ADAPTATION IN PANTOTHENATE-REQUIRING NEUROSPORA. I. A GENE MODIFYING PANTOTHENATE MUTANTS

Davis, r . H. (California Inst. Tech., Pasadena.) Adaptation in pantothenate-requiring Neurospora. i. a gene modifying pantothenate mutants. Amer. Jour. Bot. 4(5): 351–357. Illus. 1960.—a modified pantothenicless strain was isolated from a pan-1, al-1, A mycelium which had adapted to a limiting concentration of pantothenate. The modified and original strains differ by a single gene, m, which is not linked genetically to either of the 2 known pantothenic acid loci. The gene m appears to modify the uptake, rather than the synthesis, of pantothenate on the part of both pan-1 and pan-2 mutants. Neither pan mutant in combination with m grows on minimal medium. However, the pan-1 m and pan-2 m strains grow to a greater extent than pan-1 or pan-2 in limiting pantothenate concentrations. The mechanism of action of the m gene is discussed, and compared to modifiers of certain other mutant phenotypes of Neurospora.     

Partial characterization of two stable auxotrophic cell strains of Datura innoxia Mill

A growth analysis of several presumptive leaky auxotrophs from Datura innoxia suspension cultures led to the discovery of an adenine-requiring cultures led to the discovery of an adenine-requiring cell strain (Ad1). Both Ad1 and Pn1, a pantothenate-requiring strain isolated earlier from these cultures, still require either adenine or pantothenate for growth after more than one year in culture. Attempts to select prototrophic revertants have failed. Ad 1 also grew well in a medium containing either 5-aminoimidazole-4-carboxamide ribotide or inosine instead of adenine; Pn 1 with pantoic acid alone but not at all in the presence of -alanine or -ketoisovalerate alone instead of pantothenate. Pn 1 cells starved of pantothenate for up to 4d and Ad1 of adenine for 10d or more resumed growth when transferred to appropriately supplemented media. Wild-type Datura cells grown on unsupplemented medium would not crossfeed the required nutrients to the auxotrophs. The starvation and cross-feeding experiment showed that both auxotrophs could be used in reconstruction experiments to develop enrichment-selection techniques for the isolation of more auxotrophs.     

TRANSPLANTATION OF NUCLEI IN NEUROSPORA CRASSA

Wilson , James F. (Hartnell Coll., Salinas, Calif.) Transplantation of nuclei in Neurospora crassa. Amer. Jour. Bot. 50(8): 780–786. Illus. 1963.—Heterocaryons of N. crassa were produced artificially by cell-to-cell transfer of protoplasm of genetically marked strains. The injected hyphal sections were excised and cultured separately. The criteria of prototrophic growth and recovery of conidia of the donor genotype were used to prove that functional nuclei had been transplanted. Reciprocal injections were made with 2 pairs of macroconidial and 3 pairs of microconidial strains. Growth curves and conidial ratios of these artificial heterocaryons were compared to the corresponding natural heterocaryons. In each pair of heterocaryons produced by reciprocal injection, the growth curve of only one was equivalent to the naturally formed heterocaryon of that pair. The growth curve of the other artificial heterocaryon differed either in rate or in the lag period before growth occurred. There was no apparent relation between conidial ratios of the natural heterocaryons and the artificial heterocaryons with comparable growth curves. Injection of normal nuclei into a morphological temperature-sensitive mutant produced an apparent heterocaryon which grew with normal morphology at 34 C. The apparent stability of Neurospora nuclei may make in vitro studies possible.     

A CYTOPLASMIC CHARACTER IN NEUROSPORA CRASSA : The Role of Nuclei and Mitochondria

Nuclear fractions isolated from mutants of Neurospora produced no effect when microinjected into mutants with complementary biochemical requirements. DNA isolated from the nuclear fractions similarly injected also had no effect. Mitochondrial fractions isolated from an abnormal inositolless strain (abn-1) produced drastic changes in the rate of growth, morphology, reproductive characteristics, and cytochrome spectra of normal inositolless strains when single hyphal compartments were microinjected and isolated, whereas the mitochondrial fractions of the wild type produced no effect. These results provide evidence for the transmission of biochemical and biological characters when mitochondria are transferred to new nucleocytoplasmic environments.     

