Lucas, S. G., Kirkland, J. I. and Estep, J. W., eds., 1998, Lower and Middle Cretaceous Terrestrial Ecosystems. New Mexico Museum of Natural History and Science Bulletin No. 14.   I H C 
THE ROLE OF INSECTS IN LATE JURASSIC TO MIDDLE CRETACEOUS ECOSYSTEMS 
CONRAD C. LABANDEIRA 
Smithsonian Institution, National Museum of Natural History, Department of Paleobiology, Washington DC 20560; 
and University of Maryland, Department of Entomology, College Park MD 20742 
ABSTRACT: The relationships between insects and other organisms in the Late Jurasic to 
Middle Cretaceous ecosystems is documented in the f ossU record by generalized to highly host- 
specific vasailar plant and insect associations, and to a much lesser extent by plant-fungal-insect 
and tetrapod-insect associations. Vascular plant and insect associations are essentialy modem 
during this interval, and consist of external foliage feeding, leaf mining, galling, v^rood boring, 
piercing-and-sucking, sporivory and pollinivory, nectarivory, and pollination sjmdromes. Late 
Jurassic versions of all these interactions occurred on a diverse repertoire of major 
gymnospermous plant clades (angiosperms excepted) whereas by the end of the Middle 
Cretaceous most of these interactions had been transferred onto angiosperms either by descent 
from gymnospermous ancestors or by direct host transfer. Examples of these host-plant shifts 
include generalized external foliage feeding, probable host-specific leaf mining, galling, 
pollinivory, and nectarivory. While most of these associations did not persist to the present, there 
is evidence that relict, primitive insect lineages survived as intimate herbivores today on host- 
plant taxa with Late Jurasic to Middle Cretaceous ancestors, notably cycads and primitive 
dicotyledonous angiosperms. 
INTRODUCTION 
Terrestrial ecosystems underwent a dramatic transformation 
during the interval encompassing the Late Jiuassic to the Middle 
Cretaceous. Foremost among this change was the turnover, at the 
highest taxonomic levels, of plant clades, so that, by the end of the 
Middle Cretaceous, at 88 Ma, angiosperms had largely replaced 
other major clades of vascular plants, with the principal 
exceptions of cool-temperate coniferous forests and local sites rich 
in ferns or gymnospermous plants (Parker, 1976; Wing et al., 
1993). By the end of the Cretaceous, mid-Mesozoic clades such as 
bennettitaleans, cheirolepidaceous conifers, and several lineages 
of seed ferns were extinct, and others that have extant 
representatives, such as gingkoaleans, gnetaleans and cycads, 
survived at decreased levels of diversity. This shift in ecosystem 
composition also characterized major tetrapod lineages, notably 
dinosaurs, in which a Late Jurassic fauna dominant in large 
sauropods, basal theropod clades, and omithischian stegosaurids 
gave way to a Lower Cretaceous fauna of few sauropods, and 
considerably more omithischians such as omithopods (e.g., 
hypsUophodontids and iguanodontids). Later during the 
Cretaceous, advanced carnivorous theropods, a plethora of 
omithischian groups?especially ceratopsians, hadrosaurs and 
pachycephalosaurs?diversified and dominated the terrestrial 
megafaima. This taxonomic shift was perhaps induced by an 
angiosperm-dominated flora, indicated by dental specialization. 
Unlike the important turnover in major plant and tetrapod 
taxa during this interval, and the drastic pattern of extinction 
affecting many groups at the terminal Cretaceous, insects had a 
considerably subtler pattern. Major clades of modem insects 
(orders to superfamUies) mostly originated during the Triassic, or 
less commonly were holdovers from the Permian that have 
persisted to the present, irrespective of major shifts in vascular 
plant and tetrapod taxonomic composition. The probable 
exceptions of Mantodea (mantids) and Isoptera (termites) are 
noteworthy, both which many now consider as subgroups of 
cockroaches (Grimaldi, 1997; Klass, 1997, 1998; but see 
Kambhampati, 1996). Unfortunately ecto- and endoparasitic 
groups such as the Phthiraptera (lice), Strepsiptera (stylopids) and 
Siphonaptera (fleas) have very poor fossil records and are not 
known for certain in pre-Cenozoic deposits (Traub, 1980; Kim, 
1988; Kathiri??amby and Grimaldi, 1993; Poinar, 1995). 
Nevertheless, many modem insect families originated during the 
Mesozoic (Labandeira, 1994), although some recent studies 
indicate that this pattern does not extend to infrafamilial taxa, 
such as subfamilies and tribes, many Mesozoic examples of which 
are apparently extinct. (However, see Lawrence [1995] and 
Rasnitsyn [1997] for examples of recen?y discovered modem taxa 
previously known only as extinct fossus). 
It is fortunate that, in addition to the insect body-foss? record, 
there are parallel data of trace fossus?especially vascular plant- 
and-insect associations, but also rare insect-cind-tetrapod 
interactions. These associational data docvunent the often intricate 
ecological relationships between insects and vascular plants and 
less commonly insects and tetrapods. Although limited to well- 
preserved deposits and spotty in temporal distribution, such data 
provide a unique glimpse into the minor components of 
ecosystem structure that is rarely available by more indirect 
means, such as recent analogs or functional analysis of organismic 
structures. The scope of such associational data includes plant 
damage, insect gut contents, floral features tied to insect use, 
insect mouthpart structure and patterns of hair and setae 
distribution (vestiture), and special insect struchores that 
accommodate plant products, such as antermal scrobes and leg 
corbiculae for housing fungal spores and pollen, respectively 
(Labandeira, 1997,1998b). These data will be emphasized in this 
contribution, rather than a descriptive narrative portraying the 
succession of Late Jurassic to Middle Cretaceous insect faunas. 
The fundamental, albeit overly ambitious, questions addressed 
herein is "What were the effects between insects and other 
organisms during this interval?" and "How did these roles 
106 
contribute to the evolving structure of Mesozoic ecosystems?" 
THE RELEVANT FOSSIL RECORDS 
A perusal of the relevant literature on the associations of fossil 
insects with other organisms reveals that, like the amount of 
biomass participating in trophic levels within terrestrial 
ecosystems, the further the trophic distance from primary 
production, the less the docvunentation. Thus, Figure 1 has four 
times more literature sources and considerably more reliable data 
on vascular plant-insect associations than it does for 
insect-tetrapod associations. Because vascular plants are a 
relatively ubiquitous part of the terrestrial fossil record in terms 
of frequency of occurrence and abundance, they provide a 
desirable opportunity for scrutinizing insect interactions during 
long stretches of geologic time. By contrast, the vertebrate fossil 
record is significantly more degraded and provides a weak signal 
for associations with insects. Historically adding to this de- 
emphasis has been lack of docvunentation by vertebrate 
paleobiologists of premortem or postmortem insect damage to 
bone tissue. 
Vascular Plants 
Late Jurassic floras are dominated by gymnospermous seed 
plants, and to a lesser degree pteridiphytes. Some of the best 
described Late Jurassic plant assemblages are of Kimmeridgian 
age, from the French Jura Mountains (Barale, 1981) and the 
lacustrine shales at Karatau, in southeasem Kazakst?n 
(Doludenko and Orlovskaya, 1976). The French material, 
consistent with a marginal marine lagoonal setting, consists of 
diverse cycads, bennettitaleans, conifers and ferns, and rare 
gingkocileans; the Kazakstani material is dominated by 
beimettitaleans and conifers, contains subdominant cycads and 
gingkoaleans, and rare czekanowskialeans. The paucity of well- 
described Jiurassic floras in North America is striking; one of the 
best documented is the Late Oxfordian to Early Kimmeridgian 
Monte de Oro flora of north-central California (Vakhrameev, 
1988), characterized by mostly cycads and subdominant 
beimettitaleans and iems. The vegetation of the Tithoi?an 
Morrison Flora from the Rocky Mountains has been reconstructed 
as widely scattered conifers and more closely-spaced 
beimettitaleans occurring among cycads and ferns, and rare 
caytonialean seed ferns and gingkoaleans (Miller, 1987). By 
contrast, a probable Late Jurassic Nipania Flora from India 
consists dominantly of pentoxylaleans and conifers, with rare 
ferns, and notably, bennettitaleans are "conspicuous" by their near 
absence (Shah, 1977). 
Early Cretaceous (Neocomian) macrofloras are almost entirely 
dominated by gymnospermous and pteridiphyllous plants, 
although angiospermous pollen is known in paleoequatorial 
regions at the end of this interval (Brenner, 1976). Angiosperm 
pollen assemblages, eventually including macrofloral remains, 
gradually expand poleward throughout the later Early and 
Middle Cretaceous (Retallack and Dilcher, 1981; Lidgard and 
Crane, 1990; Drinnan and Crane, 1990). However, most Early 
Cretaceous floras lack angiosperms?even those as 
stratigraphically high as the upper Aptian Kootenai Flora of 
Montana, which was dominated by ferns, caytonialean seed ferns 
and conifers, with rare Gingko and bennettitaleans. The 
Koonwarra flora of Australia, of similar age, contains only one 
angiosperm pollen species out of 62 known taxa (Dettman, 1986), 
and one of the earliest known angiosperms has been described as 
an inflorescence from this deposit (Taylor and Hickey, 1990). 
Typical of the worldwide floristic heterogeneity of the Early 
Cretaceous is the well-known Weald Flora of Britain, 
reconstructed by Batten (1974) and Oldham (1976) as savanna-Hke 
vegetation with open forest containing relatively tall conifers and 
gingkoaleans and arborescent seed ferns of lower-stature, all 
interspersed among a pteridophyte ground layer. 
