Pre-Roman improvements to agricultural production: Evidence from livestock husbandry in late prehistoric Italy

Angela Trentacoste; Ariadna Nieto-Espinet; Silvia Valenzuela-Lamas

doi:10.1371/journal.pone.0208109

Abstract

Domestication of wild cattle, sheep, and pigs began a process of body size diminution. In most of Western Europe this process continued across prehistory and was not reversed until the Roman period. However, in Italy, an increase in livestock body size occurred during the Iron Age, earlier than the Western provinces. In order to better understand the nature and timing of this early increase in animal size, this paper presents a detailed regional study of taxonomic abundance and biometric data from zooarchaeological assemblages recovered from the Po and Venetian–Friulian Plains in northern Italy. Our results demonstrate a high level of regionality in the choice of species exploited, with husbandry systems focused on different domesticates, as well as regional differences in animal size. However, despite significant variation in species frequencies, settlement structure, and epigraphic tradition, all areas with sufficient data demonstrate similar significant changes in livestock body size. Cattle and sheep increased incrementally in size prior to the Roman conquest in all regions considered; surprisingly, pigs continued to decrease in size throughout later prehistory. The incremental pace and pan-regional character of the size change in cattle and sheep suggests an internally motivated phenomenon rather than herd replacement with a new larger population, as might follow colonisation or conquest. The divergence in size trends for bovids and suids suggests a noteworthy change in cattle and sheep herding practices during the Iron Age or final centuries of the Bronze Age, in contrast with greater continuity in pig management. Our analysis provides a thorough zooarchaeological synthesis for northern Italy and, for the first time, demonstrates that both cattle and sheep increased in size outside of Roman territory well before the conquest of this area. This study offers a basis for future chemical analyses (DNA, isotopes), which will further investigate the cause(s) of livestock size changes in northern Italy.

Citation: Trentacoste A, Nieto-Espinet A, Valenzuela-Lamas S (2018) Pre-Roman improvements to agricultural production: Evidence from livestock husbandry in late prehistoric Italy. PLoS ONE 13(12): e0208109. https://doi.org/10.1371/journal.pone.0208109

Editor: Peter F. Biehl, University at Buffalo - The State University of New York, UNITED STATES

Received: August 22, 2018; Accepted: November 12, 2018; Published: December 31, 2018

Copyright: © 2018 Trentacoste et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: Biometric standards for cattle are available from doi: 10.13140/RG.2.2.13512.78081. All other relevant data are within the manuscript and its Supporting Information files.

Funding: This work was financially supported by the ERC-Starting Grant ZooMWest – Zooarchaeology and Mobility in the Western Mediterranean: Husbandry production from the Late Bronze Age to the Late Antiquity (award number 716298), funded by the European Research Council Agency (ERCEA) under the direction of SVL. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

A reduction in body size is widely recognised consequence of animal domestication [1–3]. Although the initial timing of morphological changes and of the selective aims that led to their emergence are still matters of debate [4, 5], this decrease in the livestock size proved to be a persistent and progressive trend. Across Western Europe, domestic animals, and particularly cattle, continued to decrease in size between the Neolithic and Iron Age [6–13]. Various explanations for this phenomenon have been put forward, including preference for smaller more manageable animals [14], and intensification in herding strategies through sub-adult breeding [15]. Regardless of the origin of this size decrease, the Roman Empire had a significant impact on its trajectory.

Roman conquest brought about an end to the Iron Age and significant changes to the social and economic organisation of Western Europe [16–18], including to animal farming strategies [12]. New methods of production are evident in changes to the species exploited and–breaking with millennia of progressive size diminution–a significant increase in the size of livestock. Although changes were not uniform [19] and exceptions occur [20–21], an increase in animal size is visible across conquered territories: France [22–24], Belgium [25], the Netherlands [26], Germany [27, 28], Switzerland [29–31], Britain [32], and Spain [12, 33]. This transformation of livestock husbandry is thought to result from the introduction of different forms of animal production [21, 34].