Pantothenate auxotrophy of Methylobacterium spp. isolated from living plants

A number of pink-pigmented facultative methylotrophs (PPFMs) belonging to Methylobacterium spp. isolated from living plant samples were found to require B vitamins for their growth in minimal medium, and most B vitamin-auxotrophic PPFMs required pantothenate (vitamin B_⁵). Further investigation of pantothenate auxotrophy using the representative strain Methylobacterium sp. OR01 demonstrated that this strain cannot synthesize β-alanine, one of the precursors of pantothenate. β-alanine and several precursors of pantothenate restored the growth of Methylobacterium sp. OR01 in minimal medium. Furthermore, this strain could colonize leaves of Arabidopsis thaliana cultivated in medium without pantothenate or its precursors. Pantothenate, β-alanine and several precursors were detected in the suspension of A. thaliana leaves. These results suggest that pantothenate-auxotrophic PPFMs can symbiotically colonize the surface of plant leaves by acquiring β-alanine and other precursors, in addition to pantothenate. Finally, the fitness advantage of B vitamin auxotrophy of PPFMs in the phyllosphere environment is discussed.     

Extracellular enzyme production by haploids,heterocaryons and diploids of Aspergillus nidulans

Summary Extracellular amylase, lipase and protease produced by haploids, diploids and heterocaryons of Aspergillus nidulans were analysed. Three morphologically normal strains and 8 morphologic mutants as well as various genetic combinations of the 11 strains were examined in solid culture medium containing specific substrates. The enzyme production of each strain was determined by measuring the halo around the colony. It was observed that the colonies showing less growth also showed more alterations in enzyme production. The compact strains (BVIII and B6) and the slow-growing heterocaryons (pp+M32 and pp+M35) showed the highest enzymatic index for the three enzymes simultaneously. If colony growth is not considered, then for amylase and protease the highest values were reached by some diploid and heterocaryons and for lipase by one morphological strain. The results showed that morphological mutants and some combinations could be used for higher production of amylase, lipase and protease.     

Incorporation of pantothenate into citrate lyase by a pantothenateless mutant of Klebsiella pneumoniae.

A pantothenate-requiring mutant of Klebsiella pneumoniae was isolated. The mutant showed an absolute dependence on pantothenate for growth. When grown in the presence of [14C]pantothenate, the mutant incorporated [14C]pantothenate into citrate lyase (3.4 mol/mol of enzyme). Analysis of a double-labeled enzyme ([14C]pantothenate and [3H]acetate) by gel electrophoresis in sodium dodecyl sulfate showed that both 3H and 14C were associated solely with the smallest subunit, the acyl carrier protein of citrate lyase.     

Identification of the native NIT2 major nitrogen regulatory protein in nuclear extracts of Neurospora crassa

The nit-2 gene of Neurospora crassa encodes the major nitrogen regulatory protein which acts in a positive fashion to activate the expression of many different structural genes during conditions of nitrogen limitation. An E. coli-expressed NIT2/-Gal fusion protein binds specifically to DNA in vitro by recognizing GATA core elements. Nuclear extracts prepared from a wild-type N. crassa strain contain a protein factor which displays all of the properties expected for the native NIT2 protein. The native NIT2 protein in nuclear extracts binds with high affinity to DNA fragments which contain two GATA elements, weakly to fragments with a single GATA element, and fails to bind to DNAs which lack these sequences. The DNA binding ability of the protein factor in nuclear extracts is efficiently blocked by a polyclonal antibody developed against the zinc-finger region of NIT2 protein. Western blot analysis with the anti-NIT2 antiserum revealed a specific protein with a size of approximately 110,000 daltons, in excellent agreement with the predicted size of NIT2. Both the specific NIT2 DNA binding activity and the protein detected by Western blot are totally lacking in nuclear extracts of a nit-2 rip mutant strain. These results all support the conclusion that the native NIT2 protein in Neurospora cells has been identified. The NIT2 protein is localised in nuclei and could not be detected in the cytoplasmic fraction of cells subjected to nitrogen derepression or nitrogen repression, indicating that the nuclear import of NIT2 is not regulated.     

GENETICS OF PHYTOPATHOGENIC FUNGI. V. HETEROCARYONS INVOLVING FORMAE OF FUSARIUM OXYSPORUM

Garber , E. D., Ellen G. Wyttenbach , and T. S. Dhillon . (U. Chicago, Chicago, Ill.) Genetics of phytopathogenic fungi. V. Heterocaryons involving formae of Fusarium oxysporum. Amer. Jour. Bot. 48(4): 325–329. 1961.—Heterocaryons involving mutant strains of 4 formae of Fusarium oxysporum were studied; the strains differed in nutritional requirements, resistance to acriflavine, and colonial morphology and color. Spores from the heterocaryons gave colonies on minimal medium which resembled one component strain in morphology and color; spores from heterocaryons involving f. pisi yielded colonies on complete medium containing a concentration of acriflavine inhibitory to the other component strain.     

