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.     

The effect of a heterochronic mutation, Teopod2, on the cell lineage of the maize shoot

Teopod2 (Tp2) is a semi-dominant mutation of maize that prolongs the expression of characteristics normally confined to the juvenile phase of development. Two of the many dramatic morphological effects of this mutation are an increase in the number of vegetative nodes, and a reduction in the overall size of the shoot. To determine the cellular basis of these phenotypes, the technique of clonal analysis was used to compare the cell division patterns of wild-type and Tp2 plants. Our results indicate that Tp2 increases the number of vegetative nodes produced by the apicalmost cells in the meristem but does not affect the cell lineage of the basal, juvenile, part of the shoot. This result demonstrates that Tp2 does not act uniquely in a 'juvenile' domain of the meristem, but instead causes cells that are normally destined to produce adult structures to express juvenile traits inappropriately. Clonal analysis also demonstrates that Tp2 does not affect the size of the meristem prior to germination, nor does it affect the cell lineage of the basic structural unit of the stem, the phytomer. Thus the effects of this mutation on the size of the shoot are the result of changes in cell fate late in development.     

Heterochronic mutations affecting shoot development in maize

Three semidominant, nonallelic mutations of maize, Teopod 1 (Tp1), Teopod 2 (Tp2) and Teopod 3 (Tp3), have a profound effect on both vegetative and reproductive development. Although each mutation is phenotypically distinct, they all (1) increase the number of vegetative phytomers; (2) increase the number of phytomers producing ears, tillers and prop roots; (3) increase the number of leaves bearing epidermal wax; (4) decrease the size of leaves and internodes; (5) decrease the size of both the ear and tassel; and (6) transform reproductive structures into vegetative ones. The analysis presented here suggests that this phenotype reflects the prolonged expression of a juvenile, vegetative developmental program which overlaps with the reproductive developmental program. The expression of these mutations is different in each of the four inbred backgrounds used in this study. Tp1 and Tp2 have similar phenotypes and are more highly expressed in the A632 and Oh51a inbred backgrounds than in W23 and Mo17. Tp3 has less extreme effects than either of these mutations and has the opposite modification pattern; i.e., it is more highly expressed in W23 and Mo17 than in A632 and Oh51a. The expression of Tp1 and Tp2 in the presence of varying doses of their wild-type alleles indicate that both are gain-of-function mutations. The phenotypes of Tp1 and Tp2 and the nature of their response to variation in gene dose suggest that they control related, but nonidentical functions. The developmental and evolutionary implications of the heterochronic phenotype of these mutations is discussed.     

Gibberellins promote vegetative phase change and reproductive maturity in maize.

Postembryonic shoot development in maize (Zea mays L.) is divided into a juvenile vegetative phase, an adult vegetative phase, and a reproductive phase that differ in the expression of many morphological traits. A reduction in the endogenous levels of bioactive gibberellins (GAs) conditioned by any one of the dwarf1, dwarf3, dwarf5, or another ear1 mutations in maize delays the transition from juvenile vegetative to adult vegetative development and from adult vegetative to reproductive development. Mutant plants cease producing juvenile traits (e.g. epicuticular wax) and begin producing adult traits (e.g. epidermal hairs) later than wild-type plants. They also cease producing leaves and begin producing reproductive structures later than wild-type plants. These mutations greatly enhance most aspects of the phenotype of Teopod1 and Teopod2, suggesting that GAs suppress part but not all of the Teopod phenotype. Application of GA3 to Teopod2 mutants and Teopod1, dwarf3 double mutants confirms this result. We conclude that GAs act in conjunction with several other factors to promote both vegetative and reproductive maturation but affect different developmental phases unequally. Furthermore, the GAs that regulate vegetative and reproductive maturation, like those responsible for stem elongation, are downstream of GA20 in the GA biosynthetic pathway.     

The early phase change gene in maize

Recessive mutations of the early phase change (epc) gene in maize affect several aspects of plant development. These mutations were identified initially because of their striking effect on vegetative phase change. In certain genetic backgrounds, epc mutations reduce the duration of the juvenile vegetative phase of development and cause early flowering, but they have little or no effect on the number of adult leaves. Except for a transient delay in leaf production during germination, mutant plants initiate leaves at a normal rate both during and after embryogenesis. Thus, the early flowering phenotype of epc mutations is explained completely by their effect on the expression of the juvenile phase. The observation that epc mutations block the rejuvenation of leaf primordia in excised shoot apices supports the conclusion that epc is required for the expression of juvenile traits. This phenotype suggests that epc functions normally to promote the expression of the juvenile phase of shoot development and to suppress the expression of the adult phase and that floral induction is initiated by the transition to the adult phase. epc mutations are epistatic to the gibberellin-deficient mutation dwarf1 and interact additively with the dominant gain-of-function mutations Teopod1, Teopod2, and Teopod3. Genetic backgrounds that enhance the mutant phenotype of epc demonstrate that, in addition to its role in phase change, epc is required for the maintenance of the shoot apical meristem, leaf initiation, and root initiation.     

