Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-23T20:05:26.445Z Has data issue: false hasContentIssue false

The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity

Published online by Cambridge University Press:  23 October 2023

Kay Schneitz*
Affiliation:
Plant Developmental Biology, TUM School of Life Sciences, Technical University of Munich, Munich, Germany
*
Corresponding author: Kay Schneitz; Email: [email protected]

Abstract

The 1991 review paper by Coen and Meyerowitz on the control of floral organ development set out the evidence available at that time, which led to the now famous ABC model of floral organ identity control. The authors summarised the genetic and molecular analyses that had been carried out in a relatively short time by several laboratories, mainly in Arabidopsis thaliana and Antirrhinum majus. The work was a successful example of how systematic genetic and molecular analysis can decipher the mechanism that controls a developmental process in plants. The ABC model is a combinatorial model in which each floral whorl acquires its identity through a unique combination of floral homeotic gene activities. The review also highlights the similarities in the regulation of floral organ identity between evolutionarily distant plant species, emphasising the general relevance of the model and paving the way for comprehensive studies of the evolution of floral diversity.

Type
Classics
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press in association with The John Innes Centre

The late 1980s and early 1990s were an exciting time in plant developmental biology. Within the period of about a year, from November 1990 to September 1991, two reviews on the role of homeotic genes in floral development appeared in Science (Schwarz-Sommer et al., Reference Schwarz-Sommer, Huijser, Nacken, Saedler and Sommer1990) and Nature (Coen & Meyerowitz, Reference Coen and Meyerowitz1991). The two reviews summarised the pioneering work that had been performed mainly in the laboratories of Enrico Coen at the John Innes Centre, Norwich, UK, Elliot M. Meyerowitz at the California Institute of Technology, Pasadena, CA, USA, and by Zsuzsanna Schwarz-Sommer and Hans Sommer from Heinz Saedler’s department at the Max Planck Institute for Plant Breeding Research, Cologne, Germany. In October 1991, yet another landmark paper was published in Nature, describing the exciting work of the laboratory of Gerd Jürgens, then at the Ludwig-Maximilians-University, Munich, Germany, later at the University of Tübingen, Tübingen, Germany, which successfully performed a systematic genetic analysis of the body organisation of the Arabidopsis embryo (Mayer et al., Reference Mayer, Ruiz, Berleth, Miséra and Jürgens1991).

What made these papers special? Two groundbreaking genetic analyses had identified the key genes that regulate segmental identity and segmentation in Drosophila (Lewis, Reference Lewis1978; Nüsslein-Volhard & Wieschaus, Reference Nüsslein-Volhard and Wieschaus1980). They paved the way for a series of subsequent molecular and genetic studies that identified a regulatory network of transcription factors and signalling components that control these and other important developmental decisions (Gehring, Reference Gehring1993; Morata & Lawrence, Reference Morata and Lawrence2022). The question was whether such a genetic and molecular strategy could be successful in plants. It should be remembered that plant developmental biology was not a new field of research at that time, but it was certainly an underexplored one. In fact, very little was known about the genetic and molecular mechanisms that regulate plant development (Steeves & Sussex, Reference Steeves and Sussex1989). There was a general belief that plant development, because of its inherently more flexible nature, must be controlled by mechanisms quite different from those that govern animal development. Unimaginable from a present-day perspective, a considerable number of plant scientists even believed that genes did not play a significant role in plant development. For many developmental biologists, including myself, who, like other aspiring plant developmental biologists of my generation, had an animal background (Schneitz et al., Reference Schneitz, Spielmann and Noll1993), the work summarised in these papers embodied the certainty that a coherent genetic and molecular approach was feasible and could lead to fundamental insights into the mechanisms underlying developmental processes in plants.

Obviously, the two reviews on floral homeotic genes did not come out of nowhere. In fact, floral mutants had been studied for centuries (Meyerowitz et al., Reference Meyerowitz, Smyth and Bowman1989). However, they provided a concise summary of the painstaking genetic work on floral homeotic mutants in Arabidopsis (Bowman et al., Reference Bowman, Smyth and Meyerowitz1989; Reference Bowman, Smyth and Meyerowitz1991; Komaki et al., Reference Komaki, Okada, Nishino and Shimura1988; Kunst et al., Reference Kunst, Klenz, Martinez-Zapater and Haughn1989; Meyerowitz et al., Reference Meyerowitz, Bowman, Brockman, Drews, Jack, Sieburth and Weigel1991; Schultz & Haughn, Reference Schultz and Haughn1991) and Antirrhinum (Carpenter & Coen, Reference Carpenter and Coen1990; Coen, Reference Coen1991; Coen et al., Reference Coen, Doyle, Romero, Elliott, Magrath and Carpenter1991; Stubbe, Reference Stubbe1966). The two reviews also highlighted the initial molecular identification and characterisation of the floral homeotic genes deficiens (def) (Sommer et al., Reference Sommer, Beltrán, Huijser, Pape, Lönnig, Saedler and Schwarz-Sommer1990) and floricaula (flo) (Coen et al., Reference Coen, Romero, Doyle, Elliott, Murphy and Carpenter1990) in Antirrhinum and AGAMOUS (AG) (Yanofsky et al., Reference Yanofsky, Ma, Bowman, Drews, Feldmann and Meyerowitz1990) in Arabidopsis. Here, I highlight the 1991 review by Coen and Meyerowitz titled ‘The war of the whorls: genetic interactions controlling flower development’. The reason is that in this review, results from the analysis of floral mutants from two evolutionary divergent species, Antirrhinum majus and Arabidopsis thaliana, were combined to propose a general model for the regulation of floral organ identity. The earlier review by Schwarz-Sommer et al. focussed on Antirrhinum floral development. The Coen and Meyerowitz review also discusses other aspects of floral development, including the determination of floral meristem identity, the control of floral organ number and floral symmetry. Here, I focus on floral organ identity because, from my perspective, this is what it is best known for.

Figure 1. The ABC model and the control of floral organ identity. (a) Mature wild-type flower of Arabidopsis thaliana. (b) Schematic representation of the ABC model. The four whorls and the corresponding floral organs are indicated as well as the A, B and C regions. The arrows denote that A and C functions act antagonistically. The spatial extent of the E function is also displayed. (c) Representation of the Arabidopsis apetala2 (ap2) mutant phenotype (defective in A function) and the explanation based on the ABC model. (d) The Arabidopsis pistillata (pi) mutant phenotype (loss of B function). (e) The Arabidopsis agamous (ag) mutant phenotype (defective in C function). The Se* notation indicates the defect in floral meristem termination as shown in (f). (f) Top view of a mature flower of the Arabidopsis ag mutant. Note the abundance of petals. The ag mutant is also defective in floral meristem termination and thus produces a flower within a flower. (g) Floral organisation of an Arabidopsis mutant lacking PI and AG activity (defective in B and C functions). (h) A mature flower of wild-type Cardamine pratensis. (i) An ag-like flower of a natural variant of Cardamine pratensis. Compare with (f). Abbreviations: ca, carpel; pe, petal; se, sepal; st, stamen. Images in (h,i) courtesy of Thomas Huber.