Uniquely in Western Europe, significant increases in animal size and changes to livestock frequencies pre-date the Roman conquest of northern and central Italy by centuries [7, 35, 36]. High percentages of pig remains and growth in animal body size are apparent in Etruscan cities as well as Rome and its environs during the first millennium BC [35, 37–39]. These trends continued to intensify during the Imperial period [40], by which point they had become a hallmark of ‘Romanisation’ in other parts of the Empire [19]. Within north/central Italy, these characteristic developments are linked to the rise of urban Etruscan and Roman culture, as marginal areas of Italy do not consistently demonstrate similar changes [20, 35, 41]. Urbanism is argued to be a primary force in catalysing changes to species frequencies, due to the functional challenges of provisioning cities with protein [37, 42, 43] and the socio-economic benefits of producing surplus animals [35]. Thus, the ‘Roman’ high-pig pattern became established during a period of increasing urbanisation during the first millennium BC, but do changes in animal size have the same origin?

Compared to species representation, the evolution of animal size in late prehistoric Italy is less understood. Because livestock varied significantly in stature across the Italian peninsula [7, 41, 42, 44, 45], analyses must be conducted on a sub-regional scale in order to establish useful patterns; a larger frame of analysis will convolute diachronic trends because the regional distribution of sites is not constant through time. A few late Bronze/early Iron Age sites have produced livestock with withers’ heights taller than those recorded in for earlier phases [45], but without detailed understanding of regional patterns of size evolution, the significance of these examples remains unclear: do they represent the origin of an accelerating trend towards larger animals that culminates in the Roman period? Or do they only appear large because comparative data are drawn from a different geographic area with smaller animals? In order to establish the origin and potential catalysts for animal size change, higher-resolution understanding of its development is needed.

Aims

This paper examines frequencies of domestic animals and development of livestock size within northern Italy in order to better understand the evolution of animal husbandry strategies and the socio-economic and ecological factors that impacted it. Northern Italy provides an ideal setting to pursue this line of inquiry. The region demonstrates significant and well documented changes in husbandry regimes across later prehistory [45–50], including the emergence of the recognised ‘urban Etruscan/Roman’ trend for larger animals and abundant pigs [7, 35, 51, 52]. These developments took place in an interconnected and climatically comparable geographic context. The Po Valley, Italy’s largest alluvial basin, joins the adjacent Venetian–Friulian Plain to form a unified landscape across most of the region. Within this area, local conditions would have varied dependant on land use, forest/vegetation cover, and fluvial networks, but the territory is subject to a similar climate (Köppen–Geiger climate zone Cfa), albeit with slightly cooler temperatures and greater precipitation on the higher edges of the valley (Cfb) [53]. Limiting the study area to a well-connected region with comparable climatic constraints allows for better assessment of the role of socio-economic and cultural factors in shaping husbandry strategies.

Within this region, we compare five study areas (Fig 1) with distinct archaeological trajectories. In anticipation of subsequent research on the Roman transition, here we focus on later prehistory, specifically the Middle Bronze Age to late Iron Age, c. 1650–150 BC [54–57]. While the process was not linear or continuous [56], this time frame encompasses a period of increasing social complexity and regionalisation, and the transition from diffuse villages to cities in the southern and eastern Po Valley [54, 57]. Of particular significance to this study is the development of urban Etruscan culture in the South study area [58].

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Fig 1. Map of sites and study regions.

See S1 Table for details. Terrain data available from the U.S. Geological Survey.

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We aim to address three questions: How does livestock representation change through time? When/where do larger animals emerge? And how do changes in species representation relate to developments in animal size? These analyses will provide new data on the geographic distribution of husbandry regimes and on the nature of diachronic change (e.g. rapid/progressive). This evidence allows us to establish whether Etruscan/Roman animal-exploitation patterns (abundant pigs, large animals) are indeed unique to these cultures, and to what extent urban settlement structures were perquisite for improvements in livestock. In light of current evidence for animal management regimes particular to urban Etruscan and Roman culture [7, 35, 39, 51, 52], we hypothesise that changes in species representation and growth in animal size reflect a new agricultural strategy related to urban settlement networks, and anticipate greater continuity in other, non-urban parts of the study area.

Archaeological context

Broadly considered, later prehistory saw demographic growth alongside population consolidation, social hierarchisation, and an intensification of production/trade, although these phenomena were neither linear nor homogenous.