Glossy15 Controls the Epidermal Juvenile-to-Adult Phase Transition in Maize

Loss-of-function mutations at the maize Glossy15 (Gl15) locus alter the normal transition from juvenile-to-adult growth by conditioning the abbreviated expression of juvenile epidermal cell traits and the coordinate precocious expression of adult epidermal cell features. These include epicuticular wax composition, cell wall characteristics, and the presence or absence of differentiated epidermal cell types (e.g., epidermal macrohairs and bulliform cells). A transposon-induced mutable allele of Glossy15 (gl15-m1) was isolated and employed in both phenotypic and genetic analyses to characterize the role of Gl15 in the maize juvenile-to-adult phase transition. Comparisons between Gl15-active and Gl15-inactive somatic sectors in the leaves of variegated plants demonstrated that the Gl15 gene product acts in a cell-autonomous manner to direct juvenile epidermal differentiation but does not affect factors that regulate the overall process of phase change. Examination of the gl15-m1 phenotype in the Corngrass1, Teopod1, and Teopod2 mutant backgrounds showed that the prolonged expression of juvenile epidermal traits associated with these mutations also required Gl15 activity. These results support a model whereby the cell-autonomous Gl15 gene product responds to a juvenility program that operates throughout the vegetative shoot to condition the juvenile differentiation of maize leaf epidermal cells.     

Clonal mosaic analysis of EMPTY PERICARP2 reveals nonredundant functions of the duplicated HEAT SHOCK FACTOR BINDING PROTEINs during maize shoot development

The paralogous maize proteins EMPTY PERICARP2 (EMP2) and HEAT SHOCK FACTOR BINDING PROTEIN2 (HSBP2) each contain a single recognizable motif: the coiled-coil domain. EMP2 and HSBP2 accumulate differentially during maize development and heat stress. Previous analyses revealed that EMP2 is required for regulation of heat shock protein (hsp) gene expression and also for embryo morphogenesis. Developmentally abnormal emp2 mutant embryos are aborted during early embryogenesis. To analyze EMP2 function during postembryonic stages, plants mosaic for sectors of emp2 mutant tissue were constructed. Clonal sectors of emp2 mutant tissue revealed multiple defects during maize vegetative shoot development, but these sector phenotypes are not correlated with aberrant hsp gene regulation. Furthermore, equivalent phenotypes are observed in emp2 sectored plants grown under heat stress and nonstress conditions. Thus, the function of EMP2 during regulation of the heat stress response can be separated from its role in plant development. The discovery of emp2 mutant phenotypes in postembryonic shoots reveals that the duplicate genes emp2 and hsbp2 encode nonredundant functions throughout maize development. Distinct developmental phenotypes correlated with the developmental timing, position, and tissue layer of emp2 mutant sectors, suggesting that EMP2 has evolved diverse developmental functions in the maize shoot.     

The narrow sheath duplicate genes: sectors of dual aneuploidy reveal ancestrally conserved gene functions during maize leaf development

The narrow sheath mutant of maize displays a leaf and plant stature phenotype controlled by the duplicate factor mutations narrow sheath1 and narrow sheath2. Mutant leaves fail to develop a lateral domain that includes the leaf margins. Genetic data are presented to show that the narrow sheath mutations map to duplicated chromosomal regions, reflecting an ancestral duplication of the maize genome. Genetic and cytogenetic evidence indicates that the original mutation at narrow sheath2 is associated with a chromosomal inversion on the long arm of chromosome 4. Meristematic sectors of dual aneuploidy were generated, producing plants genetically mosaic for NARROW SHEATH function. These mosaic plants exhibited characteristic half-plant phenotypes, in which leaves from one side of the plant were of nonmutant morphology and leaves from the opposite side were of narrow sheath mutant phenotype. The data suggest that the narrow sheath duplicate genes may perform ancestrally conserved, redundant functions in the development of a lateral domain in the maize leaf.     

