Deletion of the col-26 Transcription Factor Gene and a Point Mutation in the exo-1 F-Box Protein Gene Confer Sorbose Resistance in Neurospora crassa.

L-Sorbose induces hyperbranching of hyphae, which results in colonial growth in Neurospora crassa. The sor-4 gene, which encodes a glucose sensor that acts in carbon catabolite repression (CCR), has been identified as a sorbose resistance gene. In this study, we found that the deletion mutant of col-26, which encodes an AmyR-like transcription factor that acts in CCR, displayed sorbose resistance. In contrast, the deletion mutants of other CCR genes, such as a hexokinase (hxk-2), an AMP-activated S/T protein kinase (prk-10), and a transcription factor (cre-1), showed no sorbose resistance. Double mutant analysis revealed that the deletion of hxk-2, prk-10, and cre-1 did not affect the sorbose resistance of the col-26 mutant. Genes for a glucoamylase (gla-1), an invertase (inv), and glucose transporters (glt-1 and hgt-1) were highly expressed in the cre-1 mutant, even in glucose-rich conditions, but this upregulation was suppressed in the Δcre-1;Δcol-26a double-deletion mutant. Furthermore, we found that a dgr-2(L1)a mutant with a single amino-acid substitution, S11L, in the F-box protein EXO-1 displayed sorbose resistance, unlike the deletion mutants of exo-1, suggesting that the function of EXO-1 is crucial for the resistance. Our data strongly suggest that CCR directly participates in sorbose resistance, and that COL-26 and EXO-1 play important roles in regulating the amylase and glucose transporter genes during CCR.

Substrate specificities of Fusarium biosynthetic enzymes explain the genetic basis of a mixed chemotype producing both deoxynivalenol and nivalenol-type trichothecenes.

Fusarium species are traditionally grouped into type A and type B trichothecene producers based on structural differences in the mycotoxin they synthesize. The type B trichothecene-producing Fusarium graminearum strains are further divided into 3-acetyldeoxynivalenol (3-ADON), 15-acetyldeoxynivalenol (15-ADON), and nivalenol (NIV) chemotypes. The former two chemotypes, collectively termed a deoxynivalenol (DON) chemotype, evolved from a NIV chemotype by inactivation of FgTri13, which encodes trichothecene C-4 hydroxylase, during the evolutionary process. Despite stable overexpression of FgTri13, however, both 3-acetylnivalenol (3-ANIV) and 3-ADON accumulate equally in shake flask culture of a transgenic 3-ADON chemotype. In this study, we investigated why the "3-ANIV chemotype" could not be obtained using this strategy. When analysis was extended to the transgenic NIV chemotype, in which FgTri7 C-4 acetylase gene was disrupted and FgTri8 deacetylase gene was replaced with the 3-ADON chemotype's orthologue, C-4 unoxygenated 3-ADON, as well as C-4 oxygenated 3-ANIV, accumulated as the end product. A feeding experiment with an ΔFgtri5ΔFgtri3 double gene disruptant, a trichothecene non-producing mutant unable to acetylate C-15 of the trichothecene ring, revealed the importance of the 15-O-acetyl group for efficient C-4 hydroxylation of DON-type trichothecenes. This implies that traditional DON and NIV chemotype diversification is not solely explained by FgTri13, but is also explained by the function of the FgTri8 trichothecene deacetylase gene. None of the crude cell extracts from existing chemotypes showed highly specific C-15 deacetylation activity against 3,15-diacetylnivalenol (3,15-diANIV) without deacetylating C-15 of the C-4 unoxygenated earlier intermediate, 3,15-diacetyldeoxynivalenol. Thus, an unnatural Fusarium trichothecene, 3-ANIV, could only be synthesized as part of a mixture with 3-ADON, unless the esterase encoded by FgTri8 evolves to act on the 15-O-acetyl of 3,15-diANIV with high specificity. We also explain why the transgenic "15-ANIV chemotype", which can be generated through functional inactivation of FgTri7, uses an engineered pathway via 3,15-diANIV, but not 15-ADON, to generate 15-ANIV. Tri genes appear to evolve continuously, and altered functions of trichothecene pathway enzymes result in the generation of new trichothecenes, such as NX-2 and NX-3, which have been recently discovered in field isolates of F. graminearum. As recombination of FgTri8 between existing F. graminearum isolates could give rise to a strain that produces mixtures of DON and NIV-type trichothecenes, it may also be noteworthy to monitor the emergence of a field isolate that invalidates traditional chemotype classification.

