specified by their respective DNA-binding domains. Furthermore, we provide additional evidence for interaction of amino and carboxy fingers of GATA-1 in defining its binding site. By performing cotransfection experiments, we also show that transactivation parallels DNA binding. A chimeric protein containing the finger domain of areA and the activation domains of GATA-1 is capable of activating transcription in mammalian cells through GATA motifs. Our findings suggest a mechanism by which GATA proteins might selectively regulate gene expression in cells in which they are coexpressed.

GATA-4 is a novel transcription factor expressed in endocardium of the developing heart

We have isolated and characterized Xenopus cDNA clones for a new transcription factor that represents an early marker for the developing heart. The cDNAs encode a protein that we have designated GATA-4; it contains the highly conserved DNA-binding domain that characterizes this family of cell-type restricted transcriptional activators. Whole-embryo in situ analysis of Xenopus embryos demonstrates that the GATA-4 gene is transcribed in presumptive cardiac ventral mesoderm at the time that bilateral progenitors fuse and form the cardiac tube. GATA-4 is therefore the earliest molecular marker of cardiogenesis yet characterized. By stage 30, the GATA-4 mRNA is expressed in the developing atria and ventricles; at stage 38, cross-sections reveal that the gene is active in the endocardial layer, but not in myocardium. By stage 40, GATA-4 message is detected in the great vessels. In the adult frog, the GATA-4 gene is highly transcribed in heart and gut; lower levels of message are detected in various endoderm-derived tissues and gonads. Expression in the stomach is largely confined to the epithelium. The GATA-4 gene is first activated at stage 11; mRNA is initially present throughout the marginal zone of explants and later partially localized to the ventral marginal zone. GATA-4 mRNA is also detected at high levels in cultured endodermal explants derived from the vegetal region of early embryos. In mesoderm induction experiments, GATA-4 transcription is not induced in animal caps treated with activin or bFGF. The GATA-4 gene may provide a new early marker for studying the inductive processes that lead to the formation of the cardiovascular system and for the specification of the endocardial lineage.

Fungal catabolic gene regulation: molecular genetic analysis of the amdS gene of Aspergillus nidulans

Aspergillus nidulans is an excellent experimental organism for the study of gene regulation. Genetic and molecular analyses of trans-acting and cis-acting mutations have revealed a complex pattern of regulation involving multiple independent controls. Expression of the amdS gene is regulated by the facB and amdA genes which encode positively acting regulatory proteins mediating a major and a minor form of acetate induction respectively. The product of the amdR gene mediates omega amino acid induction of amdS. The binding sites for each of these proteins have been localised through amdS cis-acting mutations which specifically affect the interaction with the regulatory protein. The global controls of nitrogen metabolite repression and carbon catabolite repression regulate the expression of many catabolic genes, including amdS. Nitrogen control is exerted through the positively acting areA gene product and carbon control is dependent on the creA gene product. Each of the characterized regulatory genes encodes a DNA-binding protein which recognises particular sequences in the amdS promoter to activate or repress gene expression. In addition, there is evidence for other genetically uncharacterized proteins, including a CCAAT-binding complex, which interact with the 5' region of the amdS gene.

Molecular characterization of conventional and new repeat-induced mutants of nit-3, the structural gene that encodes nitrate reductase in Neurospora crassa

Nitrate reductase of Neurospora crassa is a dimeric protein composed of two identical subunits, each possessing three separate domains, with flavin, heme, and molybdenum-containing cofactors. A number of mutants of nit-3, the structural gene that encodes Neurospora nitrate reductase, have been characterized at the molecular level. Amber nonsense mutants of nit-3 were found to possess a truncated protein detected by a specific antibody, whereas Ssu-1-suppressed nonsense mutants showed restoration of the wild-type, full-length nitrate reductase monomer. The mutants show constitutive expression of the truncated nitrate reductase protein; however normal control, which requires nitrate induction, was restored in the suppressed mutant strains. Three conventional nit-3 mutants were isolated by the polymerase chain reaction and sequenced; two of these mutants were due to the deletion of a single base in the coding region for the flavin domain, the third mutant was a nonsense mutation within the amino-terminal molybdenum-containing domain. Homologous recombination was shown to occur when a deleted nit-3 gene was introduced by transformation into a host strain with a single point mutation in the resident nit-3 gene. New, severely damaged, null nit-3 mutants were created by repeat-induced point mutation and demonstrated to be useful as host strains for transformation experiments.

