AUTHOR=Palanog Alvin D. , Nha Chau Thanh , Descalsota-Empleo Gwen Iris L. , Calayugan Mark Ian , Swe Zin Mar , Amparado Amery , Inabangan-Asilo Mary Ann , Hernandez Jose E. , Sta. Cruz Pompe C. , Borromeo Teresita H. , Lalusin Antonio G. , Mauleon Ramil , McNally Kenneth L. , Swamy B. P. Mallikarjuna 

TITLE=Molecular dissection of connected rice populations revealed important genomic regions for agronomic and biofortification traits

JOURNAL=Frontiers in Plant Science

VOLUME=14

YEAR=2023

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2023.1157507

DOI=10.3389/fpls.2023.1157507

ISSN=1664-462X

ABSTRACT=<p>Breeding staple crops with increased micronutrient concentration is a sustainable approach to address micronutrient malnutrition. We carried out Multi-Cross QTL analysis and Inclusive Composite Interval Mapping for 11 agronomic, yield and biofortification traits using four connected RILs populations of rice. Overall, MC-156 QTLs were detected for agronomic (115) and biofortification (41) traits, which were higher in number but smaller in effects compared to single population analysis. The MC-QTL analysis was able to detect important QTLs viz: <italic>qZn<sub>5.2</sub>, qFe<sub>7.1</sub>, qGY<sub>10.1</sub>, qDF<sub>7.1</sub>, qPH<sub>1.1</sub>, qNT<sub>4.1</sub>, qPT<sub>4.1</sub>, qPL<sub>1.2</sub>, qTGW<sub>5.1</sub>, qGL<sub>3.1</sub></italic>, and <italic>qGW<sub>6.1</sub></italic>, which can be used in rice genomics assisted breeding. A major QTL (<italic>qZn<sub>5.2</sub></italic>) for grain Zn concentration has been detected on chromosome 5 that accounted for 13% of R<sup>2</sup>. In all, 26 QTL clusters were identified on different chromosomes. <italic>qPH<sub>6.1</sub></italic> epistatically interacted with <italic>qZn<sub>5.1</sub></italic> and <italic>qGY<sub>6.2</sub></italic>. Most of QTLs were co-located with functionally related candidate genes indicating the accuracy of QTL mapping. The genomic region of <italic>qZn<sub>5.2</sub></italic> was co-located with putative genes such as <italic>OsZIP5</italic>, <italic>OsZIP9</italic>, and <italic>LOC_OS05G40490</italic> that are involved in Zn uptake. These genes included polymorphic functional SNPs, and their promoter regions were enriched with <italic>cis</italic>-regulatory elements involved in plant growth and development, and biotic and abiotic stress tolerance. Major effect QTL identified for biofortification and agronomic traits can be utilized in breeding for Zn biofortified rice varieties.</p>