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

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

Genetical and molecular analyses of qa-2 transformants in Neurospora crassa.

Neurospora crassa qa-2+ transformants from five different donor DNA clones were analyzed by genetical and molecular techniques. None of the 32 transformants have the qa-2+ DNA replacing the qa-2- gene in linkage group VII. In one transformant, the qa-2+ DNA was inserted adjacent to the qa-2- gene. Thirty-one transformants have the qa-2+ inserts at sites not linked, or not closely linked, to the qa-2 locus in LG VII. Plasmid sequences were integrated along with the qa-2+ gene in 28 transformants. In the unlinked duplication-type transformants, catabolic dehydroquinase (the qa-2+ gene product) was induced at 5-100% of the wild-type-induced enzyme activity, with 24 transformants in the 5-80% range. The reduced levels of enzyme activity may be due to "position effects" of sequences adjacent to the integration site either in the N. crassa genomic DNA or in the flanking plasmid (pBR322 or pBR325) sequences. Unexpected gene conversion-like events, in which a qa-2+ gene was changed to qa-2-, were observed in tetrads from intercrosses between unlinked duplication-type transformants and in selfings of such transformants.

Revertants and secondary arom-2 mutants induced in non-complementing mutants in the arom gene cluster of Neurospora crassa.

Extensive genetical and biochemical studies have been performed with revertants and secondary arom-2 mutants induced in two different primary non-complementing mutants which map within the arom gene cluster of Neurospora crassa. These studies indicate that mutant M54 but not M25 can revert by super-suppressor mutations in unlinked genes, thus confirming previous evidence that M54 contains a nonsense codon. At least three new super suppressors of M54 have been detected. All four super suppressors (including one previously detected) when combined with M54 result in high levels of all five of the arom enzymic activities in the form of arom multienzyme complexes very similar to (but not necessarily identical with) that in wild type (WT).-Evidence has also been obtained that the two non-complementing mutants can yield revertants which appear to result from true back mutations and produce arom aggregates essentially indistinguishable from that of WT. In addition, M25, but not M54, when plated on quinic acid yields revertants (secondary mutants) some of which are phenotypically indistinguishable from arom-2 primary mutants and others of which, although also mapping within the arom-2 gene, exhibit unusual properties. Genetic evidence indicates that the M25 secondary mutants are localized within the arom-2 gene, but that they arise from mutational events more complex than ones resulting in single base pair changes in the M25 codon.-The recovery of secondary arom-2 mutants as revertants of non-complementing arom mutants provides strong evidence, independent of earlier recombination data, that non-complementing arom mutants are located within the arom-2 structural gene of the arom gene cluster. In addition, the occurrence and characteristics of these secondary arom-2 mutants provide strong evidence, independent of the results with nonsense suppressors, that the arom gene cluster is transcribed, beginning with the arom-2 gene, as a single polycistronic messenger ribonucleic acid (mRNA) molecule which is subsequently translated into the arom multienzyme complex.

Temperature-sensitive pleiotropic revertants from a mutant in the arom gene cluster of Neurospora crassa.

Genetical and biochemical studies have been performed with revertants induced in a polyaromatic mutant (No. 58) in the arom gene cluster of Neurospora crassa. In addition to complete and partial revertants able to grow on minimal at both 25 degrees and 35 degrees , temperature-sensitive revertants capable of growth on minimal at 25 degrees but not at 35 degrees have been recovered. One of these revertants has been shown to lack biosynthetic dehydroquinase activity at both temperatures (utilizing the inducible catabolic isozyme for growth at 25 degrees ), to have dehydroshikimate reductase activity only at 25 degrees , and to form an arom aggregate having a molecular weight approximately one-half that of wild type. These results are interpreted as indicating that pleiotropic mutants in the arom gene cluster can result from missense mutations, as well as from nonsense mutations as indicated in previous studies.

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

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

Use of gene replacement transformation to elucidate gene function in the qa gene cluster of Neurospora crassa.

Gene replacement by transformation, employing selective genetic recombination techniques, has been used to delete or disrupt the qa-x, qa-y and qa-1S genes of the qa gene cluster of Neurospora crassa. The growth characteristics of the strain carrying the deletion of the qa-y gene support earlier evidence that this gene encodes a quinic acid permease. The strain containing the deletion of the qa-1S gene (delta qa-1S) was examined with respect to quinic acid induction and carbon catabolite repression. The delta qa-1S strain exhibits constitutive expression of the qa genes supporting earlier evidence that the qa-1S gene codes for a repressor. Several of the qa genes continued to be expressed at high levels even in the presence of glucose in the delta qa-1S strain, which indicates that transcription of these genes is not being affected directly by a repressor molecule in the presence of glucose.

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

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

Direct induction in wild-type Neurospora crassa of mutants (qa-1 c ) constitutive for the catabolism of quinate and shikimate.

A color test has been developed for the selection and identification of mutants in Neurospora crassa, constitutive for the three normally inducible enzymes which convert quinate to protocatechuate. By this means seven such mutants have been recovered after ultra violet irradiation of wild type and have been shown to be allelic (or very closely linked) to the qa-1(C) mutants previously obtained by other means. Thus, the regulation of the synthesis of these three catabolic enzymes is indicated to be under the control of a single gene, qa-1(+).

