Hostname: page-component-76fb5796d-5g6vh Total loading time: 0 Render date: 2024-04-27T05:42:04.073Z Has data issue: false hasContentIssue false
  • English
  • Français

South American Maize and Political Economy of the Middle and Late Formative Soconusco Region of Guatemala

Published online by Cambridge University Press:  15 June 2023

Thomas C. Hart Open the ORCID record for Thomas C. Hart [Opens in a new window] ,
Neil A. Duncan ,
Deborah M. Pearsall  and
Michael W. Love
Thomas C. Hart*
Affiliation:
Center for Archaeological and Tropical Studies, University of Texas, Austin, TX, USA
Neil A. Duncan
Affiliation:
Department of Anthropology, University of Central Florida, Orlando, FL, USA
Deborah M. Pearsall
Affiliation:
Department of Anthropology, University of Missouri, Columbia, MO, USA
Michael W. Love
Affiliation:
Department of Anthropology, California State University, Northridge, CA, USA
*
Corresponding author: Thomas C. Hart, Email: thomas.hart@utexas.edu
Rights & Permissions [Opens in a new window]

Abstract

We present macrobotanical, starch, and phytolith data from artifacts and sediments from Middle Formative La Blanca (1000–600 cal BC) and Late Formative El Ujuxte (600 cal BC–cal AD 115 ) in the Soconusco region in Guatemala. Potential economic plants identified included palm (cf. Arecaceae), two varieties of maize (Zea mays), guava (Psidium guajava), bean (Phaseolus), chili peppers (Capsicum), squash (Cucurbitaceae), custard apple (Annonaceae), coco plum (Chrysobalanaceae), lerén (Calathea), arrowroot (Maranta), and bird-of-paradise (Heliconia). The results suggest that control of food production and consumption was critical for the transition from complex chiefdoms during the Middle Formative to the archaic state in the Late Formative. The arrival of a more productive South American variety of maize at El Ujuxte (about 2549 BP) allowed elites to exploit an already existing broad-based economic system and to use the maize-based religious system to increase control over maize agricultural practices and maintain power through ideology and disciplinary power. These data suggest that the arrival of fully domesticated South American maize likely influenced the overall development of Mesoamerican state-level societies.

Resumen

Resumen

Presentamos datos macrobotánicos, almidón y fitolitos de artefactos y sedimentos del Formativo Medio La Blanca (1000–600 cal aC) y Formativo Tardío El Ujuxte (600 cal aC–115 cal dC), región de Soconusco, Guatemala. Las posibles plantas económicas identificadas incluyen la palma (cf. Arecaceae), dos variedades de maíz (Zea mays), la guayaba (Psidium guajava), frijol (Phaseolus), chiles (Capsicum), calabaza (Cucurbitaceae), crema de manzana (Annonaceae), la ciruela de coco (Chrysobalanaceae), el lerén (Calathea), el arrurruz (Maranta) y el ave del paraíso (Heliconia). Los resultados demuestran que el control de la producción y el consumo de alimentos fueron fundamentales para la transición de los cacicazgos complejos durante el Formativo medio al estado arcaico en el Formativo tardío. La llegada de una variedad sudamericana de maíz más productiva a El Ujuxte (ca. 2549 AP) permitió a las élites explotar un sistema económico de base amplia ya existente y utilizar el sistema religioso basado en el maíz para aumentar el control sobre las prácticas agrícolas de maíz y mantener el poder mediante la ideología y el poder disciplinario. Estos datos sugieren que la llegada del maíz sudamericano totalmente domesticado influyó en el desarrollo general de las sociedades mesoamericanas estatales.

Keywords

starchphytolithsmacrobotanical remainsarchaeobotanymaizeFormativeGuatamalaSoconuscoalmidónfitolitosrestos macrobotánicosarqueobotánicamaízFormativoGuatamalaSoconusco
Type
Article
Information
Latin American Antiquity , First View , pp. 1 - 14
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of the Society for American Archaeology

The origins of social complexity and the shift to intensive maize agricultural systems that characterize Mesoamerican state-level societies remain highly debated (Arnold Reference Arnold2009; Awe et al. Reference Awe, Ebert, James Stemp, Kathryn Brown, Sullivan and Garber2021; Kennett et al. Reference Kennett, Thakar, VanDerwarker, Webster, Culleton, Harper, Kistler, Scheffler and Hirth2017, Reference Kennett, Lipson, Prufer, Mora-Marín, George, Rohland and Robinson2022; Killion Reference Killion2013; Nichols Reference Nichols2015:2; Rosenswig Reference Rosenswig2015). In the Maya region, scholars place the origins of maize agricultural intensification anywhere between the Archaic (9000–3500 BP; Kennett et al. Reference Kennett, Lipson, Prufer, Mora-Marín, George, Rohland and Robinson2022) and the Middle Formative (about 3250 BP; Rosenswig et al. Reference Rosenswig, VanDerwarker, Culleton and Kennett2015). Yet these debates center largely around when maize becomes productive enough to sustain sedentary populations and cause a shift in diet and social organization. Kennett and colleagues (Reference Kennett, Lipson, Prufer, Mora-Marín, George, Rohland and Robinson2022) suggest that Chibchan-speaking peoples migrated into Mesoamerica from Panama around 5600 BP and brought with them more productive South American maize. They hypothesize that the horticultural traditions brought by these peoples resulted in intensified forms of maize agriculture around 4700 BP, more than 1,500 years before other known markers of agricultural intensification. In contrast, Rosenswig and coworkers (Reference Rosenswig, VanDerwarker, Culleton and Kennett2015) suggest that these new intensified maize agricultural systems developed later, during the Middle Formative, at multiple locations around Mesoamerica depending on the environmental and cultural histories of each subregion.

The La Blanca / El Ujuxte project seeks to understand the role of agriculture in the shift from the complex chiefdoms of the Middle Formative to the archaic states of Late Formative Soconusco through a study of data pertaining to foodways: well-contextualized macroremains, phytoliths, and starch grains recovered from site sediments and artifact residues. Our study of multiproxy paleoethobotanical data supports Kennett and colleagues’ (Reference Kennett, Lipson, Prufer, Mora-Marín, George, Rohland and Robinson2022) hypothesis that South American maize was introduced to Mesoamerica. Our evidence also suggests that (1) maize intensification is not tied to the emergence of social complexity, at least in the Soconusco region; (2) the dramatic social and political changes that are characteristic of the Late Formative, such as the loss of household autonomy, decrease in household rituals, and an increase in public rituals, only developed once more productive varieties of maize became available; and (3) these changes are the result of authority figures exploiting a new resource to consolidate their control over already existing maize-based economic and religious systems.

