A global search for novel transcription factors impacting the Neurospora crassa circadian clock

For this reverse genetic screen, we analyzed the sexual progeny obtained from crosses between circadian luciferase reporter strains and TF KOs available from the Fungal Genetic Stock Center (FGSC, Kansas City, MO, USA). The KOs were obtained as part of the N. crassa Functional Genomics Project, where individual loci were replaced with the hygromycin B phosphotransferase (hph) gene drug-resistance cassette (Colot et al. 2006; Collopy et al. 2010). We generated a list of putative TF-encoding genes based on the presence of the DNA binding domain sequence described for the N. crassa genome available in the web platform CISBP (cisbp.ccbr.utoronto.ca) (Weirauch et al. 2014). Such list included other genes previously related to transcriptional function (Borkovich et al. 2004; Tian et al. 2011), and which has been recently compiled (Carrillo et al. 2017), yielding a final list of 302 putative TFs loci listed in the Supplementary Table S1.

The reporter utilized in the primary screen was a firefly luciferase gene under the control of a minimal frq clock promoter (frq_c-box-luc) integrated into the his-3 locus in LG I: his-3::frq_c-box-luc (Gooch et al. 2008; Larrondo et al. 2015). Alternatively, another reporter consisting on a destabilized firefly luciferase (containing a PEST domain), under the control of the same minimal frq_c-box promoter was utilized, this time targeted to the csr-1 locus: csr-1::frq_c-box-luc^PEST, as previously described (Cha et al. 2015; Olivares-Yanez et al. 2016). Both loci are ∼3 million bp apart, improving the number of successful crosses to that linkage group, by diminishing cosegregation of the reporter and hygromycin cassettes (Bardiya and Shiu 2007; Gooch et al. 2008; Honda and Selker 2009; Gooch et al. 2014). To confirm that the observed effects were not due to some spurious factor arising during the cross, and to also test the extent of circadian alterations caused by the missing gene, we also conducted a secondary screen utilizing a circadian output reporter. For this, we used con-10^luc (con-10^luc-bar) (Lauter and Yanofsky 1993; Olivares-Yanez et al. 2016), which corresponds to a fusion of luciferase to the con-10 ORF at its endogenous locus. And while technically con-10^luc is a translational reporter, it faithfully recapitulates core circadian alterations as frq_c-box-luc does (Olivares-Yanez 2015) and, therefore, it helps further characterizing the mutants of interest. The reporters were introduced in lab strains derived from crosses between progenies of 87-74 and FGSC #9568 (Larrondo et al. 2015; Olivares-Yanez 2015) which were used as the parental strains for the crosses. They were also utilized as WT controls, along with selected hygromycin sensitive siblings from the progenies derived from the screen crosses.

Out of a list of 302 putative TFs encoding genes in the N. crassa genome (Montenegro-Montero 2014), 45 KO strains were not available in the N. crassa FGSC KO collection (http://www.fgsc.net/↗) at the time we obtained the arrayed strains from the FGSC.

Culture conditions for vegetative growth and asexual reproduction utilized Vogel minimal medium (VM) (Vogel 1956), whereas conditions for sexual development used synthetic crossing medium (SCM) (Westergaard and Mitchell 1947). Sorbose-containing medium (FIGS) was used for colony isolation on plates and ascospore germination and isolation (Davis and de Serres 1970). Picked ascospores were then grown on slants containing VM media supplemented with hygromycin (200 μg/ml; Calbiochem, San Diego, CA, USA) and luciferin (GoldBio) (10 μM), in order to select for progenies carrying knockout cassettes and reporter activity, respectively.

To conduct the circadian analyses (see below), spores from the selected progenies were inoculated in a 96 well plate containing LNN-CCD media (Larrondo et al. 2015; Olivares-Yanez 2015), with 25 μM of Luciferin (GoldBio). Cultures were grown for 24 hours in constant light (LL) at 25°C and then were analyzed under free-running conditions; consisting of constant darkness (DD) and 25°C, for 4–5 days in Percival incubators equipped with CCD PIXIS 1024B cameras (Princeton Instruments). As part of the high-throughput design, several 96 well-plates were run together in a single CCD camera run.

