The Evolutionary History of the African Buffalo: Is It Truly a Bovine?

H. H. T. Prins; J. F. de Jong; D. Geraads

doi:10.1017/9781009006828.005

2 - The Evolutionary History of the African Buffalo: Is It Truly a Bovine?

from Part I - Conservation

Published online by Cambridge University Press: 09 November 2023

J. F. de Jong and

Edited by

Philippe Chardonnet and

Herbert H. T. Prins

Show author details

Alexandre Caron: Affiliation:
Centre de Coopération Internationale en Recherche Agronomique pour le Développement (CIRAD), France
Daniel Cornélis: Affiliation:
Centre de Coopération Internationale en Recherche Agronomique pour le Développement (CIRAD) and Foundation François Sommer, France
Philippe Chardonnet: Affiliation:
International Union for Conservation of Nature (IUCN) SSC Antelope Specialist Group
Herbert H. T. Prins: Affiliation:
Wageningen Universiteit, The Netherlands

Book contents

Summary

The current tribe Bovini may very well be polyphyletic. African buffalo might be descended from African Boselaphini, but the African fossil record before 8 Myr is quite poor. Palaeontological data tally well with nuclear DNA data showing that African buffalo and Asian buffalo separated some 8 Myr ago and are very distantly related. Cross-fertilization experiments and (failed) implantation tests of embryos of Asian Bovini into African buffalo wombs underscore the fact that these species are evolutionarily very distantly related. Karyotypic evolution of African buffalo is also very different from these Asian Bovini. This may warrant the establishment of a separate tribe for the African buffalo and its ancestors, namely, the Syncerini. Until recently there were two species of buffalo in Africa, Syncerus caffer and S. antiquus, which in some parts of their range coexisted. The ecology of the single surviving species of African buffalo may thus have been co-shaped by that recently extinct sister taxon. Because the present species is so distantly related to wild cattle and Asian buffalo, little or nothing can be learned from studying these species for the ecology or management of the African buffalo, even if much were known about these species in the wild (which is not the case).

Keywords

African buffalo Pelorovis antiquus Syncerus species swarm Bovini Syncerini Boselaphini Bos Bubalus Pachyportax

Type: Chapter
Information: Ecology and Management of the African Buffalo , pp. 25 - 48

DOI: https://doi.org/10.1017/9781009006828.005 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2023
Creative Commons: This content is Open Access and distributed under the terms of the Creative Commons Attribution licence CC-BY-NC-ND 4.0 https://creativecommons.org/cclicenses/

Introduction

If one sees an African buffalo (Syncerus caffer) for the first time after seeing many water buffalo (Bubalus bubalis), one could easily believe they are closely related. In 1758, Carolus Linnaeus named the water buffalo scientifically, but he did not classify the African buffalo. The first formal mention is by Anders Sparrmann (Reference Sparrmann1779), a pupil of Linnaeus, who classified the species as Bos caffer, just as his mentor had classified the Asian species as Bos bubalis. A military artist named Charles Hamilton Smith coined the Latin genus name Bubalus for the Asian buffalo in 1827. A nineteenth-century taxonomist, Brian Hodgson, elevated the African buffalo to its own genus, namely, Syncerus Hodgson, Reference Hodgson1847. What justifies the separation of these two ‘buffalo’ into distinct genera? Strangely enough, two fundamental characters: namely, in Syncerus the vomer and the palate are not fused, and the nuchal hair-stream is not reversed (Groves, Reference Groves1969). Groves states: ‘Consequently the generic separation of Bubalus from Syncerus seems thoroughly justified, and some at least of the similarity between them (such as that in the shape of the horn cores) must be put down to parallelism.’ Whether these two fundamental traits have any ecological meaning is unknown, but the case for parallelism is intriguing.

A systematic classification is in principle based on diagnosable (often morphological, thus not necessarily functionally important) characters, mainly of extant species (see Zachos, Reference Zachos, Zachos and Asher2018 for a review). Systematicists decided that the African buffalo should not be classified into one genus with the Asian buffalo, but does the fossil material combined with DNA-based phylogenies provide enough clues to establish the evolutionary history of the African buffalo? Our analysis will show that there is quite some doubt as to whether the African buffalo is related to the Asian buffalo species swarm, or to the larger one comprising wild cattle, yak and bison. The question that arises, of course, is whether taxonomy and systematics have any bearing on ecology and management. We believe it does if, by having knowledge on related species, one can more safely generalize; if not, then systematics at the level of the genus or higher is irrelevant. Indeed, conservation is about species – not genera, families or tribes.

The African buffalo is a large bovid. Mammals are classified as ‘bovid’ if they have, at least in the adult male, two or rarely four unforked horns. These are composed of bone cores protruding from their skull after ‘horn buds’ which are covered by a permanent layer of keratin start growing in the skin and fuse with the skull (Davis et al., Reference Davis, Brakora, Stilson, Melletti and Burton2014). Bovids emerged some 18.5 Myr ago (Vrba and Schaller, Reference Vrba, Schaller, Vrba and Schaller2000) or even slightly more recently (Bibi, Reference Bibi2013). Some studies refer to an older emergence of the Bovidae based on material from Mongolia in the Middle Oligocene, thus 26 Myr ago (Trofimov, Reference Trofimov1958; see Thomas, Reference Thomas1984), but this is now questioned (Métais et al., Reference Métais, Antoine and Marivaux2003). The mammals classified as Bovidae are thought to be related to each other, and the common trait of unforked horns is taken to be a shared, derived character, common between ancestor and descendants. Modern molecular techniques allowed this assumption to be put to the test, resulting in updated insights about the classification of the ~140 bovid species within the approximately 40 genera (Grubb, Reference Grubb, Wilson and Reeder1993). Within this group of Bovidae, African buffalo are classified with the subfamily Bovinae, within the tribe Bovini. The other two tribes in that subfamily are the Tragelaphini and the Boselaphini. All other bovids are classified within the subfamily Antilopinae.

