6 NOVEMBER 2009    VOL 326    SCIENCE    www.sciencemag.org 
808
PERSPECTIVES
Evolution of Animal Pollination
PALEONTOLOGY
Jeff Ollerton and Emma Coulthard 
Animals pollinated specialized seed plants even 
before ? owering plants evolved.
 T
he evolution of animal pollination in 
? owering plants (angiosperms) and 
the resulting coevolution and diver-
si? cation of both angiosperms and major 
pollinator groups during the late Cretaceous 
(99.6 to 65.5 million years ago) is one of the 
classic stories of evolutionary biology ( 1). 
On page 840 of this issue, however, Ren et 
al. ( 2) challenge aspects of this story and 
hint at a much more complex ecological 
scenario for the evolution of plant-pollina-
tor relationships.
An important feature of the traditional 
story is that the non-angiosperm seed plants 
living during the Mesozoic (251 to 65.5 mil-
lion years ago) were mainly wind-pollinated. 
Although the fossil record of these plants 
shows evidence of possible animal pollina-
tion as early as the late Carboniferous (320 
to 300 million years ago) ( 3), this evidence 
is open to interpretations of the size of pol-
len grains (apparently too large to be wind-
dispersed), the possibly attractive function of 
reproductive organs, and patterns of damage 
by insects. The assumption is that although 
animal pollination may predate the evolution 
of the ? owering plants, it was rare and unspe-
cialized relative to what was to follow in the 
late Cretaceous ( 4).
Ren et al. now marshal evidence from an 
impressive range of sources?from compara-
tive morphology of fossil insect mouthparts 
to elemental analysis of the fossils and their 
surrounding matrix?to propose that a previ-
ously overlooked group of Mesozoic scorpi-
on? ies was able to feed on a nectarlike ? uid 
( 5) produced by a group of now-extinct non-
angiosperm seed plants. The authors suggest 
that the scorpion? ies in turn pollinated the 
plants. This may be the earliest known exam-
ple of coevolution between plants and polli-
nators. The evidence that Ren et al. present 
is compelling, and if they are correct, it will 
change our understanding of the early ecol-
ogy and evolution of pollination by insects.
As Darwin ( 6) famously recognized when 
he speculated about the coevolution of ? ower 
and tongue length between the Madagascan 
orchid Angraecum sesquipedale and its (then 
unknown) moth pollinator, ? owering plants 
have often evolved tubular structures that 
hold nectar or protect reproductive organs. 
The plants can thus discriminate between 
? ower visitors, enabling them to specialize on 
pollinators with appropriately sized mouth-
parts ( 7,  8). This match between mouthparts 
and ? ower depth ( 9) facilitates more accurate 
pollen placement, meaning that less pollen is 
wasted, and prevents nonpollinating animals 
from robbing nectar. It may be a major fac-
tor driving the diversi? cation of some angio-
sperm genera ( 8) and structuring the patterns 
of interaction with pollinators in plant com-
munities ( 10), but until Ren et al.?s study, it 
was considered unimportant in non-angio-
sperm pollination.
The 11 scorpion? y species described by 
Ren et al. have mouthparts that are both rela-
tively long and consistent with ? uid feeding 
by sucking. The species represent three dif-
ferent families, pointing to repeated conver-
gent evolution of this feeding strategy, which 
in turn suggests that substantial quantities of 
nectarlike ? uid ( 5) were available to these 
taxa. Ren et al. believe that the source was a 
group of non-angiosperm seed plants belong-
ing to diverse, and mostly extinct, lineages. 
All these species have repro-
ductive organs that are poorly 
adapted to wind pollination 
(the previously presumed mode 
of reproduction for these taxa). 
Wind pollination requires that 
pollen-receptive areas are easily 
accessible to windborne pollen, 
which is clearly not the case for 
these plants. Pollen transfer by 
insects thus seems most likely, 
and the scorpion? ies are the best 
candidates so far identi? ed.
Some will ? nd these claims 
controversial, particularly as a 
key piece of evidence is miss-
ing: The authors failed to ? nd 
any pollen associated with these 
fossils. This is especially sur-
prising for the amber-encased 
insects, where pollen preserva-
tion would be expected ( 11). 
Absence of evidence is not, 
however, evidence of absence, 
and further fossils may provide 
this information.
Biotic pollination was the 
dominant angiosperm pollina-
tion strategy by the late Cre-
taceous ( 12). Ren et al.?s research tests old 
notions that angiosperms evolved in a pre-
dominantly wind-pollinated world. Further-
more, it challenges us to rethink assumptions 
that early pollinators were short-tongued gen-
eralists that could only exploit open ? owers 
with easily accessible nectar. Living repre-
sentatives of the earliest diverging flower-
ing plants have a diverse range of pollination 
systems ( 13), and many are far from general-
ized in their interactions with pollinators. The 
presence of long-tongued pollinating scorpi-
on? ies both before and at the same time as the 
? rst angiosperms allows us to imagine that 
? owering plants evolved deep ? owers early in 
their radiation, coexisting with open, general-
ist ? owers and gymnosperms as part of a spe-
cialist-generalist spectrum similar to modern 
plant communities ( 14).
Can modern assemblages of plants and 
pollinators be viewed as analogous to their 
Mesozoic counterparts, at least in terms of 
functionality, if not phylogenetic identity? 
Other Mesozoic insects have been suggested 
to be ? uid-feeding pollinators ( 15,  16), and if 
this is so, then the scorpion? ies described by C
R
E
D
I
T
:
 
