페레니얼 라이그라스에서 Mycorrhiza 접종이 탄수화물대사와 가뭄스트레스 저항성에 미치는 영향 Mycorrhizal colonization effects on C metabolism in relation to drought-tolerance of perennial ryegrass원문보기
Mycorrhiza 접종이 페레니얼 라이그라스가 가뭄 스트레스 저항성에 대한 효과를 검증하기 위해 mycorrhiza 접종구(AM)와 mycorrhiza를 접종하지 않은 비접종구 (non-AM)를 정상적 토양 수분 (-0.04Mpa) 및 가뭄 스트레스 (-0.12MPa)를 각각 처리한 후 0.14 및 28일에 잎의 수분포텐셜, 인의 함량, 작물의 성장 및 탄수화물 농도를 분석하였다. 가뭄 스트레스구에서 잎의 수분포텐셜, 클로로필, 인의 함량 및 잎의 성장이 유의적으로 감소되었다. 가뭄에 의한 이러한 생리적 장해요인들은 mycorrhiza 접종에 의해 완화되었다. 가뭄 스트레스하에서 잎의 soluble sugar 농도는 감소 되었으며, AM 처리구는 non-AM 처리구보다 soluble sugar 농도는 높게 나타났다. 가뭄 스트레스하에서 지상부의 starch와 fructan의 축적은 가뭄 스트레스 하에서 감소되는 반면 뿌리에서는 증가하였다. 가뭄 스트레스 하에서 뿌리에서 starch의 농도는 non-AM 처리구에서 AM처리구보다 더 높게 나타났다. 가뭄 스트레스 하에서 잎의 fructan 농도는 약간 감소하였으나 뿌리에서는 현저히 증가하였다. 가뭄 스트레스 하에서 처리 후 28일째 fructan의 농도는 정상적 수분공급구와 비교해 볼 때 non-AM과 AM 잎에서 각각 18.7% 와 13.3% 낮았다. 뿌리에서 가뭄스트레스에 의한 fructan의 축적은 mycorrhiza 접종에 의해 약 14% 감소되었다. 이상의 결과들은 mycorrhiza 접종은 잎의 수분 포텐셜과 인의 함량을 더 높게 유지하게 하고, soluble sugar의 함량을 더 많이 보유하게 함으로써 작물의 가뭄에 대한 내성을 증가 시킴을 잘 보여 주었다.
Mycorrhiza 접종이 페레니얼 라이그라스가 가뭄 스트레스 저항성에 대한 효과를 검증하기 위해 mycorrhiza 접종구(AM)와 mycorrhiza를 접종하지 않은 비접종구 (non-AM)를 정상적 토양 수분 (-0.04Mpa) 및 가뭄 스트레스 (-0.12MPa)를 각각 처리한 후 0.14 및 28일에 잎의 수분포텐셜, 인의 함량, 작물의 성장 및 탄수화물 농도를 분석하였다. 가뭄 스트레스구에서 잎의 수분포텐셜, 클로로필, 인의 함량 및 잎의 성장이 유의적으로 감소되었다. 가뭄에 의한 이러한 생리적 장해요인들은 mycorrhiza 접종에 의해 완화되었다. 가뭄 스트레스하에서 잎의 soluble sugar 농도는 감소 되었으며, AM 처리구는 non-AM 처리구보다 soluble sugar 농도는 높게 나타났다. 가뭄 스트레스하에서 지상부의 starch와 fructan의 축적은 가뭄 스트레스 하에서 감소되는 반면 뿌리에서는 증가하였다. 가뭄 스트레스 하에서 뿌리에서 starch의 농도는 non-AM 처리구에서 AM처리구보다 더 높게 나타났다. 가뭄 스트레스 하에서 잎의 fructan 농도는 약간 감소하였으나 뿌리에서는 현저히 증가하였다. 가뭄 스트레스 하에서 처리 후 28일째 fructan의 농도는 정상적 수분공급구와 비교해 볼 때 non-AM과 AM 잎에서 각각 18.7% 와 13.3% 낮았다. 뿌리에서 가뭄스트레스에 의한 fructan의 축적은 mycorrhiza 접종에 의해 약 14% 감소되었다. 이상의 결과들은 mycorrhiza 접종은 잎의 수분 포텐셜과 인의 함량을 더 높게 유지하게 하고, soluble sugar의 함량을 더 많이 보유하게 함으로써 작물의 가뭄에 대한 내성을 증가 시킴을 잘 보여 주었다.
To investigate the effects of arbuscular mycorrhizal (AM) fungus (Glomus intraradices) colonization on drought-stress tolerance, leaf water potential, chlorophyll concentration, P content and carbohydrate composition were examined in perennial ryegrass (Lolium perenne L.) plants exposed to drought-s...
