Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-25T06:05:44.045Z Has data issue: false hasContentIssue false

Evolution of the sheep coat: the impact of domestication on its structure and development

Published online by Cambridge University Press:  10 June 2020

Neville Jackson
Affiliation:
CSIRO Division of Animal Production, Prospect, NSW2148, Australia
Ian G. Maddocks
Affiliation:
CSIRO Division of Animal Production, Prospect, NSW2148, Australia
James E. Watts
Affiliation:
PO Box 2604, Bowral, NSW2576, Australia
David Scobie
Affiliation:
AgResearch, Lincoln Research Centre, Private Bag 4749, Christchurch8140, New Zealand
Rebecca S. Mason
Affiliation:
Discipline of Physiology, School of Medical Sciences, Faculty of Medicine and Health, University of Sydney, Sydney, NSW2006, Australia
Clare Gordon-Thomson
Affiliation:
Discipline of Physiology, School of Medical Sciences, Faculty of Medicine and Health, University of Sydney, Sydney, NSW2006, Australia
Sally Stockwell
Affiliation:
CSIRO Agriculture and Food, Brisbane, Queensland4067, Australia
Geoffrey P.M. Moore*
Affiliation:
Discipline of Physiology, School of Medical Sciences, Faculty of Medicine and Health, University of Sydney, Sydney, NSW2006, Australia
*
Author for correspondence: Geoffrey Philip Moore, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Wild sheep and many primitive domesticated breeds have two coats: coarse hairs covering shorter, finer fibres. Both are shed annually. Exploitation of wool for apparel in the Bronze Age encouraged breeding for denser fleeces and continuously growing white fibres. The Merino is regarded as the culmination of this process. Archaeological discoveries, ancient images and parchment records portray this as an evolutionary progression, spanning millennia. However, examination of the fleeces from feral, two-coated and woolled sheep has revealed a ready facility of the follicle population to change from shedding to continuous growth and to revert from domesticated to primitive states. Modifications to coat structure, colour and composition have occurred in timeframes and to sheep population sizes that exclude the likelihood of variations arising from mutations and natural selection. The features are characteristic of the domestication phenotype: an assemblage of developmental, physiological, skeletal and hormonal modifications common to a wide variety of species under human control. The phenotypic similarities appeared to result from an accumulation of cryptic genetic changes early during vertebrate evolution. Because they did not affect fitness in the wild, the mutations were protected from adverse selection, becoming apparent only after exposure to a domestic environment. The neural crest, a transient embryonic cell population unique to vertebrates, has been implicated in the manifestations of the domesticated phenotype. This hypothesis is discussed with reference to the development of the wool follicle population and the particular roles of Notch pathway genes, culminating in the specific cell interactions that typify follicle initiation.

Type
Perspective
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 (http://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) 2020. Published by Cambridge University Press

1. Background

Sheep and goats, of the subfamily Caprinae, are amongst the earliest bovids to have been domesticated. Derived from wild species, they inhabited the Fertile Crescent 10,000–12,000 years ago. This region encompassed parts of south-eastern Anatolia, Mesopotamia and western Iran (Reed, Reference Reed and Mason1984; Zeder, Reference Zeder2008). Mitochondrial DNA profiles reveal a number of domestication events (Pedrosa et al., Reference Pedrosa, Uzun, Arranz, Gutiérrez-Gil, Primitivo and Bayón2005; Pereira et al., Reference Pereira, Davis and Luísa Pereira2006; Tapio et al., Reference Tapio, Marzanov and Ozerov2006). Evidence from prehistoric habitation sites (Zeder, Reference Zeder2008) and genetic signatures (Kijas et al., Reference Kijas, Lenstra and Hayes2012; Fariello et al., Reference Fariello, Servin and Tosser-Klopp2014) indicates early management and selection strategies, including culling, polling and castration. Although originally from elevated and mountainous terrain, domesticated caprines adapted to a variety of new environments. By tracking retroviral sequences in the ovine genome, Chessa et al. (Reference Chessa, Pereira and Arnaud2009) mapped the movements of people and livestock – the so-called ‘Neolithic package’ – to the Far East and westwards to Europe and Africa. The integrations and their predicted mutation rates indicate that present-day European Mouflon, Soay and other North Atlantic island sheep are relics of those early migrations.

Initially sourced for food, archaeological discoveries, contemporary images, parchment inclusions (Ryder & Stephenson, Reference Ryder and Stephenson1968) and other research (Ryder, Reference Ryder1958, Reference Ryder1986; Fraser & Short, Reference Fraser and Short1960; Carter, Reference Carter1968) indicate that harvesting of coat fibres began some millennia later. Early fleeces were pigmented, with coarse overhairs, similar to those of their wild counterparts. Wool was found in textiles from the early Bronze Age and white wool in the Iron Age (Ryder, Reference Ryder and Mason1984; Sherratt, Reference Sherratt, Hodder, Isaac and Hammond1984). Fine fibres were identified in parchment made from sheepskin in the Middle East, early in the Modern Era (Ryder, Reference Ryder1958, Reference Ryder and Mason1984). Fine wool became a valuable commodity and a symbol of prestige. The pallium, made with white wool, was an exclusive papal vestment in the fourth century (Davis, Reference Davis1958).

The appearance of domesticated sheep in the Iberian Peninsula has been dated at 5000–7000 BCE (Zeder, Reference Zeder2008; Ciani et al., Reference Ciani, Lasagna and D'Andrea2015). Fine-woolled Apulian sheep were introduced during the Roman occupation in the first millennium, and two-coated sheep were introduced from North Africa. Evidence of fine-woolled sheep of Spanish origin emerged around the thirteenth century. The Merino was possibly the first recognized breed in the late Middle Ages, spreading through Europe, Asia and Australia during the eighteenth and nineteenth centuries (Carter & Clarke, Reference Carter and Clarke1957b; Ryder, Reference Ryder1964; Ciani et al., Reference Ciani, Lasagna and D'Andrea2015). Table 1 summarizes changes in fleece traits following domestication (Carter, Reference Carter1955; Ryder, Reference Ryder1958, Reference Ryder1960, Reference Ryder1964, Reference Ryder1966, Reference Ryder1986; Ryder & Stephenson, Reference Ryder and Stephenson1968; Sherratt, Reference Sherratt, Hodder, Isaac and Hammond1984).

