CTAB DNA Extraction and Genotyping-by-Sequencing to Map Meiotic Crossovers in Plants

Chromosome-scale genome assembly of Zoysia japonica uncovers cold tolerance candidate genes

Zoysiagrass stands out as a crucial native turfgrass due to its exceptional abiotic stress tolerance, extensive adaptability, and high ornamental value. In this study, we generated a high-quality chromosome-level genome assembly of Compadre (COM) zoysiagrass, leveraging PacBio SMRT sequencing and Hi-C scaffolding technologies. The resulting genome assembly (312.42 Mb) is anchored on 20 chromosomes, with a Scaffold N50 of 18.72 Mb. In total, 49,074 genes and 306,768 repeat sequences were annotated in the assembled genome. The first chromosome-scale genome of Zoysia japonica 'Compadre' provides a critical genetic resource for cold-tolerant turfgrass breeding through identifying stress-responsive candidate genes. Additionally, we have successfully established a cell nucleus extraction and library construction protocol tailored for zoysiagrass ATAC-seq technology, and a total of 80 low temperature tolerance candidate genes were preliminarily identified via ATAC-seq and RNA-seq profiling, thereby initiating the exploration of turfgrass epigenomics.

The P-type ATPase gene AHA5 is involved in proanthocyanidins accumulation in Medicago truncatula

Proanthocyanidins (PAs) are the second most abundant plant phenolic natural products. The proton membrane H+-ATPase (AHA) is required for PA transportation in vacuoles, but it remains unclear which AHA gene(s) encode tonoplast proton pump in M. truncatula. Here, we identified three Tnt1 mutant lines of MtAHA5, resulting in PAs deficit in seeds. MtAHA5 was preferentially expressed in developing seeds, exhibiting its highest transcript levels at early stages. Although MtAHA3, MtAHA4, and MtAHA9 shared similar transcript patterns with MtAHA5 and other structural genes involved in PA biosynthesis, their mutant lines did not exhibit any PA-deficit phenotypes. Subcellular localization analysis demonstrated that MtAHA5 is targeted to the tonoplast in tobacco leaves; conversely, MtAHA3 and MtAHA9 are localized to the cytoplasm, suggesting that MtAHA5 acts as a tonoplast proton pump but not MtAHA3 or MtAHA9. Further genetic analyses revealed that MtAHA5 could complement the PA-deficit phenotype in mtaha5 mutants and ataha10 mutants. Transient transcription assays indicated that MtAHA5 is activated by the MBW complex to regulate the PA accumulation. Collectively, our findings suggest that MtAHA5 serves as a tonoplast proton pump to generate the driving force for MATE1-mediated transport of PA precursors into vacuoles.

Optimizing a modified cetyltrimethylammonium bromide protocol for fungal DNA extraction: Insights from multilocus gene amplification

Genomic DNA (gDNA) extraction is an important step in many molecular studies of fungal biology, and it is necessary to evaluate the efficiency, cost-effectiveness, and efficacy of different extraction methods to ensure successful amplification of the target gene and minimize deoxyribonucleic acid (DNA) degradation. The modified cetyltrimethylammonium bromide (CTAB) method was found to be effective in releasing high molecular weight gDNA with minimal protein contamination. Based on anticipated gDNA yield and quality, extraction time, cost effectiveness, successful amplification, and waste management, our findings serve as a guide for selecting techniques of gDNA extraction from fungal species. This study presents a modified CTAB method for extracting DNA from a variety of fungal species including Aspergillus, Penicillium, Alternaria, Dothiorella, and Fusarium. Comparison of three cell crushing methods reveals similar gDNA yields, demonstrating the method's effectiveness. Furthermore, the modified CTAB method is cost-effective and safe, eliminating the need for grinding with liquid nitrogen or bead beating. The method has a potential use for nucleic-based fungal disease diagnosis such as fish fungal diseases, plant pathogens, fruit rot associated pathogens, and human fungal diseases as we were successful in PCR amplifying several gene loci from varied fungal pathogens.