To understand how floral homeotic genes regulate floral organ identity, it is necessary to first look at the bauplan of the flowers of Arabidopsis and Antirrhinum (Fig. 1a). They consist of four concentric units called whorls. Each whorl is distinct and characterised by a unique type of floral organ. The outermost whorl 1 contains sepals; the next inner whorl 2 bears petals; whorl 3 features stamen and the innermost whorl 4 contains carpels, which carry the ovules. The two outermost whorls bearing the sepals and petals form the perianth. Organ number per whorls varies between whorls and the two species. For example, in Arabidopsis, whorl 1 bears four sepals, whereas whorl 3 contains six stamens. In Antirrhinum, whorl 1 bears five sepals and whorl 3 ultimately contains four stamens. Pattern formation in the flower thus leads to the formation of repeating developmental units, the concentric whorls, each of which is endowed with its own particular identity, as evidenced by the different types of floral organs of varying numbers that they form.

Homeotic genes are characterised by their respective mutant phenotypes. A defect in a homeotic gene disrupts the specification of early progenitor cells and eventually leads to the substitution of one organ type for another (Bateson, Reference Bateson1894). Careful systematic analysis of the type of organ transformation and where it occurs in the mutant flower led to the realisation that floral homeotic genes do not affect individual organs but three distinct and overlapping regions, each spanning two neighbouring whorls (Fig. 1b–g). The regions were named A, B and C, elaborating on a notation proposed in an earlier review by George Haughn and Chris Somerville (Haughn & Somerville, Reference Haughn and Somerville1988). Region A spans whorls 1 and 2, region B whorls 2 and 3 and region C whorls 3 and 4. For example, defects in the flowers of the Arabidopsis floral homeotic mutant apetala 2 (ap2) are restricted to region A as they form carpels rather than sepals in whorl 1 and stamens rather than petals in whorl 2 (Fig. 1c). A similar phenotype can be observed for ovulata (ovu) mutants in Antirrhinum. However, ovu mutants carry gain-of-function alleles of PLENA (PLE) (Bradley et al., Reference Bradley, Carpenter, Sommer, Hartley and Coen1993) (see below for problems with the A function). The pistillata (pi) mutant of Arabidopsis and the deficiens (def) mutant of Antirrhinum are affected in region B. Flowers of pi/def mutants carry sepals and carpels instead of petals and stamens in whorls 2 and 3, respectively (Fig. 1d). Plants with loss-of-function defects in the Arabidopsis gene AGAMOUS (AG) or its Antirrhinum homologue PLE bear flowers with defects restricted to region C with stamens in whorl 3 being substituted by petals and carpels in whorl 4 being replaced by sepals or variable structures (Fig. 1e,f). In addition, multiple homeotic genes can contribute to whorl identity. This is obvious in Antirrhinum where, for example, the combined action of DEF and GLOBOSA (GLO) regulate the identity of whorls 2 and 3 (region B). In Arabidopsis, a similar observation was made for PI and APETALA3 (AP3).

Analysis of Arabidopsis and Antirrhinum floral homeotic mutants eventually led to the now famous ABC model of floral organ identity control that was outlined so lucidly in the review by Coen and Meyerowitz. At its core, it is a combinatorial model. Multiple homeotic floral genes are assumed to operate in the three overlapping A, B and C regions providing each whorl with a unique combination of A, B and C regulatory functions (originally named a, b and c in Coen and Meyerowitz’s review) (Fig. 1b). The identity of whorl 1 sepals is based on the A function, of whorl 2 petals on a combination of A and B functions, of whorl 3 stamens on a combination of B and C functions and of whorl 4 carpels on C function. The model further states that the B function domain does not depend on either the A or C function genes. Finally, it includes an antagonistic interaction between A and C functions which results in the absence of C function activity in whorls 1 and 2 and A function activity in whorls 3 and 4.

What happens if there is no floral homeotic activity at all? Arabidopsis plants impaired in A, B and C functions, as in ap2 ap3 ag triple mutants, form flower-like structures made entirely of leaf-like organs (Bowman et al., Reference Bowman, Smyth and Meyerowitz1991). This finding suggests a leaf-like ‘ground state’ that is modified by the activity of homeotic genes. The idea that floral organs derive from a leaf-like ground state is reminiscent of surprisingly similar ideas put forward by two eminent German scholars of the eighteenth century. The embryologist Caspar Friedrich Wolff set out his hypothesis in his ‘Theoria Generationis’ (Wolff, Reference Wolff1759) and the poet Johann Wolfgang von Goethe formulated his thoughts in his ‘Metamorphose der Pflanzen’ (Goethe, Reference Goethe1790). Interestingly, both scholars derived their ideas from comparisons between regular and irregular flowers of a species, where, for example, stamens were transformed into petals. Such examples can be observed in nature today (Fig. 1h,i). In a sense, the two authors pioneered the use of a genetic analysis to study developmental processes, where one learns about the regular function of a gene by studying the consequences of the absence of its function, centuries before such an approach was commonly accepted and successfully applied to the study of development.

It is important to note that this elegant ABC model was derived entirely from genetics. It provided a robust framework that repeatedly proved itself in genetic experiments. The key point is that a unique combination of the functions A, B and C provides a pre-pattern in the floral meristem that ultimately determines the identity of each whorl. It conveniently explained all single and multiple mutant phenotypes. However, it did not provide ready insight into the molecular mechanism regulating floral organ identity. Nevertheless, it made testable predictions. For example, it proposed that activity of A, B and C functions is restricted to the respective A, B and C regions. Molecular analysis of the structure of floral homeotic genes and their mode of action revealed that in most cases the spatial regulation of gene activities underlying A, B and C functions occurs at the RNA level in young floral meristems. For example, in situ hybridisation data suggested that expression of DEF or AG is restricted to the B and C regions, respectively (Schwarz-Sommer et al., Reference Schwarz-Sommer, Huijser, Nacken, Saedler and Sommer1990;Sommer et al., Reference Sommer, Beltrán, Huijser, Pape, Lönnig, Saedler and Schwarz-Sommer1990; Yanofsky et al., Reference Yanofsky, Ma, Bowman, Drews, Feldmann and Meyerowitz1990). In addition, expression analysis further revealed that the A function gene APETALA2 (AP2) inhibits the expression of the C function gene AG in future whorls 1 and 2 (Drews et al., Reference Drews, Bowman and Meyerowitz1991).

