X-ray-induced specific-locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. V. Irreparable mutants of genotype ad-3A ad-3B, ad-3A ad-3B nic-2, and ad-3B nic-2 result from multilocus deletion and an unexpectedly high frequency of multiple-locus mutations

More extensive complementation tests than those performed initially (Webber and de Serres, 1965) on a series of 832 X-ray-induced specific-locus mutations in the adenine-3 (ad-3) region of a two-component heterokaryon (H-12) of Neurospora crassa (de Serres, 1989a) showed that unexpectedly high frequencies of specific-locus mutations in the ad-3 region have additional, but separate, sites of recessive lethal (RLCL) damage in the immediately adjacent genetic regions. The frequencies of these X-ray-induced multiple-locus mutants in the ad-3 region are orders of magnitude higher than that expected on the basis of target theory and classical models of chromosome structure during interphase (de Serres, 1989a). Genetic fine structure analyses, by means of homology tests with tester strains carrying genetic markers in the ad-3 and immediately adjacent regions, have been performed to map the presumed multiple-locus mutations. In a previous paper (de Serres, 1989c), X-ray-induced irreparable ad-3 mutants of the following genotypes and numbers (ad-3A or ad-3B were analyzed, and the high frequency of multiple-locus mutations was confirmed. In the present paper, X-ray-induced irreparable ad-3 mutants of the following genotypes and numbers (ad-3A ad-3B, ad-3A ad-3B nic-2, and ad-3B nic-2 have also been subjected to the same genetic fine structure analysis. These experiments, in the previous (de Serres, 1989c) and present papers, were designed to determine the extent of the functional inactivation in the ad-3 and immediately adjacent genetic regions in individual mutants classified as presumptive multilocus deletions or multiple-locus mutations.     

Effect of the homokaryotic or heterokaryotic state of the uvs-2 allele in Neurospora crassa on mitomycin C-induced killing and ad-3 mutation

Mitomycin C (MC) was tested for its killing and mutagenic activities in the ad-3 forward-mutation test in Neurospora crassa. The test was conducted in 4 dikaryons of N. crassa in order to determine the effect of the uvs-2 allele, which causes a defect in nucleotide excision repair, on MC-induced killing and ad-3 mutation. These dikaryons were homokaryotic for uvs-2⁺ (H-12), homokaryotic for uvs-2 (H-59), and heterokaryotic for uvs-2/uvs-2⁺ (H-70 and H-71). MC induced killing and ad-3 mutation in H-12, but the presence of uvs-2 in the homokaryotic state (H-59) resulted in a great increase in the killing and mutagenic activities of MC. This increased sensitivity to MC-induced killing and mutation conferred by uvs-2 in the homokaryotic state (H-59 vs. H-12) is a different effect than that noted by others for a defect in nucleotide excision-repair in Escherichia coli and Salmonella typhimurium or in human cells. The dikaryons heterokaryotic for uvs-2/uvs-2⁺ had the same sensitivity to MC as H-12, indicating that for MC-induced killing and ad-3 mutation uvs-2 is recessive to uvs-2⁺.     

X-ray-induced specific locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. I. Modification of the heterozygous effects of multilocus deletions covering the ad-3A or ad-3B loci

The basis for the reduced growth rates of heterokaryons between strains carrying nonallelic combinations of gene/point mutations (ad-3R) and multilocus deletion mutations (ad-3IR) has been investigated by a simple genetic test. The growth rates of forced 2-component heterokaryons (dikaryons) between multilocus deletion mutations were compared with forced 3-component heterokaryons (trikaryons) containing an ad-3AR ad-3BR double mutant as their third component. Since the third component has no genetic damage at other loci immediately adjacent to the ad-3A or ad-3B locus, the growth rate on minimal medium depends on the functional activity of the unaltered (and presumed "wild-type") ad-3A and ad-3B loci in the first two components. In many cases, the requirements of the original dikaryons have been satisfied by the addition of unaltered genes (in the third component), and these trikaryons grow at wild-type rate on minimal medium. Those trikaryons growing at less than wild-type rate were shown to be adenine-requiring, and wild-type growth rate was obtained with the addition of low levels of adenine to the medium. Such tests in the present experiments have shown that ad-3IR mutations result not only in inactivation of the ad-3 loci by multilocus deletion but also, in many cases, in partial gene inactivation by an unknown mechanisms at other loci in the immediately adjacent regions. The heterozygous effects observed in our present experiments with multilocus deletions in Neurospora can be explained either by a spreading-type position effect of the type found by others in Drosophila, mice, Oenothera and Aspergillus or by undetected genetic damage ("cryptic mutations") in the immediately adjacent genetic regions. An attempt will be made to distinguish between these two alternative hypotheses with techniques for DNA cloning and sequencing in future experiments.     

Comparison of cyclopropene, 1-methylcyclopropene, and 3,3-dimethylcyclopropene as ethylene antagonists in plants

A comparison has been made of cyclopropene (CP), 1-methylcyclopropene (1-MCP), and 3,3-dimethyl-cyclopropene (3,3-DMCP) in their ability to protect plants against ethylene. In bananas, both CP and 1-MCP are effective around 0.5 nL L^–1, and 3,3-DMCP was effective at 1 L L^–1. Bananas treated with CP and 1-MCP again become sensitive to ethylene at 12 days and those treated with 3,3-DMCP at 7 days. Mature green tomatoes are protected by 5–7 nL L^–1 of 1-MPC for 8 days at 25°C and tomatoes treated with 3,3-DMCP at 5–10 L L^–1 are protected for 5 days. Carnation flowers are protected with CP or 1-MCP after exposure to 0.5 nL L^–1 for 24 hours and by 1 L L^–1 of 3,3-DMCP. The display life of Campanula flowers is increased from 3.3 to 5.4 days by 10 L L^–1 of 3,3-DMCP and to 9 days by 20 nL L^–1 of 1-MCP. Ethylene inhibition of pea seedlings is reduced by treatment with 1-MCP at 10 L L^–1 of ethylene but as ethylene is increased to 3000 L L^–1 growth inhibition increases. 3,3-DMCP treatment causes very little reduction of the ethylene effect even at very low concentrations.     