During the early Albian, angiosperm macrof ossUs entered the 
fossil record in some equatorial floras, initially as small-leafed 
morphs with irregular venation, representing weedy herbaceous 
or shrubby vegetation (Vakhrameev, 1964; Hickey and Doyle, 
1977). During the middle to late Albian, additional large-leafed 
angiosperms with more ordered venation became more abundant, 
representing a variety of growth forms in disturbed habitats of 
riparian commimities. By early Cenomanian time, lowland sites 
were dominated by diverse magnoliid, hamamelid, rosid and 
other angiosperms (Crabtree, 1987; Lidgard and Crane, 1990), at 
least in the Northern Hemisphere. The poleward migration of 
angiosperms from the equator to mid- and high-latitude floras 
took approximately 20 to 30 million years (Wing and Sues, 1992). 
The best studied early Middle Cretaceous flora is the Dakota 
Flora, best preserved in Kansas and Nebraska, collectively 
consisting of at least 400 species of vascular plcints (Dilcher, pers. 
comm.), including herbs, shrubs and trees. 
Tetrapods 
Because the focus of this voltune is predominantly on the 
Early and Middle Cretaceous vertebrate assemblages, only brief 
mention will be made of the Late Jurassic to Middle Cretaceous 
tetrapod succession. During the Late Jurassic, tetrapod faimas 
were dominated by gigantic, long-necked sauropods and 
primitive omithischians, mostiy herbivorous stegosaurs, bipedal 
camptosaurs and hypsilophodonts, and reptiles such as tur?es, 
sphenodontians and lizards. Some of the earliest lineages of birds 
and mammals are known from this interval. During the Early 
Cretaceous, tetrapod faunas became differentiated between the 
northern and southern hemispheres (Bonaparte, 1990). In the 
Northern Hemisphere, Late Jurassic assemblages were replaced 
by ankylosavus, larger-bodied omithopods with complex 
dentition (especially hadrosaurs), the earliest ceratopsians, 
sphenodontian lepidosaurs, multituberculate mammals, and an 
early radiation of bird lineages. By contrast. Early Cretaceous 
assemblages of the Southern Hemisphere contained holdovers 
such as gigantic sauropods, many endemic taxa, and a rarity of 
hadrosaurid omithopods and placental mammals (Bonaparte, 
1987; Wing and Sues, 1992). Middle Cretaceous tetrapod faunas 
were characterized by more diverse and dentally specialized 
omithischians and theropods. 
Insects 
In the context of a Phanerozoic geochronology and a modem 
taxonomic framework. Late Jurassic to Middle Cretaceous insects 
have a modem cast. The most profound event during the 400 
million year fossil record of insects was the end-Permian 
extinction and associated earlier Permian replacements, during 
which there was major taxonomic turnover in insect diversity, 
and after which was a steep drop in the origination of orders and 
the commencement of post-Paleozoic family-level originations 
that  constitute  the  principal  insect  taxa  recognized  today 
107 
(Labandeira and Sepkoski, 1993; Jarzembowski and Ross, 1996). 
Thus, the Paleozoic insect fauna is distinct from the post-Paleozoic 
modem insect fauna at the highest taxonomic levels (Labandeira, 
1999b), and those Paleozoic taxa that survived the end-Permian 
event became a relatively minor component of the modem insect 
fauna. Of these, three families of the Paleozoic orders Miomoptera 
and Glosselytrodea survive into the Early Jurassic, one of which, 
the Polycytellidae, into the Late Jurassic (Labandeira, 1994). The 
Geraridae of the polyphylet?c "Protorthoptera" is recorded in the 
Middle Triassic, and the paraphyletic stem-groups "Hypoperlida" 
and "Paratrichoptera" have single families extending into the 
Middle Triassic and Early Cretaceous, respectively (Labandeira, 
1994). The Blattodea sensu Grimaldi (1997) comprises a related 
assemblage of taxa, including roaches (Blattoidea), termites 
(Isoptera) and mantids (Mantodea), whose fossil record 
historically has been difficult to interpret, because pre-Cretaceous 
roaches bear prominent ovipositors (Vishniakova, 1973), whereas 
Cretaceous to Recent roaches lack them and deposit eggs in cases 
known as o?thecae. Related to this issue is the absence of termites 
and mantids in pre-Cretaceous deposits (but see Hasiotis and 
Demko, 1996). Although the extension of three Paleozoic-aspect 
cockroach families into the Late Jurassic to Late Cretaceous 
suggests prolonged evolutionary stasis, the absence of any 
o?thecate cockroaches, mantids or termites in pre-Cretaceous 
deposits indicate that a radiation of these taxa probably occurred 
during the Late Jurassic. 
The insect body-fossil record is relatively rich during the Late 
Jurassic to Middle Cretaceous (Fig. 1), and is comparable to the 
coeval vascular plant record and superior to the vertebrate record 
in abundance and frequency in occurrence of taxa. Insect-yielding 
deposits during this time interval typically consist either of 
compressions and impressions occurring as lacustrine fluvial, 
deltaic, and lagoonal fine-grained, laminated shales and 
limestones bordering lowland water bodies (Zherikhin, 1978; 
Sinichei?cova and Zherikhin, 1996), or as placer or in situ amber 
deposits representing woodland and forest environments (Schlee 
and Glockner, 1978; Grimaldi, 1996). However, these two 
distinctive and major taphonon?c modes are not distributed 
evenly during this interval (Fig. 1): while fine-grained elastic 
deposits are globally widespread and abundant, occurring 
throughout this 70-million-year interval, amber deposits are 
confined to approximately six well-known deposits in the upper 
45-million-year portion of this interval, and essentially sample 
forested habitats of the Northern Hemisphere. One 
taphonomically distinctive deposit type that has a geochronologic 
window occurrence that corresponds almost exac?y to the Late 
Jurassic to Middle Cretaceous are lithographic limestones 
(Labandeira, 1999a). Lithographic limestones represent lagoonal 
environments of quiet and brackish water marginal to marine 
deposits, and include major Lagerst?tten such as the Solnhofen 
Formation of southern Germany (Barthel et al., 1994), Santana 
Formation of Cear?, northeastern Brazil (Grimaldi, 1990; Maisey, 
1991), and the Caliza con Carac?as Formation of northeastern 
Spain (Martmez-DelcHs, 1991a). Notably, these and other major 
Late Jurassic to Middle Cretaceous deposits?including the Yixian 
Formation of Liaoning, northeastern China (Ren et al., 1995), 
Korumburra Group of Victoria, southeastern Australia Qell and 
Duncan, 1986), several adjacent localities from southwestern 
Mongolia (Rasnitsyn, 1986), and the Zaza Formation at Baisa, in 
Transbaikalian Russia (Rasnitsyn, 1990)?have been explored 
intensively during the past two decades, resulting in major 
increases in imderstanding of global insect paleobiology. 
Additionally, there has been continued description of taxa from 
earlier known deposits such as Karatau in southern Kazakst?n, 
and Magadan in central Russia. 
Several major phylogenetic events of insects had a major 
impact on Late Jurassic to Middle Cretaceous ecosystems and 
shaped the taxonomic character of the global insect fauna that 
persists today. These events can be encapsulated by four major 
radiations transpiring during the Middle to late Jurassic, and 
another four radiations occurring during the Late Jurassic to Early 
Cretaceous. The earlier Jurassic events are: (1) the expansion of 
hemipteran bugs into lotie and lentic aquatic habitats (Popov, 
1971), a radiation that postdated the earlier invasion of freshwater 
by nematocerous Diptera (Wootton, 1988; Labandeira, 1997); (2) 
the diversification of cucujoid beetle groups, notably plant- 
feeding chrysomeloid and curculionoid lineages onto 
gymnospermous plants (Crowson, 1991; Ponomarenko, 1995; 
FarreU, 1998); (3) ?ie basal radiation of brachycerous fly clades, 
some of which developed pollination mutualisms, initially with 
gymnosperms (Labandeira, 1998a), and subsequen?y on early 
angiosperms (Dilcher, 1996, but see Ren, 1998a); and (4) the 
proliferation of parasitoid apocritan wasp clades (Rasnitsyn, 
1988a), resulting in taxa that invaded live insect and tetrapod 
hosts as larvae, and adults that probably were nectar-feeders and 
assisted the pollination of seed plants and later angiosperms 
(Hespenheide, 1985; Jervis, et al., 1993). 
During the Late Jurassic to Early Cretaceous, there was further 
co-optation of seed plants in several respects, probably including 
angiosperms during the later phases of this interval. The 
previously mentioned radiation of blattodean clades (5) probably 
resulted in the first example of insect sociality, in termites, and a 
co-ordinate major invasive of xylic substrates (WUson, 1971), a 
phenomenon that was soon followed by the advent of bees (6) 
which evidently were derived from sphecoid wasps (Brothers, 
1975) and subsequen?y became intimately involved as pollinators 
of angiosperms; (7) the radiation of major lepidopteran 
subgroups, involved overwhelmingly in endophytic consumption 
of gymnospermous and angiospermous seed plants (Thien et al., 
1985; Labandeira et al, 1994; Davis, 1994); and finally (8) the 
multiplication of cyclorrhaphan fly lineages from a brachyceran 
ancestor (Sinclair, 1994), resulting in penetration of live and dead 
vertebrate hosts, and the occupation of moist habitats involving 
decomposing plant and fungal detritus (Oldroyd, 1964). After the 
conclusion of these important insect radiations sometime during 
the Middle Cretaceous, the major, insect-related features were 
essentially established (Jarzembowski, 1995; Labandeira, 1997), 
with the possible exception of derived modes of insect pollination 
of angiosperms, which progressed during the Late Cretaceous 
and Paleogene with the appearance of specialized flowers 
(Willemstein, 1987; Crepet and Fr?s, 1997). 