The resulting images series obtained from CCD camera runs were analyzed with a customized script for ImageJ (Larrondo et al. 2012). The acquired data sets varied in some cases containing 2 or 3 pictures per hour, with exposition times of 10 or 5 minutes respectively, a difference that does not affect the analyses as information can be compared throughout the data sets. Importantly, control wild-type (WT) strains were included in each 96-well plate and each experimental run. The obtained luciferase traces were analyzed as raw as well as normalized data sets (see below).

For the circadian analysis of the recorded time series, the data were uploaded as individual CCD camera runs (each run containing the corresponding WT controls) in BioDare2 (Biological Data Repository 2), a free-available online platform (https://biodare2.ed.ac.uk/↗) (Moore et al. 2014; Zielinski et al. 2014) which provides a comprehensive analysis of circadian parameters using different algorithms (Zielinski et al. 2014). The data were processed in the following manner for the primary screen: first, data were detrended to remove stationary effects over the time series, as such trends can cause distortions in the data masking circadian information. In addition, we discarded the first and last 12 hours of the data to minimize noise effects associated with the transition from light to darkness and improve subsequent detrending. Periods were calculated using a fast Fourier transform-nonlinear least-squares analysis (FFT-NLLS). Finally, we normalized and aligned every data point respect to the average of all points in their time series to facilitate their visualization (Plautz et al. 1997; Zielinski et al. 2014). The entire data sets produced in this genetic screen are stored in the BioDare2 platform, as an open access repository, with the spirit of propelling further analysis of these and other data by the circadian community. Importantly, the data sets from each CCD camera run are enlisted in the platform as “Neurospora TF Circadian Clock” plus the date of the CCD camera run; these entries also describe the experimental conditions, reporters and the TF KOs analyzed in each run. Period was re-calculated (see below) to compare this circadian parameter for each strain with an internal control (WT) in each 96-experimental run, to minimize the potential noise when comparing different plates in different experiments. The WT strains used in each plate and camera run were the parental reporters used for the crosses, their siblings, along WT siblings (hygromycin sensitive) of the KO crosses. The averaged period calculated for these WT is 21.76 hours, similar to the previous reported value of ∼21.5 utilizing similar WT controls (Larrondo et al. 2015). For the analyses, we calculated period change (Δτ; as Period_KO—Period_wt.), measured in hours.

We defined the tolerance interval for the WT population using their Δτ in each of the experiments, taking three standard deviation from the mean population (Zhang et al. 2009), after confirming their normal distribution (Shapiro–Wilk test, P < 0.05). With this interval, we covered approximately 99.7% of the WT population and we were able to define TF KOs of interest as the ones that fell outside this range. To reduce the outlier effects, we compared the median of the different selected progenies from each cross.

To analyze the circadian defects between the obtained results using the core and the circadian output reporters we applied a t-test comparing them, discarding samples that showed different results (P < 0.05).

Selected KO strains from the primary genetic screen were complemented by electroporating their conidia with an amplicon containing the corresponding gene, aiming at replacing the hph cassette located in the respective knockout loci (Colot et al. 2006; Collopy et al. 2010). The complementation cassettes were constructed by yeast recombination cloning (Oldenburg et al. 1997; Raymond et al. 1999) containing 5’- and 3’-Flanking regions with the ORF plus a V5-tag and the bar cassette for resistance selection (Collopy et al. 2010). Subsequently, the selection was made through microconidiation to obtain homokayotic strains containing the complemented genes at their endogenous loci (Ebbole and Sachs 1990). Thus, complementation was conducted on a subset of particular KOs derived from the screen, to confirm that the absence of a specific TF encoding gene is the cause of the observed period defect. As the absence of some TFs leads to conidial and growth problems (Carrillo et al. 2017), we focused instead on strains of interest that could be easily subjected to a transformation protocol. Thus, we complemented KOs for NCU01238, NCU00499, NCU10006, and NCU08999, which were transformed with a cassette reconstituting the missing ORF, plus a V5 tag: complementation of the four above-mentioned mutant loci recovered a WT period phenotype.

