Conditional gene expression reveals stage-specific functions of the unfolded protein response in the Ustilago maydis/maize pathosystem

Genomic localization and the presence of resistance marker cassettes affect the activity of promoters specifically expressed in planta

In previous studies, promoters of U. maydis mig (maize induced genes)-genes that are specifically expressed in planta were used for conditional gene expression during infection (Lo Presti et al., 2015b; Scherer et al., 2006; Wahl et al., 2010). In addition to the mig1 gene (Basse et al., 2000), mig genes include the mig2 gene cluster harboring five highly homologous genes, all of which are plant-specifically expressed but not involved in the virulence of U. maydis (Basse et al., 2002). The mig2-genes (mig2_1, mig2_2, mig2_3, mig2_4 and mig2_5) differ in their strength and temporal dynamics of expression. Thus, their promoters represent suitable targets for controlled and plant-specific expression/overexpression of a gene of interest.

To address the effect of overexpressing the spliced version of the cib1 mRNA (cib1^s in the following text), encoding the UPR regulator Cib1, during pathogenic development in planta, we integrated a P_{mig2_1}:cib1^s promoter fusion into the ip locus of the solopathogenic SG200 strain (Kämper et al., 2006). The ip or cbx locus is commonly used for integration of linear DNA into the U. maydis genome by homologous recombination, conferring resistance against carboxin (Brachmann, 2001). Since the virulence of strain SG200P_{mig2_1}:cib1^s was severely attenuated in plant infection experiments (Figure 1A), we investigated at which stage pathogenic development was blocked. Our analysis revealed the inability of SG200P_{mig2_1}:cib1^s to induce filamentous growth on charcoal containing solid media and on the leaf surface (Figure 1B), suggesting that pathogenic development is abrogated before plant penetration.

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Figure 1 The locus of integration and presence of a resistance cassette influence promoter activity.

(A) Plant infection assay with the solopathogenic strain SG200 and a derivative expression strain. Strains SG200 and SG200 P_{mig2_1}:cib1^s (ip locus) were inoculated into 8 day-old maize seedlings. Disease symptoms were rated 8 dpi and grouped into categories as shown in the figure legend. n = number of inoculated plants. Significance was calculated using the Mann-Whitney-test. ***P < 0.001 (B) Analysis of b-dependent filament formation on PD-CC solid media and on the leaf surface. Strains SG200 and SG200P_{mig2_1}:cib1^s (ip locus) were spotted on PD-CC solid media. Photographs were taken after 24 hours at 28°C. White fuzzy colonies indicate the formation of filaments. Fungal hyphae were stained 24 hours after inoculation with calcofluor to visualize the cells. Scale bar =10 µm. (C) qRT-PCR analysis of cib1^s gene expression when integrated in different loci and after removal of the resistance cassette. Primers specifically detecting the spliced cib1 transcript were used. RNA was isolated from exponentially growing U. maydis strains SG200, SG200 P_{mig2_1}:cib1^s (ip locus integration), FB1Δcib1Δmig2_1::Pcib1^s (mig2_1 locus, +Nat^R) and FB1Δcib1Δmig2_1::cib1^s (mig2_1 locus, -Nat^R). eIF2b was used for normalization. Expression values represent the mean of three biological replicates with two technical duplicates each. Error bars represent the SEM. Statistical significance was calculated using the students t test. *P value < 0.05, **P < 0.01, and ***P < 0.001. (D) qRT-PCR analysis of pit1 and pit2 gene expression when integrated in different loci and after removal of the resistance cassette. RNA was isolated from exponentially growing U. maydis strains SG200, SG200 P_pit1/2:pit2/1 (ip locus integration), SG200 P_pit1/2:pit2/1 (pit2/1 locus, +Nat^R), SG200 P_pit1/2:pit2/1 (pit2/1 locus, +Hyg^R) and P_pit1/2:pit2/1 (pit2/1 locus, -Hyg^R). eIF2b was used for normalization. Expression values represent the mean of three biological replicates with two technical duplicates each. Error bars represent the SEM. Statistical significance was calculated using the students t test. *P value < 0.05, **P < 0.01, and ***P < 0.001.

