326

Biology and Biotechnology of Environmental Stress Tolerance in Plants, Volume 3

Nagel, M., Alqudah, A. M., Bailly, M., Rajjou, L., Pistrick, S., Matzig, G., Börner, A., &

Kranner, I., (2019). Novel loci and a role for nitric oxide for seed dormancy and preharvest

sprouting in barley. Plant Cell Environ., 42, 1318–1327.

Nayyeripasand, L., Garoosi, G. A., & Ahmadikhah, A., (2021). Genome-wide association

study (GWAS) to identify salt-tolerance QTLs carrying novel candidate genes in rice during

early vegetative stage. Rice, 14, 1–21.

Neang, S., De Ocampo, M., Egdane, J. A., Platten, J. D., Ismail, A. M., Seki, M., Suzuki, Y., et

al., (2020). A GWAS approach to find SNPs associated with salt removal in rice leaf sheath.

Ann. Bot., 126, 1193–1202.

Oladzad, A., Porch, T., Rosas, J. C., Moghaddam, S. M., Beaver, J., Beebe, S. E., Burridge,

J., et al., (2019). Single and multi-trait GWAS identify genetic factors associated with

production traits in common bean under abiotic stress environments. G3: Genes, Genomes,

Genetics, 9, 1881–1892.

Pantaliao, G. F., Narciso, M., Guimarães, C., Castro, A., Colombari, J. M., Breseghello, F.,

Rodrigues, L., et al., (2016). Genome-wide association study (GWAS) for grain yield in rice

cultivated under water deficit. Genetica, 144, 651–664.

Pariasca-Tanaka, J., Baertschi, C., & Wissuwa, M., (2020). Identification of loci through

genome-wide association studies to improve tolerance to sulfur deficiency in rice. Front.

Plant Sci., 10, 1668.

Pedranzani, H., Racagni, G., Alemano, S., Miersch, O., Ramírez, I., Peña-Cortés, H., Taleisnik,

E., et al., (2003). Salt tolerant tomato plants show increased levels of jasmonic acid. Plant

Growth Reg., 41, 149–158.

Piepho, H. P., Möhring, J., Melchinger, A. E., & Büchse, A., (2008). BLUP for phenotypic

selection in plant breeding and variety testing. Euphytica., 161, 209–228.

Platt, A., Vilhjálmsson, B. J., & Nordborg, M., (2010). Conditions under which genome-wide

association studies will be positively misleading. Genetics, 186, 1045–1052.

Poland, J. A., Bradbury, P. J., Buckler, E. S., & Nelson, R. J., (2011). Genome-wide nested

association mapping of quantitative resistance to northern leaf blight in maize. Proceed.

Nat. Acad. Sci., 108, 6893–6898.

Quail, M. A., Kozarewa, I., Smith, F., Scally, A., Stephens, P. J., Durbin, R., Swerdlow, H.,

& Turner, D. J., (2008). A large genome center’s improvements to the Illumina sequencing

system. Nat. Meth., 5, 1005–1010.

Rafalski, J. A., (2010). Association genetics in crop improvement. Curr. Opin. Plant Biol.,

13, 174–180.

Raman, H., Raman, R., Qiu, Y., Yadav, A. S., Sureshkumar, S., Borg, L., Rohan, M., et al.,

(2019). GWAS hints at pleiotropic roles for FLOWERING LOCUS T in flowering time and

yield-related traits in canola. BMC Genom., 20, 1–18.

Rizzo, J. M., & Buck, M. J., (2012). Key principles and clinical applications of “next­

generation” DNA sequencing. Cancer Prev Res., 5, 887–900.

Ronaghi, M., Karamohamed, S., Pettersson, B., Uhlen, M., & Nyren, P., (1996). Real-time

DNA sequencing using detection of pyrophosphate release. Anal. Biochem., 242, 84–89.

Saade, S., Maurer, A., Shahid, M., Oakey, H., Schmöckel, S. M., Negrão, S., Pillen, K., &

Tester, M., (2016). Yield-related salinity tolerance traits identified in a nested association

mapping (NAM) population of wild barley. Sci. Rep., 6, 1–9.

Sallam, A., & Martsch, R., (2015). Association mapping for frost tolerance using multi-

parent advanced generation inter-cross (MAGIC) population in faba bean (Viciafaba L.).

Genetica, 143, 501–514.