Variants in mismatch repair genes are overrepresented in clade A isolates with TR34<\/sub>\/L98H<\/h3>\nEukaryotic MMR consists of two major recognition complexes: MutS\u0251 (Msh2-Msh6), which recognises base\u2013base mismatches and small loops, and MutS\u03b2 (Msh2-Msh3), which recognises larger loops, with a bias towards deletion loops34<\/a><\/sup>. The MutL\u0251 protein complex (Pms1-Mlh1) directs downstream protein\u2013protein interactions, is required for daughter strand recognition, and has endonuclease activity. We screened 218 previously sequenced A. fumigatus<\/i> isolates20<\/a><\/sup> 65 originating from environmental and 153 from clinical sources in the United Kingdom (Supplemental dataset\u00a01<\/a>), of which 91 contain TR34<\/sub>\/L98H and 7 contain TR46<\/sub>\/Y121F\/T289A cyp51A<\/i> azole resistance mutations, for variants in MMR genes msh2<\/i> (AFUB_039320, AFUA_3G09850), msh3<\/i> (AFUB_090020, AFUA_7G04480), msh6<\/i> (AFUB_065410, AFUA_4G08300), pms1<\/i> (AFUB_029050, AFUA_2G13410) and mlh1<\/i> (AFUB_059270, AFUA_5G11700). In total, across all five genes, 212 non-synonymous point mutations were present relative to the Af<\/i>293 reference strain (Supplemental dataset\u00a01<\/a>). No frameshift, nonsense, or truncation mutations were observed in any of the isolates; thus, variants were expected to alter rather than abolish the activity of the MMR systems. Of these variants, non-synonymous mutations in msh2<\/i> (c.A2435G, p.E812G), msh6<\/i> (c.G698C, p.G233A) and pms1<\/i> (c.A1331G,p.E444G) were significantly associated with clade A (Fig.\u00a01a\u2013c<\/a>, msh2<\/i>: d.f.\u2009=\u20091, \u03c7<\/i>2<\/sup>\u2009=\u20098.88, P<\/i>\u2009=\u20090.0029, msh6<\/i>: d.f.\u2009=\u20091, \u03c7<\/i>2<\/sup>\u2009=\u2009141.64, P<\/i>\u2009<\u20092.2\u2009\u00d7\u200910\u221216<\/sup>, pms1<\/i>: d.f.\u2009=\u20091, \u03c7<\/i>2<\/sup>\u2009=\u200919.12, P<\/i>\u2009=\u20091.2\u2009\u00d7\u200910\u22125<\/sup>); however, only the G233A variant in msh6<\/i>, which occurs prior to the annotated N-terminal MutS domain responsible for mismatch recognition (Fig.\u00a01e<\/a>), was significantly associated with the presence of the azole resistance mutation TR34<\/sub>\/L98H in cyp51A<\/i> (d.f.\u2009=\u20091, \u03c7<\/i>2<\/sup>\u2009=\u2009122.27, P<\/i>\u2009<\u20092.2\u2009\u00d7\u200910\u221216<\/sup>). With the exception of the variants we have identified within clade A of A. fumigatus<\/i>, the G233 amino acid is perfectly conserved across over 150 million years of evolutionary history35<\/a><\/sup> within the Trichocomaceae<\/i> family (Fig.\u00a01f<\/a>). In total, 85% (105\/123) of clade A isolates contained the G233A variant allele of msh6<\/i>, while the variant is only present in 3% of isolates in clade B (3\/95). Of the 86 TR34<\/sub>\/L98H azole-resistant genotypes, 96.5% contained G233A, whereas. of the 7 isolates containing the TR46<\/sub>\/Y121F\/T289A resistance haplotype, only 4 harbour the msh6<\/i>-G233A variant (Fig.\u00a01d<\/a>). Notably, msh6<\/i> is encoded on chromosome 4 0.36\u2009Mbs away from the cyp51A<\/i> gene, however, previous population genomic studies have shown that genetic linkage can decay rapidly even within the resistant cluster21<\/a><\/sup>. The cyp51A<\/i> gene has a high average fixation index (F<\/i>ST<\/sub>) of 0.1127 (standard error (se)\u2009=\u20090.025) between isolates within clades A and B, implying population subdivision at this locus (average genome-wide F<\/i>ST<\/sub>\u2009=\u20090.086, se\u2009=\u20090.00026). In comparison, msh6<\/i> also has a high average F<\/i>ST<\/sub> of 0.1386 (se\u2009=\u20090.0422). A two-tailed t<\/i>-test assuming unequal variances between chromosome 4 (where both msh6<\/i> and cyp51A<\/i> are located) and the whole of the genome recovers a significant p<\/i>-value of 1.367e\u221267<\/sup>, suggesting multiple loci across chromosome 4 are associated with azole drug resistance. In addition, previous analysis shows this region has a significant association with itraconazole resistance20<\/a><\/sup> (treeWAS P<\/i>\u2009<\u20090.001). The association between G233A, clade A and TR34<\/sub>\/L98H was also evident in a global collection of isolates36<\/a><\/sup> (Fig.