To identify novel regulators impacting the N. crassa circadian clock we adopted a reverse genetic strategy, focusing on putative TFs encoded in its genome (Borkovich et al. 2004; Tian et al. 2011; Weirauch et al. 2014). The screen consisted of analyzing the behavior of circadian luciferase reporters in the absence of individual TFs. As indicated in the methods section, this was achieved by crossing strains missing a particular TF, available from the N. crassa KO collection, with strains containing a circadian luciferase reporter. Diverse biological and technical issues limited the current extensiveness of this screen: we started our study with a list of 289 genes encoding for putative TFs in the N. crassa genome, defined from previous work from our lab (Weirauch et al. 2014), adding later on other putative TF encoding genes (Borkovich et al. 2004; Tian et al. 2011; Carrillo et al. 2017), yielding a final list of 302 TF possible candidates summarized in Supplementary Table S1. Nevertheless, KOs for 45 of these genes were unavailable in our version of the N. crassa KO collection (Colot et al. 2006) when we started the screen (Supplementary Table S1; KOs not available), while some of the genes were essential and therefore obtaining such mutants as homokaryons were not possible (Giaever and Nislow 2014; Carrillo et al. 2017). Thus, for the available 257 KOs, sexual crosses were conducted with a strain containing a clock-luciferase reporter, in order to analyze the effect of deleting specific TFs. From this long list, 91 crosses failed to yield enough hyg^R, luc⁺ offspring for the circadian luciferase analyses.

Genetic linkage issues can explain some of these 91 nonproductive crosses; 41 KO loci are in the same chromosome (LGI) as his-3, implying a genetic linkage between the hph cassette and the luciferase reporter. Therefore, for these unsuccessful crosses (based on a reporter strain where luciferase was inserted at his-3) (Honda and Selker 2009), we conducted new crosses for 18 knockouts, but this time utilizing a frq-c-box reporter located at a different region of LGI; the csr-1 locus (Bardiya and Shiu 2007), which allowed obtaining progeny for 11 additional TF Knockouts, leaving only 80 unsuccessful crosses (Supplementary Table S1; failed offspring) of which 30 can be clearly attributed to genetic linkage. Importantly, among these 80, many of the KOs appeared to be associated with developmental and growth problems (Carrillo et al. 2017), partially explaining the failure to obtain successful progenies. Thus, in toto, this screen circadianly examined a total of 177 TFs knockouts, corresponding to ∼60% of the cohort of putative N. crassa transcriptional regulators (Supplementary Table S1; analyzed strains). The resulting progenies from each cross, and the corresponding WT controls (parental strains and hygromycin sensitive siblings) were monitored for luciferase expression, and analyzed through the Biodare2 platform, focusing on period change (Δτ) (Moore et al. 2014; Zielinski et al. 2014) and plotted accordingly as shown in Supplementary Figure S1. Progeny of two of the 177 crosses were not included in the plots as they were cataloged as arrhythmic: Δwc-1 and Δwc-2, which is expected as they correspond to core clock components (Supplementary Figure S1). Interestingly, the analysis of ΔNCU02666 first suggested that its absence also abrogated rhythms, as it exhibited extremely low and apparently arrhythmic LUC signals. Nevertheless, normalization of the data revealed weak, but rhythmic oscillations for that reporter (c-box-luc), whilst analysis with a different one (con-10^luc, see next section) confirmed that in ΔNCU02666 the clock still runs with a WT period (Supplementary Figure S2). The reason why in this mutant the behavior of the c-box reporter is extremely weak, although the core clock still runs, remains to be determined.

