Abstract
Embryonic aneuploidy from mis-segregation of chromosomes during meiosis causes pregnancy loss. Proper disjunction of homologous chromosomes requires the mismatch repair (MMR) genes MLH1 and MLH3, essential in mice for fertility. Variants in these genes can increase colorectal cancer risk, yet the reproductive impacts are unclear. To determine if MLH1/3 single nucleotide polymorphisms (SNPs) in human populations could cause reproductive abnormalities, we use computational predictions, yeast two-hybrid assays, and MMR and recombination assays in yeast, selecting nine MLH1 and MLH3 variants to model in mice via genome editing. We identify seven alleles causing reproductive defects in mice including female subfertility and male infertility. Remarkably, in females these alleles cause age-dependent decreases in litter size and increased embryo resorption, likely a consequence of fewer chiasmata that increase univalents at meiotic metaphase I. Our data suggest that hypomorphic alleles of meiotic recombination genes can predispose females to increased incidence of pregnancy loss from gamete aneuploidy.
Similar content being viewed by others
Introduction
The essential function of meiotic recombination is to drive pairing of homologous chromosomes, ensuring proper disjunction of homologs to daughter cells at the first meiotic division. Failure of a chromosome pair to undergo at least one crossover per chromosome arm predisposes to formation of aneuploid gametes that, if fertilized, leads to pregnancy loss. Approximately 50–70% of early miscarriages are associated with chromosome abnormalities, with most having aneuploidy, primarily trisomies1,2. It is well recognized that the incidence of aneuploidy in abortuses increases with female age and has been hypothesized to be attributable to non-genetic factors such as decay of chromosome cohesion3,4. However, there are indications that parental genetic factors can predispose to generation of aneuploid conceptuses, and may contribute to cases of recurrent pregnancy loss (RPL; defined as three or more consecutive miscarriages)5,6. For example, much attention has focused on the potential effects of variants/mutations in the synaptonemal complex protein SYCP3 in human RPL7,8, because SYCP3-deficient female mice experience loss of embryos resulting from aneuploid oocytes9. However, it is unclear whether, or to what extent, mutations or deleterious variants in SYCP3 or other genes cause miscarriages or RPL.
Chromosome mis-segregation during meiosis can occur at Meiosis I (MI) or Meiosis II (MII), though a lack of recombination on extra/missing chromosomes has been associated with inefficient crossover maturation before MI10. The resulting gametes, if fertilized, can lead to aneuploid embryos that are almost universally incompatible with viability, thus causing miscarriage. Several genes are required for crossover (CO) recombination (and thus fertility) in mice, including the mismatch repair (MMR) proteins MLH1 and MLH3, which form a heterodimeric endonuclease required to resolve double Holliday junction recombination intermediates11,12,13,14,15,16,17,18,19. Null alleles of Mlh1 or Mlh3 cause meiotic arrest and sterility in mice because they are needed for ~90% of all crossovers (those known as interference-dependent Class I crossovers)11,20,21,22,23,24,25. The absence of COs leads to univalent chromosomes that fail to align properly while attached to microtubules at the metaphase plate, thus triggering the spindle assembly checkpoint (SAC) and blocking anaphase progression26. However, recombination defects affecting bivalent formation of only one or a few chromosome pairs is inefficient at triggering the SAC, allowing such gametes to survive and thus predisposing to aneuploidy27,28,29,30.
We hypothesized that human population variants in MLH1/3 might cause defects in chromosome segregation during MI or MII, leading to infertility, miscarriage, and/or developmental defects. To test this and gain a comprehensive understanding of the functional impact of such variants, we systematically evaluated human missense single nucleotide polymorphisms (SNPs) curated in the ExAC and (subsequently) gnomAD databases31,32. Minor alleles predicted to be deleterious in silico by various algorithms, and which deviated from normal function in biochemical assays or genetic assays in yeast, were selected for modeling in mice. Most of the mutant mouse models were fertile but exhibited crossing over defects that led to age-related decreases in female fecundity, elevated aneuploidy, and consequent increases in pregnancy loss. These results have implications especially for older couples, or those experiencing RPL, who may be at increased risk for having conceptuses or children with trisomies as a result of bearing variants in these recombination genes.
Results
Strategy and selection of candidate pathogenic MUTL homolog variants
To test the possibility that segregating infertility variants of MLH1 or MLH3 exist in human populations, we identified potentially pathogenic missense SNPs in these genes using methods and criteria outlined in Fig. 1a, including: (1) functional prediction algorithms scoring the variant as deleterious; (2) has an allele frequency (AF) within the range of 0.02 to 2% in any gnomAD-listed population; (3) disruptive to binary protein-protein-interactions in yeast two-hybrid (Y2H) assay; or (4) causes an MMR and/or recombination phenotype in baker’s yeast (S. cerevisiae) when the orthologous amino acid is altered. These steps were used to prioritize a subset of MLH1 and MLH3 variants for subsequent modeling in mice. In particular, steps 3 and 4 were explored as a means to potentially improve the success rate of identifying functionally consequential infertility variants for mouse modeling, compared to our previous studies that utilized only computational predictions33,34.
Disease-associated mutations in MLH1 often function molecularly by disrupting corresponding protein-protein interactions35,36. As such, we searched for all potentially functional MLH1 missense variants that matched our defined 0.02% < AF < 2% criteria range. These MLH1 variants were introduced into Y2H bait and prey vectors, then tested for whether they disrupted known interactions with 8 proteins that were available as full-length clones in the hORFeome v8.1 or the Mammalian Genome Collection (MGC). Overall, 13 MLH1 variants were tested by Y2H across 68 total SNP-interaction pairs. We then further filtered these variants for SNPs that scored as deleterious across multiple functional prediction algorithms. This resulted in five MLH1 predicted deleterious variants that disrupted 27 out of 37 (73%) of their corresponding SNP-interactions pairs (Table 1; Supplementary Data 1).
For MLH3, we modeled eleven human SNPs in yeast by constructing strains bearing the cognate amino acid (AA) changes in the endogenous MLH3 gene, then measuring MMR using a lys2 frameshift reversion assay37. Most of the AAs are located in conserved endonuclease and ATP binding domains (Table 2; Supplementary Fig. 1). To measure meiotic crossing over, these strains were mated to an mlh3Δ strain so that the diploids contained fluorescence markers separated by ~20 cM on chromosome VIII38. The diploids were sporulated to identify, in complete tetrads, presence or absence of crossovers (Supplementary Fig. 2). Three of the MLH3 SNPs (rs781779034, rs138006166 and rs781739661) had null-like or intermediate phenotypes for MMR, and null-like crossing over defects (Tables 1 and 2; Supplementary Table 1). Additionally, all three were classified as deleterious by functional prediction algorithms (Table 1). Overall, nine of the eleven alleles modeled in yeast conferred null-like or intermediate phenotypes in either or both tested metrics (Table 2).
