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Clearly describe the hypothesis or question addressed in the scientific article in your own words. Summarize the methods, results, and interpretation of those results of the authors of the scientific article.State the significance of the discovery or scientific study – More than what and when, why is the result of the scientific study important in understanding dinosaurs and Mesozoic history?
Journal of Zoology. Print ISSN 0952-8369
Necks for sex: sexual selection as an explanation for
sauropod dinosaur neck elongation
P. Senter
Department of Math and Science, Lamar State College at Orange, Orange, TX, USA
Keywords
Sauropoda; Saurischia; Dinosauria; neck;
sexual selection.
Correspondence
Phil Senter, Department of Math and
Science, Lamar State College at Orange,
410 Front Street, Orange, TX 76630, USA.
Email: phil.senter@lsco.edu
Received 15 December 2005, accepted
3 May 2006
doi:10.1111/j.1469-7998.2006.00197.x
Abstract
The immensely long neck of a sauropod is one of the most familiar and striking of
anatomical specializations among dinosaurs. Here, I use recently collected
neontological and paleontological information to test the predictions of two
competing hypotheses proposed to explain the significance of the long neck.
According to the traditional hypothesis, neck elongation in sauropods increased
feeding height, thereby reducing competition with contemporaries for food.
According to the other hypothesis, which is advanced for the first time here, neck
elongation in sauropods was driven by sexual selection. Available data match the
predictions of the sexual selection hypothesis and contradict the predictions of the
feeding competition hypothesis. It is therefore more plausible that increases in
sauropod neck lengths were driven by sexual selection than by competition for
foliage.
Introduction
Sauropod dinosaurs, the largest land animals in geological
history, are well known not only for their great size but also
for their often extremely long necks. Previous authors have
noted that differing neck lengths in different sauropod species
resulted in different feeding heights for different species,
assuming that some species browsed with vertical necks
(Bakker, 1978; Barrett & Upchurch, 1995) or in a tripodal
posture (rearing up on the hindlimbs, using the tail as a prop;
Riggs, 1904; Bakker, 1978; Barrett & Upchurch, 1995). It
could therefore be argued that interspecific competition for
foliage provided the selective pressure that drove neck elongation in sauropods because an increase in neck length in a given
sauropod taxon would result in a different feeding height,
providing a selective advantage by reducing competition for
food. Until now, no alternative hypothesis has been presented
to challenge the hypothesis – hereafter called Hypothesis A –
that interspecific competition for foliage provided the selective pressure that drove neck elongation in sauropods.
In the 19th century, Charles Darwin presented a similar
hypothesis regarding giraffes, postulating that interspecific
competition for foliage provided the selective pressure
that drove neck elongation in the giraffe (Darwin, 1871).
However, for the giraffe, this hypothesis has recently fallen
out of favor because of substantial evidence to the contrary
(Simmons & Scheepers, 1996). Several lines of evidence
falsify the interspecific competition hypothesis and instead
support a hypothesis that sexual selection drove the increase
in neck size in the giraffe (Simmons & Scheepers, 1996).
Given this, it is reasonable to formulate an alternate
hypothesis – hereafter called Hypothesis B – that sexual
selection pressure drove neck elongation in sauropods.
Previous authors have identified six major indicators that
a character has arisen via sexual selection:
(1) The character is more exaggerated in one sex than in the
other (Darwin, 1871; Simmons & Scheepers, 1996).
(2) The character is used in dominance contests or courtship displays (Zahavi, 1975; Grafen, 1990; Simmons &
Scheepers, 1996).
(3) The character provides no immediate survival benefit –
in contrast to characters driven by other kinds of selection,
which are fixed in a population because of some survival
benefit (Darwin, 1871; Simmons & Scheepers, 1996).
(4) The character incurs a survival cost – in contrast to
characters driven by other kinds of selection, which are fixed
in a population only if they incur minimal or no survival cost
(Zahavi, 1975; Grafen, 1990).
(5) The character exhibits positive allometry during individual ontogeny (Clutton-Brock, Albon & Harvey, 1980;
Petrie, 1988, 1992).
(6) As body size increases through phylogenetic history, the
size increase in the body part in question is not correlated
with size increases in other body parts and therefore cannot
be explained by allometric scaling alone (Simmons &
Scheepers, 1996).
Hypotheses and predictions
From the above, the following list of predictions can be
generated for Hypotheses A and B for sauropod neck
elongation:
Journal of Zoology 271 (2007) 45–53 c 2006 The Author. Journal compilation c 2006 The Zoological Society of London
45
Sexual selection on sauropod necks
P. Senter
Prediction 1: Hypothesis A predicts that sauropod neck
dimensions are not greater in one sex than in the other,
whereas Hypothesis B predicts that they are.
Prediction 2: Hypothesis A predicts that sauropod necks
are not used in dominance contests and courtship displays,
whereas Hypothesis B predicts that they are.
Prediction 3: Hypothesis A predicts that interspecific
differences in sauropod neck lengths provided vertical
stratification of foraging among sauropod species and
between sauropods and other taxa, whereas Hypothesis B
predicts that interspecific differences in sauropod neck
lengths did not have that effect.
Prediction 4: Hypothesis A predicts that sauropod neck
elongation did not incur a survival cost, whereas Hypothesis
B predicts that it did.
Prediction 5: Hypothesis A makes no particular prediction regarding ontogenetic allometry, whereas Hypothesis B
predicts that sauropod neck dimensions exhibited positive
allometry through ontogeny.
Prediction 6: Both hypotheses predict that neck length will
increase across sauropod phylogenetic history. However,
Hypothesis A predicts that, because selection pressure is
toward increasing the vertical reach of the head, the limbs –
the lengths of which also influence head height – increase in
relative length along with the neck across phylogeny,
whereas Hypothesis B predicts that increases in neck length
across phylogeny are unrelated to limb length.
When making such predictions about extinct taxa, it is a
good rule of thumb to be able to point to similar processes in
extant taxa. Therefore, each of the above predictions carries
with it the corollary that the phenomenon in question can be
observed in some extant, long-necked taxa.
Predictions versus fossil evidence
Prediction 1 cannot be tested with available sauropod
material. For any given sauropod species, too few specimens
that have enough overlapping cervical and postcervical
skeletal elements to run reliable statistical tests of bimodal
variation in cervical dimensions relative to postcervical
dimensions have been collected and prepared. Sexual
dimorphism in neck dimensions does occur in giraffes
(Simmons & Scheepers, 1996); therefore, there is precedent
for this prediction of Hypothesis B among extant longnecked animals. It is tempting to cite the contemporaneous
Jurassic, North American sauropods Diplocodus and
Barosaurus as an example of cervical dimorphism in sauropods. Their appendicular skeletons are virtually indistinguishable; the major difference between the two taxa is that
the cervical vertebrae of Barosaurus are relatively 130–150%
the lengths of those of Diplodocus (McIntosh, 1990, 2005).
From this, one might reasonably infer that ‘Barosaurus’ is a
sexual dimorph of Diplodocus, with relative neck length as
the main difference between the two morphs. However, a
number of other minor differences between the axial skeletons of Diplodocus and Barosaurus exist (McIntosh, 2005),
and it would be premature to synonymize the two taxa
46
without a rigorous analysis with a large sample size. Such an
analysis, which is beyond the scope of this paper, would be
needed to test whether the postcervical differences between
Barosaurus and Diplodocus can be attributed to individual
variation, interspecific variation or to consequences of
‘Barosaurus’ being the sex with the longer neck.
Prediction 2 also cannot be tested for sauropods because
the behaviour of extinct animals cannot be observed.
Among extant animals, male giraffes use the neck in
dominance contests involving combat with much direct
contact, often delivering blows to each other with the head
(Estes, 1991). Sexual selection pressure has therefore resulted in cranial dimorphism such that better protection
against impact is present in male giraffe skulls than in those
of females (Simmons & Scheepers, 1996). No known sauropod skull exhibits cranial thickenings suggestive of selection pressure for withstanding forceful impact. However,
sexual selection on neck length in sauropods need not have
involved direct combat. Dominance in male elephants is
based on height, and is determined as soon as two individuals can tell which stands taller (Estes, 1991). There is
therefore precedent among extant animals for determination
of a reproductively relevant parameter (dominance) by
simple display of a bodily dimension – in the case of
sauropods, neck length.
Unlike the case for predictions 1 and 2, evidence exists to
test predictions 3–6 in sauropods in addition to citing
precedent among extant long-necked animals. As for prediction 3, reconstructions of brachiosaurid and camarasaurid sauropods feeding with necks held vertically and
diplodocids feeding tripodally are consistent with this prediction of Hypothesis A, because these postures result in
marked differences in feeding heights between contemporaneous sauropod species (Bakker, 1978). However, several
lines of evidence falsify this prediction 3 for Hypothesis A
and support Hypothesis B. First, vertical stratification due
to neck length would have existed only for adult sauropods.
The vertical foraging ranges of juveniles of all species overlapped each other, and the vertical foraging ranges of
juveniles of longer-necked sauropod species overlapped
those of the adults of shorter-necked sauropod species.