Table 1. Approximate phases for the appearance of changes in sheep types and fleece and fibre traits from wild sheep to the Merino.

2. Follicle and fibre types

The hair coats of wild and many domesticated caprines are similar in appearance and structure (Ryder, Reference Ryder1958). Commonly pigmented brown or black, they are composed of a layer of long, coarse, medullated primary (P) fibres of variable diameters. These cover an undercoat of shorter, finer, unmedullated secondary (S) fibres. Coarse fibres are three to five times the diameter of fine fibres, with densities between 3 and 5/mm2, secondary/primary (S/P) follicle ratios of 3–4 (Carter, Reference Carter1968) and fleece weights of about 1 kg. There are annual cycles of growth and shedding (Carter, Reference Carter1955; Ryder & Stephenson, Reference Ryder and Stephenson1968). Here, for convenience, these traits will be referred to as ‘primitive’.

A micrograph of a skin section from a two-coated Barbary sheep (Ryder, Reference Ryder1958; Mason, Reference Mason1967) is depicted in Fig. 1a, showing a trio group of coarse P fibres adjacent to clusters of fine S fibres. The fibre diameter distributions are plotted in the histogram of Fig. 1b.

Fig. 1. Transverse skin section and fibre diameter distribution of Barbary sheep. (a) Primary (P) follicles in a trio group; fibres are large, medullated and of variable diameters (P Ø: 32, 53 and 26 μm, respectively). Secondary (S) follicles are in wedge-shaped clusters, adjacent to P follicles and have finer, shorter fibres (S Ø: 9 μm). Bar = 100 μm. (b) Histogram of the distribution of P and S fibre diameters (Dp, Ds) in the skin sample. P fibre frequencies are shaded.

By contrast, modern (hereafter: ‘woolled’) sheep, used for the manufacture of textiles, have fleeces composed of predominantly white, unmedullated P and S fibres, S/P ratios of 5–20 and wool weights of 3–5 kg (Carter & Clarke, Reference Carter and Clarke1957a; Carter, Reference Carter1968). Wool growth is continuous and fibre diameters are more uniform, with P/S fibre diameter (Dp/Ds) ratios ranging from 1.0 to 1.3 (Carter, Reference Carter1968). Figure 2a depicts a transverse skin section from a fine Merino, with Fig. 2b showing a histogram of the fibre diameters. The P and S distributions are superimposed.

Fig. 2. Transverse skin section and fibre diameter distribution of a modern Merino sheep. (a) Primary (P) follicles in a trio group; P fibres are fine, not medullated and have similar diameters (Ø: 20 μm). Secondary (S) follicles are numerous and are also of uniform diameter (Ø: 22 μm). Bar = 100 μm. (b) Histogram of the distribution of P and S fibre diameters (Dp, Ds) in the skin sample. P fibre frequencies are shaded.

Comparisons between woolled and primitive breeds show the extent of the differences in P and S fibre diameters and follicle densities (Figs 3a & 3b). Data from Merino sheep fall into clusters, separated from both primitive sheep and other modern English breeds.

Fig. 3. Comparisons of (a) primary and secondary fibre diameters and (b) primary and secondary follicle densities in a range of modern breeds; the primitive Soay sheep is designated ℗. Data from Carter (Reference Carter1968). Corriedales (Merino × Longwool) display intermediate characteristics. A primary to secondary fibre diameter ratio of 1 is shown as a diagonal line in (a).

Carter (Reference Carter, Lyne and Short1965) commented that secondary follicle density in the Merino could be an order of magnitude greater and fleece weights three to five times those of other modern breeds.

3. Evolution of the coat

The prevailing view of the evolution of modern sheep is from an archaeological perspective (Ryder, Reference Ryder1964), with a millennial timescale (Table 1). It was postulated that conversion from a hairy two-coated animal with an annual moult to one with continuously growing fibres occurred via an intermediate stage, typified by the ‘woolly Soay’ of the Outer Hebrides. Coarse hairs were gradually replaced with finer, continuously growing fibres and fibre diameters transitioned from a skewed, fine-to-coarse profile to a normal distribution, as illustrated in Fig. 2b. Earlier, Fraser (Reference Fraser1953) proposed an evolutionary path with no intermediate stages, but this was highly speculative, involving a ‘fibre substrate’. Despite this, the direct path has received support from recent genotype analyses. Employing models that measured gene flow between sheep breeds, Ciani et al. (Reference Ciani, Lasagna and D'Andrea2015) showed the highest values amongst early Merino and wild/feral sheep. Indeed, the studies suggest not only that differences between primitive and woolled animals were small, but that changes from one to the other were achieved, or were achievable, rapidly. The implications of these observations are that the Merino fleece may not be as remote from its two-coated origins as generally assumed.

To explore this, we have re-examined the nature of the fleece with the benefit of more recent insights into factors affecting the development of the follicle population and new perspectives on the consequences of domestication.

4. Development of the follicle population

The basic structure and composition of the coats and the development and distribution of the follicle populations are alike in primitive and woolled sheep. Follicles are initiated in overlapping waves and at similar times, during foetal life (Fraser, Reference Fraser1953; Marston, Reference Marston and Hammond1955). The P follicles are formed first, commonly arranged in trio groups. Densities average 3–5/mm2, and each is associated with a sweat gland and arrector muscle (Tänzer, Reference Tänzer1926; Carter, Reference Carter1968; Tuncer et al., Reference Tuncer, Uslu, Taş and Şireli2018). Later, S follicles develop, initially at non-randomly spaced sites in the skin: the secondary original follicles. Finally, secondary derived follicles arise by branching from other S follicles (Hardy & Lyne, Reference Hardy and Lyne1956). Derived follicles are highly variable in number and are primarily responsible for differences in follicle densities amongst breeds (Carter, Reference Carter1968; Moore et al., Reference Moore, Jackson, Isaacs and Brown1998). They are also widespread, having been reported both in woolled (Carter & Clarke, Reference Carter and Clarke1957a, Reference Carter and Clarke1957b; Orwin, Reference Orwin1961) and primitive sheep, including the Karakul (Tänzer, Reference Tänzer1926) and Soay (Ryder, Reference Ryder1959).