Modern molecular techniques show that the subfamily Antilopinae as classified by morphologists has a very different evolutionary, and thus classificatory, structure than previously thought (Ropiquet and Hassanin, Reference Ropiquet and Hassanin2005; Hassanin, Reference Hassanin, Melletti and Burton2014). Enough reasonably well-dated fossils are available to pinpoint some major bifurcations between tribes in time. These phylogenies all suggest that the tribe Bovini is nested together with the Tragelaphini and the Boselaphini in one ‘proper’ subfamily, the Bovinae (Bibi, Reference Bibi2013; Druica et al., Reference Druica, Ciorpac and Cojocaru2016). At first sight, the message about the evolution of the Bovini does not appear to have changed much since publications by Sinclair (Reference Sinclair1977) and Gentry and Gentry (Reference Gentry and Gentry1978). Yet there is now perhaps more reason to consider the Bovini as a heterogeneous (non-monophyletic) group, the African buffalo not being closely related to either the water buffalo of Asia (Bubalus) or oxen, bisons and yaks. Perhaps it deserves a special tribe, Syncerini, but the evolution of the Bovini is still shrouded in much uncertainty. Five insights play havoc. First, phylogenies based on molecular markers rely heavily on available genetic material. For bovids, to date this material has been taken from living and thus contemporary specimens; fossil material does not yet play a role, except for some very recently extinct species. This means that for extinct tribes or even subfamilies there is no genetic information that has the potential to upset phylogenies that are based on parsimonious calculus (cf. Frantz et al., Reference Frantz, Schraiber and Madsen2013; Table 2.1). Second, the phylogeny based on mitochondrial DNA shows a short period around 18–15 Myr in which the Boselaphini, Tragelaphini and Bovini separated (Hassanin, Reference Hassanin, Melletti and Burton2014; Zurano et al., Reference Zurano, Magalhãesa and Asato2019). It should be realized, however, that the phylogenetic trees based on DNA suggest such divergence to have taken place some 10 million years before the oldest finds of Tragelaphini (second half Late Miocene, c.7 Myr) or Bovini (c.8 Myr). Furthermore, the calibration of the molecular-based phylogeny is based on fossils from other families mainly (see Zurano et al., Reference Zurano, Magalhãesa and Asato2019 for details) while fossil Boselaphini may be hard to identify, because early forms had few distinctive features. Third, the fossil material itself may indicate that Bovini evolved from Boselaphini several times and not just once (Gentry, Reference Gentry, Werdelin and Sanders2010). In fact, evidence for this is very slender, but this may nevertheless still be true because there is no evidence that early African Bovini (which are rare and poorly known) are derived from Asian forms. It is quite possible that they derived directly from African Boselaphini (close to Tragoportax; see Figure 2.1). Fourth, the number of Bovid species recognized in the fossil material is strongly determined by sampling effort, and there are many more sites for some periods than for others (Patterson et al., Reference Patterson, Faith, Bobe and Wood2014). Lastly, within the Bovini tribe there is a worrying lack of clarity about not only the proper naming of species and genera in the fossil material, but also whether particular fossil species and their living descendants should be taken to belong to a particular genus or to another. Much dust has been stirred up on the systematic position of Pelorovis. Was it a distinct genus? Did it belong to the genus Bos? Did it belong to the genus Syncerus? Yet if animal populations cannot be classified into valid species and allocated precise generic status, then concepts like ‘competitive exclusion’ or ‘niche differentiation’ become very difficult to apply.

Figure 2.1 Phylogeny of the Bovini and Syncerini. During the Pleistocene members of the genus Bos ventured into Africa too (see text). The separation between Boselaphini and Bovini or Syncerini is very unclear.

The Genus Pelorovis and the Syncerus antiquus Conundrum

We start with Pelorovis and the issues surrounding its phylogenetic position to better understand the evolution of Syncerus. The most important insight that emerges is that there was a second species of Syncerus, namely S. antiquus, in much of Africa that went extinct only very recently, in the last two millennia. It overlapped in space and in time with the extant African buffalo.

Hans Reck started the excavations in Olduvai (Tanzania) and found the remains of a large mammal, which he named Pelorovis (‘frightful sheep’). Later, Gentry (Reference Gentry1967) classified Pelorovis with the Bovini, but thought it to be very distantly related to the Asian Bovini. Pelorovis may have been derived from Simatherium (Geraads, Reference Geraads1992) like the African buffalo Syncerus. The difficulty of Bovini classification is well underscored by the struggle palaeontologists have in allocating the different species of Pelorovis to their classificatory nook: does a fossil belong to Pelorovis or to Bos or Syncerus, and, alternatively, should the genus Pelorovis be seen as an independent genus, or do the species of this genus better fit in Bos or Syncerus? Indeed, an identical specimen may be classified as Pelorovis or as Simatherium (Gentry, Reference Gentry, Werdelin and Sanders2010), showing the opaqueness of the systematics and phylogeny of the Bovini (see Table 2.1).

Table 2.1 Interplay between palaeontology and genetics to deduce a reliable phylogeny. The trade-off one makes between knowledge from genetics and palaeontological knowledge is not straightforward. It may upset established phylogeny, yet it may also strengthen it. If knowledge from palaeontology and genetics (if these have been reached independently) overlap, inference about the past is very strong. If there are mismatches between the two fields of enquiry, a research strategy can be formulated once one realizes the mismatch.

		Genetics
		Species that have been allotted an unquestionable place in a phylogeny, thus ‘knowns’	Species of which the place in a phylogeny depends on a priori choices	Species of which the genetics has not yet been carried out, thus ‘unknowns’
Palaeontology	Knowns (i.e. species that have been found and have been classified with confidence)	If there is match, we have reached a true justified belief (the hallmark of good science). If the two do not match, both fields of knowledge have to actively work together to solve the issues. Exciting new insights can arise: e.g. on the origin of Bison bonasus as a possible hybrid species of Bison priscus and Bos primigenius	Genetics should follow palaeontology and recalculate phylogenies. Bayesian approaches should incorporate prior knowledge from palaeontology	Here future progress in palaeo-DNA will perhaps make very unexpected changes
	Uncertain (i.e. species that have been found but about which the classification is unsure)	Palaeontology should incorporate knowledge from genetics to decide on the best place of such a species in an existing phylogeny	Danger exists that there is false certainty in published phylogenies by geneticists	A general state of ignorance predominates
	Unknowns (i.e. species that have not yet been found or identified)	Phylogenies based on absent species may give a false sense of certainty	Phylogenies based on absent species may give a false sense of certainty	‘Unknown unknowns’, which may upset any established phylogeny

