[1] Munns, R. (2005). Genes and salt tolerance: bringing them together. New Phytologist, 167(3): 645-663. [2] Zhang, B. , Pan, X. , Cobb, G. P. , & Anderson, T. A. (2006). Plant microrna: a small regulatory molecule with big impact. Developmental Biology, 289(1): 3-16. [3] Jones-Rhoades, M. W. , Bartel, D. P. , & Bartel, B. (2006). Micrornas and their regulatory roles in plants. Annual Review Of Plant Biology, 57(1): 19-53. [4] Chai, J. , Feng, R. , Shi, H. , Ren, M. , Zhang, Y. , & Wang, J. (2015). Bioinformatic identification and expression analysis of banana micrornas and their targets. PLOS ONE, 10(4): e0123083. [5] Suzuki, Y. , & Sugano, S. . (2003). Construction of a full-length enriched and a 5'-end enriched cdna library using the oligo-capping method. Methods Mol Biol, (221): 73-91. [6]Ding, Q. , Zeng, J. , & He, X. Q. (2014). Deep sequencing on a genome-wide scale reveals diverse stage-specific micrornas in cambium during dormancy-release induced by chilling in poplar. BMC Plant Biology, 14(1): 267-279. [7]Gao, P. , Bai, X. , Yang, L. , Lv, D. , Li, Y. , & Cai, H. , et al. (2010). Over-expression of osa-mir396c decreases salt and alkali stress tolerance. Planta, 231(5): 991-1,001. [8]Feng, H. , Wang, X. , Zhang, Q. , Fu, Y. , & Kang, Z. (2013). Monodehydroascorbate reductase gene, regulated by the wheat pn-2013 mirna, contributes to adult wheat plant resistance to stripe rust through ros metabolism. Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanisms. 1839(1):1-12. [9]Wu, Y. F. , Reed, G. W. , & Tian, C. Q. (2006). Arabidopsis microrna167 controls patterns of arf6 and arf8 expression, and regulates both female and male reproduction. Development,133(21): 4,211-4,218. [10] Glazińska, Paulina, Wojciechowski, W. , Wilmowicz, E. , Zienkiewicz, A. , Frankowski, K. , & Kopcewicz, J. (2014). The involvement of inmir167 in the regulation of expression of its target gene inarf8, and their participation in the vegetative and generative development of ipomoea nil plants. Journal of Plant Physiology, 171(3-4): 225-234. [11] Ru, P. , Xu, L. , Ma, H. , & Huang, H. . (2006). Plant fertility defects induced by the enhanced expression of microrna167. Cell Research, 16(5):457-465. [12] Liu, N. , Wu, S. , Van Houten, J. , Wang, Y. , Ding, B. , & Fei, Z. , et al. (2014). Down-regulation of auxin response factors 6 and 8 by microrna 167 leads to floral development defects and female sterility in tomato. Journal of Experimental Botany,65(9): 2,507-2,520. [13] Wang, Y. , Li, K. , Chen, L. , Zou, Y. , & Li, X. (2015). Microrna167-directed regulation of the auxin response factors gmarf8a and gmarf8b is required for soybean nodulation and lateral root development. Plant physiology, 168(3): 984-999. [14] Jodder, J. , Das, R. , Sarkar, D. , Bhattacharjee, P. , & Kundu, P. (2017). Distinct transcriptional and processing regulations control mir167a level in tomato during stress. RNA Biology, 15(1):130-143. [15] Liu, H. H. , Tian, X. , Li, Y. J. , Wu, C. A. , & Zheng, C. C. (2008). Microarray-based analysis of stress-regulated micrornas in arabidopsis thaliana. RNA, 14(5): 836-843. [16] Zhu, J. , Li, W. , Yang, W. , Qi, L. , & Han, S. (2013). Identification of micrornas incaragana intermediaby high-throughput sequencing and expression analysis of 12 micrornas and their targets under salt stress. Plant Cell Reports,32(9):1,339-1,349. [17] Kumar, R. (2014). Role of micrornas in biotic and abiotic stress responses in crop plants. Applied Biochemistry & Biotechnology, 174(1):93-115. [18] Khan, M. A. , & Duke, N. C. (2001). Halophytes - a resource for the future. Wetlands Ecology and Management, 9(6): 455-456. [19] Zhao, K. F. , Fan, H. , Song, J. , Sun, M. X. , Wang, B. Z. , & Zhang, S. Q. , et al. (2005). Two na+ and cl? hyperaccumulators of the chenopodiaceae. Journal Of Integrative Plant Biology, 47(3): 311-318. [20] Song, J. , Feng, G. , & Zhang, F. (2006). Salinity and temperature effects on germination for three salt-resistant euhalophytes,halostachys caspica,kalidium foliatumandhalocnemum strobilaceum. Plant and Soil, 279(1-2): 201-207. [21] Zeng, Y. , Li, L. , Yang, R. , Yi, X. , & Zhang, B. (2015). Contribution and distribution of inorganic ions and organic compounds to the osmotic adjustment in halostachys caspica response to salt stress. Scientific Reports, 5(1): 13,639. [22] Yang, R. , Zeng, Y. , Yi, X. , Zhao, L. , & Zhang, Y. (2015). Small rna deep sequencing reveals the important role of micrornas in the halophyter, halostachys caspica. Plant Biotechnology Journal, 13(3): 395-408. [23] Allen, E. , Xie, Z. , Gustafson, A. M. , & Carrington, J. C. (2005). Microrna-directed phasing during trans-acting sirna biogenesis in plants. Cell, 121(2): 207-221. [24] Schwab, R. , Palatnik, J. F. , Riester, M. , Schommer, C. , Schmid, M. , & Weigel, D. (2005). Specific effects of micrornas on the plant transcriptome. Developmental Cell, 8(4):517-524. [25] 杨瑞瑞, 曾幼玲. 盐生植物盐爪爪的耐盐生理特性探讨[J]. 广西植物, 2015,35(3):366-372. YANG Rui-rui, ZENG You-ling. (2015). Physiological characteristics of the halophytic plant Kalidium foliatum to salt stress [J]. Guihaia, 35(3):366-372. (in Chinese) [26] Nagpal, P. , Ellis, C. M. , Weber, H. , Ploense, S. E. , & Barkawi, L. S. (2005). Auxin response factors arf6 and arf8 promote jasmonic acid production and flower maturation. Development, 132(18): 4,107-4,118. |