ASSOCIATIONS OF INSECTS WITH OTHER ORGANISMS 
Much of the paleoecology of insects and other organisms is 
revealed in the trace-fossil record of insect-mediated damage, 
both as tissue response to invasive trauma when the host was 
alive, as well as detritivorous patterns of tissue consumption after 
death. While the Late Jurassic to Middle Cretaceous fossil record 
of vascular plant-insect and insect-tetrapod associations is not as 
bountiful as either the Late Carboniferous or Paleogene intervals 
(Labandeira, 1999b), there is, nevertheless, sufficient primary 
evidence for documenting major interactions between insect 
108 
culprits and their plant targets (Figs. 1-4). Presently, only a herbivorous insect species on extant vasciilar plants are mono-or 
tentative glimpse of associations between insects and their oligophagous (Futuyma and Mitter, 1996), and many of those 
tetrapod hosts is available, primarily ectoparasitism and blood- consume only a particular tissue type, such as the abaxial palisade 
feeding.  Lastly,  there  are  imphcations  in a  few  of these layer by a leaf-mining moth larva or the consumption by an 
interactions for the role that fimgi played in the mediation of encapsulated gall midge larva of nutritive tissue that is produced 
plant decomposition by insects. by its host plant (Hering, 1951; Meyer, 1987). These and other 
interactions, such as external foliage feeding, leave distinctive, 
Plant-Insect Associations often   highly   stereotyped,   patterns   of   damage   on   plant 
.       .        ?    ,.    ,                         ? .    ,1                  ,.,-1, organs?features of which are eminently preservable in the fossil Insects  coUectavely  consume  virtually  any  nutritionally ,    ^          , ,?.      - ^^ -n.          ^      /L i   i     -r.-   ^       r LL. 
..         ,   .         -'     ,         ,        ?   .1   .   j. ,               , . plant record (Figs. 2-3). The most useful classincation of these 
rewardmg substance, and nowhere is their dietary repertoire j            ^.^i./-^      i^j-                             i..-. 
..   ,.,     -   ,,   .         . j         . ^         .,1    1    ,  Hi   , damage types IS the functional-feedmg-group approach, which 
more manifest than m their mynad associations with plants. Most -i?    ?      ..i.   j                           ^ j  -r-    ?   ii               ^     j 
-'                                    ^ specines how the damage was created. Typically encountered 
FIGURE 1. Distribution of major insect deposits and associations between insects and plants and insects and reptiles during the Late Jurassic to 
Middle Cretaceous. Included are deposits and associations resolvable more-or-less to the stage-level placement, and their geochronological positions 
are approximate in many cases. Insect deposits are designated as striped bars for compressions and as gray bars for amber. Taxai ranges in the center 
and right panels are solid for well-established occurrences and dotted for unconfirmed data; similarly solid dots represent direct evidence for an 
association whereas unfilled dots represent indirect evidence. Geochronology is from Harland et al. (1990); taxa are from Cleal (1993a, 1993b) for 
plants and Benton (1993) for reptiles. 
Major insect deposits. Documentation and sources for major insect deposits are: 1, amber from the Raritan-Magothy Fm., Sayreville, New Jersey, 
USA (Grimaldi et al., 1989); 2, Beleytinskaya Fm., Kizyl Zhar, BCazakhstan (Kozlov, 1988); 3, amber from the Dolganskaya Fm., Agapa, Krasnoyarsk 
Oblast, Russia (Kalugina, 1992; Szadziewski, 1996); 4, unnamed mudstones at Orapa, Botswana (Rayner, 1993); 5, Steinkohle Fm., Jihocesky Region, 
Czech Republic (Fritsch, 1882; Fric, 1901); 6, amber from Durtal and Bezonnais, Maine-et-Loire Dept., France (Schl?ter, 1978); 7, Olskaya Fm., 
Magadan, Russia (Zherikin, 1978); 8, Dakota Fm., Kansas and Nebraska, USA (Upchurch and Dilcher, 1990; Labandeira et al., 1994); 9, Khetana, 
northeastern Russia (Ponomarenko, 1995); 10, Dalzai Fm., Jilin Prov., China (Lin, 1994); 11, Mogotuinsk Fm., Manlay, Omnogovy Region, Mongolia 
(Kalugina et al., 1980); 12, Grato Fm., Cear? State, Brazil (Grimaldi, 1990; Maisey, 1991); 13, Glushkovo Fm., Unda and Daia, Chita Prov., Russia 
(Kovalev and Mostovski, 1997); 14, Koonwarra Bed, Leongnatha, Victoria Prov., Ausfralia (Jell and Duncan, 1986); 15, Khurlit Fm., Bon Tsagan, 
Bayan-Khongor Aimak, Mongolia (Rasnitsyn, 1991); 16, amber from Chosi, Q?ba Prefect., Japan (Fujiyama, 1994); 17, Gurvan-Eren Fm., Bulgan 
Aimak, Mongolia (Rasnitsyn, 1988b); 18, Turga Fm., Semen, Chita Region, Russia (Eskov and Zonshtein, 1990); 19, amber from Golling, Austria 
(Borkent, 1997a); 20, Upper Weald Clay, Surrey, Britain (Jarzembowski, 1991); 21, Laiyang Fm., Shandong Province, China (Lin, 1994); 22, Calizas 
de la Hu?rguina, Las Hoyas, Cuenca, Spain (Mart?nez-Delclis and Nel, 1994); 23, Lower Weald Clay, Sussex, Britain (Jarzembowski, 1991); 24, amber 
from Jezzine and Dar-el-Baidha, Lebanon (Schlee and Dietrich, 1970); 25, Vinkinskaya Fm., Bolboia and Urtuya, Priarguisk Region, Russia (Rasnitsyn, 
1990); 26, Zaza Fm., Baisa, Buryat Prov., Russia (Rasnitsyn, 1986); 27, Schouchang Fm., Zhejiang, China (Lin, 1994); 28, Waldhuist Clay, Britain 
Qarzembowski, 1990); 29, Caliza con Carac?as Fm., Montsec, Lleida Prov., Spain (Martmez-Delclis, 1991a, 1991b); 30, Purbeck Beds, Dorset, England 
(Allen and Wimbledon, 1991); 31, Khotont, Ara-Khangai Aimak Mongolia (Lukashevich, 1996); 32, Ulan-Ereg Fm., Khoutin, Cenfral Gobi Aimak, 
Mongolia (Ponomarenko, 1997); 33, Yixian Fm., Liaoning Prov., China (Ren et al., 1995); 34, Dabeagou Fm., Hebei Prov., China (Lin, 1994); 35, 
Solnhofen Plattenkalk, Bavaria, Germany (Lambkin, 1994); 36, Todlito Fm., Warm Springs, New Mexico (Bradbury and Kirkland, 1968); 37, 
Nusplinger Plattenkalk, Westerberg, Germany (Schwiegert et al., 1996); 38, Karabastau Fm., Karatau, Chiment Oblast, Kazakhstan (Rohdendorf, 
1968a); 39, Udinskaya Fm., Mogzon, Chitinskaya Oblast, Russia (Kalugina and Kovalev, 1985). See also Rohdendorf (1957) Zherikhin (1978), 
Kalugina and Kovalev (1985), Rasnitsyn (1990) and Lin (1994) for additional Eurasian locality information. 
Plants. Occurrences of insect associations on major vascular plant dades from the Late Jurassic to the Middle Cretaceous interval, documented 
from the literature. Sources for insect-plant associations are: A, external feeding on fem foliage (Labandeira and Dilcher, 1993); B, stem borings in 
the fem Tempskya (Seward, 1924); C, coprolites with fern spores (Kampmann, 1983); D, nepticuloid leaf-mines on Pachypteris (Rozefelds, 1988); E, 
stem borings on Hermanophyton (Tidwell and Ash, 1990); F, inferred life-habit attributes of fossil chiysomelid and curculionoid beetles consistent 
with associations in co-occurring cycads (Crowson, 1991; Ponomarenko, 1995); G excavated galleries with frass within cones of Cycadeoidea 
(Delevoryas, 1968; Crepet, 1974); H, bennettitalean pollen (Vitimipollis) in the gut of a xyelid sawfly (Krassilov and Rasnitsyn, 1983); I, probable insect 
removal of the ovuliferous layer within the receptacle of a Williamsonia cone (Bose, 1968; Crowson, 1991); J, mouthpart structure of several 
brachyceran fly taxa consistent with nectaring on co-occurring gnetaleans (Nartshuk, 1996; Labandeira, 1998a; but see Ren, 1998a); K, earlier 
brachyceran flies with mouthpart structure consistent with nectaring on gnetaleans (Rohdendorf, 1968; Labandefra, 1997,1998a); L, lepidopteran 
mines of Nepticulidae on Platanaceae, Cercidiphyllaceae and Trochodendraceae (Kozlov, 1989; Dormer and Wilkinson, 1989); M, co-occurrence of 
insects bearing elongate mouthparts and probable pollen-laden vestiture with funnel-shaped flowers (Ra3aier, 1991,1993); N, leaf mines on various 
dicots (Fritsch, 1882; Fric, 1901); O, lepidopteran mines of Nepticulidae and Gracillariidae on magnoliid and hamamelid dicots (Labandeira et al., 
1994); P, foliar gall on "Sassafras" (Hickey and Doyle, 1977); Q, foliar gall on Pabiana (Upchurch et al., 1994); R, winteraceous pollen (Afropollis) in 
the gut of an xyelid sawfly (Caldas et al., 1989); S, caddisfly case constructed from Karkenia seeds (Krassilov and Sukacheva, 1979); T, probable stylet 
punctures on the cuticle of Pseudofrenelopsis (Watson, 1977); U, the nemonychid weevil Libanorhinus associated with co-occurring Araucariaceae, 
based on life-habits of extant descendants (Kuschel and Poinar, 1993); V, conifer pollen (Alisporites, Pinuspollenites) in the gut of a xyeUd sawfly 
(Krassilov and Rasnitsyn, 1983); W, wood boring of a bark beetle on conifer wood (Jarzembowski, 1990); X, Classopollis conifer poUen in the gut of 
the hagloid orthopteran Aboilus (Krassilov et al, 1997a, 1997b); Y, borings in female cones of Araucaria (Stockey, 1978; Crowson, 1991; Farrell, 1998), 
although geochronologic placement is uncertain. See Figures 2 and 3 for additional details. 
