Many studies show that salinity tol

Many studies show that salinity tolerance is a complex trait controlled by quantitative trait loci (QTL) [4]. For example, 11 QTL for seedling survival were identified on chromosomes 1, 4, 6, 7, and 9 using a Nona Bokra × Koshihikari F2:3 population. One major QTL for shoot K+ concentration on chromosome 1 (qSKC-1) explained 40.1% of the total phenotypic variance [5]. SKC1 was subsequently map-based cloned; it encodes a Na+ transporter of the HKT type and is involved in Na+ and K+ homeostasis [6]. Another QTL, SalTol, was fine-mapped to the same region and also acts mainly to control shoot Na+/K+ homeostasis, suggesting that SKC1 may be the causal gene underlying the SalTol QTL [7]. A salt-induced gene SalT, identified previously, was found to co-localize with SalTol and was 2.4 Mb away from SKC1 [8].

Landraces are currently being exploited as preferred potential donors of abiotic stress tolerance traits because of their local adaptation [4]. For instance, favorable alleles at the SKC1 and SalTol loci were derived from indica landraces Nona Bokra [6] and Pokkali [7], respectively. With close genetic similarity to current cultivars, the tolerance traits could readily be introduced into commercial breeding lines [4].

The southern part of Bangladesh is well known for high salinity and popular landraces from the region are well adapted and regarded as possessing some resistance to salt stress, particularly at the seedling stage [9]. The situation is further increased by selection of rice landraces, which has happened in the case of association analysis using collected germplasm from this region. An evaluation of genetic diversity and identification of markers in Bangladesh rice landraces could provide useful information for genetic improvement of salt tolerance.

SSR have been the predominant molecular markers used in kinship and population studies because they are multiallelic, reproducible, PCR-based, and generally selectively neutral [10]. They can be applied for genetic diversity and association analysis of important agronomic and quality traits in rice [11], [12], [13], [14] and [15].

In the present study, 96 rice accessions from southern Bangladesh were subjected to a genetic diversity and association mapping study using SSR and STS markers. The main objective of the present study was to: 1) characterize the genetic diversity and population structure of Bangladesh rice landraces; 2) develop novel STS markers for salt-tolerance genes and confirm their effect; and 3) identify loci significantly associated with salinity tolerance in rice.