A novel fungicide aminopyrifen inhibits GWT-1 protein in glycosylphosphatidylinositol-anchor biosynthesis in Neurospora crassa.

Aminopyrifen, 4-phenoxybenzyl 2-amino-6-methylnicotinate, strongly inhibited the mycelial growth of a wild-type Neurospora crassa strain on Vogel's minimal medium containing 1.2% sucrose, with a 0.001 mg/L concentration required for 50% growth inhibition. Similar to micafungin, an inhibitor of beta-1, 3-glucan synthetase, aminopyrifen further inhibited the growth of N. crassa deletion mutants of MAP kinase cascade genes, such as mak-1 and mak-2, than the wild-type strain, suggesting that aminopyrifen perturbs cell wall-related processes. Furthermore, we found that three chitin synthase gene mutants (chs-1, chs-5, and chs-7) were highly sensitive to both chemicals; however, aminopyrifen, but not micafungin, induced a swollen germ tube from the conidia of chs-5 and chs-7 mutants on Vogel's medium containing 1.2% sucrose. To elucidate the target protein of aminopyrifen, we isolated mutants resistant to aminopyrifen after UV treatment of conidia of the wild-type strain or the chs-5 strain. The resistance mutations were localized to the gwt-1 gene that encodes an acyltransferase, GWT-1, which participates in the biosynthesis of the glycosylphosphatidylinositol (GPI) precursor, and were found to result in S180F and V178A alterations in the protein. These results strongly suggest that aminopyrifen works as an inhibitor targeting GWT-1, a protein involved in GPI-anchor biosynthesis.

The effects of water absorption and roasting conditions on fracture properties and internal structure of sesame seeds.

We investigated the effects of soaking, residence time before roasting and roasting conditions on the fracture properties and structure of the cross-section of sesame seeds. Soaking time affected only the size of the side voids of the seed cross-section. The fracture force and strain of the roasted seeds decreased as residence time increased. The center void of the roasted seeds, important for seed crispness increased as residence time increased. In contrast, the side void of the roasted seeds only increased with residence time during the first 10 min. Seeds roasted at higher temperatures had smaller fracture forces and larger central voids than those roasted at lower temperatures. During roasting at 300 °C, the fracture force and strain decreased as the center void ratio increased. Overall, both a sufficient time for moisture diffusion in the seeds and a high roasting temperature were necessary to produce crisp roasted seeds.

White sesame seed water-soluble fraction enhances human neuroblast cell viability via an anti-apoptotic mechanism.

Defatted sesame seed flour is recovered as a byproduct after oil extraction and is usually considered a waste product. Previously, we showed that water-soluble fractions purified from defatted white and gold sesame seed flour exhibited good antioxidant activity in vitro. We also identified ferulic acid and vanillic acid as the bioactive antioxidants in both white and gold sesame seed water-soluble fractions (WS-wsf and GS-wsf, respectively). In this study, we hypothesized that WS-wsf and GS-wsf may have neuroprotective effects due to their antioxidant potential. Treatment with WS-wsf for 24 hours enhanced human neuroblastoma SH-SY5Y cell viability and proliferation, while GS-wsf, ferulic acid, and vanillic acid did not show similar effects. In addition, WS-wsf (1-3 mg/mL) significantly and dose-dependently protected SH-SY5Y cells against camptothecin-induced apoptosis, suggesting the involvement of an anti-apoptosis mechanism in the neuroprotective effects of WS-wsf. In fact, treatment with WS-wsf significantly decreased the mRNA expression levels of pro-apoptotic Bax and p53 genes. WS-wsf also enhanced Bcl-2 protein level and Akt phosphorylation. Taken together, this study showed that WS-wsf has interesting neuroprotective potential via an anti-apoptotic mechanism, which is independent from its antioxidant capacity.