Second, evidence from zygopophyseal articulations (Martin, 1987; Stevens & Parrish, 1999, 2005), beam mechanics
(Martin, Martin-Rolland & Frey, 1998), and the morphology of cervical ribs, neural arches (Martin et al., 1998) and
centra (Martin, 1987; Stevens & Parrish, 2005) indicates that
sauropod necks were habitually held subhorizontally, even
in taxa that are typically portrayed with vertically oriented
necks (Bakker, 1978; Paul, 1987; Paul & Leahy, 1992;
Berman & Rothschild, 2005). Keystone-shaped cervical
centra (‘vertebral bodies’ in mammalian nomenclature) at
the bases of their necks allow giraffes, camelids and birds to
hold their necks vertically, but sauropod cervical centra lack
such shapes, even among sauropods that are typically
portrayed with vertical necks (Stevens & Parrish, 2005).
Given this, the internal architecture of cervical centra in
some sauropod species that indicates a reduced need to
counteract tensile stress – which has been interpreted as
Journal of Zoology 271 (2007) 45–53 c 2006 The Author. Journal compilation c 2006 The Zoological Society of London
P. Senter
Sexual selection on sauropod necks
evidence for vertical neck posture (Berman & Rothschild,
2005) – is better interpreted as a consequence of the reduction of tensile stress that is brought about by increased
ventral bracing of cervical vertebrae by elongation of and
overlap between cervical ribs in those sauropod taxa
(Martin et al., 1998). The ability to lift the head above the
level of the back was limited or absent in sauropods (Martin,
1987; Martin et al., 1998; Stevens & Parrish, 1999, 2005),
and the absence of stress fractures in diplodocid dorsal
vertebrae and metacarpals demonstrates that these animals
did not stand tripodally (Rothschild & Molnar, 2005).
Sauropods therefore fed at relatively low levels, and many
may have grazed (Stevens & Parrish, 1999, 2005). Obviously, if a neck is held horizontally, its length does not
influence vertical reach. On the other hand, limb length does
influence vertical reach, as it influences the height of the
mouth on the head at the end of a horizontally held neck.
Therefore, if selection pressure toward vertical stratification
of foraging were present in sauropods, it would have acted
on limb length rather than neck length. The prediction of
Hypothesis A that sauropod neck elongation was related to
vertical stratification of foraging is therefore not supported
by the data. The data instead support the prediction of
Hypothesis B that sauropod vertical feeding envelopes overlapped those of their shorter-necked and smaller contemporaries. The same is true for extant giraffes, which tend to
feed with the neck horizontal (Simmons & Scheepers, 1996),
and camelids, which graze. Neck elongation in both these
extant cases is unrelated to typical foraging height, except
insofar as the long limbs of camelids require their necks to
be equally long so that their mouths can reach the ground.
As for prediction 4, the metabolic expense needed to grow
and maintain such a huge neck must be considered a cost. A
more dramatic cost relates to sauropod heights. In a
sauropod, acetabular height is a close match to the height
of the base of the neck, and in a large theropod, acetabular
height is a close match to the height of the mouth (Fig. 1).
The acetabular heights of large theropods often resembled
the acetabular heights of contemporaneous sauropods (the
fauna of the Morrison Formation, in which most large
theropods were dwarfed by most contemporaneous sauropods, is an exception to the rule; Fig. 2). Therefore, the
horizontally held necks of all but the largest sauropods were
within biting range of large carnivores, at least some of
which are known to have preyed upon sauropods (Bakker &
Bir, 2004). Longer necks at that convenient height would
have provided longer targets, making it easier for a carnivore to find a place to bite than would have been the case
with shorter-necked prey. This is especially true of grazing
(a)
(b)
sauropods, in which the height of much of the neck would
have been well below the acetabulum, regardless of acetabular height. There is no reason not to suppose that, as with
any other vertebrate, a single bite that severed carotid
arteries, jugular veins or vagus nerves would have been
sufficient to dispatch a sauropod. The evolution of more
neck, and hence more vulnerability to a fatal bite, therefore
incurred a survival cost for all but the longest-limbed sauropods. Selection pressure to increase foraging height without
such a survival cost would have resulted in elongation of the
limbs instead of the neck, and, incidentally, may have driven
the evolution of proportionately longer limbs in sauropod
colossi such as Brachiosaurus. Prediction 4 of Hypothesis B is
therefore supported, whereas prediction 4 of Hypothesis A is
not. Male giraffes are killed by lions more often than female
giraffes are (Simmons & Scheepers, 1996). The same may
have been true for whichever sauropod sex exhibited longer
necks, because longer necks would have been larger targets
at bite height, and hence more vulnerable to attack.
The fossil record has not yet yielded intact cervical and
postcervical skeletons for a wide enough range of ontogenetic stages across enough taxa to test for positive allometry
(prediction 5) of the neck in sauropods generally. However,
enough data are available for the genus Camarasaurus to
show that the neck increased in relative length through
ontogeny in this taxon (Ikejiri, Tidwell & Trexler, 2005).
This is consistent with prediction 5 of Hypothesis B. Neck
length exhibits positive allometry in the giraffe also
(Simmons & Scheepers, 1996).
To test prediction 6, I ran regressions of natural logtransformed values of humerus+radius versus neck length
and femur+tibia versus neck length (Table 1) for a taxonomically broad spectrum of sauropods (n = 11; one specimen
apiece of the sauropod species Shunosaurus lii, Euhelopus
zdanskii, Mamenchisaurus hochuanensis, Mamenchisaurus
youngi, Omeisaurus junghsiensis, Amargasaurus cazaui,
Dicraeosaurus hansemanni, Diplodocus carnegii, Apatosaurus
louisae, Brachiosaurus brancai and Jobaria tiguidensis;
E. zdanskii and M. hochuanensis were omitted from the
forelimb vs. neck sample, because their forelimbs are unknown). For forelimb versus neck, R2 =0.3484 (P40.05).
For hindlimb versus neck, R2 = 0.0402 (P40.05). Limb
lengths are therefore not correlated with neck lengths in
sauropods. Prediction 6 of Hypothesis B is therefore supported, whereas prediction 6 of Hypothesis A is not. Within
Giraffidae also, limb and neck lengths are not correlated; the
increase in neck length in Giraffa is disproportionate to the
increase in length of its limbs, as compared with other
giraffids (Simmons & Scheepers, 1996).
Figure 1 Skeletal reconstructions of a sauropod
and a theropod (not to scale), showing that
acetabular height is a good proxy for the height
of the base of the neck in a sauropod and for
the height of the mouth in a large theropod.
(a) The sauropod Apatosaurus (from McIntosh,
Brett-Surman & Farlow, 1997). (b) The theropod Allosaurus (from Paul, 1987).
Journal of Zoology 271 (2007) 45–53 c 2006 The Author. Journal compilation c 2006 The Zoological Society of London
47
Sexual selection on sauropod necks
P. Senter
(a)
(b)
(c)
2500
3000
4000
2000
2500
3500
3000
2000
1500
2500
2000
1500
1000
1500
1000
1000
500
500
0
0
P
V
Pf
Ba
Ae
500
0
M
Mc
O
Mh
S
Y
Ys
B
T
J
D
Ds
A
Ti
(d)
4000
3500
3000
2500
2000
1500
1000
500
0
Aj
Al
H
Sh
Dl
E
Bl
Dc
C
Cs
Se
Hp
Er
Sm
Af
Tt
(e)
(f)
(g)
(h)
(i)
3500
5000
4500
4000
3500
3000
2500
2000
1500
1000
500
0
3000
4500
4000
3500
3000
2500
2000
1500
1000
500
0
3500
3000
2500
2000
1500
1000
500
0
Ci
Tc
2500
2000
1500
1000
500
Ah
Ad
G
0
Cw
Vd
Aa
Cd
3000
2500
2000
1500
1000
500
Ps
Ab
Bi
Csa
0
As
Tr
Figure 2 Acetabular heights (lengths in mm of femur+tibia+metatarsus) of sauropods (white bars) and contemporaneous large theropods (black
bars). Note that in all faunae shown here, at least some sauropod necks are within biting range of the largest contemporaneous theropods. See
Table 1 for data sources and bases for estimation of lengths of missing elements. (a) Cañodon Asfalto Formation fauna (Middle Jurassic).
