[Effects of three intercropping species on growth, nutrition absorption, and fruit quality of oriental melon]. / 3ç§é—´ä½œæ¤ç‰©å¯¹è–„çš®ç”œç“œæ¤æ ªç”Ÿé•¿ã€è¥å »å¸æ”¶å’Œæžœå®žå“è´¨çš„å½±å“.

To explore the effects of different intercropping species on growth, nutrition absorption, and fruit quality of oriental melon, we examined plant height, stem diameter, root activity, contents of mineral elements (N, P, K, Ca and Mg), and fruit quality and yield of oriental melon under the oriental melon monoculture (MM), intercropping of fennel/oriental melon (FM), tillered-onion/oriental melon (TM), or wormwood/oriental melon (WM). Results showed that plant height of intercropping treatments was significantly higher than that of the monoculture over time. The stem diameter of the FM and TM treatments was significantly higher than that of the MM treatment, while there was no significant difference between the WM and MM treatments. At the stretch tendril stage, fruit setting stage, and fruit expanding stage, root activity of FM treatment was significantly higher than that of MM and TM treatments. The mine-ral elements contents of oriental melon plants in three intercropping treatments were higher than that in MM treatment in different degrees, with the mine-ral elements contents of FM treatment being higher than that of TM and WM treatments. The single fruit weights of FM and TM treatments did not differ from the MM treatment. The fruit quality indices of FM treatment were not lower than MM treatment, while some fruit quality indices (including the contents of glucose, fructose, and sucrose) of WM and TM treatments were lower than that under MM treatment. In summary, fennel was a suitable species for intercropping with the oriental melon.

Grafting helps improve photosynthesis and carbohydrate metabolism in leaves of muskmelon.

The most important quality for muskmelon (Cucumis melo L.) is their sweetness which is closely related to the soluble sugars content. Leaves are the main photosynthetic organs in plants and thus the source of sugar accumulation in fruits since sugars are translocated from leaves to fruits. The effects of grafting muskmelon on two different inter-specific (Cucurbita maxima×C. moschata) rootstocks was investigated with respect to photosynthesis and carbohydrate metabolism. Grafting Zhongmi1 muskmelon on RibenStrong (GR) or Shengzhen1 (GS) rootstocks increased chlorophyll a, chlorophyll b and chlorophyll a+b content and the leaf area in middle and late developmental stages of the plant compared to the ungrafted Zhongmi1 check (CK). Grafting enhanced the net photosynthesis rate, the stomatal conductance, concentration of intercellular CO(2) and transpiration rate. Grafting influenced carbohydrates contents by changing carbohydrate metabolic enzymes activities which was observed as an increase in acid invertase and neutral invertase activity in the functional leaves during the early and middle developmental stages compared to CK. Grafting improved sucrose phosphate synthase and stachyose synthase activities in middle and late developmental stages, thus translocation of sugars (such as sucrose, raffinose and stachyose) in GR and GS leaves were significantly enhanced. However, compared with CK, translocation of more sugars in grafted plants did not exert feedback inhibition on photosynthesis. Our results indicate that grafting muskmelon on inter-specific rootstocks enhances photosynthesis and translocation of sugars in muskmelon leaves.