Plant Syst Evol (2009) 283:247–262
DOI 10.1007/s00606-009-0225-1
ORIGINAL ARTICLE
The earliest record of the genus Cola (Malvaceae sensu lato:
Sterculioideae) from the Late Oligocene (28–27 Ma) of Ethiopia
and leaf characteristics within the genus
Aaron David Pan • Bonnie F. Jacobs
Received: 12 September 2007 / Accepted: 14 September 2009 / Published online: 10 October 2009
Ó Springer-Verlag 2009
Abstract A fossil leaf compression from the Late
Oligocene (28–27 Ma) of northwestern Ethiopia is the
earliest record of the African endemic moist tropical forest
genus Cola (Malvaceae sensu lato: Sterculioideae). Based
on leaf and epidermal morphology, the fossil is considered
to be very similar to two extant Guineo-Congolian species
but differences warrant designation of a new species. This
study also includes a review of the fossil record of Cola, a
comprehensive summary of leaf characteristics within
several extant species of Cola, Octolobus, and Pterygota,
and a brief discussion of the paleogeographic implications
of the fossil species affinity and occurrence in Ethiopia.
Keywords Cola Cuticle Octolobus Pterygota
Sterculiaceae
Introduction
The Malvaceae sensu lato (which includes Bombacaceae,
Malvaceae sensu stricto, Sterculiaceae, and Tiliaceae) are
major woody components of present-day African tropical
moist forests (Judd and Manchester 1997; Alverson et al.
1999). For example, in most 0.1 ha African forest plots
A. D. Pan (&)
Fort Worth Museum of Science and History,
1600 Gendy Street, Fort Worth, TX 76107-4062, USA
e-mail: apan@fwmsh.org
B. F. Jacobs
Roy M. Huffington Department of Earth Sciences,
Southern Methodist University, 750395, Dallas,
TX 75275-0395, USA
e-mail: bjacobs@mail.smu.edu
examined by Gentry (1988), the Sterculiaceae or Tiliaceae
were almost always among the top ten most species-rich
angiosperm families (Phillips and Miller 2002). In these
plots, the most speciose group within Malvaceae s.l. is a
subclade of the Cola clade sensu Wilkie et al. (2006)
consisting of Cola Schott & Endl., Octolobus Welw., and
Pterygota Schott & Endl.
The African endemic Cola, the second largest genus
(approximately 100–125 species) in the subfamily Sterculioideae, is almost entirely restricted to moist evergreen
and semideciduous forest formations (Cheek 2002; Bayer
and Kubitzki 2003; Judd et al. 2008). The genus, which
typically is a common component of the forest understorey,
includes shrubs, treelets, and trees that rarely reach more
than 30 m in height. While the majority of Cola species are
found in West and Central Africa, about 20 species occur
in eastern (Uganda, Tanzania, Kenya, and southern
Somalia), northern (Mali, Niger, and southern Sudan), and
southern Africa (Malawi, Mozambique, South Africa, and
Zambia) (Fig. 1; Keay and Brenan 1973; Verdoorn 1981;
White et al. 2001; Cheek 2002; Lebrun and Stork 2003;
Cheek personal communication).
Octolobus is closely related, and possibly sister to Cola
(Cheek and Frimodt-Møller 1998; Wilkie et al. 2006). This
African endemic tri- or tetratypic genus consists of small
forest trees found mainly in West and Central Africa,
although one species reaches Tanzania (Cheek and
Frimodt-Møller 1998; Bayer and Kubitzki 2003). Both
genera are similar in possessing indehiscent follicles and
exalbuminous seeds (Bayer and Kubitzki 2003; Wilkie
et al. 2006). Pterygota, a pantropical genus of about 15
species of tall forest trees, differs from both Cola and
Octolobus in possessing dehiscent follicle fruits with
winged seeds (Mabberley 1997; Bayer and Kubitzki 2003;
Lebrun and Stork 2003).
123
248
A. D. Pan, B. F. Jacobs
Materials and methods
Fig. 1 Distribution map of the genus Cola, modified from Lebrun
and Stork (2003) and Coates Palgrave (1977). Geometric shapes
correspond to the number of species that occur (or co-occur) within a
particular area: circles 1 or 2 species, triangles 3–5 species, squares
6–9 species; pentagons, 10 or more species. Daggers denote
confirmed and purported fossil records of Cola
A recently discovered fossil leaf compression from the
Late Oligocene of Ethiopia (28–27 Ma) Guang River flora
can be identified confidently as Cola and is described
below. This fossil represents the oldest record of the genus.
The presence of a fossil Cola from Ethiopia is interesting
biogeographically because the genus is not present there
today (Friis 1992; Vollesen 1995) and indicates a different
distribution on the Afro-Arabian continent during the
Paleogene (Fig. 1). In addition, the genus is an indicator of
moist forest communities and thus provides insight into the
Late Oligocene vegetation on the northwestern Ethiopian
plateau.
Very little information on the epidermal anatomy of
living Cola has been published and no data are available
regarding the leaf epidermal anatomy of Octolobus or
Pterygota. The only sources of data about epidermal
micromorphology within Cola are Gehrig (1938), Metcalfe
and Chalk (1950), and Inamdar et al. (1983), none of which
are comprehensive. Consequently, leaf cuticle samples
from several extant species of Cola and some species of
Octolobus and Pterygota were prepared, examined, and
described to provide comparative epidermal micromorphological characters. These data have proven useful in
identification of the fossil and are provided here for future
systematic and phylogenetic investigations of the genus
and the Sterculioideae (Table 1 and Appendix).
123
Cuticle was prepared from fossil leaf fragments (0.5–
1 cm2) by first rinsing the material in 10% hydrochloric
acid (HCl) for 10–30 min to remove carbonates. The leaf
material was then rinsed with distilled water and placed in
a solution of 48% hydrofluoric acid (HF) for 24–48 h to
dissolve the silicate matrix. Following this step, the cuticle
was placed in a 20% bleach (NaClO)–water solution for a
very brief amount of time (on the order of 20 s to 1 min) to
dissolve away excess organics. The cuticle was thoroughly
rinsed with distilled water and mounted on microscope
slides in glycerine.
Leaf cuticle samples from 38 extant species of Cola, 2
species of Octolobus, and 2 species of Pterygota were
sampled for comparative purposes from herbaria at the
Missouri Botanical Garden (MO) and the Royal Botanic
Gardens at Kew (K). Samples (0.5–1 cm2) were soaked in
distilled water for 24 h to resaturate. Subsequently, the
specimens were treated with a solution of 10% potassium
hydroxide (KOH) until they darkened fully, washed with
distilled water, and placed in baths of 30–60% bleach to
remove mesophyll. The cleared specimens were then
stained with a Safranine O solution, rinsed with 90%
ethanol (C2H5OH), and mounted on microscope slides in
glycerine jelly. Light microscope slides of both the fossil
and herbarium samples are housed in the Roy M.
Huffington Department of Earth Sciences at Southern
Methodist University in Dallas, TX.
Most of the terminology and definitions used in the text
and Appendix are taken from the Manual of Leaf Architecture (Ellis et al. 2009) and Dilcher (1974). Where terms
differ, they are defined in the text. Dominant abaxial
and adaxial trichome characters (characters 26 and 41 in
Table 1 and Appendix) were determined by randomly
observing 100 hairs among the prepared cuticle microscope
slides of each species. In cases where fewer than 100 hairs
were present on a slide, trichome dominance was based on
a percentage of fewer than 100 randomly observed hairs. If
the number of hairs observed was fewer than 20, and there
were more than two hair types present the character state
was scored as ‘‘no trichomes predominate.’’ Epidermal cell
sizes are recorded in measured micrometer ranges (lm;
characters 14 and 29 in Table 1, Appendix). For these
measurements only nonsubsidiary epidermal cells that
were not adjacent to veins or hairs were included.
