Tobacco in the Pacific Northwest

The genus Nicotiana (family: Solanaceae) includes a number of species of leafy herbs and shrubs. The presence of the psychoactive alkaloid nicotine in the leaves of Nicotiana species has made tobaccos plants of interest for peoples around the world. Several species, including the hybrid N. tabacum used in the production of modern commercial tobacco products, are indigenous to the Americas, with the ultimate origins of most species lying in South America (Goodspeed Reference Goodspeed1954). Although the Pacific Northwest is at the northern limit of the natural range of the genus, two species—N. attenuata (coyote tobacco) and N. quadrivalvis (Indian tobacco; syn: N. bigelovii)—were in the region before contact, and both are important to Indigenous peoples of the Plateau and Northwest Coast.

Kroeber (Reference Kroeber1941) reports that a large area from the central Columbia Plateau through the Fraser Plateau is populated by groups who traditionally smoked tobacco. The Columbia Plateau to the south and east of this area was supposedly without traditional tobacco use (but see Tushingham et al. Reference Tushingham, Snyder, Brownstein, Damitio and Gang2018). This is summarized by Kroeber (Reference Kroeber1941) in his Map 8, reproduced in part here (Figure 1). In the Pacific Northwest outside of the Plateau, there is more variability in the use of tobacco. West of the Cascade Range and north of the Columbia River, no coastal peoples included in the survey indicated that they traditionally smoked tobacco. Instead, coastal peoples smoked a variety of other plants, including T. brevifolia needles, A. uva-ursi leaves, and others (Gunther Reference Gunther1973; Kroeber Reference Kroeber1941). Given the profound effects of contact on Indigenous practices, it is difficult to say with complete confidence that coastal peoples never used tobacco. Furthermore, the lack of a durable material culture associated with smoking on the coast (Gunther Reference Gunther1973:35; Turner Reference Turner1998:163–164) limits the potential for relevant material culture to preserve archaeologically.

The two tobaccos native to the region, N. attenuata and N. quadrivalvis, have distinct, but overlapping, distributions. The former species is endemic to the Plateau, occurring wild and under cultivation as far north as Secwepemc country in southern-central British Columbia (Teit Reference Teit and Boas1909), whereas the current natural range of the latter extends only as far north as central Oregon (Goodspeed Reference Goodspeed1954; Hammet Reference Hammet and Winter2000; Turner and Taylor Reference Turner and Taylor1972; Winter Reference Winter and Winter2000). Both species were used in different contexts by various peoples of the Plateau. Except for chewing of N. quadrivalvis among the Haida and Tlingit (Turner and Taylor Reference Turner and Taylor1972), we could not find any references indicating tobacco cultivation or use on the coast north of the mouth of the Columbia River.

For the Pacific Northwest peoples who used tobacco, it was regarded as a sacred and powerful plant that could serve in recreational, ceremonial, and medicinal roles. Early interactions between Natives and non-Natives in the Pacific Northwest were often punctuated by the trading or sharing of tobacco (Douglas Reference Douglas1914). In these cases, smoking (of tobacco, at least) is an activity that signaled and reinforced positive interpersonal relationships and doubled as a means of conflict resolution. Other perspectives, including those drawing on present-day discussions with Indigenous people, emphasize the sacred nature of tobacco and the durability of its importance to Native communities (Phillips Reference Phillips, Bollwerk and Tushingham2016; Snyder Reference Snyder, Bollwerk and Tushingham2016). Tobacco is frequently singled out as having supernatural origins by Interior Northwest peoples. For example, Keddie (Reference Keddie, Bollwerk and Tushingham2016) citing (Teit Reference Teit and Boas1900:309) notes that Syilx (Okanagans) would smoke ceremonially before all “serious undertakings.” Likewise, Turner (Reference Turner2014:213) explains that for a number of interior peoples “all councils and many feasts began with smoking ceremonies.” This practice is continued today as what Turner (Reference Turner2014:214) identifies as part of “routine rituals of respect for the spirits . . . that provide for the people.”