Seven species of Pelorovis have been named. Pelorovis oldowayensis is the best-known form; it has long, regularly curved horncores, first emerging almost posteriorly but recurving forwards, with a total span that can reach 2 m. It is best represented in Olduvai, but also in other Eastern African sites and in Israel (Geraads, Reference Geraads and Tchernov1986). Pelorovis turkanensis has shorter horns; it overlaps in time with the former species, but appears earlier. The North African ‘Bos’ bubaloides, ‘Bos’ praeafricanus and Pelorovis howelli (Hadjouis and Sahnouni, Reference Hadjouis and Sahnouni2006) are almost certainly identical with one or the other East African forms. Pelorovis kaisensis from Uganda and perhaps Ethiopia differs in its virtually straight horns (Geraads and Thomas, Reference Geraads and Thomas1994; Alemseged et al., Reference Alemseged, Wynn and Geraads2020). The origin of the genus is unclear, especially because the distinction between the earlier African Ugandax and Simatherium dwindled recently with the discovery of more fossils. The last species to go extinct was Pelorovis antiquus (a.k.a. Homoiceras antiquus, H. baineii or H. nilsonii: Rossouw, Reference Rossouw2001). However, this species may be better understood as Syncerus antiquus. Neither Gentry (Reference Gentry, Werdelin and Sanders2010) nor Klein (Reference Klein1994) were convinced that this was correct, but at present the leading verdict is that one could accept this view. S. antiquus had a wide distribution, and survived in northern Africa till recent times (Figure 2.2). A very late drawing of it may have been from Egypt just prior to the first Pharaoh from the so-named Amratian Civilization (~3600 bce ; see Childe, Reference Childe1958, figure 1.9). Lovely rock art from the desert of Algeria shows scenes, including bulls fighting (e.g. Brodrick, Reference Brodrick1948, p. 37).

(a) S. antiquus from I-n-Habeter, Mesāk, Libya.

Photo Jean-Loïc Le Quellec.

(b) Rock engraving of S. antiquus from Tilizzāyen, Mesāk, Libya.

Photo Jean-Loïc Le Quellec (used with permission).

Figure 2.2 In rocky massifs in the Sahara, petroglyphs (engravings in the rock) of animal species are quite widespread. This rock art was made when the Sahara was covered by savannas or steppes, and thus shows many species that are now only known from the Sahel or East Africa. Among these are depictions of Syncerus (or Pelorovis) antiquus, which is now extinct but was once widespread.

In the Early Pleistocene beds in Arabia, a very large bovid has been found that is classified as Pelorovis cf. oldowayensis (Thomas et al., Reference Thomas, Geraads and Janjou1998). This may be an early proof of an outward migration of members of the genus Pelorovis, together with the ‘Ubeidiya occurrence. Intriguingly, it had very large feet apparently adapted to move on soft substrates’ (Thomas et al., Reference Thomas, Geraads and Janjou1998). The case shows how nomenclature intertwines with dating: the finds described by Thomas et al. (Reference Thomas, Geraads and Janjou1998), and interpreted on the basis of morphological data as being close to P. oldowayensis, were later re-interpreted because the beds from which the fossils were extracted were dated later in time and were thus allocated to Syncerus antiquus (Stewart et al., Reference Stewart, Louys, Price, Drake, Groucutt and Petraglia2019). This latter approach to classification is, in our opinion, incorrect. Similarly, molars of a smaller species that looked like those of S. caffer were classified as S. antiquus because S. antiquus is known from south-west Asia but S. caffer is not (Stewart et al., Reference Stewart, Louys, Price, Drake, Groucutt and Petraglia2019). However, Geraads (Reference Geraads and Tchernov1986) also identified Pelorovis oldowayensis from the Early Pleistocene in a nearby area, namely Israel, and later Martínez-Navarro et al. (Reference Martínez-Navarro, Belmaker and Bar-Yosef2012) confirmed the identification, but assigned the species to Bos.

This raises the issue of the relationships of Pelorovis with Bos, a mostly Eurasian genus that includes, besides the modern cattle and aurochs, several wild, endangered southern Asian species and fossil species in the same area. In Africa, unquestionable early representatives of the genus are Bos buiaensis from Eritrea, dated to 1 Myr (Martínez-Navarro et al., Reference Martínez-Navarro, Rook, Papini and Libsekal2010), a Middle Pleistocene B. primigenius from Tunisia dated to 0.7 Myr (Martínez-Navarro et al., Reference Martínez-Navarro, Karoui-Yaakoub and Oms2014) and a species from the lower Awash Valley of Ethiopia, which is close to the southern Asian extinct species B. acutifrons (Geraads et al., Reference Geraads, Alemseged and Reed2004).

The Tunisian find is almost certainly a Eurasian immigrant (pace Martínez-Navarro et al., Reference Martínez-Navarro, Karoui-Yaakoub and Oms2014), while the fact that the Eastern African forms were found close to the Aden straits strongly suggests that they are Asian immigrants. Detailed studies of the geology of the Bab-al-Mandab (the entry to the Red Sea from the Gulf of Aden) show that the straits between the Horn of Africa and the Hadhramaut, where a shallow sill is positioned (the Hanish Sill), remained submerged during the Pleistocene (Al-Mikhlafi et al., Reference Al-Mikhlafi, Edwards and Cheng2018). Yet during glacial periods, the straits were ‘sufficiently narrow for both sides of the channel to have been visible at all times’ and only about 1–3 km wide (Lambeck et al., Reference Lambeck, Purcell and Flemming2011), thus making it feasible that Asian species of Bos crossed here into Africa. Note that the occurrence of S. c. nanus until a century ago on Bioko Island, some 35 km off the mainland in the Gulf of Guinea, cannot be taken as an example of buffalo being able to cross such a distance at sea, because Bioko Island was linked to the mainland until the beginning of the Holocene (Ceríaco et al., Reference Ceríaco, Bernstein and Sousa2020). Nevertheless, buffalo are good swimmers, and are able to cross wide rivers like the Nile and the Zambesi.

