A mutation in gamma-tubulin alters microtubule dynamics and organization and is synthetically lethal with the kinesin-like protein pkl1p.

Mitotic segregation of chromosomes requires spindle pole functions for microtubule nucleation, minus end organization, and regulation of dynamics. gamma-Tubulin is essential for nucleation, and we now extend its role to these latter processes. We have characterized a mutation in gamma-tubulin that results in cold-sensitive mitotic arrest with an elongated bipolar spindle but impaired anaphase A. At 30 degrees C cytoplasmic microtubule arrays are abnormal and bundle into single larger arrays. Three-dimensional time-lapse video microscopy reveals that microtubule dynamics are altered. Localization of the mutant gamma-tubulin is like the wild-type protein. Prediction of gamma-tubulin structure indicates that non-alpha/beta-tubulin protein-protein interactions could be affected. The kinesin-like protein (klp) Pkl1p localizes to the spindle poles and spindle and is essential for viability of the gamma-tubulin mutant and in multicopy for normal cell morphology at 30 degrees C. Localization and function of Pkl1p in the mutant appear unaltered, consistent with a redundant function for this protein in wild type. Our data indicate a broader role for gamma-tubulin at spindle poles in regulating aspects of microtubule dynamics and organization. We propose that Pkl1p rescues an impaired function of gamma-tubulin that involves non-tubulin protein-protein interactions, presumably with a second motor, MAP, or MTOC component.

Mutational analysis of the gene for Schizosaccharomyces pombe RNase MRP RNA, mrp1, using plasmid shuffle by counterselection on canavanine.

Reverse genetics in fission yeast is hindered by the lack of a versatile established plasmid shuffle system. In order to screen efficiently and accurately through plasmid-borne mutations in the essential gene for the RNA component of RNase MRP, mrp1, we have developed a system for plasmid shuffling in fission yeast using counterselection on canavanine. The system takes advantage of the ability of the Saccharomyces cerevisiae CAN1 gene to complement a Schizosaccharomyces pombe can1-1 mutation. Two general use plasmids were constructed that allow directional cloning and initial selection for histidine before counterselection by canavanine. The strain constructed for plasmid shuffling carries auxotrophic markers for ade6, leul, ura4 and his3 along with the can1-1 mutation. Using this system we examined several partial deletions and point mutations in conserved nucleotides of Schizosaccharomyces pombe RNase MRP RNA for their ability to complement a chromosomal deletion of the mrp1 gene. The degree of background canavanine resistance as well as plasmid-plasmid recombination encountered in these experiments was sufficiently low to suggest that the system we have set up for counterselection by canavanine in fission yeast using multicopy plasmids will be widely useful.

A functional dominant mutation in Schizosaccharomyces pombe RNase MRP RNA affects nuclear RNA processing and requires the mitochondrial-associated nuclear mutation ptp1-1 for viability.

The essential gene for RNase MRP RNA, mrp1, was identified previously in Schizosaccharomyces pombe by homology to mammalian RNase MRP RNAs. Here we describe distinct site-specific mutations in RNase MRP RNA that support a conserved role for this ribonucleoprotein in nucleolar 5.8S rRNA processing. One characterized mutation, mrp1-ND90, displays dominance and results in accumulation of unspliced precursor RNAs of dimeric tRNA(Ser)-tRNA(Met)i, suggesting a novel nuclear role for RNase MRP in tRNA processing. Cells carrying the mrp1-ND90 mutation, in the absence of a wild-type copy of mrp1, additionally require the mitochondrially associated nuclear mutation ptp1-1 for viability. Analysis of this mrp1 mutation reinforces previous biochemical evidence suggesting a role for RNase MRP in mitochondrial DNA replication. Several mutations in mrp1 result in unusual cellular morphology, including alterated nuclear organization, and are consistent with a broader nuclear role for RNase MRP in regulating a nuclear signal for septation; these results are a further indication of the multifunctional nature of this ribonucleoprotein.

Requirement for CD8+ T cells in the development of airway hyperresponsiveness in a marine model of airway sensitization.