In Drosophila, the homeotic genes regulating segment identity encode homeobox transcription factors (Gehring, Reference Gehring1993). Interestingly, floral homeotic genes also encode transcription factors but not of the homeobox family. Most of them, such as DEF or AG, encode transcription factors of the MADS-box class (Sommer et al., Reference Sommer, Beltrán, Huijser, Pape, Lönnig, Saedler and Schwarz-Sommer1990; Yanofsky et al., Reference Yanofsky, Ma, Bowman, Drews, Feldmann and Meyerowitz1990), named after the conserved DNA-binding motif shared by the canonical members of this gene family, which include yeast MCM1, AG, DEF and human SRF (Schwarz-Sommer et al., Reference Schwarz-Sommer, Huijser, Nacken, Saedler and Sommer1990). Thus, there is an interesting parallel logic in the regulation of regional identity between animals and plants (Meyerowitz, Reference Meyerowitz1997). In both instances, the overlapping spatial expression patterns of transcription factor genes determine the identities of repetitive body regions, segments in Drosophila and floral whorls in plants.

The elegant original ABC model was immediately widely accepted. However, it soon became apparent that the A, B and C genes were not sufficient for floral organ identity (Krizek & Meyerowitz, Reference Krizek and Meyerowitz1996; Mizukami & Ma, Reference Mizukami and Ma1992), indicating that additional components were missing. The missing factors turned out to be the four closely related and redundantly acting SEPALLATA (SEP) genes, also members of the MADS-box gene family (Ditta et al., Reference Ditta, Pinyopich, Robles, Pelaz and Yanofsky2004; Pelaz et al., Reference Pelaz, Ditta, Baumann, Wisman and Yanofsky2000). The SEP genes were assigned the E function required for petal, stamen and carpel identity, and thus the modern standard model is known as the ABCDE model [the D function is required for ovule development (Angenent et al., Reference Angenent, Franken, Busscher, van Dijken, van Went, Dons and van Tunen1995; Colombo et al., Reference Colombo, Franken, Koetje, van Went, Dons, Angenent and van Tunen1995) which happens within the carpel and for simplicity is not discussed here]. The genetic and molecular evidence led to the notion that the combinatorial property of the original ABC model relies on region-specific multimeric complexes of MADS-box transcription factors of the A, B and C classes in combination with one of the SEP factors and that these higher-order complexes are required and sufficient for promoting floral organ identity (Honma & Goto, Reference Honma and Goto2001; Pelaz et al., Reference Pelaz, Tapia-López, Alvarez-Buylla and Yanofsky2001). To reflect this molecular scenario, the ‘floral quartet model’ of floral organ identity has been proposed, which emphasises the different multimeric protein complexes (Theissen, Reference Theissen2001). Taken together, the ABCE/floral quartet model provides a convenient scenario for the regulation of floral organ identity in Arabidopsis. But is it universally applicable?

Through the comparisons between the regulators of floral development of Arabidopsis and Antirrhinum, the 1991 review by Coen and Meyerowitz also immediately demonstrated the importance of a comparative evolutionary developmental (evo-devo) genetics approach in assessing the general relevance of the findings. Their discussion of the topic highlighted that despite their taxonomic distance Antirrhinum and Arabidopsis share extensive homology with respect to the genetic and molecular mechanisms regulating floral organ identity. The ABC model inspired numerous laboratories to embark on a fruitful scientific journey to investigate the genetic and molecular basis of the evolution of floral organ identity (Chanderbali et al., Reference Chanderbali, Berger, Howarth, Soltis and Soltis2016; Kramer, Reference Kramer2019; Theißen et al., Reference Theißen, Melzer and Rümpler2016).

The evolutionary studies revealed a high degree of conservation but also interesting differences in the regulation of floral organ identity between plant species. For example, there is consensus in the literature that B and C function genes are required for reproductive organ identity across the angiosperms (Di Stilio, Reference Di Stilio2011). In addition, B and C class genes were found to be present in gymnosperms, where they are also expressed in reproductive organs (Gramzow et al., Reference Gramzow, Weilandt and Theißen2014; Melzer et al., Reference Melzer, Wang and Theissen2010; Winter et al., Reference Winter, Becker, Münster, Kim, Saedler and Theissen1999). The results suggest functional conservation between B/C class genes that seems to predate the emergence of angiosperms. However, the A function has been contentious from the beginning. For example, in contrast to Arabidopsis, no recessive loss-of-function alleles of A-function genes affecting the entire perianth (whorls 1 and 2) were identified in Antirrhinum or other investigated plants (Litt, Reference Litt2007). There is additional evidence that is difficult to reconcile with the original ABC model and often relates to the proposed dual role of the A function in controlling organ identity in whorls 1 and 2 and repressing C function in this region. Indeed, it is debated whether there is an A function equivalent to that proposed for Arabidopsis outside the Brassicaceae, or whether there is indeed an A function in any species (Causier et al., Reference Causier, Schwarz-Sommer and Davies2010). To address this central problem, Causier et al. proposed to replace the classical A function with a new (A) function resulting in an (A)BC model. The (A) function is flexible and expandable and can encapsulate multiple regulatory cascades. It first provides floral context by initially controlling floral meristem identity and subsequently regulates the B and C functions.

Another example relates to representatives of early-diverging (‘basal’) angiosperm lineages, including Amborella, Nymphaeales, magnoliids and basal eudicots. Corresponding representatives show an impressive floral diversity that encompasses more gradual transitions in organ identity, often including an undifferentiated perianth carrying organs called tepals (Chanderbali et al., Reference Chanderbali, Berger, Howarth, Soltis and Soltis2016). This is in contrast to the perianth organisation in Arabidopsis thaliana and Antirrhinum majus, which are highly derived species within the rosids and asterids, respectively, and bear distinct sepals and petals. The gradual transition in floral morphology during the early evolution of flowers was associated with broader expression domains of floral identity regulator genes [‘shifting border’ (Bowman, Reference Bowman1997) or ‘sliding boundary’ (Kramer et al., Reference Kramer, Di Stilio and Schlüter2003) models] and coupled with functional gradients such that there is decreasing expression/functional influence towards the edges of each expression domain (‘fading borders’ model) (Buzgo et al., Reference Buzgo, Soltis and Soltis2004; Chanderbali et al., Reference Chanderbali, Yoo, Zahn, Brockington, Wall, Gitzendanner, Albert, Leebens-Mack, Altman, Ma, dePamphilis, Soltis and Soltis2010). In this evolutionary model, the early ‘fading boundaries’ system with broadly overlapping expression domains evolved into the ABCE/(A)BC framework, including the sharply delineated expression domains of class A, B and C genes.

