Application of GA to developing na2 tassels enhanced their feminisation, supporting this hypothesis.When considering mutants with pleiotropic phenotypes, it is difficult to ascertain whether we are observing epistasis, additivity, or synergy simply because there may be epistasis for one phenotype, but not for another. Thus it is important to take into account all metrics when evaluating the mutant interactions.The fun and na2 mutants interact both additively and synergistically in different tissues. The fun mutant acts additively with na2 to reduce the overall height of the plant by further affecting the tassel and internodes. Since the d5;na2 double mutant also showed additive effects for height31, this could point to a role for FUN in the GA pathway. On the other hand, the synergistic interaction between fun and na2 at the auricle would point to FUN’s involvement in the BR pathway. These two data need not be in contradiction – Best et al.’s work clearly showed that the BR and GA pathways impinge on one another31, and the FUN protein itself may be involved in this crosstalk. Though there is very mild feminisation in the bri1::RNAi tassel, this is not an originally described phenotype of the bri1::RNAi line, nor is it common in family AV802 . Further, the metric of branch number does not indicate feminisation in the bri1::RNAi tassel, though bri1::RNAi is slightly shorter which can be considered a feminine inflorescence trait. Lack of feminisation in the bri1::RNAi tassel is surprising since removing BR causes feminisation in the tassel in the na1 and na2 mutants. Combining the bri1::RNAi line with fun leads to more feminisation than fun alone, implying not simple epistasis by the feminised tassel of fun, but rather an enhancement of the very mild feminisation caused by bri1::RNAi. Similarly,vertical cannabis grow the reduced height phenotype is enhanced in the double mutant . Phenotype enhancement, or additivity, is also observed at the auricle.
Though auricle size was not found to be smaller in bri1::RNAi plants in family AV802, a smaller auricle in bri1::RNAi plants has been reported75. Thus we can consider the completely absent auricle phenotype observed in bri1::RNAi;fun plants in family AV802, as compared to the bri1::RNAi and fun single mutants of AV802, as an enhancement of the reduced auricle associated with fun. No leaf width phenotype has been reported for bri1::RNAi plants, and fun appears to have simple epistasis of the leaf width phenotype.According to almost all metrics measured, fun is epistatic to bin2::RNAi. The oversized auricle of bin2::RNAi is completely abolished in the double mutant. Since increased leaf angle has been linked to BR hypersensitivity in rice76 as well as appearing in this bin2::RNAi line, it is reasonable to assume that this monstrous auricle is a product of BR hypersensitivity, and by extension, auricle growth is promoted by BR. The fact that the fun mutation abolishes this auricle growth is strong support for the function of FUN in the BR pathway, downstream of bin2::RNAi. On the other hand, the retention of leaf blade margin crenulations in the double mutant does not fit into this explanation, unless FUN is simply not expressed along the margin, which would be consistent with the Wab1;fun double mutant . The strong feminisation seen in the double mutant is further support for the placement of fun downstream of bin2::RNAi in the BR signalling pathway. BR is known to accumulate in developing anthers, and hence is a hormone associated with masculinity in maize. The fact that loss of normal FUN produces feminisation in the bin2::RNAi background also supports the hypothesis that FUN is in the BR pathway, downstream of BIN2. Taking together these phenotypes and interactions, this analysis supports the hypothesis that fun functions late in BR pathway, perhaps at its intersection with GA. Additivity with na2 for height is observed as with the d5 GAknockout mutant. At the same time fun enhances the feminisation phenotype of BR deficient na2 and acts additively with the BR insensitive bri1:RNAi while abolishing the phenotypes of the hyper-responder bin2:RNAi. Figure 4-11 shows FUN’s tentative placement in the BR pathway.
Classical mutants tasselseed1and ts2 were first described by Emerson in 1920 following the “freak” class exhibition of the Annual Corn Show in Lincoln, Nebraska 1913-1487. Together with the classical mutant silkless1, described by Jones in 192588, these mutants have elucidated the role of JA in sex determination in Zea mays. The ts mutants bear tassels that are heavy with seeds, so that they bend over from their own weight at maturity. All or most flowers will be female, but the tassel retains a normal degree of branching that is not seen in the ear or fun mutant tassels87. Upon cloning, ts1 was found to be a lipoxygenase that catalyses a step in the JA biosynthetic pathway35. While the function of the alcohol dehydrogenase encoded by ts236 has not been definitively shown, the similarity of the ts1 and ts2 phenotype, the lack of any interaction in the ts1, ts2 double mutant, and rescue of the ts2 phenotype by JA application35 supports the hypothesis that it is also in the JA pathway. The sk1 mutant is described as developing normal cobs but failing to produce any silks such that even stripping back the husk leaves and pollinating directly onto the ear failed to produce any kernels. No differences in the tassel nor the vegetative parts of the plant were originally noted but it was later observed that sk1 has less tassel branches than normal siblings. Combining sk1 with the mutants ts1 and ts2 put sk1 in the same pathway. Though in the first generations of the double mutant sk1 and ts2, partial epistasis was observed, two further rounds of self pollinations of these double mutants revealed complete epistasis by ts2. That is, both the tassel and the ear bear silks. From this it was concluded that sk1 in some way inhibits the silk killing product of ts292, supposedly, JA35,36. This has been supported by the cloning of SK1 as a uridine diphosphate -glycosyltransferase, the overexpression of which resulted in very low JA accumulation in developing tassels and a feminised tassel phenotype37. In summary: SK1 breaks down JA that would otherwise lead to pistil abortion. In a normal tassel, JA accumulates in the pistils and they abort; in a normal ear, SK1 degrades the JA and prevents silk abortion.Since addition of JA was unable to fully rescue the feminised tassel of fun plants, FUN is unlikely to be deficient in JA.
