Homology Weekly: Mandible Adductor Apodemes

Thursday, September 24th, 2009 | Ants, Comparative Anatomy, Homology Weekly, Morphology

The unusual mandible closer apodeme (left one in the pair) of species in the Odontomachini genus group. Disected out and cleared from all muscles (Scanning Electron Micrograph, Roberto Keller/AMNH)

The unusual hook-shaped mandible closer apodeme (left one in the pair) of species in the Odontomachini genus group (Anochetus emarginatus pictured here). Piece dissected out and cleared from all muscles (Scanning Electron Micrograph, Roberto Keller/AMNH)

Last August, before taking a break from blogging, I posted an impossible-to-answer trivia. It consisted of the image above depicting an unidentified mysterious skeletal piece (sclerite) in the shape of a hook, together with two key pieces of information: a) it is entirely internal; b) it comes in pairs.

A regular visitor to this blog, Marc “Teleutotje” Van der Stappen quickly asked if it was part of the sting apparatus. This was a perfectly good guess, since it satisfies both a) and b), but the mysterious sclerite occurs on the opposite end of the ant. A subsequent comment by C.M. Wilson guessed the tentorium. It was also a good guess. We are now correctly assuming it is something inside the head, but I will argue that, since the tentorial arms are invaginations of the outer cuticle, strictly speaking they are not entirely internal.

The sclerite in question is nothing but the structure that serves as a link between the insect mandible and some of the muscles moving it. It is a specific type of apodeme: a term used to describe any internal piece of the arthropod skeleton that gives support to muscles¹. The tricky part of the trivia was that, while these apodemes exist in all ants (in all insects with mandibles in fact), they are extremely modified into strong hooks only in a small clade consisting of the ponerine trap-jaw genera Anochetus and Odontomachus (a group sometimes referred as the subtribe Odontomachini, but not currently recognized).

Ants have the basic type of mandible articulation found in most insects and known as dicondylic: each mandible interacts with the head capsule through a couple of hinges (called condyles in 1337 anatomical speak), and has two sets of muscles connected to it that pull on opposite sides– one for opening the mandible (abductor) and one for closing it (adductor). Now, the muscles don’t attach directly to the mandible but do so by way of a membranous ligament that, in the case of the mandible closer, connects in turn to an apodeme that receives all the muscle packs, hence the name mandible closer apodeme (in German, of course, all of the above information is summarized into a single, long word).

The left column shows the shape and location of the mandible closer apodemes in <i>Myrmecia</i> and <i>Odontomachus chelifer</i>. Right column: mandible closer apodemes painted (in orange) as they would appear internally on the head of an Odontomachus worker ant. (Drawings from Paul and Gronenberg 1999; SEM image by Roberto Keller/American Museum of Natural History)

The left column shows the shape and location of the mandible closer apodemes (solid black) inside the head in Myrmecia sp. and Odontomachus chelifer. Right column: mandible closer apodemes painted (in orange) as they would appear internally on the head of an Odontomachus bauri worker ant. b, apodeme base; c, apodeme collateral branches; l, ligament; SOG, suboesophageal ganglion (Drawings from Paul and Gronenberg, 1999; SEM image by Roberto Keller/American Museum of Natural History)

In most ants the mandible closer apodemes consist of a highly sclerotized (that is, hardened) basal body (b) that branches into three long extensions (c) running towards the back of the head, as exemplified with Myrmecia sp. in the illustration above². Numerous muscle packages run from the inside of the head capsule to these collateral branches, so when the muscles contract all the force generated concentrates on the massive sclerotized base that pulls the mandible shut via the flexible ligament (l).

The mandible closer apodeme in members of the ponerine trap-jaw ant clade also has a stout base and three collateral branches. Here, however, the lateral branch is modified into a massive (really massive) and highly sclerotized hook. This is what you see in the image opening this post and in the illustration immediately above. Also above, to the right is an SEM of the head of a Odontomachus species where I painted in orange how these apodemes would look internally in place, so you can appreciate the size of these structures. They are also highly pigmented due to sclerotization: when you prepare workers of these ants for regular skeletal observation by clearing the muscles and other soft tissues with a strong base (KOH), you can see the couple of large pigmented spirals through the semitransparent cuticle of the head.

The hook-shaped branches provide extra attachment surface and support to the powerful adductor muscles, that in the case of these ants fill about two thirds of the entire head volume³. The apodeme in ants of this group also differs from the basic type in that it has a ventral projection that receives a specialized muscle called “trigger muscle”⁴. This muscle, one on each side of the head, is responsible for causing the subtle deformation of the frontal part of the ant’s head that releases the mandibles that were locked in the catapult mechanism to either strike prey or propel the ant into the air.

You can read all the details of this mechanism in the papers cited below.

Notes and references

The tentorium is also a type of apodeme, hence the guess by the second commenter gets extra points ↩
Taken from the wonderful paper: Paul, J., and W. Gronenberg. 1999. Optimizing Force and Velocity: Mandible Muscle Fibre Attachments in ants. J. Exp. Biol. 202:797-808. ↩
Gronenberg, W., and B. Ehmer. 1996. The mandible mechanism of the ant genus Anochetus (Hymenoptera, Formicidae) and the possible evolution of trap-jaws. Zoology 99:153-162. ↩
Gronenberg, W. 1995. The fast mandible strike in the trap-jaw ant Odontomachus. I. Temporal properties and morphological characteristics. J. Comp. Physiol. A. 176:391-398. ↩

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Tags: Anochetus, Apodeme, Mandibles, Odontomachus, Trap-jaw ants

7 Comments to Homology Weekly: Mandible Adductor Apodemes

Marc "Teleutotje" Van der Stappen
September 24, 2009

If you want to know more about the mechanisms that rule the workings of the mouthparts you can read this:

”The mouthparts of ants”, Thesis of Jürgen Paul, Würzburg, Univ., Diss., 2001.

Roberto Keller
September 24, 2009

This is really great. Thank you Marc!

Pete Yeeles
September 27, 2009

Enjoyable and interesting Homology Weekly, as usual. Thanks!

James C. Trager
October 5, 2009

I second Pete’s comment. It is good to be learning new things about ant morphology in such an accessible manner (after 40 years of studying these critters).

Santiago Meneses
October 22, 2009

This is really interesting. I wonder how these structures are arranged in Acanthognathus.

Roberto Keller
October 23, 2009

The mechanism in Acanthognathus is described in:
Gronenberg, W., Brandao, C. R. F., Dietz, B. H. and Just, S. (1998). Trap-jaws revisited: the mandible mechanism of the ant Acanthognathus. Physiol. Ent. 23, 227–240. doi: 10.1046/j.1365-3032.1998.233081.x (subscription required).

Basically, Acanthognathus ants also have a strong lateral branch that allows the closing movement, but the branch doesn’t bent anteriorly into a hook as it does in the ponerine trap-jaw ants.

Santiago Meneses
October 23, 2009

Thank you very much Roberto! Dacetine ants are awesome.
What are those black branches that run anteriorly from the posterior margin of the head in the drawing of Odontomachus chelifer? Are they a different apodeme?

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