The image of Pennsylvanian Iowa does not resonate with the state’s flat, corn-dominated landscape. However, evidence from petrified plants suggests that mangroves temporarily dominated the flora of central Iowa. These anatomically preserved plant fossils are present in coal balls, spherically shaped coal concretions. They formed through the process of permineralization, when water rich in the mineral calcium carbonate (CaCO3) trickled into plant cells, resulting in structural preservation. Subsequent debris accumulated on top of the plants, freezing them in time.
Anne Raymond, a paleoecologist at Texas A&M, has spent her academic career documenting prehistoric plant life. With the knowledge that many plants disappeared abruptly in the late Pennsylvanian, she seeks to relate paleoclimate changes to the fossil record. In 1988, she published a study in which she convincingly argued the existence of fossilized mangroves in a collection of 78 coal balls retained from Iowa’s Urbandale mine. Known as cordaitaleans, these ancient mangroves composed 56 percent of identifiable coal ball debris. Conversely, freshwater tree ferns, including the seed plants Medullosa and Psaronius, represented 31 percent of debris, and lycopods composed five percent of debris (Raymond 1988). Raymond not only proposed the mangrove lifestyle of cordaitaleans but also developed a hypothesis for early plant succession in the Urbandale swamp.
Urbandale
Cordaitaleans: Saltwater Inhabitants
To
persist in their saltwater environments, mangroves have evolved root structures
that limit salt intake and enable subsistence at tide’s edge. In many species,
roots are coated with suberin, a rubbery material that prevents water from
penetrating tissue (Werner and Stelzer 1990). Abundant prop roots systems keep
mangrove trunks upright in soft marine sediments. Some mangroves even have
pneumatophores, roots that extend out of the mud to take in air (Warne 2007). Likewise,
cordaitalean fossils indicate evidence of massive root systems that served as a
salt filtration system. Raymond found two indicators of swamp salinity in
Urbandale coal ball cordaitalean fossils – the distribution of pyrite crystals
and the ratio of shoot to root debris. Present in sea water, sulfur-reducing bacteria allow for formation of iron-sulfide complexes, including pyrite (FeS2). Raymond uncovered an abundance of this mineral in the Urbandale coal balls. Disseminated pyrite that occured both inside and outside roots indicated freshwater species that were unable to exclude saltwater. Pyrite that rimmed fossilized roots evidenced saltwater exclusion. Among the Urbandale coal balls, Raymond found that cordaitalean roots lacked internal pyrite. Thus, they remained alive throughout marine inundations. Conversely, pyrite saturated tree fern and lycopod roots, indicating their vulnerability to marine infiltration (Figure 1).
(a) (b)
Low cordaitalean shoot to root ratios further supported Raymond’s theory. Like modern mangroves, cordaitaleans living in a marine environment would have benefitted from extensive root tissue. To determine shoot to root ratios, Raymond superimposed a grid over peels from fifty Urbandale coal balls (a total sample surface area of 4299 cm2). After identifying the organ type (i.e. shoot or root) and plant form for the largest piece of debris in each square, she calculated the percentage of shoot debris for each coal ball. Interestingly, nearly twenty percent of Urbandale coal balls featured debris composed of only zero to ten percent shoot debris. As expected, these low-shoot coal balls contained primarily cordaitalean fossils. Conversely, coal balls with higher shoot percentages contained evidence of Medullosa, Psaronius, and lycopods – the freshwater plants. Thus, the taxonomic composition of low-shoot coal balls aligns with Raymond’s pyrite inferences, implying that Pennsylvanian cordaitaleans were mangroves.
The
Urbandale Swamp Flora: A Freshwater-Saltwater Gradient?
If cordaitaleans were indeed ancient
mangroves, did they grow in a different subenvironment from their freshwater
counterparts? Did freshwater and saltwater plants live at the same time? In
1983, Raymond T.L. Phillips preliminarily approached this question when they
analyzed the paleoecology of Iowa coal balls from three mines, including the
Urbandale Mine. They discovered a gradient between cordaitalean debris and tree
fern debris – within each coal ball, the freshwater plants’ roots were oriented
closer to the cordaitalean debris than were their shoots. Based on this
relationship, Raymond and Phillips suggested that tree ferns succeeded
cordaitaleans in early Iowa swamp forests. However, their gradient analysis was
largely quantitative and excluded lycopod fossils (Raymond and Phillips 1983). In her 1988 study, Raymond completed a root-penetration analysis of the Urbandale coal balls that confirmed her earlier gradient theory. She tabulated the number of instances in which roots belonging to the four major taxa (cordaitaleans, Medullosa, Psaronius, and lycopods) penetrated debris of each of the other taxa. Consistent with the gradient analysis, root penetration data suggested that cordaitaleans colonized the swamp first and were replaced by Medullosa and Psaronius – in terms of root contact, the freshwater tree ferns grew through the cordaitalean debris ninety percent of the time (Figure 2a). Raymond further postulated that the two tree fern species coexisted; the percentages of Medullosa – Psaronius penetrations and Psaronius – Medullosa penetrations were both approximately fifty percent. Although lycopod fossils composed five percent of the Urbandale coal ball debris, Raymond found only root debris. This suggested that lycopods colonized Iowan landscapes following accumulation of cordaitalean and tree fern peat (Figure 2b).
(a) (b)
Iowa
Mangroves: A Figment of the Pennsylvanian
After analyzing the pyrite patterns and
shoot-to-root ratios of Urbandale coal balls, Raymond asserted that
Pennsylvanian cordaitaleans lived mangrove lifestyles. Further, she completed
fossil gradient and root penetration analyses to indicate that they preceded
the colonization of freshwater tree ferns and lycopods. In light of major
paleogeographical events, Iowa’s present lack of marine forests comes as no
surprise. The Urbandale coal balls immortalize tropical flora that existed when
North American, Europe, and Asia composed a single continent.
References
Raymond,
A. 1983. Peat taphonomy of recent mangrove peats and Upper Carboniferous
coal-ball peats. Ph.D. Dissertation. University of Chicago, pp 293.
Raymond,
A. 1988. The paleoecology of a coal-ball deposit from the Middle Pennsylvanian
of Iowa dominated by cordaitalean gymnosperms. Review of Paleobotany and Palynology. 53: 233-250.
Warne,
K. 2007. Mangroves: forests of the tide. National
Geographic Magazine. ncm.com.
Werner,
A. and R. Stelzer. 1990. Physiological responses of the mangrove Rhizophora mangle grown in the absence
and presence of NaCl. Plant, Cell, and
Environment. 13: 243-255.