Huihui Li

Oct 4, 2024 | nature.com | Dawei Li |Yao Zhou |Huihui Li |Wanneng Yang |Sanwen Huang

AbstractThe genetic analysis of potato is hampered by the complexity of tetrasomic inheritance. An ongoing effort aims to transform the clonally propagated tetraploid potato into a seed-propagated diploid crop, which would make genetic analyses much easier owing to disomic inheritance. Here, we construct and report the large-scale genetic and heterotic characteristics of a diploid F2 potato population derived from the cross of two highly homozygous inbred lines.

Jul 1, 2024 | onlinelibrary.wiley.com | Jingjing Wang |Yani Wang |Huihui Li |Weijing Wang

CONFLICT OF INTEREST STATEMENT The authors declare no conflicts of interest. Supporting Information Filename Description jcpe14039-sup-0001-Supinfo.docxWord 2007 document , 650.1 KB Data S1. Supporting information. REFERENCES , , , & (2016). Validity of self-reported periodontal disease: A systematic review and meta-analysis. Journal of Periodontology, 87(12), 1474–1483. https://doi.org/10.1902/jop.2016.160196 , , & (2022).

Oct 9, 2023 | nature.com | Huihui Li |Li Wang |CHEN CHEN

AbstractFulminant myocarditis (FM) is a life-threatening inflammatory disease. However, the mechanisms underlying its acute onset are unknown. By dynamic cardiac function measurement, we discovered that the initiation of sudden hemodynamic collapse was on day 4 in the mouse model of FM.

Aug 25, 2023 | nature.com | Xi Wang |Huihui Li

AbstractGenetic dissection of agronomic traits is important for crop improvement and global food security. Phenotypic variation of tassel branch number (TBN), a major breeding target, is controlled by many quantitative trait loci (QTLs). The lack of large-scale QTL cloning methodology constrains the systematic dissection of TBN, which hinders modern maize breeding.

Aug 17, 2023 | nature.com | César D. Petroli |Guntur V. Subbarao |Juan Burgueno |Tadashi Yoshihashi |Huihui Li |Jorge Duran | +1 more

AbstractBiological nitrification inhibition (BNI) is a plant function where root systems release antibiotic compounds (BNIs) specifically aimed at suppressing nitrifiers to limit soil-nitrate formation in the root zone. Little is known about BNI-activity in maize (Zea mays L.), the most important food, feed, and energy crop. Two categories of BNIs are released from maize roots; hydrophobic and hydrophilic BNIs, that determine BNI-capacity in root systems.