Abstract
Understanding plant adaptation mechanisms to prolonged water immersion provides options for genetic modification of existing crops to create cultivars more tolerant of periodic flooding. An important advancement in understanding flooding adaptation would be to elucidate mechanisms, such as aerenchyma air-space formation induced by hypoxic conditions, consistent with prolonged immersion. Lysigenous aerenchyma formation occurs through programmed cell death (PCD), which may entail the chemical modification of polysaccharides in root tissue cell walls. We investigated if a relationship exists between modification of pectic polysaccharides through de-methyl esterification (DME) and the formation of root aerenchyma in select Fabaceae species. To test this hypothesis, we first characterized the progression of aerenchyma formation within the vascular stele of three different legumes—Pisum sativum, Cicer arietinum, and Phaseolus coccineus—through traditional light microscopy histological staining and scanning electron microscopy. We assessed alterations in stele morphology, cavity dimensions, and cell wall chemistry. Then we conducted an immunolabeling protocol to detect specific degrees of DME among species during a 48-hour flooding time series. Additionally, we performed an enzymatic pretreatment to remove select cell wall polymers prior to immunolabeling for DME pectins. We were able to determine that all species possessed similar aerenchyma formation mechanisms that begin with degradation of root vascular stele metaxylem cells. Immunolabeling results demonstrated DME occurs prior to aerenchyma formation and prepares vascular tissues for the beginning of cavity formation in flooded roots. Furthermore, enzymatic pretreatment demonstrated that removal of cellulose and select hemicellulosic carbohydrates unmasks additional antigen binding sites for DME pectin antibodies. These results suggest that additional carbohydrate modification may be required to permit DME and subsequent enzyme activity to form aerenchyma. By providing a greater understanding of cell wall pectin remodeling among legume species, we encourage further investigation into the mechanism of carbohydrate modifications during aerenchyma formation and possible avenues for flood-tolerance improvement of legume crops.
Highlights
Flooding is among the most common and costly natural disasters inflicted upon agricultural lands (Doocy et al, 2013)
Cavity formation began near the metaxylem of one xylem pole within the stele and expanded to form a transversely circular aerenchymatous space that occupied the center of the stele (Figure 2B)
We described these tissues as being composed of large, nucleated “bubble-like” cells that we name “tylose-like cells” (TLCs) due to their cosmetic resemblance to tyloses found in xylem vessels of various hardwoods (Esau, 1965; Carlquist, 2013; Leśniewska et al, 2017)
Summary
Flooding is among the most common and costly natural disasters inflicted upon agricultural lands (Doocy et al, 2013). Aerenchyma tissues are characterized by the formation of large, air-filled channels or cavities in the stems, leaves or roots in plant cortical or vascular tissues (Yamauchi et al, 2013; Takahashi et al, 2016). These cavities allow plants to tolerate hypoxic conditions induced through prolonged water immersion by maintaining oxygen levels sufficient for cellular respiration and reducing the number of cells utilizing oxygen (Evans, 2004; Postma and Lynch, 2011; Yamauchi et al, 2013). Oxygen from aerenchyma diffuses through the plant apoplast into the surrounding soil, which increases soil oxygen content and protects tissues from infection by bacteria and fungi favored by anaerobic conditions (Jackson and Armstrong, 1999; Cronk and Fennessy, 2009; Takahashi et al, 2016)
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