Secondary metabolites are often highly biologically active molecules and are widely used from antibacterial to anticancer drugs. In this issue of Chemistry and Biology, Zaehle and coworkers describe the gene cluster and biosynthesis of the polyketide terrein, a secondary metabolite produced by the soil-borne fungus Aspergillus terreus.

Aspergillus nidulans responds to light in several aspects. The balance between sexual and asexual development as well as the amount of secondary metabolites produced is controlled by light. Here, we show that germination is largely delayed by blue (450 nm), red (700 nm), and far-red light (740 nm). The largest effect was observed with far-red light. Whereas 60 % of the conidia produced a germ tube after 20 h in the dark, less than 5 % of the conidia germinated under far-red light conditions. Because swelling of conidia was not affected, light appears to act at the stage of germ-tube formation. In the absence of nutrients, far-red light even inhibited swelling of conidia, whereas in the dark, conidia did swell and germinated after prolonged incubation. The blue-light signaling components, LreA (WC-1) and LreB (WC-2), and also the cryptochrome/photolyase CryA were not required for germination inhibition. However, in the phytochrome mutant, ∆fphA, the germination delay was released, but germination was delayed in the dark in comparison to wild type. This suggests a novel function of phytochrome as far-red light sensor and as activator of polarized growth in the dark.

Light sensing in organisms is conferred by a small number of light-absorbing, organic molecules. The primary light reaction is transmitted to the protein moiety, which in turn triggers cellular reactions. In filamentous fungi a large number of different morphogenetic and physiological processes is controlled by light; flavine- and tetrapyrrol-containing photoreceptors are main players.

Kinesin molecular motors serve a variety of cellular functions usually in dynamic processes. One characteristic feature of many kinesins is their ATP-dependent processive movement along polymerized microtubules. However, many kinesins work as stationary polymerases or depolymerases. Therefore, it needs to be determined for each motor, whether it moves processively along microtubules or not. The Schizosaccharomyces pombe kinesin-7, Tea2, has been shown to be involved in cell end marker transportation towards the cortex to organize the actin cytoskeleton. In human, kinesin 7 promotes microtubule polymerization. In Aspergillus nidulans, the machinery for determining growth directionality is conserved, but there is no evidence yet that kinesin 7, KipA is potentially involved in the transportation of the cell end marker proteins, TeaA or TeaR or newly identified proteins such as KatA. We expressed KipA in Escherichia coli and determined the catalytic properties of this kinesin. Here we show that KipA is an active ATPase, which is able to dimerize and move processively along microtubules with a speed of 9.48 μm/min.

Aspergillus nidulans senses red and blue-light and employs a phytochrome and a Neurospora crassa White Collar (WC) homologous system for light perception and transmits this information into developmental decisions. Under light conditions it undergoes asexual development and in the dark it develops sexually. The phytochrome FphA consists of a light sensory domain and a signal output domain, consisting of a histidine kinase and a response regulator domain. Previously it was shown that the phytochrome FphA directly interacts with the WC-2 homologue, LreB and another regulator, VeA. In this paper we mapped the interaction of FphA with LreB to the histidine kinase and the response regulator domain at the C-terminus in vivo using the bimolecular fluorescence complementation assay and in vitro by co-immunoprecipitation. In comparison, VeA interacted with FphA only at the histidine kinase domain. We present evidence that VeA occurs as a phosphorylated and a non-phosphorylated form in the cell. The phosphorylation status of the protein was independent of the light receptors FphA, LreB and the WC-1 homologue LreA.

Aspergilli are ubiquitous soil-borne fungi growing within or on the surface of numerous organic substrates. Growth within a substrate or growth on the surface correlates to different growth conditions for the hyphae due to significant changes in oxygen or reactive oxygen species levels and variations in humidity or temperature. The production of air-borne spores is supported by the substrate-air interphase and also requires a sensing system to adapt appropriately. Here we focus on light as important parameter for the mycelium to discriminate between different habitats. The fungal ‘eye’ includes several light sensors which react to a broad plethora of wavelengths. Aspergillus nidulans light receptors comprise a phytochrome for red-light sensing, white collar-like blue-light signaling proteins, a putative green-light sensing opsin and a cryptochrome/photolyase as distinct sensory systems. Red- and blue-light receptors are assembled into a light-sensing protein complex. Light receptors transmit their signal to a number of other regulatory proteins including a bridging protein, VeA, as part of a trimeric complex. VeA plays a central role in the balance of asexual and sexual development and in the coordination of morphogenesis and secondary metabolism.

•First description of CRISPR/Cas9 application in A. alternata.•Establishment of a pyrG mutant.•Use of GFP.The filamentous fungus Alternaria alternata is a potent producer of many secondary metabolites, some of which like alternariol or alternariol-methyl ether are toxic and/or cancerogenic. Many Alternaria species do not only cause post-harvest losses of food and feed, but are aggressive plant pathogens. Despite the great economic importance and the large number of research groups working with the fungus, the molecular toolbox is rather underdeveloped. Gene deletions often result in heterokaryotic strains and therefore, gene-function analyses are rather tedious. In addition, A. alternata lacks a sexual cycle and classical genetic approaches cannot be combined with molecular biological methods. Here, we show that CRISPR/Cas9 can be efficiently used for gene inactivation. Two genes of the melanin biosynthesis pathway, pksA and brm2, were chosen as targets. Several white mutants were obtained after several rounds of strain purification through protoplast regeneration or spore inoculation. Mutation of the genes was due to deletions from 1 bp to 1.5 kbp. The CRISPR/Cas9 system was also used to inactivate the orotidine-5-phosphate decarboxylase gene pyrG to create a uracil-auxotrophic strain. The strain was counter-selected with fluor-orotic acid and could be re-transformed with pyrG from Aspergillus fumigatus and pyr-4 from Neurospora crassa. In order to test the functioning of GFP, the fluorescent protein was fused to a nuclear localization signal derived from the StuA transcription factor of Aspergillus nidulans. After transformation bright nuclei were visible.