The Early Bronze Age (c. 2300–1700 BC) of the Po Valley was characterised by pile-dwelling ‘palafitte’ villages, which represented part of a larger phenomenon of lake-side settlement in Switzerland and Central-Eastern Europe more generally [59]. During the Middle Bronze Age (c. 1700–1350 BC) the number of palafitte villages near lake basins declined, while a new form of settlement–terramare–spread along fluvial courses of the Po Valley [56, 59, 60]. Terramare villages used structural elements similar to palafitte, but were enclosed by moat and earthen rampart that functioned as part of the site’s irrigation network, as well as serving a defensive function [61]. Generally 1–2 ha in size, terramare displayed a high degree of internal organisation. Their dense distribution and use of complex irrigation and water management systems points significant population growth [56] and an intense exploitation of the territory [62, 63]. Significant tracks of the region’s forests were cleared, especially in the southern Po Plain, to supply building material and create space for agriculture and grazing [63–69]. Friuli also developed a more complex settlement pattern, but comparable with Istria, with fortified castellieri sites on hills [70].

Agriculture was based on cultivation of cereals and, to a lesser extent, legumes [63, 71, 72]. Millets were introduced as cultivars [73, 74]. This diversification of crops allowed the possibility of more than one annual harvest. Ploughs were used to prepare soil for planting, and material evidence for wooden ploughs in northern Italy dates back to Early Bronze Age [75]. Crop rotation, manuring, and fallowing were probably used to maintain or improve field productivity [76, 77]. The organisation of fields is difficult to reconstruct, but archaeobotanical evidence suggests a division of land between garden plots and extensive fields for cereals [77]; a similar land-use strategy has been proposed for Bronze Age agriculture in Switzerland [78, 79]. The diffusion of metal agricultural tools improved farming practices [75, 80], and the expansion of metallurgy may also have encouraged seasonal exploitation of upland pastures near metal sources [81]. Animals kept within settlements during cold months were foddered with twigs, grasses, and herbs [82].

The Recent Bronze Age (c. 1350–1150 BC) saw further changes in settlement patterns. Some sites were abandoned, while others increase in size; certain terramare villages reached an area of 15–20 ha [56, 59]. The development of organised settlements on this scale, alongside greater specialisation in metal production, and the distribution of status items in necropoli suggest more hierarchic forms of social organisation than visible in previous centuries [83, 84]. At the end of the Recent Bronze Age terramare-palafitte culture collapsed. Settlements were abandoned, leading to an almost complete depopulation of part of the southern Po Plain [56]. Aridification of environments already subject to deforestation and intensive cultivation appear to have had a significant role [62, 63, 85]; movement towards a more hierarchal society also may have caused a social crisis, exacerbated by environmental degradation [56]. While a large part of the southern plain was depopulated, the lowlands southeast of Verona and northern hills display greater settlement continuity [86, 87], and during the subsequent Final Bronze Age this area developed into the economic fulcrum of Po Valley. Settlement density in the Friulian lowlands increased before sharply falling [88].

The Final Bronze Age (c. 1150–950 BC) saw population consolidation along rivers and communication routes. Settlements developed into the first large clusters with proto-urban characteristics, the most important of which was Frattesina [89], which demonstrated a high level of complexity in craft production with the import of raw materials from as far as Egypt and the Baltic [90]. Shared forms of material culture and funerary practice (cremation) associated with proto-Villanovian culture spread across the peninsula. From the eighth century BC, Iron Age material culture developed a strong regional character. Distinct archaeological cultures evolved in areas that would later coincide with those occupied by historical populations: Etruscans, Venetians, Rhaetians, etc. [57, 89]. Population centres in the southern Po Plain, and later Veneto, grew larger and become more organised, with streets, rectilinear plans, and public buildings [58, 91]. Social stratification and the emergence an aristocracy visible is in the funerary record [57, 92]. Exchange relationships within the Po Plain intensified, as did trade with Europe, central Italy, and the Greek world, mediated by the region’s Etruscan cities [93].

Archaeobotanical remains from across northern Italy suggest a degree of continuity in crop choice between the Bronze and Iron Ages, with a potential increase in the importance of legumes [94]. The greater diffusions of iron, especially from the sixth century BC, expanded the use of metal ploughs and agricultural tools, and the potential to work heavier soils [95]. It has recently been proposed that surplus cereal production in the Iron Age Germany was achieved through manuring and an expansion in cultivation [96]. However, the applicability of this conclusion to an Italian lowland context is unclear. Pollen spectra do not indicate significant clearing during the Iron Age, e.g. [68], although the diffusion of iron tools and ploughs may have allowed cultivation of heavier soils that were already more or less free of trees. By the mid first millennium BC vine cultivation had become well established [97, 98], and in Etruscan territory it was sufficiently organised to produce a surplus for export [99–101]. This scale of production suggests established land-holding and long-term strategies in land use.

