The birth of ant genomics.

T oday science is in the age of biology and biology is in the age of genomics. Sequencing the entire genome of an organism, an enterprise that could not have been imagined barely 50 y ago, is being thought of as the first step toward a complete understanding of its biology. If I had been asked to recommend just two families of living organisms from which to pick the first two species for whole-genome sequencing, I would surely have suggested Hominidae (with ourselves) and Formicidae (with all ants). My choice of the ant family is easy to justify. The family Formicidae consists of approximately 14,000 species of ants, all of which exhibit advanced and sophisticated social life, not unlike our own in many respects and perhaps surpassing us in some ways. The ants live in colonies headed by one or a small number of fertile queens and large number (which can sometimes run into millions) of sterile workers, and display sophisticated division of labor and most impressive levels of communication and coordination among colony members (Fig 1). One of the many features of great interest is the vastly different phenotypes and lifespans of queens and workers, despite developing from the same genome. Ants have achieved spectacular ecological success and dominance, accounting for more than a third of all insect biomass and, along with termites, for more than 25% of all animal biomass in some tropical forests (1). Whole-genome sequencing was, until recently, a relatively expensive and timeconsuming affair, so many organisms had to wait in a queue for their turn. We humans had to wait until the year 2001 and the ants have had to wait until hundreds of other animals, plants, and microbes had been sequenced. However, fortunately, the wait is now over. The genomes of the invasive Argentine ant Linepithema humile (2), the red harvester ant Pogonomyrmex barbatus (3), and the fire ant Solenopsis invicta (4) are being simultaneously unveiled in PNAS. The genome sequences of two other ants, Camponotus floridanus and Harpegnathos saltator (5), were also published recently. In addition the genome sequence of the leaf-cutter ant Atta cephalotes will soon be published in another journal (6), taking the total to six. Thus, we are truly witnessing the birth of ant genomics, indeed, of comparative ant genomics. Actually, we now find ourselves in an even better situation because the honeybee genome has already been sequenced (7), taking the number of eusocial species to seven, and because three species of the parasitic wasp Nasonia have also been sequenced (8), we have 10 hymenopteran genome sequences for comparative study. The Argentine ant L. humile is remarkable in many ways, especially because of its successful invasion from South America to every Mediterranean-type climate, including most of Europe and North America (9), and even more so because it appears to form mega-supercolonies ranging over hundreds of thousands of kilometers (10). The harvester ant P. barbatus is a rather famous granivore, being a favorite model to study variations in social organization (11), mechanisms of caste determination (12), and the organization of labor (13). The fire ant S. invicta, introduced from South America, has spread across the United States and has become one of the most serious pests threatening agriculture and human life and defying most extermination efforts (14). C. floridanus, found in the southeastern United States, is perhaps the most nondescript of the lot but it is good to have to compare with the others, especially because of its well organized, monogynous colonies with only two worker castes (15). H. saltator is rather special, a jumping ant from India whose workers can copulate with males from their own colonies and contribute to egg-laying, alongside the queens, as gamergates (i.e., married workers) (16). Finally, A. cephalotes is another “star” as ants go, being an extremely serious pest of agriculture in the Neotropics, a status achieved as a result of its habit of harvesting leaves and using them to cultivate fungal gardens—a 50-millionyear-old form of ant agriculture (17). With the publication of these six ant genomes, we have thus obtained a total of approximately 1.5 billion base pairs’ worth of new data. What can we do with this massive amount of data? Are the data worth the time, effort, and money that went into their collection? The answers to these questions should not be taken as obviously being in the affirmative, but should be examined very carefully. In addition to the actual genome sequences, most of these articles provide basic information such as genome size, expected number of genes, transcriptome sequences, and information about duplicated genes, missing genes, and transposable elements. Each article makes preliminary comparisons with some of the other related genomes to point out similarities and differences. Each article also lists several pleasing results. For example, the Argentine ant genome has expansions and/or abundance of gustatory, odorant receptor, cytochrome P450, royal jelly protein, and methylation-related genes and a paucity of immune genes. The harvester ant genome shows expansion of chemoreception and cytochrome P450 genes. The fire ant Fig. 1. (A) A portion of the nest of the invasive Argentine ant L. humile showing workers tending brood (photo: Marc Dantzker). (B) A small portion of a laboratory colony of a red imported fire ant S. invicta (photo: Yannick Wurm). (C) An example of the fungus garden of the leaf-cutter ant A. cephalotes (photo: Jarrod Scott) with a single ant carrying a leaf also shown (Inset; photo: Alex Wild).