Background

Subsistence Strategies of Early, Middle, and Late Formative Soconusco

Considerable attention, in the form of macrobotanical, pollen, starch grain, phytolith, and genetic analysis, has been devoted to understanding the origins of agriculture during the Archaic (Dickau et al. Reference Dickau, Ranere and Cooke2007; Doebley Reference Doebley2004; Hufford et al. Reference Hufford, Xun Xu, van Heerwaarden, Pyhäjärvi, Chia, Cartwright and Elshire2012; Piperno and Flannery Reference Piperno and Flannery2001; Pohl et al. Reference Pohl, Piperno, Pope and Jones2007; Ranere et al. Reference Ranere, Piperno, Holst, Dickau and Iriarte2009; Vallebueno-Estrada et al. Reference Vallebueno-Estrada, Rodríguez-Arévalo, Rougon-Cardoso, González, Cook, Montiel and Vielle-Calzada2016, among others). This focus also applies to the Soconusco region where scholars have attempted to find early direct evidence of maize use through the analysis of archaeobotanical data (Blake and Neff Reference Blake, Neff and Lesure2011; Kennett et al. Reference Kennett, Piperno, Jones, Neff, Voorhies, Walsh and Culleton2010; Mangelsdorf Reference Mangelsdorf, Coe and Flannery1967; Neff et al. Reference Neff, Pearsall, Jones, Arroyo, Collins and Freidel2006; Popper and Lesure Reference Popper, Lesure and Lesure2010; Powis et al. Reference Powis, Hurst, del Carmen Rodríguez, Ortíz C., Blake, Cheetham, Coe and Hodgson2007; Rosenswig et al. Reference Rosenswig, VanDerwarker, Culleton and Kennett2015). Except for recent work by Rosenswig and colleagues (Reference Rosenswig, VanDerwarker, Culleton and Kennett2015), there is little archaeobotanical research on agriculture and the development of complex chiefdoms and the state during the Middle and Late Formative periods.

The development of agriculture in Soconusco is thought to be a gradual process from the Archaic to the Early Formative (Blake and Neff Reference Blake, Neff and Lesure2011). Populations moved between inland and coastal regions during the Middle and Late Archaic and relied on small-scale horticultural strategies. Cultigens from inland horticultural sites appear to supplement foraging of terrestrial and maritime resources during coastal occupations (Blake and Neff Reference Blake, Neff and Lesure2011). Legumes appear first in central Soconusco during the Middle Archaic, whereas maize (Zea mays), arrowroot (Maranta arundincacea), squashes (Cucurbita), achira (Canna), cotton (Gossypium), and other cultigens appear throughout the region during the Late Archaic.

Subsistence strategies of the Early Formative are considered largely continuations of earlier Archaic traditions (Rosenswig et al. Reference Rosenswig, VanDerwarker, Culleton and Kennett2015). The main difference was the emergence of sociopolitical inequality, sedentism, and two-tiered settlements in the Mazatán region during the Early Formative. Rosenswig and colleagues (Reference Rosenswig, VanDerwarker, Culleton and Kennett2015:91) hypothesize that these trends were due to an increase in maize production toward the end of the Early Formative around 1000 cal BC that set the stage for dramatic changes in the Middle Formative (Lesure et al. Reference Lesure, Sinesky, Wake, Lohse, Borejsza and Joyce2021). Several important species first appear in the archaeological record of the Early Formative, including avocado (Persea americana; Feddema Reference Feddema1993), jocote (Spondias; Coe and Flannery Reference Coe and Flannery1967), tree nuts (Popper and Lesure Reference Popper, Lesure and Lesure2010), and cacao (Theobroma; Powis et al. Reference Powis, Hurst, del Carmen Rodríguez, Ortíz C., Blake, Cheetham, Coe and Hodgson2007).

La Blanca, El Ujuxte, and the Emergence of Late Formative Archaic States

The Pacific coastal plain from modern Chiapas, Mexico, to El Salvador (Figure 1) has a rich archaeological record during the entire Formative, making it a key region for understanding the trajectory of early complex societies in Mesoamerica. Trends toward social complexity begin here as early as anywhere in Mesoamerica, and the overall sequence from Early to Terminal Preclassic was characterized by Love (Reference Love and O'Donovan2002) as a series of cycles with an overall trend toward greater complexity. From the Early Formative center of Paso de la Amada to the Late Preclassic cities of El Ujuxte, Izapa, and Takalik Abaj, the region's settlements were among the largest in Mesoamerica. As an important trade corridor from the Archaic period to modern times, the Pacific coastal plain was a place where people of many different origins visited or lived (Love Reference Love, Nichols and Pool2012; Love and Guernsey Reference Love, Guernsey and Lesure2011). The zone probably held speakers of several languages, and the moniker “Southern Maya Region” is simplistic.

Figure 1. The Pacific coastal plain showing the Formative period sites discussed in the article.

Although the overall trajectory for the Formative was of increasing complexity, there were multiple cycles of centralization and collapse (Love Reference Love2007). Within the Mazatán region of Mexico during the Early Formative, Paso de la Amada was followed in succession by Cantón Corralito and Ojo de Agua. At the beginning of the Middle Formative, population within the Mazatán region declined sharply and, at the same time, surged within the Río Naranjo region of Guatemala. An unprecedented level of aggregation both westward and eastward marked the rise of the La Blanca polity around 1000 cal BC.

La Blanca was about 300 ha in size, with a three-tiered settlement hierarchy covering approximately 350 km2. Within the settlement, there is marked evidence of social stratification at the household level, manifested in the differential distribution of jade beads and other prestige goods (Love and Guernsey Reference Love, Guernsey and Lesure2011). Soon after 600 cal BC, La Blanca declined to the size of a hamlet, and political power shifted to new cities.

The early city-states of Izapa and El Ujuxte were both, in part, outgrowths of the collapsed La Blanca polity and the economic changes that took place there. El Ujuxte was a planned city about 900 ha in size that was oriented along a north–south axis about 35° east of magnetic north, toward the rising of the star Capella (Love and Rosenswig Reference Love, Rosenswig, Love and Guernsey2021:155, 157) The five-tiered regional polity covered about 600 km2 and was at least twice the size of the La Blanca polity. There were at least four secondary centers within the El Ujuxte polity that contained public buildings that were replicas of the larger versions found at El Ujuxte (Love and Rosenswig Reference Love, Rosenswig, Love and Guernsey2021:161).

Love (Reference Love and O'Donovan2002) characterized the transition as political cycling, in which centralized power had to be reestablished after the La Blanca polity broke up. In that formulation, elites seeking power were viewed as having consciously modified economic and ideological structures of the previous system to enhance their power. In the process they created economic and ideological institutions that gave rise to an early state form of administration.

The Late Formative represented the climax of trends in population growth and nucleation throughout the Pacific coast, piedmont, and highlands (Love Reference Love2007; Love and Rosenswig Reference Love, Rosenswig, Love and Guernsey2021). Izapa and El Ujuxte were part of a network of early city-states that included Kaminaljuyu, Takalik Abaj, Chalchuapa, Chocolá, and Bilbao. These cities were linked by trade networks and intellectual exchanges of art styles, ritual practices, and political ideologies (Love and Guernsey Reference Love, Guernsey and Lesure2011).

The paleoethnobotanical component of the La Blanca / El Ujuxte project seeks to understand subsistence strategies in the Middle and Late Formative and mechanisms that led to the formation of the Late Formative archaic state at El Ujuxte after the collapse of the Middle Formative La Blanca polity (Love Reference Love and O'Donovan2002:222). Love hypothesizes that changes in economics, ideology, and daily practice at El Ujuxte were key to the reestablishment of political authority after La Blanca collapsed in 600 cal BC: specifically, the loss of individual household autonomy (economics), the development of leadership deriving its power from the larger cosmos rather than more localized earthbound forces (ideology), and the creation of disciplinary power by leadership (daily practice) were instrumental in solidifying more permanent political and social structures. The botanical data presented here supports Love's hypothesis that there was a loss of individual household autonomy (economics) during the Late Formative due, in large part, to the arrival of more productive maize varieties.