By contrast, Martínez-Navarro et al. (Reference Martínez-Navarro, Pérez-Claros and Palombo2007, Reference Martínez-Navarro, Rook, Papini and Libsekal2010) envisage an evolutionary line of the genus Bos starting as Bos (P.) turkanensis (Late Pliocene), B. (P.) oldovayensis (Early Pleistocene), B. (P.) buiaensis (Early Pleistocene) and thence Bos primigenius (the Aurochs) and also Bos planifrons (which more often is taken as the direct ancestral form of Bos primigenius namadicus – the Indian form of the aurochs which developed into Bos indicus, the zebu). The important consequence of accepting this interpretation is that the direct ancestors of cattle and zebu evolved in Africa and not in Asia. This would agree with the parsimony analysis on morphological characters performed by Geraads (Reference Geraads1992), which showed them to be close on the cladograms. However, the detailed study by Gentry (Reference Gentry1967) showed that the cranial morphology of P. oldowayensis is very different from that of Bos, and it is likely that their closeness on cladograms results from parallelisms. Furthermore, the contemporaneity of the last representatives of the former species with Bos buiaensis make an ancestral–descendant relationship extremely unlikely (Geraads, Reference Geraads, Gallotti and Mussi2018). Moreover, this reasoning sits very uncomfortably with studies that base their reasoning on genetics: B. primigenius, cattle and zebu all fit snugly within the phylogenies of the other Asian Bos species (cf. Van der Made, Reference Van der Made2013). After carefully considering the arguments and fossil material, Tong et al. (Reference Tong, Chen, Zhang and Wang2018) conclude that B. primigenius was not derived from species that have been classified as Pelorovis, and support the view that B. primigenius evolved in South Asia, as does Van der Made (Reference Van der Made2013). Likewise, Bar-Yosef and Belmaker (Reference Bar-Yosef and Belmaker2016) maintain the position that B. primigenius appeared in southwestern Asia as early as 1.2 Myr bp, and it continually occurred in this region until the Late Pleistocene. They recognize B. buiaensis in the Jordan Valley much later, namely 0.5–0.8 Myr, but as stated, this could well have been a Pelorovis. Indeed, many authors have stated that Pelorovis (Syncerus) antiquus was part of the mammal assemblage of the Pleistocene Levant.

Is there good reason to accept the view that Pelorovis antiquus should be considered as Syncerus antiquus as deduced by Peters et al. (Reference Peters, Gautier, Brink and Haenen1994) but rejected by Klein (Reference Klein1994)? The predecessor (but not necessarily ancestor) of P. antiquus was P. oldovayensis. This species was already present in the Levant (Bar-Yosef and Belmaker, Reference Bar-Yosef and Belmaker2016) and perhaps in Arabia (Thomas et al., Reference Thomas, Geraads and Janjou1998) in the Early Pleistocene. Yet, Martínez-Navarro and Rabinovich (Reference Martínez-Navarro and Rabinovich2011) argue to classify this species as S. antiquus; however, their publication does not present arguments other than opinion. The original argument put forward by Peters et al. (Reference Peters, Gautier, Brink and Haenen1994) to view P. antiquus merely as a form of S. caffer, or as a separate species S. antiquus, was mainly based on the observation that the postcranial skeleton hardly differed from S. caffer (Peters et al., Reference Peters, Gautier, Brink and Haenen1994). However, this is a weak argument, because ‘The similarity in the postcranial skeleton known from Bos, Bison and Bubalus arnee is surprising considering that, according to an analysis of mitochondrial DNA, the separation of the Bubalus–Syncerus clade from the Bos–Bison clade goes back to the Middle Miocene’ (Van der Made et al., Reference Van der Made, Torres, Ortiz, Fernández-Jalvo, King, Yepiskoposyan and Andrews2016; see also Von Koenigswald et al., Reference Koenigswald, Schwermann, Keiter and Menger2019). The main argument of Klein (Reference Klein1994) was that the two species coexisted for a long time, and if both were to be viewed as Syncerus, then that would not have been possible. This is, however, based on an old ‘rule’ of competitive exclusion formulated by Charles Darwin but for which there is no firm evidential support (Prins and Gordon, Reference Prins, Gordon, Prins and Gordon2014a, Reference Prins, Gordon, Prins and Gordon2014b). Note that species of the same genus can very well coexist, as exemplified by Lechwe and Puku or Plains Zebra and Grevy’s zebra in Africa, or for that matter by the many different Anas spp., Anser spp., Corvus spp., etc. in the Boreal zone.

Yet we also have not read convincing arguments to accept the view that Pelorovis antiquus was merely another African buffalo or even a more drought-adapted subspecies of the present-day African buffalo (cf. Peters et al., Reference Peters, Gautier, Brink and Haenen1994). Indeed, the stance one takes with respect to the systematic position of P. antiquus affects the way the evolutionary history of S. caffer is interpreted. Note that this has little to do with accepting or rejecting the narrow species concept proposed by Groves and Grubb (Reference Groves and Grubb2011, p. 1 ff.). However, Gentry (Reference Gentry, Werdelin and Sanders2010) takes P. antiquus (grudgingly) as S. antiquus, even though he does not present arguments for (or against) this view. However, this evidence is murky, because it depends so much on interpretation in the case of the fossil Bovini material. This implies that one has to consider two alternative scenarios in the evolution of Syncerus: namely, one with S. antiquus as a species coexisting with S. caffer and living in the same area as B. primigenius in northern Africa, and the other in which Syncerus never reached the areas to the north of the Sahara but that the relevant ‘buffalo’ species in that area was P. antiquus.