Mouse modeling of nsSNPs and reproductive phenotypes
Based on the bioinformatic, biochemical and genetic data described above, we initially modeled five MLH1 and three MLH3 nsSNPs in mice via CRISPR/Cas9-mediated genome-editing (Table 1, Supplementary Fig. 2). These eight mutant mouse lines with ‘humanized’ alleles were phenotyped in several ways, beginning with male reproductive parameters. Two mutants had obvious phenotypes. Mlh3R1230H/R1230H males exhibited a ~4 fold reduction in testes size, and an absence of epididymal sperm (Fig. 1b, c). Consistent with the absence of sperm, histological sections of mutant testes revealed a lack of haploid spermatids, and the most advanced spermatocytes appeared to be at meiotic metaphase I or anaphase I (Fig. 1d), reminiscent of null animals for both Mlh1 and Mlh311,14,21. The phenotypes of Mlh1K618T/K618T males were less severe; their testes weighed 80% of WT, and there were ~35% fewer epididymal sperm (Fig. 1b, c). Histology also revealed a substantial number of spermatocytes arrested in metaphase I (Fig. 1d). Fertility trials of homozygous mutant males confirmed that Mlh3R1230H/R1230H males were completely sterile, whereas Mlh1K618T/K618T males were subfertile, producing 40% fewer pups over a duration 10 months of fertility trials (Fig. 1h). In contrast to Mlh1K618T and Mlh3R1230H, there were no obvious reproductive defects in males homozygous for the remaining 6 alleles that were modeled. Sperm counts were normal and litter sizes sired by these mutant males were not lower than controls (Fig. 1c, h). Testis weights were also normal, though modestly lower in Mlh3R93G/R93G homozygotes.
Lack of COs between homologs at meiotic metaphase I in Mlh-null mutants causes a failure of proper alignment at the metaphase plate, leading to anaphase block11,20,21,22,23,24,25. Despite the absence of reproductive defects in the remaining 6 mutant alleles, testis sections revealed abnormal pyknotic-appearing metaphase spermatocytes with disorganized metaphase plates and misaligned chromosomes (Fig. 1d; explored in more detail below). This was more directly assessed by TUNEL staining of seminiferous tubule cross-sections positive for the metaphase marker phospho-histone H3 (Ser10)39 which showed marked increases in apoptotic cells compared to WT (Fig. 1e–g). Confocal analysis readily revealed misaligned chromosomes at the metaphase plates of MI spermatocytes in the less severe mutants (Supplementary Fig. 3). These data suggested that the allelic variants caused severe-to-subtle defects in chromosome alignment at the metaphase plate at MI, and/or unrepaired recombination intermediates, leading to apoptosis.
When this work began, the two K618 variants in MLH1 (K618E and K618T) were (and are still) present in dbSNP as rs35001569 and rs63750449, respectively. These amino acid changes are caused by AAG>GAG and AAG>ACG nucleotide changes, respectively. However, after those mouse models were created and phenotype analyses were performed (including female data presented below), the gnomAD database (v2.1) was revised to indicate that these two variants co-occur (are in phase) nearly perfectly (963/973 and 963/971 occurrences, respectively), encoding a K618A AA change as a result. This explains why both variants are annotated to occur at essentially identical frequencies in populations (Table 1). We therefore generated an Mlh1K618A allele and found that both male and female homozygotes are fertile. Thus, this allele is either a neutral variant or has subtle defects that may be revealed with more comprehensive studies such as those described below.
Meiotic recombination defects in mutants
To determine if defects in crossing-over might underlie the metaphase I aberrations, we immunolabeled pachytene spermatocyte chromosome spreads to quantify MLH1 foci, a proxy for “Type 1” crossovers (COs), which are subject to interference and constitute ~90% of all CO40. In the two most severe mutants Mlh3R1230H/R1230H and Mlh1K618T/K618T, chromosomes exhibited normal homolog pairing and synapsis as reported for knockouts11,14,21, but had markedly reduced MLH1 foci (Fig. 2a, b; 2.9 and 7.7 per cell, respectively, vs. 21.4 foci in WT). Such a severe reduction in ‘obligate’ class I COs might either trigger apoptosis at metaphase I, or prevent zygotic progression after fertilization21,26.
The Mlh1V716M and Mlh1E268G mutants, though less affected, also had significantly fewer total MLH1 foci per spermatocyte on average. Since even small reductions in CO recombination might lead to some chromosomes lacking an obligate CO (chiasma), we quantified MLH1 focus-deficient chromosomes. Five of the seven mutants examined exhibited a significant increase in MLH1 focus-deficient chromosomes (Fig. 2c). This suggests an increase in spermatocytes bearing one or more achiasmate chromosomes. Consistent with this hypothesis, Mlh1K618T/K618T spermatocytes exhibited an average of ~2 fewer metaphase I chiasmata than controls, leading to a significant decrease in bivalent chromosomes (increase in univalents; Fig. 2d, e).
Age-dependent decline in reproductive capacity of Mlh1/3 mutant females associated with increased oocyte aneuploidy
In Mlh1 or Mlh3 knockouts, females are sterile because their oocytes cannot form a normal spindle and chromosomes do not properly align to the meiotic metaphase I plate30,41. This near complete absence of bi-oriented, CO-tethered bivalents at diakinesis can activate quality control mechanisms, namely the Spindle Assembly Checkpoint (SAC), causing meiotic arrest26,28. The SAC appears to be more stringent in spermatocytes than oocytes27,29,42,43, thus eliminating defective spermatocytes whereas oocytes attempt to complete gametogenesis. To test potential impacts on fertility of females bearing the humanized Mlh1/3 alleles, we evaluated fecundity of the Mlh1E268G, Mlh1V326A, Mlh1K618E, Mlh1K618T, and Mlh1V716M mutants. Interestingly, litter sizes of all mutant females declined over time compared to controls (Fig. 3a) and overall, they had only ~ half of the total offspring as controls over the 36 weeks they were housed with WT sires (Fig. 3b). The overall shortfall became dramatic when mutant dams were 5–6 months old, and this shortfall was largely attributable to the following: (i) decrease in fecundity after the first ~six litters (Fig. 3a); (ii) longer intervals between litters; and (iii) earlier cessation of litters, despite evidence for continued ovulation (Supplementary Fig. 4). Collectively, these resulted into 1.6–2-fold fewer pups from all 5 mutant dams compared to WT (Fig. 3b). The most severe phenotypes were displayed by Mlh1K618T and Mlh1V716M dams. After their first five litters, these dams produced 2.2- fold and 6.5-fold fewer pups than WT, respectively, (22 ± 6.1; 7.7 ± 2.6; 49.8 ± 8 SEM).
Whereas homozygotes of the aforementioned five alleles showed age-related decrease in litter sizes, only Mlh1K618T/K618T females had dramatically fewer (~half) follicles (combined primordial and developing follicles, Fig. 3c) at three weeks of age. While we did not perform longitudinal studies on the Mlh1K618A allele, female homozygotes were fertile. In preliminary crosses, two young homozygous females had apparently normal litter sizes—an average of 7.5 pups/litter (N = 5 litters)—when crossed to heterozygous males.