Methods

Over a 15-year period, the La Blanca / El Ujuxte project combined regional surveys with excavations at two major centers to investigate the development of social complexity on the Pacific coast of Guatemala during the Middle and Late Formative. Although public areas and monumental constructions were investigated at both sites, the focus was on domestic zones and sampling of households. At both sites, the goal of the excavations was to obtain a cross section of social ranks and to understand how domestic economic and ritual practices changed in the context of increasing political centralization. To date, the project has excavated 20 domestic areas at La Blanca and 14 at El Ujuxte.

To understand economic strategies associated with the emergence of the archaic state, we examined archaeological sediments and artifact residues from both elite and commoner residential contexts for macrobotanical remains, phytoliths, and starch grains. Samples were collected from each excavated level below 50 cm (the presumed depth of the plow zone). Paleoethnobotanical remains reported here include all materials from El Ujuxte (seasons from 1995 to 1997) and materials from the 2003 and 2004 seasons at La Blanca. The work at La Blanca sampled eight house lots, each consisting of a domestic mound and the approximately 400 m2 around it.

We sampled artifact microfossil residues for artifact types for which a function related to food processing or consumption could be inferred from the form of the artifact, its context, or both. Assumptions about artifact function were derived from ethnoarchaeological studies in the case of metates (Searcy Reference Searcy2011) and the residue analysis of similar artifacts in Mesoamerica (Cagnato and Ponce Reference Cagnato and Ponce2017). Evidence of food production included the presence of maize starch (from the edible portion, the kernel) or cob phytoliths (from inedible tissues associated with kernels) on food-processing artifacts, such as grinding stones, grater and grinding bowl sherds, and cooking vessel sherds. Ceramics likely involved in consumption were sampled from both domestic and ritual contexts.

Our assessment of economic strategies using macroremains was based on plant tissues that became charred, either deliberately through the burning of garbage or fuel, or accidentally—for example, from a cooking mishap or while making a fire—and analyzing their richness and relative abundance. In terms of maize, charred tissues were largely limited to cupules (from the inedible cob) and kernels. Comparing the abundance of these tissues in a ratio (kernel:cupule and kernel:cob) provided insights into whether a site or site area was heavily involved in food production (higher proportion of cupules or cobs) or received prepared foods (higher proportion of kernels; Pearsall Reference Pearsall2019:156, 160).

Nineteen artifacts from Ujuxte and 102 artifacts from La Blanca were sampled for phytoliths and starches using the “piggyback” protocol and processed at the University of Missouri Paleoethnobotany Laboratory (Chandler-Ezell and Pearsall Reference Chandler-Ezell and Pearsall2003). In the piggyback protocol, residues are systematically removed in the reverse order in which they were deposited, thereby ensuring that microfossils contained in the cracks and pores of an artifact are associated with their primary deposition (Hart Reference Hart2011). Starch slides were counted in their entirety, whereas a diagnostic count (up to 200 count) was conducted for phytoliths. Identifications were made based on the laboratory's neotropical comparative collection and published sources (see Pearsall Reference Pearsall2015:254–266).

In addition to sampling artifacts for microfossils, 23 sediment samples from Ujuxte and eight from La Blanca were analyzed for phytoliths. Samples were processed and counted following standard procedures (Pearsall Reference Pearsall2015:275–277). Samples collected at La Blanca came from the residential sector in the central and southeast corner of the site, whereas those collected at El Ujxute represented commoner and elite residences, as well as liminal spaces in between.

A total of 6,380 standardized 10-liter samples were collected from La Blanca and processed using machine-assisted flotation, and 1,794 standardized two-liter samples were collected from El Ujuxte and processed using bucket flotation. Sediment sample sizes were measured using a standardized bucket in the field. In addition, 94 handpicked or screen-recovered carbon samples were collected from El Ujuxte. All samples were floated in Guatemala and then shipped to the University of Missouri for analysis (see the tDAR raw data table for more information regarding which specific samples at El Ujuxte were recovered by flotation versus handpicked).

Results

Artifacts

In this article, we use the phrase “economic” to mean “useful” plants. Phytoliths were recovered from almost all La Blanca (91 of 96) and El Ujuxte (18 of 19) artifacts, whereas starches were recovered from about half the artifacts from La Blanca (50 of 102) and about one-third from El Ujuxte (7 of 18 artifacts). Both commoner and elite residents at La Blanca processed and consumed annual crops such as maize (Zea mays), squash (Cucurbita), and chili peppers (Capsicum), as well as root and tuber crops such as lerén (Calathea) and arrowroot (Maranta). Arboreal seed and fruit phytoliths from the soursop (Annonaceae), palm (Arecaceae), coco plum (Chrysobalanaceae), and persimmon (Ebenaceae) families were recovered, and other arboreal indicators were present. Sedge (Scirpus, Cyperus, and Carex) seed phytoliths suggest the use of wetland plant resources (see Supplemental Table 1 for a summary by operation of economic starch and phytoliths recovered from Ujuxte and La Blanca artifacts).

In general, similar combinations of phytoliths and starch grains were recovered from manos, metates, worked stone, and ceramic grinding and grating bowls, indicating that grinding tools were used to process multiple taxa and there was no specialization in terms of artifact types and economic plants. Maize, fruit, and root crop residues were all found on both ceramic and stone grating/grinding/pounding tools, for instance. Thirty-one artifacts from La Blanca also contained burnt epidermal cells, indicating the cooking or processing of cooked foods. Phytolith and starch grain results from El Ujuxte artifacts were similar to those from La Blanca (Supplemental Tables 2 and 3).

Interestingly, bird-of-paradise (Heliconia) leaf phytoliths, which do not represent foods, were recovered by sonication from artifact surfaces of both grinding implements and ceramics; they were among the most abundant phytolith types recovered. This indicates a strong association of bird-of-paradise leaves with artifact use.

Sediments

Phytoliths recovered from sediments from La Blanca and El Ujuxte reflect localized anthropogenic landscapes (Supplemental Tables 4 and 5). At La Blanca, cultivated and encouraged plants such as maize, bird-of-paradise, and Marantaceae co-occur with open habitat indicators. Open habitat assemblages include a large proportion of grass, sedge, and herb phytoliths and a limited number of arboreal types. Arboreal phytoliths recovered were mostly from the palm family (Arecaeae). Phytoliths from El Ujuxte samples were similar but also included lerén (Calathea) tuber phytoliths, sedge seed phytoliths, and squash rind phytoliths. The most common phytolith type at both sites was Podostemaceae, or river-weed. Podostemaceae is a family of mostly submerged, moss-like herbs found in stony rivers (Mabberley Reference Mabberley1997; Piperno Reference Piperno2006). The Soconusco plain experiences high sedimentation caused by the seasonal flooding of rivers flowing from the Sierra Madre mountains and by intense tropical storms (Kennett et al. Reference Kennett, Piperno, Jones, Neff, Voorhies, Walsh and Culleton2010; Voorhies and Kennett Reference Voorhies and Kennett1995). These events are likely to move Podostemaceae phytolith-bearing sediments from rivers over the plain and even into coastal mangroves (Kennett et al. Reference Kennett, Piperno, Jones, Neff, Voorhies, Walsh and Culleton2010). Sediment phytolith assemblages reflect the dynamic alluvial landscape that Ujuxte and La Blanca peoples inhabited.