To select for the strongest circadian phenotypes in our screen, we defined upper and lower thresholds based on a tolerance interval of three standard deviations of the WT mean values for Δτ (see Materials and Methods; Supplementary Figure S3); this tolerance interval corresponds to ±0.49 hours. With this approach, we covered ∼99.7% of the WT group (assuming a normal distribution, Shapiro–Wilk test P < 0.05). The selection of TF KOs of interest comprise strains with calculated median outside this tolerance interval (Zhang et al. 2009). For a better visualization of the scattered Δτ data emerging from the plotted 175 crosses, it was separated in two groups: strains exhibiting shorter (Figure 1) and longer (Figure 2) periods. The results of our primary screen analyses are summarized in Supplementary Table S2, indicating the experimental identifiers, calculated period change (Δτ), number of biological replicates, and the descriptive statistics for each of the studied TF KOs; also, we listed in a secondary supplementary table (Supplementary Table S3), the raw results from each individual strain retrieved from the BioDare2 platform for simpler and faster access.

Out of this analysis, only 36 KOs showed statistically significant differences in the primary screen, based on the above-mentioned criteria of three standard deviation from the wild-type population mean (Zhang et al. 2009). Notably, 30 out of 36 TF KOs displayed shorter period, results that contrast with what has been observed in similar screens conducted in other circadian models, where most of the identified genes affecting the clock yield longer periods (Matsumoto et al. 2007; Hirota et al. 2008; Zhang et al. 2009; Agrawal and Hardin 2016). To ensure that the circadian change in these 36 candidates was caused by the removal of the specific locus of interest, we also analyzed WT siblings for each selected KO. This additional evaluation helped reducing the deviation associated with technical noise derived from the analysis of different plates and/or camera runs, or for potential unlinked spontaneous mutations present in the KO or emerging during the sexual crosses (Watters and Stadler 1995).

To confirm that the clock defects observed in our screen with a minimal core clock reporter (c-box-luc) were actually due to circadian alterations, and not to unidentified technical issues, such as low reporter expression or other reasons (see Supplementary Figure S2), we evaluated the behavior of a different reporter in the selected TF KOs. For this, we utilized the output gene con-10 (NCU07325), which exhibits robust circadian expression (Lauter and Yanofsky 1993; Hurley et al. 2014). con-10 is a vastly studied gene, expressed in late stages of conidial differentiation (Roberts et al. 1988; Olmedo et al. 2010a), responds to light (Olmedo et al. 2010b; Wu et al. 2014), and is highly expressed during carbon starvation, similar to our experimental conditions, (Xiong et al. 2014, 2017) among others regulations (Kays et al. 2000; Thompson et al. 2008; Wang et al. 2012; Pengkit et al. 2016; Dekhang et al. 2017). We created a con-10^luc reporter by integrating luc at the corresponding locus obtaining a fusion between the latter and the con-10 ORF (Olivares-Yanez et al. 2016).

This secondary analysis (Figure 3) reduced the number of TFs of interest derived from the primary screen. Four of the 36 candidate TFs were disregarded in the following analysis for experimental issues; three of them (NCU04390, NCU08289, and NCU08651) failed to produce successful offspring with the con-10^luc reporter, whereas the KO for NCU02017 severely affected the expression of the circadian output reporter; leaving further confirmation of these KOs pending. Nine strains were also left out of the refined list of TFs of interest as in the con-10^luc analyses since period differences did not statistically recapitulate what had been observed with the core clock reporter (Figure 3).

Thus, interestingly, the use of two different circadian reporters allowed us to observe differences in the degree of circadian alteration of several TF KOs strains (Supplementary Figure S2). These differences could relate to a direct effect of the candidate TF in both pathways: alterations on the N. crassa clock and in output pathways (con-10), versus a major effect only in the former and compensatory mechanisms in the latter (albeit this would be less likely). A clear example of a KO impacting both core clock function and the output pathways while severely compromising the quality of con-10 rhythms is Δada-2 (NCU02017), where the expression of con-10^luc appears severely affected. This TF KO shows defects in both sexual and asexual development (Sun et al. 2019) and differential gene expression upon carbon source differences (Reilly et al. 2015), conditions where con-10 regulation is affected (Wang et al. 2012; Xiong et al. 2014, 2017).

