Abstract
Extracting DNA from cyanobacteria can be a challenge because of their diverse morphologies, challenging cellular structure, and the heterotrophic microbiome often present within cyanobacterial cultures. As such, even with high DNA yields, the percentage of reads coming from the cyanobacterial host can be low, leading to an incomplete cyanobacterial genome assembly. In this research, we optimized a DNA isolation protocol using three iterative cell lysis steps to enrich the portion of DNA isolated coming from the cyanobacterial host rather than the heterotrophic microbiome. In order to utilize in-house nanopore sequencing, we faced a challenge using our lysis protocol: the iterative lysis approach led to more DNA shearing than is ideal for this sequencing technology. To solve this, we used two bead-based size selection steps to remove shorter molecules of DNA before nanopore sequencing. Analysis of the sequenced reads showed that, in the first lysis, the cyanobacterial sequences were only 35% of all reads. In the repeated lysis steps, however, the proportion of reads coming from the cyanobacterium increased to 75% or higher. Using our iterative lysis protocol, we were able to sequence the genomes of two fresh water cyanobacteria isolated from northern Mississippi, namely Leptolyngbya sp. BL-A-14 and Limnothrix sp. BL-A-16. The genomes of these isolates were assembled as closed chromosomes of 7.2 and 4.5 Mb for BL-A-14 and BL-A-16, respectively. As it is not always possible to prepare axenic cultures of cyanobacteria, we hope our approach will be useful for sequencing other xenic cultures of cyanobacteria.