(b) Shangshaximiao Formation fauna (Upper Jurassic). (c) Tendaguru Formation fauna (Upper Jurassic). (d) Morrison Formation fauna (Upper
Jurassic). (e) Cerro Barcino Formation fauna (Lower Cretaceous). (f) Rı́o Limay Formation (Lower–Upper Cretaceous). (g) Cedar Mountain
Formation (Lower Cretaceous). (h) Baharija Formation (Upper Cretaceous). (i) North Horn Formation (Upper Cretaceous). A, Allosaurus
tendagurensis; Aa, Acrocanthosaurus atokensis; Ab, Aegyptosaurus baharijensis; Ae, Apatosaurus excelsus; Aj, Apatosaurus ajax;
Ad, Andesaurus delgadoi; Af, Allosaurus fragilis; Ah, Argentinosaurus huinculensis; Al, Apatosaurus louisae; As, Alamosaurus sanjuanensis;
B, Brachiosaurus brancai; Ba, Brachiosaurus altithorax; Bi, Bahariasaurus ingens; Bl, Barosaurus lentus; C, Camarasaurus grandis; Ci, Chubutisaurus
insignis; Cd, Ceratosaurus dentisulcatus; Cs, Camarasaurus supremus; Csa, Carcharodontosaurus saharicus; Cw, Cedarosaurus weiskopfae;
D, Dicraeosaurus hansemanni; Dc, Diplodocus carnegii; Dl, Diplodocus longus; Ds, Dicraeosaurus sattleri; E, Eobrontosaurus yahnapin;
Er, Edmarka rex; G, Giganotosaurus carolinii; H, Haplocanthosaurus delfsi; Hp, Haplocanthosaurus priscus; J, Janenschia robusta;
M, Mamenchisaurus jingyanensis; Mc, Mamenchisaurus constructus; Mh, Mamenchisaurus hochuanensis; O, Omeisaurus maoianus; P, Patagosaurus fariasi; Pf, Piatnitzkysaurus floresi; Ps, Paralititan stromeri; S, Sinraptor hepingensis; Se, Suuwassea emilieae; Sh, Seismosaurus hallorum;
Sm, Saurophaganax maximus; T, Tornieria africana; Tc, Tyrannotitan chubutensis; Ti, Theropoda indet.; Tr, Tyrannosaurus rex; Tt, Torvosaurus tanneri;
V, Volkheimeria chubutensis; Vd, Venenosaurus dicrocei; Y, Yangchuanosaurus magnus; Ys, Yangchuanosaurus shangyuensis.
Conclusion
Discussion
Available evidence is consistent with predictions 3–6 of
Hypothesis B but not with their counterparts for Hypothesis
A. Hypothesis A is therefore falsified, whereas Hypothesis B
is supported by the evidence. It is therefore more likely that
sauropod neck elongation resulted from sexual selection
than from interspecific competition for foliage.
It is difficult to think of the neck of a sauropod as a sexual
signaling device, because it has been interpreted for decades
as an adaptation for high browsing. However, the horizontal posture of the sauropod neck belies the old interpretation. Bizarre and counterintuitive as it may seem, the sexual
selection hypothesis fits the data better than the foliage
48
Journal of Zoology 271 (2007) 45–53 c 2006 The Author. Journal compilation c 2006 The Zoological Society of London
P. Senter
Sexual selection on sauropod necks
Table 1 Lengths (mm) of sauropod and theropod skeletal segments used in regressions and Fig. 2
Taxon
Humerus
Radius
Femur
470
825ae
1240
450u
701dl
–
1040
–
545
553om
480
1050
1830
2090
1220
1470
955
1490
860
705
1508om
1200
640
1252d
1150
780
1006
602
930
880
665
855f
682
–
–
–
–
–
–
–
–
–
–
–
–
1290
1571o
1883o
1836al
1830
1730
2866o
1440
2030
1485
1465
1395
890
913o
1094o
1130
1148ae
1065
1550
1064
1117
930
901
884
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
1680
990
1570d
1598c
1745
1275
1260
1150m
1417m
1120
1310
2358o
1320
1588d
1178d
1350
1127o
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
Sauropoda: taxa used in limb neck regressions
Amargasaurus cazaui
720
Apatosaurus louisae
1138ae
Brachiosaurus brancai
2130
Dicraeosaurus hansemanni
750
Diplodocus carnegii
916dl
Euhelopus zdanskii
–
Jobaria tiguidensis
1360
Mamenchisaurus hochuanensis
–
Mamenchisaurus youngi
830
Omeisaurus junghsiensis
845
Shunosaurus lii
670
Sauropoda: other
Aegyptosaurus baharijensis
–
Alamosaurus sanjuanensis
–
Andesaurus delgadoi
–
Apatosaurus ajax
–
Apatosaurus excelsus
–
Ap. louisae
–
Argentinosaurus huinculensis
–
Barosaurus lentus
–
Brachiosaurus altithorax
–
Camarasaurus grandis
–
Camarasaurus supremus
–
Cedarosaurus weiskopfae
–
Chubutisaurus insignis
Dicraeosaurus sattleri
Diplodocus longus
Eobrontosaurus yahnapin
Haplocanthosaurus delfsi
Haplocanthosaurus priscus
Janenschia robusta
Mamenchisaurus constructus
Mamenchisaurus jingyanensis
Omeisaurus maoianus
Omeisaurus tianfuensis
Paralititan stromeri
Patagosaurus fariasi
Seismosaurus halli
Suuwassea emiliae
Tornieria africana
Venenosaurus dicrocei
Volkheimeria chubutensis
Theropoda
Acrocanthosaurus atokensis
Allosaurus fragilis
Allosaurus tendagurensis
Bahariasaurus ingens
Carcharodontosaurus saharicus
Ceratosaurus dentisulcatus
Edmarka rex
Giganotosaurus carolinensis
Piatnitzkysaurus floresi
Saurophaganax maximus
Sinraptor hepingensis
Tendaguru theropod (unnamed)
–
–
–
–
–
–
–
–
–
–
–
1690
–
–
752
Tibia
Metatarsus
Neck
Information source
–
2390
5740
8680
2270
6430
8000
4030
9460
5959
8530
2670
Salgado & Bonaparte (1991)
Riggs (1903)
Janensch (1929a,b)
Janensch (1929a,b)
Hatcher (1901)
Wiman (1929)
Sereno et al. (1999)
Young & Zhao (1972)
Ouyang & Ye (2002)
Young (1939)
Zhang (1988)
184o
225o
269o
255al
254al
240
381o
216b
305c
223
214
201
–
–
–
–
–
–
–
–
–
–
–
–
1040
590
1075
1001
912h
666h
850
690
850
630
820
1370o
1800
1086d
839f
870
655o
240o
145d
209
212
262c
191c
189c
205
253mc
168s
229
337o
198s
232d
177d
203d
178
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
651
395
98s
–
Stromer (1934)
Gilmore (1922)
Calvo & Bonaparte (1991)
McIntosh (1995)
Gilmore (1936)
Bonnan (2001)
Bonaparte & Coria (1993)
McIntosh (2005)
Riggs (1904)
McIntosh et al. (1996)
McIntosh et al. (1996)
Tidwell, Carpenter & Brooks
(1995)
Salgado (1993)
Janensch (1929a,b)
Bonnan (2001)
Bonnan (2001)
McIntosh & Williams (1988)
McIntosh & Williams (1988)
Janensch (1929a,b)
Young (1954)
Zhang, Li & Zeng (1998)
Tang et al. (2001)
He et al. (1984)
Smith et al. (2001)
Bonaparte (1986)
Gillette (1991)
Harris & Dodson (2004)
Janensch (1929a,b)
Tidwell, Carpenter & Meyer
(2001)
Bonaparte (1986)
1277
910
1119a
1220
1260
759
1065p
1430
552
1135
980
825
958aa
734a
910
1154f
977f
594
944p
1161a
492
921a
860sd
830
419
327a
431a
619a
639a
1353ce
559p
551a
290
437a
459sd
318a
–
–
–
–
–
–
–
–
–
–
–
–
Currie & Carpenter (2000)
Madsen (1976)
Janensch (1925)
Stromer (1931)
Stromer (1931)
Madsen & Welles (2000)
Bakker et al. (1992)
Coria & Salgado (1995)
Bonaparte (1986)
Chure (1995)
Gao (1992)
Janensch (1925)
275d
314c
183d
215
143s
–
200
–
285om
175
Journal of Zoology 271 (2007) 45–53 c 2006 The Author. Journal compilation c 2006 The Zoological Society of London
49
Sexual selection on sauropod necks
P. Senter
Table 1 Continued
Taxon
Torvosaurus tanneri
Tyrannosaurus rex
Tyrannotitan chubutensis
Yangchuanosaurus magnus
Yangchuanosaurus shangyuensis
Humerus
Radius
–
–
–
–
–
–
–
–
–
–
Femur
813e
1308
1400
950
850
Tibia
725
1245
1136
844y
755
Metatarsus
427
671
539
866a
327a
Neck
Information source
–
–
–
–
–
Britt (1991)
Brochu (2003)
Novas et al. (2005)
Dong, Zhou & Zhang (1983)
Dong et al. (1983)
All neck lengths are from Parrish (2006), except that of M. youngi, which is from Ouyang & Ye (2002). As much as possible, estimated limb bone
lengths are based on limb proportions in conspecifics or congeners. a, estimate based on limb proportions in All. fragilis (Gilmore, 1920);
aa, estimate based on limb proportions in Ac. atokensis (Stovall & Langston, 1950); ae, estimate based on limb proportions in Ap. excelsus
(Bonnan, 2001); al, estimate based on limb proportions in Ap. louisae (Bonnan, 2001); b, estimate based on limb proportions in Bar. lentus
(Bonnan, 2001); c, estimate based on limb proportions in Cam. grandis (McIntosh et al., 1996); ce, estimate based on limb proportions in
Ceratosaurus nasicornis (Gilmore, 1920); d, estimate based on limb proportions (ischium to limb lengths in Seismosaurus hallorum) in Dip. carnegii
(Hatcher, 1901); dl, estimate based on limb proportions in Dip. longus (Bonnan, 2001); f, estimate based on length of fibula; h, estimate based on
limb proportions in H. delfsi (McIntosh & Williams, 1988); m, estimate based on limb proportions in M. youngi (Pi, Ouyang & Ye, 1996);
mc, estimate based on limb proportions in M. constructus (Young, 1954); o, estimate based on limb proportions (ischium length to limb lengths for
Ve. dicrocei and Ala. sanjuanensis estimates; humerus length to hindlimb lengths for Par. stromeri and An. delgadoi) in Opisthocoelicaudia
skarzynskii (Borsuk-Bialynicka, 1977); om, estimate based on limb proportions in Om. maoianus (Tang et al., 2001); p, estimate based on limb
proportions (pubis length to limb lengths for Ed. rex estimates) in Pi. floresi (Bonaparte, 1986); s, estimate based on limb proportions of Sh. lii
(Zhang, 1988); sd, estimate based on limb proportions in Si. dongi (Currie & Zhao, 1993); u, estimate based on length of ulna; y, estimate based on
limb proportions in Y. shangyuensis (Dong et al. 1983).
competition hypothesis does. Even so, it is important to note
that these two hypotheses are not the only possible hypotheses relating to sauropod neck elongation, and it is possible
that fossil data might better fit the predictions of some other
hypothesis that is as yet unformulated. In any case, sauropods did use non-cervical means to reduce competition for
foliage; differences in dentition, dental microwear and adult
limb lengths show that contemporaneous sauropods often
exhibited different diets and feeding heights (Stevens &
Parrish, 2005).