5. Fibre shedding

Two-coated sheep undergo annual cycles of growth and shedding. Ryder (Reference Ryder1960, Reference Ryder1966) described a spring moult in the Soay and European Mouflon and Slee (Reference Slee, Lyne and Short1965) in the Wiltshire Horn. Ryder (Reference Ryder1962) reported shedding in Merinos, but this was not confirmed (Lyne, Reference Lyne1961; Ryder, Reference Ryder1967). It is generally accepted that the fleece grows continuously and that moulting, if it occurs, is negligible. However, Merinos show annual rhythms of wool growth that coincide with those observed in shedding sheep (Bennett et al., Reference Bennett, Hutchinson and Wodzicka-Tomaszewska1962; Hutchinson, Reference Hutchinson, Lyne and Short1965). These are more pronounced in haired regions, perhaps echoing an archaic hair growth cycle.

A significant insight into a means by which continuous wool growth might have superseded shedding was reported by O'Connell et al. (Reference O'Connell, Scobie, Hickey, Sumner and Pearson2012). Selective breeding programmes to increase and decrease greasy fleece weights (up- and down-selection) in Wiltshire Horn sheep revealed an inverse correlation between fleece weight and the extent of shedding over the body. The transformation from two coats to continuous growth occurred progressively, encompassing 80% of the fleece after 8 years of selection.

6. Primitive traits in Merinos

Sheep with primitive traits appear sporadically but persistently in research and industry Merino flocks in Australia. These include, variously, individuals with coarse, occasionally medullated P fibres, high Dp/Ds ratios and low follicle densities. Although mostly anecdotal, there are some published reports. Cox (Reference Cox1936) described a Merino ram with “extraordinary wool growth, which is said to be similar to the original wild sheep, having a coating of short wool and hair.” Marston (Reference Marston and Hammond1955) noted that some Merino strains grew long, coarse fibres resembling those of the outer coats of primitive sheep. Similarly, a medium Merino flock with a mean S/P ratio of 22 and a follicle density of 64/mm2 included a ewe with an S/P ratio of 3–5 and a follicle density of 20/mm2 (Carter & Clarke, Reference Carter and Clarke1957a).

Coarse fibres have been found in individual animals from both stud and research flocks. Using Dp/Ds values as a comparative measure of fibre diameter distributions (Carter & Clarke, Reference Carter and Clarke1957a), ratios >1.5 were found in ewes in almost all strains and environments (Gallagher, Reference Gallagher1970; Gallagher & Yeates, Reference Gallagher and Yeates1970).

Further, an up- and down-selection programme to determine the effects of changes in follicle size and number on wool growth, which ran for 8 years (Jackson et al., Reference Jackson, Lax and Rendel1979), generated a number of animals with primitive characteristics. Figures 4a and 4b depict a skin section and fibre diameter distribution of a high selection line ewe at the end of the experiment. Large medullated P fibres were present and P and S diameter distributions were skewed into the coarse range.

Fig. 4. Transverse skin section and primary (P) and secondary (S) fibre diameter distribution of a ewe from the follicle size and number selection experiment. (a) The fibre of the P follicle (P at centre) is large and medullated (arrowhead); also shown is an adjacent P follicle with an unmedullated fibre. Bar = 100 μm. (b) Fibre diameter histogram from the same skin sample, showing P and S fibre diameter (Dp, Ds) distributions. Ds values range from coarse to fine. P frequencies are shaded.

7. Feral sheep

Although human-mediated selection has not focused primarily on environmental fitness, there are many instances of domesticates escaping to, and thriving, in ecosystems unlike those of their wild origins. Whilst the Soay and European Mouflon are probably the best known, their returns to the wild occurred before coat fibres had become commodified (Poplin, Reference Poplin1979). Feral Merino populations are, by contrast, more recent phenomena, having been reported on islands in Hawaii, California, the Solomons and New Zealand (Orwin & Whitaker, Reference Orwin and Whitaker1984; Sumner et al., Reference Sumner, Scobie, O'Connell and Henderson2017). The provenance of most flocks is not well documented. However, an isolated population on Arapawa Island, New Zealand, appear to have originated from Merino breeds (Orwin & Whitaker, Reference Orwin and Whitaker1984; Pickering et al., Reference Pickering, Young, Kijas, Scobie and McEwan2013; Ciani et al., Reference Ciani, Lasagna and D'Andrea2015). Reportedly sourced from Australia in the nineteenth century, animals were abandoned or escaped in the 1860s, eventually consolidating into a fairly stable population of small flocks. A detailed study in the 1980s found that many of the traits exhibited by the animals were those of primitive breeds. They were observed to lose their fleeces, beginning with belly and neck regions. Shedding was achieved by a combination of seasonal fibre thinning and physical abrasion, a behaviour observed in the Mouflon (Ryder, Reference Ryder1960). Coats were commonly pigmented and fleece weights were about half those of mid-nineteenth-century Merinos (Massy, Reference Massy2007). Mean fibre diameter (23.1 μm) was similar to that of a medium-woolled Merino, but diameter distributions were positively skewed, ranging from 9 to 109 μm. Some larger fibres were medullated. The skin had a follicle density of 26.9/mm2 and an S/P ratio of 6.0 (Orwin & Whitaker, Reference Orwin and Whitaker1984).

A transverse skin section and a histogram of fibre diameters from three Arapawa ewes sampled in 1993–1994 are shown in Figures 5a and 5b. The P and S fibre diameters fall into two distributions with means of 37 and 19 μm, respectively. They approximate those of the 1985 high selection line Merino of Fig. 4b.