It is possible that in the Mlh1K618T mutants with reduced follicles at three weeks of age (and which also had the greatest reduction in COs in males), oocyte loss was triggered by failure to repair CO-designated DSBs, and subsequent activation of the meiotic DNA damage checkpoint44. Alternatively, the smaller litter sizes from mutant dams might be attributable decreased COs and thus increased aneuploidy in ovulated eggs with age, although it is unclear how this would occur. An increase in aneuploidy could lead to increased embryonic lethality as with Sycp3 null females9.
To test the hypothesis that reduced litter sizes are attributable to aneuploidy-induced embryo loss, we first examined the fraction of aneuploid eggs produced by mutant females (3–4 months of age). Following hormone stimulation, oocytes were matured in vitro to MII, then spread to visualize chromosomes. All mutants examined except Mlh1K618T and Mlh1V716M, both of which had smaller ovarian reserves (see above), contained similar numbers of prophase I arrested oocytes as WT females (Fig. 3d). About 70% of the oocytes from all genotypes matured to MII after 15 h (Fig. 3e), although maturation, as marked by polar body extrusion, was ~20% less efficient for the Mlh1K618E and Mlh1V326A genotypes. Next, we evaluated the ability of these females to produce euploid eggs (20 pairs of sister chromatids), and then we quantified the number of sister chromatid pairs in eggs from each mutant. The Mlh1E268G, Mlh1K618T and Mlh1V326A alleles presented marked increases in aneuploid eggs, detected as abnormal number of pairs of sister chromatids (Fig. 3f and insets, g; 20.9 ± 7.1%, 25.8 ± 12.9% and 12.7 ± 2.3, respectively, compared to 4.5 ± 2.7% in WT). Moreover, eggs from Mlh1E268G and Mlh1V326A alleles presented an abnormal phenotype of prematurely separated sister chromatids (Fig. 3f insets, outlined red).
We next explored whether the high levels of aneuploidy in eggs from mutant females led to increased embryonic death of embryos. Control and mutant females that were 3–4 months old (similar to the age of females used in the ploidy experiments) were mated with wild-type males, dissected at E13.5, and the numbers of viable embryos and corpora lutea (CL; reflecting the number of ovulated oocytes) were counted. The fraction of embryonic lethality was inferred as: [CL-embryos]/CL45. Whereas lethality was only 3.4% in WT mothers, it was several fold higher in the mutants, ranging from 11.4% in Mlh1V326A to 34.5% in Mlh1E268G (Table 3). These results suggest that mutations in MLH1/3 can elevate the incidence of aneuploid oocytes, leading to a corresponding increase in spontaneous pregnancy loss.
Discussion
The process of meiotic recombination, specifically crossing over, is essential for fertility and the production of viable, healthy offspring. A severe reduction in COs will prevent proper alignment of meiotic chromosomes at the metaphase I plate, leading to arrest or failed fertilization. However, if only one or a very few chromosomes lack a chiasma, viable gametes can still form but will be prone to mis-segregation of parental homologs; this can lead to aneuploid embryos. A recent study of recombination in human fetal oocytes revealed that having 10–20% fewer COs (MLH1 foci) overall was associated with such oocytes having 1–2 chromosomes completely lacking a CO46. Given that the most common cause of miscarriage (~60%) is embryonic aneuploidy, primarily trisomies1, it is of interest whether the frequency of so-called “exchangeless” chromosomes is genetically controlled. There are indications that parental genetic factors can predispose to generation of aneuploid conceptuses, and may contribute to cases of RPL5,6. In this respect, variants impacting genes important for recombination, including the MUTL homologs, are potential candidates for influencing aneuploidy rates.
SNPs in MLH1 and MLH3 have been statistically associated with male infertility in some studies focusing on candidate genes (i.e., not GWAS), but there have not been validation studies47,48,49. For female fertility, GWAS for phenotypes such as age to menopause, polycystic ovary syndrome, and endometriosis have been performed, but only a few associations have been reported for genes involved in oogenesis per se50. In this study, we focused on human Variants of Unknown Significance (VUS) in MLH1/3, with the goal of determining possible effects on fertility. Because our earlier studies of VUS in essential fertility genes indicated that functional prediction algorithms alone overpredicted deleteriousness33, we applied additional functional criteria to select variants for mouse modeling, namely, studies of analogous mutations in yeast or disruption of protein-protein interactions in Y2H assays. Given that most of the alleles reported here that exhibited defects in these assays caused phenotypes in mice, we believe that this approach is valuable for prioritizing experimentation.
In our opinion, the most intriguing result from this study is that female fecundity in several mutants declined with age and reproduction ceased prematurely (Fig. 3a, b), despite having no apparent shortfall (compared to WT) in the ovarian reserve at wean age (Fig. 3c). One possibility is that after wean age (~3 weeks), oocyte attrition accelerated in the mutants, such that they exhausted their ovarian reserve. However, histology of these older females revealed numerous corpora lutea, indicative of continued ovulation in these aged females (Supplementary Fig. 5). Future experiments aimed at quantifying the reserve, numbers of ovulated eggs, the ability of these eggs to become productively fertilized, and other markers of ovarian aging could reveal the basis of this phenomenon.
An alternative explanation is that the quality of oocytes recruited later in life might be lower than at earlier stages in the mutants. We can only speculate as to the nature of such quality differences, but they might be related to increased aneuploidy caused by prolonged periods in primordial follicles with achiasmate chromosomes. It is also possible that these mice might represent an example of the “production line” hypothesis that was originally proposed as an explanation for increased aneuploidy in women as they age51. This hypothesis posits that eggs are ovulated in the order that they originally proceed through meiosis in utero, and that the “later” oocytes suffer from deficient recombination, and thus higher aneuploidy at MI. While this hypothesis has been refuted in humans52, there is evidence that in mice, the first oogonia to enter meiosis are the first to be ovulated53. Nevertheless, there is no evidence relating crossover rates to time of meiotic entry. Interestingly, a similar phenomenon was observed in Sycp3 null mice, where an age-correlated decrease in litter sizes was attributable to increased embryonic death from aneuploidy9. Additionally, a small scale study implicated mutations in SYCP3 as being responsible for RPL in two women7. It has been hypothesized that women with smaller ovarian reserves have an increased chance of having aneuploid abortuses54. In future work, our models may be useful in exploring this possible relationship in aging mice, and to better understand sexually dimorphic consequences upon gamete quality and checkpoint mechanisms.
Inherited mutations in MLH1 can cause Lynch Syndrome, sometimes referred to as hereditary non-polyposis colorectal cancer (HNPCC), although patients are also subject to a variety of cancers including endometrial55. Lynch Syndrome exhibits a dominant mode of inheritance, and the tumors are characterized by microsatellite instability (MSI). Tumor initiation is attributable to either epigenetic silencing or mutation of the normal MLH1 allele inherited from one parent55,56,57. Mice null for Mlh1 exhibit MSI, increased morbidity (moribund at an average age of 7 months), and develop lymphoma and various types of tumors including gastrointestinal58. However, we did not observe an increased incidence of tumors in any lines or microsatellite instability in the mutants tested (data not shown). Mutations in MLH3 are not associated with Lynch Syndrome, but there is one report that null mice are predisposed (50%) to gastrointestinal tumors with a long latency59. Although the orthologous yeast mlh3 alleles have MMR defects (Table 1), we did not observe tumors or premature morbidity in our Mlh3 mouse mutants. However, we did not age them beyond 1 year. It is also possible that for both sets of models (Mlh1/3), that the genetic background we used was not as tolerant to transformation (at least before 1 year of age) as those in published studies. Because of these caveats, we cannot conclude that these alleles do not cause Lynch Syndrome in humans.