Water-soluble fractions from defatted sesame seeds protect human neuroblast cells against peroxyl radicals and hydrogen peroxide-induced oxidative stress.

Oxidative stress is involved in the development of aging-related diseases, such as neurodegenerative diseases. Dietary antioxidants that can protect neuronal cells from oxidative damage play an important role in preventing such diseases. Previously, we reported that water-soluble fractions purified from defatted sesame seed flour exhibit good antioxidant activity in vitro. In the present study, we investigated the protective effects of white and gold sesame seed water-soluble fractions (WS-wsf and GS-wsf, respectively) against 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH) and hydrogen peroxide (H2O2) induced oxidative stress in human neuroblast SH-SY5Y cells. Pretreatment with WS-wsf and GS-wsf did not protect cells against AAPH-induced cytotoxicity, while simultaneous co-treatment with AAPH significantly improved cell viability and inhibited membrane lipid peroxidation. These results suggest that WS-wsf and GS-wsf protect cells from AAPH-induced extracellular oxidative damage via direct scavenging of peroxyl radicals. When oxidative stress was induced by H2O2, pretreatment WS-wsf and GS-wsf significantly enhanced cell viability. These results suggest that in addition to radical scavenging, WS-wsf and GS-wsf enhance cellular resistance to intracellular oxidative stress by activation of the Nrf-2/ARE pathway as confirmed by the increased Nrf2 protein level in the nucleus and increased heme oxygenase 1 (HO-1) mRNA expression. The roles of ferulic and vanillic acids as bioactive antioxidants in these fractions were also confirmed. In conclusion, our results indicated that WS-wsf and GS-wsf, which showed antioxidant activity in vitro, are also efficient antioxidants in a cell system protecting SH-SY5Y cells against both extracellular and intracellular oxidative stress.

Involvement of MAK-1 and MAK-2 MAP kinases in cell wall integrity in Neurospora crassa.

Among three MAPK disruptants of Neurospora crassa, Δmak-1 was sensitive and Δmak-2 was hypersensitive to micafungin, a beta-1,3-glucan synthase inhibitor, than the wild-type or Δos-2 strains. We identified six micafungin-inducible genes that are involved in cell wall integrity (CWI) and found that MAK-1 regulated the transcription of non-anchored cell wall protein gene, ncw-1, and the beta-1,3-endoglucanase gene, bgt-2, whereas MAK-2 controlled the expression of the glycosylhydrolase-like protein gene, gh76-5, and the C4-dicarboxylate transporter gene, tdt-1. Western blotting analysis revealed that, in the wild-type strain, MAK-1 was constitutively phosphorylated from conidial germination to hyphal development. In contrast, the phosphorylation of MAK-2 was growth phase-dependent, and micafungin induced the phosphorylation of unphosphorylated MAK-2. It should be noted that the phosphorylation of MAK-1 was virtually abolished in the Δmak-2 strain, but was significantly induced by micafungin, suggesting functional cross talk between MAK-1 and MAK-2 signalling pathway in CWI.

Hydroxylations of trichothecene rings in the biosynthesis of Fusarium trichothecenes: evolution of alternative pathways in the nivalenol chemotype.