If the sexual selection hypothesis is correct, then the
dramatic reduction in neck length of the newly discovered
dicraeosaurid sauropod Brachytrachelopan mesai (Rauhut
et al., 2005) indicates that great neck length was less
important for sexually significant behaviour in B. mesai
than in other sauropods. It therefore stands to reason that
sexual behaviour in B. mesai departed from the sauropod
norm. Even in other members of the Dicraeosauridae, necks
are relatively shorter and cervical neural spines are relatively
longer than in other sauropods (Janensch, 1929a,b; Salgado
& Bonaparte, 1991). Given this, it is plausible that members
of the Dicraeosauridae exhibited a change in sexual behaviour such that vertical neck dimensions became more
important than horizontal neck dimensions for reproductive
communication.
As archosaurs, dinosaurs lacked a pheromonal sense and
must therefore have relied on visual, acoustic and tactile
cues to communicate such reproductively significant information as gender and dominance (Senter, 2002). Visual
display structures that apparently served such purposes and
were probably under the influence of sexual selection are
well known in theropods and ornithischians (Chapman
et al., 1997). This is the first time that such a role has been
suggested for sauropod neck length.
50
Acknowledgements
The following people deserve thanks for supplying limb and
neck measurements or for helping me find them in the
literature: J. M. Parrish, M. F. Bonnan, J. B. Smith,
J. A. Wilson, M. C. Lamanna, P. Christiansen, F. E. Novas,
M. J. Wedel, J. D. Harris, J. S. McIntosh, D. J. Chure and
K. L. Davies. I thank P. Chiou for translating Chinese articles
for me. Translations by M. C. Lamanna, M. T. Carrano,
J. A. Wilson, W. Downs, J. Jin and J. D. Oldroyd of several
other articles were made available through the Polyglot
Paleontologist website (http://ravenel.si.edu/paleo/paleoglot/
index.cfm). I also thank the reviewer for constructive comments that improved this paper.
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53
Journal of Zoology
Journal of Zoology. Print ISSN 0952-8369
The long necks of sauropods did not evolve primarily
through sexual selection
M. P. Taylor1, D. W. E. Hone2, M. J. Wedel3 & D. Naish4
1Department of Earth Sciences, University of Bristol, Bristol, UK
2 School of Biology and Environmental Sciences, University College Dublin, Belfield, Dublin, Ireland
3 Department of Anatomy, College of Osteopathic Medicine of the Pacific and College of Podiatric Medicine, Western University of Health
Sciences, Pomona, CA, USA
4 Palaeobiology Research Group, School of Earth and Environmental Sciences, University of Portsmouth, Portsmouth, UK
Keywords
sexual selection; dinosaurs; sauropods;
giraffes; necks; feeding; behaviour; ecology.
Correspondence
Michael P. Taylor, Department of Earth
Sciences, University of Bristol, Bristol BS8
1RJ, UK.
Email: dino@miketaylor.org.uk
Editor: Nigel Bennett
Received 28 October 2010; revised 8 April
2011; accepted 19 April 2011
doi:10.1111/j.1469-7998.2011.00824.x
Abstract
It has recently been argued that the elongate necks of sauropod dinosaurs evolved
primarily through selection for their use as sexual and dominance signals, and not
as an adaptation for accessing a large ‘feeding envelope’ as traditionally thought.
Here we explore this idea and show that all six arguments that have been advanced
in support of the sexual selection hypothesis are flawed: there is no evidence for
sexual dimorphism in the necks of sauropods; neither is there any evidence that
they were used in dominance displays; long necks provided significant survival
benefits in allowing high browsing and energetically efficient grazing; their fitness
cost was likely less than has been assumed; their positive allometry through
ontogeny is uninformative given that ontogenetic allometry is common in animals;
apparent lack of correlation between neck and leg length across phylogeny is
illusory due to over-representation of mamenchisaurids in a previously analysed
dataset, and in any case is not informative as the unique morphology of sauropod
necks suggests they, rather than legs, may have been cheaper to elongate when
evolving increased vertical reach. In no speciose, morphologically varied, longlived tetrapod clade has sexual selection consistently acted on a single part of the
body, and it is unlikely that Sauropoda is the exception to this. In summary, there
is no convincing evidence that sexual selection was the primary force driving the
evolution of sauropod necks. While a subsidiary role for sexual selection cannot be
discounted, the traditional hypothesis that sauropod necks evolved primarily due
to the feeding benefits that they conferred is, by comparison, far better supported.
Introduction
Sauropod dinosaurs are instantly recognizable thanks to their
unique bauplan: a huge, robust torso borne on four columnar
limbs, a long neck, a proportionally small head and a long tail.
The long necks of sauropods have long fascinated palaeontologists. For much of the 20th century, sauropods were imagined to be amphibious or aquatic herbivores that used their
long necks as snorkels (e.g. Wiman, 1929). However, Bakker
(1971) and Coombs (1975) used diverse lines of evidence to
show that sauropods were predominantly terrestrial herbivores that foraged on terrestrial vegetation, and subsequent
discoveries and studies have endorsed this interpretation
(Taylor, 2010). Within this terrestrial paradigm, the sauropod
neck has most usually been imagined as an adaptation
allowing access to a large ‘feeding envelope’: that is, a foraging
area that extends from ground level to many metres up into
tall plants (e.g. Bakker, 1971; Martin, 1987; Paul, 1998;
Upchurch & Barrett, 2000; Wedel, Cifelli & Sanders, 2000).
150
The use of the long neck as a tool for foraging is
intuitively appealing given that these very large herbivores
would have required huge amounts of energy and would
have benefited from access to the largest possible feeding
envelope. Furthermore, an ability to reach food inaccessible
to species belonging to the other great herbivorous dynasties
of the Jurassic and Cretaceous (thyreophorans, ornithopods
and marginocephalians) would be an obvious advantage.
The different neck lengths of the various sauropod taxa
(Fig. 1) would conceivably create ecological partitioning
among contemporaneous sauropod species similar to that
seen in modern African ungulates (Leuthold, 1978; Bakker,
1986). Such niche partitioning would go some way towards
explaining the extraordinary level of sauropod diversity in
the Late Jurassic: 19 genera were contemporaneous during
the 3.4 million years of the Kimmeridgian Age alone
(Taylor, 2006). Alternatives to a foraging role for the neck
have rarely been proposed. However, Senter (2006) – inspired by a controversial hypothesis about giraffe neck
Journal of Zoology 285 (2011) 150–161 c 2011 The Authors. Journal of Zoology c 2011 The Zoological Society of London
M. P. Taylor et al.
Sauropod necks were not sexually selected
Figure 1 Sauropod necks, showing relationships for a selection of species, and the range
of necks lengths and morphologies that
they encompass. Phylogeny based on that
of Upchurch et al. (2004: fig. 13.18). Mamenchisaurus hochuanensis (neck 9.5 m long) modified from Young & Zhao (1972: fig. 4);
Dicraeosaurus hansemanni (2.7 m) modified
from Janensch (1936: plate XVI); Diplodocus
carnegii (6.5 m) modified from Hatcher (1903:
plate VI); Apatosaurus louisae (6 m) modified
from Lovelace, Hartman & Wahl (2008: fig. 7);
Camarasaurus supremus (5.25 m) modified
from Osborn & Mook (1921: plate 84); Giraffatitan brancai (8.75 m) modified from Janensch
(1950: plate VIII); giraffe (1.8 m) modified from
Lydekker (1894:332). Alternating grey and
white vertical bars mark 1 m increments.
evolution – recently suggested that sauropod necks were
sexually selected display ornaments.
Like sauropods, the long-necked giraffes of the genus
Giraffa are long-necked herbivores with necks traditionally
inferred to be advantageous in feeding (e.g. Cameron & du
Toit, 2007) and their gross similarity has not gone unnoticed
(as, e.g. in the name of the sauropod Giraffatitan). However,
the long-held idea that giraffes gained a competitive ecological advantage from a long neck and great vertical reach
was challenged by Simmons & Scheepers (1996), who
advanced the alternative hypothesis that sexual selection is
the primary factor driving the evolution of the neck. Building on the work of Simmons & Scheepers (1996), and using
giraffes as an analogue, Senter (2006) proposed the novel
hypothesis that the long sauropod neck also evolved
through sexual selection rather than for any benefit related
to feeding.
