Oak extractive-induced stress reveals the involvement of new enzymes in the early detoxification response of Phanerochaete chrysosporium.

Extensive evidence showed that the efficiency of fungal wood degradation is closely dependent on their ability to cope with the myriad of putative toxic compounds called extractives released during this process. By analysing global gene expression of Phanerochaete chrysosporium after short oak extractive treatment (1, 3 and 6 h), we show that the early molecular response of the fungus concerns first mitochondrial stress rescue followed by the oxidation and finally conjugation of the compounds. During these early responses, the lignolytic degradative system is not induced, rather some small secreted proteins could play an important role in cell protection or signaling. By focusing on the functional characterization of an hitherto uncharacterized glutathione transferase, we show that this enzyme interacts with wood molecules suggesting that it could be involved in the detoxification of some of them, or act as a scavenger to prevent their cytosolic toxicity and favour their transport.

The two Arabidopsis RPS6 genes, encoding for cytoplasmic ribosomal proteins S6, are functionally equivalent.

Many eukaryotic genomes have experienced ancient whole-genome duplication (WGD) followed by massive gene loss. These eliminations were not random since some gene families were preferentially retained as duplicates. The gene balance hypothesis suggests that those genes with dosage reduction can imbalance their interacting partners or complex, resulting in decreased fitness. In Arabidopsis, the cytoplasmic ribosomal proteins (RP) are encoded by gene families with at least two members. We have focused our study on the two RPS6 genes in an attempt to understand why they have been retained as duplicates. We demonstrate that RPS6 function is vital for the plant. We also show that reducing the level of RPS6 accumulation (in the knock-out rps6a or rps6b single mutants, or in the double heterozygous RPS6A/rps6a,RPS6B/rps6b), confers a slow growth phenotype (haplodeficiency). Importantly, we demonstrate that the functions of two RPS6 genes are redundant and interchangeable. Finally, like in most other described Arabidopsis rp mutants, we observed that a reduced RPS6 level slightly alters the dorsoventral leaf patterning. Our results support the idea that the Arabidopsis RPS6 gene duplicates were evolutionarily retained in order to maintain an expression level necessary to sustain the translational demand of the cell, in agreement with the gene balance hypothesis.