Though failure to correct the feminised phenotype was more obvious in the first application of JA family AV920 still showed a failure to rescue by JA application when branch number is considered. AV920 was not ideal for this experiment because the fun plants in this family were not heavily feminised. This could have been due to the fact that they were grown in the winter greenhouse – greenhouse grown fun plants have been observed to be less feminised than those grown in the field, and the winter greenhouse is particularly sub-optimal for growing corn. Further these plants were the fun-2 allele, which has not been adequately characterised, but may have lower feminisation severity than the original fun-1 allele. Finally, the genealogy of these plants contains a recent cross to Mo17, which may have reduced the severity of the phenotype ,vertical farming system as well as the fact that some of the fun plants were heterozygous for ts1 . Nevertheless, JA application to fun and ts1 plants in family AV920 did not refute the original experiment showing that JA is unable to fully rescue the feminised tassel phenotype of fun plants. ts1 and fun can be considered additive in their effects on feminisation of the tassel. Double mutant tassels were more heavily feminised than either double mutant, supporting the hypothesis that ts1 and fun are in different pathways. The lack of lower floret abortion in the tassel of ts1 and ts1;fun plants compared to successful lower floret abortion in fun plants further supports the hypothesis that fun is not deficient in JA since JA is required for lower floret abortion in the ear. The loss of silks in the sk1;fun further refutes the hypothesis that FUN is involved in the production of JA. A JA biosynthetic mutant would be expected to retain silks in combination with sk1, as previously shown with ts1 and ts2. The retention of feminised traits in the form of glabrous, thickened glumes in the double mutant implies an additive interaction – the fun mutation is still causing aspects of feminisation in the tassel, though the lack of functional SK1 cannot protect the silk from abortion by the action of JA. Branch loss in both sk1 and fun, and the additivity in the double is a complex set of observations. Though branch loss is a feminine trait since the ear is branchless and tassels are branched, the sk1 mutant also has branch loss. sk1 is presumably high in JA due to the loss of the SK1 gene that is responsible for JA degradation. This high JA allows silk abortion, and so would seem to be a masculine characteristic. Paradoxically, this loss of functional SK1 is also associated with the feminine trait of less branching in the tassel, implying a role for JA in branch inhibition during tassel development. Since there is an additive interaction between the sk1 and fun mutations, and addition of JA to developing fun tassels lead to tassels that resembled the sk1;fun double mutant tassels, the hypothesis of FUN being outside of the JA pathway is supported.If we consider JA and BR as masculinising hormones in Zea mays, GA can be thought of as a feminising hormone. In the 50s, Nickerson showed that application of GA directly to the whorl during tassel development was sufficient to induce feminisation of the terminal inflorescence. In the early 80s it was shown that developing ears have GA levels two orders of magnitude higher than in developing tassels.
The d1 mutant in maize was shown to block steps in the GA biosynthesis pathway and when the gene was cloned it was found to be a GA3 oxidase that catalyses the final step in bioactive GA synthesis. While the most striking phenotype of d1 is its tiny stature, more pertinent to this discussion is its ear phenotype, dubbed “anther ear”. Without the presence of GA, the anthers of the ear do not arrest and instead grow out to produce bisexual flowers in the ear while the flowers of the tassel are normal63. As such it is perhaps erroneous to call GA a simple feminising hormone – rather it is a male killer hormone. The mRNA coding for D1 protein was shown by in situ to accumulate in stamen primordia of the developing ear which undergo cell cycle arrest and ceases growth early in its development. d1 mutant plants do not undergo this stamen primordia arrest in the ear. Since the fun mutant was feminised in the tassel, we made crosses to GA mutants and applied paclobutrazol which is an antagonist of the GA pathway and has applications as a plant growth retardant and fungicide95. PBZ blocks the entkaurene oxidation step of GA biosynthesis, and thus plants treated with this compound are unable to produce GA. PBZ has been used to investigate the role of GA in maize, and to elucidate the nature of dwarf mutants in the GA pathway. The dominant D9 mutant was obtained from the maize stock centre and is similar to the D8 maize mutant, which both bear similarities to the biosynthetic d1 mutant. D8 and D9 are both dwarf, have increased tillering, and display varying degrees of anther ear. All the D8 alleles described have anther ear, while D9 displays full anther ear in some backgrounds, but in others it develops anthers up to the point that they are visible with a magnifying glass. The D8 locus on chromosome 1 encodes a DELLA protein, and D9 has been shown to encode a duplicate of this protein located on chromosome 5. DELLA proteins are part of the Gibberellic Acid signalling pathway, and act to repress the GA response.