Investigation of the role of cell-cell interactions in division plane determination during maize leaf development through mosaic analysis of the tangled mutation

Most plant cells divide in planes that can be predicted from their shapes according to simple geometrical rules, but the division planes of some cells appear to be influenced by extracellular cues. In the maize leaf, some cells divide in orientations not predicted by their shapes, raising the possibility that cell-cell communication plays a role in division plane determination in this tissue. We investigated this possibility through mosaic analysis of the tangled (tan) mutation, which causes a high frequency of cells in all tissue layers to divide in abnormal orientations. Clonal sectors of tan mutant tissue marked by a closely linked albino mutation were examined to determine the phenotypes of cells near sector boundaries. We found that tan mutant cells always showed the mutant phenotype regardless of their proximity to wild-type cells, demonstrating that the wild-type Tan gene acts cell-autonomously in both lateral and transverse leaf dimensions to promote normally oriented divisions. However, if the normal division planes of wild-type cells depend on cell-cell communication involving the products of genes other than Tan, then aberrantly dividing tan mutant cells might send abnormal signals that alter the division planes of neighboring cells. The cell-autonomy of the tan mutation allowed us to investigate this possibility by examining wild-type cells near the boundaries of tan mutant sectors for evidence of aberrantly oriented divisions. We found that wild-type cells near tan mutant cells did not divide differently from other wild-type cells. These observations argue against the idea that the division planes of proliferatively dividing maize leaf epidermal cells are governed by short-range communication with their nearest neighbors.     

The viviparous8 mutation delays vegetative phase change and accelerates the rate of seedling growth in maize

Post-embryonic shoot development in plants can be divided into a juvenile vegetative, an adult vegetative, and a reproductive phase, which are expressed in different domains on the shoot axis. The number and position of the phytomers in each phase are determined by the time at which a plant begins and ceases making phytomers of a particular phase and the rate at which phytomers are made during that phase. The viviparous8 (vp8) mutation of maize increases the number of juvenile vegetative phytomers and decreases the number of adult vegetative phytomers by affecting both of these processes. vp8 increases the number of juvenile vegetative phytomers by increasing the rate of leaf initiation early in shoot development and delaying the juvenile-to-adult transition (vegetative maturation). It reduces the number of adult phytomers because the delay in vegetative maturation is not matched by a corresponding delay in flowering time; vp8 plants produce a tassel at the same time as wild-type plants. Thus, Vp8 normally controls the production of a factor that functions both to repress the rate of growth early in shoot development and to promote vegetative maturation, but which has no major role in floral induction. vp8 dramatically enhances the phenotypes of the dwarf and Teopod mutants and requires a functional Glossy15 gene to prolong the expression of juvenile epidermal traits. Evidence suggesting that vp8 does not affect phase change by reducing the level of abscisic acid is discussed.     

Engineering variegated floral patterns in tobacco plants using the Arabidopsis transposable element Tag1

Variegated flower phenotypes were generated using the Arabidopsis transposon Tag1 and the maize R regulatory gene. Tag1 was inserted between the CaMV 35S promoter and the maize R gene and transformed into tobacco plants. In half of the transgenic plants, variegated flower patterns were observed. Each line had a different pattern, with varying intensities with three lines showing only tiny sectors indicative of late excision and one showing large sectors indicative of earlier excision.     

SUSTAINED TREATMENT WITH GIBBERELLIC ACID OF MAIZE PLANTS CARRYING ONE OF THE DOMINANT GENES TEOPOD AND CORN-GRASS

Nickerson , Norton H. (Washington U., St. Louis, Missouri.) Sustained treatment with gibberellic acid of maize plants carrying one of the dominant genes Teopod and Corn-grass. Amer. Jour. Bot. 47(10): 809–815. Illus. 1960.—Groups of field-grown plants of 2 dominant maize mutants, Corn-grass (Cg), and Teopod (Tp), were treated with either distilled water or with 1 of 3 concentrations of aqueous gibberellic acid (GA) every 3 days from the seedling stage until tassel emergence. Both dominant mutants were found to respond to GA in such manner that certain treated plants became essentially normal in phenotype. The role of GA in modifying expression of specific genes is briefly discussed.     