Macroremains

The overall macrobotanical assemblages from La Blanca and El Ujxute were quite small, given the large number of samples collected, and they varied considerably among operations (Supplemental Tables 6 and 7). Maize kernels and cob tissues (no cupules), a Psidium guajava seed, a Phaseolus bean fragment, wood, and unknown seeds, nuts, and fruit rind tissues were recovered from La Blanca. El Ujuxte had a similar plant list, with the addition of Arecaceae (palms) and pigweed (Trianthema portulacastrum). Interestingly, in addition to maize kernels, large numbers of maize cupules were recovered from Ujuxte. Most of the material recovered from both sites was charred wood (not identified to taxon).

Discussion

Subsistence, Plant Use, and Agricultural Intensification at La Blanca and El Ujuxte

Comparison of the overall richness of identified taxa and morphotypes at El Ujuxte and La Blanca—the values for macroremains, sediment phytoliths, and artifact residues were calculated separately; see Table 1—reveals that their richness was virtually identical between the two sites and time periods. This suggests that La Blanca and El Ujuxte engaged in broad-based agricultural strategies that were a continuation of Early and Middle Formative practices in the Soconusco region. The results from La Blanca imply that food was being processed and consumed at the household level throughout the Conchas phase (1000–600 cal BC; Love Reference Love2018:265). As might be expected given the low counts and low densities of remains, the richness of identified taxa and morphotypes from La Blanca was relatively low (n = 13 for macrobotanicals, n = 14 for artifacts, and n = 5 sediment phytoliths) and highly variable among contexts and the three measures (Table 2; Supplemental Table 8). Commoner contexts (Ops. 31, 34, 35, 36, 38) and elite contexts (Ops. 32, 37) overlapped in the richness of artifact residues and were very similar in terms of phytolith indicators. In terms of macroremains, richness was markedly lower in Operation 37 (elite, N = 4) than in most commoner contexts (range, 3–12). Operation 34, a commoner context, had the highest richness for macrobotanicals (N = 12), whereas Operation 38, also a commoner context, had the lowest (N = 3). Operation 32, an elite context, had the highest richness for artifact residues (N = 12), and Operation 36, a commoner context, had the lowest (N = 4). Although there are other markers of social inequality at La Blanca, such as construction of large mounds and access to rare minerals (Love and Guernsey Reference Love, Guernsey and Lesure2011), plant food richness and procurement of rare plant foods do not indicate social inequality because of the similar richness of foods in both commoner and elite contexts.

Table 1. Richness of Taxa at La Blanca and El Ujuxte.

Table 2. Maize Kernel: Cupule Ratio at El Ujuxte.

The richness of macrobotanical remains (n = 16), artifact residues (n = 14), and sediment phytoliths (n = 10) at El Ujuxte is similar to that at La Blanca but varied considerably among operations (Table 1; Supplemental Tables 8 and 9). Macrobotanical richness was highest in commoner contexts such as Operations 12, 13, and 17 and at the sole elite context in Operation 18. Macrobotanical richness was the lowest at commoner contexts in Operations 8, 9, 14, and 20. Residue richness was highest (N = 6) from surface-collected grinding stones from the 1993 field season. Interestingly, Operation 15, a commoner site, where a high density of macroremains indicated good preservation, had modest richness (n = 5) and was dominated by wood. In addition to maize, macroremains of foods recovered from El Ujuxte included bean (Phaseolus), two types of palm (Arecaceae), guava (Psidium guajava), and unidentified root/tuber and fruit/nut remains. A few small bean cotyledons were present, potentially representing wild taxa, but most appear to be common bean (Phaseolus vulgaris; Supplemental Table 10). Other unidentified dense tissues may represent small pieces of palm meats, beans, dense maize kernels, or unknown fruits/nuts.

An important observation is that there is no reduction in plant food richness at El Ujuxte, indicating that the agricultural system had not narrowed. Narrowing of the subsistence base—for instance, to focus more production capacity on a single crop like maize—is a characteristic of agricultural intensification, as is cropping of land at more frequent intervals, maintaining more open habitats, and so on. Our findings suggest that food production remained broad-based at El Ujuxte.

The occurrence of bird-of-paradise (Heliconia) phytoliths directly associated with artifacts at both sites is intriguing. Showy bird-of-paradise flowers are used as ornamentals (Haeckel Reference Haeckel2008). However, the broad pliable leaves are used for wrapping food throughout the tropics (Criley and Broschat Reference Criley, Broschat and Janick1992) and as coverings for cooking pots (Kress Reference Kress1990). In Central America, the ethnobotany of Heliconia is not well studied, although modern uses of leaves as wrappings for hallacas, tamales, and humitas are widespread and likely reflect older cooking practices (e.g., Díaz-José et al. Reference Díaz-José, Guevara-Hernández, Morales-Ríos and López-Ayala2019; Lazos Chaverro and Alvarez-Buylla Reference Lazos Chaverro and Roces1988). In addition to wrappings, the Q'eqchi’ Maya use bird-of-paradise leaves to line cooking pots to prevent the burning of steaming tamales, and some species are used as thatch (FLAAR Mesoamerica 2017). Heliconia may also be consumed; shoots of several species are harvested for food among the Guayi of Costa Rica (Castaneda Langlois Reference Castaneda Langlois2004). Several Heliconia species are also used medicinally (Balick and Arvigo Reference Balick and Arvigo2015). The relatively common occurrence of bird-of-paradise phytoliths associated with artifacts in our assemblages suggest several potential uses of leaves in the past as utilitarian, consumable, or medicinal plants.

Types of Maize

Measurements and endosperm characteristics of maize kernels from La Blanca and El Ujuxte indicate that two types of maize were consumed at both sites and that the maize at Late Formative El Ujuxte was generally more productive, in terms of having larger kernels, than that at Middle Formative La Blanca (Supplemental Tables 11 and 12). Both sites had kernels indicative of pop or flint (denser endosperm) and flour (porous endosperm) maize. In addition, maize starch recovered from both sites included granules with smooth surfaces (i.e., without compression facets). Such starch grains are produced by flour (soft) endosperm maize (Piperno and Holst Reference Piperno and Holst1998). Although there was overlap in kernel sizes between the Middle and Late Formative datasets, Late Formative maize kernels are clearly larger on average (Av. W × T) than those of the Middle Formative, being both wider (across the face of the kernel, embryo side) and thicker (front to back).

Maize Production and Consumption Patterns

Macrobotanical, sediment phytolith, and artifact residue analysis from La Blanca suggests that maize was processed and consumed at the household level for both elite and commoners during the Conchas phase (1000–600 cal BC). Maize microfossils were commonly recovered from artifacts at La Blanca: of 96, 31 had maize phytoliths and 41 had maize starch. Microfossil concentrations were low, but a diverse array of artifacts—including manos and metates, a ceramic bark beater, ceramic figurine heads, grinding/grating bowl sherds, and other sherds—preserved maize starch and leaf and cob phytoliths (Supplemental Table 2). With the exception of commoner site Operation 34, all site mounds—whether commoner (Ops. 31, 35, 36, and 38) or elite (Ops. 32 and 37)—had a minor maize presence in their macroremains. Operation 34 is unique because it is the only mound to contain any charred cob tissues and sizable kernel fragments.