Molecular cloning, characterization, and nucleotide sequence of nit-6, the structural gene for nitrite reductase in Neurospora crassa

The Neurospora crassa assimilatory nitrite reductase structural gene, nit-6, has been isolated. A cDNA library was constructed from poly(A)+ RNA isolated from Neurospora mycelia in which nitrate assimilation had been induced. This cDNA was ligated into lambda ZAP II (Stratagene) and amplified. This library was then screened with a polyclonal antibody specific for nitrite reductase. A total of six positive clones were identified. Three of the six clones were found to be identical via restriction digests, restriction fragment length polymorphism mapping, Southern hybridization, and some preliminary sequencing. One of these cDNA clones (pNiR-3) was used as a probe in Northern assays and was found to hybridize to a 3.5-kb poly(A)+ RNA whose expression is nitrate inducible and glutamine repressible in wild-type mycelia. pNiR-3 was used to probe an N. crassa genomic DNA library in phage lambda J1, and many positive clones were isolated. When five of these clones were tested for their ability to transform nit-6 mutants, one clone consistently generated many wild-type transformants. The nit-6 gene has been subcloned to generate pnit-6. The nit-6 gene has been sequenced and mapped; its deduced amino acid sequence exhibits considerable levels of homology to the sequences of Aspergillus sp. and Escherichia coli nitrite reductases. Several pnit-6 transformants have been propagated as homokaryons. These strains have been assayed for the presence of multiple copies of the nit-6 gene, as well as nitrite reductase activity.

sid1, a gene initiating siderophore biosynthesis in Ustilago maydis: molecular characterization, regulation by iron, and role in phytopathogenicity

Iron uptake in Ustilago maydis is mediated by production of extracellular hydroxamate siderophores. L-Or-nithine N5-oxygenase catalyzes hydroxylation of L-ornithine, which is the first committed step of ferrichrome and ferrichrome A biosynthesis in U. maydis. We have characterized sid1, a gene coding for this enzyme, by complementation in trans, gene disruption, and DNA sequence analysis. A comparison of genomic DNA and cDNA sequences has shown that the gene is interrupted by three introns. The putative amino acid sequence revealed similarity with Escherichia coli lysine N6-hydroxylase, which catalyzes the hydroxylation of lysine, the first step in biosynthesis of aerobactin. Two transcription initiation points have been determined, both by PCR amplification of the 5' end of the mRNA and by primer extension. A 2.3-kb transcript which accumulates in cells grown under low iron conditions was detected by Northern hybridization. A less abundant 2.7-kb transcript was observed in cells grown in iron-containing medium. By contrast, constitutive accumulation of the 2.3-kb transcript was observed in a mutant carrying a disruption of urbs1, a gene involved in regulation of siderophore biosynthesis. Analysis of the pathogenicity of mutants carrying a null allele of sid1 suggests that the biosynthetic pathway of siderophores does not play an essential role in the infection of maize by U. maydis.

Operator derepressed mutations in the proline utilisation gene cluster of Aspergillus nidulans

The proline utilisation gene cluster of Aspergillus nidulans can be repressed efficiently only when both repressing nitrogen and repressing carbon sources are present. We show that two cis-acting mutations in this cluster permit the efficient transcription of the prnB gene under repressing conditions, resulting in direct or indirect derepression of two other transcripts of the pathway. These mutations are transitions that define a 5'GAGACCCC3' sequence. Similar sequences are found upstream of other genes subject to carbon catabolite repression. We propose that this sequence defines the binding site for the negatively-acting CreA protein, which mediates carbon catabolite repression in this fungus.

