Trichoderma harzianum transcriptome in response to cadmium exposure.

Cadmium (Cd) is a heavy metal present in the environment mainly as a result of industrial contamination that can cause toxic effects to life. Some microorganisms, as Trichoderma harzianum, a fungus used in biocontrol, are able to survive in polluted environments and act as bioremediators. Aspects about the tolerance to the metal have been widely studied in other fungi although there are a few reports about the response of T. harzianum. In this study, we determined the effects of cadmium over growth of T. harzianum and used RNA-Seq to identify significant genes and processes regulated in the metal presence. Cadmium inhibited the fungus growth proportionally to its concentration although the fungus exhibited tolerance as it continued to grow, even in the highest concentrations used. A total of 3767 (1993 up and 1774 down) and 2986 (1606 up and 1380 down) differentially expressed genes were detected in the mycelium of T. harzianum cultivated in the presence of 1.0 mg mL-1 or 2.0 mg mL-1 of CdCl2, respectively, compared to the absence of the metal. Of these, 2562 were common to both treatments. Biological processes related to cellular homeostasis, transcription initiation, sulfur compound biosynthetic and metabolic processes, RNA processing, protein modification and vesicle-mediated transport were up-regulated. Carbohydrate metabolic processes were down-regulated. Pathway enrichment analysis indicated induction of glutathione and its precursor's metabolism. Interestingly, it also indicated an intense transcriptional induction, especially by up-regulation of spliceosome components. Carbohydrate metabolism was repressed, especially the mycoparasitism-related genes, suggesting that the mycoparasitic ability of T. harzianum could be affected during cadmium exposure. These results contribute to the advance of the current knowledge about the response of T. harzianum to cadmium exposure and provide significant targets for biotechnological improvement of this fungus as a bioremediator and a biocontrol agent.

Blastocladiella emersonii spliceosome is regulated in response to the splicing inhibition caused by the metals cadmium, cobalt and manganese.

Blastocladiella emersonii is an aquatic fungus of the phylum Blastocladiomycota, localized near the base of the fungal tree. Previous studies have shown that B. emersonii responds to heat shock and cadmium exposure inducing the transcription of a high number of genes. EST sequencing from heat shocked and cadmium exposed B. emersonii cells has shown that exposure to cadmium causes strong splicing inhibition. Despite the knowledge about splicing inhibition by cadmium, it is still unclear if other metal contaminants can cause the same response. In the present study, we have demonstrated that the effect of cadmium exposure on splicing inhibition is much stronger than that of other divalent metals such as cobalt and manganese. Data presented here also indicate that intron retention occurs randomly among the fungal transcripts, as verified by analyzing differently affected transcripts. In addition, we identified in the genome of B. emersonii the genes encoding the snRNA splicing components U1, U2, U4, U5 and U6 and observed that spliceosome snRNAs are upregulated in the presence of metals, in particular snRNA U1 in cells under cadmium exposure. This observation suggests that snRNA upregulation might be a defense of the fungal cell against the metal stress condition.

Small heat shock protein genes are developmentally regulated during stress and non-stress conditions in Blastocladiella emersonii.

Small heat shock proteins (sHsps) are molecular chaperones of low molecular weight involved in an early association with misfolded proteins. In response to heat shock, B. emersonii induces the synthesis of a number of proteins. As sHsps are still poorly studied in B. emersonii and in fungi overall, the aim of this work was to carry out a in-depth characterization of sHsps during B. emersonni life cycle, as well as in response to thermal stress. We verified a strong induction of the hsp17 gene in cells exposed to heat shock both in germination and sporulation stages, and that Hsp17 protein levels show the same pattern of variation of its mRNA. Unlike hsp17 and hsp30, hsp16 gene is not significantly induced during heat shock, in germination or sporulation cells. However, at normal temperatures, the hsp16 gene presents high mRNA levels in sporulation cells, whereas the hsp30 gene presents high mRNA levels in germination cells. Interestingly, heat shock mRNA levels for hsp17 and hsp30 genes are 10 times higher in germination cells than in sporulation cells. Thus, our data show that the expression of these sHsp genes is quite distinct, both under normal temperature as during heat shock.

Environmental stresses inhibit splicing in the aquatic fungus Blastocladiella emersonii.

BACKGROUND: Exposure of cells to environmental stress conditions can lead to the interruption of several intracellular processes, in particular those performed by macromolecular complexes such as the spliceosome. RESULTS: During nucleotide sequencing of cDNA libraries constructed using RNA isolated from B. emersonii cells submitted to heat shock and cadmium stress, a large number of ESTs with retained introns was observed. Among the 6,350 ESTs obtained through sequencing of stress cDNA libraries, 181 ESTs presented putative introns (2.9%), while sequencing of cDNA libraries from unstressed B. emersonii cells revealed only 0.2% of ESTs containing introns. These data indicate an enrichment of ESTs with introns in B. emersonii stress cDNA libraries. Among the 85 genes corresponding to the ESTs that retained introns, 19 showed more than one intron and three showed three introns, with intron length ranging from 55 to 333 nucleotides. Canonical splicing junctions were observed in most of these introns, junction sequences being very similar to those found in introns from genes previously characterized in B. emersonii, suggesting that inhibition of splicing during stress is apparently a random process. Confirming our observations, analyses of gpx3 and hsp70 mRNAs by Northern blot and S1 protection assays revealed a strong inhibition of intron splicing in cells submitted to cadmium stress. CONCLUSION: In conclusion, data indicate that environmental stresses, particularly cadmium treatment, inhibit intron processing in B. emersonii, revealing a new adaptive response to cellular exposure to this heavy metal.