Senter (2006) surveyed the criteria by which sexually
selected characters are recognized in extant taxa, constructed a series of six predictions relating to the contrasting
hypotheses of feeding benefit versus sexual selection, and
then tested both hypotheses against fossil evidence. He
concluded that the sexual selection hypothesis is more
consistent with predictions than the feeding benefit hypothesis. The six predictions which Senter considered should be
fulfilled by taxa in which neck elongation was sexually
selected are as follows:
1. Sexual dimorphism of the neck.
2. Use of the neck in dominance or courtship displays.
3. Intraspecific differences in neck length that do not facilitate vertical partitioning.
4. Neck elongation that incurred a survival cost.
5. Positive allometry in neck growth through ontogeny.
6. Positive allometry across phylogeny that is not correlated
with limb length.
While conceding that the first two hypotheses could not
be tested, Senter found support consistent with the other
predictions and thus considered the elongation of the
sauropod neck to be the result of sexual selection.
Senter’s hypothesis is novel, his assumptions and evidence are clearly stated, and his conclusion is at odds with
conventional interpretations. Despite this, his work has not
attracted critical analysis. Instead, the conclusion that sexual selection played an important or even dominant role in
the evolution of the sauropod neck appears to have been
accepted at face value in the literature on both selection
(Swallow et al., 2009) and sauropod palaeobiology
(Sander & Clauss, 2008; Siegwarth, Smith & Redman,
2010). Mateus, Maidment & Christiansen (2009) applied
Senter’s criteria to the long-necked stegosaur Miragaia
longicollum, but with inconclusive results. However, recent
work on both giraffes (Cameron & du Toit, 2007; Mitchell,
van Sittert & Skinner, 2009) and sauropods (Christian &
Dzemski, 2007; Taylor, Wedel & Naish, 2009) challenges
Senter’s (2006) analyses and the assumptions underlying
them. Also of relevance is the recent resurgence in work
on sexual selection in non-avian dinosaurs: this research
has involved the reassessment and reanalysis of ‘conventional’ hypotheses in the light of new data and new techniques (e.g. Knell & Sampson, 2010; Padian & Horner,
2010 on mate recognition and sympatric separation) or
modern theory. Note, however, that ‘classic’ traits such
as horns and crests have received the bulk of the attention
to date.
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Sauropod necks were not sexually selected
In this paper we explore the implications of these and
other studies for the sexual selection hypothesis of long
necks in sauropods. We show that Senter’s sexual selection
hypothesis rests on a false dichotomy, demonstrate that
most of his predictions deemed indicative of sexual selection
are not fulfilled, and introduce additional arguments in
favour of the traditional feeding-advantage hypothesis.
Sexual selection and survival
selection are not mutually exclusive
A foundational problem with Senter’s argument that sauropod necks were sexually selected is that it rests on the false
assumption that sexual selection and survival selection are
mutually exclusive. This assumption can be seen, for example, in Senter’s prediction 2: ‘[The feeding hypothesis]
predicts that sauropod necks are not used in dominance
contests and courtship displays, whereas [the sexual selection hypothesis] predicts that they are’. This ignores the
possibility that long necks were under selection pressure
from both factors.
Morphological adaptations rarely have a single function.
While structures may originally arise under selection from a
single dominant factor, they are almost invariably co-opted
for others. For example, the horns of various bovids provide
a sexual signal by advertising fitness (Ezenwa & Jolles,
2008), function in intra- and interspecific combat (Caro
et al., 2003), provide some defence against predators, and
have a minor thermoregulatory role (Hoefs, 2000). Similarly, the casques of cassowaries fulfill a number of functions, both sexual and non-sexual: they are used for display,
to help detect infrasonic calls (Mack & Jones, 2003), and for
manipulating foliage at shoulder height and leaf litter on the
ground (Folch, 1992). Perhaps the most obvious example of
co-option is the elephant trunk, which, among many other
functions, is used for breathing, as a tactile organ, to gather
food and water, and as a social signal; and while elephants’
tusks are used for both inter- and intraspecific combat, their
primary use is to help collect food (Barnes, 1995).
If sauropod necks were used for dominance signals and
increased reach for feeding then any test could result in a
double positive or double negative result and no informative
inference could be made. Such a dual use of long necks is not
without precedent in the world of modern reptiles: the
proportionally long necks of saddlebacked Galápagos giant
tortoises Geochelone nigra are used both to enable great
vertical reach during foraging, and to determine dominance
in intra- and intersubspecific conflicts (Fritts, 1984; Fig. 2).
As noted above, Senter’s hypothesis that sauropods used
their necks as sexual signals was inspired by the hypothesis
of Simmons & Scheepers (1996) that the length of the giraffe
neck was driven by a role in sexual selection, and that its
length offers no competitive benefit in foraging at height.
This ‘necks for sex’ hypothesis is highly problematical and
has not been supported by subsequent evaluation. Male and
female giraffes have previously been shown to feed at
different heights (Ginnett & Demment, 1997, 1999). Cameron & du Toit (2007) showed that elongate necks in giraffe do
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M. P. Taylor et al.
provide vertical stratification, and that giraffes gain an
advantage by feeding above the reach of other herbivorous
mammals. Importantly, Cameron & du Toit’s (2007) study
is based on experimental, rather than simple observational,
evidence. More recent work (Simmons & Altwegg, 2010) has
suggested that neck elongation in giraffes may indeed be
linked to sexual selection, but concedes that the role of the
neck as a browsing device cannot be ruled out and may well
have been important. Finally, Van Sittert, Skinner & Mitchell (2010) argued that ontogenetic allometry of the neck does
not differ between male and female giraffes. Therefore, in so
far as Senter’s argument rests on analogy with what had
been asserted regarding sexual selection in giraffes, the
argument is weakened by the subsequent challenges to
Simmons & Scheepers’ (1996) work.
In short, to assume that sexual selection can be considered both independent from, and exclusive of, a competitive
ecological function is erroneous. It remains possible that the
sauropod neck originally arose either as a sexually selected
feature or to help gather food, but it cannot be demonstrated that the necks remained monofunctional throughout
their evolution, or that they could not be co-opted for a
secondary function.
Senter’s predictions re-evaluated
We now consider in turn each of Senter’s predictions for
animals in which long necks are sexually selected rather than
conferring an ecological advantage, and re-evaluate whether
these predictions are fulfilled in sauropods.
Prediction 1: sexual dimorphism of the neck
Contrary to common perception (e.g. Padian & Horner,
2010), sexual dimorphism of a trait is not a prerequisite for
any inference of sexual selection. While sexual dimorphism
can of course be a strong indicator of sexual selection, the
existence of mutual sexual selection complicates the issue.
As originally noted by Huxley (1914), and more recently
expanded upon by Hunt et al. (1999), Kraaijeveld et al.
(2004) and others, sexually selected characters can appear in
both males and females of a species: both sexes may be
ornamented. Each may use ornaments to signal to the other;
consequently a sexually selected trait may become exaggerated in both sexes. In the crested auklet Aethia cristatella,
for example, both sexes bear feather plumes on their heads
and both sexes prefer mates with longer crests (Jones &
Hunter, 1993, 1999). Some sexual dimorphism may be
evident in such cases, but it can be minor and far less
dramatic than in ‘classic’ sexually selected traits like the tails
of peacocks.
While a lack of dimorphism does not therefore provide a
barrier to the possibility of sexual selection in sauropod
necks (mutual sexual selection could be at play), it does
cause serious issues for the way in which Senter (2006) tested
sexual selection. For example, his prediction 1 that ‘[feeding
advantage] predicts that sauropod neck dimensions are not
greater in one sex than in the other, whereas [sexual
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M. P. Taylor et al.
Sauropod necks were not sexually selected
Figure 2 Long necks often serve multiple functions, as demonstrated here by Galápagos giant
tortoises Geochelone nigra. (a) Use of the long
neck for high browsing is commonly practized
by terrestrial testudines. Based on a photograph in Moll (1986:74–75). (b) Use of the long
neck in establishing dominance. The two tortoises shown in the illustration were photographed on Santa Cruz Island: the domeshelled animal on the right belongs to the native
form G. n. porteri while the saddlebacked
animal at left represents the Española form G.
n. hoodensis. Based on a photograph in Fritts
(1984: Fig. 2).
selection] predicts that they are’ would test negatively for
mutual sexual selection under this definition, even if in fact
sexual selection were the sole driving force of neck length.
Nevertheless, if we are to follow the hypotheses as stated
by Senter, strong sexual dimorphism in neck length is a
requirement. As Senter himself recognized, available samples of sauropod taxa are unfortunately not large enough to
demonstrate bimodal distribution of morphological features
within any sauropod species. While Senter (2006, p. 46)
tentatively suggested that the contemporaneous Late Jurassic diplodocids Barosaurus and Diplodocus of the USA’s
western interior might have been sexual dimorphs of a single
taxon, he rightly concluded that ‘it would be premature to
synonymize the two taxa without a rigorous analysis with a
large sample size’. In fact, these genera have different
numbers of cervical vertebrae (McIntosh, 2005; M. J.