Fig. 5. Transverse skin section and fibre diameter distribution of Arapawa Island sheep. (a) Trio group of primary (P) follicles. Secondary (S) follicles located are in wedge-shaped clusters between the P follicles. Bar = 100 μm. (b) Fibre diameter histogram from the same skin samples, showing P and S fibre distributions (Dp, Ds). P fibre frequencies are shaded.

Comparisons between modern Merino P and S diameters and densities and those of primitive (Soay) and Arapawa sheep are depicted in Figs 6a and 6b.

Fig. 6. Comparisons between (a) primary and secondary fibre diameters and (b) primary and secondary follicle densities in modern Merino breeds (Carter, Reference Carter1968) and in Arapawa sheep. The Arapawa mean fibre diameters in (a) are from the data of Fig. 5b. The follicle density measurement in (b) is from Orwin & Whitaker (Reference Orwin and Whitaker1984); the Soay sheep ℗ and Merino values are from Carter (Reference Carter1968).

The transformations observed in this small, isolated sheep population occurred within approximately 30 generations, indicating that adaptation to the prevailing environment was not only rapid, but occurred in a sufficiently large proportion of the animals to ensure survival. The changes in fleece traits are consistent with the observations of Darwin (Reference Darwin1868), who noted the rapidity with which selective breeding could generate new types, the difference being that the changes in Arapawa sheep were a reversion, having occurred in the absence of human intervention. Given the small size of the population, the likelihood that the animals evolved as a consequence of random mutations coupled with natural selection is remote.

8. The domesticated phenotype

One aspect of the evolution of the fleece not previously addressed has been the effect of the domestication process itself, beginning at the capture of animals from the wild and introducing them to an environment created by humans. The pioneering work of the Soviet scientist Dmitry Belayev, using wild silver foxes, demonstrated that by selecting individuals for a single behavioural trait (tameness), an array of seemingly unrelated developmental, physiological, hormonal and skeletal modifications were induced (Belayev, Reference Belayev1969, Reference Belayev1979). In addition to a progressively increasing tolerance of human proximity, there were alterations to the shape and size of the skull and long bones, brain size was reduced and the breeding season was prolonged. Tameness in young foxes was correlated with reductions in corticotrophin-releasing hormone secretion, adrenal gland size and circulating cortisol levels (Trut et al., Reference Trut, Oskina and Kharlamova2009). Coat pigmentation altered, blazes and white areas developed and there were changes in hair length, texture and seasonal moulting. These appeared rapidly and more or less concurrently. More than half of the foxes in the experiment exhibited the traits after 50 years of selection.

Perhaps more remarkably, the effects of domestication were not confined to silver foxes. Similar arrays of physical and behavioural traits were reportedly induced in otherwise unrelated vertebrates (sheep, horses, dogs, etc.) in which the only common denominator was that of being brought under human control (Trut et al., Reference Trut, Oskina and Kharlamova2009; Wilkins et al., Reference Wilkins, Wrangham and Fitch2014). The term ‘domestication syndrome’ was abstracted by Wilkins et al. (Reference Wilkins, Wrangham and Fitch2014) to describe the suite of traits recurring in species in which evolutionary pathways did not cross but had nevertheless evolved in the same direction.

9. The neural crest

The genetic and developmental mechanisms underlying domestication have been widely canvassed. The observations suggested that mutations with equivalent effects were present in the same genes. The phenotypic similarities in such a range of species seemed likely to result from a gradual accumulation of cryptic genetic changes early during vertebrate evolution. The implications are that the mutations, because they did not affect fitness in the wild, were not exposed to adverse selection. Their frequencies were therefore inherited unchanged, becoming increasingly buffered against alterations as species diverged. Their accumulated effects only became apparent following exposure to a human environment.

Wilkins et al. (Reference Wilkins, Wrangham and Fitch2014) postulated the involvement of the neural crest (NC), a transient embryonic cell population unique to vertebrates and of considerable antiquity (Sauka-Spengler et al., Reference Sauka-Spengler, Meulemans, Jones and Bronner-Fraser2007). Differentiating early during embryogenesis, it gives rise to a population of multipotent, self-renewing NC cells (NCCs) with extensive developmental and regulatory functions. Following an epithelial to mesenchymal transition (Simoes-Costa & Bronner, Reference Simoes-Costa and Bronner2013), NCCs migrate extensively and contribute to the specification of many tissues that characterize the domesticated phenotype, differentiating into pigment cells, elements of the nervous system, musculature, connective tissue, cartilage, bone and skin (Le Douarin, Reference Le Douarin1968; Adameyko et al., Reference Adameyko, Lallemend and Aquino2009).

It was proposed that the domesticated phenotype developed as a consequence of deficits in proliferation or migratory capacities of the NCCs, resulting in lower densities at their final destinations (Wilkins et al., Reference Wilkins, Wrangham and Fitch2014). Whilst consistent with alterations in some physical features and perhaps pigmentation, changes in hair texture and increases in fibre growth and follicle density suggest an alternative explanation: that of redirecting NCCs to alternative developmental pathways (Kulesa et al., Reference Kulesa, Bronner-Fraser and Fraser2000). Clonal analysis has confirmed that single NCCs can not only differentiate into a variety of cell types, but also propagate cells with similar potential (Bronner-Fraser & Fraser, Reference Bronner-Fraser and Fraser1988). Thus, for example, whilst differentiating into pigment cells in skin (Le Douarin, Reference Le Douarin1968), melanoblasts may also generate sub-lineages with functions not involving melanin synthesis (Aoki et al., Reference Aoki, Yamada, Hara and Kunisada2009; Uehara et al., Reference Uehara, Izumi and Kubo2009).

