Mutational analysis of the DNA-binding domain of the CYS3 regulatory protein of Neurospora crassa.

cys-3, the major sulfur regulatory gene of Neurospora crassa, activates the expression of a set of unlinked structural genes which encode sulfur catabolic-related enzymes during conditions of sulfur limitation. The cys-3 gene encodes a regulatory protein of 236 amino acid residues with a leucine zipper and an upstream basic region (the b-zip region) which together may constitute a DNA-binding domain. The b-zip region was expressed in Escherichia coli to examine its DNA-binding activity. The b-zip domain protein binds to the promoter region of the cys-3 gene itself and of cys-14, the sulfate permease II structural gene. A series of CYS3 mutant proteins obtained by site-directed mutagenesis were expressed and tested for function, dimer formation, and DNA-binding activity. The results demonstrate that the b-zip region of cys-3 is critical for both its function in vivo and specific DNA-binding in vitro.     

A thermodynamic scale for leucine zipper stability and dimerization specificity: e and g interhelical interactions.

The leucine zipper is a dimeric coiled-coil protein structure composed of two amphipathic alpha-helices with the hydrophobic surfaces interacting to create the dimer interface. This structure has been found to mediate the dimerization of two abundant classes of DNA binding proteins: the bZIP and bHLH-Zip proteins. Several workers have reported that amino acids in the e and g positions of the coiled coil can modulate dimerization stability and specificity. Using the bZIP protein VBP as a host molecule, we report a thermodynamic scale (delta delta G) for 27 interhelical interactions in 35 proteins between amino acids in the g and the following e positions (g<==>e') of a leucine zipper coiled coil. We have examined the four commonly occurring amino acids in the e and g positions of bZIP proteins, lysine (K), arginine (R), glutamine (Q), glutamic acid (E), as well as the only other remaining charged amino acid aspartic acid (D), and finally alanine (A) as a reference amino acid. These results indicate that E<==>R is the most stable interhelical pair, being 0.35 kcal/mol more stable than E<==>K. A thermodynamic cycle analysis shows that the E<==>R pair is 1.33 kcal/mol more stable than A<==>A with -1.14 kcal/mol of coupling energy (delta delta Gint) coming from the interaction of E with R. The E<==>K coupling energy is only -0.14 kcal/mol. E interacts with more specificity than Q. The R<==>R pair is less stable than the K<==>K by 0.24 kcal/mol. R interacts with more specificity than K. Q forms more stable pairs with the basic amino acids K and R rather than with E. Changing amino acids in the e position to A creates bZIP proteins that form tetramers.     

cys-3, the positive-acting sulfur regulatory gene of Neurospora crassa, encodes a protein with a putative leucine zipper DNA-binding element.

The sulfur-regulatory circuit of Neurospora crassa consists of a set of unlinked structural genes which encode sulfur-catabolic enzymes and two major regulatory genes which govern their expression. The positive-acting cys-3 regulatory gene is required to turn on the expression of the sulfur-related enzymes, whereas the other regulatory gene, scon, acts in a negative fashion to repress the synthesis of the same set of enzymes. Expression of the cys-3 regulatory gene was found to be controlled by scon and by sulfur availability. The nucleotide sequence of the cys-3 gene was determined and can be translated to yield a protein of molecular weight 25,892 which displays significant homology with the oncogene protein Fos, yeast GCN4 protein, and sea urchin histone H1. Moreover, the putative cys-3 protein has a well-defined leucine zipper element plus an adjacent charged region which together may make up a DNA-binding site. A cys-3 mutant and a cys-3 temperature-sensitive mutant lead to substitutions of glutamine for basic amino acids within the charged region and thus may alter DNA-binding properties of the cys-3 protein.     

Thymine 7-hydroxylase from Neurospora crassa. Substrate specificity studies.

A partially purified preparation of thymine 7-hydroxylase (thymine, 2-oxoglutarate : oxygen oxidoreductase (7-hydroxylating), EC 1.14.11.6) from Neurospora crassa was incubated with a number of pyrimidines chemically related to tyymine. 1. Pyrimidines with oxygen or sulfur substituents on atoms Nos. 2 and 4 as well as an alkyl group on atom Nos. 1 or 5 were substrates. 2. Km values were determined for 1-methyluracil, 1-ethyluracil, thymine, 6-azathymine, 1-methylthymine, 1-ethylthymine, 5-formyluracil and 5-hydroxymethyluracil. 3. Uracil was identified as one of the metabolites after incubation with 1-methyluracil. The one-carbon metabolite has not been characterized. 4. Several pyrimidines with polar groups on atoms Nos. 2 and 4 were inhibitory. 5. Addition of 1-methyluracil, 1-methylthymine, 1-ethylthymine or 5-hydroxymethyluracil to incubations with thymine and 2-oxo[1-14C1]glutarate did not result in additional formation of 14CO2, indicating that the same enzyme acts on the different compounds. It has previously been found (Bankel, L., Holme, E., Lindstedt, G. and Lindstedt, S. (1972) FEBS Lett. 21, 135-138) that a mutant strain of N. crassa which is devoid of thymine 7-hydroxylase activity also lacks ability to perform the coupled oxygenation of 2-oxoglutarate and 1-methyluracil, 5-hydroxymethyluracil and 5-formyluracil, respectively. It is concluded that one and the same oxygenase is responsible for the activities studied.     

