Research Article
Role of Cyanobacteria in Improving Fertility of Saline Soil
Bangladesh Rice Research Institute, Gazipur, Bangladesh.
M. A. Hashem
Soil Science Department, Bangladesh Agricultural University, Mymensingh, Bangladesh
Soil salinity appears to be a major problem in Bangladesh agriculture. Agricultural land use In saline areas is very poor, which is much lower than the country's average cropping intensity (Banu et al., 1993 ). Rice production in the country has been seriously hampered by the high soil salinity and this problem is becoming more serious every year (Hashem et al., 1995). Improving the fertility of the saline soil is an utmost necessary from the agriculture point of view. The saline soil of Bangladesh have been managing by the farmers themselves using the impact of monsoon rains during the salinity and allowing easy cultivation of transplanted aman rice. Soils which contain sufficient neutral soluble salts in the root zone to adversely affect crop growth and production are termed saline soils (Hashem, 2001). Soluble salts are predominantly the chlorides and sulphates of sodium, calcium and magnesium. Sodium chloride is the dominant salt. The saturated paste pH of saline soil is less than 8.5 and the electrical conductivity of the saturation extract is generally more than 4 dS m1 at 25°C. Saline soils are not suitable for crop production although they have high agriculture potential (Hashem, 2001). The present study has been planned with the following objectives: 1.To identify the Cyanobacterial strains occurring in saline soils.2. To determine the role of cyanobacteria in improving fertility of saline soil.
There are reports that some cyanobacteria can grow successfully on saline soil where most plants with the exception of halophytes fail to grow. The fertility of saline soil can be improved by using cyanobacteria. Soil based cyanobacterial inoculum that are prepared from saline soils and that are adopted to areas ecological problem may effectively be used in N economy and improved fertility of these soils.
The experiment was conducted at Shymnagar, Satkhira during the T. Aman season of 2000. The experimental plot belongs to non-calcareous Grey Floodplain. The soil was leam with pH 7.9, organic matter 1.93%, total nitrogen 0.18%, available P 18.3 ppm and available S 14.5 ppm. Soil texture, pH, Organic matter, total nitrogen, available P and S were determined following standard methods (Black, 1965; Jackson, 1962; Page et al., 1982; Olsen et al., 1954). The experiment consisted of six treatments comprising T1 = Control, T2 = Recommended Fertilizer Dose (RFD), T3 = RFD-20%N, T4 = RFD-20%N+Cyanobacteria, T5 = RFD-40% N and T6 = RFD-40%N+Cyanobacteria. The experiment was laid out in randomized complete block design (RCBD) with four replications having unit plot size of 5x4 m2 . The fertilizer rates used were 65 kg N ha1 from urea, 8 Kg P ha1 from triple superphosphate, 30 Kg K ha1 from muriate of potash and 5 kg S ha-from gypsum. Urea was applied in three equal splits-first during final land preparation and the remaining in two equal splits at maximum tillering and panicle initiation stages of crop growth. Cyanobacterial inoculum was applied @ 20 kg ha1 in two split-7 and 30 days after transplanting. The rice variety used was BRRIdhan 31 as test crop. Thirty five days old seedling were transplanted on 4 Aug. 2000, maintaining a spacing 20x15 cm2, three seedling being transplanted hill1. Necessary intercultural operations were done as and when required during growth period of crop. The crop was harvested plot wise on 17 Dec. 2000. The yield components and yield were recorded. All the parameters under study were statistically analyzed by F-test to examine the treatment effects and the mean difference were adjudged by Dancan's multiple range test (DMRT) (Gomez and Gomez 1984).
Organic matter: The organic matter content of the post harvest soils varied from 1.82 to 2.02%. The organic matter content of initial soil was 1.93%. It was observed that organic matter content tended to increase in the soils treated with T4 (RFD-20% N+Cyanobacteria) and T6 (RFD-40% N+Cyanobacteria). T1 (control), T2 (RFD), T3 (RFD20% N) and T5 (R-FD-40% N) caused a decreasing effect of organic matter. All these 4 treatments did not contain cyanobacterial inoculum The highest Value of organic matter was found in T6 (RFD-40% N+Cyanobacteria) which was statistically identical with T4 (RFD20%N+Cyanobacteria). The lowest organic matter content was in T2 (RFD) which was statistically identical with T1 (control), T3 (RFD-20% N) and T5 (RFD-40% N). The increase in organic matter contents in treatments T4 and T6 (both the treatment contained cyanobacterial inoculum) clearly indicated that this increase was due to application of cyanobacteria.
Table 1: | Effect of cyanobacterial inoculum on organic matter and total nitrogen contents of the post harvest experimental soils |
In a column, the figures having common letter(s) do not differ significantly at 5% level of significance |
Total nitrogen: The application of different treatments caused a slight variation in the total N content of the post harvest soils compared to the initial soil. The initial status of total nitrogen was 0. 18%. The maximum total nitrogen in post harvest soil was in treatment T4 which was statistically identical with T1 (control), T2 (RFD), T3 (RFD-20% N) and T6 (RFD-40% N+Cyanobacteria). The lowest value of 0. 14% was found in T5 (RFD-40% N).
Banu et al. (1993) observed that Nostoc H.17, Scytonema H.26 and Fischerella H.39 fixed high amount of nitrogen under high saline conditions.
A good number of reports also support that cyanobacteria can fix a significant amount of atmospheric nitrogen eg. Roger and Kulasooriya (1980) described that the generally accepted amount of N fixed by cyanobacteria is on average 30-40 kg ha1 crop1 (Table 1).
Table 2: | Effect of cyanobacterial inoculum on available phosphorus and sulphur contents of the post harvest experimental soils |
Available phosphorus: Available P content of post harvest soils was not significantly influenced by different treatments though treatments having cyanobacterial Inoculum showed higher amount of nitrogen than those having no inoculum. Available P content varied from 17.4 to 19.1 ppm. Available P content of initial soil was 18.3 ppm. The highest P content of 19.1 ppm was recorded in T6 (RFD-40% N+Cyanobacteria). The lowest P content was noted in T1(control) (Table 2).
Available sulphur: Soil available S was not significantly affected due to application of the cyanobacterial isolates. Nevertheless, plots treated with cyanobacterial inoculum had little higher S content than those having no inoculum The S content of post harvest soil ranged from 14.0 to 15.8 ppm. The maximum S content of post harvest soil was recorded in treatment T4 (RFD20% N+Cyanobacteria) and the lowest was noted in the control.