10. Neural crest cells and follicle morphogenesis

We propose that, in the sheep, rather than failing to migrate, NCCs are redirected to fates that include an increased commitment to hair follicle morphogenesis. There is evidence to support this view. NCCs are found in epidermal and dermal compartments of the skin and hair follicles, together with NC-derived cells (Fernandes et al., Reference Fernandes, McKenzie and Mill2004) and those expressing NCC markers. The origins and fates of NCCs and NC-derived cells have been actively debated (Sieber-Blum et al., Reference Sieber-Blum, Grim, Hu and Szeder2004; Jinno et al., Reference Jinno, Morozova and Jones2010). However, attenuation of Wnt signalling using Cre/LoxP-knockout technology (Li et al., Reference Li, Rhéaume and Teng2007) and, more specifically, in NCCs (Narytnyk et al., Reference Narytnyk, Gillinder, Verdon, Clewes and Sieber-Blum2014) resulted in reductions in both hair follicle density and fibre diameter, implicating NCCs in that specific morphogenetic process.

Previously, we have shown that both follicle density and fibre diameter in the sheep are determined at follicle initiation (Moore et al., Reference Moore, Jackson and Lax1989, Reference Moore, Jackson, Isaacs and Brown1996). Each follicle and the dimensions of its fibre are specified by the numbers of mesenchymal cells that condense into a papilla at an initiation site (Moore et al., Reference Moore, Jackson, Isaacs and Brown1998). Prepapilla cells are derived from a lineage that differentiates in the mesenchyme at follicle initiation. They participate in the development of the whole follicle population (Moore et al., Reference Moore, Jackson, Isaacs and Brown1996, Reference Moore, Jackson, Isaacs and Brown1998). At initiation, the cells aggregate as a consequence of transient Notch signalling (Gordon-Thomson et al., Reference Gordon-Thomson, Botto, Cam and Moore2008) and intercellular Notch–Delta and Delta–Delta interactions (Xavier et al., Reference Xavier, Gordon-Thomson and Wynn2013). In association with an epidermal cell cluster, they constitute a follicle primordium at each initiation site. The reductions in follicle size and density that result from NCC inactivation (Narytnyk et al., Reference Narytnyk, Gillinder, Verdon, Clewes and Sieber-Blum2014) and the presence of NCCs in follicle papillae (Fernandes et al., Reference Fernandes, McKenzie and Mill2004; Sieber-Blum et al., Reference Sieber-Blum, Grim, Hu and Szeder2004) place NCCs in the papilla aggregates at follicle initiation.

11. Conclusions

Primitive sheep and the modern Merino are generally regarded as occupying either end of a range of fibre-producing breeds. However, examination of the nature of the fleece and its ready adaptability suggest that the differences are less striking than their similarities. The development and types of follicles initiated are essentially identical, and similar growth cycles are present, albeit to varying degrees. The rapidity and apparent facility with which a follicle population may convert from shedding to continuous growth and revert from domesticated to feral states argue that the apparent differences are simply stages in a spectrum of types, ranging from coarse fibres and two coats to fine and continuously growing. The random appearance of primitive traits in modern flocks then becomes a not unexpected occurrence. A labile process appears to be in play.

Domestication has emerged as a dynamic feature of the evolution of sheep breeds. Within this environment, modifications to the coat structure and composition have occurred in timeframes and to sheep population sizes that exclude evolutionary variations arising from random mutations and natural selection. The fact that these changes occur so consistently and, from available evidence, rapidly, points to an accumulation of a suite of genetic changes that only achieved phenotypic expression through exposure to an environment managed by humans. The involvement of NCCs in follicle morphogenesis is a working hypothesis that provides a single, coherent and essentially consistent rationale for the appearance of changes in coat structure, characteristics and composition associated with a domesticated phenotype.

Seemingly, the Merino has access to an extensive wardrobe. What it is wearing at any particular time is a consequence of two competing and unrelenting environmental forces: one natural, the other human.

Acknowledgements

The work was carried out at CSIRO Division of Animal Production, Prospect, NSW, and supported, in part, by the Bicentennial Research Fund, NSW Branch of the Australian Association of Stud Merino Breeders. We thank John Lax for discussions. Technical support was provided by M. Halcomb, R.M. Farrell, D.A. Swinton and C. Wilson. The software for the IBAS 2 System to perform the image analyses was developed between 1983 and 1986 by I.G. Maddocks, M. Halcomb and N. Jackson.

Author contributions

NJ, IGM, JEW and GPMM designed the study. Together with DS, CG-T and SS, they collected and analysed the samples and data. All authors contributed to the production of the manuscript.

Conflicts of interest

The authors declare no conflicts of interest.

Financial support

No funding was received to support this study.

Materials and methods

Skin preparation

Skin samples were harvested from the mid-side of each animal using a 10 mm Ø trephine, fixed and stained using standard histological procedures, but omitting haematoxylin staining (Maddocks & Jackson, Reference Maddocks and Jackson1988).

Automated measurement of follicle and fibre characters

Data pertaining to follicle and fibre characters were collected from skin samples by standard microscopic examination of histological material or automated imaging. For the latter procedure, sectioned material was examined on an image analysis system consisting of a Kontron IBAS 2 image-processing computer and a Zeiss Research microscope equipped with a high-resolution monochrome video camera and a Zeiss monochromator. The system scanned as many microscope fields as could be obtained from the specimen, moving in a pattern that avoided resampling of areas already measured. For each field, fibre images were segmented and P fibres identified.

P and S fibres were counted and measured separately (Carter, Reference Carter1943). Results were presented as P, S and total follicle counts/mm2 of skin, S/P, mean diameter, standard deviation and coefficient of variation for P, S and total fibre numbers, respectively. Data from each skin sample were prepared as a histogram of fibre diameters as frequencies in 32 × 2 μm classes.