Metabolic Basis for the Isoleucine, Pantothenate or Methionine Requirement of ilvG Strains of Salmonella typhimurium

Salmonella typhimurium strain DU501, which was found to be deficient in acetohydroxy acid synthase II (AHAS II) and to possess elevated levels of transaminase B and biosynthetic threonine deaminase, required isoleucine, methionine, or pantothenate for growth. This strain accumulated α-ketobutyrate and, to a lesser extent, α-aminobutyrate. We found that α-ketobutyrate was a competitive substrate for ketopantoate hydroxymethyltransferase, the first enzyme in pantothenate biosynthesis. This competition with the normal substrate, α-ketoisovalerate, limited the supply of pantothenate, which resulted in a requirement for methionine. Evidence is presented to support the conclusion that the ambivalent requirement for either pantothenate or methionine is related to a decrease in succinyl coenzyme A, which is produced from pantothenate and which is an obligatory precursor of methionine biosynthesis. The autointoxification by endogenously produced α-ketobutyrate could be mimicked in wild-type S. typhimurium by exogenously supplied α-ketobutyrate or salicylate, a known inhibitor of pantothenate biosynthesis. The accumulation of α-ketobutyrate was initiated by the inability of the residual AHAS activity provided by AHAS I to efficiently remove the α-ketobutyrate produced by biosynthetic threonine deaminase. The accumulation of α-ketobutyrate was amplified by the action of transaminase B, which decreased the isoleucine pool by catalyzing the formation of α-keto-β-methylvalerate and aminobutyrate from isoleucine and α-ketobutyrate; this resulted in release of threonine deaminase from end product inhibition and unbridled production of α-ketobutyrate. Isoleucine satisfied the auxotrophic requirement of the AHAS II-deficient strain by curtailing the activity of threonine deaminase. Additional lines of evidence based on genetic and physiological experiments are presented to support the basis for the autointoxification of strain DU501 as well as other nonpolarigenic ilvG mutant strains.     

BIOMECHANICS AND ALGINIC ACID COMPOSITION DURING HYDRODYNAMIC ADAPTATION BY EGREGIA MENZIESII (PHAEOPHYTA) JUVENILES1

To investigate the possible link between cell wall alginic acid composition and tissue mechanics, juveniles of Egregia menziesii (Turn.) Aresch. were grown under controlled conditions in an outdoor flowing seawater system under three different force regimes. After 6–10 weeks of growth, tissue strength, breaking strain, modulus, toughness, work of fracture, and the percentage of polymannuronate, polyguluronate, and alternating sequences in the cell wall alginic acid were examined. The force regime had significant effects on all mechanical indices except toughness. Juveniles grown under high energy conditions (water velocity = 1.2 m · s^?1) were about two times stronger, two times stiffer, and had a 1.5 times greater work of fracture than those from low energy conditions (<1 cm ·^?1). Treatment effects on thallus strength and modulus were predicted from alginic acid composition data to test for the importance of this cell wall material in whole plant adaptation to hydrodynamic stress. However, the prediction that differences in alginic acid composition were responsible for differences in tissue mechanical properties was inconsistent with observations. Therefore, the hypothesis that alginates play a central role in structural adaptation could not be accepted.     

Selection and characterisation of mutants lacking arginase in Neurospora crassa

Summary A Neurospora mutant (aga) lacking arginase was selected by virtue of its inability to utilize arginine as a source of ornithine, using a strain in which ornithine was needed to satisfy a proline requirement. It mapped in linkage group VII (right arm), close to wc. The most important characteristic of the mutant was its extreme sensitivity to arginine. Inclusion of 1 mM arginine in the medium lead to a 40-fold increase in the arginine pool and a 90% inhibition of growth. This inhibition was relieved by the addition of ornithine or proline. The high arginine pool was associated with only a slight repression of two biosynthetic enzymes examined and with a five-fold induction of ornthine transaminase, the second enzyme of arginine catabolism. It is expected that the aga mutant will be of value in further work on the regulation of arginine biosynthesis in Neurospora.     

ADAPTATION TO COMPETITION BY NEW MUTATION IN CLONES OF ALEXANDRIUM MINUTUM

We describe two competition experiments between clones of the dinoflagellate Alexandrium minutum. In the first experiment, two clones originating from a single haploid cell competed until one of the clones was almost driven to extinction. In the second experiment, these two clones were allowed to compete with the original populations, which were previously kept as cysts. The results indicate that an improvement of the competitive ability in both clones has occurred during the history of competition. This adaptation to competition must be attributed to selection acting on the new genetic variation that has arisen by mutation.     

