Identification of rhizospheric microorganisms associated with sorghum

Tshabuse, Freedom

January 2012

>Magister Scientiae - MSc / Approximately 50% of sorghum (Sorghum bicolour (L.) Moench) produced globally is used as human food, with 95% of its total consumption occurring in Africa. Unfortunately, sorghum crops are prone to pathogenic attack, notably leading to a reduction in production yields. Generally, chemical agents are used as fertilizers and/or biocides to increase crop production. However, these chemicals can have a detrimental environmental impact including the eutrophication of fresh water and marine ecosystems. Thus, there is increased interest in plant growth promoting rhizobacteria (PGPR), as an alternative to chemicals, to facilitate eco-friendly biological control of soil-borne pathogens. PGPRs colonize the plant root system (i.e rhizosphere and rhizoplane) and promote growth and production yields essentially via the biological control of plant pathogens and their role in the nutrient cycles (e.g N fixation). The aim of this study is to characterize the microbial communities associated with sorghum in South Africa, and to identify common bacteria which could further be developed and applied to improve sorghum growth and yield. Sorghum rhizospheric environments (rhizoplane and rhizosphere) were collected from three sites characterized by different agricultural practices (Free State, Limpopo and North West). Denaturing gradient gel electrophoresis (DGGE) and Terminal-restriction fragment length polymorphism (T-RFLP) were used to identify microbial community molecular fingerprints. Sorghum-associated microbial communities were found to be different in all rhizospheric soil samples which could be explained by differences in soil chemistry, agricultural practices and geographical location. The analyses also clearly demonstrated that the sorghum bacterial community structures were similar in the rhizoplane, indicating the strong influence that the sorghum plant has in determining the rhizoplane colonizers. The archaeal community structure from rhizoplane and rhizosphere in each sampling site were dissimilar, which could be explained by differences in soil type and/or agricultural practices. Both the T-RFLP and DGGE analyses revealed that Bacillus sp. were consistently associated with South African Sorghum, Arthrobacter sp. were detected in the rhizoplane, while Uncultured archaea were detected in the rhizoplane of sorghum. These microorganisms represent valuable targets for engineering to promote growth and yield in sorghum.

Rhizobacteria

Sorghum

Rhizoplane

Rhizospheric microorganisms

The Study of Phytoremediation of PCP Contaminated Soil

Cheng, Hsiu-chen

25 January 2006

In this study, the phytoremediation techniques are used to treat the soil contaminated by pentachlorophenol(PCP).First, four plants species were selected,including Allium tuberosum, Vigna radiata (L.) Wilczek, Pennisetum alopecuroides, and Medicago sativa to compare their treatment efficiencies for PCP in soil.The experimental results showed that the species of Allium tuberosum presented the highest degradation rate 76% after 35-day test run with the initial concentration of 20mg/kg in soil. In the second stage,the species of Allium tuberosum was thus selected to run the tests of feasibility of using phytoremediayion to treat the soils contaminated byPCP.During the e xperiment,the pot tests inside a greenhouse were run for 330 days.The result indicated that the species of Allium tuberosum contributed to the increase of microorganism and dehydrogenase activity in the soil. Bisides,we also found that adding with nutrients could help Allium tuberosum to depress the PCP stress.The test with vegetation of Allium tuberosum and addition of nutrients showed that the PCP degradation rate was measured equal to 98.4% with the concentration of PCP degraded from 42mgkg-1 to 0.68mgkg-1 after 330days. Finally, molecule biotechnology of PCR-DGGE was applied to the test of observing the microbiota in the soils.According to the test results,we found that the diversity of microorganisms could be raised through planting the species of Allium tuberosum. The microbiota in the soils with PCP pollutant have more varieties than the microbiota in soils without vegetation, which was infered that the addition of PCP might stimulate the vitality of microbes in the soils. Moreover, comparing the microbiota on rhizosphere of the plant species and in the bulk soils, it was found that the actitivies of root exudates might be able to increase the varieties of rhizospheric microorganisms.

Phytoremediation

PCP

PCR/DGGE

rhizospheric microorganisms

pentachlorophenol