In terms of period, Δsub-1 (NCU01154) and Δada-9 (NCU01238), where significantly shorter when examining output compared to the core clock reporter (Figure 3). Both of these TFs had been previously associated with con-10 regulation: in Δsub-1, light induction of con-10 is reduced (Sancar et al. 2015a), and in the case of ADA-9, this TF is capable of interacting with RCO-1 (Olivares-Yanez et al. 2016), a transcriptional co-repressor that drastically affects con-10 expression (Yamashiro et al. 1996). In addition, both KOs show alterations on sexual and asexual development (Carrillo et al. 2017), conditions where con-10 expression is differentially regulated, as commented above. Yet, it is not obvious to explain that period for a particular KO would yield so different results with the core-clock and output reporters.

Thus, applying a conservative criterion restricting the list to those which absence showed significant period changes in both screens, we identified 23 TF encoding genes, which corresponds to ∼7.6% of the total number of putative TFs in N. crassa (and a ∼13% of the successfully analyzed for luc expression). Importantly, other clock screens based on similar reverse genetics approaches have shown variable results. For example, while in a broad screen using human cells the rate of genes of interest was near 1% for a total of 22,468 genes, or a smaller subgroup (Maier et al. 2009; Zhang et al. 2009), depending on the size of the screen or the category of the analyzed genes such rates can go up. Thus, genes flagged as of interest were ∼3.8% of 133 circadianly expressed genes screened in Drosophila (Matsumoto et al. 2007), compared to ∼22% of 86 phosphatase encoding genes in the same organism (Agrawal and Hardin 2016). To our knowledge, there are no published studies exclusively focusing on the circadian impact of TFs, although TFs with a clock-related function have been already identified in unbiased screens (Matsumoto et al. 2007).

Thus, based on the strict criteria of showing period alterations when assessing with both reporters, we have identified 23 TFs with strong and reproducible circadian defects, which appear to be involved in a broad range of cellular processes, as it is indicated in the next paragraphs for each one. The absence of the corresponding ORFs in the progeny of these 23 KOs was confirmed by PCR, and for four particular KOs (that will be further pursued for mechanistic studies) we conducted complementation assays (see below and Supplementary Table S4).

NCU08999: (Δτ = +1.38 h) this locus encodes for a bHLH TF, which is an ortholog of the yeast centromere binding factor 1 (cbf-1) (Stoyan et al. 2001). This gene is known to be expressed late after phytosphingosine treatment (Videira et al. 2009). Recently this N. crassa TF was described to have a similar circadian phenotype (∼2 h lengthened period), as determined by race tube assays (Cao et al. 2018). Interestingly, the authors failed to observe circadian expression of luciferase in their characterization of this mutant, which could be partially explained by their experimental settings (see Discussion), a discrepancy we have seen with other mutants like Δrco-1 (Zhou et al. 2013; Olivares-Yanez et al. 2016). The period phenotype associated with ΔNCU08999 was restored to WT upon complementation (Figure 4B).

NCU04001: (Δτ = +0.87 h) identified as female fertility 7 (ff-7), this zinc-finger TF was found to interact with SUB-1 (NCU01154) in regulating the expression of several genes in LL and DD conditions. This transient complex is able to interact with WCC upon light exposure, modulating several genes (Sancar et al. 2015a). ADV-1 (NCU07392) regulates NCU04001/ff-7 expression in a light dependent manner (Dekhang et al. 2017). ff-7 is subjected to metabolic regulation and its expression is decreased in a Δcol-26 (NCU07788) strain in amylose (Xiong et al. 2017), and it is also reduced in a strain overexpressing CSP-1 (NCU02713) in light conditions (Sancar et al. 2011).