The Guang River flora
The newly discovered Ethiopian Late Oligocene (28–
27 Ma) fossil is from a moderately diverse assemblage
(approximately 40 morphotypes, assumed to be species) of
well-preserved leaf, floral, and wood (logs and stumps)
Species
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Cola acuminata (P. Beauv.) Schott & Endl.
0
0
0
1
0
0
0,1
1,2
1
1
0
2
0?1
22.5–55; 19–35.5
0
Cola altissima Engl.
0
0,1
0
1
0
0
1
1
1
1
0
2
0?1
13–54.5; 9.5–22.5
0
Cola amharaensis sp. nov. A.D. Pan & B.F. Jacobs*
0
?
0
1
0
0
0
?
1
1
0
2
0?1
16.5–53; 9.5–35.5
0
Cola attiensis Aubrév. & Pellegr.
0
0,1,3
0
1
0
0
0,1
1,2
1
1,2
0
2
0?1
19–51.5; 16–26
0
Cola ballayi Cornu ex Heckel
0
0,2,3
0
1
0
0
0,1
1,2
1
1
0
2
0?1
16–53; 8–29
0
Cola buntingii Bak. f.
1
1
0
1
0
0
1
2
0
?
0
2
0?1
11–64.5; 9.5–29
0
Cola caricaefolia (G. Don) K. Schum.
0
0,1
0
0
1
2
3
1,2
2
1
0
2
0?1
19–64.5; 13–45
0
Cola chlamydantha K. Schum.
1
0,1
1
2
0
0
1
2
0
1,2
0
2
0?1
14.5–45; 16–31
0
Cola clavata Mast.
0
1
0
1
0
0
0
1
1
0,1
0
2
0?1
12.5–32.5; 9.5–16
0
Cola cordifolia (Cav.) R. Br.
0
0,2
0
1
0,1
2
3
0,1,2
1,2
0,1
0
2
0?1
6.5–16.5; 6.5–13
0
Cola digitata Mast.
1
0
0
1
1
0
0
1
1
0,1
0
2
0?1
9.5–50; 6.5–32.5
0
Cola discoglypremnophylla Brenan & A. P. D. Jones
0
0
0
2
0
0,2
1,3
?
1
0
0
2
0?1
16–34; 8–27.5
0
0
Cola ficifolia Mast.
0
0,1
0
1
1
0,1,2
1,3
1
1,2
1,2,3
0
2
0?1
25.5–77.5; 9.5–42
Cola flavo-velutina K. Schum.
0
0
0
1
0
0
0
2
1
1
0
2
0?1
16–59.5; 9.5–35.5
0
Cola gabonensis Mast., non sensu Aubrév., nec sensu M. Bodard
0
1
0
0
0
0
1
1,2
0,1
1
0
2
0?1
35.5–61; 19–42
0
Cola greenwayi Brenan
Cola heterophylla (P. Beauv.) Schott & Endl.
0
0
0,1
0,1
0
0
1
0
0
0,1
0
0,1
1
1,3
1,2
2
0,1
1,2
1,2
0,1
0
0
2
2
0?1
0?1
16–40; 9.5–24
24–71; 22.5–35
0
0
Cola hispida Brenan & Keay
0
1
0
0
1
2
3
1
2
1
0
2
0?1
32–84; 29–48.5
0
Cola lateritia K. Schum.
0
0,1,2
0
1
0,1
2
3
0,1
2
1
0
2
0?1
24–38.5; 9.5–32.5
0
Cola laurifolia Mast.
0
0
0
1
0
0
1
0, 1
0
0,1
0
2
0?1
8–32.5; 6–22.5
0
Cola lepidota K. Schum.
1
0,2
1
1
0
0
0,1
1
0
1
0
2
0?1
16–65.5; 12.5–39
0
Cola letouzeyana Nkongmeneck
0
1
1
1
0
1,2
3
1,2
2
1
0
2
0?1
29–68; 19.5–29
0
Cola lissachensis Pellegr.
1
1
1
1
0
0
0
2
0
2,3
0
2
0?1
13–45; 13–29
0
Cola mahoundensis Pellegr.
0
0,1
0
0
1
1
3
1
2
1
0
2
0?1
22.5–77.5; 14.5–32.5
0
Cola marsupium K. Schum.
0
0,1
0
0
0,1
2
3
2
2
0,1
0
2
0?1
29–100; 16–47
0
Cola millenii K. Schum.
0
0,1
0
0
0
1,2
1,3
1
1,2
1
0
2
0?1
12.5–58; 4.5–29
0
Cola minor Brenan
0
0,1
0
1
0
0
0
1
0
1,2
0
2
0?1
9.5–39; 9.5–19.5
0
Cola mossambicensis Wild
0
0,2
0
1
0
0
1
0,1
1
1
0
2
0?1
9.5–32.5; 6–16
0
Cola natalensis Oliver
0
0,1
0
1
0
0
1
1,2
0
1
0
2
0?1
9.5–39; 9.5–19.5
0
Cola nigerica Brenan & Keay
0
0
0
1
0
0
0,1
2
1
1
0
2
0?1
20.5–58; 12.5–39
0
Cola nitida (Vent.) Schott & Endl.
Cola pachycarpa K. Schum.
0
1
0,1
0,1
0
0
1
2
0
0?2
0
0
1
1
1,2
1,2
1
0
0,1
2
0
0
2
2
0?1
0?1
22.5–58; 8–31
16–61; 12.5–21
0
0
0
0
0,1
0
1
0
0
1
2
0,1
0,1
0
2
0?1
9.5–52; 8–19.5
0
0,2
0
0
0,1
1,2
1,3
1
1,2
0,1
0
2
0?1
22.5–71; 12.5–53.5
0
Cola simiarum Sprague ex Brenan & Keay
0
0,3
0
0
2
0
1
2
1
0,1
0
2
0?1
9.5–37; 6.5–22.5
0
Cola stelechantha Brenan
0
0,1
0
1
0
0
1
1,2
0,1
1
0
2
0?1
16–68; 9.5–31
0
249
123
Cola porphyrantha Brenan
Cola scheffleri K. Schum.
The earliest record of the genus Cola from the Late Oligocene
Table 1 Leaf morphology and epidermal micromorphology characteristics within Cola, Octolobus, and Pterygota
250
123
Table 1 continued
Species
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
0
Cola uloloma Brenan
0
0,1
1
1
0
0
1
1,2
0
0,1
0
2
0?1
15.5–42; 13–23
Cola usambarensis Engl.
0
0
0
1
0
0
1
1,2
1
0,1
0
2
0?1
16–55; 9.5–22.5
0
Octolobus spectabilis Welw.
0
0,1
0
1
0
0
1
2
0,1
1
0
2
0?1
19–45; 12.5–29
0
Octolobus zenkeri Engl.
0
0
0
1
0
0
1
2
1
1
0
2
0?1
12.5–37; 9.5–19.5
0
Pterygota bequaertii De Wild.
0
2
0
1
0
1,2
2,3
1,2
2
0,1
0
2
0?1
16–48.5; 16–22.5
0
Pterygota macrocarpa K. Schum.