We have previously shown that constitutive expression of cib1^s inhibits the formation of infectious filaments (Heimel et al., 2013). Hence, we tested if integration of the P_mig2:1:cib1^s construct into the ip locus might result in increased expression levels of cib1^s during growth in axenic culture. Indeed, levels of cib1^s were significantly increased in strain SG200P_{mig2_1}:cib1^s, when compared to the SG200 control strain (Figure 1C). Since elevated cib1^s levels might either result from increased activity of the cib1 wild type (WT) ORF that is also present in SG200P_{mig2_1}:cib1^s, or from “leaky” P_{mig2_1}-driven expression, we used the Δcib1 background for further analyses. To study if this effect is specific for the ip locus, we generated U. maydis strain FB1Δcib1 Δmig2_1::cib1^s (mig2_1 locus (+Nat^R)) by replacing the mig2_1 ORF with the cib1^s gene. To exclude potential effects of the resistance cassette used for integration, the nourseothricin (Nat^R) resistance cassette was removed by FLP/FRT recombination (Khrunyk et al., 2010). This revealed that elevated cib1^s-levels indeed resulted from aberrant P_{mig2_1} activity and only strains in which the nourseothricin resistance marker was removed (mig2_1 locus (-Nat^R)) were devoid of any detectable cib1^s expression (Figure 1C). In summary, our data strongly suggest that both the genomic locus and the presence of a resistance marker contribute to the increased activity of the mig2_1 promoter in axenic culture.

To pinpoint if this effect is specific for cib1^s, we performed an analogous experiment with the pit1 and pit2 genes, which are divergently transcribed from the same promoter. In axenic culture, expression of both genes is barely detectable but highly induced during biotrophic growth in planta (Doehlemann et al., 2011; Lanver et al., 2018). We determined expression levels of both genes when (re-)integrated into U. maydis strain SG200Δpit1/2 (Hampel et al., 2016) into 1) the ip locus or the native pit1/2 locus, using either 2) nourseothricin (Nat^R) or 3) hygromycin resistance (Hyg^R) cassettes and 4) after removal of the resistance marker (Figure 1D). Surprisingly, transcript levels of both pit1 and pit2 were drastically increased when integrated into the ip locus (approximately 400-fold and 800-fold, respectively) in comparison to the SG200 (WT) control. Even when expressed from their native genomic locus, transcript levels of both genes were still significantly increased (pit1: 49-fold (Nat^R) and 10-fold (Hyg^R); pit2: 134-fold (Nat^R) and 13-fold (Hyg^R)) and only after removal of the resistance marker cassette (pit1/2 locus (-Hyg^R)) expression of pit1 and pit2 was similar to the SG200 (WT) control (Figure 1D). In summary, these data demonstrate that the locus of integration and the presence of resistance marker cassettes influence the activity of “conditional promoters”.

Overexpression of cib1^s does not disturb pathogenic development in planta

To set up a system that allows for proper functioning of conditional promoters we constructed plasmids harboring promoters of the mig1, mig2_1, mig2_2 or mig2_3 genes. 3’ sequences were followed by a SfiI restriction site for integration of the gene of interest, an FRT-Hyg^R or an FRT-Nat^R resistance marker cassette and a 1kb sequence harboring the 3’ UTR for recombination and integration into the genomic locus of respective mig genes. It is important to note that neither single nor the combined deletion of all mig genes negatively affected pathogenic development of U. maydis (Farfsing et al., 2005). To specifically increase cib1^s levels in planta and address the effect of UPR hyperactivation on pathogenic development, we expressed cib1^s under control of the mig1 or the mig2_1 promoter. To this end, the mig1 or mig2_1 ORFs were replaced by cib1^s, followed by the removal of the resistance marker cassette in the U. maydis strain FB1Δcib1 (Heimel et al., 2010b) (see Supplemental Figure 1 for an overview of the approach). We first checked for leaky cib1^s-expression by testing ER stress resistance and filamentous growth of the generated strains. When spotted on solid media supplemented with the ER stress-inducing drugs tunicamycin (TM) or dithiothreitol (DTT), the hyper-susceptibility of the FB1Δcib1 progenitor strain was not suppressed, suggesting that P_mig1 and P_{mig2_1} are not active in axenic culture (Figure 2A). Consistently, filamentous growth of respective strain combinations was not affected in mating assays on charcoal containing potato dextrose (PD) solid media (Figure 2B), thus confirming the absence of leaky cib1^s expression.

