Ethical statement

Sample collection was exclusively non-invasive and complied with the laws of Ethiopia and Germany and with the guidelines of the International Primatological Society. During sampling of faecal material, no animals were harmed or disturbed.

Sample collection

During nationwide surveys of gelada distribution and abundance between 2014 and 2016 [42] (S1 File), we non-invasively collected 174 faecal samples from wild geladas. Fresh samples were collected less than ten minutes after geladas defecated, thus minimising the risk of repeated sampling from the same individuals. Geographic coordinates of each sample were assigned at the time of collection by GPS (Fig 1, S1 Table), in addition to consecutive number, date, and broad location. Faecal samples were collected and stored following the two-step protocol of [43] and [44]. Samples were stored at ambient temperature for up to three months in the field and at -20°C upon arrival in the laboratory of the German Primate Center (DPZ).

The Ethiopian Wildlife Conservation Authority, and government officials in the following provinces/regions: North and South Shoa, North Gondar, North and South Wollo Zones, and Oromia and Tigray Regions, North Shewa Zone provided permissions to conduct this research.

DNA extraction, sequencing

We extracted total genomic DNA using the First DNA All Tissue Kit (Gen-Ial) according to the manufacturers’ protocols, with minor modifications as outlined in [45]. After extraction, DNA concentration was measured with a NanoDrop ND-1000 spectrophotometer (Peqlab) and extracts were stored at -20°C until further processing. We amplified and sequenced a ~1800 bp-long fragment of the mitochondrial genome, spanning the complete cytochrome b gene (cytb), the tRNA genes for Threonine (tRNA-Thr) and Prolin (tRNA-Pro), as well as 462 bp of the HVI region of the D-loop, via three over-lapping PCR products to ensure that sequences were obtained even if DNA was degraded. PCR products with sizes of 604–831 bp were amplified with primers 5’-AACCATCGTTGTATTTCAAC-3’ and 5’-CGTGTAGGAATAGTAAGTG-3’, 5’-AACCTCGTCCAATGAGTC-3’ and 5’-TAAAATATAATACAGATGCTAC-3’, and 5’-CAAAGCATGATATTCCGC-3’ and 5’-GAGGTAAGAACCAGATGCCG-3’. Primers were designed on the basis of available mitochondrial genome sequences from geladas. PCR reactions were carried out in a total volume of 30 μl containing 1 U Biotherm DNA Taq polymerase (Genecraft), 1x reaction buffer, 0.16 mM of each dNTP, 0.33 μM of each primer, 0.6 mg/ml BSA and ~100 ng genomic DNA. Thermo cycling conditions comprised of 94°C for 2 min, followed by 40–50 cycles of 94°C for 1 min, 54°C for 1 min and 72°C for 1 min, followed by 72°C for 5 min. We checked PCR performance on 1% agarose gels and excised PCR products with correct size from the gel. After purification with the QIAquick Gel Extraction Kit (Qiagen), PCR products were Sanger-sequenced on an ABI 3130xL sequencer (Applied Biosystems) using the BigDye Terminator 3.1 Cycle Sequencing kit (Applied Biosystems) and the amplification primers. To avoid and check for cross-sample contamination, all working steps were carried out in separate laboratories under routine precautions. Appropriate negative controls were included into all assays and 10% of randomly selected samples were re-analysed.

Obtained sequence electropherograms were checked with 4Peaks 1.8 (nucleobytes.com/4peaks/) and sequences were assembled in SeaView 4.5.4 [46]. SeaView was also used to verify correct translation of nucleotide sequences of the protein-coding cytb gene into corresponding amino acid sequences. Sequences have been deposited in GenBank (for accession numbers see S1 Table).

Data analyses

For phylogenetic reconstructions, we used all unique gelada haplotypes that were obtained from this study and added orthologous baboon sequences from GenBank (S1 Table). The alignment comprising 71 sequences (61 gelada and 10 baboon sequences) was generated with Muscle 3.8.31 [47] as implemented in SeaView and corrected by eye. After indels and poorly aligned positions have been removed with Gblocks 0.91b [48] using standard settings, the original alignment with 1739 bp in length was reduced to 1730 bp.