0
2
0
1
0
2
3
0,1
2
0,1
0
2
0?1
12.5–55; 9.5–35.5
0
27
28
Species
16
17
18
19
20
21
22
23
24
25
26
29
30
Cola acuminata
0?1
–
1
1
1 ? 2?3
0
0
0
2(?3)
(?0 ?)2 ? 3
0
1
0?1
9.5–43.5; 8–27.5
0
Cola altissima Engl.
0?1
–
1
1
1 ? 2?3
0
0
0
2
2?3
0
0
0?1
22.5–48.5; 12.5–34
0
Cola amharaensis*
0?1
–
1
1
2
0
0
0
1
2
0
0
0?1
24–42; 14.5–31
0
Cola attiensis
0?1
–
1
1
2
0
0
0
1
2
0
0
0?1
16–39; 14.5–21
0
Cola ballayi
0?1
–
1
1
1 ? 2?3
0
0
0
1
2
0
0
0?1
11–39; 14.5–26
0
Cola buntingii
1?2
0
1
1
1?3
0
0
0
2
2?3
0
0
0?1
16–42; 13–16
0
Cola caricifolia
1?2
0
1
1
1 ? 2?3
0
0
0
1
2
0
0
0?1
16–55; 12.5–35.5
0
Cola chlamydantha
1?2
0
1
1
0 ? 1?2
0
1,3
0
2
1?3
0
0
0?1
6.5–29; 4.5–18
0
Cola clavata
1
–
1
1
2
0
0
0
2
2?3
1
0
0?1
9.5–24; 3–19.5
0
Cola cordifolia
1
–
1
1
2
0
0
0
2
2?3
2
0
0?1
6–22.5; 6–16
0
Cola digitata
0 ? 1?2
0
1
1
1
0
0
0
2
2?3
0
0
0?1
11–35.5; 11–22.5
0
Cola discoglypremnophylla
0?1
–
1
1
2
0
0
0
1
2
0
1
0?1
16–35.5; 11–27.5
0
Cola ficifolia
1?2
0
1
1
1?2
0
3
0
2
2?3
0
0
0?1
19–45; 12.5–27.5
0
Cola flavo-velutina
Cola gabonensis
0?1
2
–
0
1
1
1
1
2
2
0
0
0
0
0
0
2
2
2?3
2?3
0
0
0
0
0?1
0?1
19–39; 16–24.5
25.5–64.5; 22.5–42
0
0
Cola greenwayi
1?2
0
1
1
2
0
0
0
2
2?3
2
1
0?1
16–39; 11–29
0
Cola heterophylla
1?2
0
1
1
1?2
0
0
0
2
2?3
0
0
0?1
39–68; 35–40
0
Cola hispida
1?2
0
1
1
2
0
0
0
2
2?3
0
0
0?1
38.5–82; 25.5–51.5
0
0
Cola lateritia
0?1
–
1
1
0 ? 1?2 ? 3
0
0
0
1
2
0
0
0?1
27–38.5; 8–32
Cola laurifolia
0?1
–
1
1
0
0
0
0
2
2?3
1
0
0?1
11–31; 6.5–19.5
0
Cola lepidota
0?1
–
2
1
1?2
0
1,3
0
2
2?3
1
0
0?1
13–32; 13–24
0
1?2
0
1
1
2
0
0
0
2
2?3
0
1
0?1
19–40; 16–29
0
0?1
–
1
1
0 ? 1?2 ? 3
0
1,3
0
2
2?3
1
0
0?1
11–25.5; 11–22.5
0
Cola mahoundensis
2
0
1
1
1?2
0
0
0
3
0 ? 2?3
1
0
0?1
22.5–58; 22.5–39
0
Cola marsupium
1?2
0
1
1
2
0
0
0
1
2
0
0
0?1
25.5–55; 16–29
0
Cola millenii
0?1
–
1
1
1 ? 2?3
0
0
0
3
0 ? 2?3
0
0
0?1
25.5–51.5; 9.5–42
0
Cola minor
0?1
–
1
1
2
0
0
0
1
3
2
0
0?1
9.5–29; 6.5–18
0
Cola mossambicensis
0?1
–
1
1
2
0
0
0
2
2?3
0
0
0?1
12.5–26; 6–19.5
0
A. D. Pan, B. F. Jacobs
Cola letouzeyana
Cola lissachensis
Species
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
Cola natalensis
1?2
0
1
1
2
0
0
0
1
3
2
0
0?1
9.5–32.5; 9.5–16
0
Cola nigerica
0
–
1
1
1?3
0
0
0
1
2
0
0
0?1
16–52; 12.5–40.5
0
Cola nitida
0
–
1
1
1 ? 2?3
0
0
0
2
2?3
0
0
0?1
12.5–42; 9.5–26
0
Cola pachycarpa
0?1
–
1
1
1
0
1,3
0
2
2?3
0
0
0?1
16–45; 12.5–29
0
Cola porphyrantha
1?2
0
1
1
1?2
0
0
0
2
2?3
0
0
0?1
9.5–22.5; 8–21
0
Cola scheffleri
2
0
1
1
1 ? 2?3
0
0
0
1
2
0
0
0?1
38.5–68; 19–42
0
Cola simiarum
0
–
1
1
0 ? 1?2
0
1
0
1
2
0
0
0?1
9.5–51.5; 6–42
0
Cola stelechantha
0?1
–
1
1
1?2
0
0
0
2
2?3
0
0
0?1
25–58; 12.5–32.5
0
Cola uloloma
1
–
1
1
2
0
0
0
2
2?3
0
0
0?1
16–33; 12.5–31
0
Cola usambarensis
0?1
–
1
1
2
0
0
0
1
3
2
0
0?1
16–39; 12.5–24
0
Octolobus spectabilis
0?1
–
1
1
2
1
0
0
2
2?3
1
0
0?1
14.5–43.5; 12–37
0
0
Octolobus zenkeri
0 ? 1?2
0
1
1
2
0
0
0
2
2?3
1
1
0?1
14.5–32.5; 9.5–30
Pterygota bequaertii
2
0
2
1
1 ? 2?3
0
0
0
2
2?3
0
0
0?1
16–39; 9.5–35.5
0
Pterygota macrocarpa
1?2
0
1
1
2
0
0
0
2
2?3
0
0
0?1
12.5–32.5; 9.5–19.5
0
Species
31
32
33
34
35
36
37
38
39
40
41
The earliest record of the genus Cola from the Late Oligocene
Table 1 continued
42
Cola acuminata
0?1
–
1
0
–
–
–
–
2
2?3
0
1
Cola altissima
0?1
–
1
0
–
–
–
–
2
2?3
1
0
Cola amharaensis*
1?2
0
1
0
–
–
–
–
?
?
?