As mentioned in the Results, when this project began, we selected the two variants at K618 (K618E and K618T) that remain present in dbSNP as rs35001569 and rs63750449, respectively. However, after the mouse models were created, the gnomAD database was revised to indicate that these two variants co-occur (are in phase), encoding a K618A amino acid change at essentially identical frequencies in populations (Table 1). The question remains as to whether the MLH1K618E and MLH1K618T exist at all in populations, or at very low frequencies (approximately 100-fold lower based on the numbers cited above). Notably, the MLH1K618E and MLH1K618T alleles are listed in the ClinVar database, and reported in patient samples60,61,62. It is unclear if the three alleles arose independently, or if they were derived from one another. Regarding the MLH1K618A allele and its relationship to Lynch Syndrome, which is somewhat controversial, a recent large study found no evidence for this allele’s involvement, and thus concluded that MLH1K618A is benign63. Interestingly, a computational and experimental study of MLH1 variants suggested that many variants that cause Lynch Syndrome do so by thermodynamically de-stabilizing the MLH1 protein, leading to increased degradation64. Abildgaard and colleagues64 tested four of the alleles modeled here (MLH1E268G, K618T, K618A and V716M), and each were classified as being “likely benign” by virtue of the proteins having substantially normal stability.
In sum, these studies indicate that variants in the MUTLγ (MLH1/3) complex genes can have subtle-to-severe effects on gametogenesis that may go unnoticed without rather detailed phenotyping, including aging studies. Homozygosity for most of the alleles did not cause infertility or drastic reductions in ovarian reserve or sperm counts, although it is conceivable that some of these alleles in trans to a null allele, or in the context of a variant in the other member of the MUTLγ complex, could cause synthetic phenotypes. Nevertheless, the phenotypes of increased aneuploidy in oocytes, and reduced reproductive lifespan of females are highly relevant to the human condition, and thus these mouse models can be valuable for assessing risk at an early age in women, and to dissect the biology of these phenomena.
Methods
Construction of baker’s yeast strains to measure meiotic crossing over and DNA mismatch repair
The SK1 background baker’s yeast strain EAY3255 was constructed for the analysis of MMR and meiotic crossing over phenotypes65. These and all yeast strains generated/used are listed in Supplementary Table 2. EAY3255 contains a spore autonomous fluorescent protein (Tomato) marker located near the centromere on chromosome VIII38 and a lys2::InsE-A14 cassette to measure reversion to Lys+ 37. mlh3 alleles cloned into pEAI plasmids (mlh3-X::KANMX) were transformed into EAY3255 by digesting each plasmid with BamHI and SalI to generate an mlh3-X::KANMX fragment. Approximately 1 μg of each digested plasmid was mixed with 40 μg of salmon sperm carrier DNA (Invitrogen, San Diego, CA, boiled just before addition) and added to ~108 yeast that had been grown to mid-log in yeast extract-peptone-dextrose (YPD) media. The cell-DNA mixture was suspended in a solution containing 0.1 M lithium acetate, 10 mM Tris 8.0, 1 mM EDTA, 40% polyethylene glycol66. The resulting mixture was incubated for 40 min at 42 °C then allowed to recover overnight in 5 ml of YPD media and then plated onto a plate containing geneticin (G418; Invitrogen) at 200 μg/ml. At least two independent transformants for each genotype (verified by DNA sequencing) were made.
EAY3255 and derivatives were used to measure the effect of mlh3 mutations on lys2::InsE-A14 reversion rate (see below). To measure meiotic crossing over, strains from the EAY3255 background were each mated to EAY3486, an SK1 mlh3Δ strain containing the m-Cerulean fluorescence marker located at THR1 on chromosome VIII, ~20 cM away from the Tomato marker present at CEN8 in EAY3255. Diploids were selected on yeast synthetic minimal media lacking tryptophan and leucine and maintained as stable strains. Diploids were then patched onto YPD media for growth for two days at 30 °C. Meiosis was induced upon patching the diploid strains from YPD onto sporulation media (1% potassium acetate; 0.1% yeast extract; 0.05% glucose; 0.021% complete amino acids (2% Bacto Agar (Difco)) and incubated at 30 °C for 48–72 h prior to analysis. Wild-type strains carrying the fluorescent protein markers used to make the above test strains were obtained from Scott Keeney38.
Spore autonomous fluorescent protein expression assay to measure meiotic crossing over
Tetrads obtained from EAY3255/EAY3486 background diploids were treated with 0.5% NP40 and briefly sonicated before analysis by fluorescence microscopy. Tetrads were analyzed using a Zeiss AxioImager M2 microscope equipped with RFP and CFP filters. At least 250 tetrads for each mlh3 allele were counted to determine the % tetratype (two spores show the parental genotype and two show a configuration consistent with a crossover event between the Tomato and m-Cerulean markers located on Chromosome VIII; Supplementary Table 1). Two independent transformants were measured per allele, measured on at least two days with a similar amount analyzed to avoid batch effects. A statistically significant difference (p<0.002) from wild-type and mlh3Δ controls, based on χ2 analysis (Pearson χ2 contingency test, with a Bonferonni correction for 26 comparisons), was used to classify each allele as exhibiting a wild-type (+), intermediate (+/−, +/−), or null (-) phenotype.
lys2 A14 reversion assay to monitor MMR
The EAY3255 derived haploid strains described above were analyzed for reversion to Lys+. Briefly, strains described in Supplementary Table 2 were freshly struck from frozen stocks and grown in complete synthetic minimal media to ~2 mm in diameter colonies (~3 days growth at 30 °C) and then individual colonies were inoculated in 3 ml of yeast synthetic minimal media and grown overnight at 30 °C (~16 h). Overnight cultures were plated with appropriate dilutions onto plates with complete synthetic minimal media and synthetic minimal media lacking lysine to measure lys2::insE-A14 reversion. Colonies were counted after 3 days of incubation at 30 °C. Rates of lys2::insE-A14 reversion were calculated as μ=f/ln(N·μ), where f is reversion frequency and N is the total number of revertants in the culture37. 11 to 16 independent cultures were analyzed for each mutant allele as well as wild-type and mlh3Δ controls. Two independently constructed transformants for each allele were analyzed on at least two days to avoid batch effects, with a similar number of repetitions performed each day. Reversion rates (Supplementary Table 1) were measured and the median rate for each genotype was normalized to the wild-type median rate (1X) to calculate fold increase. Alleles were classified as wild-type (+), intermediate (+/−), or null (-) based on the 95% confidence intervals (CI)67. If the 95% CI for the allele overlapped with the 95% CI for one of the controls (wild-type or null) they were considered statistically equivalent to the respective control.
