The cultivated tomato (Lycopersicon esculentum) has a unipinnate compound leaf. In the developing leaf primordium, major leaflet initiation is basipetal, and lobe formation and early vascular differentiation are acropetal. We show that engineered alterations in the expression of a tomato homeobox gene, LeT6, can cause dramatic changes in leaf morphology. The morphological states are variable and unstable and the phenotypes produced indicate that the tomato leaf has an inherent level of indeterminacy. This is manifested by the production of multiple orders of compounding in the leaf, by numerous shoot, inflorescence, and floral meristems on leaves, and by the conversion of rachis-petiolule junctions into "axillary" positions where floral buds can arise. Overexpression of a heterologous homeobox transgene, kn1, does not produce such phenotypic variability. This indicates that LeT6 may differ from the heterologous kn1 gene in the effects manifested on overexpression, and that 35S-LeT6 plants may be subject to alterations in expression of both the introduced and endogenous LeT6 genes. The expression patterns of LeT6 argue in favor of a fundamental role for LeT6 in morphogenesis of leaves in tomato and also suggest that variability in homeobox gene expression may account for some of the diversity in leaf form seen in nature.During vegetative growth most higher plants are indeterminate. The SAM produces a radially symmetrical, acropetally differentiating shoot axis (stem) and determinate, bilaterally symmetrical lateral organs (leaves). Leaves can be one of two types, simple or compound, and the nature of these has been a matter of debate. The ontogenetic relationship of the dicot compound leaf to the simple leaf is unclear (Merrill, 1986), with various researchers concluding that the basic leaf form is simple (Eames, 1961) or compound pinnate (Hagemann, 1984), or that compound leaves have some shoot-like features and may represent a continuum between shoots and leaves (Sattler and Rutishauser, 1992; Lacroix and Sattler, 1994).To determine morphogenetic patterns and the level of indeterminacy in compound leaves, we have used homeobox genes that were cloned from tomato (Lycopersicon esculentum) (Chen et al., 1997; Janssen et al., 1998). Homeobox genes encode transcription factors that control the regulation of cell fate (McGinnis et al., 1984;Scott et al., 1989). The first plant homeobox gene cloned was the maize knotted1 (kn1) gene (Vollbrecht et al., 1991). kn1-like homeobox (knox) genes have been placed into two classes (Kerstetter et al., 1994). Although no specific function has as yet been ascertained for class II knox genes (Serikawa et al., 1997), class I knox genes play a role in meristem maintenance and leaf and flower determination at the shoot apex. Class I knox genes are not expressed in initiating organ primordia, mature leaves, or floral organs in simpleleaved species (Smith et al., 1992; Jackson et al., 1994; Long et al., 1996).We have cloned a class I knox gene, LeT6 (L. esculentum T6), and shown tha...