0
Cola attiensis
0 ? 1?2
0
1
0
–
–
–
–
2
2?3
0
0
Cola ballayi
0?1
–
1
0
–
–
–
–
1
3
2
0
Cola buntingii
Cola caricifolia
1?2
0?1
0
–
1
1
0
0
–
–
–
–
–
–
–
–
2
1
2?3
2
2
0
0
0
Cola chlamydantha
1
–
1
1
0,3
0
0
0
1
3
2
0
Cola clavata
1
–
1
0
–
–
–
–
1
3
2
0
Cola cordifolia
0?1
–
1
0
–
–
–
–
2
2?3
1
0
Cola digitata
0?1
–
1
0
–
–
–
–
2
2?3
1
0
Cola discoglypremnophylla
1?2
0
1
1
0
0
0
0
1
3
2
0
Cola ficifolia
0?1
–
1
0
–
–
–
–
2
2?3
2
0
Cola flavo-velutina
1?2
0
1
0
–
–
–
–
1
2
0
0
Cola gabonensis
0?1
–
1
0
–
–
–
–
2
2?3
0
0
0
1?2
0
1
0
–
–
–
–
2
2?3
2
1
–
1
1
2
0
0
0
1
2
0
0
Cola hispida
0?1
–
1
1
2
0
0
0
2
2?3
0
0
Cola lateritia
0?1
–
1
0
–
–
–
–
2
2?3
0
0
Cola laurifolia
0?1
–
1
0
–
–
–
–
2
2?3
2
0
251
123
Cola greenwayi
Cola heterophylla
252
123
Table 1 continued
Species
31
32
33
34
35
36
37
38
39
40
41
42
Cola lepidota
0
–
1
0
–
–
–
–
1
3
2
0
Cola letouzeyana
1?2
0
1
0
–
–
–
–
2
2?3
2
0
Cola lissachensis
0?1
–
1
1
0
0
0
0
2
2?3
2
0
Cola mahoundensis
1?2
0
1
0
–
–
–
–
1
2
0
1
Cola marsupium
0?1
–
1
0
–
–
–
–
1
2
0
0
Cola millenii
0?1
–
1
0
–
–
–
–
3
0 ? 2?3
0
0
Cola minor
0?1
–
1
0
–
–
–
–
1
3
2
0
Cola mossambicensis
0?1
–
1
0
–
–
–
–
1
3
2
0
Cola natalensis
0?1
–
1
0
–
–
–
–
1
3
2
0
Cola nigerica
0
–
1
0
–
–
–
–
1
3
2
0
Cola nitida
0?1
–
1
0
–
–
–
–
2
2?3
0
0
Cola pachycarpa
0?1
–
1
0
–
–
–
–
1
1
0
0
Cola porphyrantha
1?2
0
1
1
2
0
0
0
1
3
2
0
Cola scheffleri
Cola simiarum
2
0?1
0
–
1
1
0
0
–
–
–
–
–
–
–
–
2
0
0?2
?
0
?
0
?
Cola stelechantha
0
–
1
0
–
–
–
–
2
2?3
1
0
Cola uloloma
1
–
1
0
–
–
–
–
1
?
2
0
Cola usambarensis
1?2
0
1
0
–
–
–
–
1
3
2
0
Octolobus spectabilis
0?1
–
1
0
–
–
–
–
1
3
2
0
Octolobus zenkeri
1?2
0
1
0
–
–
–
–
2
2?3
2
0
2
0
–
–
–
–
2
2?3
1
0
0
1
0
–
–
–
–
2
2?3
0
0
Pterygota bequaertii
1
Pterygota macrocarpa
1?2
See Appendix for characters and character states. A comma separating more than one number (e.g., ‘‘1, 2’’) denotes that a particular species can have more than one character state for a
particular character, but these character states do not co-occur on the same leaf. The symbol ‘‘?’’ (as in ‘‘1 ? 2’’) denotes that a species can have two or more co-occurring character states. The
symbols ‘‘–’’ and ‘‘?’’ indicate that the character is not applicable or the state of a particular character is unknown, respectively. Asterisk (‘‘*’’) indicates the fossil Ethiopian Cola species in the
table. Characters 14 and 29 are length and width ranges given in micrometers (lm)
A. D. Pan, B. F. Jacobs
The earliest record of the genus Cola from the Late Oligocene
compressions, known as the Guang River flora (Pan et al.
2006; Pan 2007). The flora is located in the northwestern
plateau region of Ethiopia, about 60 km west of Gondar (in
the Chilga Woreda, Amhara region; Fig. 1). Rocks of this
region consist of massive Oligocene trap basalts interspersed with tuffs, lignites, and fluvial volcaniclastic and
clastic sediments exposed along streams and gullies (Mohr
1971; Yemane et al. 1987; Kappelman et al. 2003; Jacobs
et al. 2005). Along a portion of the Guang River, a 100 m
sedimentary section has been dated to between 28 and
27 Ma (Chron C9n) based on K–Ar and 40Ar/39Ar radiometric dates and paleomagnetic reversal stratigraphy
(Kappelman et al. 2003; Cande and Kent 1995). Fossils are
prevalent in these sediments and include plants, mammals,
and invertebrates (Kappelman et al. 2003; Sanders et al.
2004; Pan et al. 2006; Garcı́a Massini et al. 2006).
The autochthonous or parautochthonous Guang River
flora is preserved in an approximately 22-cm-thick massive
greenish-gray mudstone layer derived from a weathered
overbank (or pond) ash deposit, which provided the parent
material for an overlying Gleysol (Jacobs et al. 2005; Pan
et al. 2006; Pan 2007). The fossiliferous sediment is
underlain by a hard 1-cm-thick lignitic layer and overlain
by a 70-cm-thick yellowish-green silty claystone. Gleysols
are commonly formed in areas with high water tables that
are waterlogged for most of the year; lignites are derived
from organically rich, waterlogged soils characterized by
chemically reducing conditions (Mack et al. 1993). Based
on the sediments in which the fossils are preserved, the
large number of entire-margined notophyllous to mesophyllous leaf taxa present, species composition, and the
high species heterogeneity over short distances (based on
lateral sampling), the flora likely represents a moist tropical
forest community growing in swampy or water-saturated
(at least for a large portion of the year) conditions.
Results
Systematic Paleobotany
Malvaceae Juss. 1789
Sterculioideae Burnett 1835
Cola Schott & Endl. 1832
Cola amharaensis sp. nov. A. D. Pan and B. F. Jacobs
Diagnosis Entire-margined, mesophyllous leaf with
cuneate base, apical pulvinus, and triplinerved basal
venation (Fig. 2). Primary venation is pinnate, secondary
venation is brochidodromous, and tertiary venation is
alternate percurrent with admedially ramified veins
(Fig. 2). Abaxial leaf epidermal cells are rectangular and
isodiametric (Figs. 3, 4). Stomatal complexes are brachyparacytic and restricted to the abaxial side of the leaf
253
Fig. 2–7 Cola amharaensis Pan and Jacobs sp. nov. and Cola flavovelutina. Fig. 2. Cola amharaensis Holotype CH41-P36/CH41-P41;
scale bar 15 mm. Fig. 3. Brachyparacytic stomata of C. amharaensis; scale bar 30 lm. Fig. 4. Multicellular glandular hairs of
C. amharaensis; scale bar 30 lm. Fig. 5. Leaf of Cola flavo-velutina;
scale bar 15 mm. Fig. 6. Brachyparacytic stomata of C. flavovelutina; scale bar 30 lm. Fig. 7. Multicellular glandular hairs of
C. flavo-velutina; scale bar 30 lm
(Fig. 3). Anticlinal cell walls are rounded to undulate and
have bead-like thickenings. Periclinal cell walls have a
stippled texture (Figs. 3, 4). Abaxial glandular hairs possess
globose or capitate heads and are uniseriate or biseriate and
multicellular (Fig. 4). Buttressed hair bases are present on
the adaxial surface.