Kernel:cob and kernel:cupule ratios are useful measures of maize processing and consumption. At the Mississippian site of Cahokia, Illinois, kernel:cob ratios of less than four indicate that household units were shelling their cobs and cooking their own maize kernels, whereas high kernel:cob ratios—those greater than four—indicate that households were being provisioned with shelled maize (Pauketat Reference Pauketat1994; Pearsall Reference Pearsall2019:156, 160). A similar measure is calculated using kernel:cupule ratios at the Olmec sites of La Joya and Bezuapan, Mexico (VanDerwarkerr Reference VanDerwarker2006:102, 103) and the Mississippian site of Moundville, Alabama (Scarry and Steponaitis Reference Scarry, Steponaitis and Gremillion1997:119, 120). Operation 34 at La Blanca contained 14 kernel fragments greater than 2 mm and 6 cob tissues for a kernel:cob ratio of 2.3:1, suggesting that those commoners were shelling and consuming their own maize (Supplemental Table 6).

At El Ujuxte, macrobotanicals indicate that maize was processed for household consumption by both commoners and elites early on during the Caramelo phase (500–300 cal BC), but maize was being provisioned by the end of site occupation during the Sierra phase (cal AD 100–200; Love Reference Love2018). A low kernel:cupule ratio (0.37:1) from the top of mound 36 (Op. 12) in Area B, a commoner context, suggests that they were processing and consuming their own maize during the Caramelo phase (500–300 cal BC; Table 3). Almost no charred maize was recovered during the subsequent Cataluña phase (300–100 cal BC) as El Ujuxte grew in size. During the Pitahaya phase (cal 100 BC–AD 100), the elite residence of Mound 46 (Op. 18) had a high 7.38:1 kernel:cupule ratio, indicating that shelled maize was brought in and cooked. This shift from household maize processing and consumption to provisioning continues during the final Sierra phase (cal AD 100–200) and can be seen in Area B, the middle area (Op. 17) between mounds 36 (Op. 12) and 38 (Op. 13). Operation 17 is a commoner context that is radiocarbon dated to cal AD 115 (Love Reference Love2018) and had an extremely high kernel:cupule ratio of 444:1 (Table 2). This midden, which could represent a single burning event or the repeated deposition of food waste over time, is an exception. However, the extremely high ratio still suggests that maize was being processed and then redistributed to the community, in this case to a commoner household. This stands in contrast to earlier periods where maize was processed and consumed exclusively at commoner and elite households. Unfortunately, insufficient numbers of maize microfossils were recovered from artifacts or sediments to explore production and consumption patterning further.

Table 3. Mean Maize Cupule Width from el Ujuxte, El Gigante, and El Riego.

* Estimate based on 20% shrinkage of kernals during charring

Maize in Regional Context

Recently Kennett and colleagues (Reference Kennett, Thakar, VanDerwarker, Webster, Culleton, Harper, Kistler, Scheffler and Hirth2017) analyzed well-preserved maize macroremains from the El Gigante site in Honduras. Cobs from the Late Formative component of the cave, dating 2350–980 cal BP, overlap temporally with Ujuxte, suggesting that comparisons would be informative. There is evidence at El Gigante for strong selection for increased yield through local development or the introduction of new varieties outside the range of teosinte (Kennett et al. Reference Kennett, Thakar, VanDerwarker, Webster, Culleton, Harper, Kistler, Scheffler and Hirth2017). Kistler and colleagues (Reference Kistler, Thakar, VanDerwarker, Domic, Bergström, George and Harper2020) propose that ancient maize genomes from El Gigante are closely related to ancient and modern maize from South America, raising the possibility that El Ujuxte maize (cal AD 115, 1835 BP) might also be descended from South American maize, given the ages of the two sites (Kennett et al. Reference Kennett, Thakar, VanDerwarker, Webster, Culleton, Harper, Kistler, Scheffler and Hirth2017; Love Reference Love2018). DNA analysis of desiccated maize from the Estanzuela Late Formative period of El Gigante revealed that they were a combination of local, semidomesticated maize and fully domesticated maize types developed in South America (Kistler et al. Reference Kistler, Thakar, VanDerwarker, Domic, Bergström, George and Harper2020).

We compared the size of Late Formative charred maize cupules from El Ujuxte to that of desiccated (uncharred) maize cupules from the same time periods at El Gigante, Honduras, and caves in El Riego, Tehuácan Valley, Mexico (Kennett et al. Reference Kennett, Thakar, VanDerwarker, Webster, Culleton, Harper, Kistler, Scheffler and Hirth2017). To compare charred (El Ujuxte) and desiccated (El Gigante and El Riego) maize cupules, one must take into account the amount of shrinkage that occurs during charring. Charring shrinks cupules about 20%, a middle calculation based on experimental work by Benz (Reference Benz, Johannessen and Hastorf1994). Cupule width was measured from the outside of one cupule wing to the outside of the other wing.

A total of 18 measurable charred cupules were recovered from the beginning of the Late Formative during the Caramelo phase (500–300 cal BC) at El Ujuxte. The average width was 5.39 mm (all measurements were adjusted for 20% shrinkage) with a range of 3.38–7.63 mm. This is larger than the El Gigante Estanzuela Late Formative maize (average width 5.08 mm, n = 15) and the Late Formative El Riego maize (average width 4.77 mm, n = 4; Kennett et al. Reference Kennett, Thakar, VanDerwarker, Webster, Culleton, Harper, Kistler, Scheffler and Hirth2017:Table S5; see Table 3). Four cupules from El Ujuxte exceed the El Gigante mean, and five exceed the El Riego mean. An additional 17 cupules were recovered from the later Pitahaya phase (cal. 100 BC–AD 100; Love Reference Love2018; Supplemental Table 13) during the Late Formative at Ujuxte (average width 4.76 mm, range 4.13–5.95 mm, adjusted for shrinkage) and were close to the same size as maize from Late Formative El Riego.

A paired two-sample t-test of unequal variances was conducted between two groups: the Archaic and Early Formative maize at El Gigante and El Reigo versus the Late Formative maize at El Gigante, El Reigo, and El Ujuxte (Caramelo phase, 500–300 cal BC, Pitahaya phase, cal 100 BC–AD 100; Love Reference Love2018). Kistler and colleagues (Reference Kistler, Thakar, VanDerwarker, Domic, Bergström, George and Harper2020) suggest that Archaic and Early Formative maize at El Gigante is descended from maize of South American origin because it is similar in row number and size to the Late Formative maize recovered from the site. Our paired t-test (df = 5, two-tail p = 0.002) reveals that differences in average cupule widths between the earlier and later maize are real. Based on this trait, the Archaic and Early Formative period maize appears to be different from the Late Formative maize. It is likely that El Gigante, El Riego, and El Ujuxte are all the same types of maize descended from varieties developed in and dispersed from South America (see Supplemental Text 1 for a discussion on a hypothesized Pacific coastal dispersion route from South America that contrasts with the overland hypothesis; Kennett et al. Reference Kennett, Lipson, Prufer, Mora-Marín, George, Rohland and Robinson2022).