Wedel, pers. obs.), and so cannot be sexual dimorphs of a
single species. Furthermore, sexual dimorphism has not
been persuasively demonstrated for any non-avian dinosaur
species (Padian & Horner, 2010).
While it is not possible to statistically demonstrate
dimorphism, qualitative comparisons can nevertheless be
made. Robust and gracile ‘morphs’ have been identified in
several dinosaur taxa – for example, Coelophysis (=‘Syntarsus’) rhodesiensis (Raath, 1990) and Tyrannosaurus rex
(Larson, 2008), so we may consider whether there is similarly any evidence for different neck lengths within a single
sauropod species. To our knowledge, there is no such
evidence in the fossil record. If anything, the uniformity of
cervical morphology within sauropod species suggests that
their necks were not sexually dimorphic. In general, isolated
cervical vertebrae are diagnostic at least to the genus level
(McIntosh, 1990). Upchurch, Tomida & Barrett (2005)
identified differences in cervical neural spine height among
species of Apatosaurus, but not differences in neck length. So
not only is sexual dimorphism in sauropod neck length not
amenable to statistical analysis, there is not even any
anecdotal evidence to suggest its presence.
In conclusion, we simply do not have the data to determine whether sauropods were sexually dimorphic or not,
Journal of Zoology 285 (2011) 150–161 c 2011 The Authors. Journal of Zoology c 2011 The Zoological Society of London
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Sauropod necks were not sexually selected
and dimorphism is in any case not a prerequisite for sexual
selection. Therefore, prediction 1 contributes no information and can be discarded.
Prediction 2: use of the neck in dominance or
courtship displays
As noted by Senter (2006, p. 46), this prediction ‘cannot be
tested for sauropods because the behaviour of extinct
animals cannot be observed’. While this is generally true,
some forms of agonistic behaviour, such as the ‘necking’ of
male giraffes, are correlated with osteological features such
as progressive thickening of skull bones through ontogeny
(Simmons & Scheepers, 1996: p. 780) and signs of trauma.
We would expect to see evidence of similar development in
sauropods if their behaviour was similar; but again as noted
by Senter, such features have not been observed in any
sauropod.
Prediction 2, therefore, also contributes little information, and if anything weighs weakly against the sexual
selection hypothesis.
Prediction 3: intraspecific differences in
neck length that do not facilitate vertical
partitioning
In formulating this prediction and arguing for its falsification, Senter relied on a sequence of assumptions. The
indication of sexual selection from the literature, as originally stated (Senter 2006, p. 45) is that ‘The character
provides no immediate survival benefit – in contrast to
characters driven by other kinds of selection, which are fixed
in a population because of some survival benefit (Darwin,
1871; Simmons & Scheepers, 1996)’. From this, Senter
derived the prediction that if sauropod necks were not
sexually selected then ‘interspecific differences in sauropod
neck lengths provided vertical stratification of foraging
among sauropod species and between sauropods and other
species’. This is a very specific restatement of the original,
general, prediction and makes the following assumptions:
(A) that interspecific competition is the only kind that
occurs or matters, (B) that the only way longer necks could
have benefited sauropods was by an increase in vertical
reach and (C) that the only value of increased vertical reach
is niche partitioning due to stratification. In falsifying this
revised prediction, Senter further assumed (D) that such
niche partitioning is not possible due to overlapping juvenile
and adult heights and (E) that the necks of sauropods could
not be raised much above the horizontal. Every single link in
this chain of reasoning is flawed.
(A) Senter implicitly assumed that increases in neck
length due to survival benefits were driven only by interspecific competition; but one of the tenets of natural selection is that an organism competes most intensely with the
organisms to which it is most similar, that is, the other
members of its own population (Darwin, 1859). So
even members of a single sauropod species with no close
competing taxa – for example, Sauroposeidon proteles in the
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fauna of the Antlers Formation (Wedel et al., 2000) – would
still benefit from neck elongation due to intraspecific
competition.
(B) The second assumption is that the only survival
benefit of the long neck would be from improved vertical
reach. However, it has repeatedly been argued that even if
sauropod necks could not be raised high, their owners would
nevertheless benefit from a larger feeding envelope at
ground level – see, for example Martin (1987) on Cetiosaurus, Stevens & Parrish (1999) on Diplodocus and Apatosaurus, Sereno et al. (2007) on Nigersaurus and Ruxton &
Wilkinson (2011) on Giraffatitan (= ‘Brachiosaurus’ of their
usage). Extant geese (e.g. Branta canadensis) provide a
useful analogue: although they use their long necks to ‘grub’
for aquatic vegetation (thus improving their vertical reach,
albeit downward), they also graze on low-lying terrestrial
plants, and such ‘green browse’ makes up most of their diet
(Owen, 1980). Grazing geese sweep their heads and necks
from side to side during grazing, exactly as has been
proposed for low-necked sauropods.
(C) The assumption is made that niche partitioning is the
only putative benefit of increased feeding height. This is a
very complex ecological scenario that explores only one of
several possible survival benefits. Sauropods would also
benefit from access to better quality food, and from the
ability to reach the only available food during times of
unusually intense competition.
The analogy with giraffes is instructive here: while
giraffes do feed at low heights where food plants are shorter
(Young & Isbell, 1991), the most important factor is what is
consumed. Giraffes prefer to feed at higher levels, both
because there is less competition from other browsers, and
because higher foliage (in acacia trees) tends to have more
protein and less tannin than foliage lower down. Feeding
higher up is more productive and thus faster, meaning that
giraffes need spend less time than when feeding at lower
levels (Woolnough & Du Toit, 2001; Cameron & du Toit,
2007). High level browsing by giraffes can be intensive on
some plants, and indeed the famous ‘bell’ shape of Balanites
trees is formed by this habit (Foster, 1966).
Even if it were true that giraffes habitually browsed with
their necks horizontal whenever possible, it would remain
the case that the long necks, enabling higher browsing when
necessary, would provide access to scarce food during times
of environmental stress. Therefore, other things being equal,
animals able to browse at higher levels are at an evolutionary advantage in terms of their ability to survive prolonged
drought even if they do not use high browsing at other times.
In conclusion, giraffes use their necks to maximize their
exploitation of available browse, and there is no reason to
doubt that analogous high browsing in sauropods would
share the same evolutionary benefits.
The significance of this sequence of assumptions (A)–(C)
is that even if it were demonstrated that sauropods were not
niche-partitioned by feeding height, this would by no means
exhaust the many other survival benefits they might have
enjoyed thanks to their long necks. Shorn of these unwarranted assumptions, the prediction should be much more
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M. P. Taylor et al.
general: that longer necks provided some kind of immediate
survival benefit. However, the vertical feeding stratification
hypothesis is not in fact disproven, as we will now show.
(D) Senter used the inevitable overlap among taxa in
browsing height as evidence against the stratification hypothesis: ‘vertical stratification due to neck length would
have existed only for adult sauropods’. The vertical foraging
ranges of juveniles of all species overlapped each other’
(Senter, 2006: p. 46). But this criterion would make it
impossible for any organisms that change size over ontogeny to pass the test; it is equivalent to arguing that canopy
trees in rain forests do not compete for open spaces because
juvenile trees of different species overlap in height. In any
case, extant ecosystems show that there is marked overlap in
browsing heights and competition between taxa where
stratification is possible. For example, in African savannahs,
vertical stratification can be seen between various taxa, yet
they still overlap with dominant herbivores (Leuthold,
1978). Various species of giraffe, elephant, rhinoceros,
zebra, suid, buffalo and antelope feed in overlapping environments (Sinclair, 1985; McNaughton & Georgiadis, 1986;
Woolnough & Du Toit, 2001), yet each manages to occupy a
separate ecological niche. Stratification is therefore by no
means the only way to eliminate or reduce competition.
Feeding guilds of taxa are likely to be influenced in their
distribution by more than just one aspect of food acquisition
(Sinclair, 1985).
(E) Senter’s claim that sauropods could not derive a
survival benefit from their long necks also rests on the
assumption that they could not raise their necks in order to
reach high branches. Senter (2006: p. 47) stated that ‘The
ability to lift the head above the level of the back was limited
or absent in sauropods [. . .] Obviously, if a neck is held
horizontally, its length does not influence vertical reach’.
This concept of restricted vertical reach is based on the work
of Martin (1987) and Stevens & Parrish (1999, 2005): based
on inferences made about the neck’s ‘neutral posture’ and
the range of vertical movement allowed by the dry bones in
the neck skeleton, these authors suggested that sauropods
were mostly restricted to near-horizontal neck postures, and
that their vertical reach was limited.
However, the neck posture and range of motion estimates
of Martin (1987) and Stevens & Parrish (1999, 2005) are
hypotheses rather than established facts, and have not been
validated by subsequent studies. In particular, the underlying osteological data is too poor to support the reported
precision of the estimates (Upchurch, 2000); assumptions
about the mobility of intervertebral joints are probably
incorrect (Taylor, 2009; Taylor et al., 2009); and verification
of the methods using extant animals has not been demonstrated. Indeed, most extant tetrapods habitually hold their
necks maximally extended at the base (Vidal, Graf &
Berthoz, 1986), and achieve this posture by extending the
cervico-dorsal joint farther than osteology alone would
suggest is possible (Taylor et al., 2009). Until convincing
evidence to the contrary is presented, habitual elevated neck
posture should be the null hypothesis for sauropods (Taylor
et al., 2009).