To study the role of CD8+ T cells in allergic sensitization, we examined the effects of in vivo depletion of CD8+ T cells prior to sensitization on IgE production, immediate type cutaneous hypersensitivity and development of altered airway responsiveness. BALB/c mice were thymectomized and treated with anti-CD8 antibody resulting in depletion of CD8+ T cells (<1%) in spleen and lymphoid tissues. In these mice, sensitization to ovalbumin (OVA) via the airways still resulted in IgE anti-OVA responses and immediate cutaneous reactions to OVA, but the animals were unable to develop airway hyperresponsiveness, eosinophil infiltration of the lung parenchyma, or IL-5 production in the local lymph nodes of the airway. Transfer of CD8+ T cells from naive animals during sensitization (on day 8 of the 10-d protocol) fully restored the ability to develop airway hyperresponsiveness and this was accompanied by IL-5 production and eosinophil accumulation in the lung. These data indicate a critical role for CD8+ T cells in the production of IL-5 and the development of altered airway responsiveness after antigen sensitization through the airways.

Schizosaccharomyces pombe RNase MRP RNA is homologous to metazoan RNase MRP RNAs and may provide clues to interrelationships between RNase MRP and RNase P.

RNase MRP and RNase P ribonucleoproteins are structurally and functionally similar across a large evolutionary distance. To better characterize possible complex interrelationships between these two enzymes, we have employed the fission yeast Schizosaccharomyces pombe. Unlike Saccharomyces cerevisiae, S. pombe is believed to harbour only one genetic locus for the RNA component of RNase P and does not contain a known mitochondrially encoded RNase P RNA. We have identified the single nuclear gene for the RNA component of RNase MRP in S. pombe, mrp-1, by homology to vertebrate RNase MRP RNAs. The mrp-1 gene encodes an RNA of maximum mature length 400 nucleotides that shares a high degree of identity, in evolutionarily conserved regions, to both vertebrate RNase MRP RNAs and S. pombe RNase P RNA. Disruption of mrp-1 in the diploid strain SP826 and sporulation of tetrads resulted in a 2 dead:2 viable segregation, consistent with the gene being essential. Lethality is rescued by a plasmid-borne copy of mrp-1. Partially purified ribonucleoprotein RNase MRP activity correctly and efficiently processed all previously characterized heterologous mitochondrial RNA substrates. The compact mitochondrial genome of S. pombe contains sequence elements with > 50% identity to mammalian D-loop CSBI and CSBII elements. The identification of mrp-1 in S. pombe should facilitate not only comparisons between the related ribonucleoproteins RNase MRP and RNase P, but should also provide an opportunity for genetic elucidation of RNase MRP function in a situation reflective of the animal kingdom.

cpc-1, the general regulatory gene for genes of amino acid biosynthesis in Neurospora crassa, is differentially expressed during the asexual life cycle.

CPCI, the principal regulatory protein required for cross-pathway control of amino acid biosynthetic genes in Neurospora crassa, contains a domain similar to the DNA-binding domain of GCN4, the corresponding general regulator in Saccharomyces cerevisiae. We examined binding by CPC1 synthesized in vitro and by CPC1 present in N. crassa whole-cell extracts. CPCI from both sources was shown to bind to the DNA sequence 5'-ATGACTCAT-3', which is also the preferred recognition sequence of GCN4, CPC1 was confirmed as the source of DNA-binding activity in extracts by immunoblotting. Slightly mobility differences between DNA complexes containing CPCI synthesized in vitro and CPC1 in mycelial extracts were observed. Analyses of N. crassa extracts from different stages of asexual development revealed that CPC1 was abundant immediately following spore germination and through early mycelial growth but was scarce subsequently. CPC1 levels could be increased at any time by imposing amino acid starvation. Copies of the CPC1 response element are located upstream of several genes regulated by cross-pathway control, including cpc-1 itself.

Characterization of Neurospora CPC1, a bZIP DNA-binding protein that does not require aligned heptad leucines for dimerization.

CPC1 is the transcriptional activator of amino acid biosynthetic genes of Neurospora crassa. CPC1 function in vivo was abolished upon deletion of segments of cpc-1 corresponding to the presumed transcription activation domain, the DNA-binding and dimerization domains, or a 52-residue connector segment of CPC1. A truncated CPC1 polypeptide containing only the carboxy-terminal 57-residue segment of CPC1 was sufficient to form homodimers that bound DNA. However, deletion of the segment of cpc-1 corresponding to the connector segment in the full-length CPC1 polypeptide abolished DNA binding. Removal of a segment of cpc-1 corresponding to the GIn-rich region of CPC1 reduced in vivo function only slightly. The homologous transcription activator of Saccharomyces cerevisiae, GCN4, did not substitute for CPC1 in N. crassa. Chimeric CPC1-GCN4 polypeptides that contained the GCN4 transcriptional activation domain or the domain of GCN4 that corresponds to the essential 52-residue connector segment of CPC1, functioned with reduced efficiency. However, a chimeric polypeptide containing the GCN4 DNA-binding and dimerization domains in place of those of CPC1 functioned essentially as well as wild-type CPC1. The basic and dimerization domains of CPC1 were characterized by introducing deletions or site-directed amino acid replacements. The basic region was required for DNA binding but not for dimerization. CPC1 has a short dimerization domain containing heptad residues Leu-1, Leu-2, Trp-3, and His-4. When Val was substituted for Leu-1 or Leu-2, CPC1 was fully active, but when Val replaced Trp-3, dimerization and DNA binding were prevented. DNA band shift analyses with CPC1 heterodimers demonstrated that CPC1 does not require aligned heptad leucine residues for dimerization. Replacement of two charged residues located between Leu-1 and Leu-2 of CPC1 abolished dimerization and DNA binding.

