JOINTLESS is a MADS-box gene controlling tomato flower abscission zone development.

Abscission is a universal and dynamic process in plants whereby organs such as leaves, flowers and fruit are shed, both during normal development, and in response to tissue damage and stress. Shedding occurs by separation of cells in anatomically distinct regions of the plant, called abscission zones (AZs). During abscission, the plant hormone ethylene stimulates cells to produce enzymes that degrade the middle lamella between cells in the AZ. The physiology and regulation of abscission at fully developed AZs is well known, but the molecular biology underlying their development is not. Here we report the first isolation of a gene directly involved in the development of a functional plant AZ. Tomato plants with the jointless mutation fail to develop AZs on their pedicels and so abscission of flowers or fruit does not occur normally. We identify JOINTLESS as a new MADS-box gene in a distinct phylogenetic clade separate from those functioning in floral organs. We propose that a deletion in JOINTLESS accounts for the failure of activation of pedicel AZ development in jointless tomato plants.

Interactions between jointless and wild-type tomato tissues during development of the pedicel abscission zone and the inflorescence meristem.

The jointless mutation of tomato results in the formation of flower pedicels that lack an abscission zone and inflorescence meristems that revert to vegetative growth. We have analyzed periclinal chimeras and mericlinal sectors of jointless and wild-type tissue to determine how cells in different meristem layers (L1, L2, and L3) and their derivatives interact during these two developmental processes. Cells in the inner meristem layer, L3, alone determined whether the meristem maintained the inflorescence state or reverted to vegetative growth. Moreover, L3 derivatives determined whether a functional pedicel abscission zone formed. Limited and disorganized autonomous development of wild-type L2-derived cells occurred when they overlay mutant tissue. Adjacent mutant and wild-type L3-derived tissues in pedicels developed autonomously, indicating little or no lateral communication. Only the outermost L3-derived cells within the pedicel were capable of orchestrating normal pedicel development in overlying tissues, revealing the special status of those cells as coordinators of development for L1- and L2-derived cells, whereas the innermost L3-derived cells developed autonomously but did not influence the development of other cells.

Additional vegetative growth in maize reflects expansion of fates in preexisting tissue, not additional divisions by apical initials.

The maize shoot is usually determinate: the apical meristem produces a fixed number of vegetative nodes before it switches to tassel development. Culturing maize meristems, however, delays their determinacy. Cultured meristems may form up to twice the usual number of vegetative nodes. Clonal analysis of the "extra" vegetative nodes reveals that these nodes are the product of conversion, roughly equivalent to a homoeotic transformation, of tissue that otherwise would form the base of the tassel. Altered activity of the apical initials does not generate the extra vegetative growth. The conserved, stereotypical activity of the apical initials even in the face of radically prolonged vegetative growth suggests that apical initials in this annual grass may acquire a highly restricted fate (presporogenous tissue) early in embryogenesis.

Experimental Analysis of Tassel Development in the Maize Mutant Tassel Seed 6.

The maize (Zea mays L.) mutation Tassel seed 6 (Ts6) disrupts both sex determination in the tassel and the pattern of branching in inflorescences. This results in the formation of supernumerary florets in tassels and ears and in the development of pistils in tassel florets where they are normally aborted. A developmental analysis indicated that extra florets in Ts6 inflorescences are most likely the result of delayed determinacy in spikelet meristems, which then initiate additional floret meristems rather than initiating floral organs as in wild type. I have used culturing experiments to assay whether delayed determinacy of Ts6 mutant tassels is reflected in an altered timing of specific determination events. Length of the tassel was used as a developmental marker. These experiments showed that although Ts6 tassels elongate much more slowly than wild type, both mutant and wild-type tassels gained the ability to form flowers with organs of normal morphology in culture at the same time. In situ hybridization patterns of expression of the maize gene Kn, which is normally expressed in shoot meristems and not in determinate lateral organs, confirmed that additional meristems, rather than lateral organs, are initiated by spikelet meristems in Ts6 tassels.

Heterochronic Effects of Teopod 2 on the Growth and Photosensitivity of the Maize Shoot.

Teopod 2 (Tp2) is a semidominant mutation of maize that prolongs the expression of juvenile vegetative traits, increases the total number of leaves produced by the shoot, and transforms reproductive structures into vegetative ones. Here, we show that Tp2 prolongs the duration of vegetative growth without prolonging the overall duration of shoot growth. Mutant shoots produce leaves at the same rate as wild-type plants and continue to produce leaves after wild-type plants have initiated a tassel. Although Tp2/+ plants initiate a tassel later than their wild-type siblings, this mutant tassel ceases differentiation at the same time as, or shortly before, the primary meristem of a wild-type tassel completes its development. To investigate the relationship between the vegetative and reproductive development of the shoot, Tp2/+ and wild-type plants were exposed to floral inductive short day (SD) treatments at various stages of shoot growth. Tassel initiation in wild-type plants (which normally produced 18 to 19 leaves) was maximally sensitive to SD between plastochrons 15 and 16, whereas tassel branching was maximally sensitive to SD between plastochrons 15 and 18. Tassel initiation and tassel morphology in Tp2/+ plants (which normally produced 21 to 26 leaves) were both maximally sensitive to SD between plastochrons 15 and 18. Thus, the constitutive expression of a juvenile vegetative program in Tp2/+ plants does not significantly delay the reproductive maturation of the shoot.

Development of maize plants from cultured shoot apices.

Excised shoot apices of maize (Zea mays L.), comprising the apical meristem and one or two leaf primordia, have been cultured and can form rooted plantlets. The plantlets, derived from meristems that had previously formed 7-10 nodes, develop into mature, morphologically normal plants with as many nodes as seed-grown plants. These culture-derived plants exhibited the normal pattern of development, with regard to the progression of leaf lengths along the plant and position of axillary buds and aar shoots. Isolation of the meristem from previously formed nodes reinitiates the pattern and number of nodes formed in the new plant. Thus, cells of the meristem of a maize plant at the seedling stage are not determined to form a limited number of nodes.

Activation of low and null activity isozymes of maize alcohol dehydrogenase by antibodies.

Antisera were raised against several purified, high specific activity isozymes of maize alcohol dehydrogenase (ADH1). The various antisera had different effects on the activity of immunoprecipitated ADH. One antiserum completely inactivated maize ADH. This inactivation could be blocked by preincubation of the enzyme with NAD+, its cofactor, or with NADP. The different antisera were used to analyze variant forms of ADH1. Isozymes having lowered specific activity were activated to wild-type levels by precipitation of the enzymes with noninactivating antisera. Isozymes having no detectable ADH activity (CRM+ nulls) were activated by immunoprecipitation with noninactivating antisera when preincubated with NAD+ or NADP. All of the CRM+ nulls were shown to be unable to bind NAD+, a flaw which can account for their lack of activity. The results indicate that a conformational equilibrium between active and inactive forms of maize ADH in solution controls the specific activity of the various isozymes. Both NAD+ and antibodies raised against high specific activity enzymes can interact with low activity isozymes to shift the balance of the equilibrium toward the active form, thus increasing their specific activity.