Description Mesophyllous leaf compression fragment
(and counterpart) with length of 78 mm and maximum
width of 58.5 mm. The entire-margined lamina is either
elliptic or obovate and symmetrical. The base is cuneate
and has an acute angle. The petiole has an apical pulvinus
(4 mm long, 2.5 mm wide) which is attached at the top of a
13-mm-long petiole fragment (Fig. 2). The primary venation is pinnate, although the leaf is triplinerved at the base
with secondary veins (oriented at more acute angles than
subsequent secondaries) following parallel to the margin,
123
254
A. D. Pan, B. F. Jacobs
thinning toward a connection to the next pair of secondaries (Fig. 2). Secondary venation is brochidodromous and
the spacing between pairs of secondary veins decreases
somewhat towards the base. Weak intersecondaries are
present and merge with the tertiary veins. Tertiary venation
is alternate percurrent with admedially ramified vein
course. Quaternary veins form a regular polygonal reticulate pattern. Cuticle: Abaxial cells are isodiametric to
rectangular in shape and are 16–53 lm long and 10–36 lm
wide (Fig. 3). Abaxial anticlinal cell walls are generally
straight to rounded and possess bead-like thickenings.
Abaxial epidermal periclinal cell surfaces are stippled. The
stomatal complex is brachyparacytic and stomata are
restricted to the abaxial leaf surface (Fig. 3). Glandular
trichomes are present and consist of a single foot cell and
uniseriate or biseriate multicellular, generally 3–4 layered,
globose or capitate head (Fig. 4). The glandular trichomes
range in size from 29 to 35.5 lm long and from 32 to
42 lm wide (Fig. 4), typically wider than long. Adaxial
cells are isodiametric, 24–42 lm long and 15–31 lm wide.
The adaxial epidermal cell surface ornamentation is similar
to that of the abaxial side. Anticlinal cell walls are rounded
to undulate. Trichome bases, which may have buttresses,
have been observed on the adaxial surface and, based on
morphology, likely represent glandular hairs (Fig. 17).
Holotype CH41-P36/CH41-P41 (Fig. 2); found at sublocality CH41 in the Guang River flora. This specimen is
housed at the National Museum of Ethiopia in Addis Ababa.
Etymology The species is named for the Amhara Province of Ethiopia where the fossil and the Guang River flora
were found.
Remarks The fossil can be placed in the genus Cola
based on the following characteristics: simple leaves with
entire margins, cuneate base with an acute angle and triplinerved veins, the presence of a pulvinus at the apex of the
petiole (Figs. 2, 5), weak brochidodromous secondary
venation, and the presence of multicellular glandular hairs
on the epidermal surfaces of the leaf (Figs. 4, 7). The fossil
differs from Octolobus in possessing a cuneate leaf base
and trichomes that are solely glandular. Also, Octolobus
spectabilis has stomatal complex chains and clusters
(Fig. 23), defined here as four or more adjacent stomatal
complexes lacking separating epidermal (nonsubsidiary)
cells, a characteristic that is absent in the fossil and almost
all extant species of Cola observed, excluding C. letouzeyana. The fossil differs from Pterygota, which have subcordate/cordate, rounded, or almost truncate bases.
Based on leaf
the fossil most
C. flavo-velutina
African species.
123
and epidermal characters of the species,
closely resembles Cola attiensis and
(Fig. 5), two extant West and Central
The fossil is similar to both in (1)
possessing a simple-entire margined leaf with a cuneate
base, (2) triplinerved basal veins which fade towards the
margin, (3) straight to rounded abaxial anticlinal cell walls
(Fig. 2), (4) brachyparacytic stomata (or rarely other paracytic stomatal complex types) restricted to the abaxial side
(Fig. 3), (5) multicellular glandular hairs present and
dominant (C70% of hairs encountered are glandular) on the
abaxial surface (Fig. 4), and (6) adaxial anticlinal cell walls
that are rounded to undulate. In addition, hair bases similar
to those of the multicellular glandular hairs of the abaxial
side are present on the adaxial surface. These bases may
indicate that glandular hairs are present and possibly predominant on the adaxial cell surface of the fossil, a
characteristic that also occurs within Cola attiensis and
C. flavo-velutina. Furthermore, the length and width ranges
of abaxial and adaxial epidermal cells in the Ethiopian Cola
are quite similar those in C. attiensis and C. flavo-velutina.
Cola attiensis is a small tree or shrub found along river
banks or moist ground in evergreen forest growing on
sandy clays in Côte d’Ivoire and has been reported from
Cameroon and Gabon (Hallé 1961; Lebrun and Stork 2003;
Holmgren et al. 2004). Cola flavo-velutina is a shrub or
tree growing in the understorey of very moist rainforest in
Ghana, Nigeria, Cameroon, and Gabon (Hallé 1961;
Lebrun and Stork 2003).
While the fossil differs little from Cola attiensis and
C. flavo-velutina based on the characters mentioned above,
the fossil is placed in a new species Cola amharaensis
because it differs by having buttresses on some adaxial hair
bases (Fig. 17; buttresses were absent from all hair bases
observed in C. attiensis and C. flavo-velutina), an absence
of stellate/peltate hairs or hair bases on the abaxial surface
(stellate hairs are present in Cola flavo-velutina), and a lack
of straight anticlinal cell walls on the adaxial surface (which
can occur within C. attiensis). The closest resemblance to
Cola amharaensis sp. nov. among the eastern African
species observed in this study is C. usambarensis, which
differs from the fossil in having a convex leaf base and
possessing only stellate/peltate hairs on its leaf surfaces.
Other eastern and southern Cola species not included in
this study are not similar to the fossil (Keay and Brenan 1973;
Brenan 1978; Verdoorn 1981; Coates Palgrave 1977; White
et al. 2001; Cheek 2002). Primary differences include
leaf base morphology (Cola chlorantha, C. congolana,
C. gigantea, C. lukei, and C. octoloboides), and the absence
of triplinerved or trinerved venation at the base of the leaf
(C. congolana).
Comparative leaf morphology in extant Cola,
Octolobus, and Pterygota
A variety of leaf types are present within the Cola ?
Octolobus ? Pterygota clade sensu Wilkie et al. (2006).
The earliest record of the genus Cola from the Late Oligocene
These include both simple and palmately compound leaved
species, which are entire-margined, and may be unlobed or
lobed. Simple, unlobed, entire-margined leaves are often
trinerved (or triplinerved). Cola, a relatively large genus,
has a diverse array of leaf morphologies, while Octolobus
consists solely of entire-margined, unlobed, simple-leaved
species. Octolobus spectabilis is usually not trinerved at the
base, but trinerved basal veins do occur consistently within
O. heteromerus and O. zenkeri. Pterygota species can have
either lobed or unlobed leaves, are usually palmately
veined, and often have a cordate or subcordate base,
although nearly truncate bases may also occur.
255
Stellate/peltate hairs
The majority of species have deciduous stellate/peltate
hairs with only polygonal (usually pentagonal or hexagonal)-shaped hair bases with thickened margins and acute
points present (Fig. 11). However, whole stellate/peltate
trichomes are abundant on the abaxial surfaces of Cola
cordifolia and C. lepidota. Intact hairs also occur more
sporadically in Cola heterophylla (abaxial), C. lateritia
(adaxial), C. mahoudensis (abaxial; Fig. 10), C. millenii
(abaxial), and Pterygota bequaertii (adaxial).
Glandular hairs
Micromorphology
Epidermal cells
Most epidermal cells within all three genera are isodiametric or rectangular in shape and 3–8 sided (Fig. 8).