Determination of the inactivating alterations in two mutant alleles of the Neurospora crassa cross-pathway control gene cpc-1.

cpc-1 is the locus specifying what is believed to be the major trans-activating transcription factor that regulates expression of amino acid biosynthetic genes subject to cross-pathway control in Neurospora crassa. Mutants altered at this locus are incapable of the global increase in gene expression normally seen in response to amino acid starvation. Using polymerase chain reaction methodology we have cloned and sequenced the inactive mutant allele, cpc-1 (CD15). The cpc-1 (CD15) mutation was found to be a single base pair deletion in codon 93 of the cpc-1 structural gene. A second, presumed lethal, allele, cpc-1 (j-5), also was investigated. Northern analyses with strains carrying the cpc-1 (j-5) allele revealed that no cpc-1 mRNA is produced. Southern and genetic analyses established that the cpc-1 (j-5) mutation involved a chromosomal rearrangement in which a break occurred within the cpc-1 locus, normally resident on linkage group VI; a small fragment from the left arm of linkage group VI, containing the cpc-1 promoter region and ylo-1, was translocated to the right arm of linkage group I. Other studies indicate that the cpc-1 locus itself is not essential for viability. Lethality previously attributed to the cpc-1 (j-5) mutation is due instead to the production of progeny that are deficient for essential genes in an adjoining segment of linkage group VI. Molecular characterization of cpc-1 (j-5) x ylo-1 pan-2 duplication progeny indicated that cpc-1 is normally transcribed towards the linkage group VI centromere.

Evolution of the tryptophan synthetase of fungi. Analysis of experimentally fused Escherichia coli tryptophan synthetase alpha and beta chains.

During evolution of fungi, the separate tryptophan synthetase alpha and beta polypeptides of bacteria appear to have been fused in the order alpha-beta rather than the beta-alpha order that would be predicted from the order of the corresponding structural genes in all bacteria. We have fused the tryptophan synthetase polypeptides of Escherichia coli in both orders, alpha-beta and beta-alpha, with and without a short connecting (con) sequence, to explore possible explanations for the domain arrangement in fungi. We find that proteins composed of any of the four fused polypeptides, beta-alpha, beta-con-alpha, alpha-beta, and alpha-con-beta, are highly active enzymatically. However, only the alpha-beta and alpha-con-beta proteins are as active as the wild type enzyme. All four fusion proteins appear to be less soluble in vivo than the wild type enzyme; this abnormal characteristic is minimal for the alpha-con-beta enzyme. The alpha and beta domains of the four fusion polypeptides were not appreciably more heat labile than the wild type polypeptides. Competition experiments with mutant tryptophan synthetase alpha protein, and the fusion proteins suggest that in each fusion protein the joined alpha and beta domains have a functional tunnel connecting their alpha and beta active sites. Three tryptophan synthetase beta'-alpha fusion proteins were examined in which the carboxyl-terminal segment of the wild type beta polypeptide was deleted and replaced by a shorter, unnatural sequence. The resulting deletion fusion proteins were enzymatically inactive and were found predominantly in the cell debris. Evaluation of our findings in relation to the three-dimensional structure of the tryptophan synthetase enzyme complex of Salmonella typhimurium (5) and the results of mutational analyses with E. coli suggest that tryptophan synthetase may have evolved via an alpha-beta rather than a beta-alpha fusion because in beta-alpha fusions the amino-terminal helix of the alpha chain cannot assume the conformation required for optimal enzymatic activity.

The cross-pathway control gene of Neurospora crassa, cpc-1, encodes a protein similar to GCN4 of yeast and the DNA-binding domain of the oncogene v-jun-encoded protein.

