Limited correlation between expansin gene expression and elongation growth rate.

The aim of this work was to study the role of the cell wall protein expansin in elongation growth. Expansins increase cell wall extensibility in vitro and are thought to be involved in cell elongation. Here, we studied the regulation of two tomato (Lycopersicon esculentum cv Moneymaker) expansin genes, LeExp2 and LeExp18, in rapidly expanding tissues. LeExp2 was strongly expressed in the elongation zone of hypocotyls and in the faster growing stem part during gravitropic stimulation. LeExp18 expression did not correlate with elongation growth. Exogenous application of hormones showed a substantial auxin-stimulation of LeExp2 mRNA in etiolated hypocotyls and a weaker auxin-stimulation of LeExp18 mRNA in stem tissue. Analysis of transcript accumulation revealed higher levels of LeExp2 and LeExp18 in light-treated, slow-growing tissue than in dark-treated, rapidly elongating tissue. Expansin protein levels and cell wall extension activities were similar in light- and dark-grown hypocotyl extracts. The results show a strong correlation between expansin gene expression and growth rate, but this correlation is not absolute. We conclude that elongation growth is likely to be controlled by expansin acting in concert with other factors that may limit growth under some physiological conditions.

Tissue-specific expression and promoter analysis of the tobacco Itp1 gene.

The Nicotiana tabacum Itp1 gene (Ntltp1) encodes a small basic protein that belongs to a class of putative lipid transfer proteins. These proteins transfer lipids between membranes in vitro, but their in vivo function remains hotly debated. This gene also serves as an important early marker for epidermis differentiation. We report here the analysis of the spatial and developmental activity of the Ntltp1 promoter, and we define a sequence element required for epidermis-specific expression. Transgenic plants were created containing 1346 bp of the Ntltp1 promoter fused upstream of the beta-glucuronidase (GUS) gene. In the mature aerial tissues, GUS activity was detected predominantly in the epidermis, whereas in younger aerial tissues, such as the shoot apical meristem and floral meristem, GUS expression was not restricted to the tunica layer. Unexpectedly, GUS activity was also detected in young roots particularly in the root epidermis. Furthermore, the Ntltp1 promoter displayed a tissue and developmental specific pattern of activity during germination. These results suggest that the Ntltp1 gene is highly expressed in regions of the plant that are vulnerable to pathogen attack and are thus consistent with the proposed function of lipid transfer proteins in plant defense. Deletions of the promoter from its 5' end revealed that the 148 bp preceding the translational start site are sufficient for epidermis-specific expression. Sequence comparison identified an eight-nucleotide palindromic sequence CTAGCTAG in the leader of Ntltp1, which is conserved in a number of other Itp genes. By gel retardation analysis, the presence of specific DNA-protein complexes in this region was demonstrated. The characterization of these factors may lead to the identification of factors that control early events in epidermis differentiation.