\u00a0S1<\/a>, Clade A: d.f.\u2009=\u20092, \u03c7<\/i>2<\/sup>\u2009=\u2009463.93, P<\/i>\u2009<\u20092.2\u2009\u00d7\u200910\u221216<\/sup>, TR34<\/sub>\/L98H: d.f.\u2009=\u20091, \u03c7<\/i>2<\/sup>\u2009=\u2009326.23, P<\/i>\u2009<\u20092.2\u2009\u00d7\u200910\u221216<\/sup>). Thus, the presence of the non-synonymous variant G233A in msh6<\/i>, which is an essential component of MutS\u0251, responsible for recognising base\u2013base mispairing, is strongly associated with the presence of azole resistance allele TR34<\/sub>\/L98H in clade A.<\/p>\n\nFig. 1: Variants in MMR are significantly overrepresented in clade A.<\/b><\/figcaption>\n![\"figure](\"https:\/\/media.springernature.com\/lw685\/springer-static\/image\/art%3A10.1038%2Fs41467-024-54568-5\/MediaObjects\/41467_2024_54568_Fig1_HTML.png\")
<\/source><\/picture><\/a><\/div>\n\nOccurrence of MMR variant alleles in clade A (red) and clade B (blue) for a<\/b> msh2<\/i> (E812G), b<\/b> msh6<\/i> (G233A) and c<\/b> pms1<\/i> (E444G). d<\/b> An unrooted maximum-likelihood phylogenetic tree using genome-wide SNPs relative to Af<\/i>293 of 218 WGS UK isolates20<\/a><\/sup>. The presence of variants in msh2<\/i>, msh6<\/i> and pms1<\/i> are highlighted in the black boxes, the presence of cyp51A<\/i> resistance variants and clade are coloured. e<\/b> Domain structures of Msh6 in A. fumigatus<\/i>, G233A variant labelled, labels show predicted domain positions in protein sequence. f<\/b> G233 locus homology across Trichocomaceae, alignments of 140 isolates spanning Aspergillus<\/i> ssp., 27 Talaromyces<\/i> and Paecilomyces<\/i>, and 122 Penicillium<\/i> Msh6 protein sequences. G233 highlighted in yellow, G233A variants are only present in Aspergillus fumigatus<\/i>. Cladogram shows the hierarchical clustering of Msh6 protein sequences. Source data are provided as a Source Data file.<\/p>\n<\/div>\n<\/div>\n<\/figure>\n<\/div>\nMutS and MutL null mutants result in a hypermutator phenotype<\/h3>\n
Given variant alleles in msh2<\/i>, msh6<\/i> and pms1<\/i> are significantly associated with clade A, and in the case of msh6<\/i> TR34<\/sub>\/L98H azole resistance genotypes, we first asked whether each of the three genes influence mutation rate. The three genes were independently deleted from the wild-type strain MFIG001, a laboratory strain that clusters within clade B37<\/a><\/sup>. The minimal inhibitory concentrations to voriconazole, a current antifungal used to treat A. fumigatus<\/i> infections, or the phase III clinical trial compound olorofim in the orotomide class38<\/a><\/sup> were not altered in the MMR defective strains relative to the parental MFIG001 strain (Fig.\u00a0S2<\/a>) indicating no direct effect of these alleles on azole or orotomide sensitivity. To measure mutation rates, a modified Luria\u2013Delbr\u00fcck fluctuation test39<\/a><\/sup> was implemented in which mononucleated spores from replicate cultures grown without selection were challenged with voriconazole to determine the probability that spores would spontaneously gain mutations that provide resistance (see the \u201cMethods\u201d section and Fig.\u00a02a<\/a>). The rate of spontaneous mutation in the wild-type MFIG001 strain to voriconazole was 2.78\u2009\u00d7\u200910\u221210<\/sup> (\u00b16.9\u2009\u00d7\u200910\u221211<\/sup>) per spore, similar to rates measured in other fungal species40<\/a>,41<\/a>,42<\/a><\/sup>. The modified Luria\u2013Delbr\u00fcck method was validated by treatments with the mutagen ethyl methanesulfonate during growth. The method detected the linear increase in mutation rate in MFIG001 to voriconazole with increasing concentrations of the mutagen (linear regression, R<\/i>2<\/sup>\u2009=\u20090.92, F<\/i>1,13<\/sub>\u2009=\u2009153, P<\/i>\u2009<\u20090.001, Fig.