Artifact Distribution Analysis

To explore the precontact distribution of smoking across time and space, we synthesized data from (1) a review of published and gray literature, (2) an exploration of the collections held by numerous institutions in the United States and Canada via the Reciprocal Research Network (RRN; see Rowley Reference Rowley2013), and (3) a systematic search of the collections databases of the Washington State University Museum of Anthropology (WSU MoA), which curates extensive collections from over 600 sites in the Pacific Northwest (Damitio et al. Reference Damitio, Gilreath-Brown and Tushingham2018; for details of search methodology, see Supplemental Text 1). Many of the references to pipes or pipe fragments had only very general provenience. However, only data on smoking artifacts with proveniences in well-documented archaeological contexts were included in the study. Site location and other data were compiled in a Microsoft Access database and exported to ArcGIS Desktop 10 for visualization and analysis.

Chemical Analyses

We employed chemical methods developed in part for this project that involve both basic biomarker screening and ancient residue metabolomics approaches. The biomarker approach employed here and by others (e.g., Echeverría et al. Reference Echeverría, Planella and Niemeyer2014; Eerkens et al. Reference Eerkens, Ardura, Fiehn, Blake, Lentz, Tushingham and Palazoglu2012; Rafferty Reference Rafferty2002, Reference Rafferty2006; Rafferty et al. Reference Rafferty, Lednev, Virkler and Chovanec2012; Tushingham et al. Reference Tushingham, Ardura, Eerkens, Palazoglu, Shahbaz and Fiehn2013, Reference Tushingham, Snyder, Brownstein, Damitio and Gang2018) relies on the identification of a small number of compounds associated with specific plants. This approach can suggest the association of an artifact with a plant taxon, but further refinement is often impossible because target compounds are typically associated with more than one plant species or taxonomic group. Thus, while the biomarker nicotine indicates a likely association with tobacco, the biomarker approach cannot distinguish between species of Nicotiana.

Metabolomics is the study of the comprehensive complement of compounds involved in cellular metabolism. Every organism relies on many thousands of such compounds—metabolites—for both basic and specialized biological functions. Most metabolites are shared across large taxonomic groupings, but some are unique in their presence or absence, or in their quantity within a species or genus (e.g., nicotine in the genus Nicotiana). A metabolomics approach in archaeological residue analysis seeks to reduce reliance on the presence of a single compound, as in the biomarker approach, and improve the possibility of species-level identification by instead comparing the entire metabolic “fingerprint” of the target species with the compounds extracted from an archaeological specimen. This fingerprint consists of the total metabolome—all of the metabolites in a biological sample—as characterized through chemical extraction and detection using a variety of instrumentation.

In this study, we characterized the chemical residue contents of archaeological artifacts and experimental specimens using methods developed and discussed in detail by Brownstein and colleagues (Reference Brownstein, Tushingham, Damitio, Nguyen and Gang2020). For residue extraction, samples were submerged sequentially in three solvents—2% aqueous tartaric acid, acetonitrile:2-propanol:water [3:2:2], and methyl tert-butyl ether—and sonicated for 10 minutes in each. We employed three solvents in sequence to extract the broadest possible range of compounds. Because the metabolomics analysis is untargeted, it is important that the compounds extracted and characterized be as nearly representative of the total metabolic fingerprint as possible in order to capture the uniqueness of each sample.

Following drying and resuspension in a smaller, more concentrated volume, extracts were analyzed using a liquid chromatography–mass spectrometry (LC-MS) system (see Brownstein et al. [Reference Brownstein, Tushingham, Damitio, Nguyen and Gang2020] for details and technical specifications). The LC-MS data were processed using MZmine v2.32 (Pluskal et al. Reference Pluskal, Castillo, Villar-Briones and Orešič2010). Among other things, this resulted in a list of all compounds in each analysis with the mass-to-charge ratio (m/z, which corresponds to the molecular mass of the detected compound), the retention time, and the peak intensity for each compound.

Before comparing the metabolic fingerprints of each sample, we conducted a targeted analysis of each specimen for known biomarkers. Although the vast majority of the compounds in the output of the LC-MS analysis are unidentified, it is possible to locate known compounds using chemical standards run under the same conditions. This was done for, among others, anabasine, cotinine, and nicotine as biomarkers for tobaccos and arbutin as a biomarker for A. uva-ursi. The tabular output of the LC-MS analysis was checked for these compounds in all specimens. Additionally, the presence or, more commonly, the absence of these compounds was confirmed through a direct visual analysis of the chromatograms and mass spectra produced by the LC-MS analysis.