Variant selection for MLH1
To select MLH1 SNPs for cloning and subsequent Y2H testing, we filtered gnomAD v2.1 for missense mutations with overall AF between 0.02% and 2%. 15 missense SNPs fell within this range, of which 13 were successfully cloned and tested by Y2H.
Generating mutant MLH1 clones
Clones for MLH1 and all Y2H-tested interaction partners were obtained from hORFeome v8.168 or v5.169. The MLH1 alleles were generated by site-directed mutagenesis. Primers for mutagenesis were designed using the webtool primer.yulab.org. To minimize sequencing artifacts, PCR was limited to 18 cycles using Phusion polymerase (New England Biolabs, M0530). Mutagenesis PCR product was then digested overnight using DpnI (New England Biolabs, R0176) followed by bacterial transformation into competent cells. Single colonies were recovered on LB agar plates containing spectinomycin. Four colonies were picked per mutagenesis attempt and then were validated to contain the mutation of interest through Sanger sequencing using primers designed to cover the entire MLH1 sequence.
Profiling disrupted protein interactions through Y2H
Wild-type and successfully mutated MLH1 clones were transferred into Y2H vectors pDEST-AD and pDEST-DB by Gateway LR reactions then transformed into MATa Y8800 and MATα Y8930, respectively. Testable Y2H interaction partners were identified by surveying a Y2H reference interactome comprised of interactions reported in four publications70,71,72,73. All ORFs corresponding to interactions with MLH1 were then selected for Y2H testing. MLH1 interaction partners, transformed into MATa Y8800 and MATα Y8930 were then mated against AD- and DB-MLH1 transformed yeast of the opposite mating type in a pairwise orientation by co-spotting yeast inoculants onto YEPD agar plates. To screen for autoactivators, DB-MLH1 yeast cultures were also mated against MATa yeast transformed with empty pDEST-AD vector. Mated yeast were incubated overnight at 30 °C and then replica-plated onto dropout Synthetic Complete agar media lacking leucine and tryptophan (SC-Leu-Trp) to select diploid yeast. After overnight incubation at 30 °C, diploid yeast were then replicate-plated onto dropout SC agar media lacking leucine, tryptophan, histidine, and supplemented with 1 mM of 3-amino-1,2,4-triazole (SC-Leu-Trp-His+3AT). Diploid yeast were also replica-plated onto SC agar media lacking leucine, tryptophan, and adenine (SC-Leu-Trp-Ade). After overnight incubation at 30 °C, plates were replica-cleaned and incubated again for three days at 30 °C. An interaction was scored as disruptive only if (1) mutant MLH1 reduces growth by at least 50% relative to its corresponding wild-type interaction, and (2) neither wild-type nor mutant DB-MLH1 scored as an autoactivator.
Production of ‘humanized’ mouse-lines and mouse breeding
All ‘humanized’ alleles were generated by CRISPR/Cas9-mediated genome editing33,74. In particular, high-quality gRNA seed sequences were selected using the Benchling (https://benchling.com) guide design tool, and sgRNAs were produced via cloning-free in vitro transcription75. Cas9 protein, sgRNA and single stranded oligodeoxynucleotides (ssODN) bearing the desired sequence changes (oligos listed in Supplementary Table 3) were microinjected into single cell zygotes produced from matings between FVB/NJ and B6(Cg)-Tyrc-2J/J) inbred mice. Correctly edited founder (F0) animals were backcrossed to B6(Cg)-Tyrc-2J/J for two generations, then maintained in a mixed strain background (C57BL/6 J x FVB/NJ).
Fertility tests and embryo loss
Control and experimental animals (8–10 weeks old) were housed with age-matched fertile mates (C57BL/6J) for up to 10–12 months of age. Litter sizes were determined by counting pups on the day of birth.
For embryo loss analyses, homozygous females (12–16 weeks old) were mated to WT males and the presence of a copulation plug in the morning was recorded as 0.5 dpc. Females were sacrificed at 13.5 dpc for counting of both implantation sites and corpora lutea (CL; indicating the numbers of ovulated oocytes). Graphs and statistical analyses were performed with GraphPad Prism5.
Ovary histology and follicle quantification
Ovaries were collected from 3-week females and were fixed in Bouin’s for 24 h, washed in 70% ethanol, paraffin embedded, and further serial sectioned at 6 µm followed by staining with hematoxylin and eosin (H&E). Every fourth section was counted under light microscopy. Though we reported the combined number of follicles in Fig. 3, we maintained records of the follicle subtypes (e.g., primordial, primary, secondary, antral) and can provide them upon request.
Surface spread preparation and immunocytology
To prepare prophase I surface spreads76, mouse seminiferous tubules were incubated in a buffer consisting of 30 mM Tris pH7.2, 50 mM sucrose, 17 mM trisodium dehydrate, 5 mM EDTA, 0.5 mM DTT, 0.1 mM PMSF, pH8.2-8.4) at room temperature for 1 h. Small sections of testis tubule were dissected in 100 mM sucrose and spread onto slides coated with 1% paraformaldehyde and 0.15% Triton X, then incubated in a humid chamber for 2 h at room temperature. For all experiments, at least 3 males from each genotype were evaluated. Following final washing of chromosome slides in 0.4% Photo-Flo 200 (Kodak 1464510) for 2 × 5 min, slides were air dried for ~10 min and stored in −80 °C or used immediately for staining.
For staining, slides were washed in 1xPBS, 0.4% Photoflo for 10 min, followed by 2 × 10 min. washes in 1x PBS, 0.1% Triton X and 1 hr incubation in blocking buffer (3% BSA, 10% Goat Serum, 0.0125% Triton X, 1 x PBS), at 37 °C. Finally, all antibodies were diluted in blocking buffer, and slides were incubated for 12 hr at RT.
Primary antibodies used were: rabbit anti-SYCP3 (1:500, ab15093; Abcam), mouse anti-SYCP3 (1:500, ab97672; Abcam), and mouse anti-MLH1 (1:50, 550838; BD Pharmingen). Slides were washed and incubated for 1 hr with the following secondary antibodies: goat anti rabbit-IgG 488 (1:2,000, A11008; Molecular Probes), goat ant-rabbit IgG 594 (1:1,000, A11012; Molecular Probes), and goat anti-mouse IgG 594 (1:1,000, A11005; Molecular Probes). Nuclei were counterstained with DAPI, and slides were mounted with ProLong Gold antifade reagent (P36930; Molecular Probes).
Sperm counting
Cauda epididymides were dissected and minced into 2 mL of PBS. Sperm were allowed to swim into the buffer via 15 min incubation at 37 °C. The sperm were diluted PBS, incubated for 1 min at 60 °C, and then counted with a hematocytometer.