References

Adameyko, I., Lallemend, F., Aquino, J.B. et al. (2009). Schwann cell precursors from nerve innervation are a cellular origin of melanocytes in skin. Cell 139, 366379.CrossRefGoogle ScholarPubMed
Aoki, H., Yamada, Y., Hara, A. and Kunisada, T. (2009). Two distinct types of mouse melanocyte: differential signalling requirement for the maintenance of non-cutaneous and dermal versus epidermal melanocytes. Development 136, 25112521.CrossRefGoogle Scholar
Belayev, D.K. (1969). Domestication of animals. Science Journal 5, 4752.Google Scholar
Belayev, D.K. (1979). Destabilising selection as a factor in domestication. Journal of Heredity 70, 301308.CrossRefGoogle Scholar
Bennett, J.W., Hutchinson, J.C.D. and Wodzicka-Tomaszewska, M. (1962). Annual rhythm of wool growth. Nature 194, 651652.CrossRefGoogle Scholar
Bronner-Fraser, M. and Fraser, S.E. (1988). Cell lineage analysis reveals multipotency of some avian neural crest cells. Nature 335, 161164.CrossRefGoogle ScholarPubMed
Carter, H.B. (1943). Studies in the biology of the skin and fleece of sheep. 1. The development and general histology of the follicle group in the skin of Merino sheep. Council for Scientific & Industrial Research Bulletin No. 164, 141.Google Scholar
Carter, H.B. (1955). The hair follicle group in sheep. Animal Breeding. Abstracts 23, 102.Google Scholar
Carter, H.B. (1965). Variation in the hair follicle population of mammalian skin. In: Biology of the Skin and Hair Growth, eds Lyne, A.G. and Short, B.F. (pp. 2533). Sydney, Australia: Angus and Robertson.Google Scholar
Carter, H.B. (1968). Comparative Fleece Analysis Data for Domestic Sheep. The Principal Fleece Staple Values of Some Recognized Breeds. Canberra, Australia: Agricultural Research Council.Google Scholar
Carter, H.B. and Clarke, W.H. (1957a). The hair follicle group and skin follicle population of Australian Merino sheep. Australian Journal of Agricultural Research 8, 91108.CrossRefGoogle Scholar
Carter, H.B. and Clarke, W.H. (1957b). The hair follicle group and follicle population of some non-Merino breeds of sheep. Australian Journal of Agricultural Research 8, 109119.CrossRefGoogle Scholar
Chessa, B., Pereira, F., Arnaud, F. et al. (2009). Revealing the history of sheep domestication using retrovirus integrations. Science 324, 3236.CrossRefGoogle ScholarPubMed
Ciani, E., Lasagna, E., D'Andrea, M., et al. and the International Sheep Genomics Consortium (2015). Merino and Merino-derived sheep breeds: a genome-wide intercontinental study. Genetics Selection Evolution 47, 111.CrossRefGoogle ScholarPubMed
Cox, E.W. (1936). The Evolution of the Australian Merino. Sydney, Australia: Angus and Robertson Ltd.Google Scholar
Darwin, C. (1868). The Variations in Animals and Plants under Domestication. Baltimore, MD, USA: Johns Hopkins University Press (1998 edition).Google Scholar
Davis, R.H.C. (1958). A History of Medieval Europe. London, UK: Longmans, Green & Co.Google Scholar
Fariello, M.-I., Servin, B., Tosser-Klopp, G. et al. and International Sheep Genomics Consortium (2014). Selection signatures in worldwide sheep populations. PLoS ONE 9, e103813.CrossRefGoogle ScholarPubMed
Fernandes, K.J.L., McKenzie, I.A., Mill, P. et al. (2004). A dermal niche for multipotent adult skin-derived precursor cells. Nature Cell Biology 6, 10821093.CrossRefGoogle ScholarPubMed
Fraser, A.S. (1953). Factors in the genetic determination of fleece structure in sheep. Journal of Genetics 51, 222236.CrossRefGoogle Scholar
Fraser, A.S. and Short, B.F. (1960). The Biology of the Fleece. Technical Paper No. 3. Melbourne, Australia: CSIRO Animal Research Labs.Google Scholar
Gallagher, J.R. (1970). An evaluation of Merino wool quality. II. An estimate of the incidence of coarse fibres in Australian Merino wool. Journal of Agricultural Science Cambridge 74, 99102.CrossRefGoogle Scholar
Gallagher, J.R. and Yeates, N.T.M. (1970). An evaluation of Merino wool quality. I. The incidence of coarse fibres in two Australian Merino flocks. Journal of Agricultural Science Cambridge 74, 9198.CrossRefGoogle Scholar
Gordon-Thomson, C., Botto, S.A., Cam, R.G. and Moore, G.P.M. (2008). Notch pathway gene expression and wool follicle cell fates. Australian Journal of Experimental Agriculture 48, 648656.CrossRefGoogle Scholar
Hardy, M.H. and Lyne, A.G. (1956). The pre-natal development of wool follicles in Merino sheep. Australian Journal of Biological Science 9, 341.CrossRefGoogle Scholar
Hutchinson, J.C.D. (1965). Photoperiodic control of the annual rhythm of wool growth. In: Biology of the Skin and Hair Growth, eds Lyne, A.G. and Short, B.F. (pp. 565573). Sydney, Australia: Angus & Robertson.Google Scholar
Jackson, N., Lax, J. and Rendel, J.M. (1979). Breeding of Sheep for Efficient Wool Production. Research Report. Sydney, Australia: CSIRO Division of Animal Production.Google Scholar
Jinno, H., Morozova, O., Jones, K.L. et al. (2010). Convergent genesis of an adult neural crest-like dermal stem cell from distinct developmental origins. Stem Cells 28, 20272040.CrossRefGoogle ScholarPubMed
Kijas, J.W., Lenstra, J.A., Hayes, B. et al. and The International Sheep Genomics Consortium (2012). Genome-wide analysis of the world's sheep breeds reveals high levels of historic mixture and strong recent selection. PLoS Biology 10, e1001258.CrossRefGoogle ScholarPubMed
Kulesa, P., Bronner-Fraser, M. and Fraser, S. (2000). In ovo time-lapse analysis after dorsal neural tube ablation shows rerouting of chick midbrain neural crest. Development 127, 28432852.Google Scholar
Le Douarin, N. (1968). The Neural Crest. Cambridge, UK: Cambridge University Press.Google Scholar
Li, B., Rhéaume, C., Teng, A. et al. (2007). Developmental phenotypes and reduced Wnt signaling in mice deficient for pygopus 2. Genesis 45, 318325.CrossRefGoogle ScholarPubMed
Lyne, A.G. (1961). The postnatal development of wool follicles, shedding and skin thickness in inbred Merino and Southdown Merino crossbred sheep. Australian Journal of Biological Sciences 14, 141156.CrossRefGoogle Scholar
Maddocks, I.G. and Jackson, N. (1988). Structural Studies of Sheep, Cattle and Goat Skin. Sydney, Australia: CSIRO Division of Animal Production.Google Scholar
Marston, H.R. (1955). Wool growth. In: Progress in the Physiology of Farm Animals, ed. Hammond, J. (pp. 543581). London, UK: Butterworths.Google Scholar
Mason, I.L. (1967). Sheep Breeds of the Mediterranean. Edinburgh, UK: Commonwealth Agricultural Bureau.Google Scholar
Massy, C. (2007). The Australian Merino: The Story of a Nation. Sydney, Australia: Random House.Google Scholar
Moore, G.P.M., Jackson, N. and Lax, J. (1989). Evidence of a unique developmental mechanism specifying follicle density and fibre size in sheep selected for single skin and fleece characters. Genetical Research Cambridge 53, 5762.CrossRefGoogle ScholarPubMed