\u00a0S3<\/a>). Mutation rates for voriconazole resistance in the MMR deletion strains \u0394msh2<\/i>, \u0394msh6<\/i> and \u0394pms1<\/i> were ~85-, ~47 and ~173-fold higher than the parental wild-type strain (Fig.\u00a02b<\/a>, Two sample ML-test, MFIG001-\u0394msh2<\/i> T<\/i>\u2009=\u2009\u22123.83, P<\/i>\u2009<\u20090.001, MFIG001-\u0394msh6<\/i> T<\/i>\u2009=\u2009\u22123.82, P<\/i>\u2009<\u20090.001, MFIG001-\u0394pms1<\/i> T<\/i>\u2009=\u2009\u22124.12, P<\/i>\u2009<\u20090.0001). The MICs of spontaneous resistant mutants to voriconazole ranged from 4 to 32\u2009\u00b5g\/ml and were not dependent upon the genetic background (Kruskal\u2013Wallis, d.f.\u2009=\u20092, \u03c7<\/i>2<\/sup>\u2009=\u20094.25, P<\/i>\u2009=\u20090.119). Sequencing of the cyp51A<\/i> gene showed that 37% (10\/27) of the randomly selected spontaneously resistant isolates had the known voriconazole resistance allelic variant G448S (4\/8 MFIG001, 2\/7 \u0394msh2<\/i>, 3\/6 \u0394msh6<\/i>, 1\/6 \u0394pms1<\/i>), but these exclusively occurred within isolates with MICs\u2009\u2265\u200916\u2009\u00b5g\/ml. No mutations within cyp51A<\/i> were observed in the other resistant isolates and tandem repeats in the promotor of cyp51A<\/i> were never observed.<\/p>\n\nFig. 2: MutS and MutL null mutants significantly elevate mutation rates.<\/b><\/figcaption>\n![\"figure](\"https:\/\/media.springernature.com\/lw685\/springer-static\/image\/art%3A10.1038%2Fs41467-024-54568-5\/MediaObjects\/41467_2024_54568_Fig2_HTML.png\")
<\/source><\/picture><\/a><\/div>\n\na<\/b> Workflow of fluctuation tests to measure mutation rates in A. fumigatus<\/i>. Clonal isolates were cultured in the absence of antifungal selection to generate genetic diversity. Resistant mutants were selected on lethal concentrations of antifungals. Counts of resistant mutants were fitted to the Luria\u2013Delbr\u00fcck distribution to calculate the number of mutational events. b<\/b> Mutation rates for resistance to voriconazole for MMR-deficient mutants. Each point shows the calculated mutation rate from a single independent fluctuation test using 12 replicate cultures. Error bars show 95% confidence intervals, cross bars show the median mutation rate across fluctuation tests. Fold differences show median fold change in mutation rate from the parental MFIG001 strain. Triangle points represent mutation rates measured using independently constructed deletion mutants. c<\/b> Mutational frequency to olorofim resistance. d<\/b> Mutational frequency to itraconazole resistance. Each point shows the mutational frequency of an individual population (N<\/i>\u2009=\u20096). Error bars show SEM and cross bars show median mutational frequency. Fold differences show median fold change in mutation frequency from the parental MFIG001 strain. Source data are provided as a Source Data file.<\/p>\n<\/div>\n<\/div>\n<\/figure>\n<\/div>\n
Whole genome sequencing (WGS) of a further five randomly selected spontaneous voriconazole-resistant isolates from the wild-type MFIG001 strain revealed that only one mutational event was detectable in the entire genome of each resistant strain, all generating a G448S variant in cyp51A<\/i>. In contrast, sequencing of five resistant isolates derived from the msh2<\/i> null mutant and 6 from the msh6<\/i> and pms1<\/i> null mutants resulted in 28 (s.e. 4), 48 (s.e. 6), and 35 (s.e. 3.2) mutations (synonymous, non-synonymous and intergenic) per genome respectively (Fig.