In retrospect, the impact of Coen and Meyerowitz’s (Reference Coen and Meyerowitz1991) review on the regulation of floral organ identity was profound. Although the original simple model has been modified and remains under scrutiny today, variations of the ABC model continue to form the basis of our understanding of how floral organ identity is regulated at the genetic and molecular level (Ali et al., Reference Ali, Raza, Atif, Aslam, Ajmal and Chung2019; Bowman et al., Reference Bowman, Smyth and Meyerowitz2012; Causier et al., Reference Causier, Schwarz-Sommer and Davies2010; Chanderbali et al., Reference Chanderbali, Berger, Howarth, Soltis and Soltis2016; Kramer, Reference Kramer2019; Rijpkema et al., Reference Rijpkema, Vandenbussche, Koes, Heijmans and Gerats2010; Rümpler & Theißen, Reference Rümpler and Theißen2019; Theißen et al., Reference Theißen, Melzer and Rümpler2016). The authors not only summarised the exciting new insights of the period culminating in the original ABC model, but convincingly highlighted the value of systematic molecular and genetic analysis in unravelling the regulation of plant development. Furthermore, the review illustrated the power of an evo-devo genetics approach and helped pave the way for rigorous molecular analysis of the evolutionary basis of the dazzling floral diversity that surrounds us today.

Acknowledgements

I thank members of my lab for fruitful discussions and the three referees for helpful comments.

Financial support

Work in my lab is supported by the Deutsche Forschungsgemeinschaft (Grant Nos. SFB924/TPA2, FOR2581/TP7 and SCHN 723/11-1).

Competing interest

The author declares no competing interest.

Authorship contribution

K.S. conceived and wrote this review.

Data availability statement

Data availability is not applicable to this article as no new data were created or analysed in this study.