The Neurospora crassa genome: cosmid libraries sorted by chromosome.

A Neurospora crassa cosmid library of 12,000 clones (at least nine genome equivalents) has been created using an improved cosmid vector pLorist6Xh, which contains a bacteriophage lambda origin of replication for low-copy-number replication in bacteria and the hygromycin phosphotransferase marker for direct selection in fungi. The electrophoretic karyotype of the seven chromosomes comprising the 42.9-Mb N. crassa genome was resolved using two translocation strains. Using gel-purified chromosomal DNAs as probes against the new cosmid library and the commonly used medium-copy-number pMOcosX N. crassa cosmid library in two independent screenings, the cosmids were assigned to chromosomes. Assignments of cosmids to linkage groups on the basis of the genetic map vs. the electrophoretic karyotype are 93 +/- 3% concordant. The size of each chromosome-specific subcollection of cosmids was found to be linearly proportional to the size of the particular chromosome. Sequencing of an entire cosmid containing the qa gene cluster indicated a gene density of 1 gene per 4 kbp; by extrapolation, 11,000 genes would be expected to be present in the N. crassa genome. By hybridizing 79 nonoverlapping cosmids with an average insert size of 34 kbp against cDNA arrays, the density of previously characterized expressed sequence tags (ESTs) was found to be slightly <1 per cosmid (i.e., 1 per 40 kbp), and most cosmids, on average, contained an identified N. crassa gene sequence as a starting point for gene identification.

Sequence and characterization of the met-7 gene of Neurospora crassa.

The proteins encoded by the met-7+ and met-3+ genes of Neurospora crassa are required to form a functional cystathionine-gamma-synthase (CGS). The met-7+ gene has been cloned by complementation of a met-7 mutant. The nucleotide sequence of the complementing DNA reveals the presence of a 542-amino acid open reading frame (ORF). Disruption of this ORF abolishes complementation of the met-7 mutation.

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

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

Sacral agenesis. Neurologic and neuropathologic features.

The neurologic deficits in sacral agenesis involve motor function much more than sensory function, in a lumbosacral distribution; autonomic involvement, with neurogenic bladder, is variable. Relative sensory sparing may be due to the derivation of sensory nerves from neural cre, t tissue, which is uninvolved. An occult sacral meningomyelocele with ectopic neural tissue was found at necropsy in one of our patients. Primary amyoplasia may account for small but histologically normal muscles derived from the same somites as the aplastic vertebrae.

Primary reticulum-cell sarcoma (microglioma) of the brain with massive cardiac metastasis. Case report.

A patient is presented with reticulum-cell sarcoma of the brain and a large metastasis to the heart.

Xylazine in human tissue and fluids in a case of fatal drug abuse.

A fatal case of multiple drug abuse in a 36-year-old veterinarian involving injection of xylazine and ingestion of alcohol and clorazepate is presented. Quantitative analysis of xylazine was by gas liquid chromatography with a nitrogen detector. Xylazine concentrations (mg/L or mg/kg) were: blood, 0.2; brain, 0.4; kidney, 0.6; liver, 0.9; lung, 1.1; omentum adipose 0.05; and urine, 7.0. Blood ethanol and nordiazepam concentrations were 380 mg/dL and 2.5 mg/L, respectively.

Laceration of the stomach by blunt trauma in a child: a case of child abuse.

A case of perforation of the stomach following blunt abdominal trauma is described in a two-year-old boy. The abdominal trauma was the result of a blow to the abdomen by the stepfather. The child had ingested a large meal in the hour preceding the injury. The child died from peritonitis and shock 12 h following the injury. The literature on gastric perforation by blunt trauma is reviewed. Injuries to the stomach from nonpenetrating trauma are quite rare and are most often related to vehicular accidents. Gastric injury in a child presenting with a history of a minor home or play injury should arouse suspicion of more significant and perhaps intentional trauma.

Homicide by intravenous injection of naphtha.

A case of homicide by the intravenous injection of Energine, a petroleum distillate spot remover, is presented. This case is the only known homicide committed with naphtha. This elderly man had severe natural disease in addition to chest trauma sustained in the assault leading to death; however, the rapid injection of approximately 25 mL of Energine was the overwhelming cause of death.

Sexual asphyxiation: an unusual case involving four male adolescents.

A case of sexual asphyxiation is described involving children, adolescent males, homosexuality and two bizarre strangulations. Two adolescent males (ages 13 & 10) initially engaged in homosexual activity in conjunction with sexual asphyxiation. This unusual activity was by chance observed by one of the boy's younger brother and his friend. The younger children (aged 7 & 8) expressed a desire to join in the activity, which they did by letting ligatures be tied around their necks and engaging in anal intercourse to the point of fatal asphyxiation. The case is of interest in the reported way the younger boys discovered the practice (a sexually explicit magazine) and is unusual because of the young ages of the boys involved.