Abstract
Next-generation sequencing is an efficient method that allows for substantially more markers than previous technologies, providing opportunities for building high-density genetic linkage maps, which facilitate the development of nonmodel species' genomic assemblies and the investigation of their genes. However, constructing genetic maps using data generated via high-throughput sequencing technology (e.g., genotyping-by-sequencing) is complicated by the presence of sequencing errors and genotyping errors resulting from missing parental alleles due to low sequencing depth. If unaccounted for, these errors lead to inflated genetic maps. In addition, map construction in many species is performed using full-sibling family populations derived from the outcrossing of two individuals, where unknown parental phase and varying segregation types further complicate construction. We present a new methodology for modeling low coverage sequencing data in the construction of genetic linkage maps using full-sibling populations of diploid species, implemented in a package called GUSMap. Our model is based on the Lander-Green hidden Markov model but extended to account for errors present in sequencing data. We were able to obtain accurate estimates of the recombination fractions and overall map distance using GUSMap, while most existing mapping packages produced inflated genetic maps in the presence of errors. Our results demonstrate the feasibility of using low coverage sequencing data to produce genetic maps without requiring extensive filtering of potentially erroneous genotypes, provided that the associated errors are correctly accounted for in the model.
Highlights
Next-generation sequencing is an efficient method that allows for substantially more markers than previous technologies, providing opportunities for building high-density genetic linkage maps, which facilitate the development of nonmodel species’ genomic assemblies and the investigation of their genes
The distribution of the overall map distance estimates obtained using the various software packages in the first set of simulations is given in Figure 1, while the distribution of the recombination fraction estimates for each simulation are given in Figures S1– S9 in File S2
At moderate depth with no sequencing error, the overall map distance estimates from LM2, OneMap v2.0-4 (OM), and CRI-MAP 2.507 (CM) were slightly larger than the true value, which suggests that the cut-off of six has not removed all errors associated with low sequencing depth
Summary
Next-generation sequencing is an efficient method that allows for substantially more markers than previous technologies, providing opportunities for building high-density genetic linkage maps, which facilitate the development of nonmodel species’ genomic assemblies and the investigation of their genes. Two software packages have been developed for performing linkage mapping in full-sib families using sequencing data These are Lep-MAP (Rastas et al 2013, 2016) and HighMap (Liu et al 2014), both of which address the computational problem associated with high-density maps but are not designed to handle low coverage sequencing data. Another complication is the presence of sequencing errors, reads where the base has been called incorrectly, which leads to inflated genetic distances if not taken into account. Several variants of this model derived for full-sib family populations in diploid species have been suggested (Ling 2000; Wu et al 2002; Tong et al 2010), which reduces the computational complexity by exploiting the conditional independence between individuals given the parental phase
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