Reptiles. Occurrences of insect associations on principal terrestrial reptile clades from the Late Jurassic to Middle Cretaceous interval, 
documented from the literature. Sources for insect-reptile associations are: A, the unassigned insect Saurophthirodes presumably an ectoparasite on 
pterosaurs (Ponomarenko, 1986); B, the unassigned irwect Saurophthirus presumably also an ectoparasite on pterosaurs (Ponomarenko, 1976); C, 
insect (?dermestid) borings in sauropod and theropod bones (Laws, 1996; Hasiotis and Fiorillo, 1997); D, biting midge (ceratopogonid) feeding on 
hadrosaur (1 Cory thesaurus) blood, based on mouthpart structure of fossils and extant descendants (Borkent, 1995); E, black fly (simuliid) feeding 
on probable omithischian, based on mouthpart structure (Kalugina, 1992). See Figure 4 for additional documentation. 
109 
ii?sect functional feeding groups in the fossil record are external 
foliage feeding, leaf mining, and galling?sporivory/pollinivory 
and piercing-and-sucking are much less encountered. 
External Foliage Feeding 
External foliage feeding is the consumption of live leaf tissue 
from without, and is t5^ically indicated by dark, thickened caUus 
tissue rimming the excised margin of a leaf. External foliage 
feeding is a broad category that includes margin feeding, or 
consumption along the margin of a leaf, regardless of the 
tortuosity of the feeding trace; hole feeding, consisting of tissue 
removal surrounded on all sides by callus tissue; skeletonization, 
or the consumption of softer interveinal tissue, leaving a 
meshwork of vascular tissue; surface abrasion, in which one or 
more layers of foliar tissue are removed, leaving at least one 
lamina intact; free feeding, characterized by consimiption of 
almost the entire blade, with only primary venation and possibly 
a few flaps of mesophyll tissue remaining; and bud-feeding, a 
specialized type whereby an insect "tunnels" through a leaf bud. 
leaving a stark and repetitive sequence of "shot-holes" in the 
furled, mature leaf or frond (Coulson and Witter, 1984). 
Frequentiy it is difficult to differentiate skeletonization from 
surface abrasion, and comparison to the surrounding sediment 
matiix may resolve the differences. 
External foliage feeding extends minimally to the Late 
Carbor?ferous (Scott: and Taylor, 1983; Chaloner et al., 1991; 
Labandeira, 1998b) and possibly to the Early Devonian (Kevan et 
al., 1975). All subtypes of external foliage feeding except for bud- 
feeding are documented from an Early Permian flora in north- 
central Texas (Beck and Labandeira, 1999). The foliage of early 
Mesozoic plants such as ferns, cycadophytes and seed-ferns were 
also attacked by external feeders (Grauvogel-Stamm and Kelber, 
1996; Ash, 1997), although there has been no quantification of 
these data. Littie is known of external foliage feeding for Late 
Jurassic or Early Cretaceous floras, but floras such as the 
Cenomanian Dakota flora of the central United States (Labandeira 
et al., 1994) (Fig. 3A-C) and tiie Turonian Beleutinskaya 
Formation of Kizyl-Djar, Kazakst?n (Kozlov, 1988) were heavily 
attacked. 
Age 
(Ma) 
Stage 
Major 
Insect 
Deposits 
Principal Terrestrial Clades 
Plants Reptiles 
90- 
100- 
110- 
120- 
130- 
140- 
150- 
Turonian IIIIIIIIITT 
Cenomanian 
Albian 
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Aptian 
imiiiiifT 
Barrennian 
Hauterivian 
Valanginian iiiiiiiiiiiiiiii 
mil TTT 
? HI' iiTin 
Berriasian 
iTnTrnmr 
Tithonian I ? ? ? 11 ? ? ? iTlTT 
iiiiiiiimiiiii 
Kimmeridgian 
Oxfordian 
O 
CO ? 
E to CO  tc 0 C ?   0 
>. 2 ?i CO ~ 
CO '^ 
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CO 
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X    CO CO o    m 
Q. CO O) 
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(g) (5) 
lio 
Leaf Mining 
Leaf mining is the extraction of live, internal, foliar tissue by 
holometabolous larvae (Hering, 1951), or possibly certain mites 
(Fernandez and Athias-Binche, 1986). Leaf miners typically lack 
access to the external environment until emergence at the end of 
the larval or pupal stage. Patterns of tissue consumption by leaf 
miners are frequently highly stereotyped, especially in terms of 
oviposition site, mine v^ridth, two-dimensional trajectory of the 
mine, nature of the frass trail, and disposition of frass in the 
terminal chamber (Needham et al., 1928; Hering, 1951). Leaf 
mines of holometabolous insects are produced only by larvae of 
moths (Lepidoptera), flies (Diptera), sawflies (Hymenoptera) and 
beetles (Cole?ptera), and either are linear and serpentine, 
frequently undulatory or irregular in progression, or they are 
ovate or multilobate blotches. All leaf mines evidently are 
constrained to some extent by primary and often secondary leaf 
venation. Because of the pronounced plant host specificity of 
modem leaf-miiung taxa, knowledge of the host spectrum of 
modem leaf miners is helpful in the identification of Cenozoic 
leaf-mines, and can be of use in identifying basal leaf-mining taxa 
on basal angiosperm taxa for Middle and Late Cretaceous floras 
(Kozlov, 1988; Labandeira et al., 1994; Davis, 1994). 
Leaf mining is the only major functional feeding group 
without convincing representation in the Paleozoic, although 
certain damage to Pennsylvanian and Early Permian 
Macroneuropteris seed-fern foliage is suggestive (M?ller, 1982; 
Labandeira and Beall, 1990). The earliest documented evidence is 
on the Late Triassic broadleaved conifer Hediphyllum (Rozefelds 
and Sobbe, 1987), consisting of high-sinuosity, small-diameter 
traces that may have been produced by beetle larvae. Known 
preangiospermous leaf mines are very rare; in addition to the 
Triassic example, Skalski (1979) mentioned but did not illustrate 
mines on seed-fern foliage from the Late Jurassic Karatau flora of 
Kazakst?n, and Rozefelds (1988) figured and described mines that 
he referred to the lower lepidopteran clade, Nepticuloidea, on the 
corystosperm seed fern Pachypteris (Fig. 2A), a conclusion 
bolstered by specialist opinion. Modem Nepticulidae mine 
primitive and advanced dicotyledonous angiosperms. If 
Rozefeldis identification is secure, and barring the occurrence of 
Late Jurassic angiosperms, these important specimens imply that 
the radiation of the Lepidoptera occurred endophytically on seed 
fems, not on angiosperms. Accordingly, nepticuloids 
subsequently became miners on angiosperms either through a 
corystosperm to angiosperm line of descent, or by lateral host- 
switching later during the Early Cretaceous. Certainly by earliest 
Cenomanian times, several leaf-mine morphotypes were present, 
including the. monotrysian Nepticulidae and the ditrysian 
Gracillariidae, established on multiple lineages of magnoliid, 
rosid and hamamelid dicots (Fig. 4D-E), exhibiting considerable 
host specificity (Labandeira et al., 1994). The expansion of leaf- 
mining taxa on a broad spectrimi of host-plant taxa continued 
throughout the Cretaceous, and includes mines on additional 
hamamelids of the families Trochodendraceae, Cercidiphyllaceae 
(katsura tree) and Platanaceae (sycamores) as well as on rosid and 
dilleniid host taxa (Kozlov, 1988; Stephenson, 1992; Labandeira et 
aL, 1995). 
Galling 
The formation of insect or mite galls starts with the invasion 
of plant tissue by either an egg iriserted by an ovipositor or by 
subsequent burrowing into subdermal tissue by a newly emerged 
larva or nymph from a surface-deposited egg (Meyer, 1987). Once 
in contact with plant tissue, substances from the larva that mimic 
various plant-produced hormones locally induce anomalous 
tissue proliferation, resulting in formation of a gaU. Gall 
formation typically includes an outer sclerenchymatous tissue to 
provide protection and support, and inner nutritive tissue as a 
source of rich food to the encapsulated, developing nymph or 
larva (Meyer, 1987). Galls thus are abnormal, three-dimensional 
expansions of proliferated plant tissue encapsulating one or more 
immature insects in a central chamber. They occur on particular 
organs and tissue types, and virtually all gallers possess high host 
specificity, many requiring a particular host species for successful 
development. Galls are classified according to their location on a 
plant, and include twig, petiole, leaf midrib, leaf lamina and floral 
types, although the most typically encountered as fossils are 
midrib and lamina galls of leaves. Three major terrestrial groups 
of arthropods are gallers on vascular plants: mites, which 
FIGURE 2. Examples from the literature of insect associations with 
vascular plants from Late Jurassic to Middle Cretaceous ecosystems. 