References

Ali, Z., Raza, Q., Atif, R. M., Aslam, U., Ajmal, M., & Chung, G. (2019). Genetic and molecular control of floral organ identity in cereals. International Journal of Molecular Sciences, 20, 2743. https://doi.org/10.3390/ijms20112743 CrossRefGoogle ScholarPubMed
Angenent, G. C., Franken, J., Busscher, M., van Dijken, A., van Went, J. L., Dons, H. J., & van Tunen, A. J. (1995). A novel class of MADS box genes is involved in ovule development in petunia. The Plant Cell, 7, 15691582.Google Scholar
Bateson, W. (1894). Materials for the study of variation. Macmillan.Google Scholar
Bowman, J. L. (1997). Evolutionary conservation of angiosperm flower development at the molecular and genetic levels. Journal of Biosciences, 22, 515527.CrossRefGoogle Scholar
Bowman, J. L., Smyth, D. R., & Meyerowitz, E. M. (1989). Genes directing flower development in Arabidopsis . The Plant Cell, 1, 3752.Google ScholarPubMed
Bowman, J. L., Smyth, D. R., & Meyerowitz, E. M. (1991). Genetic interactions among floral homeotic genes of Arabidopsis . Development, 112, 120.CrossRefGoogle ScholarPubMed
Bowman, J. L., Smyth, D. R., & Meyerowitz, E. M. (2012). The ABC model of flower development: Then and now. Development, 139, 40954098.CrossRefGoogle ScholarPubMed
Bradley, D., Carpenter, R., Sommer, H., Hartley, N., & Coen, E. (1993). Complementary floral homeotic phenotypes result from opposite orientations of a transposon at the plena locus of Antirrhinum . Cell, 72, 8595.CrossRefGoogle ScholarPubMed
Buzgo, M., Soltis, P. S., & Soltis, D. E. (2004). Floral developmental morphology of Amborella trichopoda (Amborellaceae). International Journal of Plant Sciences, 165, 925947.CrossRefGoogle Scholar
Carpenter, R., & Coen, E. S. (1990). Floral homeotic mutations produced by transposon-mutagenesis in Antirrhinum majus . Genes & Development, 4, 14831493.CrossRefGoogle ScholarPubMed
Causier, B., Schwarz-Sommer, Z., & Davies, B. (2010). Floral organ identity: 20 years of ABCs. Seminars in Cell & Developmental Biology, 21, 7379.CrossRefGoogle ScholarPubMed
Chanderbali, A. S., Berger, B. A., Howarth, D. G., Soltis, P. S., & Soltis, D. E. (2016). Evolving ideas on the origin and evolution of flowers: New perspectives in the genomic era. Genetics, 202, 12551265.CrossRefGoogle ScholarPubMed
Chanderbali, A. S., Yoo, M.-J., Zahn, L. M., Brockington, S. F., Wall, P. K., Gitzendanner, M. A., Albert, V. A., Leebens-Mack, J., Altman, N. S., Ma, H., dePamphilis, C. W., Soltis, D. E., & Soltis, P. S. (2010). Conservation and canalization of gene expression during angiosperm diversification accompany the origin and evolution of the flower. Proceedings of the National Academy of Sciences of the United States of America, 107, 2257022575.CrossRefGoogle ScholarPubMed
Coen, E. S. (1991). The role of homeotic genes in flower development and evolution. Annual Review of Plant Physiology and Plant Molecular Biology, 42, 241279.CrossRefGoogle Scholar
Coen, E. S., Doyle, S., Romero, J. M., Elliott, R., Magrath, R., & Carpenter, R. (1991). Homeotic genes controlling flower development in Antirrhinum . Development, 113, 149155.CrossRefGoogle Scholar
Coen, E. S., & Meyerowitz, E. M. (1991). The war of the whorls: Genetic interactions controlling flower development. Nature, 353, 3137.CrossRefGoogle ScholarPubMed
Coen, E. S., Romero, J. M., Doyle, S., Elliott, R., Murphy, G., & Carpenter, R. (1990). floricaula: A homeotic gene required for flower development in Antirrhinum majus . Cell, 63, 13111322.CrossRefGoogle ScholarPubMed
Colombo, L., Franken, J., Koetje, E., van Went, J., Dons, H. J., Angenent, G. C., & van Tunen, A. J. (1995). The petunia MADS box gene FBP11 determines ovule identity. The Plant Cell, 7, 18591868.Google ScholarPubMed
Di Stilio, V. S. (2011). Empowering plant evo-devo: Virus induced gene silencing validates new and emerging model systems. BioEssays: News and Reviews in Molecular, Cellular and Developmental Biology, 33, 711718.CrossRefGoogle ScholarPubMed
Ditta, G., Pinyopich, A., Robles, P., Pelaz, S., & Yanofsky, M. F. (2004). The SEP4 gene of Arabidopsis thaliana functions in floral organ and meristem identity. Current Biology: CB, 14, 19351940.CrossRefGoogle ScholarPubMed
Drews, G. N., Bowman, J. L., & Meyerowitz, E. M. (1991). Negative regulation of the Arabidopsis homeotic gene AGAMOUS by the APETALA2 product. Cell, 65, 9911002.CrossRefGoogle ScholarPubMed
Gehring, W. J. (1993). Exploring the homeobox. Gene, 135, 215221.CrossRefGoogle ScholarPubMed
Goethe, J. W. (1790). Die Metamorphose der Pflanzen. J.G. Cotta.Google Scholar
Gramzow, L., Weilandt, L., & Theißen, G. (2014). MADS goes genomic in conifers: Towards determining the ancestral set of MADS-box genes in seed plants. Annals of Botany, 114, 14071429.CrossRefGoogle ScholarPubMed
Haughn, G. W., & Somerville, C. R. (1988). Genetic control of morphogenesis in Arabidopsis . Developmental Genetics, 9, 7389.CrossRefGoogle Scholar
Honma, T., & Goto, K. (2001). Complexes of MADS-box proteins are sufficient to convert leaves into floral organs. Nature, 409, 525529.CrossRefGoogle ScholarPubMed
Komaki, M. K., Okada, K., Nishino, E., & Shimura, Y. (1988). Isolation and characterization of novel mutants of Arabidopsis thaliana defective in flower development. Development, 104, 195203.CrossRefGoogle Scholar
Kramer, E. M. (2019). Plus ça change, plus c’est la même chose: The developmental evolution of flowers. Current Topics in Developmental Biology, 131, 211238.CrossRefGoogle ScholarPubMed
Kramer, E. M., Di Stilio, V. S., & Schlüter, P. M. (2003). Complex patterns of gene duplication in the APETALA3 and PISTILLATA lineages of the Ranunculaceae. International Journal of Plant Sciences, 164, 111.CrossRefGoogle Scholar
Krizek, B. A., & Meyerowitz, E. M. (1996). The Arabidopsis homeotic genes APETALA3 and PISTILLATA are sufficient to provide the B class organ identity function. Development, 122, 1122.CrossRefGoogle Scholar
Kunst, L., Klenz, J. E., Martinez-Zapater, J., & Haughn, G. W. (1989). AP2 gene determines the identity of perianth organs in flowers of Arabidopsis thaliana . The Plant Cell, 1, 11951208.CrossRefGoogle ScholarPubMed
Lewis, E. B. (1978). A gene complex controlling segmentation in Drosophila . Nature, 276, 565570.CrossRefGoogle ScholarPubMed
Litt, A. (2007). An evaluation of A-function: Evidence from the APETALA1 and APETALA2 gene lineages. International Journal of Plant Sciences, 168, 7391.CrossRefGoogle Scholar
Mayer, U., Ruiz, R. A. T., Berleth, T., Miséra, S., & Jürgens, G. (1991). Mutations affecting body organization in the Arabidopsis embryo. Nature, 353, 402407.CrossRefGoogle Scholar
Melzer, R., Wang, Y.-Q., & Theissen, G. (2010). The naked and the dead: The ABCs of gymnosperm reproduction and the origin of the angiosperm flower. Seminars in Cell & Developmental Biology, 21, 118128.CrossRefGoogle ScholarPubMed
Meyerowitz, E. M. (1997). Plants and the logic of development. Genetics, 145, 59.CrossRefGoogle ScholarPubMed
Meyerowitz, E. M., Bowman, J. L., Brockman, L. L., Drews, G. N., Jack, T., Sieburth, L. E., & Weigel, D. (1991). A genetic and molecular model for flower development in Arabidopsis thaliana . Development, 113, 157167.CrossRefGoogle Scholar
Meyerowitz, E. M., Smyth, D. R., & Bowman, J. L. (1989). Abnormal flowers and pattern formation in floral development. Development, 106, 209217.CrossRefGoogle Scholar
Mizukami, Y., & Ma, H. (1992). Ectopic expression of the floral homeotic gene AGAMOUS in transgenic Arabidopsis plants alters floral organ identity. Cell, 71, 119131.CrossRefGoogle ScholarPubMed
Morata, G., & Lawrence, P. (2022). An exciting period of Drosophila developmental biology: Of imaginal discs, clones, compartments, parasegments and homeotic genes. Developmental Biology, 484, 1221.CrossRefGoogle ScholarPubMed
Nüsslein-Volhard, C., & Wieschaus, E. (1980). Mutations affecting segment number and polarity in Drosophila . Nature, 287, 795801.CrossRefGoogle ScholarPubMed
Pelaz, S., Ditta, G. S., Baumann, E., Wisman, E., & Yanofsky, M. F. (2000). B and C floral organ identity functions require SEPALLATA MADS-box genes. Nature, 405, 200203.CrossRefGoogle Scholar
Pelaz, S., Tapia-López, R., Alvarez-Buylla, E. R., & Yanofsky, M. F. (2001). Conversion of leaves into petals in Arabidopsis . Current Biology, 11, 182184.CrossRefGoogle ScholarPubMed
Rijpkema, A. S., Vandenbussche, M., Koes, R., Heijmans, K., & Gerats, T. (2010). Variations on a theme: Changes in the floral ABCs in angiosperms. Seminars in Cell & Developmental Biology, 21, 100107.CrossRefGoogle ScholarPubMed
Rümpler, F., & Theißen, G. (2019). Reconstructing the ancestral flower of extant angiosperms: The ‘war of the whorls’ is heating up. Journal of Experimental Botany, 70, 26152622.CrossRefGoogle ScholarPubMed
Schneitz, K., Spielmann, P., & Noll, M. (1993). Molecular genetics of aristaless, a prd-type homeo box gene involved in the morphogenesis of proximal and distal pattern elements in a subset of appendages in Drosophila . Genes & Development, 7, 114129.CrossRefGoogle Scholar
Schultz, E. A., & Haughn, G. W. (1991). LEAFY, a homeotic gene that regulates inflorescence development in Arabidopsis . The Plant Cell, 3, 771781.CrossRefGoogle ScholarPubMed
Schwarz-Sommer, Z., Huijser, P., Nacken, W., Saedler, H., & Sommer, H. (1990). Genetic control of flower development by homeotic genes in Antirrhinum majus . Science, 250, 931936.CrossRefGoogle ScholarPubMed
Sommer, H., Beltrán, J. P., Huijser, P., Pape, H., Lönnig, W. E., Saedler, H., & Schwarz-Sommer, Z. (1990). Deficiens, a homeotic gene involved in the control of flower morphogenesis in Antirrhinum majus: The protein shows homology to transcription factors. The EMBO Journal, 9, 605613.CrossRefGoogle ScholarPubMed
Steeves, T. A., & Sussex, I. M. (1989). Patterns in plant development. Cambridge University Press.CrossRefGoogle Scholar
Stubbe, H. (1966). Genetik und Zytologie von Antirrhinum L. sect. Antirrhinum. VEB Gustav Fischer.Google Scholar
Theissen, G. (2001). Development of floral organ identity: Stories from the MADS house. Current Opinion in Plant Biology, 4, 7585.CrossRefGoogle ScholarPubMed
Theißen, G., Melzer, R., & Rümpler, F. (2016). MADS-domain transcription factors and the floral quartet model of flower development: Linking plant development and evolution. Development, 143, 32593271.CrossRefGoogle ScholarPubMed
Winter, K. U., Becker, A., Münster, T., Kim, J. T., Saedler, H., & Theissen, G. (1999). MADS-box genes reveal that gnetophytes are more closely related to conifers than to flowering plants. Proceedings of the National Academy of Sciences of the United States of America, 96, 73427347.CrossRefGoogle ScholarPubMed
Wolff, C. F. (1759). Theoria generationis. Pauli Emanueli Fickischen.Google Scholar
Yanofsky, M. F., Ma, H., Bowman, J. L., Drews, G. N., Feldmann, K. A., & Meyerowitz, E. M. (1990). The protein encoded by the Arabidopsis homeotic gene agamous resembles transcription factors. Nature, 346, 3539.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. The ABC model and the control of floral organ identity. (a) Mature wild-type flower of Arabidopsis thaliana. (b) Schematic representation of the ABC model. The four whorls and the corresponding floral organs are indicated as well as the A, B and C regions. The arrows denote that A and C functions act antagonistically. The spatial extent of the E function is also displayed. (c) Representation of the Arabidopsis apetala2 (ap2) mutant phenotype (defective in A function) and the explanation based on the ABC model. (d) The Arabidopsis pistillata (pi) mutant phenotype (loss of B function). (e) The Arabidopsis agamous (ag) mutant phenotype (defective in C function). The Se* notation indicates the defect in floral meristem termination as shown in (f). (f) Top view of a mature flower of the Arabidopsis ag mutant. Note the abundance of petals. The ag mutant is also defective in floral meristem termination and thus produces a flower within a flower. (g) Floral organisation of an Arabidopsis mutant lacking PI and AG activity (defective in B and C functions). (h) A mature flower of wild-type Cardamine pratensis. (i) An ag-like flower of a natural variant of Cardamine pratensis. Compare with (f). Abbreviations: ca, carpel; pe, petal; se, sepal; st, stamen. Images in (h,i) courtesy of Thomas Huber.