For metabolomics analysis, the compounds extracted from each archaeological specimen were compared with the compounds present in pipes each experimentally smoked with one of 15 different plant species (Table 1) from a list compiled by Tushingham and colleagues (Reference Tushingham, Snyder, Brownstein, Damitio and Gang2018; see also Brownstein et al. Reference Brownstein, Tushingham, Damitio, Nguyen and Gang2020). This list encompasses plants known to have been used by Pacific Northwest peoples as well as a number of plants smoked elsewhere in precontact North America. These experimental samples were produced using commercially purchased unglazed ceramic pipes and plant samples either obtained from herbaria or grown by Brownstein under controlled conditions. Plant samples were dried, placed in the pipe bowl, and ignited. The smoke was then repeatedly drawn through the pipe and then expelled using a large syringe. Each experimentally smoked pipe was replicated five times, and each replicate was used to smoke five full bowls of the plant in question. For comparison to archaeological specimens, the replicates were combined.

To compare the contents of the residues extracted from archaeological specimens to the experimentally smoked plants, a Venn diagram method was used. The LC-MS output data were processed using Microsoft Excel to produce lists for each sample of the compounds present (represented by arbitrary unique numerical identifiers). This list for each archaeological specimen was compared to the compound lists for all experimentally smoked pipes and a blank control pipe using the Draw Venn Diagram web application (Van de Peer Reference Van de Peer2015). Of greatest relevance to our analysis are the categories where there are compounds shared uniquely between an archaeological specimen and a single plant species. Where there are compounds shared only between a single plant species and a pipe specimen, there is evidence that the pipe was used to smoke that species. This association is strengthened by the presence of more than one shared compound between a plant and a pipe specimen, as do consistent matches across solvents (the extracts from each of the three solvents were treated as separate samples, meaning that each archaeological specimen or experimental pipe generated three analytical samples).

Contamination

The possibility of contamination is a major concern in the development and execution of ancient residue analyses (Washburn et al. Reference Washburn, Washburn, Shipkova and Pelleymounter2014). The artifacts included in this study were collected in the mid-twentieth century, when tobacco use by researchers was more common, and little or no precautions would have been taken to avoid contamination either during initial collection and processing or in later collections work. Although strict precautions were taken during our lab work to avoid outside introduction of nicotine or other compounds, or cross-contamination between artifacts, we cannot say with absolute certainty that the nicotine and other compounds detected in this study were not introduced. With that disclaimer, however, we are confident that our results are not the result of contamination. First, all but one artifact (45GR30.2197, which was briefly on public display at a small museum) have been in closed repository storage since their collection except during rehousing and occasional examination by researchers in a few cases. Second, we do not see the consistent presence of any compound or group of compounds across any group of the artifacts analyzed that would suggest systematic exposure to a contaminant. In other words, we would be more concerned had we identified nicotine in many of the artifacts analyzed, instead of one.

Mid-Columbia Pipe Study

Thirty-four precontact pipes and pipe fragments from Interior Northwest archaeological sites are in collections at the WSU MoA. Of these, 12 pipes from three sites in the Mid-Columbia region were selected for biomarker and metabolomics analyses, all of which were collected from cache (45DO172), house floor (45GR27, 45GR30), and roasting feature (45GR27) contexts ranging in age from approximately 620 to 4500 cal BP (Table 2). Perhaps unsurprisingly, given the range of time covered, the study artifacts represent a diverse suite of styles and materials in use in the region (Figure 2). Materials include steatite (n = 8), basalt (n = 2), and fine-grained sedimentary rock (i.e., siltstone; n = 2). Styles include a thin tubular stem with a bell-shaped bowl and thickened mouthpiece (n = 6); a more robust conical bowl, likely used with a separate stem and mouthpiece (n = 2); the oblong pipes from the Cox's Pond site (n = 3); and the cigar-shaped specimen from Cox's Pond (n = 1).

Table 2. Radiocarbon Dates from Sites in the Mid-Columbia Study.