A, Lepidopteran leaf mine (?Nepticulidae) on the corystosperm seed 
fern Pachypteris, from the Jurassic-Cretaceous boundary of 
Queensland, Australia (redrawn from Rozefelds, 1988). B, The surface- 
foraging termite Meiatermes bertrani (Lacasa and Mart?nez-Delcl?s, 
1986) (Hodotermitidae), from the Berriasian of Spain (Mart?nez-Delcl?s 
and Martineil, 1995). C, Stylet or ovipositor marks on Pseudofrenelopsis 
cuticle and epidermis (Cheirolepidaceae), from the late Aptian to early 
Albian of Glen Rose, Texas (Watson, 1977). D, Borings, probably by 
beetles, in the stem of Hermanophyton (TCorystospermaceae), from the 
Tithonian of southwestern Colorado (Tidwell and Ash, 1990). E, The 
beetle ichnogenus Pakoscolytus sussexensis Qarzembowski, 1990) within 
conifer cambium, from the Berriasian to Valanginian interval of 
England. F, Excavated galleries, undoubtedly by beetles, revealed in 
a longitudinal section of Cycadeoidea (Bennettitales), from Early 
Cretaceous of South Dakota (Delevoryas, 1968). White arrow indicates 
terminus of frass-containing tunnel. G, Probable beetle borings in the 
ovuliferous bracts of an Araucaria cone, from the Late Jurassic of 
Argentina (Stockey, 1978). White arrow at bottom indicates position 
of tunnels in bract tissue; black arrows at top indicate smaller and 
subdermally placed resin canals. H, Gallery with coprolites from 
oribatid mites in the stem of the fern Tempskya, from the Aptian to 
Albian transition of Montana (Seward, 1924). I, The hagloid 
orthopteran, Aboilus, with pollen-laden gut contents (indicated by 
arrow), from the Late Jurassic (Kimmeridgian) of Kazakhstan 
(Krassilov et al., 1997b). White arrow indicates position of food bolus 
that contains pollen. J, A Classopollis pollen grain, found in the gut of 
the orthopteran illustrated in (I) (Krassilov et al, 1997b). K, The xyelid 
sawfly Ceroxyela, with gut contents of gymnosperm pollen, from the 
Lower Cretaceous (?Valanginian) of Transbaikalia, Russia (Krassilov 
and Rasnitsyn, 1983). White arrow indicates position of pollen- 
containing food bolus. L, A conifer pollen grain of Pinuspollenites, from 
the intestine of an xyelid sawfly (Krassilov and Rasnitsyn, 1983). M, 
The eccoptarthrinid weevil Jarzembowskia?a probable feeder on 
gymnospermous reproductive structures, from the Berriasian of Spain 
(Zherikliin and Gratshev, 1997). N, A deep-throated, funneliform 
flower from the Cenomanian of Orapa, Botswana (Rayner, 1993). O, 
Elongate mouthparts of the cranefly, Helens, a probable nectar-feeder, 
also from Orapa (Rayner, 1991). P, A pollinating nemestrinid fly, 
Florinemestrinus (Ren, 1998a, 1998b), from the probable Tithonian of 
China. Q, Detail of head and elongate mouthparts of Florinemestrinus 
shown in (P) (Ren, 1998a). Scale bars: solid = 1cm; striped = 0.1 cm; 
dotted = 0.01 cm; backslashed = 0.001 cm. 
Ill 
112 
generally form smaller foliar galls 0eppson et al., 1975); 
hemipteroid insects consisting of thrips (Ananthakrishnan, 1978) 
and certain hemipterans (Rohfritsch and Anthony, 1992); and 
holometabolous insects, of which the same four orders that mine 
leaves also gall vascular plants (Dreger-Jauffret and Shorthouse, 
1992). 
The earliest known certifiable galls of vascular plants are from 
permineralized tree-fern rhachises from the Upper Pennsylvanian 
of Illinois (Labandeira and Phillips, 1996b), although earUer 
unusual structures on sphenophyte compressions from Europe 
(Thomas, 1969) may also be galls (Van Amerom, 1973). Twig galls 
are well known on Late Triassic conifers from North America 
(Ash, 1997) and Europe (Grauvogel-Stamm and Kelber, 1996); leaf 
gaUs on the bennettitalean Anomozamites are known from the 
Bajocian Jurassic of Europe (Alvin et al., 1967). They are common 
on various angiosperms from the Cenomanian Dakota flora, 
especially platanoids (Fig. 4F-H) and lauraleans (Stephenson, 
1992; Labandeira and D?cher, 1993). Isolated foliar gaUs have also 
been illustrated for earlier Albian angiosperms (Hickey and 
Doyle, 1977; Upchurch et al., 1994) as well as post-Cenomanian 
Cretaceous floras (Fritsch, 1882; Fric, 1901; Stephenson, 1992; 
Larew, 1992; Scott et al., 1994). Both gall mites (Acari: 
Eriophyoidea) and gall midges (Diptera: Cecidomyiidae) are the 
probable causative agents of many of these galls; less clear is 
whether all gall-forming species, such as gall wasps 
(Hymenoptera: Cynipidae) or gaUicolous weevils (Cole?ptera: 
Curculionoidea) were responsible for these galls. 
Wood Boring 
Tunneling by arthropods into indurated tissues is one of the 
oldest feeding methods on land, with examples extending to the 
Early Pennsylvanian (Labandeira et al., 1997) for vascular plants, 
and to the Early Devoi?an for fungi (Arnold, 1952; Hotton et al., 
1996). Boring into wood or other hardened tissues, such as seed 
sclerotesta, can be done while the host is alive (Solomon, 1995) or 
dead (Hickin, 1975). Typically, borings consist of an entry hole at 
the surface that connects with an internal network of tunnels and 
possibly galleries whose structure and three-dimensional 
geometry is more or less stereotyped. Depending on the taxon, 
certciin tissues are targeted for consumption, such as cambium for 
bark beetles or secondary wood for homtails, often with the 
assistance of intestinal symbionts for degradation of lignin and 
cellulose. In fossils, damage to tissues is initially recognized by 
circular entry or exit holes; for gallery systems paralleling wood . 
grain, exposure of borings can be made by delamination of the 
bark, exposing the targetted cambial tissue. Most two- 
dimensional cambial borings are made by bark bee?es 
(Scolytidae), bark weevils (Curculionidae) and agromyzid miners 
(Diptera: Agromyzidae). Three-dimensional borings into other 
tissues are produced by diverse taxa, including xyelid, siricid and 
tenthredinoid sawflies, anobiid, buprestid and cerambycid 
bee?es, ses?d and cossid moths, agromyzid flies, as well as much 
smaller oribatid mites (Hickin, 1975; Solomon, 1995; Labandeira 
et al., 1997). Many of these tunnel systems are intricate and 
extensive, requiring creative use of a rock saw for exposure and 
reconstruction. 
Although boring by oribatid mites on decomposing woods is 
an ancient habit, it has been docimiented principally for the 
Paleozoic and Recent (Labandeira et al., 1997); very lit?e is known 
about this functional feeding group for Mesozoic and Cenozoic 
plants. An exception was illustrated by Seward (1924), although 
he did not attribute the gallery system to any particular arthropod 
clade (Fig. 3H). Other borers of dead woody tissues are 
principally insects (Hickin, 1975). However, it is difficult to 
determine if the boring occurred while the plant host was alive or 
dead; occasionally evidence indicating that the plant host was 
alive is the presence of products of plant response to endophagy, 
including scar tissue and plugs in tunnels composed of resins, 
mucilage or other extracellular plant substances (e.g., Zhiyan and 
Bole, 1989). Alternatively, assignment of a stereot)^ed fossil 
timnel-and-gallery system can be made to a modem taxon 
possessing high host specificity, although this method generally 
is not available to mid-Mesozoic borings. Published examples of 
fossil wood borings include Permian to Triassic glossopterid 
woods from South Africa and Germany (Linck, 1949; Zavada and 
Mentis, 1989; Goth and Wilde, 1992), several bee?e taxa on Late 
Triassic araucarian wood (Walker, 1938; Hasiotis and Dubiel, 
1993), possible deathwatch beetle galleries in unknown Early 
Jurassic wood from Germany (Jurasky, 1932), beetle borings in 
Middle Jurassic cupressaceous or taxodiaceous wood from China 
(Zhiyan and Bole, 1989), and cambium borings attributable to a 
scolytid Qarzembowski, 1990) or curculionid (Stephenson, 1992) 
beetle in conifer wood from England (Fig. 2E). Other plant hosts 
with stem borings are a dipteridaceous fern from the Middle 
Jurassic of Antarctica (Yao et al., 1991) and borings on Late 
Jurassic Hermanophyton from Colorado (Fig. 2D), an enigmatic 
gymnospermous wood, perhaps similar to corystosperm seed 
ferns (Tidwell and Ash, 1990). 
Piercing-and-Sucking 
Piercing-and-sucking is a distinctive type of mite- or insect- 
mediated damage whereby stylets pierce host tissue either intra- 
or interceUularly to take up fluid food ranging in accessibility 
from subdermal mesophyU to deep-seated vascular tissue. The 
host plant responds to trauma resulting from endophytic 
consiunption (although the consumer is located external to the 
plant) by producing callus or other reactive tissue which 
frequently is expressed on the affected surface by characteristic 
spotting, wilting or curling of leaves or by gnarling of adjacent 
tissue on twigs and stems. Detection of piercing-and-sucking 
damage in the fossil record requires either weU-preserved, three- 
dimensionally permineralized material with resulting histological 
and cellular detail (Banks and Colthart, 1993; Labandeira and 
Phillips, 1996a) or two-dimensional preservation of cuticular 
surfaces, often as processed macer?is, with retention of pimcture 
holes and surrounding reaction rims (Watson, 1977; Fig. 2C). 
Surface puncture holes in even well-preserved compression 
material lacking cuticle are imdetectable. However, it can be 
inferred by large-scale teratologies such as spotting and leaf curl, 
known to be induced by piercing-and sucking insects such as 
thrips (Fennah, 1962; Boumier, 1970), whiteflies (Latta, 1937) and 
lace bugs (Crosby and Hadley, 1915). In rare iiistances, there is 
retention of the attachment scars on leaf surfaces by piercing-and- 
sucking scale insects. 
Of approximately equal antiquity to boring on plant and 
fungal substrates is piercing-and-sucking, which probably was 
present during the Early Devonian (Kevan et al., 1975; Labandeira 
and Phillips, 1996a) and is well documented on tree-fern petioles, 
seed-fem pollen organs, and platyspermic cordaite seeds from the 
Upper Pennsylvanian and Lower Permian (Sharov, 1973; 
Labandeira and Phillips, 1996a; Labandeira, 1998b). The culprits 
of this Paleozoic damage were paleodictyopterid insects, in 
113 
contrast to the few instances of post-Paleozoic damage 
attributable principally to hemipteroid insects (Fig. 2C). The lack 
of significant documented evidence of piercing-and-sucking is 
partly attributable to confusion with fungal attack. In fact, open 
dermal wounds left by insects with stylate mouthparts are point 
sources often targeted by invading fungi, that subsequently 
expand after colonization to form a similar pattern of leaf 
spotting. 