Miocene Origins of the African Buffalo

How far back in time can one trace the ancestry of the African buffalo? It may have appeared reasonably clear 50 years ago (Sinclair, Reference Sinclair1977, p. 22), but the crucial issue is whether the African buffalo really fits into the Bovini (together with the Asian buffalo and the wild cattle swarm). On the basis of DNA, it can be deduced that the last common ancestors of the Bovini and the Tragelaphini (species like the present-day kudu, bushbuck and eland antelope) lived some 18 Myr (Bibi et al., Reference Bibi, Bukhsianidze and Gentry2009) or 15 Myr ago (Zurano et al., Reference Zurano, Magalhãesa and Asato2019), but the first fossil material comes from Eotragus, which is classified as a Boselaphine (like the present-day nilgai). Between the oldest species, E. noyei from Pakistan (18 Myr), and the next species, E. sansaniensis from France (15.2 Myr), there is a gap of 3 million years, which is as long as the duration of the entire Pleistocene (Solounias and Moelleken, Reference Solounias and Moelleken1992). Then there is another enormous time gap of some 6 million years to a genus named Selenoportax/Pachyportax, again from Pakistan (9 Myr; Bibi et al., Reference Bibi, Bukhsianidze and Gentry2009). An ancestral relation between Pachyportax and Parabos (thought to be ancestral to Leptobos, Bos and Bison and perhaps to Proamphibos leading to Bubalus) has been surmised, but the evidence is weak. From Pachyportax onwards, the fog of the fossil record lifts a bit. But just when one seemed to be back on firm footing, Gentry (Reference Gentry, Werdelin and Sanders2010) dropped a bombshell by pointing out that there is a fair chance that the Bovini are not even monophyletic. Indeed, Geraads (Reference Geraads1992) had already shown that the relationship between Asian and African buffalo is not well supported. In other words, after decades of hard field work and thinking, the early history of the Bovini is not yet clear regardless of what phylogenies based on present-day DNA seem to suggest. Later we will show that cross-fertilization data between African and Asian buffalo also point to a very weak relationship within the group of organisms that are classified as Bovini.

The genus Eotragus was a long-lived one with a very wide distribution, ranging from Europe to China, Pakistan and Israel to Kenya (Solounias et al., Reference Solounias, Barry, Bernor, Lindsay and Raza1995). The genus Tethytragus was similar to Eotragus, but evolutionary perhaps not a Boselaphine, and even though T. langai still falls within the class of brachydont herbivores, it was more hypsodont than Eotragus and may already have been a grazer (DeMiguel et al., Reference DeMiguel, Azanza and Morales2011, Reference DeMiguel, Sánchez and Alba2012). Yet it appears that the early ‘invasion’ of Africa by Boselaphini at the beginning of the Middle Miocene did not lead to today’s Bovini in Africa. They may have arisen from a second ‘invasion’ of Boselaphini at the end of the Middle Miocene (Thomas, Reference Thomas1984; Gentry, Reference Gentry, Werdelin and Sanders2010).

The next genus to consider is Pachyportax, which lived during the end of the Miocene. The genus has also been classified within the Boselaphini, but it appears that the Boselaphini are not a homogeneous tribe (Bibi et al., Reference Bibi, Bukhsianidze and Gentry2009). Pachyportax latidens was a large Boselaphine during the Late Pliocene (7–3.5 Myr) of the Siwalik Hills of Pakistan with strongly developed molars for chewing roughage (Ikram et al., Reference Ikram, Safdar and Babar2017). At the same time, there was another Boselaphine in the Siwaliks with less hypsodont molars, which was of the genus Tragoportax. European Tragoportax at least are large forms, and have rather long legs (perhaps similar to the nilgai). There were quite a number of other putative Boselaphini species at that time in the Siwalik mammal assemblage (Batool et al., Reference Batool, Khan and Babar2016), but whether they were truly Boselaphine is uncertain (Bibi et al., Reference Bibi, Bukhsianidze and Gentry2009). Miocene Bovini show mesowear patterns that are similar to present-day browsers and mixed-feeders, and the molars were not yet very hypsodont (Bibi, Reference Bibi2007). Indeed, Solounias and Dawson-Saunders (Reference Solounias and Dawson-Saunders1988) elegantly showed how masticatory morphology features relating to intermediate feeding and grazing adaptations evolved in parallel several times and independently from primitive browsing conditions. According to these authors, this did not happen in a savanna-type landscape but in the broad-leaved forests and woodlands there (in Greece). Bibi’s (Reference Bibi2007) palaeoecological reconstruction is that these early Bovini started utilizing open C₃ vegetation with C₃ grasses. Indeed, C₄ grasses became important only later (Barry et al. Reference Barry, Morgan and Flynn2002), and Bibi (Reference Bibi2007) speculates that because the hypsodont index only reached values indicating pure grazing around 8 Myr ago, this behaviour started with the emergence of C₄ grassland at that time. However, the abrasion patterns of the molars do not support this (Bibi, Reference Bibi2007). The driving evolutionary force may have been the strengthening of the monsoonal system due to the uplift of the Tibetan Plateau (Searle, Reference Searle, Prins and Tsewang2017) leading to resource scarcity during the dry season (Bibi, Reference Bibi2007). The fire-dominated and grazer-induced grasslands came into existence only about 2 Myr ago in Africa (Spencer, Reference Spencer1997).

In Libya, Tragoportax cyrenaicus lived about 7 Myr ago; the species was perhaps derived from the West Eurasian form (Gentry, Reference Gentry, Werdelin and Sanders2010). From South Africa, T. acrae has been reported (also known as Mesembriportax acrae, but cladistically sitting more comfortably with Tragoportax: Spassov and Geraads, Reference Spassov and Geraads2004). Tragoportax had a very large range, from Spain to China, and from southern Asia to southern Africa (Batool et al., Reference Batool, Khan and Babar2016). In the Siwaliks, the lineage of Tragoportax changed from a C₃ browser at 8 Myr to a C₄ grazer at 7.5 Myr. By 6.5 Ma, most frugivores and/or browsers had disappeared even though areas of C₃ vegetation remained until at least 4.5 Myr on the flood plain (Patnaik, Reference Patnaik, Wang, Flynn and Fortelius2013; cf. Saarinen, Reference Saarinen, Gordon and Prins2019).