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Figure 2 Overexpression of cib1^s in planta does not affect pathogenicity of U. maydis.

(A) ER stress assay of strains FB1, FB1Δcib1, FB1Δcib1 Δmig1::cib1^s and FB1Δcib1 Δmig2_1::cib1^s. Serial 10-fold dilutions were spotted on YNBG solid medium supplemented with TM (1.0 μg/ml) or DTT (1 mM). Pictures were taken after 48 hours of incubation at 28 °C. (B) Mating assay with compatible mixtures of FB1, FB2, FB1Δcib1, FB2Δcib1, FB1Δcib1 Δmig1::cib1^s and FB1Δcib1 Δmig2_1::cib1^s. Mixtures were spotted on PD-CC solid media as shown in the figure. Photographs were taken after 24 hours at 28°C. White fuzzy colonies indicate the formation of filaments. (C) Plant infection assay with compatible mixtures of FB1 and FB2, FB1Δcib1, FB2Δcib1, FB1Δcib1Δmig1::cib1^s and FB1Δcib1 Δmig2_1::cib1^s. 8 day-old maize seedlings were co-inoculated with the indicated strain mixtures. Disease symptoms were rated 8 dpi and grouped into categories as shown in the figure legend. n = number of inoculated plants. Pictures of leaves were taken at 8 dpi and represent the most common infection symptom. Significance was calculated using the Mann-Whitney-test. ***P < 0.001.

Mixtures of mating compatible strains FB1, FB2, FB1Δcib1, FB2Δcib1, and the derivatives FB1Δcib1Δmig1::cib1^s and FB1Δcib1Δmig2_1::cib1^s were used for plant infection studies (Figure 2C). P_mig1- or P_{mig2_1}-mediated expression of cib1^s did not affect pathogenicity when strains were combined with the compatible FB2 WT strain. By contrast, when FB1Δcib1Δmig1::cib1^s or FB1Δcib1Δmig2_1::cib1^s were combined with the compatible FB2Δcib1 deletion mutant, virulence was strongly increased compared to the non-pathogenic FB1Δcib1 × FB2Δcib1 control, although not to WT (FB1 × FB2) levels. This result suggests that the mechanisms to prevent UPR hyperactivation in planta are robust and efficient in U. maydis thereby confirming the previous assumption that the UPR is specifically required during biotrophic development in planta (Heimel et al., 2010b; Heimel et al., 2013).

Establishment of a system for in planta-specific gene depletion

We next aimed to establish a gene expression system that would allow us to examine gene functions during defined developmental stages in planta by using promoters that are specifically repressed during plant infection. To this end, we screened the publicly available RNAseq data set published by Lanver et al., 2018 and identified a total of four candidate genes which are expressed during axenic growth and early steps of pathogenic development before plant penetration, but strongly repressed shortly after plant penetration (1-2 dpi; UMAG_00050, UMAG_05690 and UMAG_12184,), or at later stages during biotrophic growth in planta (UMAG_03597) (Lanver et al., 2018).

We focused on UMAG_12184 and UMAG_03597 for our current studies. Both genes are expressed in axenic culture and at early stages of pathogenic development, but are strongly repressed at 2 (UMAG_12184) or 4 dpi (UMAG_03597) (Figure 3A), during and shortly after U. maydis has established a compatible biotrophic interaction with its host plant. To test if these genes are involved in virulence, we deleted the genes in the haploid, solopathogenic U. maydis strain SG200. SG200 expresses a compatible bE1/bW2-heterodimer, and is thus capable of forming filaments and infecting its host plant, Z. mays, without the need of a compatible mating partner (Kämper et al., 2006). Both deletion strains were not affected in virulence (Figure 3B), demonstrating that these genes are dispensable for pathogenic development. In addition, neither ER or cell wall stress resistance, nor filamentous growth on charcoal containing PD solid media were strongly affected by either deletion, although filament formation was reduced in the UMAG_03597 deletion mutant (Supplemental Figure 2). However, since SG200ΔUMAG_03597 showed full virulence, this phenotype does not impair the ability of the fungus to cause disease. Based on these results, the respective promoters were regarded as suitable candidates to be used for conditional gene expression.

