Plant hormones play a crucial roles

Plant hormones play a crucial roles in the endogenous regulation of plant growth and development. Recent studies on physiological effects of brassinosteroids (BRs) in plant have provided convincing evidence that BRs are a unique class of plant hormones that are essential for normal plant growth. BRs are a number of
other naturally occurring organic compounds that exhibit strong biological activity when applied exogenously in low concentrations. Recently brassinolide, a steroidal
compound, has been noted as the sixth plant hormone subsequent to auxin, gibberellin, cytokinin, ethylene and abscisic acid (Hamada, 1986). Currently, more than sixty BRs have been identified in many plants, including dicots, monocots, gymnosperms, green algae and ferns (Sakurai & Fujioka, 1994). The identity of the active compound known as “brassins” (so called because the first extracts were from the genus Brassica), was unclear. That they were not gibberellins (GAs) was
indicated by some differences in growth pattern, such as swelling and curvature of stem, which do not occur in GA-induced growth (Srivastava, 2002).

Physiologically, after the isolation and characteriza- tion of brassinolide (BL) as steroidal compounds in plant, they suddenly became very important phytophysiological
compounds. A great number of steroidal compounds are already known as hormone in most animals and insects, but brassinolide is the first steroidal compound known to exhibit physiological role in plants. As a plant hormone, it must exist physiological role in every kind of plant, but the number of responses is still limited. In order to be recognized as a growth-promoting activities compounds, the application of BRs in various plants has been recently done.

Agriculturally, BRs have long been used for specific purpose in enhancing some desirable characteristics of agricultural crops. Physiological studies done in several laboratories have demonstrated that BRs can induce a broad spectrum of cellular responses such as stem elongation, pollen tube growth, leaf bending and epinasty, root inhibition, induction of ethylene biosynthesis, proton-pump activation, xylem
differentiation, and regulation of gene expression (Mandava, 1988; Clouse & Sasse, 1998). To date, several studies in the field has been carried out on
stress responses (Anuradha & Rao, 2001; Nakashita et al., 2003; Sharma & Bhardwaj, 2007; Alam et al., 2007). Although small number of other agricultural crops treats with BRs for increasing yield has been documented. It must, however, be mentioned that laboratory studies do not give a complete information of the physiological role of BRs when they are applied in the field.