Urban centres continued to develop in the Veneto into the latter half of the millennium, but Etruscan influence decreased as a result of Roman expansion in the south and migrations from the north. Material evidence for La Tène culture in northern Italy expanded from the sixth century BC, and came to dominate large parts of the region by the fourth century BC [102, 103]. Although described by Roman authors as a violent invasion, the archaeological evidence presents a more complex picture of acculturation following the migration of ‘Celtic’ populations into northern Italy [104]. Etruscan cities that once flourished were abandoned in the third century BC, and the Roman Republic advanced into the region and gained control over the area between the third and second centuries BC [55, 105].

Materials and methods

Sites and assemblages

Late prehistoric sites from a large portion of the eastern Po Valley and Venetian Plain were chosen for this study (S1 Table). The study area was limited to these recent valleys and their borders, in order to compare sites subject to similar climatic conditions. In order to focus on the economic use of animals, only assemblages from domestic settlement contexts were considered in analysis of taxon presence/abundance: sanctuaries, cult sites, and ritual deposits were excluded. Ritual assemblages often have a different distribution of taxa from those found in domestic contexts, e.g. a pronounced focus on a single species [35] (e.g. [106, 107]), which could bias results. Sites are divided into regional groups based on their location within the study area and regional similarities in material culture. Faunal samples with very long chronologies that could not be assigned to a useful temporal range were excluded. Only dated contexts were analysed; surface finds and materials recovered from plowzone were not considered. Despite efforts for good regional and temporal coverage, faunal assemblages are not evenly distributed across the study areas and time periods. The assemblages also vary greatly in size, from a few dozen to tens-of-thousands of bones. Information on some periods is entirely lacking, while others are represented only by a single site. This large range results from differences in site type, degree of preservation, ancient settlement patterns, and historical interests. Modern development obscures Iron Age sites in particular, as many major settlements of this period are buried under modern–as well as medieval and Roman–cities. Although dividing the study area into smaller sub-regions limited the size of comparative samples, such division was necessary for investigating differences within the Po Basin. Illustrations and tables have been organised to clearly demonstrate where gaps are present.

Quantifying taxonomic abundance and animal size

The relative proportions of cattle (Bos taurus), sheep/goat (Ovis aries/Capra hircus), and pigs (Sus scrofa) were quantified using the number of identified specimens (NISP). Although subject to several systematic biases, NISP offers a widely employed and easy to calculate method of assessing the relative frequency of different species [108]. Inter-observer differences in identification and recording are a primary concern [109–111], as they artificially inflate the importance of taxa with a greater number of ‘identifiable’ remains. In order to better control of differences in recording practice and identification skill, rib, and vertebrate fragments were excluded from NISP counts where possible, as were any specimens not identified as a specific skeletal element. Complete and partial skeletons were also excluded from these analyses, since their inclusion would inflate NISP counts. In order to apply statistical tests with a reasonable degree of confidence, only assemblages with a minimum of 110 specimens identified to the three main domesticates were considered in NISP analyses. The statistical significance of inter-regional differences was tested using a chi-squared test in R software [112].

Changes in animal size were assessed using size-index scaled Log Standard Index values (LSI) [113]. Widely available standards were used for cattle [114], sheep and goats [115], and pigs [116]. Log ratios offer a useful method for investigating animal size, because they allow measurements from different elements to be pooled into a larger sample of indices for each dimension (length and breadth). However, this method of grouping can lead to the overrepresentation of specimens that yield several measurements, a problem that is quickly compounded if a skeleton or articulating limb is included. To avoid over representation of articulating remains, our LSI analyses included only one measurement per specimen and one specimen from an articulating group of bones. Bone widths were considered separately from lengths in order to assess two-dimensional change. Measurements of bone depth were comparatively rare and were not included.

Table 1 presents the measurements used in LSI analyses in preferential order. Only one length or breadth measurement per specimen was considered, e.g. if GLl was available for a specimen, all subsequent length measurements would be excluded. This list purposefully excludes elements and measurements particularly sensitive to animal age, although it is also constrained by measurements included in the published standards. LSI values for cattle, sheep, and pigs are presented in histograms. Because accurate species distinction can be challenging for closely related taxa like sheep and goats [117], related species are also included: figures for sheep also display counts and means for goats and undistinguished sheep/goat specimens; figures for pigs also contain data identified as wild boar. Undistinguished Sus sp. were grouped with domestic pigs. The Mann-Whitney U Test, conducted in R, was used to identify statistically significant differences between populations. Only LSI values from cattle, sheep, and pig were subject to statistical analysis; goats were excluded due to a lack of reliable biometric information.