Moore, G.P.M., Jackson, N., Isaacs, K. and Brown, G. (1996). Development and density of wool follicles in Merino sheep selected for single fibre characteristics. Australian Journal of Agricultural Research 47, 11951201.CrossRefGoogle Scholar
Moore, G.P.M., Jackson, N., Isaacs, K. and Brown, G. (1998). Pattern and morphogenesis in skin. Journal of theoretical Biology 191, 8794.CrossRefGoogle ScholarPubMed
Narytnyk, A., Gillinder, K., Verdon, B., Clewes, O. and Sieber-Blum, M. (2014). Neural crest stem cell-specific deletion of the Pygopus2 gene modulates hair follicle development. Stem Cell Reviews and Reports 10, 6068.CrossRefGoogle ScholarPubMed
O'Connell, D., Scobie, D.R., Hickey, S.M., Sumner, R.M.W. and Pearson, A.J. (2012). Selection for yearling fleece weight and its effect on fleece shedding in New Zealand Wiltshire sheep. Animal Production Science 52, 456462.CrossRefGoogle Scholar
Orwin, D.F.G. (1961). Bundles of follicles in adult Romney ewes. Nature 190, 10261027.CrossRefGoogle Scholar
Orwin, D.F.G. and Whitaker, A.H. (1984). Feral sheep (Ovis aries L.) of Arapawa Island, Marlborough Sounds, and a comparison of their wool characteristics with those of four other feral flocks in New Zealand. New Zealand Journal of Zoology 11, 201224.CrossRefGoogle Scholar
Pedrosa, S., Uzun, M., Arranz, J-J., Gutiérrez-Gil, B., Primitivo, F. and Bayón, Y. (2005). Evidence of three maternal lineages in near eastern sheep supporting multiple domestication events. Proceedings of the Royal Society of Biological Sciences 272, 22112217.CrossRefGoogle ScholarPubMed
Pereira, F., Davis, S.J.M., Luísa Pereira, L., et al. (2006). Genetic signatures of a Mediterranean influence in Iberian Peninsula sheep husbandry. Molecular Biology and Evolution 23, 14201426.CrossRefGoogle ScholarPubMed
Pickering, N.K., Young, E.A., Kijas, J.W., Scobie, D.R. and McEwan, J.C. (2013). Genetic origin of Arapawa sheep and adaptation to a feral lifestyle. Proceedings of the Association for the Advancement of Animal Breeding and Genetics 20, 451454.Google Scholar
Poplin, F. (1979). Origine du Mouflon de Corse dans une nouvelle perspective paléontologique: par marronnage. Annales de Génétique et de Sélection animale 11, 133143.CrossRefGoogle Scholar
Reed, C.A. (1984). The beginnings of animal domestication. In: Evolution of Domesticated Animals, ed. Mason, I.L. (pp. 16). London, UK: Longman.Google Scholar
Ryder, M.L. (1958). Follicle arrangement in skin from wild sheep, primitive domestic sheep and in parchment. Nature 182, 781783.CrossRefGoogle ScholarPubMed
Ryder, M.L. (1959). Some unusual outgrowths from secondary follicles in Soay sheep. Nature 183, 18311832.CrossRefGoogle ScholarPubMed
Ryder, M.L. (1960). A study of the coat of the Mouflon Ovis musimon with special reference to seasonal change. Proceedings of the Zoological Society of London 135, 387411.CrossRefGoogle Scholar
Ryder, M.L. (1962). Preliminary observations on seasonal changes in the fleece of unshorn Merino sheep. Australian Society for Animal Production 4, 4648.Google Scholar
Ryder, M.L. (1964). Fleece evolution in domestic sheep. Nature 204, 555559.CrossRefGoogle Scholar
Ryder, M.L. (1966). Coat structure in Soay sheep. Nature 211, 10921093.CrossRefGoogle Scholar
Ryder, M.L. (1967). Wool fibre shedding in some Merino sheep. Australian Journal of Agricultural Research 18, 683688.CrossRefGoogle Scholar
Ryder, M.L. (1984) Sheep. In Evolution of Domesticated Animals, ed. Mason, I.L. (pp. 6385). London, UK: Longman.Google Scholar
Ryder, M.L. (1986). Sheep and Man. London, UK: Duckworth.Google Scholar
Ryder, M.L. and Stephenson, S.K. (1968). Wool Growth. London, UK: Academic Press.Google Scholar
Sauka-Spengler, T., Meulemans, D., Jones, M. and Bronner-Fraser, M. (2007). Ancient evolutionary origin of the neural crest gene regulatory network. Developmental Cell 13, 405420.CrossRefGoogle ScholarPubMed
Sherratt, A. (1984). Plough and pastoralism: aspects of the secondary products revolution. In: Pattern of the Past, eds Hodder, I., Isaac, G. and Hammond, N. (pp. 261306). Cambridge, UK: Cambridge University Press.Google Scholar
Sieber-Blum, M., Grim, M., Hu, Y.F. and Szeder, V. (2004). Pluripotent neural crest stem cells in the adult hair follicle. Developmental Dynamics 231, 258269.CrossRefGoogle ScholarPubMed
Simoes-Costa, M. and Bronner, M. (2013). Insights into neural crest development and evolution from genomic analysis. Genome Research 23, 10691080.Google ScholarPubMed
Slee, J. (1965). Seasonal patterns of moulting in Wiltshire Horn sheep. In: The Biology of Skin and Hair Growth, eds Lyne, A.G. and Short, B.F. (pp. 545563). Sydney, Australia: Angus and Robertson.Google Scholar
Sumner, R.M.W., Scobie, D.R., O'Connell, D. and Henderson, H.V. (2017). Relative live weight, fleece weight and reproductive rate of farmed feral sheep (Ovis aries L.). New Zealand Journal of Zoology 44, 319344.CrossRefGoogle Scholar
Tänzer, E. (1926). Haut und Haar beim Karakul in rassenanalytischen Vergleich. Halle, Germany: Otto Thiele.Google Scholar
Tapio, M., Marzanov, N., Ozerov, M. et al. (2006). Sheep mitochondrial DNA variation in European, Caucasian, and Central Asian areas. Molecular Biology and Evolution 23, 17761783.CrossRefGoogle ScholarPubMed
Trut, L., Oskina, I. and Kharlamova, A. (2009). Animal evolution during domestication: the domesticated fox as a model. BioEssays 31, 349360.CrossRefGoogle Scholar
Tuncer, S.S., Uslu, S., Taş, A. and Şireli, H.D. (2018). The densities of fiber follicles in the Karakaç, Norduz, and Zom sheep and a comparative analysis. Australian Journal of Veterinary Science 50, 2126.CrossRefGoogle Scholar
Uehara, S., Izumi, Y., Kubo, Y., et al. (2009). Specific expression of Gsta4 in mouse cochlear melanocytes: a novel role for hearing and melanocyte differentiation. Pigment Cell and Melanoma Research 22, 111119.CrossRefGoogle ScholarPubMed
Wilkins, A.S., Wrangham, R.W. and Fitch, W.T. (2014). The ‘domestication syndrome’ in mammals: a unified explanation based on neural crest cell behavior and genetics. Genetics 197, 795808.CrossRefGoogle Scholar
Xavier, S.P., Gordon-Thomson, C., Wynn, P.C. et al. (2013). Evidence that Notch and Delta expressions have a role in dermal condensate aggregation during wool follicle initiation. Experimental Dermatology 22, 659662.CrossRefGoogle ScholarPubMed
Zeder, M.A. (2008). Domestication and early agriculture in the Mediterranean Basin: origins, diffusion, and impact. Proceedings of the National Academy of Science of the United States of America 105, 1159711604.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Approximate phases for the appearance of changes in sheep types and fleece and fibre traits from wild sheep to the Merino.