\u00a0S4a<\/a>), including canonical azole resistance mutations cyp51A<\/i> G448S (2\/5 \u0394msh2<\/i>, 3\/6 \u0394msh6<\/i>, 2\/6 \u0394pms1<\/i>) and HMG-CoA s in 2\/5 \u0394msh2<\/i> resistant mutants (Supplemental dataset\u00a02<\/a>). The deletion of msh2<\/i> resulted in higher frequencies of transversions relative to the deletion of msh6<\/i> or pms1<\/i> (Fig.\u00a0S4b<\/a>, Tukey multiple comparisons, \u0394msh6<\/i>-\u0394msh2<\/i> P<\/i>\u2009<\u20090.05, \u0394pms1<\/i>-\u0394msh2<\/i> P<\/i>\u2009<\u20090.05) mirroring previously published results showing that the loss of function of Msh2 results in a bias towards transversions43<\/a><\/sup>. The specific base substitutions showed that the bias towards transversions in the \u0394msh2<\/i> strain was due to an over-representation of C>A mutations (Fig.\u00a0S5a<\/a>), however there were no clear trinucleotide signatures that were associated with the transversions (Fig.\u00a0S5b<\/a>). The proportion of intergenic mutations also differed significantly between deletion mutants (ANOVA, F<\/i>2,13<\/sub>\u2009=\u200933.37, P<\/i>\u2009<\u20090.001, Fig.\u00a0S4c<\/a>). While the deletion of msh6<\/i> resulted in a similar ratio of intergenic mutations (\u0394msh6<\/i> 48.4% intergenic, s.e. 2.23) to the proportion of intergenic regions in the A. fumigatus<\/i> genome (48.76%), the \u0394pms1<\/i> and \u0394msh2<\/i> mutations were overrepresented by intergenic mutations (\u0394pms1<\/i> 76.2% intergenic, s.e. 2.45, \u0394msh2<\/i> 59.8% intergenic, s.e. 2.68) suggesting that the elevated mutation rates within these strains result in deleterious or lethal intragenic mutations which are purged by negative selection, and suggesting that a high fitness costs may be associated with the deletion of these genes. Mutations in msh2<\/i> have previously been associated with elevated mutation rates and the acquisition of antifungal resistance in Cryptococcus deuterogattii<\/i>30<\/a><\/sup> with an overrepresentation of mutation occurring with homopolymer nucleotide runs29<\/a><\/sup>. WGS data from the MMR null mutants showed that while single nucleotide variants did not occur within homopolymer runs (Fig.\u00a0S6a<\/a>), single base-pair indels were strongly associated with homopolymer nucleotide runs (Fig.\u00a0S6b<\/a>), with indel events occurring in homopolymer runs with a mean length of 9 base pairs. However, indels were not clearly associated with resistance, with no mutations showing parallelism between independent resistant mutants. Moreover, only 11% of indel events occurred within protein-coding regions, despite 49% of the A. fumigatus<\/i> A1163 genome being protein-coding.<\/p>\nThe frequency of resistance to another azole-class antifungal, itraconazole and the dihydroorotate dehydrogenase (DHODH) inhibitor olorofim showed similar significant increases in mutation rate in all three MMR deficient strains, with the largest increases in \u0394pms1<\/i> and the lowest increases in mutation rate in \u0394msh6<\/i> (pairwise Wilcoxon tests, P<\/i>\u2009<\u20090.05, Fig.\u00a02c, d<\/a>). The probability of resistance arising differed between antifungals (ANOVA, F<\/i>2,225<\/sub>\u2009=\u200942.49, P<\/i>\u2009<\u20090.001), with resistance arising between 2 and 15 times more frequently to itraconazole than olorofim or voriconazole (Tukey post hoc test, P<\/i>\u2009<\u20090.001), however, there was no difference between the frequency of resistant mutants to voriconazole and olorofim (Tukey post hoc test, P<\/i>\u2009=\u20090.828). Of the randomly selected olorofim spontaneous resistant mutants, 28\/28 had mutations in the pyrE<\/i> resistance hotspot G11944<\/a>,45<\/a><\/sup>, which provided high levels of olorofim resistance (>2\u2009\u00b5g\/ml). Together, these results show that msh<\/i>2 and pms1<\/i> null mutants, which abolish the activity of the MMR system, result in highly elevated mutation rates that facilitate the emergence of resistance. Moreover, although MutS\u03b2 recognition complexes remain functional when disrupting msh6<\/i>34<\/a><\/sup>, the loss of function of msh6<\/i> still results in significant increases in mutation rate.<\/p>\nDefective MMR results in significant reduction in fitness<\/h3>\n