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Figure 3 Identification and testing of promoters for conditional gene expression.

(A) Fragments Per Kilobase Million (FPKMs) of the UMAG_12184 and UMAG_03597 genes up to 8 days post inoculation (dpi). 6 day-old maize seedlings were injected with a mixture of compatible haploid strains FB1 and FB2 and plant material was harvested at the indicated time points. Raw data was extracted from Lanver et al., 2018. (B) Plant infection assay with the solopathogenic strain SG200 and derivatives. SG200, SG200ΔUMAG_12184 and SG200ΔUMAG_03597 were inoculated into 8 day-old maize seedlings. Disease symptoms were rated 8 days after inoculation (dpi) and grouped into categories as shown in the figure legend. n = number of inoculated plants. Significance was calculated using the Mann-Whitney-test.

Cib1 is required throughout biotrophic development in planta

The bZIP transcription factor Cib1 is the central regulator of the UPR in U. maydis, and required for coordinating pathogenic development, efficient secretion of effectors and plant defense suppression (Heimel et al., 2013; Pinter et al., 2019). Pathogenic development of cib1 deletion strains is blocked immediately after plant penetration resulting in the complete absence of tumor formation (Heimel et al., 2013). To test if cib1 is only important directly after plant penetration (e.g., for release of the cell cycle block and establishment of the biotrophic interaction), or if it is also necessary at later stages of pathogenic development, we expressed cib1 under control of the UMAG_12184 and UMAG_03597 promoters (shut off at 2 and 4 dpi, respectively). To this end, we replaced UMAG_12184 or UMAG_03597 genes with the cib1 ORF in strain FB2Δcib1 (Heimel et al., 2010b), generating strains FB2Δcib1 ΔUMAG_12184::cib1 and FB2Δcib1 ΔUMAG_03597::cib1. Resistance cassettes used for selection of successful integration events were removed by FLP/FRT mediated recombination (Khrunyk et al., 2010).

The generated strains were tested for correct expression of cib1 under axenic conditions by ER stress assays using TM or DTT. Both mutants showed ER stress resistance similar to the WT (FB2) control, demonstrating that cib1 expression driven by either promoter is sufficient to suppress the ER-stress hypersensitivity of the FB2Δcib1 progenitor strain (Figure 4A) (Heimel et al., 2013). Additionally, when compatible mixtures of WT (FB1 × FB2), Δcib1 derivatives (FB1Δcib1 × FB2Δcib1) or derivatives expressing cib1 under control of conditional promoters (FB1Δcib1 × FB2Δcib1ΔUMAG_12184::cib1 or FB1Δcib1 × FB2Δcib1ΔUMAG_03597::cib1) were spotted on charcoal containing PD solid media (Figure 4B), all tested combinations developed white fuzzy colonies (Banuett and Herskowitz, 1989) indicating that mating is not affected in these strains.

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Figure 4 Conditional cib1 expression restores ER-stress resistance, but not pathogenicity.

(A) ER stress assay of strains FB2 (WT), FB2Δcib1, and derivatives. Serial 10-fold dilutions were spotted on YNBG solid medium supplemented with TM (1.0 μg/ml) or DTT (1.0 mM). Pictures were taken after 48 hours of incubation at 28 °C. (B) Mating assay with FB1, FB1Δcib1 and FB2Δcib1 ΔUMAG_12184::cib1 and FB2Δcib1 ΔUMAG_03597::cib1. Compatible mixtures of strains were spotted on potato dextrose solid media supplemented with 1% charcoal (PD-CC). Photographs were taken after 24 hours at 28°C. White fuzzy colonies indicate the formation of filaments. (C) Plant infection assay with FB1 and FB2, FB1Δcib1 and FB2, FB2Δcib1 ΔUMAG_12184::cib1 and FB2Δcib1 ΔUMAG_03597::cib1. 8 day-old maize seedlings were co-inoculated with compatible strain mixtures as indicated in the figure. Disease symptoms were rated 8 dpi and grouped into categories as shown in the figure legend. n = number of inoculated plants. Pictures of leaves were taken at 8 dpi and represent the most common infection symptom. Significance was calculated using the Mann-Whitney-test. ***P < 0.001