Conclusions: Maize Political Economy, Religion, and the Archaic State

The paleoethnobotanical component of the La Blanca / El Ujuxte project sought to understand subsistence strategies of the Middle and Late Formative and the mechanisms behind the emergence of archaic states in the Soconusco region. Paleoethnobotanical results support the original hypothesis proposed by Love (Reference Love and O'Donovan2002:223) that shifts in economic strategies and loss of individual household autonomy were instrumental in the development and maintenance of the archaic state at El Ujuxte. Macrobotanical analyses and those of sediment- and artifact-based residues at La Blanca indicate that individual households maintained their autonomy through the control of production and processing of maize and other foods. There is no evidence for agricultural intensification. In contrast, we see decreasing levels of autonomy throughout the Late Formative at El Ujuxte in the form of ever-increasing levels of maize provisioning. Indeed, it is not until the end of the El Ujuxte occupation, the Sierra phase (cal AD 100–200; Love Reference Love2018), that we find possible evidence for centralization and control over food (for additional markers of centralization, see Love and Rosenswig Reference Love, Rosenswig, Love and Guernsey2021).

The keys to understanding the shift at El Ujuxte are establishment of a maize diet and maize ideology during the Early and Middle Formative and the arrival of more productive maize varieties during the Late Formative. Archaeological research at Cuauhtémoc, a lower-tier center west of La Blanca, revealed that maize became increasingly important in both commoner and elite contexts from the Early to Middle Formative, around 1000 cal BC. Increasing quantities of maize macrobotanical remains, the appearance of manos and metates, and the development of maize iconography suggest that maize played an increasingly important dietary and religious role at Cuauhtémoc (Rosenswig et al. Reference Rosenswig, VanDerwarker, Culleton and Kennett2015). Isotopic analyses of skeletal remains from Early to Middle Formative La Blanca also suggest an increase in maize consumption within the La Blanca polity that coincided with the expansion of food production; for example, an increase in reliance on domesticated dogs (Love Reference Love1989). Although the Cuauhtémoc analysis by Rosenswig and colleagues (Reference Rosenswig, VanDerwarker, Culleton and Kennett2015:104) does not provide evidence that the La Blanca polity focused more exclusively on maize production at the expense of other foods (a key marker of agricultural intensification), the data do suggest that maize was central to La Blanca society. Our research has shown that evidence for root/tuber use is present but uncommon at both La Blanca and Ujuxte: no lerén, arrowroot, or manioc starch was recovered, and Calathea and Maranta phytoliths were relatively rare.

South American maize was instrumental in the development and centralization of the maize economy. During the shift from the Middle to Late Formative, the ideology of rulership becomes more grandiose, with rulers likening their actions to those of the maize god at the time of creation (Love Reference Love2016). However, the richness of plant taxa at La Blanca and El Ujuxte is virtually identical, suggesting that once maize agricultural systems were established during the Middle Formative, there was no intensification, despite the increasing cultural importance of maize. The more productive South American maize allowed for higher levels of maize productivity without agricultural intensification, such as shortening the fallow period in milpa cycles or constructing agricultural terraces or raised fields. Given the importance of maize in both diet and religion, Late Formative elites could and did exert their authority and control of maize through the production and redistribution of food resources such as those seen at El Ujuxte.

Acknowledgments

Fieldwork in Guatemala and the export of samples for analysis were authorized by the Instituto de Antropología e Historia de Guatemala. Meghann O'Brien sampled artifacts for residues in Guatemala in the summer of 2005, and Jason Fenton assisted with phytolith scanning at the University of Missouri. José Guillermo Rodriguez-Plaza provided the Spanish translation. Thank you to the three anonymous reviewers whose comments greatly strengthened this article.

Funding Statement

Work at La Blanca was supported by the National Science Foundation (Dissertation Improvement Grant, BCS-0451024, BCS-1424298), the National Geographic Society, the Wenner Gren Foundation for Anthropological Research, the Foundation for the Advancement of Mesoamerican Studies, the New World Archaeological Foundation, the University of Texas Department of Art and Art History, California State University Northridge, the Universidad del Valle de Guatemala, and a Fulbright-Hayes Dissertation Research Abroad Fellowship. Research at El Ujuxte was aided by grants from the National Science Foundation (SBR-9807304, SBR-96171123, and SBR-9510991), the Wenner Gren Foundation for Anthropological Research, the Heinz Foundation, the Universidad del Valle de Guatemala, Sonoma State University, California State University Northridge, and the Fulbright Senior Fellowship program.

Data Availability Statement

Data from this study are stored on tDAR, https://core.tdar.org/project/470840/archaeobotanical-data-for-el-ujuxte-and-la-blanca-guatemala-excavations. The collections of the La Blanca and El Ujuxte materials are in the Ceramoteca of the Instituto de Antropología e Historia de Guatemala and in the Salón 3 storage facility. Digital copies of all field records and data are housed at the same institution.

Competing Interests

The authors declare none.

Supplemental Material

For supplemental material accompanying this article, visit https://doi.org/10.1017/laq.2023.3.

Supplemental Text 1: South American maize and Pacific coastal trading network hypothesis.

Supplemental Table 1. Summary of Economic Phytolith and Starch Grain Types Found on Different Classes of Artifacts at La Blanca and El Ujuxte.

Supplemental Table 2. Total Phytolith and Starch Counts for Artifacts from La Blanca.

Supplemental Table 3. Total Phytolith and Starch Counts for Artifacts from El Ujuxte.

Supplemental Table 4. Economic Phytoliths from La Blanca Sediments.

Supplemental Table 5. Economic Phytoliths from El Ujuxte Sediments.

Supplemental Table 6. Macrobotanical Remain Totals from La Blanca.

Supplemental Table 7. Macrobotanical Remain Totals from El Ujuxte.

Supplemental Table 8. La Blanca Richness and Density Data.

Supplemental Table 9. El Ujuxte Richness and Density Data.

Supplemental Table 10. Phaseolus Bean Measurements from El Ujuxte.

Supplemental Table 11. Maize Kernel Measurements from El Ujuxte and La Blanca.

Supplemental Table 12. Maize Cupule Measurements from El Ujuxte.

Supplemental Table 13. Maize Kernel/Cupule Ratios at El Ujuxte.