Induced mutagenesis in Ustilago maydis

Summary A UV-revertible mutant of the nar1 structural gene for nitrate reductase was isolated in wildtype (nar ⁺ nir ⁺) Ustilago maydis. It proved to be vigorously revertible by gamma rays as well. Genetic analysis revealed that the strain carried a single, nonleaky, recessive allele (nar1-m) with an unusually high spontaneous reversion rate (3×10^-5/div.). Reliable reversion frequencies were determined with a special agar medium that reduced the normally high level of residual growth observed on nitrate minimal agar. Radiation-induced reversion frequencies in the homozygous diploid were approximately twice those in the hapliod. Following crosses to wild type, two revertants (one spontaneous and one UV-induced) were found to map at nar1. Although the molecular basis of nar1-m reversion is not known, available data suggest that some form of point mutation is involved.     

Nuclear and mitochondr1al DNA synthesis during yeast sporulation

Nuclear and mitochondrial DNA synthesis during sporulation of Saccharomyces cerevisiae has been studied in a wild-type (aα) strain and 3 sporulation deficient strains. We find that in a strain carrying a dominant mutation which prevents sporulation, nuclear DNA synthesis is initiated but not completed; mitochondrial DNA synthesis, on the other hand, does take place. In aa and αα diploids no initiation of nuclear DNA synthesis is seen to occur, and only a very low level of mitochondrial DNA synthesis is observed. We conclude that mitochondrial DNA synthesis in sporulation medium is uncoupled from nuclear DNA synthesis. In addition, the steps at which the sporulation process is arrested in aa and αα cells and in the dominant mutant can be ordered in time as being before and after the initiation of nuclear DNA synthesis.     

The effects of branched chain fatty acid incorporation into Neurospora crassa membranes

Phytanic acid (3,7,11,15-tetramethylhexadecanoic acid), an unusual branched chain fatty acid thought to disrupt the hydrophobic regions of membranes, can be incorporated into the lipids of growing Neurospora cultures. The phytanic acid must be supplied in a water soluble form, esterified to a Tween detergent (Tween-Phytanic). This fatty acid and its oxidation product, pristanic acid, were found in both the phospholipid and neutral lipid fractions of Neurospora. In phospholipids of the wild-type strain, phytanic acid was present to the extent of 4 to 5 moles percent of the fatty acids and pristanic acid, about 41 moles percent. The neutral lipids contained 42 and 4 moles percent of phytanic and pristanic acids respectively. By employing a fatty acid-requiring mutant strain (cel^?), the phytanic acid level was raised to a maximum of 16 moles percent in the phospholipids and to 63 moles percent in the neutral lipids. Under this condition, the level of pristanic acid was reduced to about 6 moles percent in phospholipids and 1 mole percent in the neutral lipids. The phytanic acid levels could not be further elevated by increased supplementation with phytanic acid or by a change in the growth temperature. In strains with a high phytanic acid content, the complete fatty acid distribution of the phospholipids and neutral lipids was determined. In the neutral lipids, phytanic acid appeared to replace the 18 carbon fatty acids, particularly linoleic acid. The presence of phytanic acid in the phospholipids was confirmed by mass spectrometry, and by the isolation of a phospholipid fraction containing this fatty acid via silicic acid column chromatography. Most of the phytanic acid in phospholipids appeared to be in phosphatidylethanolamine, and 2 lines of evidence suggest that it was esterified to both positions of this molecule. In the fatty acid-requiring mutant strain (cel^?), the replacement by phytanic acid of 10 to 15% of the fatty acids in the phospholipid produced an aberrant morphological change in the growth pattern of Neurospora and caused this organism to be osmotically more fragile than the wild-type strain. The lack of noticeable effect of the high levels of pristanic acid in the phospholipids suggests that it is not just the presence of the methyl groups in a branched chain fatty acid which leads to the altered membrane function in this organism.     