Fusarium sporotrichioides genes FsTri11, FsTri13, and FsTri1 encode cytochrome P450 monooxygenases (CYPs) responsible for hydroxylations at C-15, C-4, and C-8 of the trichothecene skeleton, respectively. However, the corresponding genes of nivalenol (NIV)-chemotype Fusarium graminearum remain to be functionally elucidated. In this study, we characterized the roles of these CYPs in NIV biosynthesis. Analyses of the metabolites of the F. graminearum Fgtri11- mutant, a disruptant of FgTri11 encoding isotrichodermin (ITD) C-15 hydroxylase, revealed a small amount of NIV-type trichothecenes suggesting that an alternative C-15 hydroxylase partially complemented FgTRI11p. In contrast, the C-7/C-8 hydroxylations depended solely on FgTRI1p, as suggested by the metabolite profiles of the Fgtri11- Fgtri1- double gene disruptant. Disruption of FgTri1 in both the wild-type and Fgtri13- mutant backgrounds revealed that FgTRI13p exhibits marginal activity toward calonectrin (CAL) and that it was the only C-4 hydroxylase. In addition, feeding experiments demonstrated that the C-4 hydroxylation of a 7-hydroxytrichothecene lacking C-8 ketone was extremely limited. The marginal activity of FgTRI13p toward CAL was advantageous for the C-7/C-8 hydroxylation steps in NIV biosynthesis, as transformation of a C-4 oxygenated trichothecene lacking C-7/C-8 modifications into NIV-type trichothecenes was quite inefficient. The significance of hydroxylation steps in the evolution of Fusarium trichothecenes is discussed.

Genetic and phenotypic characterization of the heat shock response in Pseudomonas putida.

Molecular chaperones function in various important physiological processes. Null mutants of genes for the molecular chaperone ClpB (Hsp104), and those that encode J-domain proteins (DnaJ, CbpA, and DjlA), which may act as Hsp40 co-chaperones of DnaK (Hsp70), were constructed from Pseudomonas putida KT2442 (KT) to elucidate their roles. The KTΔclpB mutant showed the same heat shock response (HSR) as the wild-type, both in terms of heat-shock protein (Hsp) synthesis (other than ClpB) and in hsp gene expression; however, the mutant was quite sensitive to high temperatures and was unable to disaggregate into thermo-mediated protein aggregates, indicating that ClpB is important for cell survival after heat stress and essential for solubilization of protein aggregates. On the other hand, the KTΔdnaJ mutant was temperature-sensitive, and formed more protein aggregates (especially of high molecular weight) upon heat stress than did KT. P. putida CbpA, a probable Hsp, partially substituted the functions of DnaJ in cell growth and solubilization of thermo-mediated protein aggregates, and might be involved in the HSR which was regulated by a fine-tuning system(s) that could sense subtle changes in the ambient temperature and control the levels of σ(32) activity and quantity, as well as the mRNA levels of hsp genes.

The relationship between the fracture properties and the tissue structure of roasted sesame seeds.

Using seven varieties of roasted sesame seeds, we examined the relationship between the fracture properties and the internal structure of roasted seeds. Analysis of fracture properties revealed significant differences across the samples in terms of fracture force and fracture strain at the biggest fracture point, and in the number of small fractures (p<0.05). Analysis of the cross-sectional structure revealed significant differences across the samples in the size of the void at the center of the sesame seed and in the overall thickness of the seed (p<0.05). Strong negative correlations were found for the center-void-to-seed thickness ratio against fracture force and fracture strain at the biggest fracture point. Moreover, fracture properties and cross-sectional structure were strongly correlated with sensory evaluations of crispness. Hence we concluded that the presence of a void in the central area of a seed decreases the necessary fracture force, resulting in a crispy texture.

Deletion and expression analysis of beta-(1,3)-glucanosyltransferase genes in Neurospora crassa.

GPI(glycosylphosphatidylinositol)-anchored beta-(1,3)-glucanosyltransferases play an active role in cell wall biosynthesis in fungi. Neurospora crassa has 5 putative beta-(1,3)-glucanosyltransferase genes, namely, gel-1, gel-2, gel-3, gel-4, and gel-5, in its genome. Among them, the gel-3 gene is constitutively expressed at the highest level in growing hyphae, whereas gel-1 is expressed at the lowest level. The gel-3 deletion mutant displayed slow growth, while other gel gene disruptants exhibited normal growth. Although no gel gene disruption affected pH sensitivity and fertility, all Δgel mutants were resistant to cell wall degradation enzymes. Micafungin, a beta-(1,3)-glucan synthase inhibitor, induced gel-4 expression in the wild-type and 2 MAP kinase mutants mak-1 and mak-2 strains. In contrast, fludioxonil, an activator of OS-2 MAP kinase, strongly induced the gel-1 gene in the wild-type strain. Its induction was nearly abolished in the os-2 and in the atf-1/asl-1 mutant. These suggested that GEL-3 is a major factor in mycelial growth, while GEL-1 and GEL-4 may play important roles in cell wall remodeling in response to stress conditions or cell wall damage, respectively.