The regulatory gene nit-2 of Neurospora crassa complements a nnu mutant of Gibberella zeae (Fusarium graminearum)

The nnu mutant of Gibberella zeae (=Fusarium graminearum) is unable to catabolize many of the nitrogen sources utilized by its wild-type parent, and may have suffered a mutation in the major nitrogen regulatory locus. Transformation of this mutant with the major nitrogen regulatory gene from Neurospora crassa, nit-2, restored the wild-type phenotype, thus confirming that the nnu mutation is in the major nitrogen regulatory locus of G. zeae. Our results are consistent with the premise of conservation of the structure of regulatory factors and suggest the possibility that functional DNA homologues of this regulatory element occur across a broad range of ascomycetous fungi.

Distinct roles for the two cGATA-1 finger domains

We have generated and analyzed by functional assays mutations of the chicken erythroid transcription factor GATA-1. The cGATA-1 protein contains two related finger domains highly conserved across species and characteristic of the family of GATA-binding factors. We find that mutations in the C-terminal finger or adjacent basic region abolish sequence-specific DNA binding, confirming that this region constitutes a novel DNA-binding domain sufficient to recognize the consensus WGATAR motif. At least three separate regions outside of this finger II domain contribute in a cooperative manner to the trans-activation potential of the protein. As expected from previous results analyzing the mouse homolog, we find that the N-terminal finger plays a role in DNA binding by affecting the stability of the DNA-protein complex. In addition, we find mutations of finger I subtly altered in DNA-binding function which greatly diminish trans-activation. Our results support the notion that the GATA-1 protein must be positioned precisely on the GATA cis element to enable the activation of target genes.

Distinct roles for the two cGATA-1 finger domains

We have generated and analyzed by functional assays mutations of the chicken erythroid transcription factor GATA-1. The cGATA-1 protein contains two related finger domains highly conserved across species and characteristic of the family of GATA-binding factors. We find that mutations in the C-terminal finger or adjacent basic region abolish sequence-specific DNA binding, confirming that this region constitutes a novel DNA-binding domain sufficient to recognize the consensus WGATAR motif. At least three separate regions outside of this finger II domain contribute in a cooperative manner to the trans-activation potential of the protein. As expected from previous results analyzing the mouse homolog, we find that the N-terminal finger plays a role in DNA binding by affecting the stability of the DNA-protein complex. In addition, we find mutations of finger I subtly altered in DNA-binding function which greatly diminish trans-activation. Our results support the notion that the GATA-1 protein must be positioned precisely on the GATA cis element to enable the activation of target genes.

Interaction of the erythroid transcription factor cGATA-1 with a critical auto-regulatory element

We have performed a mutational analysis of the promoter for the chicken erythroid-specific GATA-1 transcription factor, and have investigated in detail the interaction of the factor with an upstream auto-regulatory element (ARE). We find that a single proximal GATA binding site of the ARE is required for promoter activity in primary erythroid cells; however, this minimal promoter is inappropriately active in fibroblasts. At least two molecules of GATA-1 can interact with the ARE, and sequences outside of the consensus site appear critical for the transcriptional activity of the bound protein. Finally, we provide evidence for complex protein/DNA interactions at the ARE, including the ability of GATA-1 to bend DNA.

Transformants of Neurospora crassa with the nit-4 nitrogen regulatory gene: copy number, growth rate and enzyme activity

nit-4 is a pathway-specific regulatory gene which controls nitrate assimilation in Neurospora crassa, and appears to mediate nitrate induction of nitrate and nitrite reductase. The NIT4 protein consists of 1090 amino-acid residues and possesses a single GAL4-like putative DNA-binding domain plus acidic, glutamine-rich, and polyglutamine regions. Several mutants with amino-acid substitutions in the putative DNA-binding domain and a nit-4 deletion mutant, which encodes a truncated NIT4 protein lacking the polyglutamine region, are functional, i.e., they are capable of transforming a nit-4 mutant strain. However, transformants obtained with most of these nit-4 mutant genes possess a markedly reduced level of nitrate reductase and grow only slowly on nitrate, emphasizing the need to examine quantitatively the affects of in vitro-manipulated genes. The possibility that some mutant genes could yield transformants only if multiple copies were integrated was examined. The presence of multiple copies of wild-type or mutant nit-4 genes did not generally lead to increased enzyme activity or growth rate, but instead frequently appeared to be detrimental to nit-4 function. A hybrid nit-4-nirA gene transforms nit-4 mutants but only allows slow growth on nitrate and has a very low level of nitrate reductase.