Author comment: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R0/PR1

Comments

Dear editor,

please find enclosed my invited review for a paper of the “classics” section. I had no example to guide me and thus I hope it fits and corresponds to the expectations.

I added a figure to the main text but could not come up with a separate graphical abstract that does not replicate the figure. I simply uploaded a section of this figure as GA. Otherwise I could not have finished the submission. I don’t think it is suitable and if someone at the journal has a good idea please go ahead.

Sincerely, Kay Schneitz

Review: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R0/PR2

Conflict of interest statement

Reviewer declares none.

Comments

This is a historical review about the conception of the classic ABC model of flower development in the early 1990s. The author highlights the pivotal role that this model played in raising plant development to a higher level, and in launching the field of plant evo-devo. The article reminds us that plant development was not always the burgeoning field it is today, and points at how this mechanistic model helped place it on par with Drosophila genetics, helping draw parallels between animal and plant development. It is also good to be reminded of Goethe’s “all is leaf” idea.

I enjoyed reading certain passages, especially on page 4, comparing plant and animal development “…these papers embodied the certainty that a coherent genetic and molecular approach was feasible and could lead to fundamental insights into the mechanisms underlying developmental processes in plants.”

Having said that, I also have reservations about the added value of this historical review at this point in time, for the following reasons:

1) Similar reviews have been published in the last 20 years, some by the protagonists of the model (e.g., Bowman et al 2012-Development; Coen 2001, Irish 2017-Curr Biol; Jack 2001-Trends in PL Sci, among others).

2) The manuscript has some less focused parts, such as on page 3 midway a whole paragraph describing research on the Arabidopsis embryo, whose relevance to the rest of the argument on ABC model is unclear (including details of date and journal that should be left to the citation). Same comment on citation applies to the top of page 5, where pointing out that the work was published in the journal Science seems unnecessary (a parenthetical citation suffices).

3) On page 6, while providing one example of how the classes work seems reasonable, going on to explain each one seems redundant (from “The pistillata” to end of paragraph). Related to this, previous examples of class A mutants in Arabidopsis and Antirrhinum would need citations.

4) There is no mention of the E class and its key importance in flower evolution, not even after discussing the triple mutant, which would naturally lead to how the triple over-expressor does not recapitulate floral organs and the classic Goto (2001) paper, also not cited.

5) While I can see the value of getting such an on-target summary from chatGPT, I would not think of an AI generated text as a worthy addition to a publication, except perhaps as a side comment, or shorter quote.

6) Finally, I was excited to see panels C- E in Fig. 1, panel E particularly beautiful, and I thought it could have led to a more fruitful discussion of the potential importance of these mutations in the wild (with a few great examples to cite), but it was barely touched upon.

Review: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R0/PR3

Conflict of interest statement

Reviewer declares none.

Comments

This « Classics » manuscript describes the historical context and implications of the seminal review paper by Enrico Coen and Elliot Meyerowitz about the genetic control of floral organ identity. Indeed, this review paper is one of two that proposed, more or less simultaneously, a combinatorial model for the specification of floral organ identities (the now famous ABC model). This review paper has become a classic without any doubt, and has opened an avenue of research on floral homeotic genes, the molecular mechanisms behind their action, and their conservation across flowering plants and beyond.