Sporivory and Pollinivory 
Evidence for consumption of spores and pollen is qualitatively 
different than the five preceding functional-feeding-groups. 
Sporivory and pollinivory are not detectable as plant damage; 
consequently, a parallel ichnofossil record of coprolites and gut 
contents has been exploited to reveal the taxonomic identities of 
both the insect culprits and their interacting plants. When 
evaluated throughout the Phanerozoic, four assemblages of 
pollinating insects and their source plants have been 
characterized (Labandeira, 1998a), commencing during the latest 
Silurian to Early Devor?an, with coprolites consisting entirely or 
partially of spores from primitive vascular plants, produced by 
unknown terrestrial arthropods (Edwards, 1996). The second 
assemblage is composed of both Late Carboniferous dispersed 
coprolites from coal-swamp deposits and Early Permian insect 
gut contents in drier, upland habitats. Collectively, this 
assemblage docvunents consumption of cordaite, conifer and 
seed-fern pollen as well as marattialean tree-fern spores during 
the late Paleozoic (Rasnitsyn and Krassilov, 1996a, 1996b; 
Labandeira, 1998a, 1998b). The ichnofossil record for spore and 
pollen consumption fades after the Permian and does not resume 
imtil the mid-Jurassic, when dispersed coprolites consisting of 
Caytonia pollen from the Yorkshire Flora (Harris, 1957) enter the 
FIGURE 3. A sample of varied insect damage on dicotyledonous foliage from the Dakota Formation, an early angiosperm-dominated flora located at 
Braun's Ranch, near Delphos, Cloud Co., Kansas (see also Labandeira et al., 1994). A, Two galls (white arrows), margin feeding (top) and hole feeding 
(between midrib and right margin) on the lauralean Crassidenticulum (UF11867). B, Hole feeding remir?scent of modem weevil (Cole?ptera: 
Curculionidae) damage on the lauralean Crassidenticulum (UF12660'). C, Hole feeding reminiscent of modem leaf beetle (Cole?ptera: Chrysomelidae) 
damage on the lauralean Pandemophyllum (UF7250). D, Serpentine leaf mine (Lepidoptera: Nepticulidae) possibly on the lauralean Pabiana (UF16173). 
E, Serpentine leaf mine (Lepidoptera: Nepticulidae) on an unidentified angiosperm fragment (UF7252). F, Midrib galls (?Diptera: Cecidomyiidae) on 
a platanoid leaf (UF12730). G, Detail of gall structure outlined at top in (F). H, Detail of gall structure outlined at bottom in (F). Abbreviation: UF = 
paleobotanical collections at the University of Florida Museum of Natural History in Gainesville. Scale bars: solid = 1cm; striped = 0.1 cm. 
114 
record. 
It is this third assemblage of consumed gymnospennous 
pollen, the subsequent fourth assemblage of angiosperm 
pollinivory, and their probable overlap, that is of interest for the 
Late Jurassic to Middle Cretaceous interval (Labandeira, 1998a; 
Ren, 1998a). From the Kimmeridgian Karatau biota of Kazakst?n, 
aboilid orthopterans (grasshoppers) have yielded gut contents 
(Fig. 21) consisting of a distinctive type of Classipollis pollen (Fig. 
If) assignable either to the Coniferales or Gnetales (Krassilov et 
al., 1997a, 1997b). Evidence for consumption of exquisitely- 
preserved gymnospermous pollen also was found in the Lower 
Cretaceous Baisa biota of Russia, where isolated conifer pollen of 
Alisporites, Pinuspollenites and Vitimipollis (Fig. 2L) were lodged in 
the guts of three genera of xyelid sawflies (Fig. 2K) (Krassilov and 
Rasnitsyn, 1983). Pollen also has been foimd in the guts of xyelid 
sawflies from the Aptian Santana Formation of northeastern 
Brazil (Caldas et al., 1989); except that the consumed pollen is 
Afropollis, a form-genus assigned to winteraceous angiosperms 
(Doyle et al., 1990) and the earliest example of insect-consumed 
angiosperm pollen in the fossil record (see also Lloyd and Wells, 
1992). Kampmann (1983) has described spore-bearing coprolites 
from the Lower Cretaceous of Germany, also attributable to 
hymenopterans. Lastly, from the Turonian locality at Orapa, 
Botswana, Rayner and Waters (1991) have described staphylinid 
beetles with extensive pollen attached to their vestiture, 
suggestive of pollinivory. Evidently consumption of pollen from 
clades as diverse as conifers, cycads, gnetaleans, and 
beimettitaleans was occurring during the Late Jurassic to Middle 
Cretaceous, indicating as well that the origin of modem-style 
pollination was among seed plants prior to the ecological 
expansion of angiosperms (Dilcher, 1995; Labandeira, 1998a). At 
present, it is impossible to determine whether gymnospermous 
and angiospermous pollen during the Early Cretaceous were 
being trophically partitioned by different taxa of insect 
pollinivores. 
Nectarivory 
Because of the presence of both pollen- and nutrient-rich 
surface secretions in most seed plants, there is a tight association 
between pollinivory and nectarivory. Even if nectar coiisumption 
is the sole insect reward, the transfer of pollen to conspecific plant 
hosts is an indirect but beneficial effect resulting in a mutualism 
that can be maintained for extended intervals of geological time. 
Nectarivory is the imbibation of secretions rich in carbohydrates, 
lipids or amino acids (Baker and Baker, 1975), which are secreted 
by specialized epidermal glands (nectaries) that are associated 
with reproductive or vegetative structures (Durkee, 1983) in a 
variety of ferns and seed plants, especially angiosperms (Boimier, 
1879; Mamay, 1976; Fahn, 1979; Proctor et al., 1976). Foss? 
evidence for nectarivory is relatively indirect, and typically is of 
two types: insect mouthpart structures consistent with 
biomechanical, functional or morphological analogy to modem 
nectarivores, or as floral structures modified for the reception of 
insect mouthparts, such as placement of floral nectaries at the 
bottom of a deep, tubular corolla (Crepet, 1996). Additionally, 
there is evidence from modem nonangiospermous seed plants 
indicating that insect nectaring occurs in gnetaleans (Van der Pijl, 
1953; Meeuse et al., 1990; Kato and Inoue, 1994) and cycads 
(Brekton and Ortiz, 1983; Tang, 1987). 
Appropriate insect mouthparts are known from the fossil 
record, such as the very elongate proboscis of a scorpionfly from 
\ \ \ 
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^ 1 '    *'* 
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uo 
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?K^ w _*-*-*"?     , ,n., ^ ^.^w...? ?'^ * 
FIGURE 4. Examples from the literature of insect associations with reptile- 
grade vertebrates during Late Jurassic to Middle Cretaceous. A, Ventral 
view of the enigmatic insect Saurophthirus, a possible pterosaur 
ectoparasite, from the Lower Cretaceous of Transbaikalia, Russia 
(Ponomarenko, 1976). B, Detail of dorsal body surface structures, 
including vestiture, genitalia and setalion of leg bases (Ponomarenko, 
1976). C, Ttie presumed flea, Tanvinia, from the Aptian of Victoria, 
Australia (Riek, 1970; Jell and Duncan, 1986; also see Poinar, 1995). D, 
Interpretive rendering of life habits of Culicoides canadensis (Boesel) 
(Diptera: Ceratopogonidae) as a blood-feeder on exposed eye membranes 
of Corythosaurus, from the Upper Cretaceous of Alberta, Canada (Borkent, 
1995). Scale bars: solid = 1cm; striped = 0.1 cm. 
the Kimmeridgian-age Karatau biota of Kazakst?n 
(Novokshonov, 1997). The most spectacular examples from this 
deposit are the suite of brachyceran fly species, especially 
members of the family Nemestrinidae, with elongate prob?scides 
or investitures of dense hair (Rohdendorf, 1968b; see also 
Nartshuk, 1996). The younger Tithonian Yixian Formation of 
China also contains a relatively diverse suite of brachyceran fly 
species, including Nemestrinidae, Tabanidae and Apioceridae 
(Ren 1998a, 1998b), which strongly indicate that nutrient rich 
115 
?uids secreted by seed plants normally inaccessible to insects 
with short mouthparts, were being accessed by nectarivorous flies 
with elongate and specialized fluid-feeding prob?scides (Fig. 
2P-Q). Also of Tithonian age, the Solnhofen Formation in 
Germany has revealed a nemestrinid fly, although it is poorly 
preserved (Bemardi, 1973). In addition to the evidence from 
Mecoptera and especially Diptera above, is Kozlov's (1989) 
description of an Upper Jurassic siphonate lepidopteran from 
Karatau. 
In contrast to the Late Jurassic compression deposits, relevant 
deposits of Early Cretaceous age contribute relatively lit?e insight 
into the existence of nectarivory, and the evidence for this 
functional feeding group does not reappear imtil the Middle 
Cretaceous. Diuing the Turonian this evidence consists of various 
floral structures (Crepet, 1996; Crepet and Nixon, 1996) and the 
presence of a bee (Michener and Grimaldi, 1988) in New Jersey 
amber, and crane fly mouthparts (Fig. 20) and floral structures 
(Fig. 2N) from Botswanan compressions (Rayner and Waters, 
1991; Rayner, 1993). To date there is no known physical evidence 
for Cretaceous angiosperm floral damage that would be expected 
from mess-and-soil pollinators such as beetles (Thien, 1974; 
Grinfel'd, 1975; Gottsberger, 1988). The closest evidence for a 
precursor to this pollination type is foimd in female reproductive 
strobili of Early Cretaceous bennettitalean Cycadeoidea 
(Delevoryas, 1968; Crepet, 1974) (Fig. 2F), though the culprits for 
this damage suggest poUination syndromes of modem cycads 
rather than modem angiosperms (Crowson, 1991; Labandeira, 
1997). Moreover, nemonychid, curculionid and other weevils are 
known with long, decurved rostra, and probably were consuming 
coriifers or cycads either as larvae (Fig. 2G) or as adults (Fig. 2M), 
thus representing additional evidence for the antiquity of beetle- 
mediated pollination (Zherikhin and Gratshev, 1997). 
