Introduction
Over 600 Middle Eocene bat specimens have been excavated from the Messel pit
(Grube Messel, near Darmstadt, Germany), and seven species have been described
thus far. Many of the fossils are preserved as complete skeletons, often with
soft body outlines and gut contents. Six of the bat species represent three
extinct families, whereas Tachypteron franzeni can be assigned
to the extant family Emballonuridae (Storch et al., 2002).
T. franzeni is known only from two specimens; however,
these are extraordinarily well preserved, including the shoulder joints and
inner ears, so this had already been recognized in the original description of
T. franzeni, and these close resemblances to extant
emballonurids led to the conclusion that T. franzeni had
already evolved similar bioacoustic specializations and a similar flight style
to modern taxa.
The shoulder joints of bats are sophisticated structures showing remarkable
morphological variation. Miller's (1907) investigations on the differentiations
of the shoulder within the Microchiroptera were continued by the studies of
other authors (Vaughan, 1970; Strickler, 1978; Hermanson and Altenbach,
1983).
Three different types of shoulder joint can be distinguished within the
Chiroptera: the primitive morphology of the shoulder joint with a globular
humeral head and corresponding glenoid cavity, as seen in Megachiroptera and
Rhinopomatidae; a derived shoulder joint with an oblong humeral head and a
single trough-like articular surface on the scapula, found in members of the
superfamilies Emballonuroidea, Rhinolophoidea and Noctilionoidea; a derived
shoulder joint with a secondary articulation between the tuberculum majus and a
secondary articular facet on the dorsal side of the scapula, as seen in the
remaining families. Their distribution within the order gives evidence of
parallel evolution of the derived types (Schlosser-Sturm and Schliemann, 1995).
The morphological modifications of the derived joints are interpreted as a
functional response to a biomechanical demand connected with flight (Norberg,
2002), i.e., to limit pronation of the humerus during the downstroke of the wing
beat cycle, realized in two different mechanical ways (Schlosser-Sturm, 1982;
Altenbach, 1987; Schliemann and Schlosser-Sturm, 1999). Because movement
restriction was described for the primitive type as well (Bergemann, 2003),
functional interpretations are still a matter of controversy.