Search Results

You are looking at 61 - 70 of 83 items for :

  • "growth enhancement" x
  • Refine by Access: All x
Clear All
Open access

Shuming Ju, Lingzhen Ji, and Delan Xu

effects of promoting high growth, enhancing apical dominance, and delaying senescence ( Yan et al., 2010 ). Studies of the seasonal dynamic change of GA content in plants such as Actinidia arguta ( Yuan et al., 2020 ) and Lilium longiflorum ( Sivaci

Free access

Liang Cheng, Ning Zhang, and Bingru Huang

. Yousaf, S. Pastar, M. Afzal, M. Sessitsch, A. 2014 The endophyte Enterobacter sp. FD17: A maize growth enhancer selected based on rigorous testing of plant beneficial traits and colonization characteristics Biol. Fertil. Soils 50 249 262 Penrose, D

Free access

Chenping Xu and Beiquan Mou

., 2008 ). Compost can improve soil microorganism and colonization of root by arbuscular mycorrhizal fungi ( Montalba et al., 2010 ; Suárez-Estrella et al., 2007 ). Growth enhancement by compost amendment might also attribute to its humic substances

Free access

Maria L. Burgos-Garay, Chuanxue Hong, and Gary W. Moorman

aphanidermatum by Sphingobium sp. ( B ) Microscopic view (10×) of wet appearing P. irregulare hyphae caused by the attachment of Pseudomonas sp. ( C ) P. cryptoirregulare growth enhancing effect by Cupriavidus sp. in NA media. Table 1. Identity and

Free access

Andreas Westphal, Nicole L. Snyder, Lijuan Xing, and James J. Camberato

growth-enhancing effect that was not quantifiable with the parameters measured. Perhaps general stress suppression was responsible for improvements in early plant growth and early fruit yield. Colonization rates in a study with watermelon and G. clarum

Free access

Mason T. MacDonald, Rajasekaran R. Lada, A. Robin Robinson, and Jeff Hoyle

properties Seed Sci. Res. 10 329 339 Darlington, A. Vishnevetskaia, K. Blake, T.J. 1996 Growth enhancement and anti-transpirant activity following seed treatment with a derivative of 5-hydroxybenzimidazole

Free access

Liyuan Huang, Jun Yuan, Hui Wang, Xiaofeng Tan, and Genhua Niu

showing any symptom of Al toxicity. For example, buckwheat leaves can accumulate as much as 10 g·kg −1 Al in the leaves in 12 weeks ( Shen et al., 2006 ). Al (0.5 m m )-induced improvements of the root activity contributed to a growth enhancement in

Free access

Xin Zhao, Qianru Liu, M. Tatiana Sanchez, and Nicholas S. Dufault

noninoculated, nongrafted controls in the 2016 experiment ( Table 3 ). Considering that the plant growth and root measurements were only conducted at the flowering stage in the greenhouse experiments, it is likely that the advantage of growth enhancement in

Free access

Lesley A. Judd, Brian E. Jackson, Ted C. Yap, and William C. Fonteno

pine bark. However, these observations were quantified with root dry weights or subjective ratings, so the extent of the apparent root growth enhancement remains to be accurately quantified and explained. Further investigations of plant root growth in

Open access

Zhibin Fan, Kai Zhang, Fengyun Wang, Xiaodan Zhao, Ruiqin Bai, and Boling Liu

growth, enhanced synthesis of secondary metabolites ( Wu et al., 2001 ; Zhang et al., 2013 ), and provided tolerance against fungal diseases ( Liu et al., 2008 ). Previous studies have also found that the addition of biotic elicitors and heavy metal