References

References Cited

Arnold, Philip J. 2009. Settlement and Subsistence among the Early Formative Gulf Olmec. Journal of Anthropological Archaeology 28(4):397411.CrossRefGoogle Scholar
Awe, Jaime J., Ebert, Claire E., James Stemp, W., Kathryn Brown, M., Sullivan, Lauren A., and Garber, James F.. 2021. Lowland Maya Genesis: The Late Archaic to Late Early Formative Transition in the Upper Belize River Valley. Ancient Mesoamerica 32(3):519544.CrossRefGoogle Scholar
Balick, Michael J., and Arvigo, Rosita. 2015. Messages from the Gods: A Guide to the Useful Plants of Belize. Oxford University Press, New York.Google Scholar
Benz, Bruce F. 1994. Can Prehistoric Racial Diversification Be Deciphered from Burned Corn Cobs? In Corn and Culture in the Prehistoric New World, edited by Johannessen, Sissel and Hastorf, Christine A., pp. 2333. Westview Press, Boulder, Colorado.Google Scholar
Blake, Michael, and Neff, Hector. 2011. Evidence for the Diversity of Late Archaic and Early Formative Plant Use in the Soconusco Region of Mexico and Guatemala. In Early Mesoamerican Social Transformations: Archaic and Formative Lifeways in the Soconusco Region, edited by Lesure, Richard, pp. 4766. University of California Press, Berkeley.Google Scholar
Cagnato, Clarissa, and Ponce, Jocelyne M.. 2017. Ancient Maya Manioc (Manihot Esculenta Crantz) Consumption: Starch Grain Evidence from Late to Terminal Classic (8th–9th Century CE) Occupation at La Corona, Northwestern Petén, Guatemala. Journal of Archaeological Science: Reports 16:276286.Google Scholar
Castaneda Langlois, Hector. 2004. Ethnobotanical Analysis of Different Successional Stages as Sources of Wild Edible Plants for the Guaymi People in Costa Rica. Master's thesis, Department of Natural Resources and the Environment, University of Florida, Gainesville.Google Scholar
Chandler-Ezell, Karol, and Pearsall, Deborah M.. 2003. “Piggyback” Microfossil Processing: Joint Starch and Phytolith Sampling from Stone Tools. Phytolitherian 15(3):28.Google Scholar
Coe, Michael D., and Flannery, Kent V.. 1967. Early Cultures and Human Ecology in South Coastal Guatemala. Smithsonian Contributions to Anthropology Vol. 3. Smithsonian Institution, Washington, DC.CrossRefGoogle Scholar
Criley, Richard A., and Broschat, Timothy K.. 1992. Heliconia: Botany and Horticulture of a New Floral Crop. In Horticultural Reviews, Vol. 14, edited by Janick, Jules, pp. 155. John Wiley, New York.Google Scholar
Díaz-José, Julio., Guevara-Hernández, Francisco, Morales-Ríos, Verónica, and López-Ayala, José Luis. 2019. Traditional Knowledge of Edible Wild Plants Used by Indigenous Communities in Zongolica, Mexico. Ecology of Food and Nutrition 58(5):511526.CrossRefGoogle ScholarPubMed
Dickau, Ruth, Ranere, Anthony J., and Cooke, Richard G.. 2007. Starch Grain Evidence for the Preceramic Dispersals of Maize and Root Crops into Tropical Dry and Humid Forests of Panama. PNAS 104(9):36513656.CrossRefGoogle ScholarPubMed
Doebley, John. 2004. The Genetics of Maize Evolution. Annual Review of Genetics 38(1):3759.CrossRefGoogle ScholarPubMed
Feddema, Vicki Lynn. 1993. Early Formative Subsistence and Agriculture in Southeastern Mesoamerica. Master's thesis, Department of Anthropology and Sociology, University of British Columbia, Vancouver.Google Scholar
FLAAR Mesoamerica. 2017. Heliconia Leaves (Platanillo) as Thatch for Roofs of Mayan Houses in Remote Q'eqchi’ Areas of Alta Verapaz. Electronic document, https://www.maya-archaeology.org/mayan-archaeology-guatemala-belize-mexico-honduras-el-salvador/heliconia-platanillo-roof-thatch-mayan-house-architecture.php, accessed May 16, 2022.Google Scholar
Haeckel, Ingrid. 2008. The “Arco Floral”: Ethnobotany of Tillandsia and Dasylirion spp. in a Mexican Religious Adornment. Economic Botany 62(1):9095.CrossRefGoogle Scholar
Hart, Thomas C. 2011. Evaluating the Usefulness of Phytoliths and Starch Grains Found on Survey Artifacts. Journal of Archaeological Science 38:32443253.CrossRefGoogle Scholar
Hufford, Matthew B., Xun Xu, Joost van Heerwaarden, Tanja Pyhäjärvi, Jer-Ming Chia, Reed A. Cartwright, Robert J. Elshire, , et al. 2012. Comparative Population Genomics of Maize Domestication and Improvement. Nature Genetics 44(7):808811.CrossRefGoogle ScholarPubMed
Kennett, Douglas J., Lipson, Mark, Prufer, Keith M., Mora-Marín, David, George, Richard J., Rohland, Nadin, Robinson, Mark, et al. 2022. South-to-North Migration Preceded the Advent of Intensive Farming in the Maya Region. Nature Communications 13(1):110.CrossRefGoogle ScholarPubMed
Kennett, Douglas J., Piperno, Dolores R., Jones, John G., Neff, Hector, Voorhies, Barbara, Walsh, Megan K., and Culleton, Brendan J.. 2010. Pre-Pottery Farmers on the Pacific Coast of Southern Mexico. Journal of Archaeological Science 37(12):34013411.CrossRefGoogle Scholar
Kennett, Douglas J., Thakar, Heather B., VanDerwarker, Amber M., Webster, David L., Culleton, Brendan J., Harper, Thomas K., Kistler, Logan, Scheffler, Timothy E., and Hirth, Kenneth. 2017. High-Precision Chronology for Central American Maize Diversification from El Gigante Rockshelter, Honduras. PNAS 114(34):90269031.CrossRefGoogle ScholarPubMed
Killion, Thomas W. 2013. Nonagricultural Cultivation and Social Complexity: The Olmec, their Ancestors, and Mexico's Southern Gulf Coast Lowlands. Current Anthropology 54(5):569606.CrossRefGoogle Scholar
Kistler, Logan, Thakar, Heather B., VanDerwarker, Amber M., Domic, Alejandra, Bergström, Anders, George, Richard J., Harper, Thomas K., et al. 2020. Archaeological Central American Maize Genomes Suggest Ancient Gene Flow from South America. PNAS 117(52):3312433129.CrossRefGoogle ScholarPubMed
Kress, W. John. 1990. The Taxonomy of Old World Heliconia (Heliconiaceae). Allertonia 6(1):158.Google Scholar
Lazos Chaverro, Elena, and Roces, Maria Elena Alvarez-Buylla. 1988. Ethnobotany in a Tropical-Humid Region: The Home Gardens of Balzapote, Veracruz, Mexico. Journal of Ethnobiology 8(1):4579.Google Scholar
Lesure, Richard G., Sinesky, R. J., and Wake, Thomas A.. 2021. The End of the Archaic in the Soconusco Region of Mesoamerica. In Preceramic Mesoamerica, edited by Lohse, Jon C., Borejsza, Aleksander, and Joyce, Arthur A, pp. 481504. Routledge, London.CrossRefGoogle Scholar
Love, Michael. 1989. Early Settlements and Chronology of the Rio Naranjo, Guatemala. PhD dissertation, Department of Anthropology, University of California, Berkeley.Google Scholar
Love, Michael. 2002. Dominion, Resistance, and Political Cycling in Formative Period Pacific Guatemala. In The Dynamics of Power, edited by O'Donovan, Maria, pp. 214237. Occasional Paper 30. Center for Archaeological Investigations, Southern Illinois University, Carbondale.Google Scholar