For phylogenetic tree reconstruction in IQ-Tree 1.5.2 [49] and MrBayes 3.2.6 [50], we divided the dataset into two partitions, protein-coding and non-protein-coding (1–1140, 1141–1730). For both partitions, the best-fit model of sequence evolution was determined with ModelFinder [51,52] in IQ-Tree under the Bayesian Information Criterion (BIC). The HKY+G and TPM2u+I+G models were chosen for the protein-coding and non-protein-coding partition, respectively. The maximum-likelihood (ML) tree was reconstructed in IQ-Tree with 10,000 ultrafast bootstrap (BS) replicates [53] (S1 Fig), while the Bayesian tree was obtained from a Markov Chain Monte Carlo (MCMC) run with 10 million generations, sampling every 1000 generations, in MrBayes (S2 Fig). We checked convergence of all parameters and the adequacy of a 25% burn-in by assessing the uncorrected potential scale reduction factor (PSRF) [54], as calculated by MrBayes. Posterior probabilities (PP) for nodes and a phylogram with mean branch lengths were calculated from the posterior density of trees using MrBayes. Phylogenetic trees were visualized in FigTree 1.4.2 (http://tree.bio.ed.ac.uk/software/figtree/).

We estimated divergence times using a Bayesian approach implemented in the BEAST 2.4.7 package [55]. We performed two independent analyses each with 25 million generations and tree and parameter sampling occurring every 1000 generations. For all analyses, we assumed a relaxed lognormal clock model and applied a Coalescent Constant Population prior for branching rates. Both partitions were treated separately with their respective best-fit models. To calibrate the molecular clock, we applied an exponential prior for the split between Theropithecus and Papio with an offset of 4.0 and a mean of 1.0, translating into a median of 4.69 million years ago (Ma) and a 95% highest probability density (HPD) of 4.03–7.69 Ma. The calibration point relies on the oldest known Theropithecus fossils with an age of ca. 4 million years [12,56], suggesting that at this time Theropithecus was already established and, thus, separated from Papio. The adequacy of a 10% burn-in and convergence of all parameters was assessed by inspecting the trace of the parameters across generations using Tracer 1.6 (http://beast.bio.ed.ac.uk/Tracer). Sampling distributions of independent runs were combined with LogCombiner 2.4.2, and trees with mean node heights were summarized with TreeAnnotator 2.4.2 using a burn-in of 10%. Trees were visualized in FigTree.

For the following analyses we used the complete gelada dataset with 162 sequences, all with 1733 bp in length. To further trace phylogenetic relatedness among gelada haplotypes, we built a haplotype network in POPART 1.7 [57] using the median-joining network algorithm [58]. To check for the most likely number of clades in the dataset, we applied Automatic Barcode Gap Discovery (ABGD) [59] and AMOVA in Arlequin 3.5.2.2 [60]. For the ABGD analyses, we used Jukes-Cantor (JC), Kimura 2-parameter (K2P) and simple distance metrics as well as different relative gap widths (X = 1.0, X = 1.5), with the other parameters at default values. For the AMOVA analysis, obtained values were statistically assessed using Akaike Information Criterion (AIC) and BIC. Haplotype and nucleotide diversities were calculated for the global dataset, for southern, northern, and central populations as well as for each of the five major clades (central-1, central-2, south, north-1, north-2) with DnaSP 5 [61].

To explore the demographic history of the three main populations, we calculated Tajima’s D [62] and Fu’s F_S [63] as implemented in DnaSP 5 [61]. Under the assumption of neutrality, positive D and F_S values suggest population contraction, whereas negative values suggest population expansion. Tajima’s D is considered more powerful at detecting older and steeper population declines, whereas Fu’s F_S is more sensitive in detecting more recent and shallow population contraction [64]. To further infer the demographic history of gelada populations, we assessed effective population size changes using the Bayesian Skyline Plot (BSP) method [65] as implemented in BEAST. We generated BSPs for the global population as well as for the three geographic populations (south, north, central). As substitution models, we applied the best-fit models for each dataset and partition as chosen by jModeltest 2.1.10 [66,67] (S2 Table). The analyses were performed under a strict clock model with a coalescent Bayesian Skyline prior and a substitution rate of 3.545 x 10⁻⁸ substitutions/site/year as determined from the divergence time calculation (see above). For each dataset, we ran two independent analyses with 25 million generations, sampling every 1000 generations and a burn-in of 10%. The results of each run were checked to ensure convergence and stationarity using Tracer. The estimated effective population size was given as N_e multiplied by generation time. To get the effective population size, we divided the values by a generation time of 10 years, which is similar to those in drills (Mandrillus leucophaeus; 10–12 years, [68]) or rhesus macaques (Macaca mulatta; 11 years, [69]).