NCU03417: (Δτ = +0.52 h) encodes for a hypothetical C6 zinc-finger containing protein. Its expression in DD is altered in the absence of MAK-1 (Mitogen-Activated Protein Kinase) (Bennett et al. 2013).

NCU01243: (Δτ = +0.50 h) corresponds to zinc-finger 41 (znf-41), a TF highly conserved in many pathogenic fungi. In N. crassa, it is induced by menadione, and its absence leads to enhanced ROS sensitivity (Zhu et al. 2013). It is a light-responsive gene, directly regulated by WCC (Smith et al. 2010), while also displaying rhythmic expression (Hurley et al. 2014).

NCU01640: (Δτ = −0.51 h) corresponds to a C2H2 TF named regulatory particle non-ATPase-like-4 (rpn-4). rpn-4 is a light-responsive gene, whose expression is up-regulated by ADV-1 (Dekhang et al. 2017) and down-regulated by CSP-1 (Sancar et al. 2011). Both of these TFs are rhythmically expressed (Hurley et al. 2014; Dekhang et al. 2017), and are related to responses to particular sugar availability, implying a possible metabolic control over rpn-4. Thus, expression of the latter and of adv-1, are decreased in the presence of amylose in a Δcol-26 strain (Xiong et al. 2017). Also, the expression of this gene is strongly activated under conditions which challenge cell integrity; such as phytosphingosine treatment, an inducer of programed cell death in N. crassa, (Videira et al. 2009), and conditions that favor cell fusion and cell-to-cell communication, regulated by ADV-1 and PP-1 (NCU00340) (Fischer et al. 2018). This gene exhibits rhythmic expression (Hurley et al. 2014).

NCU02307: (Δτ = −0.51 h) is a light-responsive gene encoding for a zinc-finger TFs, up-regulated indirectly by ADV-1 (Dekhang et al. 2017), with reduced expression in a csp-1 overexpressing strain (Sancar et al. 2011). It varies differentially between new and old vegetative tissue (Tian et al. 2011), and it is mostly expressed in aerial hyphae compared to mycelia (Greenwald et al. 2010). Albeit this TF has not been well characterized yet, its expression is strongly tied to plant cell-wall degradation, being highly expressed under such conditions (Tian et al. 2009), depending on XLR-1, a well-known TF involved in hemicellulose degradation (Sun et al. 2012a). Its expression is also differentially regulated in starch, where it is repressed by the TF COL-26 (Xiong et al. 2017). NCU02307 has been reported as exhibiting rhythmic expression, with a peak in the evening (Hurley et al. 2014).

NCU04773: (Δτ = −0.56 h) encodes for a conserved fungal hypothetical protein containing a copper ion-binding domain. A related ortholog is GRISEA, a copper-dependent TF in Podospora anserina or yeast MAC1 (Borghouts and Osiewacz 1998). Podospora lacking GRISEA shows an increased lifespan by reduction of ROS and ATP, this through switching from a copper-dependent to an iron-dependent respiration system (Borghouts et al. 1997; 2001; Gredilla et al. 2006).

NCU08443: (Δτ = −0.63 h) This gene encodes for a zinc ion-binding TF. It has been shown to display rhythmic expression by RNA-Seq, with a morning peak of expression (Hurley et al. 2014).

NCU09615: (Δτ = −0.63 h) encodes for a zinc TF named vegetative asexual development 14 (vad-14) (Carrillo et al. 2017) and is a light-responsive gene, with a late-light expression pattern—between 60 and 120 min—(Wu et al. 2014), directly regulated by WCC (Smith et al. 2010) and indirectly by ADV-1 (Dekhang et al. 2017). It has been described to have rhythmic expression, with a morning peak (Hurley et al. 2014). Also, it is induced by starch-related carbon sources and not by simple sugars such as maltose (Xiong et al. 2017). In cell viability assays its levels are increased (Hutchison et al. 2009).