I very much enjoyed reading this manuscript, and in particular the historical context in which this ground-breaking paper was published. After, the author describes in detail how the textbook ABC model was established based on the characterization of single- or multiple-order floral homeotic mutants. Then, the author explains how this model was validated by further molecular evidence, such as the expression domains of ABC genes, and how the ABC model was generally validated for all flowering plants. The author highlighted the importance of this article throughout the manuscript.

I have some minor comments, some of them are suggestions that I would have appreciated reading, but it is really up to the author whether he wants to incorporate them or not:

- In the first paragraph of p.3, remove « that » in the sentence « In October 1991 yet another landmark paper that was published in Nature... »

- Following the discussion about matching expression domains of ABC genes to their proposed function, it could be added that the combinatorial nature of the ABC model has been incarnated by molecular interactions between the MADS protein players (ie the quartet model). I think this has been an important extension of the ABC model.

- I would have appreciated a few more sentences about the limits to the ABC model and alternative models that have been proposed. For now, there is only a mention of « discrepancies regarding the a function », and that the « original simple model has been modified ». The fading border model is an important one for early-diverging angiosperms for instance, and the review by Causier et al. in 2010 (Floral organ identity: 20 years of ABCs) proposed an (A)BC model that is more widely applicable to flowering plants than the textbook ABC model. In this model, the (A) function is a floral one, providing a general context for the action of B- and C-class genes in specifying petal, stamen and carpel identity. This model is more compatible with the problematic A function that is probably a specificity of Brassicaceae.

- In the last paragraph, the author asked ChatGPT to sum up the main findings on the Coen and Meyerowitz paper. Although the approach is intriguing and the result nicely shows how famous the ABC model has become, I found the summary provided by ChatGPT to be a very generic and partly redundant one. For instance, the notion of combinatorial activity is repeated several times. Also, apart from showing how astonishingly good ChatGPT is, I do not think its answers provide any supplementary insights to this paper than what the author already discussed in the previous paragraphs (and of course the author did a much better job than ChatGPT).

Review: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R0/PR4

Conflict of interest statement

Reviewer declares none.

Comments

The floral ABC model published by Coen & Meyerowitz (1991), which is the subject of this Classics review by Kay Schneitz, was a major turning point in the study and understanding of flower development. In the 30+ years since the model was first proposed, there have been countless research publications from all over the world, describing aspects of floral organ production as a direct consequence of this influential paper.

It is sometimes easy to forget the pioneering ideas that open up new doors to discovery. Here, in his review of the War of the Whorls, Schneitz gives a nice historical perspective on the derivation of the ABC model. I enjoyed reading this clearly written article, and revisiting the original Nature paper. The thought-provoking use of AI at the end of the review was a nice addition.

I have a few minor comments that may improve the manuscript:

Figure 1: for the sake of completeness, the schematic representation of a b-function mutant should also be included.

While the photographs in this figure are nice, I’m not sure how relevant part E is to the review. An example of ag-like flowers for this species is already shown in D. By removing part E, there will be space in the figure to include the b-function mutant.

The usual convention is for Figure panels to be arranged in the order they appear in the text. That is not the case here.

Page 5, second line: The full-stop after ‘et.’ should be deleted.

Page 6: It might be clearer to refer to ‘Region A’, ‘Region B’ and ‘Region C’ throughout, rather than just A, B or C. It would also be useful to refer to the appropriate panels of the Figure throughout the first part of page 6.

In the second paragraph (and throughout the manuscript), the author should underline the a, b and c regulatory functions (as Coen & Meyerowitz did) to improve readability.

Page 8, second paragraph: DEF, AG, MCM1 and SRF genes should all be italicised.

Recommendation: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R0/PR5

Comments

Dear Pr Schneitz,

We thank you very much for your appreciated manuscript highlighting the importance of the pioneer work by Coen and Meyerowitz.

Your manuscript has been now revised by three reviewers (please find their comments below) with interesting comments to improve the manuscript. In agreement with them, I think it would be interesting to develop a little bit the limitations of the ABC model and the main alternative models proposed nowadays, and to synthetize the result of your “AI experiment” at the end of the manuscript, and develop your thoughts/conclusions on it: what are the questions triggered?

We would be happy to receive a corrected version of your manuscript when it is ready.

We thank you again for having submitted your manuscript to Quantitative Plant Biology.

Thank you very much in advance,

Looking forward to reading you

Best regards

Daphné Autran

Decision: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R0/PR6

Comments

No accompanying comment.

Author comment: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R1/PR7

Comments

No accompanying comment.

Review: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R1/PR8

Conflict of interest statement

Reviewer declares none.

Comments

The author has addressed all my comments: he has added one paragraph discussing the E-function and the quartet model, one discussing the limitations of the A function, and another one about the applicability of the ABC model to early-diverging angiosperms. I think the current manuscript is a nice addition to the existing litterature on the topic.

Review: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R1/PR9

Conflict of interest statement

Reviewer declares none.

Comments

The updated version of this review is a significant improvement on the original. While I quite liked the ChatGPT section of the original, the sections that now replace it, as suggested by the other reviewers, are much more important additions to this article.

I have some minor points:

On page 7, lines 113-114 you say that the Antirrhinum ovu mutant resembles Arabidopsis ap2, leaving the reader to infer that OVU is an Antirrhinum A-function gene. Later, on page 11, lines 224-227, you correctly say that no null A-function mutants with homeotic changes to both whorls 1 and 2 have been identified in Antirrhinum or other species. This is slightly at odds with the earlier description of the ovu mutant. Somewhere it needs to be made clear that ovu is a PLE gain-of-function allele (Bradley et al., 1993) and not a true A-function mutant.

Line 170: please change “a function” to “A function”

Review: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R1/PR10

Conflict of interest statement

Reviewer declares none.

Comments

The author has addressed most of my concerns, except point 3) where perhaps they feel necessary to keep the full explanation of all mutant classes (Lines 114-124, see related comment on Fig 1, where I suggest keeping only WT and ag diagrams).

Overall, I thought the original figure was more effective. I had not requested for it to change, but rather to provide more comment on the mutant in the wild.

Other minor points that arise from newly added sections are listed below.

<u>Detailed comments (by line number)</u>:

Line 193: Please provide a reference for D function

Lines 218-222: citations are needed here also (B and C conservation across angiosperms, reviewed e.g. in 10.1002/bies.201100040; presence in gymnosperms)

238: Incorrect use of term “ancestral”, no extant organisms are ancestral, they may exhibit ancestral character states, or they may be representative of early-diverging lineages. I suggest instead “Another example relates to representatives of ancestral angiosperm lineages…” OR “Another example relates to early-diverging (“basal”) angiosperm lineage representatives…” Deleting that phrase will also take care of the issue that Amborella and Nymphaeles are basal angiosperms (ANITA grade members), while magnoliids are another lineage, and neither are eudicots. The Eudicot lineage is more recent and contains Core Eudicots (Arabidopsis, Antirrhinum, etc.) and non-core or early-diverging Eudicots (Ranunculids et al). For examples on abc model in early diverging Eudicots the author may refer to work done in the Ranunculids Aquilegia (cited), Thalictrum and California poppy.

