Abstract

This manuscript describes the identification, isolation and sequencing of a single chromosome containing high value resistance genes from a complex polyploid where sequencing the whole genome is too costly. The large complex genomes of many crops constrain the use of new technologies for genome-assisted selection and genetic improvement. One method to simplify a genome is to break it into individual chromosomes by flow cytometry; however, in many crop species most chromosomes cannot be isolated individually. Flow sorting of a single copy of a chromosome has been developed in wheat, and here we demonstrate its use to identify markers of interest in an Erianthus/Sacchurum hybrid. Erianthus/Saccharum hybrids are of interest because Erianthus is known to be highly resistant to soil borne diseases which cause extensive sugarcane yield losses in Australia. Sugarcane (Saccharum) cultivars are autopolyploids with a highly complex genome and over 100 chromosomes. Flow cytometry for sugarcane, as in most crops, does not resolve individual chromosomes to a karyotype peak for sorting. To isolate a single chromosome, we used genomic in situ hybridization (GISH) to identify the flow karyotype region containing the Erianthus chromosomes, flow sorted single chromosomes from this region, PCR screened for the Erianthus chromosomes and sequenced them. One Erianthus chromosome amplified and sequenced well, and from this data we could identify 57 resistant type genes and SNPs in nearly half of these genes. We developed KASP SNP assays and demonstrated that the identified SNP markers segregated as expected in a small introgression population. The pipeline we developed here to flow sort and sequence single chromosomes could be used in any crop with a large complex genome to rapidly discover and develop markers to important loci.

Highlights

  • Many of our grass crop species of major economic significance for example, wheat, barley, oat, rye, and sugarcane have large genomes (Kellogg 1998)

  • To isolate a single chromosome, we used genomic in situ hybridisation (GISH) to identify the flow karyotype region containing the Erianthus chromosomes, flow sorted single chromosomes from this region, PCR screened for the Erianthus chromosomes and sequenced them

  • The red chromosomes are inherited from Erianthus and the green chromosomes are inherited from Saccharum (Figure 2)

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Summary

Introduction

Many of our grass crop species of major economic significance for example, wheat, barley, oat, rye, and sugarcane have large genomes (Kellogg 1998). This presents challenges in the implementation of new technologies for genomeassisted selection and genetic improvement of crops. In the flow karyotype of the two S. officinarum accessions and three hybrid cultivars, five main peaks, representing groups of chromosomes of similar DNA content or size, were identified (Metcalfe et al 2019). Using microsatellite markers to screen chromosomes from each of the peaks it was determined that at least one homo(eo)log of each of the 10 chromosomes was present in each peak This indicates that like most other grass crops, a single peak does not contain a single chromosome. Individual chromosomes cannot be isolated by standard flow sorting in sugarcane from a single peak

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