Uncontrolled mutation can result in the accumulation of deleterious mutations, which decrease the fitness of hypermutator strains within stable environments46<\/a>,47<\/a><\/sup>. We therefore asked whether such costs were associated with the MMR defects in A. fumigatus<\/i>. Though we detected non-synonymous variants in msh2<\/i>, msh6<\/i> and pms1<\/i> no predicted loss of function mutations within the MMR genes were observed in the clinical or environmental isolates sequenced, suggesting that the complete loss of MMR could be associated with a significant cost in A. fumigatus<\/i>. However, no defect in radial growth rates was observed over 96\u2009h in the MMR deletion mutants relative to their parental strain in either nutrient-rich or minimal growth conditions (Fig.\u00a0S7<\/a>). Interestingly, morphological sectoring, likely to occur due to mutations during hyphal growth, occurred within the MMR mutants but not the parental strain. To determine whether fitness costs manifested over longer periods of growth, MMR-deficient mutants directly competed with the parental strain over five serial transfers on complete (rich) and minimal solid media (Fig.\u00a03<\/a>) in the absence of antifungal selection. The frequency of MMR deleted strains decreased through time and was dependent upon both the MMR mutant and the environment (Mixed effects linear model, Transfer:Media F<\/i>1<\/sub>\u2009=\u20097.8447, P<\/i>\u2009<\u20090.01, Transfer:Strain F<\/i>2<\/sub>\u2009=\u20097.8528, P<\/i>\u2009<\u20090.001, Fig.\u00a03a<\/a>). Growth medium had a significant effect on the relative fitness in all MMR deficient strains, with fitness being consistently lower in minimal media compared to rich media (Wilcoxon test, W<\/i>\u2009=\u2009233, P<\/i>\u2009<\u20090.05, Fig.\u00a03b<\/a>). Deletion of msh2<\/i> resulted in the highest overall cost relative to the parental strain, displaying 30% cost in rich media (T<\/i>.test, T<\/i>5<\/sub>\u2009=\u2009\u221213.6, P<\/i>\u2009<\u20090.001, Holm adjusted for multiple testing) and a 75% cost in minimal media (T<\/i>.test, T<\/i>5<\/sub>\u2009=\u2009\u221230, P<\/i>\u2009<\u20090.001, Holm adjusted for multiple testing, Fig.\u00a0
![\"figure](\"https:\/\/media.springernature.com\/lw685\/springer-static\/image\/art%3A10.1038%2Fs41467-024-54568-5\/MediaObjects\/41467_2024_54568_Fig1_HTML.png?as=webp\")
<\/source><\/picture><\/a><\/div>\nOccurrence of MMR variant alleles in clade A (red) and clade B (blue) for a<\/b> msh2<\/i> (E812G), b<\/b> msh6<\/i> (G233A) and c<\/b> pms1<\/i> (E444G). d<\/b> An unrooted maximum-likelihood phylogenetic tree using genome-wide SNPs relative to Af<\/i>293 of 218 WGS UK isolates20<\/a><\/sup>. The presence of variants in msh2<\/i>, msh6<\/i> and pms1<\/i> are highlighted in the black boxes, the presence of cyp51A<\/i> resistance variants and clade are coloured. e<\/b> Domain structures of Msh6 in A. fumigatus<\/i>, G233A variant labelled, labels show predicted domain positions in protein sequence. f<\/b> G233 locus homology across Trichocomaceae, alignments of 140 isolates spanning Aspergillus<\/i> ssp., 27 Talaromyces<\/i> and Paecilomyces<\/i>, and 122 Penicillium<\/i> Msh6 protein sequences. G233 highlighted in yellow, G233A variants are only present in Aspergillus fumigatus<\/i>. Cladogram shows the hierarchical clustering of Msh6 protein sequences. Source data are provided as a Source Data file.