Characterization, Genome Sequencing, and Development of a Rapid PCR Identification Primer for Fusarium oxysporum f. sp. crocus, a New forma specialis Causing Saffron Corm Rot

Saffron corm rot (SCR), the most serious disease affecting saffron, has been confirmed to be caused by Fusarium oxysporum in previous studies. Compared to other fungal species, F. oxysporum exhibits host specialization, a special phenomenon associated with the secreted in xylem (SIX) genes. This study examined the pathogenicity specialization of F. oxysporum isolated from saffron corms with SCR disease. The results showed that this F. oxysporum strain was strongly pathogenic to saffron corms, causing SCR; weakly pathogenic to the corms of freesia, which is in the Iridaceae family along with saffron; and not pathogenic to watermelon, melon, and tomato. Other formae speciales of F. oxysporum were not pathogenic to saffron corms. This suggests that F. oxysporum saffron strains exhibit obvious pathogenicity specialization for Iridaceae spp. Subsequently, the F. oxysporum saffron strain (XHH35) genome was sequenced, and a comparative genomics study of XHH35 and three other formae speciales was conducted using OrthoVenn3. XHH35 contained 90 specific genes absent in the other three formae speciales. These genes are involved in certain key biological processes and molecular functions. Based on BLAST homology searching, the F. oxysporum saffron strain (XHH35) genome was predicted to contain seven SIX genes (SIX 4, SIX 6, SIX 7, SIX 10, SIX 11, SIX 12, and SIX 14) highly homologous to F. oxysporum f. sp. lycopersici, which was verified using polymerase chain reaction (PCR) amplification. The corresponding individual phylogenetic tree indicated that the F. oxysporum saffron strain (XHH35) showed a separate branch with different formae speciales. This study is the first-ever report of F. oxysporum f. sp. crocus, a new forma specialis. Based on the specificity of its SIX genes, the SIX 10 gene was selected to further establish a rapid identification technique for F. oxysporum f. sp. crocus, which will be useful in future research.

Genetic insights into superior grain number traits: a QTL analysis of wheat-Agropyron cristatum derivative pubing3228

BACKGROUND

Agropyron cristatum (L.) is a valuable genetic resource for expanding the genetic diversity of common wheat. Pubing3228, a novel wheat-A. cristatum hybrid germplasm, exhibits several desirable agricultural traits, including high grain number per spike (GNS). Understanding the genetic architecture of GNS in Pubing3228 is crucial for enhancing wheat yield. This study aims to analyze the specific genetic regions and alleles associated with high GNS in Pubing3228.

METHODS

The study employed a recombination inbred line (RIL) population derived from a cross between Pubing3228 and Jing4839 to investigate the genetic regions and alleles linked to high GNS. Quantitative Trait Loci (QTL) analysis and candidate gene investigation were utilized to explore these traits.

RESULTS

A total of 40 QTLs associated with GNS were identified across 16 chromosomes, accounting for 4.25-17.17% of the total phenotypic variation. Five QTLs (QGns.wa-1D, QGns.wa-5 A, QGns.wa-7Da.1, QGns.wa-7Da.2 and QGns.wa-7Da.3) accounter for over 10% of the phenotypic variation in at least two environments. Furthermore, 94.67% of the GNS QTL with positive effects originated from Pubing3228. Candidate gene analysis of stable QTLs identified 11 candidate genes for GNS, including a senescence-associated protein gene (TraesCS7D01G148000) linked to the most significant SNP (AX-108,748,734) on chromosome 7D, potentially involved in reallocating nutrients from senescing tissues to developing seeds.

CONCLUSION

This study provides new insights into the genetic mechanisms underlying high GNS in Pubing3228, offering valuable resources for marker-assisted selection in wheat breeding to enhance yield.

Chromosome-scale genome assembly-assisted identification of Mi-9 gene in Solanum arcanum accession LA2157, conferring heat-stable resistance to Meloidogyne incognita

Root-knot nematodes (RKNs) are infamous plant pathogens in tomato production, causing considerable losses in agriculture worldwide. Mi-1 is the only commercially available RKN-resistance gene; however, the resistance is inactivated when the soil temperature is over 28 °C. Mi-9 in wild tomato (Solanum arcanum LA2157) has stable resistance to RKNs under high temperature but has not been cloned and applied. In this study, a chromosome-scale genome assembly of S. arcanum LA2157 was constructed through Nanopore and Hi-C sequencing. Based on molecular markers of Mi-9 and comparative genomic analysis, the localization region and candidate Mi-9 genes cluster consisting of seven nucleotide-binding sites and leucine-rich repeat (NBS-LRR) genes were located. Transcriptional expression profiles confirmed that five of the seven candidate genes were expressed in root tissue. Moreover, virus-induced gene silencing of the Sarc_034200 gene resulted in increased susceptibility of S. arcanum LA2157 to Meloidogyne incognita, and genetic transformation of the Sarc_034200 gene in susceptible Solanum pimpinellifolium conferred significant resistance to M. incognita at 25 °C and 30 °C and showed hypersensitive responses at nematode infection sites. This suggested that Sarc_034200 is the Mi-9 gene. In summary, we cloned, confirmed and applied the heat-stable RKN-resistance gene Mi-9, which is of great significance to tomato breeding for nematode resistance.