Group 3 LEA protein, ZmLEA3, is involved in protection from low temperature stress
Y Liu, J Liang, L Sun, X Yang, D Li - Frontiers in plant science, 2016 - frontiersin.org
Late embryogenesis abundant (LEA) proteins are a family of small highly hydrophilic
proteins that accumulate at the onset of seed desiccation and in response to adverse
conditions such as drought, salinity, low temperature, or water deficit. In previous studies, we
demonstrated that ZmLEA3 could enhance the transgenic tobacco tolerance to osmotic and
oxidative stresses. Here, we demonstrated that the transcription of ZmLEA3 in the maize
stems could be significantly induced by low temperature and osmotic stresses and by …
proteins that accumulate at the onset of seed desiccation and in response to adverse
conditions such as drought, salinity, low temperature, or water deficit. In previous studies, we
demonstrated that ZmLEA3 could enhance the transgenic tobacco tolerance to osmotic and
oxidative stresses. Here, we demonstrated that the transcription of ZmLEA3 in the maize
stems could be significantly induced by low temperature and osmotic stresses and by …
Group 3 LEA protein, ZmLEA3, is involved in protection from low temperature stress.
LY Liu Yang, LJA Liang JianAn, SLP Sun LiPing… - 2016 - cabidigitallibrary.org
Late embryogenesis abundant (LEA) proteins are a family of small highly hydrophilic
proteins that accumulate at the onset of seed desiccation and in response to adverse
conditions such as drought, salinity, low temperature, or water deficit. In previous studies, we
demonstrated that ZmLEA3 could enhance the transgenic tobacco tolerance to osmotic and
oxidative stresses. Here, we demonstrated that the transcription of ZmLEA3 in the maize
stems could be significantly induced by low temperature and osmotic stresses and by …
proteins that accumulate at the onset of seed desiccation and in response to adverse
conditions such as drought, salinity, low temperature, or water deficit. In previous studies, we
demonstrated that ZmLEA3 could enhance the transgenic tobacco tolerance to osmotic and
oxidative stresses. Here, we demonstrated that the transcription of ZmLEA3 in the maize
stems could be significantly induced by low temperature and osmotic stresses and by …