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Table 1. Measurements used in calculation of LSI values for each taxon.

https://doi.org/10.1371/journal.pone.0208109.t001

Metacarpal measurements were used to investigate diachronic changes in sex ratios for cattle and sheep. The balance of males, females, and castrates within a population can influence observed variation in animal biometry, especially if the sexual composition of the group changed over time. Metacarpals are the most sexually dimorphic element in domestic bovids [119–121], and consideration of metacarpal size and shape can provide information on sex representation [122, 123]. To aid interpretation, measurements were compared to data from animals of known sex: archaeological cattle from Eketorp ringfort [123], identified using DNA, and modern Shetland sheep [115, 124].

Results: Relative abundance of livestock

Regional patterns

Analysis of NISP data for taxon abundance and livestock ratios (Table 2) demonstrated that livestock representation varied significantly between regions (Fig 2). Inter-regional comparisons within each chronological period were statistically significant in nearly all instances, and these differences persisted through time (S2 Table). Amongst sites of the North group, pigs were relatively rare compared to cattle and sheep/goat. The proportions of livestock were more balanced between the three taxa in the Veneto, with the exception of FBA and IA0. Caprines and pigs were very abundant in the South study area, while cattle were less common. Livestock ratios from the Friuli and Romagna regions were more variable, which may reflect either a more heterogeneous approach to husbandry practices or variation resulting from the lower number of sites from these areas.

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Fig 2. Relative percentages of principal domestic livestock.

See Table 2 for sample size. Stars indicate significance of change from previous period according to Chi square tests: p ≤ 0.05*, p ≤ 0.01**, p ≤ 0.001*** (S2 Table).

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Table 2. NISP and relative percentages of principal livestock by study area.

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Diachronic change

Study regions both north and south of the River Po displayed major diachronic changes in livestock representation, but each area followed a distinct trajectory. Within individual regions, diachronic change was statistically significant for most temporal transitions (indicated in Fig 2; S2 Table). Patterns of animal exploitation evolved in all areas, but the direction and timing of these changes differed. South of the Po River, a shift in livestock percentages is apparent in the Iron Age. Its origin is obscured by a lack of data for FBA and IA0, but significant changes to livestock ratios occurred in both the South and Romagna regions by IA1. Pigs replaced sheep/goat as the most abundant taxon in the South group; caprines also decreased in the Romagna area, but there cattle rose in importance. North of the Po River, changes to NISP percentages occurred during RBA, earlier than in the southern plain. As in the other regions, the relative abundance of sheep/goat decreased, with cattle replacing them as the dominant taxon. This emphasis on cattle exploitation continued in subsequent periods, albeit to a lesser extent during RFBA–variation that could result from the small sample size. `

Unlike regions with a single change in species distribution, Friuli and the Veneto presented several fluctuations in NISP percentages. After an emphasis on sheep/goat husbandry in MBA and RBA, NISP data from the Veneto varied across the remainder of the Bronze Age and the Iron Age. For certain periods few sites were available. This factor probably contributes to the observed variation: during FBA and IA0, the Veneto is represented by a single site. This settlement, Frattesina, was a unique proto-urban centre with far-reaching trade networks [90]. Its NISP profile, with a large percentage of pigs, more closely resembles the Etruscan/Roman pattern than that of the Bronze Age sites considered here. Of all the regions, NISP patterns in Friuli are the most variable, potentially as a result of a low number of available assemblages.

Results: Biometry

Analysis of livestock biometry utilised 4886 unique post-cranial measurements. Table 3 presents summary statistics of LSI values by region and period. As stated above, the statistical significance of temporal and inter-regional differences were analysed using the Mann-Whitney U tests (S3 Table). The significance of diachronic changes is indicated in the relevant histograms; full results are available in S3 Table.

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Table 3. Sample size, mean, and standard deviation of LSI values per area and time period.

https://doi.org/10.1371/journal.pone.0208109.t003

Cattle

Diachronic change.

LSI values from cattle bone lengths (Fig 3) revealed statistically significant diachronic changes in the majority of study regions. Except in Friuli, for which there was too little data to draw conclusions, mean cattle lengths increased in all regions between the Bronze and Iron Ages. For the North and South study areas, the increase in bone lengths was most significant when BM-R and IA2 were compared; however, small increases in mean LSI values during BRF-IA0 and IA1 suggest that these changes were incremental. In the Veneto study region a significant increase in bone length occurred between BM-R and IA1. The Romagna region also displays a diachronic increase in average LSI lengths, although this change was not statistically significant (see S3 Table).