Next, we investigated the effect of plant-specific repression of cib1 in plant infection assays. When compatible mixtures of FB1Δcib1 × FB2 strains were used for inoculation of maize plants, symptom development was indistinguishable from the WT (FB1 × FB2) control (Figure 4C), demonstrating that a single functional copy of cib1 is sufficient for full virulence of the fungus. However, when cib1 was expressed under the control of P_{UMAG_12184} (FB1Δcib1 × FB2Δcib1ΔUMAG_12184::cib1), virulence was almost completely abolished and no tumors were formed, resembling the Δcib1 phenotype. By contrast, expression of cib1 under the control of P_{UMAG_03597} (FB1Δcib1 × FB2Δcib1ΔUMAG_03597::cib1) was sufficient to trigger anthocyanin production and the formation of small tumors. This indicates that prolonged expression of cib1 is sufficient to overcome the developmental block of Δcib1 strains, and initiate pathogenic growth in planta.

To visualize fungal growth in planta and assess at which step biotrophic development of the fungus stopped, infected leaves were harvested at 2, 4 and 6 dpi and stained with Chlorazol Black E (Figure 5A). Microscopic analysis revealed extensive proliferation and clamp cell formation when plants were inoculated with combinations of WT (FB1 × FB2) or FB1 × FB2Δcib1 strains. When cib1 was expressed under the control of P_{UMAG_12184} until 2 dpi (FB1Δcib1 × FB2Δcib1ΔUMAG_12184::cib1) infectious dikaryotic filaments penetrated the plant surface via appressoria at 2 dpi, but did not progress further in the plant at later stages (4 and 6 dpi). Consequently, clamp cell formation and extended fungal proliferation was not observed. By contrast, expression of cib1 under control of P_{UMAG_03597}:cib1 (FB2Δcib1ΔUMAG_03597::cib1) enabled the fungus to overcome the cell cycle block and induce proliferation, as reflected by hyphal branching and the formation of clamp cells at 4 dpi. However, the subsequent colonization of host tissue by fungal hyphae at 6 dpi appeared strongly reduced in comparison to the controls (FB1 × FB2 and FB1Δcib1 × FB2) (Figure 5A). This suggests that the reduced activity of P_{UMAG_03597} and the resulting decrease of cib1 levels at this stage prevents further progression of fungal hyphae inside the plant.

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Figure 5 Analysis of fungal morphology and plant defense response of conditional cib1 mutant strains.

(A) Fungal proliferation of compatible mixtures of FB1 and FB2, FB1Δcib1 and FB2, FB2Δcib1 ΔUMAG_12184::cib1or FB2Δcib1 ΔUMAG_03597::cib1investigated by Chlorazol Black E staining of infected leaf samples at 2, 4 and 6 dpi. Arrows point to clamp cells indicative of fungal proliferation in planta. Scale bar = 20 µm. (B) qRT-PCR analysis of PR1, PR3 and PR5 gene expression of infected maize leaves at 2, 4 and 6 dpi. Maize seedlings were inoculated with the indicated strains. GAPDH was used for normalization. Expression values represent the mean of two or three biological replicates with two technical duplicates each. Error bars represent the SEM. Statistical significance was calculated using the students t test. *P value < 0.05.