Pollen factors controlling self-incompatibility strength in Japanese pear.

Japanese pear has a genetically controlled self-incompatibility system, but both the pollen-tube growth in a semi in vivo assay and fruit set after self-pollination differ considerably among cultivars. The percentage of styles in which pollen tubes have reached the base ranges from 0 to 36 %, a value determined by culture of styles in vitro, and fruit set ranges from 0.6 to 15.2 %. Based on these data, we have assigned a value for the self-incompatibility weakness to each cultivar. Here, we showed that pollen factors control the degree of self-incompatibility. When the pollen-tube growth of 13 cultivars was compared in a completely compatible 'Hougetsu' (S (1) S (7)) style, it differed a fair amount among cultivars and showed a significantly positive relation to self-incompatibility weakness (r = 0.707). The degree of self-incompatibility of pear is, therefore, determined by pollen factor(s) unrelated to the S-locus. Although the fruit set and fruit growth of 'Hougetsu' were not affected by the pollen donor, a positive relationship was also observed between seed number and self-incompatibility weakness (r = 0.972). However, in a style with no S-RNase production (genotype: S (4) (sm) S (4) (sm) ), the relationship disappeared (r = 0.341) and pollen-tube growth was promoted by 12-36 % except in one cultivar. These results suggest that S-RNase functions as a cytotoxin on compatible pollen in a cultivar-dependent manner, and that the degree of inhibition is determined by pollen factor(s) unrelated to the S-locus. The pollen factor also functions on S-RNase in incompatible styles, resulting in a different degree of self-incompatibility.

A mutation in dnaK causes stabilization of the heat shock sigma factor σ32, accumulation of heat shock proteins and increase in toluene-resistance in Pseudomonas putida.

Heat shock gene expression is regulated by the cellular level and activity of the stress sigma factor σ(32) in Gram-negative bacteria. A toluene-resistant, temperature-sensitive derivative strain of Pseudomonas putida KT2442, designated KT2442-R2 (R2), accumulated several heat shock proteins (HSPs) under non-stress conditions. Genome sequencing of strain R2 revealed that its genome contains a number of point mutations, including a CGT to CCT change in dnaK resulting in an Arg445 to Pro substitution in DnaK. DNA microarray and real-time reverse transcription polymerase chain reaction analyses revealed that the mRNA levels of representative hsp genes (e.g. dnaK, htpG and groEL) were upregulated in R2 cells in the stationary phase. Wild-type and R2 cells showed similar heat shock responses at hsp mRNA and HSP levels; however, the σ(32) level in the mutant was not downregulated in the shut-off stage. Strain R2 harbouring plasmid-borne dnaK grew at 37°C, did not accumulate HSPs, and was more sensitive to toluene than strain R2. It is worth to note that that revertant of R2 able to grow at 37°C were isolated and exhibited a replacement of Pro445 by Ser or Leu in DnaK. Thus, the mutation in dnaK causes the temperature-sensitive phenotype, improper stabilization of σ(32) leading to HSP accumulation and increased toluene resistance in strain R2.

An AP-1-like transcription factor, NAP-1, regulates expression of the glutathione S-transferase and NADH:flavin oxidoreductase genes in Neurospora crassa.

AP-1-like transcription factors play crucial roles in oxidative stress responses in yeast and filamentous fungi. The deletion of an AP-1-like transcription factor gene, nap-1, in Neurospora crassa slightly increased its sensitivity to oxidative stressors, including menadione. Microarray and quantitative real-time reverse transcriptase-PCR analyses were employed to identify menadione-inducible genes (migs) and the roles of NAP-1 in their regulation. N. crassa migs include three putative glutathione S-transferase genes and two NADH:flavin oxidoreductase genes, orthologs of OYE2 and OYE3, both of which play roles in menadione tolerance in Saccharomyces cerevisiae. Menadione induced nuclear localization of NAP-1, and oxidative upregulation of many of migs were NAP-1 dependent. Genes for a thioredoxin, a glutathione reductase, and a glutathione peroxidase were slightly upregulated by the chemical only in the wild-type strain, suggesting that NAP-1 is involved in their oxidative induction and probably dose not contribute to high-level constitutive expressions of such genes.

