The initial domains of homeotic gene expression are influenced by the gap genes and pair-rule genes. For instance, expression of the abdA and AbdB genes is repressed by the gap gene proteins Hunchback and Krüppel. This inhibition prevents these abdomen-specifying genes from being expressed in the head and thorax (Casares and Sánchez-Herrero 1995). Conversely, the Antennapedia gene is activated by particular levels of Hunchback (needing both the maternal and the zygotically transcribed messages), so Antennapedia is originally transcribed in parasegment 4, specifying the mesothoracic (T2) segment (Wu et al. 2001).
The expression of homeotic genes is a dynamic process. The Antennapedia gene, for instance, although initially expressed in presumptive parasegment 4, soon appears in parasegment 5. As the germ band expands, Antp expression is seen in the presumptive ventral nerve cord as far posterior as parasegment 12. During further development, the domain of Antp expression contracts again, and Antp transcripts are localized strongly to parasegments 4 and 5. Like that of other homeotic genes, Antp expression is negatively regulated by all the homeotic gene products expressed posterior to it (Levine and Harding 1989; González-Reyes and Morata 1990). In other words, each of the bithorax complex genes represses the expression of Antp. If the Ultrabithorax gene is deleted, Antp activity extends through the region that would normally have expressed Ubx and stops where the Abd region begins. (This allows the third thoracic segment to form wings like the second thoracic segment, as seen in textbook Figure 9.25.) If the entire bithorax complex is deleted, Antp expression extends throughout the abdomen. (Such a larva does not survive, but the cuticle pattern throughout the abdomen is that of the second thoracic segment.)
As we have seen, the proteins encoded by the gap and pair-rule genes are transient; however, in order for differentiation to occur, the identities of the segments must be stabilized. So, once the transcription patterns of the homeotic genes have become stabilized, they are “locked” into place by alteration of the chromatin conformation in these genes. The repression of homeotic genes is maintained by the Polycomb family of proteins, while the active chromatin conformation appears to be maintained by the Trithorax proteins (Ingham and Whittle 1980; McKeon and Brock 1991; Simon et al. 1992).
Homeotic genes don’t do the work alone. In fact, they appear to regulate the action from up in the “executive suite,” while the actual business of making an organ is done by other genes on the “factory floor.” In this scenario, the homeotic genes work by activating or repressing a group of “realisator genes” that are the targets of the homeotic gene proteins and that function to form the specified tissue or organ primordia (Garcia-Bellido 1975).
Such a pathway for one simple structure—the posterior spiracle—is well on its way to being elucidated. This organ is a simple tube connecting to the trachea and a protuberance called the Filzkörper. The posterior spiracle is made in the eighth abdominal segment and is under the control of the Hox gene AbdB. Lovegrove and colleagues (2006) have found that the AbdB protein controls four genes that are necessary for posterior spiracle formation: Spalt (Sal), Cut (Ct), Empty spiracles (Ems), and Unpaired (Upd). The first three encode transcription factors; the fourth encodes a paracrine factor. None of them are transcribed without AbdB. Moreover, if these genes are independently activated in the absence of AbdB, a posterior spiracle will form.
Controlled by AbdB, these four regulator genes in turn control the expression of the realisator genes that control cell structure and function. Spalt and Cut encode proteins that activate the cadherin genes necessary for cell adhesion and the invagination of the spiracle. Empty spiracles and Unpaired encode proteins that control the small G proteins (such as Gef64C) that organize the actin cytoskeleton and the cell polarizing proteins that control the elongation of the spiracle (Figure A).
Casares, F. and E. Sánchez-Herrero. 1995. Regulation of the infraabdominal regions of the bithorax complex of Drosophila by gap genes. Development 121: 1855–1866.
García-Bellido, A. 1975. Genetic control of wing disc development in Drosophila. CIBA Found. Symp. 29: 161–182.
González-Reyes, A. and G. Morata. 1990. The developmental effect of overexpressing a Ubx product in Drosophila embryos is dependent on its interactions with other homeotic products. Cell 61: 515–522.
Ingham, P. W. and R. Whittle. 1980. Trithorax: A new homeotic mutation of Drosophila causing transformations of abdominal and thoracic imaginal segments. I. Putative role during embryogenesis. Mol. Gen. Genet. 179: 607–614.
Levine, M. S. and K. W. Harding. 1989. Drosophila: The zygotic contribution. In D. M. Glover and B. D. Hames (eds.), Genes and Embryos. IRL, New York, pp. 39–94.
Lohmann, I. 2006.Hox genes: Realising the importance of realisators.Curr Biol. 16: R988–R989.
Lovegrove, B. and 7 others. 2006. Coordinated control of cell adhesion, polarity, and cytoskeleton underlies Hox-induced organogenesis in Drosophila. Curr. Biol. 16(22): 2206–2216.
McKeon, J. and H. W. Brock. 1991. Interactions of the Polycomb group of genes with homeotic loci of Drosophila. Wilhelm Roux Arch. Dev. Biol. 199: 387–396.
Simon, J., A. Chiang and W. Bender. 1992. Ten different Polycomb genes are required for spatial control of the abdA and AbdB homeotic products. Development 114: 493–505.
Wu, L. H. and J. A. Lengyel. 1998. Role of caudal in hindgut specification and gastrulation suggests homology between Drosophila amnioproctodeal invagination and vertebrate blastopore. Development 125: 2433–2442.