Abaxial epidermal cells range in size from 8 to [100 lm
long and 6 to 48.5 lm wide. Adaxial cells range from 65 to
85 lm in length and 3 to 51.5 lm in width. Species typically have anticlinal cell walls that are either straight to
rounded, or rounded to undulate in shape. If undulate, the
sinuous walls are widely to narrowly U-shaped (Fig. 8).
Fine to prominent stippled ornamentation is present on the
abaxial and adaxial periclinal cell walls of almost all species of Cola and Octolobus that we observed (Fig. 8).
Stippled ornamentation also occurs in Pterygota macrocarpa. Striations are present on the abaxial and adaxial
(though slightly less defined) periclinal cell walls of
Pterygota bequaertii (Fig. 9) and abaxially in Cola lepidota. Anticlinal cell wall thickenings are present on all
species observed, the most common types being ‘‘knoblike’’ (Fig. 2) and ‘‘T-shaped,’’ which are defined and
illustrated in Dilcher (1974).
Trichomes
A variety of different trichome (hair) types occur within the
Malvaceae s.l. Although the family is often known for stellate,
peltate, and tufted trichomes (Figs. 10, 11; Metcalfe and
Chalk 1950; Bayer and Kubitzki 2003; Judd et al. 2008), other
types are also common. These include clavate or capitate
(globose) multicellular glandular (Figs. 12, 13), unicellular
glandular, and simple hairs (Fig. 14). Trichome types found
within Cola include glandular, simple unicellular, and stellate/
peltate hairs (Figs. 10, 12, 13, 14; in most cases a polygonal
base is usually the only indication of the presence of stellate/
peltate hairs; Fig. 11). Glandular hairs and stellate/peltate hair
bases were observed in all Octolobus and Pterygota species
examined; however, simple trichomes were absent among
observed species within these two genera.
Glandular hairs were observed in almost every species of
Cola, Octolobus, and Pterygota examined with the
exception of Cola minor, C. natalensis, and C. usambarensis (Table 1; Appendix). Hair bases are often thickened
and can exhibit buttresses, as in Cola ballayi, C. discoglypremnophylla (Fig. 16), and C. simiarum. Glandular
hairs emerge from a unicellular rectangular base cell
(Fig. 12). Most glandular hairs occur singly, but twinned
glandular hairs can be found in Cola acuminate (Fig. 13),
C. discoglypremnophylla, C. letouzeyana, and Octolobus
zenkeri.
Simple hairs
Simple hairs are quite rare within Cola and were only
observed in C. mahoundensis (Fig. 14), C. millenii, and
C. scheffleri. While it should be noted that Inamdar et al.
(1983) reported occasional simple hairs in Cola acuminata,
none were observed in this study.
Silica bodies
Silica bodies were observed in several species of Cola,
particularly around the veins (Fig. 15). When silica bodies
were observed, the majority were found on the abaxial
surface of the leaf. Cola acuminata is unusual in having
silica bodies both abaxially and adaxially, but they are
noticeably more numerous on the abaxial surface.
Silica bodies resemble jagged spheres and are usually on
the order of 3–4 lm in diameter (Figs. 9, 15).
Stomata
Nearly all stomata found within Cola, Octolobus, and
Pterygota are restricted to the abaxial leaf surface, however
a few isolated stomata occur on the adaxial surface in Cola
chlamydantha, C. discoglypremnophylla, C. heterophylla,
C. hispida, and C. porphyrantha. The majority of species
have brachyparacytic and paracytic stomatal complexes
123
256
A. D. Pan, B. F. Jacobs
Fig. 8–15 Leaf epidermal
micromorphology; scale bars
30 lm. Fig. 8. Stippled
ornamentation on the adaxial
epidermal cells of Cola flavovelutina. Fig. 9. Striated
epidermal abaxial surface and
silica bodies of Pterygota
bequaertii. Fig. 10. Stellate hair
on the abaxial surface of Cola
mahoundensis. Fig. 11. Stellate
or peltate remnant hair base on
the abaxial of C. minor.
Fig. 12. Multicellular glandular
hair on the abaxial surface of
C. mahoundensis. Fig. 13.
Twinned or coupled glandular
hairs on the abaxial surface of
C. acuminata. Fig. 14. Abaxial
unicellular simple trichome of
C. mahoundensis. Fig. 15.
Adaxial stone cells of
C. buntingii
(Figs. 3, 16, 18; however, tetracytic (Fig. 20) and anisocytic types are not uncommon and can be prevalent in some
species (Fig. 21; Table 1). Rarer stomatal complex types
including hemiparacytic, cyclocytic, hexacytic, and
anomocytic types can be found among a few species
(Figs. 19, 21; Table 1).
123
Discussion
Fossil record
The fossil record, besides the Guang River flora Cola sp.
leaf compression, includes a flower and possibly a leaf cast
The earliest record of the genus Cola from the Late Oligocene
257
Fig. 16–23 Leaf epidermal
micromorphology cont. Abaxial
surfaces; scale bars 30 lm.
Fig. 16. Buttressed hair base on
the abaxial surface of Cola
discoglypremnophylla.
Fig. 17. Buttressed hair base on
the adaxial surface of Cola
amharaensis Pan sp. nov.
Holotype CH41-P36/CH41-P41.
Fig. 18. Brachyparacytic
stomata (a paracytic stomatal
complex type) of C. uloloma.
Fig. 19. Anomocytic stoma
(a polycytic stomatal complex
type) of C. ballayi.
Fig. 20. Tetracytic stomata of
C. ballayi. Fig. 21. Hexacytic
stoma of C. nitida. Fig. 22.
Thickened periclinal wall
surrounding the stomata of
C. lissachensis. Fig. 23.
Stomatal complex cluster of
Octolobus spectabilis
from the Early Miocene of Uganda, fossil wood of the form
genus Colaxylon from the Late Neogene of Ethiopia and
Chad, a fossil denoted as cf. Cola from the Early Miocene
of Kenya, and several species of Cola and Octolobus
reported from the Late Neogene of Cameroon (Fig. 1,
Menzel 1920; Hamilton 1968; Koeniguer 1973; Lemoigne
1978; Jacobs and Winkler 1992). A fossil seed attributed to
cf. Cola from the Cretaceous of Senegal (Monteillet and
Lappartient 1981) does not appear to be similar to the
extant genus.
Fossil wood of the form genus Colaxylon is reported by
Koeniguer (1973) and Lemoigne (1978) from the Late
Neogene of Chad and Ethiopia, respectively. While it is
possible that these fossil woods may have affinity to Cola,
123
258
many genera within the Sterculioideae have similar wood
anatomical structures (Metcalfe and Chalk 1950).
The fossil flower from the Bukwa locality in western
Uganda is Early Miocene (19.5–19.1 Ma based on
40
Ar/39Ar radiometric dating of lavas; Maclatchy et al.
2006). Hamilton (1968) considered the floral cast to have
affinities with either Cola or Pterygota based on the nearsessile attachment of two whorls of bilobed anthers to the
staminal tube (androgynophore), and the presence of five
partially fused sepals. In the illustration provided by
Hamilton (1968: Fig. 1a), a structure at the apex of the
androgynophore appears to be 4–5 vestigial fused carpels
as occurs on male flowers in species of Cola and Pterygota.