Testes histology and Immunohistochemistry
For histological analyses, testes were fixed for 24 h at room temperature (RT) in Bouin’s solution. Tissue was further paraffin-embedded, sectioned (7 μm), and stained with H&E. For immunohistology, testes were essentially fixed in 4% paraformaldehyde for ∼24 h. Paraffin-embedded tissues were further sectioned at 7 μm. For TUNEL and PH3 double immunostaining, sections were deparaffinized followed by antigen retrieval using Sodium Citrate Buffer (10 mM Sodium Citrate, 0.05% Tween 20, pH 6.0). Sections were blocked in PBS containing 5% goat serum for 1 h at RT, followed by TUNEL staining, performed following instructions manufacturer’s instruction (Invitrogen, Click-iT™ TUNEL kit). This was followed by 1° antibody incubation overnight at 4 °C (anti-pH3 (Ser10), 1:100, Millipore) and anti-rabbit AF488 (Invitrogen, 1:1000) 2° antibody incubation for 1 h, RT. Slides were counterstained using DAPI, mounted in Vectashield and imaged as described in below.
Imaging and analysis of testes cross sections
Testes were fixed in Bouin’s, embedded in paraffin and stained with hematoxylin and eosin (H&E) in Cornell’s Diagnostic Pathology Lab. For TUNEL labeling, testes cross sections were double immunolabeled with TUNEL and anti-pH3 (see above) antibody and were imaged using a confocal microscope (u880, Carl Zeiss, Germany) with a Plan Apo 40× water immersion objective (1.1 NA) and Zen black software. The following lasers were used: argon laser-488 nm, blue-diode-405 nm, DPSS laser—561 nm. Following identical background adjustments for all images, cropping, color, and contrast adjustments were made with Adobe Photoshop CC 2017.
Oocyte in vitro maturation and in situ chromosome counting
Prophase I-arrested oocytes (GV) were collected following standard methods77 as follows. Forty-eight hours prior to collection, females were injected intraperitoneally with CARD HyperOva (KYD-010-EX-X5; CosmoBio USA) consisting of Inhibin antiserum and equine chorionic gonadotrophin (Sigma, 230734). Further, ovaries from 12–16 weeks old females were dissected and GV oocytes were released from the follicles by puncturing the ovaries several times with 27-gauge sewing needles in MEM/polyvinylpyrrolidone media containing 2.5 μM milrinone (Sigma-Aldrich; M4659) to prevent oocyte maturation after the release from cumulus cells. Then, cumulus cells were removed by gentle pipetting and fully-grown oocytes were matured in vitro in Chatot, Ziomek, and Bavister (CZB) media without milrinone in a humidified incubator programmed to 5% CO2 and 37 °C for 14 h until they arrived to metaphase II. They were cultured for 2 h in 100 µM Monastrol (Sigma, M8515) to disorganize the spindle and separate the chromosomes. Then, eggs were fixed in 2% paraformaldehyde in PBS for 20 min and permeabilized in PBS containing 0.2% Triton X-100 (Sigma-Aldrich, 900-93-1) for 20 min. Eggs were stained with the anticentromere antibody (ACA) to detect centromeres (Antibodies Incorporated; #15-234; 1:30) and DAPI to detect DNA. Chromosome numbers were quantified in metaphase II eggs78. Mouse eggs should have 20 pairs of sister chromatids; any deviation of this number was considered aneuploid. Eggs were imaged with the i880 (Zeiss) confocal at 0.5 µm z-intervals. Chromosome counting was performed with NIH Image J software, using cell counter plugins.
Animals
All animal strains were maintained in a mixed strain background (C57BL/6 J x FVB/NJ). We have complied with all relevant ethical regulations for animal experiments, and these experiments were performed under a protocol (2004-0038) approved by Cornell’s Institutional Animal Care and Use Committee (IACUC), which ensures ethical animal research use. Mice were housed at 23 °C with a light cycle of 10 h dark and 14 h light.
Statistics and reproducibility
All data presented in this manuscript is generated from at least 3 or more biological replicates, unless otherwise noted. Statistics is performed on datapoints with ≥3 biological replicates. Each mouse is considered a biological replicate.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All relevant data such as litter sizes and sperm numbers are present in the manuscript. Fluorescent images (immunolabelings) from which numbers were generated (such as MLH1 foci) are stored by the authors and primary images can be provided upon request. Source data are included with this manuscript. All unique materials used are readily available from the authors, with the exception of mouse strains, which may require extended periods of time for reanimation and/or breeding before providing to requestors. Source data are provided with this paper.
References
Silver, R. M. & Branch, D. In Clinical obstetrics: The fetus & mother (eds. Reece, E. A. & Hobbins, J. C.) 143–160 (Blackwell Publishing, 2007).
Soler, A. et al. Overview of chromosome abnormalities in first trimester miscarriages: a series of 1,011 consecutive chorionic villi sample karyotypes. Cytogenet. Genome Res. 152, 81–89 (2017).
Chiang, T., Duncan, F. E., Schindler, K., Schultz, R. M. & Lampson, M. A. Evidence that weakened centromere cohesion is a leading cause of age-related aneuploidy in oocytes. Curr. Biol. 20, 1522–1528 (2010).
Duncan, F. E. et al. Chromosome cohesion decreases in human eggs with advanced maternal age. Aging Cell 11, 1121–1124 (2012).
Sullivan, A. E., Silver, R. M., LaCoursiere, D. Y., Porter, T. F. & Branch, D. W. Recurrent fetal aneuploidy and recurrent miscarriage. Obstet. Gynecol. 104, 784–788 (2004).
Blue, N. R., Page, J. M. & Silver, R. M. Genetic abnormalities and pregnancy loss. Semin. Perinatol. 43, 66–73 (2019).
Bolor, H. et al. Mutations of the SYCP3 gene in women with recurrent pregnancy loss. Am. J. Hum. Genet. 84, 14–20 (2009).
Hanna, C. W., Blair, J. D., Stephenson, M. D. & Robinson, W. P. Absence of SYCP3 mutations in women with recurrent miscarriage with at least one trisomic miscarriage. Reprod. Biomed. Online 24, 251–253 (2012).
Yuan, L. et al. Female germ cell aneuploidy and embryo death in mice lacking the meiosis-specific protein SCP3. Science 296, 1115–1118 (2002).
Wang, S. et al. Inefficient crossover maturation underlies elevated aneuploidy in human female meiosis. Cell 168, 977–989.e17 (2017).
Edelmann, W. et al. Meiotic pachytene arrest in MLH1-deficient mice. Cell 85, 1125–1134 (1996).
Rogacheva, M. V. et al. Mlh1-Mlh3, a meiotic crossover and DNA mismatch repair factor, is a Msh2-Msh3-stimulated endonuclease. J. Biol. Chem. 289, 5664–5673 (2014).
Prolla, T. A. et al. Tumour susceptibility and spontaneous mutation in mice deficient in Mlh1, Pms1 and Pms2 DNA mismatch repair. Nat. Genet. 18, 276–279 (1998).
Baker, S. M. et al. Involvement of mouse Mlh1 in DNA mismatch repair and meiotic crossing over. Nat. Genet. 13, 336–342 (1996).
Ranjha, L., Anand, R. & Cejka, P. The Saccharomyces cerevisiae Mlh1-Mlh3 heterodimer is an endonuclease that preferentially binds to Holliday junctions. J. Biol. Chem. 289, 5674–5686 (2014).