OxyR is involved in the expression of thioredoxin reductase TrxB in Pseudomonas putida.

OxyR regulates the expression of a peroxiredoxin (AhpC) and two catalases (KatA and KatB), which play roles in peroxide protection, at the transcription level in Pseudomonas putida KT2442. Proteome analysis indicated significantly increased amounts of the enzymes AhpC, KatA, KatB, and a peroxiredoxin reductase (AhpF) in the oxyR1 mutant cells; these increases reflected the upregulation of the expression of the genes encoding these enzymes. Additionally, although the effect of oxyR1 mutation on the trxB transcript level was not clearly evident, it increased the amount of thioredoxin reductase (TrxB) by fivefold. Primer extension analysis revealed that trxB was constitutively transcribed from the P1 site; however, hydrogen peroxide treatment lowered the transcription of trxB from P1 but induced its transcription from P2. Adjacent to the -35 base of the P2 initiation site, sequences similar to those involved in the proposed OxyR binding in Escherichia coli were found in a region to which OxyR was shown to bind. These observations suggest that in P. putida, OxyR regulates TrxB expression by promoting trxB transcription from the P2 site when oxidative stresses lowered the transcription from the constitutive P1 site.

Genotyping of benzimidazole-resistant and dicarboximide-resistant mutations in Botrytis cinerea using real-time polymerase chain reaction assays.

Botrytis cinerea, an economically important gray mold pathogen, frequently exhibits multiple fungicide resistance. A fluorescence resonance energy transfer-based real-time polymerase chain reaction assay has been developed to detect benzimidazole- and dicarboximide-resistant mutations. Three benzimidazole-resistant mutations-(198)Glu to Ala (E198A), F200Y, and E198K-in beta-tubulin BenA were detected using a single set of fluorescence-labeled sensor and anchor probes by melting curve analysis. Similarly, three dicarboximide-resistant mutations-I365S, V368F plus Q369H, and Q369P-in the histidine kinase BcOS1 were successfully distinguished. Unassigned melting profiles in BenA genotyping assay resulted in the identification of a new benzimidazole-resistant BenA E198V mutation. This mutation conferred resistance to carbendazim as do E198A and E198K mutations. The isolates with BenA E198V mutation showed a negative cross-resistance to diethofencarb, but to a lesser extent than the E198A mutants. A survey of 210 B. cinerea field isolates revealed that most of benzimidazole-resistant isolates possessed the E198V or E198A mutation in the BenA gene, and the I365S mutation in the BcOS1 gene was also frequently observed in Japanese isolates. However, benzimidazole-resistant isolates with BenA F200Y or E198K mutations, which confer the diethofencarb-insensitive phenotype, were rare. Our BenA and BcOS1 genotyping is a rapid and reliable method that is suitable for monitoring the fungicide-resistant field population.

ATF-1 transcription factor regulates the expression of ccg-1 and cat-1 genes in response to fludioxonil under OS-2 MAP kinase in Neurospora crassa.