Identification of the promoter region involved in the autoregulation of the transcriptional activator ALCR in Aspergillus nidulans

The ALCR protein is the transcriptional activator of the ethanol utilization pathway in the filamentous fungus Aspergillus nidulans. This activator belongs to a family of fungal proteins having a conserved DNA-binding domain containing six cysteines (C6 class) with some striking features. At variance with other motifs of this class, the binding domain of ALCR is strongly asymmetrical in relation to the central cysteines and moreover was predicted to adopt a helix-turn-helix structure. This domain of ALCR was synthesized in Escherichia coli and purified as a glutathione-S-transferase fusion protein. Our results show that the transcriptional activator ALCR is a DNA-binding protein. The DNA-binding motif contains zinc that is necessary for the specific DNA binding. The ALCR peptide binds upstream of the coding region of alcR to two specific targets with different affinities that are characterized by a conserved 5-nucleotide core, 5'-CCGCA-3' (or its reverse). One site, the lower-affinity binding site, is a direct repeat, and the other, the higher-affinity binding site, is a palindromic sequence with dyad symmetry. Therefore, the ALCR binding protein is able to recognize one DNA sequence in two different configurations. An alcR mutant obtained by deletion of the two specific targets in the cis-acting region of the alcR gene is unable to grow on ethanol and does not express any alcohol dehydrogenase activity. These results demonstrate that the binding sites are in vivo functional targets (UASalc) for the ALCR protein in A. nidulans. They corroborate prior evidence that alcR is autoregulated.

Identification of the promoter region involved in the autoregulation of the transcriptional activator ALCR in Aspergillus nidulans

The ALCR protein is the transcriptional activator of the ethanol utilization pathway in the filamentous fungus Aspergillus nidulans. This activator belongs to a family of fungal proteins having a conserved DNA-binding domain containing six cysteines (C6 class) with some striking features. At variance with other motifs of this class, the binding domain of ALCR is strongly asymmetrical in relation to the central cysteines and moreover was predicted to adopt a helix-turn-helix structure. This domain of ALCR was synthesized in Escherichia coli and purified as a glutathione-S-transferase fusion protein. Our results show that the transcriptional activator ALCR is a DNA-binding protein. The DNA-binding motif contains zinc that is necessary for the specific DNA binding. The ALCR peptide binds upstream of the coding region of alcR to two specific targets with different affinities that are characterized by a conserved 5-nucleotide core, 5'-CCGCA-3' (or its reverse). One site, the lower-affinity binding site, is a direct repeat, and the other, the higher-affinity binding site, is a palindromic sequence with dyad symmetry. Therefore, the ALCR binding protein is able to recognize one DNA sequence in two different configurations. An alcR mutant obtained by deletion of the two specific targets in the cis-acting region of the alcR gene is unable to grow on ethanol and does not express any alcohol dehydrogenase activity. These results demonstrate that the binding sites are in vivo functional targets (UASalc) for the ALCR protein in A. nidulans. They corroborate prior evidence that alcR is autoregulated.

Identification of two tungstate-sensitive molybdenum cofactor mutants, chl2 and chl7, of Arabidopsis thaliana

