Watermelon Seedlings(西瓜苗)研究综述
Watermelon Seedlings 西瓜苗 - The bottle gourd rootstock-grafted (RG) watermelon seedlings were highly resistant to FON compared with self-grafted (SG) watermelon plants, with a disease incidence of 3. [1] NO treatments alleviated Pb toxicity by decreasing Pb translocation, enhancing root growth (elongation and biomass), inducing antioxidant enzymes activities, and reducing root MDA contents in watermelon seedlings. [2] The results showed that colonization with mycorrhiza for vegetable (VT) resulted in the highest biomass accumulation, photosynthetic rate, and dependence in watermelon seedlings. [3] Here, we describe experiments that aimed to determine whether relative humidity (RH) contribute to chilling tolerance by regulating leaf water potential in watermelon seedlings. [4] citrulli cells induced by fermented watermelon fruit juice could not be resuscitated and did not retain their virulence on watermelon seedlings. [5] In this study, watermelon seedlings were inoculated with the arbuscular mycorrhizal fungi (AMF) Funneliformis mosseae to investigate its effect on watermelon growth and development. [6] Herein, we used an isobaric tag for relative and absolute quantification (iTRAQ)-based quantitative proteomics approach for the comparative analysis of protein abundances in self-grafted (SG) and pumpkin rootstock-grafted (RG) watermelon seedlings in response to cold stress. [7] AB or MS fumigated soils under HT also decreased Fusarium wilt incidence of watermelon seedlings after artificial FON infection. [8] Watermelon seedlings were transplanted into eighteen plots. [9] In contrast, biofilm formation, swimming motility, and virulence on watermelon seedlings were significantly reduced in the furA mutant. [10] Watermelon seedlings had greater shoot length, stem diameter, cotyledon area, shoot dry weight-to-length (DW/L) ratio, and Dickson’s quality index (DQI) under T1 and T3, while leaf area and shoot dry weight (DW) had higher values under T1. [11]葫芦砧木嫁接(RG)西瓜幼苗对FON的抗性高于自嫁(SG)西瓜植株,发病率为3。 [1] NO 处理通过减少 Pb 易位、增强根系生长(伸长率和生物量)、诱导抗氧化酶活性和降低西瓜幼苗根系 MDA 含量来减轻 Pb 毒性。 [2] 结果表明,用菌根定植蔬菜(VT)导致西瓜幼苗的生物量积累、光合速率和依赖性最高。 [3] 在这里,我们描述了旨在通过调节西瓜幼苗的叶片水势来确定相对湿度 (RH) 是否有助于耐寒性的实验。 [4] 发酵西瓜果汁诱导的西瓜细胞不能复苏,对西瓜幼苗没有毒力。 [5] 本研究以西瓜幼苗接种丛枝菌根真菌(AMF) Funneliformis mosseae,研究其对西瓜生长发育的影响。 [6] 在这里,我们使用等压标签进行相对和绝对定量 (iTRAQ) 的定量蛋白质组学方法,用于比较分析自嫁 (SG) 和南瓜砧木嫁接 (RG) 西瓜幼苗对冷胁迫的蛋白质丰度。 [7] HT 下 AB 或 MS 熏蒸土壤也降低了人工 FON 感染后西瓜幼苗枯萎病的发病率。 [8] 西瓜苗移栽到十八块地。 [9] 相反,在furA突变体中,西瓜幼苗的生物膜形成、游泳运动和毒力显着降低。 [10] 西瓜幼苗在T1和T3下的茎长、茎粗、子叶面积、茎长比(DW/L)和迪克森品质指数(DQI)均较大,而叶面积和茎干重(DW)则T1 下的更高值。 [11]
Grafted Watermelon Seedlings 嫁接西瓜苗
Thus, this study developed a new grafting method for watermelon to inhibit rootstock regrowth and enhance scion growth, and this new method is cost-effective for grafted watermelon seedlings. [1] Furthermore, a combined application of esculin to the scion cotyledon and acid fuchsin to the rootstock root enabled simultaneous monitoring of the phloem and xylem connectivity in individual self-grafted watermelon seedlings. [2] To investigate the importance of light on healing and acclimatization, in the present study, grafted watermelon seedlings were exposed to darkness (D) or light, provided by blue (B), red (R), a mixture of R (68%) and B (RB), or white (W; 35% B, 49% intermediate spectra, 16% R) LEDs for 12 days. [3] The objective of this study was to set critical limits for the characterization of quality categories for grafted watermelon seedlings. [4]因此,本研究开发了一种抑制砧木再生、促进接穗生长的西瓜嫁接新方法,该新方法对嫁接西瓜苗具有成本效益。 [1] 此外,七叶苷对接穗子叶和酸性品红对砧木根的联合应用使得能够同时监测单个自嫁西瓜幼苗中韧皮部和木质部的连通性。 [2] 为了研究光照对愈合和适应的重要性,在本研究中,嫁接的西瓜幼苗暴露在黑暗(D)或光照下,由蓝色(B)、红色(R)、R(68%)和B (RB) 或白色 (W; 35% B, 49% 中间光谱, 16% R) LED 12 天。 [3] 本研究的目的是为嫁接西瓜幼苗质量类别的表征设定关键限制。 [4]
Old Watermelon Seedlings 老西瓜苗
Koch's postulates were verified on 15-day-old watermelon seedlings and mature fruit. [1] To confirm their pathogenicity, two-week-old watermelon seedlings (cv. [2]Koch 的假设在 15 天大的西瓜幼苗和成熟果实上得到验证。 [1] 为了确认它们的致病性,两周大的西瓜幼苗(cv. [2]