Aspergillus nidulans Transcription Factor BrlA is Utilized in a Conidiation-Independent Response to Cell-Wall Stress

Under synchronized conidiation, over 2500 gene products show differential expression, including transcripts for both brlA and abaA, which increase steadily over time. In contrast, during wall-stress induced by the echinocandin micafungin, the brlA transcript is upregulated while the abaA transcript is not. In addition, when mpkA (last protein kinase in the cell wall integrity signaling pathway) is deleted, brlA expression is not upregulated in response to wall stress. Together, these data imply BrlA may play a role in a cellular stress-response which is independent of the canonical BrlA-mediated conidiation pathway. To test this hypothesis, we performed a genome-wide search and found 332 genes with a putative BrlA response element (BRE) in their promoter region. From this set, we identified 28 genes which were differentially expressed in response to wall-stress, but not during synchronized conidiation. This set included seven gene products whose homologues are involved in transmembrane transport and 14 likely to be involved in secondary metabolite biosynthesis. We selected six of these genes for further examination and find that they all show altered expression behavior in the brlA deletion strain. Together, these data support the idea that BrlA plays a role in various biological processes outside asexual development. ImportanceThe Aspergillus nidulans transcription factor BrlA is widely accepted as a master regulator of conidiation. Here, we show that in addition to this function BrlA appears to play a role in responding to cell-wall stress. We note that this has not been observed outside A. nidulans. Further, BrlA-mediated conidiation is highly conserved across Aspergillus species, so this new functionality is likely relevant in other Aspergilli. We identified several transmembrane transporters that have altered transcriptional responses to cell-wall stress in a brlA deletion mutant. Based on our observation, together with what is known about the brlA gene locus regulation, we identify brlA{beta} as the likely intermediary in function of brlA in the response to cell-wall stress.