The characterization of mutants that are resistant to the herbicide chlorate has greatly increased our understanding of the structure and function of the genes required for the assimilation of nitrate. Hundreds of chlorate-resistant mutants have been identified in plants, and almost all have been found to be defective in nitrate reduction due to mutations in either nitrate reductase (NR) structural genes or genes required for the synthesis of the NR cofactor molybdenum-pterin (MoCo). The cholorate-resistant mutant of Arabidopsis thaliana, chl2, is also impaired in nitrate reduction, but the defect responsible for this phenotype has yet to be explained. chl2 plants have low levels of NR activity, yet the map position of the chl2 mutation is clearly distinct from that of the two NR structural genes that have been identified in Arabidopsis. In addition, chl2 plants are not thought to be defective in MoCo, as they have near wild-type levels of xanthine dehydrogenase activity, which has been used as a measure of MoCo in other organisms. These results suggest that chl2 may be a NR regulatory mutant. We have examined chl2 plants and have found that they have as much NR (NIA2) mRNA as wild type a variable but often reduced level of NR protein, and one-eighth the NR activity of wild-type plants. It is difficult to explain these results by a simple regulatory model; therefore, we reexamined the MoCo levels in chl2 plants using a sensitive, specific assay for MoCo: complementation of Neurospora MoCo mutant extracts.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular characterization of the lam locus and sequences involved in regulation by the AmdR protein of Aspergillus nidulans

The lam locus of Aspergillus nidulans consists of two divergently transcribed genes, lamA and lamB, involved in the utilization of lactams such as 2-pyrrolidinone. Both genes are under the control of the positive regulatory gene amdR and are subject to carbon and nitrogen metabolite repression. The lamB gene and the region between the two genes have been sequenced, and the start points of transcription have been determined. Within the lam locus are two sequences with homology to elements, required for AmdR regulation, found in the 5' regions of the coregulated genes amdS and gatA. In vitro and in vivo assays were used to investigate the lam and gatA regulatory elements. One of the three gatA elements and one of the two lam elements were shown to bind AmdR protein in vivo and activate transcription. With a gel shift mobility assay, in vitro binding of AmdR protein to the functional gatA element was detected. Both the functional gatA and lam boxes contain within them a CAAT sequence. In vitro binding analysis indicates that a CCAAT-specific factor(s) binds at these sequences, adjacent to or overlapping the AmdR protein-binding site.

Molecular characterization of mutations of nit-4, the pathway-specific regulatory gene which controls nitrate assimilation in Neurospora crassa

The nit-4 genes of three conventional Neurospora crassa mutations and of the closely related species, Neurospora intermedia, have been isolated by amplifying the genomic DNA with the polymerase chain reaction. Nucleotide sequencing has revealed that the three nit-4 mutants, alleles 15, 1214, and 2994, are the result of a missense mutation, a nonsense mutation and a frameshift mutation, respectively. The nucleotide sequence of the NIT4 protein coding region of a nit-4 mutant (allele 2994) and of N. intermedia have been determined and compared with that of wild-type N. crassa. The molecular characteristics confirm that the mutated gene of 2994 originated from N. intermedia and was introgressed into N. crassa. The polyglutamine domains of the N. crassa wild type, the 2994 mutant, or N. intermedia cannot replace an upstream glutamine-rich domain which is essential for nit-4 function.

NIT2, the nitrogen regulatory protein of Neurospora crassa, binds upstream of nia, the tomato nitrate reductase gene, in vitro

The nit-2 gene of Neurospora crassa encodes a trans-acting regulatory protein that activates the expression of a number of structural genes which code for nitrogen catabolic enzymes, including nitrate reductase. The NIT2 protein contains a Cys2/Cys2-type zinc-finger DNA-binding domain that recognizes promoter regions of the Neurospora nitrogen-related genes. The NIT2 zinc-finger domain/beta-Gal fusion protein was shown to recognize and bind in a specific manner to two upstream fragments of the nia gene of Lycopersicon esculentum (tomato) in vitro, whereas two mutant NIT2 proteins failed to bind to the same fragments. The dissociation kinetics of the complexes formed between the NIT2 protein and the Neurospora nit-3 and the tomato nia gene promoters were examined; NIT2 binds more strongly to the nit-3 promoter DNA fragment than it does to fragments derived from the plant nitrate reductase gene itself. The observed specificity of the binding suggests the existence of a NIT2-like homolog which regulates the expression of the nitrate assimilation pathway of higher plants.