Morphological and molecular aspects of sclerotial development in the phytopathogenic fungus Sclerotinia sclerotiorum.

Sclerotinia sclerotiorum (Lib.) de Bary produces a resistance structure called sclerotium, which guarantees its survival in soil for long periods. Morphological and melanization aspects during sclerotial development were evaluated by microscopy and qRT-PCR techniques. S. sclerotiorum produces sclerotia with different phases of maturation and melanization during growth in PDA medium. Using scanning electron microscopy we observed that there are no structural differences in the three stages of formation of melanized and non-melanized sclerotium. Through histochemical analysis we observed that the melanized sclerotium accumulates more glycogen and produces less protein than non-melanized sclerotia. Melanin was most commonly found in the rind of melanized sclerotia, and the highest concentration of lipofucsins was found in non-melanized sclerotia. These molecules are products of the lipid peroxidation pathway and are associated with oxidative stress during differentiation in fungi. The expression of histidine kinase (shk) and adenylate cyclase (sac) genes in melanized and non-melanized sclerotiawere also evaluated. The higher gene expression of shk and lesser expression of sac in non-melanized sclerotiais an indication of the participation of cell signaling in the development of these structures. The higher expression of polyketide synthase (pks), tyrosinase (tyr) and laccase (lac) in non-melanized sclerotia suggested that S. sclerotiorum can use the DHN and L-dopa pathways to produce melanin. Expression studies of the enzymes chitin synthase and glucan synthase suggest that this process occurs along with the formation of melanin. This is interesting since polysaccharides, such as chitin and ß-1,3-glucan, serve as a scaffold to which the melanin granules are cross-linked.

Hsp genes are differentially expressed during Trichoderma asperellum self-recognition, mycoparasitism and thermal stress.

Heat shock proteins (Hsp) are important factors in the response of organisms to oscillations in environmental conditions. Although Hsp have been studied for a long time, little is known about this protein class in Trichoderma species. Here we studied the expression of Hsp genes during T. asperellum growth, and mycoparasitism against two phytopathogens: Sclerotinia sclerotiorum and Fusarium oxysporum, as well as during thermal stress. The expression levels of these genes were observed by real-time PCR and they showed to be differentially expressed under these conditions. We verified that the TaHsp26c, TaHsp70b and TaHsp70c genes were differentially expressed over time, indicating that these genes can be developmentally regulated in T. asperellum. Except for TaHsp26a, all other genes analyzed were induced in the post-contact condition when T. asperellum was cultured in a confrontation plate assay against itself. Additionally, TaHsp26b, TaHsp26c, TaHsp90, TaHsp104a and TaHsp104b were induced during initial contact between T. asperellum hyphae, suggesting that these proteins must play a role in the organism´s self-recognition mechanism. When we examined gene expression during mycoparasitism, we observed that some genes were induced both by S. sclerotiorum and F. oxysporum, while others were not induced during interaction with either of the phytopathogens. Furthermore, we observed some genes induced only during confrontation against S. sclerotiorum, indicating that the expression of Hsp genes during mycoparasitism seems to be modulated by the phytopathogen. To assess whether such genes are expressed during temperature oscillations, we analyzed their transcription levels during thermal and cold shock. We observed that except for the TaHsp70c gene, all others presented high transcript levels when T. asperellum was submitted to high temperature (38 °C), indicating their importance in the response to heat stress. The TaHsp70c gene was significantly induced only in cold shock at 4 °C. Our results show the importance of Hsp proteins during self-recognition, mycoparasitism and thermal stress in T. asperellum.

Binding of oxindole-Schiff base copper(II) complexes to DNA and its modulation by the ligand.

Previous studies on copper(II) complexes with oxindole-Schiff base ligands have shown their potential antitumor activity towards different cells, inducing apoptosis through a preferential attack to DNA and/or mitochondria. Herein, we better characterize the interactions between some of these copper(II) complexes and DNA. Investigations on its binding ability to DNA were carried out by fluorescence measurements in competitive experiments with ethidium bromide, using plasmidial or calf-thymus DNA. These results indicated an efficient binding process similar to that observed with copper(II)-phenanthroline species, [Cu(o-phen)(2)](2+), with binding constants in the range 3 to 9×10(2) M(-1). DNA cleavage experiments in the presence and absence of distamycin, a recognized binder of DNA, indicated that this binding probably occurs at major or minor groove, leading to double-strand DNA cleavage, and being modulated by the imine ligand. Corroborating these data, discrete changes in EPR spectra of the studied complexes were observed in the presence of DNA, while more remarkable changes were observed in the presence of nucleotides (AMP, GMP, CMP or UMP). Additional evidence for preferential coordination of the copper centers to the bases guanine or cytosine was obtained from titrations of these complexes with each nucleotide, monitored by absorption spectral changes. Therefore, the obtained data point out to their action as groove binders to DNA bases, rather than as intercalators or covalent cross-linkers. Further investigations by SDS PAGE using (32)P-ATP or (32)P-oligonucleotides attested that no hydrolysis of phosphate linkage in DNA or RNA occurs, in the presence of such complexes, confirming their main oxidative mechanism of action.