E
M
M
A
 
C
O
U
L
T
H
A
R
D
/
U
N
I
V
E
R
S
I
T
Y
 
O
F
 
N
O
R
T
H
A
M
P
T
O
N
Landscape and Biodiversity Research Group, School of 
Applied Sciences, University of Northampton, Park Cam-
pus, Northampton NN2 7AL, UK. E-mail: jeff.ollerton@
northampton.ac.uk
Ancient legacy. Mesozoic scorpionflies (Mecoptera) probe the 
female reproductive organs of Leptostrobus cancer, a member of 
the extinct order Czekanowskiales. Modern scorpion? ies are much 
less diverse than their Mesozoic antecedents. Although they only 
rarely visit ? owers, this habit may be overlooked in modern species 
and could be a legacy of their distant ancestors.
Published by AAAS
 
o
n
 N
ov
em
be
r 6
, 2
00
9 
w
w
w
.s
ci
en
ce
m
ag
.o
rg
D
ow
nl
oa
de
d 
fro
m
 
www.sciencemag.org    SCIENCE    VOL 326    6 NOVEMBER 2009
809
PERSPECTIVES
Ren et al. were probably part of a larger fauna 
of insects visiting plant reproductive struc-
tures. The Mesozoic Era was biotically richer 
and more complex than previously realized. 
Studies such as that by Ren et al. provide a 
tantalizing glimpse of lost worlds of interac-
tions between partners that are now extinct or 
considerably less diverse. 
References
 1. M. Proctor, P. Yeo, A. Lack, The Natural History of Pollina-
tion (Timber Press, Portland, OR, 1996).
 2. D. Ren et al., Science 326, 840 (2009).
 3. W. L. Crepet, Bioscience 29, 102 (1979).  
 4. W. L. Crepet, Rev. Palaeobot. Palynol. 90, 339 (1996).  
 5. M. Nepi et al., Ann. Bot. 104, 205 (2009).  
 6. C. Darwin, On the Various Contrivances by Which British 
and Foreign Orchids are Fertilised by Insects, and on the 
Good Effects of Intercrossing (John Murray, London, 1862).
 7. J. Ollerton, S. Liede, Ecotropica 9, 107 (2003).
 8. J. B. Whittall, S. A. Hodges, Nature 447, 706 (2007).  
 9. A. Pauw et al., Evolution 63, 268 (2009).  
 10. M. Stang et al., Ann. Bot. 103, 1459 (2009).  
 11. S. R. Ramirez et al., Nature 448, 1042 (2007).  
 12. S. Hu et al., Proc. Natl. Acad. Sci. U.S.A. 105, 240 (2008).  
 13. L. B. Thien et al., Am. J. Bot. 96, 166 (2009).  
 14. N. M. Waser, J. Ollerton, Eds., Plant-Pollinator Interac-
tions: From Specialization to Generalization (Univ. of 
Chicago Press, Chicago, 2006).
 15. D. Ren, Science 280, 85 (1998).  
 16. C. C. Labandeira et al., Taxon 56, 663 (2007).
10.1126/science.1181154
Capturing the Complexities
of Molecule-Surface Interactions
CHEMISTRY
Eckart Hasselbrink 
 T
he simplest picture of a chemical reac-
tion is that two molecules approach, 
climb a potential energy barrier as 
bonds get pulled apart in the transition state, 
and then separate, forming the new products. 
Molecules move in three dimensions and have 
internal motions such as vibrations, so a quan-
titative model requires molecules to move over 
a potential energy surface ( 1). Two reports in 
this issue address the added complexities that 
result when one of the reactants is a metal sur-
face (see the ? gure). On page 829, Shenvi et 
al. ( 2) describe a method for the quantitative 
evaluation of one of the open questions in 
modeling these reactions: How is energy dis-
sipated as the molecule approaches the metal 
surface? On page 832, D?az et al. ( 3) present 
a pragmatic ? x for the problem of calculat-
ing the potential energy surface that describes 
how molecular hydrogen (H
2
) reacts with an 
atomically ? at copper surface. Their approach 
allows almost every aspect of the experimen-
tal ? ndings for this system to be reproduced.
For reactions between small molecules in 
the gas phase, potential energy surfaces cal-
culated from ? rst principles (without using 
inputs from experiments) have become quite 
successful in predicting product formation 
( 4). However, for the more complex case 
of molecules interacting with a metal sur-
face?which is of interest for understand-