Nishant, K. T., Plys, A. J. & Alani, E. A mutation in the putative MLH3 endonuclease domain confers a defect in both mismatch repair and meiosis in Saccharomyces cerevisiae. Genetics 179, 747–755 (2008).
Manhart, C. M. et al. The mismatch repair and meiotic recombination endonuclease Mlh1-Mlh3 is activated by polymer formation and can cleave DNA substrates in trans. PLoS Biol. 15, e2001164 (2017).
Manhart, C. M. & Alani, E. Roles for mismatch repair family proteins in promoting meiotic crossing over. DNA Repair 38, 84–93 (2016).
Zakharyevich, K., Tang, S., Ma, Y. & Hunter, N. Delineation of joint molecule resolution pathways in meiosis identifies a crossover-specific resolvase. Cell 149, 334–347 (2012).
Eaker, S., Cobb, J., Pyle, A. & Handel, M. A. Meiotic prophase abnormalities and metaphase cell death in MLH1-deficient mouse spermatocytes: insights into regulation of spermatogenic progress. Dev. Biol. 249, 85–95 (2002).
Lipkin, S. M. et al. Meiotic arrest and aneuploidy in MLH3-deficient mice. Nat. Genet. 31, 385–390 (2002).
Toledo, M. et al. A mutation in the endonuclease domain of mouse MLH3 reveals novel roles for MutLγ during crossover formation in meiotic prophase I. PLoS Genet. 15, e1008177 (2019).
Kolas, N. K. et al. Localization of MMR proteins on meiotic chromosomes in mice indicates distinct functions during prophase I. J. Cell Biol. 171, 447–458 (2005).
Anderson, L. K., Reeves, A., Webb, L. M. & Ashley, T. Distribution of crossing over on mouse synaptonemal complexes using immunofluorescent localization of MLH1 protein. Genetics 151, 1569–1579 (1999).
de Boer, E., Stam, P., Dietrich, A. J. J., Pastink, A. & Heyting, C. Two levels of interference in mouse meiotic recombination. Proc. Natl Acad. Sci. USA 103, 9607–9612 (2006).
Tachibana-Konwalski, K. et al. Spindle assembly checkpoint of oocytes depends on a kinetochore structure determined by cohesin in meiosis I. Curr. Biol. 23, 2534–2539 (2013).
LeMaire-Adkins, R., Radke, K. & Hunt, P. A. Lack of checkpoint control at the metaphase/anaphase transition: a mechanism of meiotic nondisjunction in mammalian females. J. Cell Biol. 139, 1611–1619 (1997).
Kouznetsova, A., Lister, L., Nordenskjöld, M., Herbert, M. & Höög, C. Bi-orientation of achiasmatic chromosomes in meiosis I oocytes contributes to aneuploidy in mice. Nat. Genet. 39, 966–968 (2007).
Sebestova, J., Danylevska, A., Novakova, L., Kubelka, M. & Anger, M. Lack of response to unaligned chromosomes in mammalian female gametes. Cell Cycle 11, 3011–3018 (2012).
Nagaoka, S. I., Hodges, C. A., Albertini, D. F. & Hunt, P. A. Oocyte-specific differences in cell-cycle control create an innate susceptibility to meiotic errors. Curr. Biol. 21, 651–657 (2011).
Karczewski, K. J. et al. The mutational constraint spectrum quantified from variation in 141,456 humans. Nature 581, 434–443 (2020).
Lek, M. et al. Analysis of protein-coding genetic variation in 60,706 humans. Nature 536, 285–291 (2016).
Singh, P. & Schimenti, J. C. The genetics of human infertility by functional interrogation of SNPs in mice. Proc. Natl Acad. Sci. USA 112, 10431–10436 (2015).
Tran, T. N., Martinez, J. & Schimenti, J. C. A predicted deleterious allele of the essential meiosis gene MND1, present in ~ 3% of East Asians, does not disrupt reproduction in mice. Mol. Hum. Reprod. 25, 668–673 (2019).
Wang, X. et al. Three-dimensional reconstruction of protein networks provides insight into human genetic disease. Nat. Biotechnol. 30, 159–164 (2012).
Wei, X. et al. A massively parallel pipeline to clone DNA variants and examine molecular phenotypes of human disease mutations. PLoS Genet. 10, e1004819 (2014).
Tran, H. T., Keen, J. D., Kricker, M., Resnick, M. A. & Gordenin, D. A. Hypermutability of homonucleotide runs in mismatch repair and DNA polymerase proofreading yeast mutants. Mol. Cell. Biol. 17, 2859–2865 (1997).
Thacker, D., Lam, I., Knop, M. & Keeney, S. Exploiting spore-autonomous fluorescent protein expression to quantify meiotic chromosome behaviors in Saccharomyces cerevisiae. Genetics 189, 423–439 (2011).
Clement, T. M., Inselman, A. L., Goulding, E. H., Willis, W. D. & Eddy, E. M. Disrupting cyclin dependent kinase 1 in spermatocytes causes late meiotic arrest and infertility in mice. Biol. Reprod. 93, 137 (2015).
Gray, S. & Cohen, P. E. Control of meiotic crossovers: from double-strand break formation to designation. Annu. Rev. Genet. 50, 175–210 (2016).
Woods, L. M. et al. Chromosomal influence on meiotic spindle assembly: abnormal meiosis I in female Mlh1 mutant mice. J. Cell Biol. 145, 1395–1406 (1999).
Hassold, T., Hall, H. & Hunt, P. The origin of human aneuploidy: where we have been, where we are going. Hum. Mol. Genet. 16 Spec No. 2, R203–R208 (2007).
Hunt, P. A. & Hassold, T. J. Sex matters in meiosis. Science 296, 2181–2183 (2002).
Qiao, H. et al. Antagonistic roles of ubiquitin ligase HEI10 and SUMO ligase RNF212 regulate meiotic recombination. Nat. Genet. 46, 194–199 (2014).
Papaioannou, V. & Behringer, R. R. Mouse Phenotypes: A Handbook of Mutation Analysis (Manual). 235 (Cold Spring Harbor Laboratory Press, 2004).
Hassold, T. et al. Failure to recombine is a common feature of human oogenesis. Am. J. Hum. Genet. https://doi.org/10.1016/j.ajhg.2020.11.010 (2020).
Markandona, O. et al. Single-nucleotide polymorphism rs 175080 in the MLH3 gene and its relation to male infertility. J. Assist. Reprod. Genet. 32, 1795–1799 (2015).
Ji, G. et al. Common variants in mismatch repair genes associated with increased risk of sperm DNA damage and male infertility. BMC Med 10, 49 (2012).
Zhang, X., Ding, M., Ding, X., Li, T. & Chen, H. Six polymorphisms in genes involved in DNA double-strand break repair and chromosome synapsis: association with male infertility. Syst. Biol. Reprod. Med 61, 187–193 (2015).
Gajbhiye, R., Fung, J. N. & Montgomery, G. W. Complex genetics of female fertility. NPJ Genom. Med. 3, 29 (2018).