Previous studies revealed that plants inoculated with Δcib1 mutant strains show increased plant defense reactions as demonstrated by elevated expression of pathogenesis related (PR) gene expression at 2 dpi (Heimel et al., 2013). It is conceivable that this observation is connected to the requirement of a functional UPR for efficient secretion and processing of effectors (Lo Presti et al., 2015b; Hampel et al., 2016; Pinter et al., 2019). To investigate if Cib1 is also required for plant defense suppression at later stages, we determined expression levels of PR genes PR1, PR3 and PR5 at 2, 4 and 6 dpi in plants inoculated with strains conditionally expressing cib1. All three PR genes are markers for salicylic acid (SA)-related defense responses that are typically suppressed by biotrophic plant pathogens like U. maydis (Glazebrook, 2005). Consistent with the results obtained in infection studies, P_{UMAG_12184}-driven expression of cib1 resulted in increased expression of PR3 and PR5 genes at 2 dpi, whereas expression of PR1 was not induced (Figure 5B). By contrast, when cib1 was expressed under the control of P_{UMAG_03597}, expression of all three PR genes was induced at 6 dpi. These observations are consistent with the expected activity of the P_{UMAG_12184} and P_{UMAG_03597} promoters that are repressed at 2 and 4 dpi, respectively. Hence, our data indicate that cib1 expression under control of the promoter of UMAG_12184 is not sufficient to establish a compatible biotrophic interaction in planta leading to a block in pathogenic development. By contrast, when cib1 is expressed for an extended time (from promoter P_{UMAG_03597}), a compatible interaction appears to be established, allowing further proliferation. This suggests that cib1 is required for plant defense suppression not only at the onset (2 dpi), but also during later (4 and 6 dpi) stages of biotrophic development in planta.

Strains and Growth Conditions

Escherichia coli TOP10 strain was used for cloning and amplification of plasmid DNA. U. maydis cells were grown at 28°C in YEPS light medium (Tsukuda et al., 1988), complete medium (CM) (Holliday, 1974) or yeast nitrogen base (YNB) medium (Freitag et al., 2011; Mahlert et al., 2006). Mating assays were performed as described before (Brachmann et al., 2001). ER-stress assays were carried out on YNB solid media containing the indicated concentrations of DTT or TM (Sigma-Aldrich). Sensitivity to Calcofluor White or Congo red was tested by drop-assay on YNB solid media containing the indicated concentration of the respective compound. Filamentous growth assays were carried out using potato-dextrose (PD) media supplemented with 1% charcoal (PD-CC) (Holliday, 1974). Strains used in this study are listed in Supplemental Table 1.

DNA and RNA procedures

Molecular methods followed described protocols (Sambrook et al., 1989). For gene deletions, a PCR-based approach was used (Kämper, 2004). Isolation of genomic DNA from U. maydis and transformation procedures were performed according to Schulz et al., 1990. Homologous integration was performed using linearized plasmid DNA or PCR-amplified DNA. Integration was verified by Southern hybridization. Total RNA was extracted from exponentially growing cells in axenic culture using Trizol reagent according to the manufacturer’s instructions (Invitrogen, Karlsruhe, Germany). RNA integrity was checked by agarose-gel-electrophoresis. Residual DNA was removed from total RNA samples using the TURBO DNA-free™ Kit (Ambion, Darmstadt, Germany). cDNA was synthesized using the iScript™ cDNA Synthesis Kit (BioRad, Munich, Germany). Primers used in this study are listed in Supplemental Table 2.

Quantitative RT-PCR

qRT-PCR analysis was performed as described (Hampel et al., 2016). For all qRT-PCR experiments, three independent biological replicates and two technical replicates were analyzed using the MESA GREEN qPCR MasterMix plus for SYBR Assay with fluorescein (Eurogentech, Cologne, Germany). qRT-PCR was performed using the CFX Connect Real-Time PCR Detection System and analyzed with the CFX Manager Maestro Software (BioRad).