NCU08042: (Δτ = −0.64 h) this locus encodes for the C6 zinc-finger TF cellulose degradation regulator 2 (CLR-2). Identified by its severe growth defect on crystalized cellulose (Avicel) (Coradetti et al. 2012). CLR-2 regulates the expression of several cellulolytic genes (Coradetti et al. 2013), and itself is induced by cellulose in a CLR-1 (NCU07705) dependent manner (Coradetti et al. 2012; Znameroski et al. 2012; Xiong et al. 2017).

NCU03643: (Δτ = −0.66 h) Encodes for a zinc-finger TF ortholog of cutinase transcription factor 1 beta (ctf1β) (Li et al. 2002; Tang et al. 2011). It is a light-responsive gene (Dong et al. 2008; Chen et al. 2009) whose expression appears to be regulated by FF-7 (Sancar et al. 2015a), and it is also affected by menadione (Zhu et al. 2013). It is downregulated in the absence of col-26, under amylose conditions (Xiong et al. 2017), and it exhibits a delayed up-regulation to quinic acid (QA), likely mediated by QA-1F (NCU06028), the main controller of the QA cluster in N. crassa (Patel and Giles 1985; Tang et al. 2011). It is positively regulated by direct binding of ADV-1, providing its basal expression (Dekhang et al. 2017). CTF1β has been predicted as an “activator” of the delayed group of metabolic genes up-regulated after QA addition (Tang et al. 2011), and it has also been reported as exhibiting rhythmic expression (Hurley et al. 2014).

NCU08652: (Δτ = −0.67 h) this locus encodes for hypothetical C6 zinc-finger TF, described based on its knockout phenotype as slower growth rate 31 (sgr-31) (Carrillo et al. 2017). It has a differential expression when grown under maltose compared with other carbon source or sucrose (Xiong et al. 2017).

NCU07675: (Δτ = −0.67 h) Encodes for a C6 zinc-finger TF defined as tall aerial hyphae 4 (tah-10). Its expression is affected by amylose, showing decreased levels in the absence of col-26 (Xiong et al. 2017), with high expression in asexual reproduction conditions (Wang et al. 2019). Its expression is reduced in a CSP-1 overexpression strain, albeit it is not a direct target of this TF (Sancar et al. 2011).

NCU01154: (Δτ = −0.71 h) submerged protoperithecia 1 (sub-1), a GATA TF, is an early light-responsive gene, directly regulated by WCC (Chen et al. 2010; Smith et al. 2010; Wu et al. 2014), exhibiting a rhythmic expression with a morning pattern (Hurley et al. 2014). Functionally, it is able to dynamically interact with FF-7, and regulate the expression of several genes in light and darkness, also acting synergistically with WCC in light-responsive genes (Sancar et al. 2015a), connecting light responses and fungal development (Kasuga et al. 2005; Wang et al. 2019). It is differentially expressed in young versus old tissue (Tian et al. 2011), favored in sexual reproduction and down-regulated in asexual development (Wang et al. 2019). It is also subjected to metabolic regulation under different carbon sources, such as maltose and amylose in a col-26 dependent manner (Xiong et al. 2017).

NCU09252: (Δτ = −0.71 h) Encodes for a hypothetical C2H2 TF whose expression in darkness depends on SUB-1 and FF-7 at basal levels (Sancar et al. 2015a), as well as on the TF vad-5 (NCU06799) (Sun et al. 2012b). It has been described as clock-controlled and temperature-regulated (Nowrousian et al. 2003), and is member of the over-expressed genes of the starch-regulon in N. crassa, dependent on COL-26 (Xiong et al. 2017), and preferentially expressed in young versus old tissue (Tian et al. 2011).