The liguleless2 gene of maize functions during the transition from the vegetative to the reproductive shoot apex

During a maize plant's (Zea mays) development, the shoot apical meristem (SAM) generates an apex that proceeds through different phases: juvenile vegetative, adult vegetative and reproductive. During each phase the structures produced are distinguishable from structures produced during the other phases. In this paper, we demonstrate that the LIGULELESS2 (LG2) function is required for an accurate vegetative to reproductive phase transition. The maize gene liguleless2 (lg2) has been shown to encode a basic-leucine zipper (bZIP) protein and to function in narrowing the region from which the ligule and auricle develop in a typical maize leaf. Here we show that lg2 mutant plants can have reduced long tassel branches, extra vegetative leaves and extra husk leaves when compared to wild-type siblings. This indicates a role for the lg2 gene in the vegetative to reproductive phase transition of the shoot apex. We also discuss a potential role for the lg2 gene in general phase transition processes.     

Genetics of dominant gibberellin-insensitive dwarfism in maize

D8 and Mpl1 are two dominant dwarfing mutations of maize. Although they differ in severity of dwarfism, both D8 and Mpl1 mutants are unresponsive to gibberellin (GA). Because of their close phenotypic resemblance to the recessive GA-sensitive dwarf mutants these dominant mutations may identify a gene whose product is involved in the reception of GA. With this possibility in mind we have studied the genetic properties of D8 and Mpl1. Both mutations map close to Adh1 on chromosome 1L. By marking normal and translocated 1L arms with different Adh1 electrophoretic mobility alleles, we investigated the effect of gene dosage on dominant dwarf phenotype. The results suggest that D8 and Mpl1 encode novel product functions and that these functions are relatively insensitive to the presence of the (presumed) wild-type product. Using X-ray induced chromosome breakage we created sectors of wild-type cells within D8 or Mpl1 tissue; these sectors were marked by the linked recessive lw mutation. The phenotypes of these sectors demonstrated that, at least in certain plant organs and tissues, dominant dwarfism can be an autonomous phenotype. These results are consistent with the hypothesis that the wild-type gene product acts as a GA receptor. The potential utility of dominant dwarf phenotype in plant developmental analysis is discussed, and possible mechanisms for the action of the D8 and Mpl1 mutations are considered.     

kurkku,a Phenotype of Acetabularia acetabulum That Is Arrested in Vegetative Growth,Can Be Rescued with Wild-Type Cytoplasm

We isolated several spontaneous phenotypes in the giant unicell Acetabularia acetabulum that have vegetative terminal morphologies. Because they arrest in vegetative development, these cell lines are effectively immortalized. However, they had to be rescued before they could be studied via classical genetics because no heterozygotes from the original self-crosses were found, that is, the wild-type siblings yielded only wild-type progeny. We attempted to rescue these phenotypes in three ways: by amputating the cell apex, by "piggybacking" the mutant nucleus through development in a binucleate heterokaryon, and by replacing the abnormal apex with a wild-type apex. We used one of our immortal cell lines, kurkku, which has a terminal phenotype consistent with arrest early in the juvenile phase of vegetative development, as a prototype for these rescue methods. The kurkku phenotype segregated 1:3 in the original self-cross in which it arose as if it were a single, recessive Mendelian trait. Although amputation failed to rescue kurkku, we succeeded in compensating for the defect both in binucleate heterokaryons and in apical grafts to wild-type cells. kurkku was always recovered in the progeny of the self-crosses of these grafts. These unique ways of analyzing vegetative mutants, combined with the ability to then perform classical genetics, may make A. acetabulum a powerful unicellular model system for the study of vegetative phase change in plants.     

EAF1 regulates vegetative-phase change and flowering time in Arabidopsis.

We have identified a new locus that regulates vegetative phase change and flowering time in Arabidopsis. An early-flowering mutant, eaf1 (early flowering 1) was isolated and characterized. eaf1 plants flowered earlier than the wild type under either short-day or long-day conditions, and showed a reduction in the juvenile and adult vegetative phases. When grown under short-day conditions, eaf1 plants were slightly pale green and had elongated petioles, phenotypes that are observed in mutants altered in either phytochrome or the gibberellin (GA) response. eaf1 seed showed increased resistance to the GA biosynthesis inhibitor paclobutrazol, suggesting that GA metabolism and/or response had been altered. Comparison of eaf1 to other early-flowering mutants revealed that eaf1 shifts to the adult phase early and flowers early, similarly to the phyB (phytochrome B) and spy (spindly) mutants. eaf1 maps to chromosome 2, but defines a locus distinct from phyB, clf (curly leaf), and elf3 (early-flowering 3). These results demonstrate that eaf1 defines a new locus involved in an autonomous pathway and may affect GA regulation of flowering.     