Hamilton (1968), who compared the fossil to living
Ugandan Cola and Pterygota species, considered it to be
most similar to Cola gigantea A. Chev., which is found
only in Uganda and is often confused with Cola cordifolia,
a species restricted to western Africa (Lebrun and Stork
2003). However, in our opinion the fossil’s loose interdigitating whorls of stamens compares more closely to the
genus Pterygota, rather than Cola (Hallé 1961 Bodard
1962; Germain 1963).
A lobed fossil leaf from the same bed as the flower was
noted by Hamilton (1968) as similar to either Euphorbiaceae or Sterculiaceae (e.g., Cola). Hamilton (1968) notes
in his description that each of the numerous main veins
(6–10?) leads to a leaf-lobe. However, Cola and Pterygota
species (that possess lobed, palmately veined, simple
leaves) generally have 3–5 lobes, and Cola gigantea leaves
are either unlobed or consistently possess three-lobes.
Thus, the affinity of this fossil leaf remains uncertain.
Cf. Cola fossil leaf impressions from the Early Miocene
Ngorora Formation (Fig. 24) have weak brochidodromous
secondary venation, alternate percurrent tertiary venation,
and possibly swollen pulvini, all features common to extant
Cola species. Moreover, the shallowly subcordate and
slightly asymmetrical base in association with both pinnate
basal secondary venation and obovate leaf shape is not
common within Cola. Only one species, Cola letouzeyana
from Cameroon, is similar in all these respects to the fossil
(Nkongmeneck 1985) and also compares favorably in
having a decrease in secondary vein angle and spacing
towards the leaf base. The fossil also looks superficially
similar to some species of Scaphopetalum Mast. (Malvaceae sensu lato: Byttnerioideae), for example S. thonneri
De Wild. & Th. Durand; however, it lacks the distinctive
trinerved venation arising from the base.
More than 700 specimens of leaf impressions found in
tuffs near Mount Cameroon were reported by Menzel
(1920), and among these he reports close affinities with 15
extant Cola and two Octolobus species. Menzel (1920)
considered all of these impressions to represent taxa that
still exist in the area today. Many of these fossils have
123
A. D. Pan, B. F. Jacobs
Fig. 24 Leaf impressions of cf. Cola from the Early Miocene
Ngorora Formation of Kenya; scale bar 30 mm
venation similar to that of Cola and Octolobus; however,
definitive identification cannot be established at this time.
While the age of these fossils is not known (considered
Late Neogene in age according to Menzel 1920), these
fossils are preserved in tuff sediments so radiometric dating
might be possible. It is interesting to note that today this
area of West Africa (the Lower Guinea center) has the
highest diversity and species richness of Cola in Africa
(Cheek et al. 1996; Cheek 2002) and is considered by
Hamilton (1976) to have been a major rainforest refugium
during the Pleistocene (Cheek et al. 1996; Linder 2001).
Leaf characters and relationships within Cola
Cola has often been split into a number of subgroups based
on leaf and reproductive characteristics by several authors,
most of which differ (at least somewhat) from one another
(see Bodard 1962 for a summary of taxonomic modifications within the genus). In this paper we have provided
leaf and epidermal characters for several species of Cola,
Octolobus, and Pterygota (summarized in Table 1 and
Appendix).
A number of purported subgenera were erected
by Hallé (1961) to categorize Gabon Cola species. One of
these, Cola subgenus Neocourtenia (which includes
C. gabonensis, C. heterophylla, C. hispida, C. mahoundensis, C. marsupium, and C. urceolata), is characterized by
palmately veined, simple-leaved (often lobed) species with
inconspicuous tertiary and higher-order veins (only visible
in dried leaves), caducous stipules, flowers that are generally less than 2 cm in diameter possessing a uniseriate
whorl of stamens on the androecium, stamens numbering
one or two per carpel, panicle-like cyme inflorescences,
and seeds with a thick, very fibrous integument (Hallé
The earliest record of the genus Cola from the Late Oligocene
1961). Within our study, we observed that charactaceous
leaf texture also supports close relationship amongst these
taxa (of the species listed above, C. urceolata was not
examined). Other species (Cola carcifolia, C. millenii, and
C. scheffleri) which share some morphological characteristics, including palmately veined simple leaves with lobes
and chartaceous texture, with Hallé’s (1961) subgenus
Neocourtenia may belong to (or closely related to) the
subgenus (Keay and Brenan 1973). Bodard (1962) considered Cola carcifolia and C. millenii to be closely related
and placed them in subgenus Haplocola along with
C. triloba (R. Br.) K. Schum., C. laurifolia, C. humilis
(which is considered a synonym of C. heterophylla;
Lebrun and Stork 2003), and C. reticulata (A. Chev.).
Cola chlamydantha, C. lepidota, C. lissachensis, and
C. pachycarpa appear to be closely related based on the
palmately compound leaves, the possession of anisocytic
stomatal complex types, thickened rims (?papillae) on the
periclinal wall of the subsidiary cells adjacent to the guard
cells (often encircling the stoma), and subsidiary cells with
striate ornamentation (Fig. 22). However, Cola chlamydantha and C. lastoursvillensis (M. Bodard & Pellegr.)
N. Hallé (not sampled) have often been placed in a separate
genus Chlamydocola K. Schum. based on a suite of characters which is unique within the genus Cola including
androphore with anthers arranged in a subsinuous or digitate wreath formation, bisexual flowers with 9–12 carpels
having numerous (22–26) ovules, albuminous seeds, and
large orbicular bracteoles surrounding the flower bud
(Hallé 1961; Bodard 1962; Germain 1963; Keay and
Brenan 1973). Due to these unique features, Chlamydocola
may turn out to be a good genus. Cola ficifolia, a palmately
lobed simple-leaved species, also has stomata with thickened to papillate rims on the periclinal wall of the subsidiary cells and anisocytic stomata. Whether this species is
closely related to those mentioned above (and those species
which may or may not themselves be closely related) is
unknown, but is worth investigating.
Paleobiogeography of Cola
The presence of Cola amharaensis in Ethiopia is interesting not only due to the absence of the genus in Ethiopia
today, but also due to the fossil’s close morphological
similarity with extant species found in the Guineo-Congolian forest region (West and Central Africa) as opposed
to living species that are found in closer geographic
proximity in Kenya, Somalia, and Sudan (Lebrun and Stork
2003; Fig. 1). At least two other fossil genera from the
Guang River flora share this pattern of absence from
Ethiopia today, and greater similarity to Guineo-Congolian
species than to extant East African taxa. These include a
fossil leaflet of the climbing calamoid palm Eremospatha
259
(G. Mann & H. Wendl.) H. Wendl. (Pan et al. 2006), a
genus restricted to West and Central Africa today, and
several fossil leaflet specimens of Cynometra (Leguminosae) that are most similar to two Central African species
(Pan 2007). In addition, fossil taxa with closer affinity to
extant Guineo-Congolian forest elements (than to East
African tropical forests) are also present in a Late Oligocene palynoflora from northeastern Kenya (Mansonia
altissima type, Petersianthus type, and Triplochiton type;
Vincens et al. 2006). These ‘‘exotic’’ taxa, as they are
referred to in Vincens et al. (2006), and those from Ethiopia document a greater geographic distribution for some
tropical moist forest elements in the Paleogene than their
extant relatives, and indicate that extant species within
these genera in eastern Africa may be more distantly
related to these fossils than would otherwise be expected.