Sinclair (Reference Sinclair1977, p. 22), based on Pilgrim (Reference Pilgrim1939) and Thenius (1969, cited in Sinclair, Reference Sinclair1977), suggested that Parabos was the ancestor of the African Bovini (Pelorovis, Syncerus) but also of the Eurasian Bos and Bubalus. The fact that much older Bovini have been found in Pakistan, namely some 8 Myr ago (Bibi, Reference Bibi2007), and that no Parabos has been found outside Europe and the Middle East, pleads against accepting the genus Parabos as ancestral to modern Bovini. This is reinforced by the fact that it seems to be seen better as belonging to the Boselaphini than to the Bovini (Gromolard, Reference Gromolard1980; Gromolard and Guerin, Reference Gromolard and Guérin1980; Geraads, Reference Geraads1992). Moreover, Parabos still occurred much later in time than the separation of Syncerus and Bubalus. It appears that Boselaphines disappeared from the African continent at the end of the Miocene (Gentry, Reference Gentry, Bubeník and Bubeník1990; Bibi, Reference Bibi2007 – the Miocene ends 5.3 Myr), unless there was a lineage leading to the present-day African buffalo.

The Pliocene Ancestors of Syncerus

Genetic data suggest a separation of Bubalus and Syncerus some 8.8 Myr ago (Hassanin, Reference Hassanin, Melletti and Burton2014) or even a million years earlier (Zurano et al., Reference Zurano, Magalhãesa and Asato2019), or (on the basis of cytochrome-c analyses) some 6 Myr ago (Druica et al., Reference Druica, Ciorpac and Cojocaru2016), thus in the Miocene. Among the oldest African Bovines, Ugandax cf. gautieri (see Thomas, Reference Thomas1984) has been reported from Lukeino, as early as about 6 Myr (Pickford and Senut, Reference Pickford and Senut2001); this species had much morphological similarity with Simatherium demissum from South Africa (Thomas, Reference Thomas1984; cf. Geraads, Reference Geraads1992). Ugandax may have been derived from the Selenoportax–Pachyportax lineage from the Siwaliks (Thomas, Reference Thomas1984; Gentry, Reference Gentry, Werdelin and Sanders2010), but Bibi (Reference Bibi2009, p. 332) states that it was also very similar to Proamphibos lachrymans (the putative ancestor of the Asian buffalo). Bibi (Reference Bibi2009, p. 339) poses that Proamphibos lachrymans was the last common ancestor of the African and Asian buffalo. Proamphibos was substantially larger than Pachyportax (Bibi, Reference Bibi2009, p. 339).

There was a suite of species within the genus Ugandax or closely related (U. [S.] demissum from Early Pliocene South Africa; U. coryndonae from the Middle Pliocene, Ethiopia; U. gautieri from Uganda, of about 5 Myr; Simatherium kohllarseni from the Middle Pliocene of Tanzania and Kenya; and S. shungurense from the Late Pliocene of Ethiopia; Geraads et al., Reference Geraads, Blondel and Mackaye2009a). Yet the evolutionary link between Ugandax–Simatherium and Syncerus also is not well supported by cladistic analyses (Geraads, Reference Geraads1992).

Ugandax coryndonae is perhaps the best known of the Pliocene African Bovini, represented by a large number of specimens from Ethiopia (Gentry, Reference Gentry2006; Geraads et al., Reference Geraads, Melillo and Haile-Selassie2009b, Reference Geraads, Bobe and Reed2012). This species may have lived until the Pleistocene, 2.5 Myr ago (Bibi, Reference Bibi2009, p. 335). In other words, the notion that Ugandax could have given rise to Syncerus (Gentry, Reference Gentry2006) is not well supported by cladistic analysis, and is further undermined by the earliest records of Syncerus perhaps overlapping in time with those of Ugandax (Gentry, Reference Gentry, Werdelin and Sanders2010; Bibi et al., Reference Bibi, Rowan and Reed2017).

The deduction that a Middle Pliocene emigration took place by a Syncerus-type buffalo from Africa into the Caucasus (Vislobokova, Reference Vislobokova2008), and from there to Eastern Europe (Evlogiev et al., Reference Evlogiev, Glazek, Sulimski and Czyzewska1997), by a species classified as Eosyncerus ivericus is most likely not justified because the material appears to be Caprine (Bukhsianidze and Koiava, Reference Bukhsianidze and Koiava2018).

So, back to Proamphibos. During the Pliocene, this large bovine lived in the foothills of the Himalayas and the floodplains of the Indus and Ganges (Khan et al., Reference Khan, Iqbal, Ghaffar and Akhtar2009). Two species have been distinguished, namely, the less advanced form (with regards to skull and horn morphology) P. lachrymans and the more advanced P. kashmiricus (Pilgrim, Reference Pilgrim1939; Khan and Akhtar, Reference Khan and Akhtar2011). The body mass of Proamphibos was about 200 kg (Dennell et al., Reference Dennell, Coard and Beech2005). Later (i.e. younger) finds of P. lachrymans have been reclassified as Damalops palaeindicus, not belonging within the Bovini but to the Alcelaphini (the hartebeest group); the presence of Proamphibos as late as 0.8 Myr ago is thus factually refuted. Apparently, it did not co-occur with Hemibos (neither with H. acuticornis nor with H. triquetricornis) and also not with Bubalus in Siwalik deposits (Badam, Reference Badam1977: his table 2; also, in figure 17.11 of Patnaik, Reference Patnaik, Wang, Flynn and Fortelius2013). The genus Proamphibos is thus considered to be more ancient than the genus Hemibos (cf. Bibi, Reference Bibi2009, p. 338). The genus Hemibos was considered to include the direct ancestor of Bubalus, and perhaps especially of the Anoa of Sulawesi (Groves, Reference Groves1976). Evidence of co-occurrence of Hemibos with Bubalus, however, pleads against this. There is no evidence that members of the genus Hemibos, which appears to have derived from Proamphibos, migrated to Africa or were involved in any way in the evolution of African Bovini and Syncerus in particular.