Sauropod necks were not sexually selected
Furthermore, even if sauropod necks were not habitually
held in the elevated posture common to extant tetrapods,
recent work by Stevens & Parrish (2005) themselves suggested that the necks of some sauropod taxa sloped gently
upward even in ‘neutral posture’. Note the substantial
difference between having a limited ability to raise the neck
and being completely unable to raise the neck; a neck need
only be elevated at 301 to achieve half of the vertical reach of
a neck elevated at 901.
It has also been suggested that sauropods were limited in
their ability to raise their necks due to the difficulty of
circulating blood to the head (e.g. Seymour, 2009). Some of
the calculations supporting this argument are flawed, and
two of us (Taylor & Wedel) are working on a refutation.
As Senter’s prediction 3 is a very specific case of the much
broader originally proposed indication of survival selection,
and as even that subset cannot be supported by evidence,
this prediction does not provide evidence in favour of sexual
selection. In fact, the numerous ways in which the long
necks of sauropods might have provided survival benefits
mean that, contra Senter, this prediction provides support
for the competing hypothesis that the long necks of sauropods were indeed selected for their benefits in ecological
competition.
Prediction 4: neck elongation that incurred a
survival cost
This prediction is misstated in Senter’s argument. It is given
as ‘The character incurs a survival cost – in contrast to
characters driven by other kinds of selection, which are fixed
in a population only if they incur minimal or no survival
cost’. In fact, things are never this simple: in general, each
evolutionary innovation has both a cost and a benefit: the
question is whether the former outweighs the latter. For
example, the large brains of humans – like the long necks of
sauropods – impose a significant metabolic cost; but their
benefits outweigh the cost and so the trait survives. Accordingly, while we wholeheartedly agree that the long necks of
sauropods imposed real costs on their owners, this fact in
itself does not constitute evidence of sexual selection.
Besides this, the costs of long necks seem to have been
overstated. The only example given by Senter (2006, p. 47)
was his claim that a horizontal sauropod neck would leave
the animal vulnerable to attack from large predatory theropods, as ‘a single bite that severed carotid arteries, jugular
veins or vagus nerves would have been sufficient to dispatch
a sauropod’. However, this assertion is problematic. Extant
predators rarely attack adult animals (especially those many
times larger than themselves) when juvenile prey is much
more vulnerable, and there is evidence from the size distribution of bones in the fossil record that this was also true
of Mesozoic theropods (Hone & Rauhut, 2009). Injuring or
killing a sauropod with a single bite to the neck would be
more difficult than the phrase ‘a single bite that severed
carotid arteries’ suggests. The neck was not simply a mass of
external blood vessels and nerves, but was constructed from
tough elements including the often robust cervical ribs, bony
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Sauropod necks were not sexually selected
laminae, ligaments and tendons. A theropod could hardly
dispatch a moving apatosaur with one swift bite, and a
raised neck would further reduce vulnerability. (Other costs
associated with sauropod anatomy, such as the need to
acquire large amounts of food, are related to size in general
rather than neck length in particular.)
The assumption that long necks impose a significant
survival cost in giraffes is also flawed. Senter (2006) suggested that, as male giraffes more frequently fall victim to
predation than females do (Simmons & Scheepers, 1996),
the long neck of a sauropod imposes a substantial survival
penalty by analogy. However, male African ungulates as a
whole are typically more vulnerable to predation then
females due to their behaviour, including solitary lifestyles
and intraspecific combat (Owen-Smith, 2007). In giraffes
specifically, males are primarily solitary (Dagg, 1971) while
females tend to associate in herds. Males are thus more
vulnerable through social factors, rather than necessarily as
a consequence of their longer necks (Leuthold, 1979; van der
Jeugd & Prins, 2000). Thus there is no evidence that the
vulnerability of male giraffe to predators is in any way due
to their neck length, and no reason to infer by analogy that
male sauropods were similarly vulnerable.
As it cannot be shown that the cost of the long necks of
sauropods outweighed their benefits, and as analogy with
giraffes suggests that these costs were in any case lower than
suggested by Senter, prediction 4 has little value in determining the function of sauropod necks.
Prediction 5: positive allometry in neck
growth through ontogeny
Senter (2006, p. 47) correctly noted that positive allometry
through ontogeny is known in the neck of Camarasaurus:
this has been briefly noted by both Britt & Naylor (1994, p.
261) and Ikejiri, Tidwell & Trexler (2005, p. 173). Furthermore, Wedel et al. (2000, p. 368) showed that the cervical
vertebrae of adult Apatosaurus individuals were proportionally 35–65% longer than those of juveniles, indicating that
the neck elongated over ontogeny. (Given the very small
sample of available cervical series for sauropod taxa, it is not
possible to meaningfully calculate the allometric slope for
any taxon.)
However, Senter’s claim that positive allometry necessarily indicates sexual selection is flawed, resting as it does on
publications from the 1980s and very early 1990s. In the last
two decades, research in this area has progressed rapidly,
and there is now an extensive literature on the relationship
between allometric growth and sexual selection. Reviews
such as that of Bonduriansky (2007) show that the picture is
more complicated than previously recognized. While sexually selected features are often positively allometric, they
may be isometric and even negatively allometric: in 10 of the
12 studies reviewed by Bonduriansky (2007, p. 843), isometry or negative allometry was reported for some or all of
the sexually selected traits analysed, and Hosken, Minder &
Ward (2005, p. 510) noted that ‘male genitalia appear to
show negative allometry in most invertebrates studied’.
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M. P. Taylor et al.
Furthermore, non-sexual features may be positively allometric: for example, Lammers & German (2002) showed
that in all four mammals that they analysed (chinchilla,
rabbit, rat and opossum), femur length and tibia length are
strongly positively allometric with respect to body mass.
Similarly, Farlow & Pianka (2000) demonstrated ontogenetic allometry in the limb bones of several species of
monitor lizard, and Simmons & Tomkins (1996) found that
the non-sexually selected elytra of earwigs were positively
allometric (though not so strongly as the sexually selected
forceps).
As both positive and negative allometry occurs for both
sexually selected and other body parts in extant animals,
its presence in the necks of sauropods cannot be construed
as compelling evidence for sexual selection, especially in
the absence of quantification of the degree of allometry.
Therefore, prediction 5 contributes little or no information
to the question of whether sauropod necks were sexually
selected.
Prediction 6: positive allometry across
phylogeny that is not correlated with
limb length
The characteristic sauropod body shape was established in
the earliest sauropods (e.g. the Late Triassic Antetonitrus;
Yates & Kitching, 2003) and remained in place until the very
end of the Mesozoic. The major sauropod clades modified
the body plan in various ways with differences in the
proportions of the neck and the limbs being relevant here.
Brachiosaurids had longer forelimbs than hindlimbs, for
example, whereas diplodocoids had apomorphically short
forelimbs, some only 65% the length of the hindlimbs
(Upchurch, Barrett & Dodson, 2004).
Almost all sauropods were long-necked in comparison
with non-sauropods, both proportionally and absolutely;
but proportional variation within Sauropoda was nevertheless pronounced. Relatively short-necked sauropods include dicraeosaurids (e.g. Brachytrachelopan mesai, Rauhut
et al., 2005) and the titanosaur Isisaurus (= ‘Titanosaurus’)
colberti (Jain & Bandyopadhyay, 1997). In all other sauropods, the neck was much longer than necessary to reach the
ground, and could be exceptionally long: in the diplodocid
Supersaurus vivianae, for example, the neck has an estimated
length of 13–16 m (Wedel, 2007, p. 195–197) compared with
a shoulder height of o4 m. Necks on the order of 10 m in
length evolved independently in mamenchisaurids (Russell
& Zheng, 1993), brachiosaurids (Wedel et al., 2000) and
diplodocids (Wedel, 2007), and possibly in giant titanosaurs
(e.g. Puertasaurus reuili; Novas et al., 2005).
One of Senter’s (2006, p. 46) key arguments is that if the
long sauropod neck evolved for use in feeding, then ‘[when]
selection pressure is towards increasing the vertical reach of
the head, the limbs – the lengths of which also influence head
height – increase in relative length along with the neck
across phylogeny’. His analysis showed no correlation
between limb length and neck length in sauropods, which
he interpreted as evidence that neck elongation was not
Journal of Zoology 285 (2011) 150–161 c 2011 The Authors. Journal of Zoology c 2011 The Zoological Society of London
M. P. Taylor et al.
selected for vertical reach. On the face of it, this result seems
reasonable, given the diversity of sizes and shapes among
sauropods (Fig. 1). However, there are two problems with
Senter’s (2006, p. 47) analysis. First, the sample size is too
small for the results to be statistically significant; and
second, the taxon selection is poor, containing an overrepresentation of the small clade Mamenchisauridae and
not a single representative of the great clade Titanosauria,
which encompasses more than a third of all sauropod genera
(Taylor, 2006). Mamenchisaurids are notable among sauropods in having the proportionally longest necks, and the
inclusion of three (Mamenchisaurus hochuanensis, Mamenchisaurus youngi and Omeisaurus junghsiensis) in the
sample of 11 sauropods biases the results away from
recognizing a neck-length/limb-length correlation. When
we replicated Senter’s correlation analysis, using the data in
his table 1 and reducing the mamenchisaurid sampling to
only O. junghsiensis, the forelimb-neck correlation improved
from 0.3484 to 0.4129, though this is also not statistically
significant. A more comprehensive sampling, which lies
beyond the scope of this study, will be required to determine
whether significant correlation exists.