The ATF/CREB family transcriptional factors are regulated by stress-activated MAP kinase in yeast. The disruptants of the atf-1 gene, which encodes an ATF/CREB family transcriptional factor, were isolated and characterized in Neurospora crassa. The characteristic phenotypes in the os-2 MAP kinase strain, such as osmotic sensitivity and fludioxonil resistance, were not observed in the Deltaatf-1 strain; however, like the os-2 strain, up-regulation of the catalase gene cat-1 and the clock-controlled gene ccg-1 by treatment with fludioxonil (1 microg/mL) or 4% NaCl was almost completely abolished in the Deltaatf-1 strain. A gel shift assay indicated that ATF-1 bound to the cat-1 and ccg-1 promoters probably through the CRE motifs. The enzyme activity of large-subunit catalase CAT-1, the major conidial catalase, was not detected in the Deltaatf-1 strain, suggesting that the production of CAT-1 during formation of conidia is largely dependent on ATF-1. Among 11 clock-controlled genes, the expression of ccg-1, ccg-9, ccg-13, and ccg-14 was induced by fludioxonil in an OS-2-dependent manner; however, induction of ccg-13 and ccg-14 was observed in the Deltaatf-1 strain, suggesting the existence of another transcription factor regulated by OS-2. The homozygous cross between the Deltaatf-1 strains produced perithecia and ascospores; however, their ascospores never germinated. These findings suggest that ATF-1 acts as one of the transcriptional factors downstream of the OS-2 MAP kinase and probably regulates some genes involved in conidiation, circadian rhythm, and ascospore maturation in N. crassa.

4-O-acetylation and 3-O-acetylation of trichothecenes by trichothecene 15-O-acetyltransferase encoded by Fusarium Tri3.

In the biosynthesis of Fusarium trichothecenes, the C-3 hydroxyl group of isotrichodermol must be acetylated by TRI101 for subsequent pathway genes to function. Despite the importance of this 3-O-acetylation step in biosynthesis, Tri101 is both physically and evolutionarily unrelated to other Tri genes in the trichothecene gene cluster. To gain insight into the evolutionary history of the cluster, we purified recombinant TRI3 (rTRI3), one of the two cluster gene-encoded trichothecene O-acetyltransferases, and examined to determine whether this 15-O-acetyltransferase can add an acetyl to the C-3 hydroxyl group of isotrichodermol. When a high concentration of rTRI3 was used in the assay (final concentration, 50 microM), we observed 3-O-acetylation activity against isotrichodermol that was more than 10(5) times less efficient than the known 15-O-acetylation activity against 15-deacetylcalonectrin. The rTRI3 protein also exhibited 4-O-acetylation activity when nivalenol was used as a substrate; in addition to 15-acetylnivalenol, di-acetylated derivatives, 4,15-diacetylnivalenol, and, to a lesser extent, 3,15-diacetylnivalenol, were also detected at high enzyme concentrations. The significance of the trace trichothecene 3-O-acetyltransferase activity detected in rTRI3 is discussed in relation to the evolution of the trichothecene gene cluster.

Genetic analysis of the Neurospora crassa RAD14 homolog mus-43 and the RAD10 homolog mus-44 reveals that they belong to the mus-38 pathway of two nucleotide excision repair systems.

Saccharomyces cerevisiae Rad14 and Rad10 proteins are essential for nucleotide excision repair (NER). Rad14 is a UV-damaged DNA binding protein and Rad10 is a structure-specific endonuclease that functions in a complex with Rad1. In this study, we identified and characterized the RAD14 and RAD10 homolog genes in Neurospora crassa, which we named mus-43 and mus-44, respectively. Disruption of mus-43 and mus-44 conferred sensitivity to UV and 4-nitroquinoline 1-oxide, but not to methyl methanesulfonate, N-methyl-N'-nitro-N-nitrosoguanidine, camptothecin, hydroxyurea, or bleomycin. The mus-44 mutant was more sensitive to UV than the mus-43 mutant. Genetic analysis indicated that mus-43 and mus-44 are epistatic to mus-38 which is a homolog of the S. cerevisiae RAD1, but not to mus-18 which belongs to a second excision repair pathway. Immunological assays demonstrated that both mus-43 and mus-44 retained the ability to excise UV-induced cyclobutane pyrimidine dimers and 6-4 photoproducts, but that excision ability was completely abolished in the mus-43 mus-18 and mus-44 mus-18 double mutants. These double mutants exhibited extremely high sensitivity to UV. In mus-43 and mus-44 mutants, the UV-induced mutation frequency increased compared to that of the wild-type. The mus-44 mutants also exhibited a partial photoreactivation defect phenotype similar to mus-38. These results suggest that both mus-43 and mus-44 function in the mus-38 NER pathway, but not in the mus-18 excision repair pathway.