A number of traits have been identi

A number of traits have been identified that are important
components of salt tolerance in rice and for which it is
possible to screen. Yeo & Flowers (1983) found a strong
negative relationship between leaf Na+ concentrations and
survival of seedlings growing in 50 mm NaCl for 6 d. Successful
selection of high- and low-Na+-transporting lines
within varieties of rice IR36 and IR20, by sampling Na+
concentrations in leaf 3 after exposure to 25–50 mm NaCl
for 6 d, has been reported (Yeo,Yeo & Flowers 1988).Akita
& Cabuslay (1990) proposed using leaf area ratio (LAR:
leaf area per total dry weight) as a screening criterion for
salt tolerance as the authors found that salt-tolerant Pokkali
and Nona Bokra had relatively lower LAR than saltsensitive
IR8 and IR50. Yeo et al. (1990) evaluated a wide
range of physiological characteristics, including shoot Na+
concentration, leaf-to-leaf compartmentation, tissue tolerance
and plant vigour, to identify salt resistance in a large
number of rice genotypes and found that plant vigour, providing
dilution of salt concentrations by growth, was more
strongly correlated with seedling survival than the other
traits. Aslam, Qureshi & Ahmed (1993) also evaluated the
criteria for salt tolerance assessment in rice based on
growth parameters (e.g. shoot and root fresh weights, shoot
and root lengths, and number of tillers) and reported a
positive significant relationship between shoot fresh weight
at the seedling stage and paddy yield of rice grown under
saline conditions. They indicated that absolute shoot fresh
weight and relative shoot fresh weight (percent of control)
could be used as the selection criteria of salt tolerance.
Later, Asch et al. (2000) reported a positive correlation
between K+/Na+ ratio of the youngest three leaves and grain
yield of rice genotypes I Kong Pao, IR64, IR4630, IR31785,
ITA 306 and IR28 after irrigation with saline water (EC