Phylogenetic investigations of Sordariaceae based on multiple gene sequences and morphology

The family Sordariaceae incorporates a number of fungi that are excellent model organisms for various biological, biochemical, ecological, genetic and evolutionary studies. To determine the evolutionary relationships within this group and their respective phylogenetic placements, multiple-gene sequences (partial nuclear 28S ribosomal DNA, nuclear ITS ribosomal DNA and partial nuclear β-tubulin) were analysed using maximum parsimony and Bayesian analyses. Analyses of different gene datasets were performed individually and then combined to generate phylogenies. We report that Sordariaceae, with the exclusion Apodus and Diplogelasinospora, is a monophyletic group. Apodus and Diplogelasinospora are related to Lasiosphaeriaceae. Multiple gene analyses suggest that the spore sheath is not a phylogenetically significant character to segregate Asordaria from Sordaria. Smooth-spored Sordaria species (including so-called Asordaria species) constitute a natural group. Asordaria is therefore congeneric with Sordaria. Anixiella species nested among Gelasinospora species, providing further evidence that non-ostiolate ascomata have evolved from ostiolate ascomata on several independent occasions. This study agrees with previous studies that show heterothallic Neurospora species to be monophyletic, but that homothallic ones may have a multiple origins. Although Gelasinospora and Neurospora are closely related and not resolved as monophyletic groups, there is insufficient evidence to place currently accepted Gelasinospora and Neurospora species into the same genus.     

Analysis of sorbose resistance in Neurospora crassa in heterokaryons of sorbose resistant mutants; contribution to the genetics of active transport

Summary Suitable auxotrophic markers were introduced into sorbose-resistant mutants and the sorbose-sensitive wildtype strain. Pairwise combinations of one resistant and one sensitive strain each as well as of two sensitive strains were then grown on minimal-agar to obtain forced heterocaryons. The growth behaviour of these on minimal-agar with and without added sorbose was compared.Of seven resistant mutants, representing six separate genes, among which were genes A and B, six mutants were recessive to the wildtype. The seventh, representing gene C, was recessive only with regard to colony-size, but intermediate with regard to germination counts. Heterocaryons forced between pairs of 2 closely linked mutants (intragenic case of the type A^– ₁+A^– ₂) were resistant, as were the separate mutants. However two heterocaryons forced between pairs of unlinked mutants (intergenic case of the type A^–+B^–) were sorbose sensitive. Heterocaryons forced between A or B-mutants and the C-mutant mentioned, unlinked to either A or B (intergenic cases of the type A^–+C^– and B^–+C^–) were more sensitive than the separate mutants but more resistant than the wildtype.It follows that sorbose-resistant mutants in heterocaryons of the intergenic types can complement each others defects (no growth complementation), but can not do so in heterocaryons of the intragenic type. Their complementation is considered to be the result of the activity of the intact wildtype genes homologous to the defective ones that are contained together in the multinucleate cells of the heterocaryons. This complementation may be taken as evidence for the recessiveness resp. intermediate expression of the different resistant mutants.Since none of the mutants checked so far were dominant compared to the wildtype, none of them can be a regulator-mutant. The possibility of explaining them as suppressor mutants is restricted by their recessiveness to mechanisms of suppression giving a recessive phenotype. An alternative explanation suggests that the respective wildtype genes may contain structural information for the synthesis of permeases involved in sorbose transport. The mutants would then be resistant due to defective permeases. Their recessiveness is in full accord with this suggestion.

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II. Teil einer Habilitationsschrift bei der Naturwissenschaftlichen Fakultät der Universität München.     

In vitro mitochondrial complementation in Neurospora crassa

Mitochondrial isoleucine-valine biosynthesis in strain 330a, an iv-1 mutant of Neurospora, is blocked at the dihydroxy acid dehydration step owing to a mutation in the nuclear structural gene for the specific enzyme dihydroxy acid dehydratase. Dehydratase purified from either the soluble or the mitochondrial fraction of wild-type Neurospora, and incubated in vitro with 330a mitochondria, restores valine synthesis from pyruvate-C ¹⁴ to wild type levels. Up to 29% of the restored synthesis could be attributed to the penetration of enzyme into the mitochondria. However, the bulk of the restored synthesis was found to be mediated via the secretion of dihydroxyvaline (DHV) by the mitochondria into the assay milieu, with subsequent enzymatic catalysis of this metabolite to ketovaline occurring outside the organelle. The ketovaline apparently diffuses back into mitochondria for final transamination to valine. This shunting of valine precursors in and out of mitochondria has been demonstrated to be the mechanism whereby two different populations of mitochondria isolated from mutants 330a and 305A (an iv-2 mutant lacking a functional reductoisomerase) can complement each other for the biosynthesis of valine, even when each population is enclosed in a separate dialysis bag. This observation provides the basis for a biochemical understanding of the growth complementation at the organismic level when these two iv-requiring mutants are cultured together in minimal medium.Work supported by grants GM 12323 and 2TO1 GM 00337 from the National Institutes of Health, USPHS, and a grant from the Robert A. Welch Foundation, Houston, Texas.