Analysis of the Genome Sequence of Strain GiC-126 of Gloeostereum incarnatum with Genetic Linkage Map.

Gloeostereum incarnatum has edible and medicinal value and was first cultivated and domesticated in China. We sequenced the G. incarnatum monokaryotic strain GiC-126 on an Illumina HiSeq X Ten system and obtained a 34.52-Mb genome assembly sequence that encoded 16,895 predicted genes. We combined the GiC-126 genome with the published genome of G. incarnatum strain CCMJ2665 to construct a genetic linkage map (GiC-126 genome) that had 10 linkage groups (LGs), and the 15 assembly sequences of CCMJ2665 were integrated into 8 LGs. We identified 1912 simple sequence repeat (SSR) loci and detected 700 genes containing 768 SSRs in the genome; 65 and 100 of them were annotated with gene ontology (GO) terms and KEGG pathways, respectively. Carbohydrate-active enzymes (CAZymes) were identified in 20 fungal genomes and annotated; among them, 144 CAZymes were annotated in the GiC-126 genome. The A mating-type locus (MAT-A) of G. incarnatum was located on scaffold885 at 38.9 cM of LG1 and was flanked by two homeodomain (HD1) genes, mip and beta-fg. Fourteen segregation distortion markers were detected in the genetic linkage map, all of which were skewed toward the parent GiC-126. They formed three segregation distortion regions (SDR1-SDR3), and 22 predictive genes were found in scaffold1920 where three segregation distortion markers were located in SDR1. In this study, we corrected and updated the genomic information of G. incarnatum. Our results will provide a theoretical basis for fine gene mapping, functional gene cloning, and genetic breeding the follow-up of G. incarnatum.

Genetic linkage map construction and quantitative trait loci mapping of agronomic traits in Gloeostereum incarnatum.

Gloeostereum incarnatum is an edible medicinal mushroom widely grown in China. Using the whole genome of G. incarnatum, simple sequence repeat (SSR) markers were developed and synthetic primers were designed to construct its first genetic linkage map. The 1,048.6 cm map is composed of 10 linkage groups and contains 183 SSR markers. In total, 112 genome assembly sequences were anchored, representing 16.43 Mb and covering 46.41% of the genome. Selfing populations were used for quantitative trait loci (QTL) targeting, and the composite interval mapping method was used to co-localize the mycelium growth rate (potato dextrose agar and sawdust), growth period, yield and fruiting body length, and width and thickness. The 14 QTLs of agronomic traits had LOD values of 3.20-6.51 and contribution rates of 2.22-13.18%. No linkage relationship was found between the mycelium growth rate and the growth period, but a linkage relationship was observed among the length, width and thickness of the fruiting bodies. Using NCBI's BLAST alignment, the genomic sequences corresponding to the QTL regions were compared, and a TPR-like protein candidate gene was selected. Using whole-genome data, 138 candidate genes were found in four sequence fragments of two SSR markers located in the same scaffold. The genetic map and QTLs established in this study will aid in developing selective markers for agronomic traits and identifying corresponding genes, thereby providing a scientific basis for the further gene mapping of quantitative traits and the marker-assisted selection of functional genes in G. incarnatum breeding programs.

Map-based cloning of genes encoding key enzymes for pigment synthesis in Auricularia cornea.

Color is an important quality attribute of fungi, and a useful marker for classification, genetic, and molecular research. However, there is much debate over which enzymes play key regulatory roles in pigment synthesis pathways among different fungi and even within the same species. Auricularia cornea is the most widely cultivated mushroom in the genus Auricularia; 1.834 million tons of this mushroom were produced in 2016 in China. Thus, systematic studies on its color inheritance and the genes encoding key enzymes for pigment synthesis have high scientific and economic value. In this study, the white strain ACW001 and the purple strain ACP004 of A. cornea were used as dikaryotic parents. Selfing populations of ACW001 and ACP004 were constructed with their monokaryotic strains. The fruiting body color of the two populations was consistent with that of their parents, confirming that the two parents were color homozygotes. All strains in the hybrid population of the two parents produced purple fruiting bodies. A robust hybrid strain (ACW001-33×ACP004-33) was selected from the hybrid population, and 87 monokaryotic strains of ACW001-33×ACP004-33 were obtained as a mapping population. Finally, a testcross population was constructed by crossing the mapping population with the test strain ACW001-9. The color genotype of each monokaryotic strain in the mapping population was identified by a fruiting test. The genomes of the two monokaryotic strains ACW001-33 and ACP004-33 were sequenced, and then simple sequence repeat (SSR) and sequence-related amplified polymorphism (SRAP) molecular marker primers were developed. Then, 88 pairs of primers that could distinguish the genotypes of the mapping population were used to construct a genetic linkage map. The genetic linkage map consisted of 12 linkage groups (LGs) spanning 1315.2 cM. The color control locus was preliminarily located at 24.5 cM of the 11th LG. Fine-mapping primers were designed based on sequence differences between ACW001-33 and ACP004-33 in the primary location region. Four color control candidate genes were located in an 8.2-kb region of ACW001-33_contig733 and a 9.2-kb region of ACP004-33_contig802. Homologous alignment and prediction of conserved domain analyses indicated that two of the color control candidate genes encoded proteins with unknown function, and the other two, ACP004_g11815 and ACP004_g11816, encoded glutamyl aminotransferases. These two genes were consecutively arranged on ACP004-33_contig802, and were likely to encode key enzymes in the γ-glutamine-4-hydroxy-benzoate (GHB) pigment synthesis pathway. Primers were designed from the flanking sequences of the two genes and used to analyze the testcross population. Products were amplified only from the 30 testcross strains with purple fruiting bodies, confirming the accuracy of the localization results. We discuss the deficiencies and advantages of map-based cloning in fungi vs. plants, and summarize the steps and requirements of the map-based cloning method for fungi. This study has provided novel ideas and methods for locating functional genes in fungi.