An independent lineage, not leading to Syncerus but perhaps related, was present in northern Africa in the form of Leptobos syrticus. Gentry (Reference Gentry, Bubeník and Bubeník1990), Duvernois (Reference Duvernois1992) and Geraads (Reference Geraads1992) concluded that it should not be maintained within the genus Leptobos; they prefer to not assign it to a genus, but conclude a similarity with Syncerus. ‘Leptobos’ syrticus may be related to Jamous kolleensis from Pliocene Chad, but this latter species does not show clear affinity with Syncerus (Geraads et al., Reference Geraads, Blondel and Mackaye2009a). Jamous kolleensis was a medium-sized bovine, still with rather primitive molars (Geraads et al., Reference Geraads, Blondel and Mackaye2009a). Because the Eurasian genus Leptobos, so important for understanding the evolution of Bos including Bison, apparently did not otherwise play a role in the evolution of Pelorovis or Syncerus, we do not deal with it in this chapter.

Thus, Proamphibos, or less likely Ugandax, is perhaps the link between Asian and African buffalo that geneticists identified to have lived some 8 Myr ago. Cladistic analysis of many fossil forms, modern Bubalus and modern Syncerus do not well support a strong relationship between Asian and African buffalo (Geraads, Reference Geraads1992). A putative separation some 8 Myr ago is an ancient one for mammals in contrast to birds because the former have prezygotic and postzygotic barriers and the latter prezygotic ones only. These postzygotic barriers are confirmed through embryo transfer experiments (see below), so the genetic distance is really to be reckoned in millions of years. On the basis of a careful analysis of karyotype evolution, it also appears that African and Asiatic buffalo evolved along two different and independent routes, as their centric fusions involved different homoeologous chromosomes (Iannuzzi et al., Reference Iannuzzi, King and Di Berardino2009).

African Buffalo Syncerus caffer – Pleistocene and Holocene Fossil Material

So, neither a cladistic analysis of many fossil and modern forms nor studies on nuclear DNA and embryology support a strong relationship between African and Asian buffalo. The ancestry of Asian buffalo, through its descending from Hemibos, which was derived from Proamphibos, appears reasonably well-founded. The ancestry of the African buffalo is shrouded in opacity. As sketched out, the Pliocene forms Ugandax led to Simatherium and may have led from there to Syncerus, but this link is not well supported by cladistic analyses (Geraads, Reference Geraads1992). Fossil Syncerus, such as at Shungura and Olduvai, had no large basal bosses (as the modern Cape buffalo Syncerus c. caffer) (Gentry, Reference Gentry, Bubeník and Bubeník1990). Gentry even states that these Simatherium were small and short-horned similar to the forest buffalo S. c. nanus of today. Whether they form an unbroken lineage to the present forest buffalo is not known, but this is very unlikely given the way that S. c. nanus is genetically nested within the other living African buffalo (Van Hooft et al., Reference Van Hooft, Groen and Prins2002). Recent genetic studies (reviewed in Prins and Sinclair, Reference Prins, Sinclair, Kingdon and Hoffmann2013) suggest that S. c. nanus is the older form and S. c. caffer only arose some 150,000 years ago. Whether the two forms (a nanus-like one and a caffer-like one), as suggested by Gentry (Reference Gentry, Bubeník and Bubeník1990), really have been present for a long time seems to be contradicted by genetic analyses (see e.g. Van Hooft et al., Reference Van Hooft, Groen and Prins2002). In Chapter 8, Prins, Ottenburghs and Van Hooft revise their opinion, and conclude that S. c. nanus is a derived form, while S. c. aequinoctialis may be closest to the ancestral form.

The first species that can be classified as Syncerus may have been Syncerus acoelotus. Geraads et al. (Reference Geraads, Blondel and Mackaye2009a) state that it was as large as the modern S. caffer but with less-advanced horns. However, because fossils are not plentiful and the remains are fragmentary, classification remains fraught with issues. Indeed, Gentry (Reference Gentry, Coppens and Howell1985) compared Shungura Member C (~2.7 Ma) Syncerus horn cores to those of Syncerus acoelotus, named from the much younger Olduvai Bed II (~1.5 Ma), but later, Gentry (Reference Gentry, Werdelin and Sanders2010) referred to them as Simatherium shungurense. Bibi et al. (Reference Bibi, Rowan and Reed2017) re-examined some of the Shungura material and state that they prefer Gentry’s (Reference Gentry, Coppens and Howell1985) opinion, so they choose to see these fossils again as Syncerus acoelotus. A possible very early find of S. caffer is from northern Sudan near Dongola; the authors were convinced it was not a Pelorovis (S.) antiquus but a true African buffalo (Chaix et al., Reference Chaix, Faure, Guerin and Honegger2000), but the age of the site is poorly supported. We are not aware of any palaeontological material that can be ascribed to some of the other existing forms of S. caffer, to wit S. c. mathewsi or S. c. brachyceros. Unless material is unearthed, one has to rely on genetic analyses to reconstruct the history of the morphological differentiation within the species. The scant sample sizes on morphology that Groves and Grubb (Reference Groves and Grubb2011, p. 122 ff.) rely on to distinguish S. brachyceros or S. mathewsi as separate species are certainly not convincing.

We mentioned earlier that phylogenies based on DNA do not take into consideration the DNA sequences of extinct species if genetic material is no longer available (see Table 2.1). So even where, for example, Bibi (Reference Bibi2013) took into account three Bubalus species (when there are five or six) into his phylogeny, he did not (and could not) include a whole suite of recently extinct species (some 10 from China: Dong et al., Reference Dong, Liu, Zhang and Xu2014) or the three species that went extinct 2–1 Myr ago (from southern Asia: Van den Bergh et al., Reference Van den Bergh, de Vos and Sondaar2001; Patnaik, Reference Patnaik, Wang, Flynn and Fortelius2013). This relative ‘blindness’ may cause an optimally parsimonious phylogeny to be an imperfect reconstruction of evolution in reality. This is no criticism of such work, to the contrary, but a call for even better integrating palaeontology with genetics (Table 2.1).

The whole group of (wild) cattle and bison combines well, but ancestors of the wild South-East Asian cattle, bison and West Asian cattle apparently speciated at one short period of time, which cannot be resolved hierarchically (MacEachern et al., Reference MacEachern, McEwan and Goddard2009). A major issue is extensive hybridization between the whole group of cattle, zebu, yak, gaur, banteng, wisent and bison. Indeed, closely related species (as established by genetic analyses) show hardly any or no barriers to cross-breeding. Species that diverged longer ago show infertility in the male offspring but none in the female offspring. Back-crosses are then very well possible, and this may explain the frequently observed introgression of genetic material in one species from another. Species that are only distantly related cannot cross-breed; in a number of cases, it has been found that in-vitro fertilization is then possible, but the embryo only survives briefly in vitro. These results are further supported by embryo transplantations of ‘normal’ embryos of one species implanted into a cow of another species.