Development of transgenic rice plants expressing maize anthocyanin genes and increased blast resistance

The functional association of flavonoids with plant stress responses, though widely reported in the literature, remains to be documented in rice. Towards this end we chose a transgenic approach with well characterized regulatory and structural genes from maize involved in flavonoid biosynthesis. Activation of anthocyanin pathway in rice was investigated with the maize genes. Production of purple anthocyanin pigments were observed in transformed Tp309 (a japonica rice variety) calluses upon the introduction of the maize regulatory genes C1 (coloured-1), R (red) and the structural gene C2 (coloured-2, encoding chalcone synthase). In addition, stable transgenic plants carrying the maize C2 gene under the control of the maize Ubiquitin promoter were generated. A localized appearance of purple/red pigment in the leaf blade and leaf sheath of R₀ C2 transgenic seedlings was observed. Such a patchy pattern of the transgene expression appears to be conditioned by the genetic background of Tp309, which is homozygous for dominant color inhibitor gene(s) whose presence was unravelled by appropriate genetic crosses. Southern blot analysis of the transgenic plants demonstrated that c2 cDNA was integrated into the genome. Western blot analysis of these primary transgenics revealed the CHS protein while it was not detected in the control untransformed Tp3O9, suggesting that Tp309 might have a mutation at the corresponding C2 locus or that the expression of this gene is suppressed in Tp309. Further analysis of C2 transgenics revealed CHS protein only in three out of sixteen plants that were western-positive in the R₀ generation, suggesting gene silencing. Preliminary screening of these R₁ plants against the rice blast fungus Magnaporthe grisea revealed an increase in resistance.     

leafy hull sterile1 is a homeotic mutation in a rice MADS box gene affecting rice flower development

Rice contains several MADS box genes. It has been demonstrated previously that one of these genes, OsMADS1 (for Oryza sativa MADS box gene1), is expressed preferentially in flowers and causes early flowering when ectopically expressed in tobacco plants. In this study, we demonstrated that ectopic expression of OsMADS1 in rice also results in early flowering. To further investigate the role of OsMADS1 during rice flower development, we generated transgenic rice plants expressing altered OsMADS1 genes that contain missense mutations in the MADS domain. There was no visible alteration in the transgenic plants during the vegetative stage. However, transgenic panicles typically exhibited phenotypic alterations, including spikelets consisting of elongated leafy paleae and lemmas that exhibit a feature of open hull, two pairs of leafy palea-like and lemma-like lodicules, a decrease in stamen number, and an increase in the number of carpels. In addition, some spikelets generated an additional floret from the same rachilla. These characteristics are very similar to those of leafy hull sterile1 (lhs1). The map position of OsMADS1 is closely linked to that of lhs1 on chromosome 3. Examination of lhs1 revealed that it contains two missense mutations in the OsMADS1 MADS domain. A genetic complementation experiment showed that the 11.9-kb genomic DNA fragment containing the wild-type OsMADS1 gene rescued the mutant phenotypes. In addition, ectopic expression of the OsMADS1 gene isolated from the lhs1 line resulted in lhs1-conferred phenotypes. These lines of evidence demonstrate that OsMADS1 is the lhs1 gene.     

Coordinate Suppression of Mutations Caused by Robertson''s Mutator Transposons in Maize

Transposable elements from the Robertson's Mutator family are highly active insertional mutagens in maize. However, mutations caused by the insertion of responder (non-autonomous) elements frequently depend on the presence of active regulator (autonomous) elements for their phenotypic effects. The hcf106::Mu1 mutation has been previously shown to depend on Mu activity in this way. The dominant Lesion-mimic 28 mutation also requires Mu activity for its phenotypic effects. We have used double mutants to show that the loss of Mu activity results in the coordinate suppression of both mutant phenotypes. This loss can occur somatically resulting in large clones of cells that have a wild-type phenotype. Autonomous and non-autonomous Mutator elements within these clones are insensitive to digestion with methylation-sensitive enzymes, suggesting extensive methylation of CG and non-CG cytosine residues. Our data are consistent with the sectors being caused by the cycling of MuDR regulatory elements between active and inactive phases. The pattern of sectors suggests that they are clonal and that they are derived from the apical cells of the vegetative shoot meristem. We propose that these cells are more likely to undergo epigenetic loss of Mu activity because of their longer cell division cycle during shoot growth. Coordinate suppression of unlinked mutations can be used to perform mosaic analysis in maize.