Phylogeny

Our study revealed five major mtDNA clades that correspond to three distribution ranges defined as northern, central, and southern; and hence suggest a demic pattern. Results of our study are largely in agreement with [30]. However, as expected from our extended geographical sampling and application of considerably more genetic information, our results provide higher phylogenetic and geographical resolutions.

Our south clade corresponds to the Arsi region clade of Shotake et al. [30]. In contrast to [30], we found further differentiation of the northern and central populations into two clades each. The respective two north clades correspond to Shotake’s “Simien Mountains” clade. These clades do not exhibit a clear demic pattern with haplotypes of both clades occurring within the Simien Mountains. The deep divergence among the north clades is interesting because there is at least one historical report of a second gelada taxon from the region of the Simien Mountains, Theropithecus gelada senex Pucheran, 1857. The type specimen was collected by the German botanist W.G. Schimper near Noari, east of Ras Dashen in the Simien Mountains [72]. T. g. senex was later classified as a synonym of T. g. gelada. However, if there have been historically two morphologically different gelada taxa, which came into secondary contact with subsequent genetic exchange, the contemporary Simien gelada population might still possess genetic signals of the two taxa. This would explain why different morphotypes might appear from time to time and could have been classified (at least in one case) as a second taxon, T. g. senex. An alternative explanation for the occurrence of the “senex” morphotype in the Noari region could be hybridization among T. g. gelada and T. g. obscurus. An indication for a hybrid origin of the “senex” type could be the occurrence of a central clade haplotype (T. g. obscurus) in the range of the north clade (T. g. gelada). The respective sample was collected in the Noari region, close to the type locality of “senex”. A genetic analysis of the type series of “senex” stored in the Strasbourg Natural History Museum would probably help to shed some light on the phylogenetic relationship of this presumed taxon.

Whether one of the northern lineages was historically also present in Tigray and Eritrea is not clear because geladas have most likely been exterminated from their former northern range (Tigray: AA, RB pers. comm.; Eritrea DZ pers. comm.). However, survey effort in Tigray has been relatively minimal, so it cannot be ruled out that small isolated populations still exist.

Our two central clades correspond largely to Shotake’s “Blue Nile river basin” clade. Similar to our two north clades, the central clades show geographical admixture, with a tendency for central-2 clade occurring mainly in the northwest of the central range. In addition to [30], we discovered that the central clades extend north across the Bashilo River into the area of Mt. Abuna Yosef. Given the reported high phenotypic diversity known among “obscurus” [29], it would be worthwhile to further investigate whether parts of the phenotypic variation can be explained by haplogroup membership.

In general, we found genetic diversity distributed into three demes with one exception. One sample with a central haplotype (h60) was found within the geographic range of the northern haplotypes, east of the Simien Mountains but west of the Tekeze River. Identical haplotypes have been found at least 350 km south. With the currently available information, we can only speculate about possible causes for this geographical mismatch. It can be a relict of a former partly overlapping distribution of the central and north clades, or it is possible that humans have transferred single individuals from one area to another. It is known at least for infant baboons in Eritrea that they are kept as pets and transported over large distances, where they are occasionally released into wild populations (pers. observation DZ).

Although the five clades are well supported, their branching pattern is not well-resolved (S1 and S2 Figs). However, our phylogenetic reconstruction does also not suggest clade relationships that correspond to their respective parapatric provenances, i.e., northern haplotypes are probably more closely related to the distant southern haplotypes instead of the geographically closer central haplotypes. Similarly, Shotake et al. [30] detected a closer relationship of the two geographically most-distant clades (Arsi and Simien) than either of the two to the geographically closer “Blue Nile river basin” clade. The unresolved phylogenetic relationships among our five clades also prevent further phylogeographic analyses, such as reconstruction of ancestral areas.