Acknowledgment We would like to thank the Authority for
Research and Conservation of Cultural Heritage, the Ministry of
Culture and Tourism, Ethiopia, and especially Ato Jara for permission
to conduct our continuing research in northwestern Ethiopia, and the
Director Mamitu Yilga and staff of the National Museum, Addis
Ababa, and the Gondar ARCCH and Chilga Ministry of Culture and
Sports Affairs for logistical support. We thank the Missouri Botanical
Garden, the Royal Botanic Gardens at Kew, and the collectors of the
herbaria specimens examined for assistance and access to their collections. We are grateful to the National Museums of Kenya, the
Baringo Paleontological Research Project, the East African Herbarium, and Christine Kabuye for their collaborative support of work in
Kenya. This project was funded by grants from the National Science
Foundation (EAR-0001259, EAR-0240251, and EAR-0617306), the
National Geographic Society, and the Dallas Paleontological Society.
Tillehun Selassie, Misege Birara, Habtewold Habtemichael, Mesfin
Mekonnen, and Drs. Ambachew Kebede and Aklilou Asfaw provided
valuable field assistance. We thank Dr. Martin Cheek for generously
sharing information about Cola and other sterculioids, for providing
advice, and for supplying cuticle specimens from the Royal Botanic
Gardens at Kew. We are grateful to Dr. Thomas Denk for images of
the Cameroon sterculioid fossils housed at the Swedish Museum of
Natural History. We also appreciatively acknowledge help from
Yohannes Desta, Yeshiwass Sitotaw, Gebremeskel Ayele, Elias
Addissu, and Teshome Yohannes at Chilga and laboratory assistance
from Kathryn Larson.
Appendix
Leaf and epidermal characteristics and states
1.
2.
3.
4.
5.
Leaf type: (0) simple, (1) palmately compound,
(2) pinnately compound
Leaf(let) shape: (0) elliptic, (1) obovate, (2) ovate,
(3) oblong, (4) special (needles, awls, etc.)
Leaf(let) attachment: (0) petiolate [petiolulate for
compound-leaved species], (1) subsessile/sessile
Leaf(let) texture: (0) chartaceous (1) semicoriaceous,
(2) coriaceous
Leaf(let) margin type: (0) entire, (1) lobed, (2)
toothed
123
260
6.
Leaf(let) base angle: (0) acute, (1) obtuse, (2) wide
obtuse
7. Leaf(let) base shape: (0) cuneate/concave/decurrent,
(1) convex/rounded, (2) truncate, (3) subcordate/
cordate/lobate
8. Leaf(let) apex morphology: (0) acute, (1) subacuminate, (2) acuminate, (3) obtuse/rounded/slightly
emarginate, (4) deltate/cuspidate, (5) emarginate
9. Primary venation: (0) pinnate, (1) tri-nerved at the
base, (2) palmately veined
10. Number of secondary vein pairs: (0) 0–5; (1) 6–10;
(2) 11–15; (3) [16
11. Secondary vein categories: (0) brochidodromous,
(1) eucamptodromous, (2) festooned brochidodromous, (3) cladodromous, (4) reticulodromous, (5)
toothed-craspedodromous, (6) toothed-semicraspedodromous, (7) toothed-festooned semicraspedodromous
12. Tertiary venation: (0) random reticulate, (1) opposite
percurrent, (2) alternate percurrent, (3) mixed opposite/alternate percurrent
13. Abaxial epidermal cell shape: (0) isodiameteric,
(1) rectangular
14. Abaxial cell size: indicated by length (first set of
numbers) and width ranges, rounded to the nearest
0.5 lm
15. Abaxial epidermal cell arrangement: (0) random (a
combination of any of the following cellular arrangements), (1) nonrandom–tetragonal, (2) nonrandom–
pentagonal, (3) nonrandom–hexagonal, (4) nonrandom–
polyagonal ([6-sided cells), (5) nonrandom–linear
16. Abaxial anticlinal cell wall pattern: (0) straight,
(1) rounded, (2) undulate
17. Abaxial anticlinal cell wall shape of undulation:
(0) U, (1) V, (2) X
18. Abaxial epidermal cell surface ornamentation:
(0) absent, (1) stippled, (2) striate
19. Abaxial stoma: (0) absent, (1) present
20. Abaxial stomatal complex type: (0) polycytic
types (anomocyptic, cyclocytic), (1) anisocytic,
(2) paracytic types (paracytic, brachyparacytic,
amphibrachyparacytic, hemiparacytic), (3) tetracytic
types (staurocytic, anomotetracytic, paratetracytic,
brachyparatetracytic)
21. Abaxial stomatal complex chains or clusters:
(0) absent, (1) present
22. Abaxial stomatal ornamentation: (0) absent, (1) striate,
(2) papillate, (3) thickened areas on periclinal wall
23. Abaxial guard cells: (0) level, (1) sunken,
(2) raised
24. Number of abaxial trichomes types: (0) glabrous/absent
(no trichomes present), (1) one, (2) two, (3) three,
(4) four, (5) five or more
123
A. D. Pan, B. F. Jacobs
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
41.
42.
Abaxial hair types present: (0) unicellular simple,
(1) unicellular glandular, (2) multicellular glandular,
(3) stellate/peltate (usually only the polygonal base is
preserved),
Abaxial trichome dominance: (0) glandular trichomes
predominate [C70% glandular], (1) no trichome type
predominates (29–69%), (2) stellate/peltate trichomes
predominate [C70% stellate/peltate], (3) simple hairs
predominate (C70% simple)
Abaxial glandular hair pairs: (0) absent, (1) present
Adaxial epidermal cell shape: (0) isodiameteric,
(1) rectangular
Adaxial cell size: indicated by length (first set of
numbers) and width ranges, rounded to the nearest
0.5 lm
Adaxial epidermal cell arrangement: (0) random (a
combination of any of the following cellular
arrangements), (1) nonrandom–tetragonal, (2) nonrandom–pentagonal, (3) nonrandom–hexagonal, (4)
nonrandom–polyagonal ([6-sided cells), (5) nonrandom–linear
Adaxial anticlinal cell wall pattern: (0) straight,
(1) rounded, (2) undulate
Adaxial anticlinal cell wall shape of undulation:
(0) U, (1) V, (2) X
Adaxial epidermal cell surface ornamentation:
(0) absent, (1) stippled, (2) striate
Adaxial stoma: (0) absent, (1) present
Adaxial stomatal complex type: (0) polycytic types
(anomocyptic, cyclocytic), (1) anisocytic, (2)
paracytic types (paracytic, brachyparacytic, amphibrachyparacytic, hemiparacytic), (3) tetracytic types
(staurocytic, anomotetracytic, paratetracytic, brachyparatetracytic)
Abaxial stomatal complex chains or clusters:
(0) absent, (1) present
Adaxial stomatal ornamentation: (0) absent, (1) striate,
(2) papillate, (3) thickened areas on periclinal wall
Adaxial guard cells: (0) level, (1) sunken, (2) raised
Number of adaxial trichomes types: (0) glabrous/
absent (no trichomes present), (1) one, (2) two, (3)
three, (4) four, (5) five or more
Adaxial hair types present: (0) unicellar simple,
(1) unicellular glandular, (2) multicellular glandular,
(3) stellate/peltate (usually only the polygonal base is
preserved)
Adaxial trichome dominance: (0) glandular trichomes
predominate (C70% glandular), (1) no trichome type
predominates (29–69%), (2) stellate/peltate trichomes
predominate (C70% stellate/peltate), (3) simple hairs
predominate (C70% simple)
Adaxial glandular hair pairs: (0) absent, (1) present
The earliest record of the genus Cola from the Late Oligocene
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