Figure 1

Fig. 1. Transverse skin section and fibre diameter distribution of Barbary sheep. (a) Primary (P) follicles in a trio group; fibres are large, medullated and of variable diameters (P Ø: 32, 53 and 26 μm, respectively). Secondary (S) follicles are in wedge-shaped clusters, adjacent to P follicles and have finer, shorter fibres (S Ø: 9 μm). Bar = 100 μm. (b) Histogram of the distribution of P and S fibre diameters (Dp, Ds) in the skin sample. P fibre frequencies are shaded.

Figure 2

Fig. 2. Transverse skin section and fibre diameter distribution of a modern Merino sheep. (a) Primary (P) follicles in a trio group; P fibres are fine, not medullated and have similar diameters (Ø: 20 μm). Secondary (S) follicles are numerous and are also of uniform diameter (Ø: 22 μm). Bar = 100 μm. (b) Histogram of the distribution of P and S fibre diameters (Dp, Ds) in the skin sample. P fibre frequencies are shaded.

Figure 3

Fig. 3. Comparisons of (a) primary and secondary fibre diameters and (b) primary and secondary follicle densities in a range of modern breeds; the primitive Soay sheep is designated ℗. Data from Carter (1968). Corriedales (Merino × Longwool) display intermediate characteristics. A primary to secondary fibre diameter ratio of 1 is shown as a diagonal line in (a).

Figure 4

Fig. 4. Transverse skin section and primary (P) and secondary (S) fibre diameter distribution of a ewe from the follicle size and number selection experiment. (a) The fibre of the P follicle (P at centre) is large and medullated (arrowhead); also shown is an adjacent P follicle with an unmedullated fibre. Bar = 100 μm. (b) Fibre diameter histogram from the same skin sample, showing P and S fibre diameter (Dp, Ds) distributions. Ds values range from coarse to fine. P frequencies are shaded.

Figure 5

Fig. 5. Transverse skin section and fibre diameter distribution of Arapawa Island sheep. (a) Trio group of primary (P) follicles. Secondary (S) follicles located are in wedge-shaped clusters between the P follicles. Bar = 100 μm. (b) Fibre diameter histogram from the same skin samples, showing P and S fibre distributions (Dp, Ds). P fibre frequencies are shaded.

Figure 6

Fig. 6. Comparisons between (a) primary and secondary fibre diameters and (b) primary and secondary follicle densities in modern Merino breeds (Carter, 1968) and in Arapawa sheep. The Arapawa mean fibre diameters in (a) are from the data of Fig. 5b. The follicle density measurement in (b) is from Orwin & Whitaker (1984); the Soay sheep ℗ and Merino values are from Carter (1968).