Other Interactions 
Plant, fungal and animal structiures undoubtedly provided 
insects with protection and shelter, as they do in extant 
ecosystems (Scott et al., 1992). However, fossil doctmientation of 
such interactions is sparse because insect domiciles other than the 
ones mentioned above are rarely preserved in the fossil record. 
Leaf-rolling and leaf-tieing are obvious candidates Johnson and 
Lyon, 1991) but are limited to a Cenozoic record of rare 
occurrences. Another suspect is mite domatia, but presently 
domatia are not known from the Mesozoic, and their earliest 
occurrence is Eocene (O'Dowd et al., 1991). The best example is 
caddisfly cases, which have a pervasive record throughout the 
later Mesozoic and Cenozoic (Sukacheva, 1982), characterized by 
selective use of plant and animal materials for case construction 
by these aquatic larvae. In fact, an informal ichnotaxonomy has 
been developed to refer to these compositionally and structurally 
distinct domiciles (Sukacheva, 1982). A notable example is a type 
of caddisfly case fabricated from seeds of the extinct gingkoalean, 
Karkmia (Krassilov and Sukacheva, 1979), from the Lower 
Cretaceous Mongolian locality of Shin-Khuduk. 
Insect-Fungus Associations 
The fossil record of insect-fungal associations reveals two, 
documentable modes of occurrence. The first mode is as 
microscopic gut endosymbionts that provide compounds for the 
digestion of such refractory foods as lignin and cellulose, typically 
by wood-boring iiisects such as termites (Darlington, 1994), bark 
beetles (Norris, 1979; Beaver, 1989), and sawflies (Madden and 
Coutts, 1979). Although gut endosymbiont microfossils from Late 
Jurassic to Middle Cretaceous insects have not been found, such 
associations may be found in Cretaceous amber (see 
documentation of microfossils in Miocene amber [Grimaldi et al., 
1994]). Nevertheless, these associatior^s can be inferred from the 
presence of late Mesozoic wood-boring insects whose modem 
descendants obligately require intestinal endosymbionts for 
survival (Bab-a, 1979; Wheeler and Blackwell, 1984; Wilding et al., 
1989). These type of associations are documented through the 
Cenozoic and into the Lower Cretaceous (Labandeira, 1999b), and 
include a Lower Cretaceous scolytid or curculionid boring in 
conifer wood Qarzembowski, 1990) and the earliest credible trace- 
fossil of an insect boring with fungi from the Early Jurassic of 
Germany (M?ller-StoU, 1936), consisting of wood borings with 
cell walls degraded by fungi and lined with hyphal masses along 
their inner wall. Presumed anobiid, buprestid and scolytid beetle 
borings in Araucarioxylon wood of the Late Triassic Chinle 
Formation (Walker, 1938) are questionably assigned (Crowson, 
1981) and lack evidence of fungi. 
The second preservable mode of association between fungi 
and insects is the cultivation of megascopic fungi, typically in 
underground cavities, by certain clades of termites (Wilson, 1971; 
Babra and Batra, 1979; Wood and Thomas, 1989) and ants (Weber, 
1979; Cherrett et al., 1989; H?Udobler and Wilson, 1990). Wh?e 
termites and ants have a good Cenozoic record, the body fossils 
of these social insects extend only to the Lower Cretaceous 
(Grimaldi, 1997, Grimaldi et al., 1997, respectively) (Fig. 2B), 
although reports of older ichnofossils for both groups extend to 
the Late Triassic Chinle Formation (Hasiotis and Dubiel, 1993, 
1995) but await corifirmation. Several Cretaceous termite body 
fossils have been assigned to the families Hodotermitidae and 
Mastotermitidae (Grimaldi, 1997); the oldest is Meiatermes bertrani 
from the Valangir?an of Montsec, Spain (Lacasa and Martinez- 
Delclis, 1986). Trace-fossil evidence for the presence of Isoptera is 
confined to the Upper and Middle Cretaceous, consisting of fecal 
pellets with distinctive hexagonal cross-sections within 
characteristic galleries of wood from the Maastrichtian of Texas 
(Rohr et al., 1986), an unspecified interval from the Upper 
Cretaceous of Argentina (Genise, 1995) and the Cenomanian of 
British Columbia (Ludvigsen, 1993). 
Known fossil representatives of ants and their immediate 
ancestors extend to the Aptian Santana Formation of BrazU 
(Brand'O et al., 1990), although tme ants (Formicidae) have a 
Tiwonian earliest docvunented occurrence from New Jersey amber 
(Wilson et al., 1967; Grimaldi et al., 1997). Evidently the caste 
system that characterizes ants was well-established during 
Turonian time, but its presence during the earlier Cretaceous 
presently has not been demonstrated because of difficulty in 
evaluating appropriate structural features of individuals 
preserved as compressions. The only extant clade with Mesozoic 
fossils is the Ponerinae, represented in New Jersey amber, which 
implies that most of the higher-level cladogenesis had transpired 
during the Lower Cretaceous and Cenomai?an, and that an 
earlier radiation of ants (Crozier et al., 1997) abo carmot be ruled 
out. Because of this sparse Early to Middle Cretaceous record, and 
the absence of Cretaceous body-fossils of mound-building and 
fungus-culturing clades (albeit cladistic relationships indicate 
their presence), it becomes important to verify recent claims of 
Late Jurassic ant nests from the Morrison Formation (Hasiotis and 
Demko, 1996) and even the Late Triassic Chinle Formation 
(Dubiel and Hasiotis, 1995). 
116 
Insect-Vertebrate Associations 
The extent and quality of evidence indicating insect- 
vertebrate associations is substantially less than those for plants 
and insects. The evidence comes in two principal forms. The first 
are external features that are consistent with an ectoparasitic or 
free-living bloodfeeding way of life and occur on insect fossils 
present in the deposits that also yield appropriate tetrapod hosts 
(Fig. 4). The second is postmortem damage to bones, such as 
borings by carrion insects on dinosaur skeletons. A third type of 
evidence, so far limited to the Late Cretaceous, involves imique 
structures in dinosaur coprolites and associated sediment that 
suggest use of dung as a food substrate and nesting site by scarab 
beetles. Most of these data are indirect, particularly the 
circumstantial evidence of trophically linked, co-occurring insects 
and tetrapods, and associations should be inferred with caution. 
Blood Feeding 
Within the lower Diptera, or Nematocera, there is evidence 
indicating that bloodsucking is the primitive feeding habit for the 
Culicidae (mosquitoes), Simuliidae (black flies), Chaoboridae 
(phantom midges), CeratOpogonidae (biting midges), and 
probably Chironon?dae (aquatic midges), based on morphologic 
examination, phylogenetic analyses and study of Mesozoic fossils 
(Downes, 1971; Borkent et al., 1987; Grogan and Szadziewski, 
1988; Kalugina, 1992). With the exception of the Culicidae, whose 
earliest known representative is from the Late Cretaceous 
(Friedrich and Tautz, 1997), the other four families have Jurassic 
and Early Cretaceous first occurrences (Craig, 1977; Kalugina and 
Kovalev, 1985; Crosskey, 1991; Kalugina, 1992; Szadziewski, 1996; 
Johnston and Borkent, 1998), indicating that blood-feeding on 
terrestrial tetrapods occurred during the mid-Mesozoic (see also 
Hermig, 1972). Additionally, several taxa occurring in Jurassic 
and Early Cretaceous deposits have relict descendants that do not 
suck blood, but probably were blood-sucking based on fossil 
mouthpart structure (Kalugina and Kovalev, 1985; Kalugina, 
1992). 
The more difficult issue is what were the identities of their 
hosts? In a recent exhaustive examination of a diverse suite of 
ceratopogonid taxa from Upper Cretaceous (Campanian) amber 
from Alberta, Canada, Borkent (1995) deduced that two and 
possibly three species of the biting midge Culicoides were feeding 
on the blood of large vertebrates that produced sufficient amounts 
of carbon dioxide for downwind detection. This inference was 
based on robust associations between feeding on large vertebrates 
and mouthpart stylet dentition and palpal sensilla location and 
number for species of modem Culicoides (Rowley and Comford, 
1972; McKeever et al., 1988). Borkent proposed that the females of 
these species attacked exposed and vascularized membranes, 
especially eyelids, or interscutal integument of large hadrosaurs 
(Fig. 4D). In older Turonian amber from New Jersey, Borkent 
(1997b) interpreted Culicoides grandibocus as a feeder on dinosaur 
blood. The other nine Culicoides species of this faima were 
probably insect feeders. 
In addition to dipteran lineages, presimiptive taxa of 
siphonapterans (fleas) or taxa closely related to Siphonaptera, are 
present in the Aptian Koonwarra locality of Australia Qell and 
Duncan, 1986). These fossUs long have been contentious (Riek, 
1970; Willmann, in Hennig, 1981; Poinar, 1995) and exhibit a 
general siphonapteran body fades (Fig. 4C), including distinctive 
pronotal and tergal combs, but their large size, presence of 
prominent,   elongate   antennae   and   lack   of   leg   jumping 
specializations disallows placement in the Siphonaptera as 
presently defined. Nevertheless, the three taxa described at 
Koonwarra clearly display features cor^sistent with an 
ectoparasitic life-habit, including laterally compressed bodies, 
long legs, dorsal setal combs, and elongate, probably stylate, 
mouthparts. 