NCU02413: (Δτ = −0.78 h) defined as response regulator 2 (rrg-2), is part of a two-component regulatory system for stress response in N. crassa (Catlett et al. 2003; Froehlich et al. 2005; Jones et al. 2007); it has been described as containing a truncated HSF DNA-binding domain and it is involved in ROS responses (Banno et al. 2007; Thompson et al. 2008). In addition, it exhibits a repressive effect on the secretion of lignocellulases, based on its requirement in the ER stress response (Fan et al. 2015). It is also downregulated during cell viability assays (Hutchison et al. 2009), being more expressed in mycelia than in aerial hyphae (Greenwald et al. 2010).

NCU10006: (Δτ = −0.83 h) Named as slow growth rate 30 (sgr-30) (Carrillo et al. 2017), is a gene coding for a C2H2 TF with an increased expression under high level of phosphate in the media (Gras et al. 2013), with no additional function or process associated with this gene. Complementation of the mutant back with the NCU10006 gene recovered WT period (Figure 4C).

NCU06213: (Δτ = −0.85 h) zinc-finger transcription factor 9 (znf-9). This gene has shown to display rhythmic expression, with an evening peak (Hurley et al. 2014).

NCU00499: (Δτ = −0.91 h) corresponds to all development altered 1 (ada-1), a bZIP, of which KO yields a strong growth phenotype (Carrillo et al. 2017). This TF has an increased expression in young versus old tissue, and mostly in aerial hyphae (Greenwald et al. 2010; Tian et al. 2011), and displays rhythmic expression (Hurley et al. 2014). The period phenotype observed in Δada-1 was reverted by complementation (Figure 4A).

NCU06140: (Δτ = −0.92 h) vegetative and sexual development (vsd-8) (Carrillo et al. 2017) encodes for a MYB TF. Under light exposure, it is up-regulated by SUB-1 and modulated by ADV-1 (Sancar et al. 2015a; Dekhang et al. 2017); in darkness, its basal levels are diminished in the absence of ff-7 and sub-1, being also a direct target of FF-7 (Sancar et al. 2015a). It exhibits metabolic regulation, having an increased expression under amylose in a Δcol-26 strain (Xiong et al. 2017), and is a downstream target of the MAP kinase signaling through the regulation by the TF PP-1 (Gras et al. 2013; Leeder et al. 2013).

NCU08848: (Δτ = −1.04 h) is a hypothetical protein with a zinc-ion binding domain. Its expression varies during conidial germination (Kasuga et al. 2005).

NCU01238: (Δτ = −1.17 h) is a PHD TF named as all developmental alteration 9 (ada-9). It is capable of interacting with the co-repressor RCO-1, a transcriptional regulator, devoid of a DNA binding domain, known to impact clock regulation and which absence leads to lengthened period (Olivares-Yanez et al. 2016). Complementation of ΔNCU01238 recovered WT period (Figure 4D).

NCU06145: (Δτ = −1.88 h) Encodes for a C2H2 TF named as really interesting gene 6 (ring-6). It is also a light down-regulated gene, bound by ADV-1 (Dekhang et al. 2017), with an expression that is affected by the presence of maltose (Xiong et al. 2017). This KO strain does not show the characteristic displays of apical branching when is exposed to cold shock (Watters et al. 2018). In our hands, ΔNCU06145 yielded the shortest period among the mutants identified in this screen.

This research was funded by ANID—Millennium Science Initiative Program—Millennium Institute for Integrative Biology (iBio ICN17_022), ANID/FONDECYT 1171151, and the International Research Scholar program of the Howard Hughes Medical Institute.

None declared.

Strains and plasmids are available upon request. Circadian data sets associated with the genetic screen are available at https://biodare2.ed.ac.uk/↗ (Zielinski et al. 2014) as “Neurospora TF Circadian Clock” and have been also uploaded as supplementary tables to figshare: https://gsajournals.figshare.com/articles/figure/Supplemental_Material_for_Mu_oz-Guzm_n_Caballero_and_Larrondo_2021/14036507?file=26476886↗.