As expected, this technique shows that embryos of Bos taurus indicus transferred to B. t. taurus cows result in fully normal parturitions (Summers et al., Reference Summers, Shelton and Edwards1983). Likewise, B. gaurus embryos have been transferred to B. taurus cows without any problems (Stover et al., Reference Stover, Evans and Dolensek1981). However, pregnancy of embryos of Bison bison that were transferred to B. taurus cows were terminated sometime between 60 and 100 days (Dorn, Reference Dorn1995). This does not mean that they are not frequently born, because they are, and are named ‘beefalo’. Sanders (Reference Sanders1925) already reported that male offspring of bison–cattle hybrids (at that time named catalo) frequently were either aborted, stillborn or died very young. Crosses between yak and cattle also often result in increased abortion (Zhang, Reference Zhang, Zhao and Zhang2000), yet the offspring that survives is valuable, because they are strong (personal observation).

Water buffalo and cattle are genetically much more distant. Indeed, the pregnancy of Bubalus bubalis embryos transferred to B. taurus cows terminated after 37 days (Drost et al., Reference Drost, Wright and Elsden1986). After in-vitro fertilization, embryos of crosses between cattle and water buffalo only survive to the blastocyst state (Kochhar et al., Reference Kochhar, Rao and Luciano2002), and to the morula state only in in-vitro fertilization of cattle with African buffalo sperm (Owiny et al., Reference Owiny, Barry, Agaba and Godke2009). Indeed, African buffalo are more distantly related to the other Bovini than to Asian buffalo.

In other words, prezygotic barriers are nearly absent between the different species of Bos and Bison, but postzygotic barriers become increasingly severe with increasing genetic (and evolutionary) distance. We deduce from this that postzygotic barriers become an overwhelming barrier between Bovini that are separated by more than 5 Myr or more, and that prezygotic barriers become an issue after a divergence of some 2 Myr. This appears to be about the same as in wild pigs (Sus; Frantz et al., Reference Frantz, Schraiber and Madsen2013), and very different from birds like ducks (Kraus et al., Reference Kraus, Kerstens and van Hooft2012) or geese (Ottenburghs et al., Reference Ottenburghs, Kraus and van Hooft2017), where postzygotic barriers do not play a (major) role against horizontal gene transfer (see also Syvanen, Reference Syvanen2012; Stewart et al., Reference Stewart, Louys, Price, Drake, Groucutt and Petraglia2019). Because the Bovini hold much interest in terms of livestock production, perhaps more is known about ‘evolution in progress’ with this species group than with nearly any other. The picture that emerges is not a simple evolutionary tree, but a system more akin to ‘reticulated evolution’ (Buntjer et al., Reference Buntjer, Otsen and Nijman2002).

Using microsatellite data, Ritz et al. (Reference Ritz, Glowatzki‐Mullis, MacHugh and Gaillard2000) put forward that some 2.5 million years ago, water buffalo and African buffalo had a common ancestor. Their data show that the genetic distance between African buffalo and species of the genus Bos appears to be equal. More recent research not using microsatellites but nuclear genome sequences suggests that the groups (Bubalus plus Syncerus) and (Bos plus Bison) split very much earlier, namely around five to nine million years ago (Bibi, Reference Bibi2013). The findings of Ritz et al. (Reference Ritz, Glowatzki‐Mullis, MacHugh and Gaillard2000) are even more difficult to understand if one realizes that a short genetic distance can point to hybridization. Hybridization between Syncerus and Bos, however, is very unlikely given the outcome of the fertilization and transplantation experiments alluded to above. An alternative explanation is that because these two genera split relatively recently, the genetic makeup is so similar because of incomplete lineage sorting (MacEachern et al., Reference MacEachern, McEwan and Goddard2009; Bibi, Reference Bibi2013).

Perhaps the true phylogenetic relationship must be derived through other techniques, as was done by Buntjer et al. (Reference Buntjer, Otsen and Nijman2002). They used amplified fragment length polymorphism (AFLP) to generate nuclear DNA fingerprints that display variation of loci dispersed over the nuclear genome of the different species. They did not use algorithms that necessitate solving a tree, and also think that a ‘consequence of reticulation is that a tree topology is not adequate for representing the phylogeny’. The Bovini thus form a prime case of ‘evolution in action’ in which there is a hugely successful group of morphologically very distinct species through which exchange of adaptive or non-adaptive genes can move within the ‘supra species’ Bos (sensu Kraus et al., Reference Kraus, Kerstens and van Hooft2012). However, the African buffalo is not part of the species swarm of cattle, gaur, zebu, banteng, yak, wisent and bison that form the Bovini. It is evolutionarily so far removed from that group of Palaearctic and Oriental Bovini that it may be thought as a single surviving species in a tribe ‘Syncerini’. Does that have any repercussions for understanding their ecology or management better? We seriously doubt this, because the amount of ecological knowledge garnered from wild Asian buffalo in their native environment is negligible. The wild Asian species is nearly extinct, and little progress has been made to reintroduce them into the wild. In other words, the African buffalo may be irreplaceable and for understanding it, one cannot plagiarize knowledge from other Bovini.

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Figure 2.1 Phylogeny of the Bovini and Syncerini. During the Pleistocene members of the genus Bos ventured into Africa too (see text). The separation between Boselaphini and Bovini or Syncerini is very unclear.

Table 2.1 Interplay between palaeontology and genetics to deduce a reliable phylogeny. The trade-off one makes between knowledge from genetics and palaeontological knowledge is not straightforward. It may upset established phylogeny, yet it may also strengthen it. If knowledge from palaeontology and genetics (if these have been reached independently) overlap, inference about the past is very strong. If there are mismatches between the two fields of enquiry, a research strategy can be formulated once one realizes the mismatch.

Figure 2.2(a) S. antiquus from I-n-Habeter, Mesāk, Libya.