241 …more gradual transitions in organ identity

253: the incorporation of the fading borders models is a nice addition, the author could consider adding that ‘shifting border’ (Bowman, 1997) and ‘sliding boundary’ (Kramer et al., 2003) model variations were also proposed to explain the diversity of flower morphology beyond basal angiosperms, such as the tepals of monocot lilies with perianth consisting of two whorls of equally petaloid organs expressing B genes.

259 by “variants” maybe the author means variations? It could be mistaken with mutants.

Figure 1:

The addition of the E class is an improvement, but the block should not go beyond the A+C blocks in my opinion, as this would suggest expression/function somewhere beyond whorls 1 and 4.

I personally preferred the previous version of this figure, with all photographs arranged together on one side, rather than interspersed with graphs, and with the original example of the agamousmutant in a wild population, I thought that was an especially unique contribution. Other examples of the use of abc mutants in the wild can be cited when referring to that panel, e.g. 10.1093/jxb/erl158; 10.1093/aob/mcad069 and 10.1016/j.cub.2022.01.066.

WT and c (ag) mutant models would be sufficient in this figure, as those are shown in the photo panels and the rest is repetitive and has been depicted too many times to warrant another reproduction.

Recommendation: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R1/PR11

Comments

Dear Kay,

We thank you very much for all the revisions in the very nice new version of your manuscript. This new version was submitted to the reviewers whose response are very positive (please find copy of their comments below), yet reviewers 1 and 3 suggest a few minor revisions on the newly added sections. I suggest to include these minor revisions, except for the revisions of Figure 1 suggested by Reviewer 1, which seem to me optionnal, since the current figure is clear and the wild ag mutant is represented. However, you might choose to change it according to the reveiwer suggestions.

Many thanks again for your contribution to Quantitative Plant Biology and for all your work.

Best regards

Daphné

Reviewer 1:

The author has addressed most of my concerns, except point 3) where perhaps they feel necessary to keep the full explanation of all mutant classes (Lines 114-124, see related comment on Fig 1, where I suggest keeping only WT and ag diagrams).

Overall, I thought the original figure was more effective. I had not requested for it to change, but rather to provide more comment on the mutant in the wild.

Other minor points that arise from newly added sections are listed below.

Detailed comments (by line number):

Line 193: Please provide a reference for D function

Lines 218-222: citations are needed here also (B and C conservation across angiosperms, reviewed e.g. in 10.1002/bies.201100040; presence in gymnosperms)

238: Incorrect use of term “ancestral”, no extant organisms are ancestral, they may exhibit ancestral character states, or they may be representative of early-diverging lineages. I suggest instead “Another example relates to representatives of ancestral angiosperm lineages…” OR “Another example relates to early-diverging (“basal”) angiosperm lineage representatives…” Deleting that phrase will also take care of the issue that Amborella and Nymphaeles are basal angiosperms (ANITA grade members), while magnoliids are another lineage, and neither are eudicots. The Eudicot lineage is more recent and contains Core Eudicots (Arabidopsis, Antirrhinum, etc.) and non-core or early-diverging Eudicots (Ranunculids et al). For examples on abc model in early diverging Eudicots the author may refer to work done in the Ranunculids Aquilegia (cited), Thalictrum and California poppy.

241 …more gradual transitions in organ identity

253: the incorporation of the fading borders models is a nice addition, the author could consider adding that ‘shifting border’ (Bowman, 1997) and ‘sliding boundary’ (Kramer et al., 2003) model variations were also proposed to explain the diversity of flower morphology beyond basal angiosperms, such as the tepals of monocot lilies with perianth consisting of two whorls of equally petaloid organs expressing B genes.

259 by “variants” maybe the author means variations? It could be mistaken with mutants.

Figure 1:

The addition of the E class is an improvement, but the block should not go beyond the A+C blocks in my opinion, as this would suggest expression/function somewhere beyond whorls 1 and 4.

I personally preferred the previous version of this figure, with all photographs arranged together on one side, rather than interspersed with graphs, and with the original example of the agamous mutant in a wild population, I thought that was an especially unique contribution. Other examples of the use of abc mutants in the wild can be cited when referring to that panel, e.g. 10.1093/jxb/erl158; 10.1093/aob/mcad069 and 10.1016/j.cub.2022.01.066.

WT and c (ag) mutant models would be sufficient in this figure, as those are shown in the photo panels and the rest is repetitive and has been depicted too many times to warrant another reproduction.

Reviewer 2:

The author has addressed all my comments: he has added one paragraph discussing the E-function and the quartet model, one discussing the limitations of the A function, and another one about the applicability of the ABC model to early-diverging angiosperms. I think the current manuscript is a nice addition to the existing litterature on the topic.

Reviewer 3:

The updated version of this review is a significant improvement on the original. While I quite liked the ChatGPT section of the original, the sections that now replace it, as suggested by the other reviewers, are much more important additions to this article.

I have some minor points:

On page 7, lines 113-114 you say that the Antirrhinum ovu mutant resembles Arabidopsis ap2, leaving the reader to infer that OVU is an Antirrhinum A-function gene. Later, on page 11, lines 224-227, you correctly say that no null A-function mutants with homeotic changes to both whorls 1 and 2 have been identified in Antirrhinum or other species. This is slightly at odds with the earlier description of the ovu mutant. Somewhere it needs to be made clear that ovu is a PLE gain-of-function allele (Bradley et al., 1993) and not a true A-function mutant.

Line 170: please change “a function” to “A function”

Decision: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R1/PR12

Comments

No accompanying comment.

Author comment: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R2/PR13

Comments

Dear Daphne and Olivier,

I followed Daphne’s suggestions for this final revision (R2). I kept figure 1 as in R1. I hope the MS is now acceptable. Cheers, Kay

Recommendation: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R2/PR14

Comments

Dear Kay,

I sincerely apologize for the waste of time with your last version due to my mistakes with the system.

Many thanks for your revised final version which includes all the last reviewers minor corrections.

Thanks again for your contribution to Quantitative Plant Biology

Best regards

Daphné

Decision: The 1991 review by Coen and Meyerowitz on the war of the whorls and the ABC model of floral organ identity — R2/PR15

Comments

No accompanying comment.