Molecular characterization of the lam locus and sequences involved in regulation by the AmdR protein of Aspergillus nidulans

The lam locus of Aspergillus nidulans consists of two divergently transcribed genes, lamA and lamB, involved in the utilization of lactams such as 2-pyrrolidinone. Both genes are under the control of the positive regulatory gene amdR and are subject to carbon and nitrogen metabolite repression. The lamB gene and the region between the two genes have been sequenced, and the start points of transcription have been determined. Within the lam locus are two sequences with homology to elements, required for AmdR regulation, found in the 5' regions of the coregulated genes amdS and gatA. In vitro and in vivo assays were used to investigate the lam and gatA regulatory elements. One of the three gatA elements and one of the two lam elements were shown to bind AmdR protein in vivo and activate transcription. With a gel shift mobility assay, in vitro binding of AmdR protein to the functional gatA element was detected. Both the functional gatA and lam boxes contain within them a CAAT sequence. In vitro binding analysis indicates that a CCAAT-specific factor(s) binds at these sequences, adjacent to or overlapping the AmdR protein-binding site.

Role of the complex upstream region of the GDH2 gene in nitrogen regulation of the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae

We analyzed the upstream region of the GDH2 gene, which encodes the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae, for elements important for the regulation of the gene by the nitrogen source. The levels of this enzyme are high in cells grown with glutamate as the sole source of nitrogen and low in cells grown with glutamine or ammonium. We found that this regulation occurs at the level of transcription and that a total of six sites are required to cause a CYC1-lacZ fusion to the GDH2 gene to be regulated in the same manner as the NAD-linked glutamate dehydrogenase. Two sites behaved as upstream activation sites (UASs). The remaining four sites were found to block the effects of the two UASs in such a way that the GDH2-CYC1-lacZ fusion was not expressed unless the cells containing it were grown under conditions favorable for the activity of both UASs. This complex regulatory system appears to account for the fact that GDH2 expression is exquisitely sensitive to glutamine, whereas the expression of GLN1, coding for glutamine synthetase, is not nearly as sensitive.

Sequence and expression of GLN3, a positive nitrogen regulatory gene of Saccharomyces cerevisiae encoding a protein with a putative zinc finger DNA-binding domain

The GLN3 gene of Saccharomyces cerevisiae is required for the activation of transcription of a number of genes in response to the replacement of glutamine by glutamate as source of nitrogen. We cloned the GLN3 gene and constructed null alleles by gene disruption. GLN3 is not essential for growth, but increased copies of GLN3 lead to a drastic decrease in growth rate. The complete nucleotide sequence of the GLN3 gene was determined, revealing one open reading frame encoding a polypeptide of 730 amino acids, with a molecular weight of approximately 80,000. The GLN3 protein contains a single putative Cys2/Cys2 zinc finger which has homology to the Neurospora crassa NIT2 protein, the Aspergillus nidulans AREA protein, and the erythroid-specific transcription factor GATA-1. Immunoprecipitation experiments indicated that the GLN3 protein binds the nitrogen upstream activation sequence of GLN1, the gene encoding glutamine synthetase. Neither control of transcription nor control of initiation of translation of GLN3 is important for regulation in response to glutamine availability.

Role of the complex upstream region of the GDH2 gene in nitrogen regulation of the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae

We analyzed the upstream region of the GDH2 gene, which encodes the NAD-linked glutamate dehydrogenase in Saccharomyces cerevisiae, for elements important for the regulation of the gene by the nitrogen source. The levels of this enzyme are high in cells grown with glutamate as the sole source of nitrogen and low in cells grown with glutamine or ammonium. We found that this regulation occurs at the level of transcription and that a total of six sites are required to cause a CYC1-lacZ fusion to the GDH2 gene to be regulated in the same manner as the NAD-linked glutamate dehydrogenase. Two sites behaved as upstream activation sites (UASs). The remaining four sites were found to block the effects of the two UASs in such a way that the GDH2-CYC1-lacZ fusion was not expressed unless the cells containing it were grown under conditions favorable for the activity of both UASs. This complex regulatory system appears to account for the fact that GDH2 expression is exquisitely sensitive to glutamine, whereas the expression of GLN1, coding for glutamine synthetase, is not nearly as sensitive.