<\/p>\n<\/div>\n<\/div>\n<\/figure>\n<\/div>\n Given variant alleles in msh2<\/i>, msh6<\/i> and pms1<\/i> are significantly associated with clade A, and in the case of msh6<\/i> TR34<\/sub>\/L98H azole resistance genotypes, we first asked whether each of the three genes influence mutation rate. The three genes were independently deleted from the wild-type strain MFIG001, a laboratory strain that clusters within clade B37<\/a><\/sup>. The minimal inhibitory concentrations to voriconazole, a current antifungal used to treat A. fumigatus<\/i> infections, or the phase III clinical trial compound olorofim in the orotomide class38<\/a><\/sup> were not altered in the MMR defective strains relative to the parental MFIG001 strain (Fig.\u00a0S2<\/a>) indicating no direct effect of these alleles on azole or orotomide sensitivity. To measure mutation rates, a modified Luria\u2013Delbr\u00fcck fluctuation test39<\/a><\/sup> was implemented in which mononucleated spores from replicate cultures grown without selection were challenged with voriconazole to determine the probability that spores would spontaneously gain mutations that provide resistance (see the \u201cMethods\u201d section and Fig.\u00a02a<\/a>). The rate of spontaneous mutation in the wild-type MFIG001 strain to voriconazole was 2.78\u2009\u00d7\u200910\u221210<\/sup> (\u00b16.9\u2009\u00d7\u200910\u221211<\/sup>) per spore, similar to rates measured in other fungal species40<\/a>,41<\/a>,42<\/a><\/sup>. The modified Luria\u2013Delbr\u00fcck method was validated by treatments with the mutagen ethyl methanesulfonate during growth. The method detected the linear increase in mutation rate in MFIG001 to voriconazole with increasing concentrations of the mutagen (linear regression, R<\/i>2<\/sup>\u2009=\u20090.92, F<\/i>1,13<\/sub>\u2009=\u2009153, P<\/i>\u2009<\u20090.001, Fig.\u00a0S3<\/a>). Mutation rates for voriconazole resistance in the MMR deletion strains \u0394msh2<\/i>, \u0394msh6<\/i> and \u0394pms1<\/i> were ~85-, ~47 and ~173-fold higher than the parental wild-type strain (Fig.\u00a02b<\/a>, Two sample ML-test, MFIG001-\u0394msh2<\/i> T<\/i>\u2009=\u2009\u22123.83, P<\/i>\u2009<\u20090.001, MFIG001-\u0394msh6<\/i> T<\/i>\u2009=\u2009\u22123.82, P<\/i>\u2009<\u20090.001, MFIG001-\u0394pms1<\/i> T<\/i>\u2009=\u2009\u22124.12, P<\/i>\u2009<\u20090.0001). The MICs of spontaneous resistant mutants to voriconazole ranged from 4 to 32\u2009\u00b5g\/ml and were not dependent upon the genetic background (Kruskal\u2013Wallis, d.f.\u2009=\u20092, \u03c7<\/i>2<\/sup>\u2009=\u20094.25, P<\/i>\u2009=\u20090.119). Sequencing of the cyp51A<\/i> gene showed that 37% (10\/27) of the randomly selected spontaneously resistant isolates had the known voriconazole resistance allelic variant G448S (4\/8 MFIG001, 2\/7 \u0394msh2<\/i>, 3\/6 \u0394msh6<\/i>, 1\/6 \u0394pms1<\/i>), but these exclusively occurred within isolates with MICs\u2009\u2265\u200916\u2009\u00b5g\/ml. No mutations within cyp51A<\/i> were observed in the other resistant isolates and tandem repeats in the promotor of cyp51A<\/i> were never observed.<\/p>\n a<\/b> Workflow of fluctuation tests to measure mutation rates in A. fumigatus<\/i>. Clonal isolates were cultured in the absence of antifungal selection to generate genetic diversity. Resistant mutants were selected on lethal concentrations of antifungals. Counts of resistant mutants were fitted to the Luria\u2013Delbr\u00fcck distribution to calculate the number of mutational events. b<\/b> Mutation rates for resistance to voriconazole for MMR-deficient mutants. Each point shows the calculated mutation rate from a single independent fluctuation test using 12 replicate cultures. Error bars show 95% confidence intervals, cross bars show the median mutation rate across fluctuation tests. Fold differences show median fold change in mutation rate from the parental MFIG001 strain. Triangle points represent mutation rates measured using independently constructed deletion mutants. c<\/b> Mutational frequency to olorofim resistance. d<\/b> Mutational frequency to itraconazole resistance. Each point shows the mutational frequency of an individual population (N<\/i>\u2009=\u20096). Error bars show SEM and cross bars show median mutational frequency. Fold differences show median fold change in mutation frequency from the parental MFIG001 strain. Source data are provided as a Source Data file.