To investigate the effects of arbuscular mycorrhizal (AM) fungus (Glomus intraradices) colonization on drought-stress tolerance, leaf water potential, chlorophyll concentration, P content and carbohydrate composition were examined in perennial ryegrass (Lolium perenne L.) plants exposed to drought-stressed or well-watered conditions. Drought stress significantly decreased leaf water potential, P content and leaf growth. These drought-induced damages were moderated by mycorrhizal colonization. Drought stress decreased the concentration of soluble sugars in shoots. AM plants had a higher foliar soluble sugar than non-AM plants under drought stress condition. Drought stress depressed the accumulation of starch and fructan in shoots, but stimulated in roots. Under drought-stressed condition, starch concentration in roots was higher in non-AM plants than in AM plants. Fructan was the largest pool of carbohydrates, showing the highest initial concentration and the highest net increase for 28 days of treatment. Drought stress slightly decreased fructan concentration in shoots, but remarkably increased in roots. Under drought-stressed condition, fructan concentrations in non-AM and AM shoots at day 28 were 18.7% and 13.3% lower than the corresponding values measured at well-watered plants. However, in the roots, fructan accumulation caused by drought was lessen 13.6% by mycorrhizal colonization. The results obtained suggest that mycorrhizal colonization improves drought tolerance of the host plants by maintaining higher leaf water status and P status, and by retaining more foliar soluble sugars.
To investigate the effects of arbuscular mycorrhizal (AM) fungus (Glomus intraradices) colonization on drought-stress tolerance, leaf water potential, chlorophyll concentration, P content and carbohydrate composition were examined in perennial ryegrass (Lolium perenne L.) plants exposed to drought-stressed or well-watered conditions. Drought stress significantly decreased leaf water potential, P content and leaf growth. These drought-induced damages were moderated by mycorrhizal colonization. Drought stress decreased the concentration of soluble sugars in shoots. AM plants had a higher foliar soluble sugar than non-AM plants under drought stress condition. Drought stress depressed the accumulation of starch and fructan in shoots, but stimulated in roots. Under drought-stressed condition, starch concentration in roots was higher in non-AM plants than in AM plants. Fructan was the largest pool of carbohydrates, showing the highest initial concentration and the highest net increase for 28 days of treatment. Drought stress slightly decreased fructan concentration in shoots, but remarkably increased in roots. Under drought-stressed condition, fructan concentrations in non-AM and AM shoots at day 28 were 18.7% and 13.3% lower than the corresponding values measured at well-watered plants. However, in the roots, fructan accumulation caused by drought was lessen 13.6% by mycorrhizal colonization. The results obtained suggest that mycorrhizal colonization improves drought tolerance of the host plants by maintaining higher leaf water status and P status, and by retaining more foliar soluble sugars.
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가설 설정
We hypothesized that AM colonization in perennial ryegrass enhances soluble sugars that may be one of factors related to drought tolerance of host plant, when plant growth is inhibited by drought stress. To test this, we examined leaf water potential, chlorophyll and plant growth for determining the severity of drought stress, and analyzed P and carbohydrate content for investigating the metabolic responses in roots and shoots of AM and non-AM plants which had been subjected to 4 weeks of drought or to well-watered condition at full vegetative stage.
제안 방법
) seeds were sterilized and germinated on wet filter paper. Four treatment combinations [arbuscular mycorrhizal inoculation (AM) or non-AM inoculation (non-AM) under drought-stressed or well-watered condition] were replicated for three times in a randomized block design. The experimental soil containing 1% (w/w) rock phosphate and 3% (w/w) organic matter was filled into 3L pots, and then sterilized.
Each treatment lasted for 28 days. Plants samples were harvested at 0, 14 and 28 day after treatment, respectively. Harvested plants were separated into shoots and roots.
We hypothesized that AM colonization in perennial ryegrass enhances soluble sugars that may be one of factors related to drought tolerance of host plant, when plant growth is inhibited by drought stress. To test this, we examined leaf water potential, chlorophyll and plant growth for determining the severity of drought stress, and analyzed P and carbohydrate content for investigating the metabolic responses in roots and shoots of AM and non-AM plants which had been subjected to 4 weeks of drought or to well-watered condition at full vegetative stage.
이론/모형
Chlorophyll concentration was extracted in DMSO and absorbance of the extract assessed with a spectrophotometer at 663 nm and 645nm. The chlorophyll concentration was calculated using the equation of Mackinney (1941).
성능/효과
IB). After 28 days of drought condition, root P content decreased by 39.0 % and 28.2 % in non-AM and AM plant, respectively.
1A). After 28 days of treatment, mycorrhizal colonization improved shoot P status by 43.8 % and 37.6 % in well-watered and drought-stressed condition. In the roots, P content responded to drought and mycorrhizal treatment with a similar pattern observed in shoots (Fig.
2B). Comparing with well-watered condition, soluble sugar concentration in drought stressed non-AM roots was slightly increased, while that of drought-stressed AM roots was significantly decreased after 28 days of treatment.
In conclusion, mycorrhizal association had a significant effect on maintaining higher leaf water potential and P status, and on retaining more foliar soluble sugars especially under drought-stressed condition. These findings suggest that AM colonization improves drought tolerance of the host plants by maintaining higher leaf water status.
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