A hidden assumption in Senter’s (2006) prediction 6 is
that a long neck can contribute to feeding performance only
by increasing vertical reach (as is the case in giraffes).
However, most sauropods differed from giraffes in that
their necks were much longer than they needed to be to
reach the ground. In addition to improving vertical reach,
such ‘excessively’ long necks could have improved feeding
performance by allowing energetically efficient access to
resources broadly distributed on the ground (Stevens &
Parrish, 1999; Ruxton & Wilkinson, 2011) or in a threedimensional feeding envelope (Martin, 1987; Wedel et al.,
2000). In light of this, it is perfectly reasonable to conclude
that sauropods might have evolved long necks for feeding
purposes without also evolving correspondingly long legs.
Even in committed high-browsers, vertical reach can be
extended by evolving either a longer neck or longer limbs.
But these two paths are not subject to equal constraints,
especially in the case of sauropods. The cervical vertebrae of
most sauropods were highly pneumatic (Wedel, 2005) and
much less dense than the limb bones, which had very thick
cortices and small (or absent) medullary cavities (Stein et al.,
2010). Sauropods were able to offset the mass penalty
imposed by a longer neck by reducing the bone-to-air ratio
of their cervical vertebrae, as seen for example in the clade
Brachiosauridae, in which the very long-necked S. proteles
has much more penumatic vertebrae than its less elongate
relative Giraffatitan brancai (Wedel & Cifelli, 2005: fig. 13).
The tendency for longer necks to correlate with greater
cervical pneumaticity is also seen in Sauropoda as a whole
(Wedel, 2007: p. 219). Because at least part of neck elongation in sauropods came ‘for free’ (though not all; longer
necks still required longer muscles, tracheae, and blood
vessels and greater transport costs), it may have been more
advantageous for sauropods to extend their vertical reach by
adding or elongating cervical vertebrae instead of changing
the length of the limbs; the latter would be free to evolve in
Sauropod necks were not sexually selected
other ways based on the demands of body support and
locomotion. This is not a trivial consideration: most sauropods were an order of magnitude more massive than
giraffes, and locomotory stresses would have been completely different from those affecting smaller animals. Their
four dense, columnar limbs had to be accelerated twice in
each step cycle (from stance, to swing, back to stance), while
their single comparatively lightweight, pneumatic necks did
not. Energetics alone may have been sufficient to prevent
sauropods from evolving a body form similar to that of
giraffes and camelids, with necks and limbs of comparable
lengths.
In summary, even if Senter’s statistical analysis is taken at
face value as showing that sauropod neck length is not
strongly correlated with leg length, this does not necessarily
mean that neck elongation did not contribute to feeding.
Consequently, prediction 6 contributes no information.
No single feature is sexually selected
across any speciose tetrapod clade
In evaluating any palaeobiological or palaeoecological hypothesis, analogy with extant animals and ecosystems is
always instructive. One important question to ask about the
sexual selection hypothesis of sauropod neck elongation is
whether there is any large extant tetrapod clade in which the
members all show a uniform maladaptive feature analogous
to the long sauropod neck. Sauropoda was a diverse and
disparate group, encompassing many genera, great morphological variation, a range of habitat preferences (Mannion &
Upchurch, 2010) and huge ecological significance: it is
reasonable to compare it in these terms with modern tetrapod clades such as Artiodactyla or even Passeriformes. If the
long necks of sauropods had negative survival value, their
retention across the whole clade is analogous to a hypothetical situation where the maladaptively long tails of birds-ofparadise are found throughout Passeriformes, or where the
enormous antlers of the Irish Elk Megaloceros are ubiquitous in Artiodactyla. Instead, we see long-term progressive
evolution of characters that have survival benefit, while
sexually selected characteristics are subject to evolutionary
‘fashion’ and tend to be much more labile.
As well as being diverse, Sauropoda also had a long
evolutionary history, originating about 210 million years
ago in the Carnian or Norian Age of the Late Triassic, and
persisting until the end-Cretaceous extinction of all nonavian dinosaurs about 65 millions years ago. Thus the
‘necks-for-sex’ hypothesis requires that this clade continued
to sexually select for exaggeration of the same organ for
nearly 150 million years, a scenario without precedent in
tetrapod evolutionary history.
Furthermore, neck elongation was a long-term evolutionary trend not just within Sauropoda, but also along the
entire archosaurian lineage leading to this clade. The clades
Ornithodira, Saurischia, Sauropodomorpha and Sauropoda
are all characterized by having longer necks than their
immediate outgroups (Gauthier, 1986; Sereno, 1991; Wilson
& Sereno, 1998). The evolution of even longer necks in
Journal of Zoology 285 (2011) 150–161 c 2011 The Authors. Journal of Zoology c 2011 The Zoological Society of London
157
Sauropod necks were not sexually selected
various sauropod lineages must be understood within the
framework of this evolutionary history, which extends even
farther back into the Triassic than that of sauropods alone,
and which encompasses many more species. The notion of
sexually selected neck elongation persisting throughout this
sequence of clades is yet further removed from anything that
has been observed in other groups, and as an outlier its
credibility is further undermined.
Although there is no long-lived or speciose tetrapod clade
that has consistently sexually selected for a single feature,
there are a few such invertebrate clades. For example,
among insects, sexual dimorphism in Diopsidae (stalk-eyed
flies) has been described from Eocene Baltic amber (Kotrba
2004), and the pincer-like cerci of Dermaptera (earwigs)
evolved in the Early Jurassic (Grimaldi & Engel 2005: fig.
7.50). It is not clear why this disparity in the persistence of
single sexually-selected features exists between insects and
tetrapods. It might be connected with the vast differences in
biomechanics and life history between the two clades, or
with the persistence of certain body forms in the clades
themselves – hardly any tetrapods have persisted essentially
unchanged since the Early Jurassic, as have earwigs. Nevertheless, the absence of such long-term (i.e. 150+ million
years) sexual selection in tetrapods casts doubt on the
hypothesis of sexual selection as the primary driver of neck
elongation in sauropods, which retained essentially the same
body form from the Late Triassic through the Late Cretaceous, a span of almost 150 million years.
M. P. Taylor et al.
little predictive power as allometric growth is very common
in animals whether or not sexual selection is at work.
6. The finding that sauropod neck length does not correlate
strongly with leg length is skewed by the over-representation
of the bizarrely long-necked and morphologically uniform
mamenchisaurids, and there are anatomical reasons why
sauropods might have favoured lengthening necks rather
than legs in order to increase vertical reach.
The proposal that the necks of sauropods – a speciose,
morphologically varied clade spanning 150 million years –
evolved due to the persistent action of sexual selection on a
single part of the body is not paralleled by sexual selection in
any tetrapod clade that is remotely comparable in diversity,
disparity or longevity.
The idea that sauropod necks were the result, fully or in
part, of sexual selection is novel and should not be dismissed
out of hand. However, evidence that might support this
hypothesis is lacking and we find no compelling support for
the idea. Further research and improved tests may yet reveal
the nature of selection acting on the sauropod neck, but at
the moment there is no convincing evidence supporting the
hypothesis that long necks in sauropods were sexually
selected, and several reasons to accept the traditional hypothesis that their necks evolved primarily due to the
feeding benefits that they conferred. The traditional model
fits well with the fossil evidence, so far as that is informative,
and it is supported by behaviour observed in extant analogues. In the absence of credible alternatives, it must remain
the null hypothesis for the evolution of long necks in
sauropods.
Conclusion
The assumption that sexual selection and feeding benefit are
mutually exclusive mechanisms in accounting for the evolution of the long necks of sauropods is mistaken. The
inspiration for the sexual selection hypothesis – the proposal
that the length of the giraffe neck predominantly resulted
from sexual selection pressure (Simmons & Scheepers, 1996)
– is at best controversial, and further study has shown it
likely that giraffe’s necks evolved under the pressure of
ecological competition.
Revisiting the six predictions used to evaluate whether
sauropod necks were sexually selected, we find that:
1. There is no statistical evidence for sexual dimorphism in
the necks of sauropods, but what anecdotal evidence we do
have indicates that it was absent.
2. It is impossible to determine whether sauropod necks
were used in dominance or courtship displays, but what little
evidence there is (e.g. absence of skull thickening) suggests
that they were not.
3. The long necks of sauropods provided significant survival benefit, both in access to higher browse and in energetically efficient feeding at ground level.
4. The survival cost imposed by the long necks of sauropods
was probably less than has been proposed, and was likely
outweighed by the survival benefits.
5. Although there is evidence that sauropod necks were
positively allometric through ontogeny, this observation has
158
Acknowledgements
We thank S.A. Hartman for supplying a high-resolution
version of his skeletal reconstruction of Apatosaurus louisae,
R.J. Knell and an anonymous reviewer for providing helpful, constructive and very timely reviews and I.C. Cuthill for
discussion on mutual sexual selection. D.W.E.H. was supported in part by grants from the Chinese Academy of
Sciences.
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