<\/p>\n<\/div>\n<\/div>\n<\/figure>\n<\/div>\n Whole genome sequencing (WGS) of a further five randomly selected spontaneous voriconazole-resistant isolates from the wild-type MFIG001 strain revealed that only one mutational event was detectable in the entire genome of each resistant strain, all generating a G448S variant in cyp51A<\/i>. In contrast, sequencing of five resistant isolates derived from the msh2<\/i> null mutant and 6 from the msh6<\/i> and pms1<\/i> null mutants resulted in 28 (s.e. 4), 48 (s.e. 6), and 35 (s.e. 3.2) mutations (synonymous, non-synonymous and intergenic) per genome respectively (Fig.\u00a0S4a<\/a>), including canonical azole resistance mutations cyp51A<\/i> G448S (2\/5 \u0394msh2<\/i>, 3\/6 \u0394msh6<\/i>, 2\/6 \u0394pms1<\/i>) and HMG-CoA s in 2\/5 \u0394msh2<\/i> resistant mutants (Supplemental dataset\u00a02<\/a>). The deletion of msh2<\/i> resulted in higher frequencies of transversions relative to the deletion of msh6<\/i> or pms1<\/i> (Fig.\u00a0S4b<\/a>, Tukey multiple comparisons, \u0394msh6<\/i>-\u0394msh2<\/i> P<\/i>\u2009<\u20090.05, \u0394pms1<\/i>-\u0394msh2<\/i> P<\/i>\u2009<\u20090.05) mirroring previously published results showing that the loss of function of Msh2 results in a bias towards transversions43<\/a><\/sup>. The specific base substitutions showed that the bias towards transversions in the \u0394msh2<\/i> strain was due to an over-representation of C>A mutations (Fig.\u00a0S5a<\/a>), however there were no clear trinucleotide signatures that were associated with the transversions (Fig.\u00a0S5b<\/a>). The proportion of intergenic mutations also differed significantly between deletion mutants (ANOVA, F<\/i>2,13<\/sub>\u2009=\u200933.37, P<\/i>\u2009<\u20090.001, Fig.\u00a0S4c<\/a>). While the deletion of msh6<\/i> resulted in a similar ratio of intergenic mutations (\u0394msh6<\/i> 48.4% intergenic, s.e. 2.23) to the proportion of intergenic regions in the A. fumigatus<\/i> genome (48.76%), the \u0394pms1<\/i> and \u0394msh2<\/i> mutations were overrepresented by intergenic mutations (\u0394pms1<\/i> 76.2% intergenic, s.e. 2.45, \u0394msh2<\/i> 59.8% intergenic, s.e. 2.68) suggesting that the elevated mutation rates within these strains result in deleterious or lethal intragenic mutations which are purged by negative selection, and suggesting that a high fitness costs may be associated with the deletion of these genes. Mutations in msh2<\/i> have previously been associated with elevated mutation rates and the acquisition of antifungal resistance in Cryptococcus deuterogattii<\/i>30<\/a><\/sup> with an overrepresentation of mutation occurring with homopolymer nucleotide runs29<\/a><\/sup>. WGS data from the MMR null mutants showed that while single nucleotide variants did not occur within homopolymer runs (Fig.\u00a0S6a<\/a>), single base-pair indels were strongly associated with homopolymer nucleotide runs (Fig.\u00a0S6b<\/a>), with indel events occurring in homopolymer runs with a mean length of 9 base pairs. However, indels were not clearly associated with resistance, with no mutations showing parallelism between independent resistant mutants. Moreover, only 11% of indel events occurred within protein-coding regions, despite 49% of the A. fumigatus<\/i> A1163 genome being protein-coding.