Expression of the gene cpc-1 is required for cross-pathway-mediated regulation of amino acid-biosynthetic genes in Neurospora crassa. We have cloned cpc-1 and present an analysis of its structure and regulation. The cpc-1-encoded transcript contains three open reading frames, two of which are located in the 720-nucleotide leader segment preceding the cpc-1 coding region. The two leader open reading frames, if translated, would produce peptides 20 and 41 residues in length. The deduced amino acid sequence of the cpc-1 polypeptide, CPC1, contains segments similar to the DNA-binding and transcriptional activation domains of GCN4, the major cross-pathway regulatory protein of yeast. The structural and functional similarities of CPC1 and GCN4 proteins suggest that cpc-1 encodes the analogous transcriptional activator of N. crassa. Messenger RNA measurements indicate that cpc-1 is transcriptionally regulated in response to amino acid starvation. The segment of CPC1 similar to the DNA-binding domain of GCN4 also is similar to the DNA-binding domains of the avian sarcoma virus oncogene-encoded v-JUN protein and human c-JUN protein.

Fusion of trpB and trpA of Escherichia coli yields a partially active tryptophan synthetase polypeptide.

The separate alpha and beta polypeptides of the tryptophan synthetase of bacteria are represented in fungi by a fusion polypeptide in which the first third is homologous to bacterial alpha chains and the remainder is homologous to bacterial beta chains. In the yeast polypeptide, a short nonhomologous "connector" joins the two homologous segments. The chromosomal order of all bacterial genes that specify tryptophan synthetase beta and alpha chains, respectively, is trpB-trpA. Fusion of these genes in their present arrangement would result in the synthesis of a polypeptide with a segmental order, N-beta-alpha-C, opposite that observed in fungi. To investigate possible explanations for the apparent transposition that occurred in the evolution of the fungal gene we have made two fusions of trpB and trpA of Escherichia coli in their natural orientation. We find that the fusion proteins are synthesized but both are less active catalytically than the wild type bacterial protein. In addition, the fusion proteins associate abnormally, they are activated only slightly by wild type alpha or beta 2, and they are less sensitive than the wild type protein to inhibition by antibodies to alpha or beta 2. The fusion proteins have normal substrate affinities. Our findings suggest that the altered structures of the fusion proteins affect catalytic ability and the locations of the alpha and/or beta chain combining sites. This structural distortion may have prevented the natural selection of direct gene fusions during the course of the fungal gene's evolution.

High level production and rapid purification of the E. coli trp repressor.

Two small, multicopy, expression plasmids were constructed that permit convenient insertion of trpR, the structural gene for the trp repressor of Escherichia coli, with its natural ribosome binding site or adjacent to the ribosome binding site for the trp leader peptide. In these plasmids trpR is positioned between the strong regulated tac promoter and the rpoC transcription terminator. IPTG induction of lacIq strains bearing these plasmids results in the production of 25-50% of the soluble cell protein as trp repressor. Mutant and wild type repressors overproduced in this manner have been purified by simple procedures.

Mutagenesis of ligands to the [4 Fe-4S] center of Bacillus subtilis glutamine phosphoribosylpyrophosphate amidotransferase.

Several mutations were constructed in residues thought to provide ligands for a [4Fe-4S] cluster in Bacillus subtilis amidophosphoribosyltransferase using site-directed mutagenesis of cloned purF. These replacements confirm the identification of cysteinyl ligands to the Fe-S center. Of five mutant enzymes, two had no activity, two less than 25% of the wild type activity, and one was lethal and could not be studied. The Fe content of the two mutant enzymes with partial activity was similar to that of the wild type. Results of partial characterization suggest that the [4Fe-4S] cluster is not involved in allosteric regulation and does not play a specific role in the ammonia- or glutamine-dependent reactions of the enzyme. At least partial enzymatic activity is required for NH2-terminal processing. Pulse labeling experiments suggest that processing is a slow post-translational process which is dependent upon cellular factors. A relationship between Fe-S centers and NH2-terminal processing of an undecapeptide leader suggests a functional connection between these two structural elements in amidophosphoribosyltransferase.

Replacement by site-directed mutagenesis indicates a role for histidine 170 in the glutamine amide transfer function of anthranilate synthase.