Love, Michael. 2007. Recent Research in the Southern Highlands and Pacific Coast of Mesoamerica. Journal of Archaeological Research 15(4):275328.CrossRefGoogle Scholar
Love, Michael. 2012. The Development of Complex Societies in Formative-Period Pacific Guatemala and Chiapas. In The Oxford Handbook of Mesoamerican Archaeology, edited by Nichols, Deborah L. and Pool, Christopher A., pp. 200214. Oxford University Press, Oxford.CrossRefGoogle Scholar
Love, Michael. 2016. Urbanization and the Practices of Identity at La Blanca, Guatemala. In Archaeology and Identity on the Pacific Coast and Southern Highlands of Mesoamerica, edited by Claudia Garcîa-Des Lauriers and Michael W. Love, pp. 2951. University of Utah Press, Salt Lake City.Google Scholar
Love, Michael. 2018. Kaminaljuyu Chronology and Ceramic Analysis: An Alternative View. Latin American Antiquity 29(2):260278.CrossRefGoogle Scholar
Love, Michael, and Guernsey, Julia. 2011. La Blanca and the Soconusco Middle Formative. In Early Mesoamerican Social Transformations: Archaic and Formative Lifeways in the Soconusco Region, edited by Lesure, Richard G., pp. 170188. University of California Press, Berkeley.Google Scholar
Love, Michael, and Rosenswig, Robert M.. 2021. The New Normal: Formative Period Cities on the Pacific Coast of Southern Mesoamerica. In Early Mesoamerican Cities: New Perspectives on Urbanism and Urbanization in the Formative Period, edited by Love, Michael E. and Guernsey, Julia, pp. 141169. Cambridge University Press, Cambridge.CrossRefGoogle Scholar
Mabberley, David J. 1997. The Plant-Book. Cambridge University Press, Cambridge.Google Scholar
Mangelsdorf, Paul C. 1967. Report on Mineralized Corn Cobs and Other Prehistoric Specimens from Salinas La Blanca. In Early Cultures and Human Ecology in South Coastal Guatemala, Vol. 3, edited by Coe, Michael D. and Flannery, Kent V., pp. 127128. Smithsonian Institution, Washington, DC.Google Scholar
Neff, Hector, Pearsall, Deborah M., Jones, John G., Arroyo, Bárbara, Collins, Shawn K., and Freidel, Dorothy E.. 2006. Early Maya Adaptive Patterns: Mid-Late Holocene Paleoenvironmental Evidence from Pacific Guatemala. Latin American Antiquity 17(3):287315.CrossRefGoogle Scholar
Nichols, Deborah L. 2015. Intensive Agriculture and Early Complex Societies of the Basin of Mexico: The Formative Period. Ancient Mesoamerica 26(2):407421.CrossRefGoogle Scholar
Pauketat, Timothy R. 1994. The Ascent of Chiefs: Cahokia and Mississippian Politics in Native North America. University of Alabama Press, Tuscaloosa.Google Scholar
Pearsall, Deborah M. 2015. Paleoethnobotany: A Handbook of Procedures. 3rd ed. Left Coast Press, Walnut Creek, California.Google Scholar
Pearsall, Deborah M. 2019. Case Studies in Paleoethnobotany: Understanding Ancient Lifeways through the Study of Phytoliths, Starch, Macroremains, and Pollen. Routledge, New YorkGoogle Scholar
Piperno, Dolores R. 2006. Phytoliths: A Comprehensive Guide for Archaeologists and Paleoecologists. AltaMira Press, Lanham, Maryland.Google Scholar
Piperno, Dolores. R., and Flannery, Kent. V.. 2001. The Earliest Archaeological Maize (Zea mays L.) from Highland Mexico: New Accelerator Mass Spectrometry Dates and their Implications. PNAS 98(4):21012103.CrossRefGoogle ScholarPubMed
Piperno, Dolores R., and Holst, Irene. 1998. The Presence of Starch Grains on Prehistoric Stone Tools from the Humid Neotropics: Indications of Early Tuber Use and Agriculture in Panama. Journal of Archaeological Science 25:765776.CrossRefGoogle Scholar
Pohl, Mary E. D., Piperno, Dolores R., Pope, Kevin O., and Jones, John G.. 2007. Microfossil Evidence for Pre-Columbian Maize Dispersals in the Neotropics from San Andres, Tabasco, Mexico. PNAS 104(16):68706875.CrossRefGoogle Scholar
Popper, Virginia S., and Lesure, Richard G.. 2010. Macrobotanical Remains from El Varal, with a Comparison to Inland Sites. In Settlement and Subsistence at Early Formative Soconusco: El Varal and the Problem of Inter-Site Assemblage Variation, edited by Lesure, Richard, pp. 113114. Monograph 65. Cotsen Institute of Archaeology, Los Angeles.CrossRefGoogle Scholar
Powis, Terry G., Hurst, W. Jeffrey, del Carmen Rodríguez, María, Ortíz C., Ponciano, Blake, Michael, Cheetham, David, Coe, Michael D., and Hodgson, John G.. 2007. Oldest Chocolate in the New World. Antiquity Project Gallery 81(314). Electronic document, https://www.antiquity.ac.uk/projgall/powis314/, accessed May 23, 2023.Google Scholar
Ranere, Anthony J., Piperno, Dolores R., Holst, Irene, Dickau, Ruth, and Iriarte, José. 2009. The Cultural and Chronological Context of Early Holocene Maize and Squash Domestication in the Central Balsas River Valley, Mexico. PNAS 106(13):50145018.CrossRefGoogle ScholarPubMed
Rosenswig, Robert M. 2015. A Mosaic of Adaptation: The Archaeological Record for Mesoamerica's Archaic Period. Journal of Archaeological Research 23(2):115162.CrossRefGoogle Scholar
Rosenswig, Robert M., VanDerwarker, Amber M., Culleton, Brendan J., and Kennett, Douglas J.. 2015. Is It Agriculture Yet? Intensified Maize-Use at 1000 cal BC in the Soconusco and Mesoamerica. Journal of Anthropological Archaeology 40:89108.CrossRefGoogle Scholar
Scarry, C. Margaret, and Steponaitis, Vincas P.. 1997. Between Farmstead and Center: The Natural and Social Landscape of Moundville. In People, Plants, and Landscapes: Studies in Paleoethnobotany, edited by Gremillion, Kristen J., pp. 107122. University of Alabama Press, Tuscaloosa.Google Scholar
Searcy, Michael T. 2011. The Life-Giving Stone: Ethnoarchaeology of the Maya Matates. University of Arizona Press, Tucson.Google Scholar
Vallebueno-Estrada, Miguel, Rodríguez-Arévalo, Isaac, Rougon-Cardoso, Alejandra, González, Javier Martínez, Cook, Angel García, Montiel, Rafael, and Vielle-Calzada, Jean-Philippe. 2016. The Earliest Maize from San Marcos Tehuacán Is a Partial Domesticate with Genomic Evidence of Inbreeding. PNAS 113(49):1415114156.CrossRefGoogle ScholarPubMed
VanDerwarker, Amber. 2006. Farming, Hunting, and Fishing in the Olmec World. University of Texas Press, Austin.CrossRefGoogle Scholar
Voorhies, Barbara, and Kennett, Douglas. 1995. Buried Sites on the Soconusco Coastal Plain, Chiapas, Mexico. Journal of Field Archaeology 22(1):6579.Google Scholar
Figure 0

Figure 1. The Pacific coastal plain showing the Formative period sites discussed in the article.

Figure 1

Table 1. Richness of Taxa at La Blanca and El Ujuxte.

Figure 2

Table 2. Maize Kernel: Cupule Ratio at El Ujuxte.

Figure 3

Table 3. Mean Maize Cupule Width from el Ujuxte, El Gigante, and El Riego.

Supplementary material: File

Hart et al. supplementary material

Hart et al. supplementary material

Download Hart et al. supplementary material(File)
File 129.9 KB