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Fig 3. Distribution of cattle bone length LSI values by study region and period.

Arrows indicate significant diachronic changes according to Mann-Whitney U tests (S3 Table).

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Cattle LSI width values (Fig 4) also increased in size, although the timing of these changes did not consistently follow that of bone lengths. Width values from Friuli were extremely small in BM-R, but only three measurements were available. The Mann-Whitney U test demonstrated a significant size increase in BRF-IA0, but conclusions should be treated tentatively on account of the small BM-R sample size. Bone widths from the Romagna region increased between the BM-R and IA1; this increase was significant for widths but not for lengths. In the North study area, width LSI values behaved in a similar fashion to lengths: there was an incremental increase in the mean between BM-R and BRF-IA0, although this increase was only statistically significant when BM-R and IA2 were compared. Unlike other regions where lengths and width values grew in tandem, the two dimensions changed independently in the Veneto and South study areas. In the Veneto, a statistically significant increase in cattle widths is visible in the BRF-IA0, earlier than the change in cattle length values during IA1. Southern widths demonstrate a significant in increase in IA1, while cattle lengths in the region were relatively stable until IA2. In these two regions, an increase in bone width without comparable alteration in length would have produced a change in the shape of cattle, creating animals which were more robust, followed in the subsequent period by the emergence of taller and relatively more slender cattle.

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Fig 4. Distribution of cattle bone width LSI values by study region and period.

Arrows indicate significant diachronic changes according to Mann-Whitney U tests (S3 Table).

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Intra-period differences.

LSI results demonstrated significant regional variation in the size of cattle, even within a single period. The data suggest that cattle in the Veneto were some of the smallest in northern Italy (in terms of animal dimensions), although data from Friuli were lacking: lengths from the Veneto were smaller on average than those from other areas during BM-R, although this difference was only statistically significant when compared to the North study area (p = 0.042*, see S3 Table). The mean of LSI widths from the Veneto was also lower than that of other BM-R regions, except for the 3 specimens from BM-R Friuli. Again, these differences were not statistically significant in all cases. Interestingly, after some sparse evidence for small animals during BM-R, Friuli produced data for large cattle during BRF-IA0. Lengths from the region during BRF-IA0 were significantly larger than any BM-R study area (p = 0.003**–0.000***) as well as other areas during BRF-IA0. Cattle LSI widths from Friuli are also significantly larger than those from other regions during the BM-R (p = 0.000***) and BRF-IA0 Veneto (p = 0.000***).

During IA2, the South study area contained the largest cattle, both in terms of individual measurements as well as for mean size. The Mann-Whitney U test demonstrated significant differences between Southern bone lengths (p = 0.010*) and widths (p = 0.000***) and those from Northern cattle in IA2. They also had greater LSI width values than Venetian cattle, at least during IA1. Interestingly, the samples from IA2 Southern cattle were not statistically different from BRF-IA0 cattle from Friuli, the largest animals of the Bronze Age.

Sex ratios.

Evaluation of the sex ratios within the study regions was difficult due to limited data. Consideration of cattle metacarpal shape (Fig 5A) did not produce a clear pattern of sexual dimorphism during the Bronze Age (e.g. North, Friuli); however, the large range of values–comparable with Eketorp ringfort [123]–suggests a mixed population comprised of males, females, and castrates. Subsequently, the appearance of very robust cattle in IA2 was accompanied by disappearance of the most slender individuals, alongside a clearer separation of slender and robust shape groups, indicating that both male and female cattle become more robust. Fig 5B suggests that some of the very tall IA2 cattle, particularly in the South, may have been castrates, on account of their long length and slender shape. Because the points lie on the established regression line, an internal change in sex ratios is more plausible than the introduction of another breed or type [122]. Overall, while changes to sex ratios may have impacted the observed size change, metacarpal data indicate an increase in height and robustness in both sexes, and thus general change in population size, potentially influenced by–but not only the result of–changes in sex composition.

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Fig 5.

Cattle metacarpal (a) shape, using slenderness indices (shaft width/length versus distal width/length), and (b) slenderness (shaft width/length) versus length. Comparative data from Telldahl et al. [123].

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