Parasitism 
Two intriguing Lower Cretaceous discoveries from Eurasia 
suggest that insects were living ectoparasitically on a hair- or 
possibly feather-bearing vertebrate, perhaps a pterosaur. The first 
discovery was made by Ponomarenko (1976), who described the 
weU-preserved compression fossil Saurophthirus longipes from the 
Baisa locality of Transbaikalian Russia (Fig. 4A-B). This 
dorsoventrally flattened, nonwinged insect bears an elongate 
head with stylate mouthparts, and free but modified antennae; 
the thorax and abdomen are scarcely differentiable from each 
other but contain setae and hairs occurring as similar segmental 
patterns. The legs are very long and have tarsal claws designed 
for firm attachment to hair or possibly feathers. This eitigmatic 
insect was probably holometabolous, related possibly to the 
Mecoptera or Siphonaptera, and sharing an overall resemblance 
to nycteribiid flies and polycter?d bugs, both which are bat 
parasites. A similar, more poorly preserved insect has been 
recorded from the younger Gurvan locality in western Mongolia 
(PonomarerJco, 1986). This taxon, Saurophthiroides mongolicus, has 
greater differentiation of the thorax and abdomen than 
Saurophthirus but curiously resembles a peculiar group of winged, 
aquatic Mesozoic orthopteroids known as chresmodeans. 
Carrion Feeding 
Several occurrences of damage to bones, mostiy in the form of 
small borings into bone tissue, are known from the Late Jurassic 
and Late Cretaceous tetrapod record. This damage consists of 
borings that are circular to elliptical in cross-section, and occurs 
in theropod and sauropod dinosaur bones. They have been 
attributed to pupae of carrion beeties (Cole?ptera: Dermestidae). 
Examples are known from the Tithonian Morrison Formation of 
northeastern Utah (Hasiotis and Fiorillo, 1997) and Wyoming 
(Laws et al., 1996) and from the Campanian Two Medicine 
Formation of northwestern Montana (Rogers, 1992). Near 
identical dermestid borings occur in modem decomposing 
carcasses (Martin and West, 1995) and have been docimiented 
more extensively in Late Cenozoic bone assemblages. It is 
noteworthy that calliphorid pupae have been reported from the 
Campanian Edmonton Formation of Alberta, Canada (McAlpine, 
1970), indicating that blow flies, which feed on rotting flesh, were 
part of a carrion community during the Late Cretaceous, and 
possibly earlier. 
Coprophagy 
The degradation and recycling of large amounts of tetrapod 
fecal material by dung beeties (Scarabaeidae) is a pervasive life- 
habit in many modem temperate and tropical regions. While 
scarabaeid body fossils occur throughout the Cenozoic and 
Mesozoic (Crowson, 1981), xmtil recen?y ichnofossUs were only 
known from the Cenozoic. Several have previously suspected that 
Mesozoic tetrapod communities supported dung beetles (e.g., 
Halffter and Matthews, 1966). Recentiy, Chin and GiU (1996) have 
established imequivocal fossil evidence for backfilled burrows 
and other distinctive modification by dung beeties of conifer-rich 
117 
dinosaur dung from the Campanian Two Medicine Formation of 
Montana. Supportive evidence may be gleaned from the body- 
fossil record of scarab beetles, which extends to the Lower 
Jurassic (Amol'di et al., 1977; Rohdendorf and Rasnitsyn, 1980; 
Crowson, 1981), but it is not clear which of these specimens, if 
any, are true dung-beetle taxa in the subfamilies Scarabaeninae 
and Geotrupinae. Additional examples of associations between 
vascular plants, dung beeties and herbivorous dinosaurs probably 
occur in earlier strata, but await discovery. 
LATE MESOZOIC ECOSYSTEM CHANGE 
AND THE PRESENT 
Other than obvious microorganisms, the four taxonomic 
cornerstones of terrestrial ecosystems are vascular plants, fungi, 
arthropods (dominan?y insects), and vertebrates. These dominant 
groups have provided the overwhelming bulk of taxa by which 
terrestrial communities are structured and, through additions and 
subtractions, have determined the course of ecosystem change 
dvuing the past few hundred mUlion years. When viewed through 
a Late Jurassic to Middle Cretaceous prism, it is clear that the 
greatest changes have been with the plants and vertebrates, 
considerably less so with insects. The role of the fungi is still 
speculative, based on their very poor fossil record. During this 70 
mulion year period of Mesozoic time, plants experienced a virtual 
complete overturn at the highest taxonomic levels?a shift from a 
typical "mesophytic" flora of ferns, seed ferns, bennettitaleans, 
conifers, cycads, gingkoaleans and ephedraleans, to a 
"cenophytic" flora of dominantiy angiosperms and subdominantly 
conifers. During this interval, tetrapod assemblages also changed, 
perhaps in ways not as dramatic as the angiosperm revolution. 
Insects apparen?y underwent a different pattern, wherein 
virtually all orders originated during the early Mesozoic or 
earlier, and most suborders and superfamUies, and many families 
were in existence by the Late Jurassic (Labandeira and Sepkoski, 
1993). This was paralleled by a similar modem ecological breadth 
by Late Jurassic times, as measured by the number of occupied 
mouthpart classes, functional feeding groups and dietary guilds 
(Labandeira, 1997,1999b). Perhaps insects were buffered from the 
vicissitudes experienced by plants and vertebrates by their 
elevated diversities, high abundance, and widespread ecological 
ubiquity. However, insects undoubtedly also experienced 
extinctions when their plant and vertebrate hosts succumbed to 
major environmental challenges. 
A reasonable expectation of these data is whether there is any 
evidence in the modem world for this Late Jurassic to Middle 
Cretaceous world? The obvious, perhaps trivial, candidates are 
Gingko, araucarian and podocarp conifers and cycads for plants, 
Sphenodon, crocodiles and turtles for tetrapods, and much of the 
present-day insect fauna. A more revealing answer, however, 
would address the associations between two or more interactive 
organisms. The most frequent examples are insect herbivores and 
their plant hosts, for which some modem studies provide an 
inkling that the earlier Mesozoic world has not been entirely 
swamped out by the subsequent advance of more modem 
angiosperms and mammals. For example, a few studies have 
documented the persistence, to the modem day, of taxa and 
associations datable to approximately 95 Ma. One is the 
prolonged genus-level stasis of the cranefly Helius (Rayner and 
Waters, 1990) and another is the association between genera of 
leaf-mining moths and their platanaceous (sycamore) host plants 
(Labandeira et al., 1994), although there are contrary views 
(Kuschel et al., 1994). More to the point is a cladistic study of the 
Curculionoidea and Chrysomeloidea?two clades of beetles that 
are almost entirely phytophagous on uve plants?wherein 
hostplant taxa were mapped onto a well-corroborated and fossil- 
caUbrated cladogram of the insect herbivore phylogeny (FarreU, 
1998). The results strongly indicate that primitive insect lineages 
have been tracking primitive plant lineages?in this case, conifers 
and cycads?since the Late Jurassic and Early Cretaceous. Similar 
relationships probably exist for other lineages of cycad bee?es 
(Endr?dy-Younga and Crowson, 1986; Crowson, 1990), and the 
dominan?y phytophagous symphytan Hymenoptera and their fem 
and conifer host plants (Vilhelmsen, 1997), although any signal in 
basal lepidopteran phylogeny and their host plants probably has 
been masked by the angiosperm radiation (see Thien et al., 1985). 
Supportive of this view are data indicating that the earliest 
lepidopteran leaf mines are on latest Jurassic or earliest 
Cretaceous seed ferns (Rozefelds, 1988); nectaring Late Jiurassic 
brachyceran flies were more likely to probe nonangiospermous 
seed plants than angiosperms (Labandeira, 1998a; but see Ren, 
1998a); and Late Jurassic to Early Cretaceous grasshoppers and 
sawflies consumed a variety of gymnospermous pollen types 
(Krassilov and Rasr?tsyn, 1983; Krassilov et al., 1997b), followed 
by the earliest insects with gut contents of angiosperm pollen 
occurring later during the Albian (Caldas et al., 1989). Although 
some of ?iese associatioiis have not persisted to the present, there 
are extant cycads with phylogenet?cally primitive weevil 
pollinators (Chadwick, 1993; F?rster et al., 1994; Norstog et al., 
1995; Farrell, 1998), and some associations of basal angiosperm 
lineages and their insect herbivores from the Middle Cretaceous 
have continued to the present day (Labandeira et al., 1994). A tad 
of these dynamic Late Jurassic to Middle Cretaceous asociations 
are still with us, albeit in unanticipated contexts. 
CONCLUSIONS 
1. There is an under-appreciated fossil record of Late Jurassic 
to Middle Cretaceous associations between insects and other 
organisms. This record of vascular plant and insect associations 
is far richer than the record of insect and tetrapod associations, 
but both can be improved significantiy by documenting subtie 
detaUs of fossus that reveal interorganismic activity. 
2. The Late Jurassic to Middle Cretaceous was an interval of 
profoimd change for vascular plants and tetrapods, much less so 
for insects, and unknown for fungi. 
3. At the beginning of this interval, the major associatioris 
between insects and vascular plants are with herbivorous insects 
and seed plants. By the end of this interval, associations with 
vascular plants shifted overwhelmingly toward angiosperms. 
4. The mid-Cretaceous angiosperm revolution swamped out 
earlier seed plant and insect associations so that they exist today 
as rare occurrences in descendant taxa. These extant taxa zie 
frequentiy basal members of their respective lineages. 
ACKNOWLEDGMENTS 
I thank Jim Kirkland for inviting me to participate in this 
forum. Appreciation is extended to Finnegan Marsh for 
formatting the figures for this article and for constmcting Figiure 
1. Financial support was provided from the Walcott Fund of the 
Smithsoi?an Institution. This is contribution no. 36 of the 
Evolution of Terrestrial Ecosystems consortium at the National 
Museum of Natural History. 
118 
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