Plasmid construction

For gene deletions, a PCR-based approach and the SfiI insertion cassette system were used (Brachmann et al., 2004; Kämper, 2004). For construction of plasmids for conditional gene expression, 0.5-1 kb flanking regions of chosen genes (UMAG_03597, UMAG_12184, mig1, mig2_1) were PCR amplified from genomic DNA, adding a SfiI restriction site to the 5’ of the left border (LB) and a BamHI (for UMAG_12184, mig1 and mig2_1) or KpnI (for UMAG_03597) restriction site to the 3’end of the right border (RB). The gene of interest (GOI; cib1 or cib1^s) was PCR amplified from genomic DNA or from plasmid P_cib1:cib1^s, respectively, adding SfiI restriction sites to the 5’ and 3’end. The Hyg^R cassette was amplified from plasmid pUMa1442 adding a BamHI (for UMAG_12184) or KpnI restriction site (for UMAG_03597) to the 3’ end and a SfiI restriction site to the 5’ end. The resulting DNA fragments were ligated to obtain LB-GOI-Hyg^R-RB or LB-GOI-Nat^R-RB and integrated into the pCR2.1 TOPO vector (Invitrogen) or the pJet1.2 vector (ThermoFisher Scientific, Waltham, Massachusetts, USA) according to the manufacturer’s instructions to generate plasmids pCR2.1 P_{UMAG_12184}:cib1(NatR), pCR2.1 P_{UMAG_03597}:cib1(HygR), pJet1.2 P_{mig2_1}:cib1^s(NatR) and pJet1.2 P_mig1:cib1^s(NatR).

For construction of the P_{mig2_1}:cib1^s construct for ip locus integration, the vectors pMig2_1:clp1 and pRU11-cib1s were cut with NdeI and EcoRI. The resulting 2.0 kb cib1^s fragment of pRU11-cib1s (Heimel et al., 2013) and the 5.2 kb backbone of Mig2_1:clp1 were ligated to obtain plasmid P_{mig2_1}:cib1^s. Plasmids generated in this study are listed in Supplemental Table 3.

Plant Infections

The haploid, solopathogenic strain SG200 and its derivatives or FB1 and FB2 and their respective derivatives were grown to an OD600 of 0.6-0.8 in YEPS light medium, adjusted to an OD600 of 1.0 in water and mixed 1:1 with a compatible mating partner. The resulting suspension was used to inoculate 8-day-old maize seedlings of the variety Early Golden Bantam. Plants were grown in a CLF Plant Climatics GroBank (Wertingen, Germany) with a 14 h (28°C) day and 10 h (22 °C) night cycle. Symptoms were scored according to disease rating criteria reported by Kämper et al., 2006. Three independent clones were used for each plant infection experiment and the average scores for each symptom are shown in the respective diagrams. Photographs from infected leaves were taken and represent the most common infection symptoms for the respective mutant.

Chlorazole Black E staining and microscopy

Infected leaf tissue was harvested at 2, 4 and 6 dpi and kept in 100% ethanol until further processing. Chlorazole Black E staining was performed as described in Brachmann et al., 2001. Microscopic analysis was performed using an Axio Imager.M2 equipped with an AxioCam MRm camera (ZEISS, Jena, Germany). All images were processed using ImageJ.

Quantification of U. maydis gene expression in planta and PR gene expression

Infected leaf tissue was harvested at the indicated time points. Samples of five infected maize seedlings were pooled per replicate, frozen in liquid nitrogen and ground to powder by mortar and pestle according to Lanver et al., 2018. Total RNA was extracted using Trizol reagent (Invitrogen) and used for qRT-PCR analysis as described above. For expression analysis of U. maydis genes, eIF2b expression levels were used for normalization. Expression of PR1, PR3 and PR5 from Zea mays were determined and normalized to GAPDH expression levels.

Statistical Analysis

Statistical significance was calculated using Student’s t test. The statistical significance of plant infection phenotypes was calculated using the Mann-Whitney test as described previously (Freitag et al., 2011). Results were considered significant if the P value was <0.05.

Accession numbers

Sequence data from this article can be found in the National Center for Biotechnology Information database under the following accession numbers: UMAG_12184, XP_011388913.1; UMAG_03597, XP_011390022.1; cib1, UMAG_11782, XP_011390112.1; mig2_1, UMAG_06178, XP_011392548.1; mig1, UMAG_03223, XP_011389652.1; pit1, UMAG_01374, XP_011387263.1, pit2, UMAG_01375, XP_011387264.1; PR1 (Zm.15280.1), BM351351; PR3 (Zm.1085.1), BM339391; PR5 (Zm.6659.1), BM075306; GAPDH (NM001111943).