The function of mitochondrial genes in Neurospora crassa.

The 18 extranuclear mutants of Neurospora crassa, without exception, have abnormal mitochondrial respiratory systems. On the basis of genetic, phenotypic and physiological criteria, these mutants are divided into four groups: 1) the cytochrome aa3 and b deficient "poky" variants that are defective in mitochondrial ribosomes assembly, 2) the cytochrome aa3 deficient mutants, [mi-3] and [exn-5], that appear to have genetic lesions affecting a component of a regulatory system controlling cytochrome aa3 synthesis, 3) the cytochrome aa3 and b deficient "stopper" mutants with physiological lesions that probably affect mitochondrial protein synthesis, and 4) cni-3, a mutant that is constitutive for an inducible mitochondrial cyanide-insensitive oxidase in spite of having a normal cytochrome mediated electron-transport system. It is proposed that the mitochondrial genophore not only codes for cellular components that are essential for the formation of the mitochondrial protein synthesizing apparatus, but also for components of a regulatory system that coordinates the expression of nuclear and mitochondrial genes during the biogenesis of the mitochondrial electorn-transport system.     

Analysis of a case of mutagen specificity in Neurospora crassa. 3. Fractionated treatment with diepoxybutane (DEB)

Summary Weak doses of DEB given before or after a moderately high dose act as booster for the production of adenine-reversions. Fractionation of a moderate or high dose into a succession of weak ones yields a dose-effect curve that lies above the linear curve expected for additivity of the fractions but below that found after continuous exposure. The results lend support to the view that DEB, in addition to producing potential adenine-reversions in DNA, promotes their realization by its effect on some cellular process or processes, and that this is the cause of the steep dose-response to continuous exposure.     

SREBP-1 dimerization specificity maps to both the helix-loop-helix and leucine zipper domains: use of a dominant negative

The mammalian SREBP family contains two genes that code for B-HLH-ZIP proteins that bind sequence-specific DNA to regulate the expression of genes involved in lipid metabolism. We have designed a dominant negative (DN), termed A-SREBP-1, that inhibits the DNA binding of either SREBP protein. A-SREBP-1 consists of the dimerization domain of B-SREBP-1 and a polyglutamic acid sequence that replaces the basic region. A-SREBP-1 heterodimerizes with either B-SREBP-1 or B-SREBP-2, and both heterodimers are more stable than B-SREBP-1 bound to DNA. Circular dichroism thermal denaturation studies show that the B-SREBP-1.A-SREBP-1 heterodimer is -9.8 kcal mol(-1) dimer(-1) more stable than the B-SREBP-1 homodimer. EMSA assays demonstrate that A-SREBP-1 can inhibit the DNA binding of either B-SREBP-1 or B-SREBP-2 in an equimolar competition but does not inhibit the DNA binding of the three B-HLH-ZIP proteins MAX, USF, or MITF, even at 100 molar eq. Chimeric proteins containing the HLH domain of SREBP-1 and the leucine zipper from either MAX, USF, or MITF indicate that both the HLH and leucine zipper regions of SREBP-1 contribute to its dimerization specificity. Transient co-transfection studies demonstrate that A-SREBP-1 can inhibit the transactivation of SREBP-1 and SREBP-2 but not USF. A-SREBP-1 may be useful in metabolic diseases where SREBP family members are overexpressed.     

Specific regulatory interconnection between the leucine and histidine pathways of Neurospora crassa.

Leucine auxotrophs of Neurospora fall into two discrete categories with respect to sensitivity to the herbicide, 3-amino-1,2,4-triazole. The pattern of resistance corresponds exactly to the ability to produce the leucine pathway control elements, alpha-isopropylmalate and the leu-3 product. An analysis of the regulatory response of the production of enzymes of histidine biosynthesis to alpha-isopropylmalate implicates the control elements of the leucine pathway as important components of the mechanism governing the production of the target enzyme of aminotriazole inhibition, imidazoleglycerol-phosphate dehydratase (EC 4.2.1.19). The evidence suggests that the regulatory interconnection between the two pathways is direct and is independent of other general integrating regulatory mechanisms which appear to be operative in both pathways. A general method for isolating leu-1 and leu-2, as well as other regulatory mutants, is described, which takes advantage of the specificity of the resistance to the inhibitor. Use of analogous systems is prescribed for the analysis of other regulatory interconnections which, like this one, might not be anticipated directly from structural or biosynthetic considerations.     

Cryobiology of Neurospora crassa. II. Alteration in freeze response of Neurospora crassa conidia by additives

Neurospora crassa conidia in aqueous suspensions were frozen and thawed in the presence of various agents. Colony counts with these treatments were compared with those of the following (a) unfrozen, agent-treated, (b) unfrozen water suspended, and (c) frozen, water suspended. It was found that dimethyl sulfoxide (0.5–20%) resulted in total protection against freeze damage. Glycerol and calcium chloride decreased survival as much as 90% with fast freeze. The latter agents have properties which should decrease the rate of outflow of cellular water during temperature lowering. The results are consistent with the proposal that intracellular ice crystal growth to membrane rupturing dimensions is the damaging freeze mechanism under these conditions.