According to our divergence time estimations, the first split between the southern + northern and central lineages occurred around 0.67 Ma and the divergence into the five major mtDNA lineages was completed around 0.43 Ma. Our estimated divergence ages are slightly older than those reported by [30], who estimated the first split around 0.4 Ma, although the lower limits of our estimated HPDs are in a similar range (S5 Table). Compared to the divergences of the main mtDNA lineages in Papio, divergence ages within geladas are relatively recent (Fig 2). On the other hand, the relatively deep divergence ages among the respective north and central clades suggest that they experienced a period of geographic isolation and independent evolutionary history before they merged again geographically. Our divergence age estimates suggest that the split of the main five gelada mtDNA lineages was not caused by climate changes during the last three or four glacial cycles. These periods are younger than our estimates (< 500,000 years [73]).

Taxonomic implications

The taxonomy of geladas is disputed [29,30,74], and our results contribute only marginally to its resolution. Based on the biogeographical patterns, genetic differences, and divergence times, Shotake et al. [30] suggest a subspecific (if not specific) rank for the three main populations. In contrast, our results do not support a taxon delineation based on mtDNA information. With the exception of the south clade, there is incomplete geographic segregation between the respective two north and two central clades. Furthermore, one should be cautious using the similarity of divergence ages between Ethiopian Papio anubis and Papio hamadryas on the one hand, and those of the central and north gelada clades on the other hand, as an argument for subspecific status of the two gelada populations, as suggested by [30]. In Papio, mtDNA markers were unable to resolve the taxonomy because of hybridization and introgression [70,71,75,76]. Since P. anubis most likely introgressed P. hamadryas populations of Eritrea and Ethiopia, they carry mitochondria derived from P. hamadryas. In fact, the divergence age between the mtDNA lineages of the two Ethiopian baboon species refers to an intra-taxon–not an inter-taxon–divergence and, thus, is not suitable to be used as a means to delimit subspecies. In many cases, mtDNA markers alone are sufficient to detect cryptic species and to delimit taxonomic groups, but in other cases, this is not possible [3]. However, given the particular biogeographical and phylogenetic position of the southern population, an allocation to the subspecies T. g. arsi is indicated, but more genetic (nuclear markers, e.g. microsatellites, single nucleotide polymorphisms, or whole genomes) and morphological information are necessary for a proper internal taxonomic revision of Theropithecus.

Genetic diversity and conservation

As reported by [30] and also found in our study, intraspecific genetic variation is generally low in geladas. In particular, the southern population seems to be genetically impoverished, which might be an effect of the overall small population size in combination with genetic drift or a population bottleneck. Haplotype diversity is comparable to estimates found in Rhinopithecus although nucleotide diversity in geladas is smaller than in this Asian colobine genus [77]. Compared to African hamadryas baboons (P. hamadryas; [78], genetic diversity in geladas is significantly lower (n = 149; haplotype diversity: h ± SD = 0.983 ± 0.003, p < 0.001; nucleotide diversity: π ± SD = 0.04251 ± 0.00088, p < 0.001).

The relatively low genetic diversity, in the southern population in particular, at first, might tempt conservation managers to increase genetic diversity by translocation of extra-demic geladas. However, such genetic rescue by translocation should be avoided here, since the preservation of the different evolutionary lineages of geladas will be undermined and any local adaptation would likely be lost, with possible negative consequences for survival in this marginal habitat [79–81]. The low genetic diversity of the southern population translates into an extremely low female effective population size (Fig 4). Female effective population sizes of the central and northern populations are considerable higher, however, they experienced a sharp decrease after the last glacial maximum.

The combination of relatively low genetic diversity and the apparent extirpation of several local populations over the last century, a trend that is suspected or confirmed in another endemic species to the Afromontane region–the endangered Ethiopian Wolf Canis simiensis [82]–supports the urgent need for conservation action of at least the southern gelada population and its ecosystem in general. The Afro-alpine grasslands in Ethiopia, on which geladas and other endemic species depend, is not only threatened by anthropogenic habitat alteration, but will most likely also shrink as a result of global warming [83,84]. At the very least and as a first step towards effective conservation of geladas, their three main demes should be regarded as independent conservation management units.