Anthranilate synthase is a glutamine amidotransferase that catalyzes the first reaction in tryptophan biosynthesis. Conserved amino acid residues likely to be essential for glutamine-dependent activity were identified by alignment of the glutamine amide transfer domains in four different enzymes: anthranilate synthase component II (AS II), p-aminobenzoate synthase component II, GMP synthetase, and carbamoyl-P synthetase. Conserved amino acids were mainly localized in three clusters. A single conserved histidine, AS II His-170, was replaced by tyrosine using site-directed mutagenesis. Glutamine-dependent enzyme activity was undetectable in the Tyr-170 mutant, whereas the NH3-dependent activity was unchanged. Affinity labeling of AS II active site Cys-84 by 6-diazo-5-oxonorleucine was used to distinguish whether His-170 has a role in formation or in breakdown of the covalent glutaminyl-Cys-84 intermediate. The data favor the interpretation that His-170 functions as a general base to promote glutaminylation of Cys-84. Reversion analysis was consistent with a proposed role of His-170 in catalysis as opposed to a structural function. These experiments demonstrate the application of combining sequence analyses to identify conserved, possibly functional amino acids, site-directed mutagenesis to replace candidate amino acids, and protein chemistry for analysis of mutationally altered proteins, a regimen that can provide new insights into enzyme function.

Study of anthranilate synthase function by replacement of cysteine 84 using site-directed mutagenesis.

Cysteine 84 was replaced by glycine in Serratia marcescens anthranilate synthase Component II using site-directed mutagenesis of cloned trpG. This replacement abolished the glutamine-dependent anthranilate synthase activity but not the NH3-dependent activity of the enzyme. The mutation provides further evidence for the role of active site cysteine 84 in the glutamine amide transfer function of anthranilate synthase Component II. By the criteria of circular dichroism, proteolytic inactivation, and feedback inhibition the mutant and wild type enzymes were structurally similar. The NH3-dependent anthranilate synthase activity of the mutant enzyme supported tryptophan synthesis in media containing a high concentration of ammonium ion.

Nucleotide sequence of Saccharomyces cerevisiae genes TRP2 and TRP3 encoding bifunctional anthranilate synthase: indole-3-glycerol phosphate synthase.

Saccharomyces cerevisiae anthranilate synthase:indole-3-glycerol phosphate synthase is a multifunctional hetero-oligomeric enzyme encoded by genes TRP2 and TRP3. TRP2, encoding anthranilate synthase Component I, was cloned by complementation of a yeast trp2 mutant. The nucleotide sequence of TRP2 as well as that of TRP3 were determined. The deduced anthranilate synthase Component I primary structure from yeast exhibits only limited similarity to that of the corresponding Escherichia coli subunit encoded by trpE. On the other hand, yeast anthranilate synthase Component II and indole-3-glycerol phosphate synthase amino acid sequences from TRP3 are clearly homologous with the corresponding sequences of the E. coli trpG and trpC polypeptide segments and thereby establish the bifunctional structure of TRP3 protein. Based on comparisons of TRP3 amino acid sequence with homologous sequences from E. coli and Neurospora crassa, an 11-amino acid residue connecting segment was identified which fuses the trpG and trpC functions of the bifunctional TRP3 protein chain. These comparisons support the conclusion that the amino acid sequence of connectors in homologous multifunctional enzymes need not be conserved. Connector function is thus not dependent on a specific sequence. Nuclease S1 mapping was used to identify mRNA 5' termini. Heterogeneous 5' termini were found for both TRP2 and TRP3 mRNA. TRP2 and TRP3 5'-flanking regions were analyzed for sequences that might function in regulation of these genes by the S. cerevisiae general amino acid control system. The 9 base pair direct repeat (Hinnebusch, A.G., and Fink, G.R. (1983) J. Biol. Chem. 258, 5238-5247) and inverted repeats were identified in the 5'-flanking sequences of TRP2 and TRP3.

Isolation of Saccharomyces cerevisiae TRP3.

Several plasmids, isolated from two plasmid pools, complemented a Saccharomyces cerevisiae trp3 mutant with defective indole-3-glycerol-phosphate synthase activity. Restriction mapping indicated that a 1.2-kilobase StuI segment was common to all complementing plasmids. Southern blot hybridization established that a cloned 5.2-kilobase BamHI fragment was derived intact from chromosomal DNA. A yeast trp3 mutant transformed with trp3-complementing plasmids contained approximately 40-fold elevated indole-3-glycerol-phosphate synthase activity. These plasmids also complemented an Escherichia coli trpC mutant, and transformants exhibited enzyme activity. Yeast trp3 is therefore associated with a 1.2-kilobase StuI DNA segment.