ing reactions in industrial catalysts?getting 
the calculations to agree with experiment is 
much more challenging, because the system 
to consider is extended and because energy 
dissipation to electronic excitations may 
become important ( 5).
Modeling a chemical reaction is typically a 
two-step process. First, the interaction energy 
of the reactants is calculated for various geo-
metric arrangements and then used to cre-
ate the potential energy surface. The latter is 
then the basis for the calculation of the dynam-
ics?that is, how the reactants will move and 
exchange energy until the products are formed. 
These analyses can be used to calculate reac-
tion probabilities for real systems, where the 
molecules have a distribution of energies.
This two-step procedure rests on the thesis 
work of Robert Oppenheimer: the so-called 
Born-Oppenheimer approximation (BOA), 
which allows calculations of electronic energy 
independent of the motion (such as bond 
vibrations) of the much heavier nuclei ( 6). 
This approximation has been very successful 
for predicting molecular structures and reac-
tion dynamics between molecules. However, 
the interaction with a metal surface is a partic-
ularly problematic case for applying the BOA 
because metals have a continuous electronic 
excitation spectrum, not discrete energy levels 
like single atoms and molecules.
It has been rigorously shown that the inter-
action of a molecule with a metal surface must 
dissipate energy into substrate electronic exci-
tations; processes that dissipate energy in this 
way are called nonadiabatic ( 7? 9). However, it 
is still not established how to predict the mag-
nitude of this energy, and the error introduced 
by the BOA, for a particular reaction system. 
The steadily increasing number of experimen-
tal studies that have reported evidence of non-
adiabatic behavior emphasizes the need to 
understand the error created by the BOA [see 
( 10) and references therein].
Shenvi et al. present a method that allows 
a quantitative account of nonadiabaticity and 
apply it to the particular case of a nitric oxide 
(NO) molecule scattering off a gold surface. 
They use data from a sophisticated experiment 
as a benchmark for their theoretical study. 
Wodtke and co-workers prepared NO mol-
ecules in a highly vibrationally excited state 
by means of laser techniques and observed 
that it loses vibrational energy several quanta 
at a time in the collision ( 11). Their experi-
mental data are only consistent with a non-
adiabatic coupling mechanism. An adiabatic 
model for this interaction would predict that 
the molecules scatter from a metal surface 
with the vibrational excitation intact, because 
the vibrational frequency is not in resonance 
with the vibrations of the surface atoms or the 
molecule-surface bond.
The vibrational motion of the NO mole-
cule is connected with an oscillating shift in 
electronic energy for adding one more elec-
tron to the NO molecule. The vibrational 
motion is hence connected with an oscillat-
C
R
E
D
I
T
:
 
P
.
 
H
U
E
Y
/
S
C
I
E
N
C
E
Fakult?t f?r Chemie and Center for NanoIntegration, Uni-
versit?t Duisburg-Essen, 45117 Essen, Germany. E-mail: 
eckart.hasselbrink@uni-due.de
When molecules meet surfaces. The inter-
action of a molecule with a metal surface 
provides a challenge for the most sophis-
ticated molecular structure calculations. 
Theory is rapidly moving toward a quanti-
tative account of how molecules scatter off 
surfaces, as discussed by Shenvi et al., or 
react and form bound surface species, as 
discussed by D?az et al.
Two large computational studies describe
how theory can better account for the way
in which molecules scatter from or react
with metal surfaces.
Published by AAAS
 
o
n
 N
ov
em
be
r 6
, 2
00
9 
w
w
w
.s
ci
en
ce
m
ag
.o
rg
D
ow
nl
oa
de
d 
fro
m