<\/p>\n The frequency of resistance to another azole-class antifungal, itraconazole and the dihydroorotate dehydrogenase (DHODH) inhibitor olorofim showed similar significant increases in mutation rate in all three MMR deficient strains, with the largest increases in \u0394pms1<\/i> and the lowest increases in mutation rate in \u0394msh6<\/i> (pairwise Wilcoxon tests, P<\/i>\u2009<\u20090.05, Fig.\u00a02c, d<\/a>). The probability of resistance arising differed between antifungals (ANOVA, F<\/i>2,225<\/sub>\u2009=\u200942.49, P<\/i>\u2009<\u20090.001), with resistance arising between 2 and 15 times more frequently to itraconazole than olorofim or voriconazole (Tukey post hoc test, P<\/i>\u2009<\u20090.001), however, there was no difference between the frequency of resistant mutants to voriconazole and olorofim (Tukey post hoc test, P<\/i>\u2009=\u20090.828). Of the randomly selected olorofim spontaneous resistant mutants, 28\/28 had mutations in the pyrE<\/i> resistance hotspot G11944<\/a>,45<\/a><\/sup>, which provided high levels of olorofim resistance (>2\u2009\u00b5g\/ml). Together, these results show that msh<\/i>2 and pms1<\/i> null mutants, which abolish the activity of the MMR system, result in highly elevated mutation rates that facilitate the emergence of resistance. Moreover, although MutS\u03b2 recognition complexes remain functional when disrupting msh6<\/i>34<\/a><\/sup>, the loss of function of msh6<\/i> still results in significant increases in mutation rate.<\/p>\n Uncontrolled mutation can result in the accumulation of deleterious mutations, which decrease the fitness of hypermutator strains within stable environments46<\/a>,47<\/a><\/sup>. We therefore asked whether such costs were associated with the MMR defects in A. fumigatus<\/i>. Though we detected non-synonymous variants in msh2<\/i>, msh6<\/i> and pms1<\/i> no predicted loss of function mutations within the MMR genes were observed in the clinical or environmental isolates sequenced, suggesting that the complete loss of MMR could be associated with a significant cost in A. fumigatus<\/i>. However, no defect in radial growth rates was observed over 96\u2009h in the MMR deletion mutants relative to their parental strain in either nutrient-rich or minimal growth conditions (Fig.\u00a0S7<\/a>). Interestingly, morphological sectoring, likely to occur due to mutations during hyphal growth, occurred within the MMR mutants but not the parental strain. To determine whether fitness costs manifested over longer periods of growth, MMR-deficient mutants directly competed with the parental strain over five serial transfers on complete (rich) and minimal solid media (Fig.\u00a03<\/a>) in the absence of antifungal selection. The frequency of MMR deleted strains decreased through time and was dependent upon both the MMR mutant and the environment (Mixed effects linear model, Transfer:Media F<\/i>1<\/sub>\u2009=\u20097.8447, P<\/i>\u2009<\u20090.01, Transfer:Strain F<\/i>2<\/sub>\u2009=\u20097.8528, P<\/i>\u2009<\u20090.001, Fig.\u00a03a<\/a>). Growth medium had a significant effect on the relative fitness in all MMR deficient strains, with fitness being consistently lower in minimal media compared to rich media (Wilcoxon test, W<\/i>\u2009=\u2009233, P<\/i>\u2009<\u20090.05, Fig.\u00a03b<\/a>). Deletion of msh2<\/i> resulted in the highest overall cost relative to the parental strain, displaying 30% cost in rich media (T<\/i>.test, T<\/i>5<\/sub>\u2009=\u2009\u221213.6, P<\/i>\u2009<\u20090.001, Holm adjusted for multiple testing) and a 75% cost in minimal media (T<\/i>.test, T<\/i>5<\/sub>\u2009=\u2009\u221230, P<\/i>\u2009<\u20090.001, Holm adjusted for multiple testing, Fig.\u00a0MutS and MutL null mutants result in a hypermutator phenotype<\/h3>\n
![\"figure](\"https:\/\/media.springernature.com\/lw685\/springer-static\/image\/art%3A10.1038%2Fs41467-024-54568-5\/MediaObjects\/41467_2024_54568_Fig2_HTML.png?as=webp\")
<\/source><\/picture><\/a><\/div>\nDefective MMR results in significant reduction in fitness<\/h3>\n