^a Dates calibrated against the IntCal13 curve (Reimer et al. Reference Reimer, Bard, Bayliss, Warren Beck, Blackwell, Ramsey and Buck2013) using CALIB rev. 5.0 (Stuiver et al. Reference Stuiver, Reimer and Reimer2005).

^b Ranges where p < 0.01 are omitted.

Figure 2. Selected pipes from the Mid-Columbia study representing the stylistic diversity of pipes in the region: (a) 45GR27.116, a conical granite pipe bowl; (b) 45GR30.2197, a fragment of a thin-walled tubular steatite pipe; and (c) 45DO172.2224, a robust oblong steatite pipe with regular incisions. Illustration by Trent Raymer.

45GR27

The Ridge Bottom Village site (45GR27) is located near 45GR30 (see below) along the shore of Moses Lake in central Washington state. The site consists of 33 generally circular depressions, likely house pits, three of which were excavated (Daugherty Reference Daugherty1952). Two pipe artifacts were collected from the site, and both were selected for analysis: a complete pipe bowl (45GR27.116) found in association with Feature 1, identified by Pouley (Reference Pouley2001) as a roasting pit, and a pipe fragment (45GR27.74) found in the floor of House Pit 1. The complete granite bowl is conical and thick walled, and it was likely used in conjunction with an inset stem made of some perishable material. The pipe fragment is similarly robust in construction and material, suggesting it was similar in style to the recovered bowl (Daugherty Reference Daugherty1952:381), even though these artifacts were recovered from contexts dating several hundred years apart. The roasting pit associated with the complete pipe bowl dates to 1520 ± 40 BP (1334–1524 cal BP; Table 3; Pouley Reference Pouley2001). House Pit 1, the context for the pipe fragment, has not been radiocarbon dated, but Pouley (Reference Pouley2001:83–84) suggests that it is roughly contemporaneous with the adjacent House Pit 2, which dates to 800 ± 60 BP (657–803 cal BP).

Table 3. Summary of Results by Site.

^a See Tushingham et al. Reference Tushingham, Snyder, Brownstein, Damitio and Gang2018.

^b Postcontact context.

^c See Tushingham et al. Reference Tushingham, Ardura, Eerkens, Palazoglu, Shahbaz and Fiehn2013.

Fraser Valley Pipe Study

Thirty-five pipes, pipe fragments, and pipe blanks from Esilao (DjRi-5), a pithouse village in the Fraser Canyon dating from 5490 ± 500 BP to the early nineteenth century AD (Borden Reference Borden, Berger and Libby1965; Mitchell Reference Mitchell1963), were included in the study. Tested pipe artifacts from DjRi-5—a subset of a total of 62 such artifacts collected from House Pit 1—include a variety of forms constructed primarily of ground and carved steatite. The majority are similar to tubular forms common in the Mid-Columbia study, but they have comparatively thicker walls (for a detailed discussion of stylistic variation of site pipes, see Mitchell [Reference Mitchell1963]). Chronology at the site is difficult to parse from published materials, but most pipes from Esilao also appear to date from the Late Archaic, whereas some are associated with postcontact deposits. One siltstone pipe from the Marpole (2400–ca. 1300 BP; Moss Reference Moss2011:98) component of the Glenrose Cannery site (DgRr-6) on the Fraser River nearer the coast (Matson Reference Matson and Matson1976:154) was tested in addition to those from DjRi-5.

Other Studies

Pipes found in relative isolation were also tested: a pumice pipe bowl from Fryingpan Rockshelter (45PI43) on the eastern slopes of Mt. Rainier and a carved steatite pipe recovered during construction at a residence in Pasco, Washington, in 2017. Lubinski and Burtchard (Reference Lubinski and Burtchard2005) assign a range of 250–1150 cal BP to the human use of 45PI43. The pipe, however, was collected from a cache in the wall of the rockshelter (Rice Reference Rice1965) and cannot be confidently associated with any particular date or period. The pipe from Pasco, Washington, is difficult to contextualize, although its material and intricate decorative carving suggest a link to the Late Archaic (e.g., Duff Reference Duff1956). This latter pipe was collected and stored for some time by a nonprofessional, and it may have been exposed to greater risk of contamination.