Western gorilla diet: A synthesis from six sites

Rogers, Michael E.; Abernethy, Katharine; Bermejo, Magdalena; Cipolletta, Chloé; Doran, Diane; McFarland, Kelley; Nishihara, Taishi; Remis, Melissa J.; Tutin, Caroline E. G.

doi:10.1002/ajp.20071

Cited by 268 publications

(251 citation statements)

References 50 publications

(122 reference statements)

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“…That is, seasonal shifts in their habitat forces them to rely mainly on fibrous fruits, leaves and herbaceous vegetation during the low ripe fruit season (Masi et al, 2009). These fibrous foods are low in readily digestible energy, higher in hemicellulose, cellulose and lignin than ripe fruit (Remis, 1997a,b,c Remis et al, 2001Rogers et al, 2004Rogers et al, ,1990Rothman et al, 2014), although in times of fruit scarcity fruits eaten are high in fiber and similar to vegetation (Remis et al, 2001). Thus, it is likely that bio-geographical and ecological factors across evolutionary timescales triggered both diversification of Gorilla spp., and the acquisition of distinct gut bacterial communities in mountain and lowland gorillas (Ley et al, 2008;Collins and Dubach, 2000;Gomez and Verdu, 2012;Sussman, 1991).…”

Section: Discussionmentioning

confidence: 99%

“…(Remis, 1997a;Doran and McNeilage, 1998). In contrast, the fragmented distribution of fruit and the higher nutritional diversity of fruit substrates expand foraging options in gorilla groups, causing individuals within groups to consume more diverse diets when fruit is available (Masi et al, 2009;Rogers et al, 2004). This is an interesting example of how macroecological patterns may be also reflected at microecological scales.…”

Section: Discussionmentioning

confidence: 99%

“…Study site, subjects and sample collection Western lowland gorilla (G.g.gorilla) fecal samples were collected near two research sites, Bai Hokou November and December usually correspond to periods of low fruit availability, whereas high fruit consumption takes place from May to July (Masi, 2007;Remis, 1997b;Masi et al, 2012;Rogers et al, 2004). Thus, September corresponds to a transition period between low and high fruit consumption.…”

Section: Methodsmentioning

confidence: 99%

“…G. g. gorilla experience marked shifts in the availability of preferred resources yearlong (Rogers et al, 2004); they spend about 80% of their time consuming readily digestible fruit when seasonally available, but shift to a similar percent of time feeding on vegetation (terrestrial herbs and leaves) in drier periods of the year (Masi, 2007;Masi et al, 2009), while also incorporating fibrous fruit and bark (Remis, 1997b).…”

Section: Introductionmentioning

confidence: 99%

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Temporal variation selects for diet–microbe co-metabolic traits in the gut of Gorilla spp

et al. 2015

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Although the critical role that our gastrointestinal microbes play in host physiology is now well established, we know little about the factors that influenced the evolution of primate gut microbiomes. To further understand current gut microbiome configurations and diet-microbe co-metabolic fingerprints in primates, from an evolutionary perspective, we characterized fecal bacterial communities and metabolomic profiles in 228 fecal samples of lowland and mountain gorillas (G. g. gorilla and G. b. beringei, respectively), our closest evolutionary relatives after chimpanzees. Our results demonstrate that the gut microbiomes and metabolomes of these two species exhibit significantly different patterns. This is supported by increased abundance of metabolites and bacterial taxa associated with fiber metabolism in mountain gorillas, and enrichment of markers associated with simple sugar, lipid and sterol turnover in the lowland species. However, longitudinal sampling shows that both species' microbiomes and metabolomes converge when hosts face similar dietary constraints, associated with low fruit availability in their habitats. By showing differences and convergence of diet-microbe co-metabolic fingerprints in two geographically isolated primate species, under specific dietary stimuli, we suggest that dietary constraints triggered during their adaptive radiation were potential factors behind the species-specific microbiome patterns observed in primates today.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Temporal variation selects for diet–microbe co-metabolic traits in the gut of Gorilla spp

et al. 2015

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“…Gorillas range throughout their habitat foraging on vegetation and insects near the forest floor (Tutin et al, 1991;Cipolletta et al, 2007). However, when seeking preferred foods, they may travel distances to swampy areas for aquatic herbs or widely dispersed fruit sources on the ground (Nishihara, 1995;Yamagiwa et al, 1996;Remis, 1997b;Goldsmith, 1999;Rogers et al, 2004). When succulent fruits are seasonally available, their day ranges increase by several times such that their mean day journey lengths approach 3 km, similar to those of the more persistently frugivorous chimpanzees (Tutin and Fernandez, 1993;Yamagiwa et al, 1996;Remis, 1997a,b).…”

Section: Divergent Anatomies and Evolutionary Historiesmentioning

confidence: 99%

Functional Anatomy and Adaptation of Male Gorillas (Gorilla gorilla gorilla) With Comparison to Male Orangutans (Pongo pygmaeus)

Zihlman

McFarland

Underwood

2011

The Anatomical Record

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Great apes diversified during the Miocene in Old World forests. Two lineages, gorillas in Africa and orangutans in Asia, have sexual dimorphisms of super-sized males, though they presumably diverged from a smaller common ancestor. We test the hypothesis that they increased in body mass independently and convergently, and that their many postcranial differences reflect locomotor differences. Whole body dissections of five adult male gorillas and four adult male orangutans allowed quantification of body mass distribution to limb segments, of body composition (muscle, bone, skin, and fat relative to total body mass), and of muscle distribution and proportions. Results demonstrate that gorilla forelimb anatomy accommodates shoulder joint mobility for vertical climbing and reaching while maintaining joint stability during quadrupedal locomotion. The heavily muscled hind limbs are equipped for propulsion and weight-bearing over relatively stable substrates on the forest floor. In contrast, orangutan forelimb length, muscle mass, and joint construction are modified for strength and mobility in climbing, bridging, and traveling over flexible supports through the forest canopy. Muscles of hip, knee, and ankle joints provide rotational and prehensile strength essential for moving on unstable and discontinuous branches. We conclude that anatomical similarities are due to common ancestry and that differences in postcranial anatomy reflect powerful selection for divergent locomotor adaptations. These data further support the evolutionary conclusion that gorillas fall with chimpanzees and humans as part of the African hominoid radiation; orangutans are a specialized outlier. Anat Rec, 294:1842Rec, 294: -1855Rec, 294: , 2011. V V C 2011 Wiley-Liss, Inc.

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The Case for Exploitation of Wetlands Environments and Foods by Pre‐Sapiens Hominins

Stewart

2010

Human Brain Evolution

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Western gorilla diet: A synthesis from six sites

Cited by 268 publications

References 50 publications

Temporal variation selects for diet–microbe co-metabolic traits in the gut of Gorilla spp

Temporal variation selects for diet–microbe co-metabolic traits in the gut of Gorilla spp

Functional Anatomy and Adaptation of Male Gorillas (Gorilla gorilla gorilla) With Comparison to Male Orangutans (Pongo pygmaeus)

The Case for Exploitation of Wetlands Environments and Foods by Pre‐Sapiens Hominins

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