Henderson, S. A. & Edwards, R. G. Chiasma frequency and maternal age in mammals. Nature 218, 22–28 (1968).
Rowsey, R., Gruhn, J., Broman, K. W., Hunt, P. A. & Hassold, T. Examining variation in recombination levels in the human female: a test of the production-line hypothesis. Am. J. Hum. Genet. 95, 108–112 (2014).
Polani, P. E. & Crolla, J. A. A test of the production line hypothesis of mammalian oogenesis. Hum. Genet. 88, 64–70 (1991).
Kline, J., Kinney, A., Levin, B. & Warburton, D. Trisomic pregnancy and earlier age at menopause. Am. J. Hum. Genet. 67, 395–404 (2000).
Lynch, H. T., Snyder, C. L., Shaw, T. G., Heinen, C. D. & Hitchins, M. P. Milestones of Lynch syndrome: 1895-2015. Nat. Rev. Cancer 15, 181–194 (2015).
Herman, J. G. et al. Incidence and functional consequences of hMLH1 promoter hypermethylation in colorectal carcinoma. Proc. Natl Acad. Sci. USA 95, 6870–6875 (1998).
Liu, B. et al. Mismatch repair gene defects in sporadic colorectal cancers with microsatellite instability. Nat. Genet. 9, 48–55 (1995).
Edelmann, W. et al. Tumorigenesis in Mlh1 and Mlh1/Apc1638N mutant mice. Cancer Res. 59, 1301–1307 (1999).
Chen, P.-C. et al. Contributions by MutL homologues Mlh3 and Pms2 to DNA mismatch repair and tumor suppression in the mouse. Cancer Res. 65, 8662–8670 (2005).
Cravo, M. et al. Pathogenicity of missense and splice site mutations in hMSH2 and hMLH1 mismatch repair genes: implications for genetic testing. Gut 50, 405–412 (2002).
Genuardi, M., Carrara, S., Anti, M., Ponz de Leòn, M. & Viel, A. Assessment of pathogenicity criteria for constitutional missense mutations of the hereditary nonpolyposis colorectal cancer genes MLH1 and MSH2. Eur. J. Hum. Genet. 7, 778–782 (1999).
Schneider, N. B. et al. Germline MLH1, MSH2 and MSH6 variants in Brazilian patients with colorectal cancer and clinical features suggestive of Lynch Syndrome. Cancer Med. 7, 2078–2088 (2018).
Abulí, A. et al. The MLH1 c.1852_1853delinsGC (p.K618A) variant in colorectal cancer: genetic association study in 18,723 individuals. PLoS ONE 9, e95022 (2014).
Abildgaard, A. B. et al. Computational and cellular studies reveal structural destabilization and degradation of MLH1 variants in Lynch syndrome. Elife 8, e49138 (2019).
Al-Sweel, N. et al. mlh3 mutations in baker’s yeast alter meiotic recombination outcomes by increasing noncrossover events genome-wide. PLoS Genet. 13, e1006974 (2017).
Gietz, R. D., Schiestl, R. H., Willems, A. R. & Woods, R. A. Studies on the transformation of intact yeast cells by the LiAc/SS-DNA/PEG procedure. Yeast 11, 355–360 (1995).
Spell, R. M. & Jinks-Robertson, S. Determination of mitotic recombination rates by fluctuation analysis in Saccharomyces cerevisiae. Methods Mol. Biol. 262, 3–12 (2004).
Yang, X. et al. A public genome-scale lentiviral expression library of human ORFs. Nat. Methods 8, 659–661 (2011).
MGC Project Team. et al. The completion of the Mammalian Gene Collection (MGC). Genome Res. 19, 2324–2333 (2009).
Rolland, T. et al. A proteome-scale map of the human interactome network. Cell 159, 1212–1226 (2014).
Rual, J.-F. et al. Towards a proteome-scale map of the human protein-protein interaction network. Nature 437, 1173–1178 (2005).
Venkatesan, K. et al. An empirical framework for binary interactome mapping. Nat. Methods 6, 83–90 (2009).
Yu, H. et al. High-quality binary protein interaction map of the yeast interactome network. Science 322, 104–110 (2008).
Singh, P., Schimenti, J. C. & Bolcun-Filas, E. A mouse geneticist’s practical guide to CRISPR applications. Genetics 199, 1–15 (2015).
Varshney, G. K. et al. High-throughput gene targeting and phenotyping in zebrafish using CRISPR/Cas9. Genome Res. 25, 1030–1042 (2015).
Holloway, J. K., Sun, X., Yokoo, R., Villeneuve, A. M. & Cohen, P. E. Mammalian CNTD1 is critical for meiotic crossover maturation and deselection of excess precrossover sites. J. Cell Biol. 205, 633–641 (2014).
Blengini, C. S. & Schindler, K. Immunofluorescence technique to detect subcellular structures critical to oocyte maturation. Methods Mol. Biol. 1818, 67–76 (2018).
Stein, P. & Schindler, K. Mouse oocyte microinjection, maturation and ploidy assessment. J. Vis. Exp. 2851 https://doi.org/10.3791/2851 (2011).
Acknowledgements
We thank S. Keeney for yeast strains, R. Munroe and C. Abratte in Cornell’s transgenic core for making mice, and P. Cohen for critical reading of the manuscript in advance of submission. This work was supported by grants R01HD082568 to J.S. and H.Y., R01HD091331 to K.S., and R35 GM134872 to E.A.
Author information
Authors and Affiliations
Contributions
P.S. characterized all Mlh1 and the Mlh3A1394T mouse mutants and contributed to writing the manuscript. R.F. performed the Y2H experiments and wrote relevant sections of the manuscript; H.Y. supervised R.F. and was involved in SNP selection metrics; C.S.B. (with P.S.) performed the oocyte development and ploidy experiments presented in Fig. 3d–g, was supervised by K.Schindler, and C.S.B. and K.S. wrote relevant parts of the manuscript. T.N.T. analyzed Mlh3 mouse mutants not done by P.S. G.P. and N.A-S. performed the yeast studies of mismatch repair and recombination, and were supervised by E.A.A., who wrote relevant parts of the manuscript and design/interpretation of the yeast experiments. K.J.S. assisted with mouse husbandry. J.C.S. oversaw the overall project, its design, and had a major role in writing and revising the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Peer review information Nature Communications thanks Alberto Pendas and other, anonymous, reviewers for their contributions to the peer review of this work. Peer review reports are available.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Source data
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Singh, P., Fragoza, R., Blengini, C.S. et al. Human MLH1/3 variants causing aneuploidy, pregnancy loss, and premature reproductive aging. Nat Commun 12, 5005 (2021). https://doi.org/10.1038/s41467-021-25028-1
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-021-25028-1
This article is cited by
-
ARHGAP26 deficiency drives the oocyte aneuploidy and early embryonic development failure
Cell Death & Differentiation (2024)
-
Prdm9 deficiency of rat oocytes causes synapsis among non-homologous chromosomes and aneuploidy
Mammalian Genome (2022)