Isolation and substrate specificities of five chitinases from the hepatopancreas of Northern shrimp, Pandalus borealis

Five enzymes designated chitinase I, IIa, IIb, III, and IV have been isolated from the hepatopancreas of Pandalus borealis in a procedure including column chromatography on Q-Sepharose, Sephacryl S-200, phenyl-Superose and Superdex 75. The isolated enzymes were analysed by SDS PAGE. Chitinase I, III, and IV gave only one major band corresponding to 54–55 kDA. Chitinase IIa showed one major band at 61 kDA and two diminutive bands at 17 and 55 kDa, while chitinase IIb gave two major bands at 17 and 44 kDa. Estimated by gel filtration, the native molecular weights of chitinase I, IIa, IIb, III, and IV were 61, 69, 39, 57, and 54 kDa, respectively. The substrate and reaction specificities of the isolated chitinases were investigated, and the results show that the isolated enzymes are true chitinases. They do not hydrolyse N,N′-diacetylchitobiose or p-Nitrophenyl-N-acetyl-β-D-glucosaminide, but express activities when longer chitooligosaccharides or nitrophenylated chitooligosaccharides are used as substrates. Chitinase I and IIa gave an initial random cleavage pattern and might be classified as endochitinases, while chitinase III and IV released dimeric units from the substrates and might be termed chitobiosidases.     

Affinity of mouse immunoglobulin G subclasses for sialic acid derivatives immobilized on dextran-coated supports

High-performance liquid affinity chromatography is a powerful method for the purification of biological compounds owing to its specificity, rapidity and high resolution. In our laboratory, we develop chromatographic supports based on porous silica beads. However, in order to minimize non-specific interactions between the inorganic surface and proteins in aqueous solution, the silica beads are coated with modified dextran. As previously reported, many affinity ligands can be covalently grafted onto dextran-coated silica. In this study, N-acetylneuramic acid, which belongs to the sialic acid family and is present in immunoglobulin G (IgG) epitopes, is used as an active ligand. The interactions of this affinity support and IgG subclasses are analyzed. This immobilized ligand enables purification of IgG3 antibodies.     

X-ray-induced specific-locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. IV. Irreparable mutants of genotype ad-3A and ad-3B result from multilocus deletion and an unexpectedly high frequency of multiple-locus mutations

The induction of specific-locus mutations in the ad-3 region of Neurospora crassa after X-irradiation was studied in a two-component heterokaryon to determine: (1) the ratio of reparable ad-3 mutants (presumed gene/point mutations, designated ad-3R) to irreparable ad-3 mutants (presumed multilocus deletions, designated ad-3IR), and (2) the induction kinetics of each class (Webber and de Serres, 1965). More extensive genetic tests made subsequently (de Serres, 1989a) on the 832 X-ray-induced specific-locus mutations recovered in those experiments showed that unexpected high frequencies of reparable and irreparable ad-3 mutants are actually multiple-locus mutants that have additional, but separate, sites of recessive lethal (RLCL) damage in the immediately adjacent genetic regions (designated ad-3R + RLCL or ad-3IR + RLCL). The frequencies of these X-ray-induced multiple-locus mutants in the ad-3 region are orders of magnitude higher than expected on the basis of target theory (where the frequency of the double mutant is expected to be the product of the frequencies of each single mutant) and classical models of chromosome structure during interphase (de Serres, 1989a). In the present paper, a random sample of 832 X-ray-induced ad-3 mutants of genotype ad-3A or ad-3B that are irreparable have been subjected to more extensive genetic fine-structure analysis. These experiments were designed to determine the extent of the functional inactivation in individual mutants in the ad-3 and immediately adjacent genetic regions in mutants classified as presumptive multilocus deletions or multiple-locus mutations. These experiments have shown that in Neurospora crassa most X-ray-induced irreparable mutants of genotype ad-3A or ad-3B map as a series of overlapping multilocus deletions. Among the 29 irreparable mutants of genotype ad-3A, there are 16 different subgroups of complementation patterns; and among the 63 irreparable mutants of genotype ad-3B, there are also 16 different subgroups. In addition, mutants classified as presumptive multiple-locus mutants result from a variety of separate, but closely linked, sites of genetic damage.(ABSTRACT TRUNCATED AT 400 WORDS)     

X-ray-induced specific-locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. II. More extensive genetic tests reveal an unexpectedly high frequency of multiple-locus mutations

More extensive genetic tests have been performed on a series of 832 X-ray-induced specific-locus mutations in the ad-3 region of a 2-component heterokaryon (H-12) of Neurospora crassa, reported earlier (Webber and de Serres 1965). Using a new tester strains and techniques for performing large-scale genetic tests (heterokaryon, dikaryon and trikaryon) to characterize ad-3 mutants induced in 2-component heterokaryons, new data have been obtained on this sample of X-ray-induced ad-3 mutants. These new data show that unexpectedly high frequencies of both single-locus (gene/point) mutations and multilocus deletions in the ad-3 region have additional, but separate, sites of resessive lethal (RL^CL) damage in the immediately adjacent genetic regions. The frequencies of these X-ray-induced multiple-locus mutants in the ad-3 region are orders of magnitude higher than expected on the basis of target theory and classical models of chromosome structure during interphase. Current models of interphase chromosome structure in higher eukaryotes as revealed by chromosome “painting” offer a possible explanation of the Neurospora data.