New fossils of Australopithecus sediba reveal a nearly complete lower back

Williams, Scott A.; Prang, Thomas C.; Meyer, Marc R.; Nalley, Thierra K; Merwe, Renier Van Der; Yelverton, Christopher; García‐Martínez, Daniel; Russo, Gabrielle A.; Ostrofsky, Kelly R.; Spear, Jeffrey K.; Eyre, Jennifer; Grabowski, Mark; Nalla, Shahed; Bastir, Markus; Schmid, Peter; Churchill, Steven E.; Berger, Lee R.

doi:10.7554/elife.70447

Cited by 10 publications

(7 citation statements)

References 62 publications

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“…Baatstrup disease) in Shaindar 3 ( 50 ) and La Chapelle-aux-Saints 1 ( 23 ) further suggest that Neandertals demonstrated lumbar lordosis. Finally, given that sexual dimorphism in lumbar wedging is present in modern humans and potentially also in Australopithecus ( 10 , 11 ), female Neandertals would be expected to demonstrate more dorsal (lordotic) wedging than the inferred male individuals included in this study.…”

Section: Discussionmentioning

confidence: 99%

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Inferring lumbar lordosis in Neandertals and other hominins

et al. 2022

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Lumbar lordosis is a key adaptation to bipedal locomotion in the human lineage. Dorsoventral spinal curvatures enable the body's center of mass to be positioned above the hip, knee, and ankle joints, and minimize the muscular effort required for postural control and locomotion. Previous studies have suggested that Neandertals had less lordotic (ventrally convex) lumbar columns than modern humans, which contributed to historical perceptions of postural and locomotor differences between the two groups. Quantifying lower back curvature in extinct hominins is entirely reliant upon bony correlates of overall lordosis, since the latter is significantly influenced by soft tissue structures (e.g. intervertebral discs). Here, we investigate sexual dimorphism, ancestry, and lifestyle effects on lumbar vertebral body wedging and inferior articular facet angulation, two features previously shown to be significantly correlated with overall lordosis in living individuals, in a large sample of modern humans and Neandertals. Our results demonstrate significant differences between postindustrial cadaveric remains and archaeological samples of people that lived preindustrial lifestyles. We suggest these differences are related to activity and other aspects of lifestyle rather than innate population (ancestry) differences. Neandertal bony correlates of lumbar lordosis are significantly different from all human samples except preindustrial males. Therefore, although Neandertals demonstrate more bony kyphotic wedging than most modern humans, we cast doubt on proposed locomotor and postural differences between the two lineages based on inferred lumbar lordosis (or lack thereof), and we recommend future research compare fossils to modern humans from varied populations and not just recent, postindustrial samples.

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Section: Discussionmentioning

confidence: 99%

“…Outside of H. sapiens , other hominin species are also thought to have been characterized by lumbar lordosis, inferred necessarily from fossilized remains ( 5 , 10 , 11 , 19 , 20 ). Interestingly, the presence of lumbar lordosis in one of our closest relatives, Neandertals, is debated.…”

Section: Introductionmentioning

confidence: 99%

Inferring lumbar lordosis in Neandertals and other hominins

et al. 2022

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“…88‐232‐234/153, U.W. 88‐126/138 ( A. sediba ) (Williams et al, 2021), SK 3981b ( Paranthropus robustus or early Homo ), A.L. 288‐1aa, A.L.…”

Section: Methodsmentioning

confidence: 99%

“…Hominins evolved lumbar lordosis, or dorsal concavity of the lower lumbar column, as an adaptation to bipedalism at some point relatively early in their evolutionary history (Been et al, 2012; Latimer & Ward, 1993; Whitcome et al, 2007; Williams et al, 2013; Williams et al, 2021). Lumbar lordosis allows an upright biped to efficiently balance the upper body over the hip joints and lower limbs.…”

Section: Introductionmentioning

confidence: 99%

Homo naledi lumbar vertebrae and a new 3D method to quantify vertebral wedging

Williams

Zeng

Guerra

et al. 2022

American Journal of Biological Anthropology

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Objectives: In humans and known fossil hominins, lumbar lordosis is produced by vertebral body wedging and other bony and soft tissue features such as the shape of the intervertebral discs. Current techniques for quantifying the wedging of vertebral bodies are limited in utility, especially when analyzing incomplete fossil material.Here, we introduce a 3D method to quantify vertebral body wedging angles that yields the angles between two "best fit" planes in the software GeoMagic Wrap (3D Systems). Materials and Methods:To test that this new method is repeatable with existing methods, we measure the wedging of 320 lumbar vertebrae representing 64 modern human individuals. For each vertebra, wedging angles were calculated from linear measurements taken with calipers and compared with estimates generated from the 3D best fit plane method. We also apply the 3D plane method to fossil hominin lumbar vertebrae, including newly described lumbar vertebrae of Homo naledi, the majority of which do not preserve the four landmarks necessary to calculate wedging angles using the traditional approach.Results: The results of the two methods are highly and significantly correlated (r 2 = 0.98, p < 0.0001). The 3D plane method was successfully applied to nearly all of the fossil hominin specimens included in the study.Discussion: The new 3D plane method introduced here is repeatable with the traditional linear measurement method and allows for the estimation of wedging angles in incomplete material. When applied to Homo naledi lumbar vertebrae, similarities to other fossil hominins and modern humans are found.

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“…It is also possible that early hominins retained knuckle‐walking features, either as part of an active locomotor repertoire that potentially also included facultative bipedalism, or as primitive retentions. Indeed, hominins seem to have retained adaptations to arboreality for several million years (Stern & Susman, 1983; Susman et al, 1984; Lovejoy, Latimer, et al 2009; Lovejoy, Simpson, et al 2009; Lovejoy, Suwa, Simpson, et al 2009; Lovejoy, Suwa, Spurlock, et al 2009; White, Asfaw, et al, 2009; White et al, 2015; Rein et al, 2017; Dunmore et al, 2020; Georgiou et al, 2020; Prabhat et al, 2021; Prang et al, 2021; Williams et al, 2021).…”

Section: Evolutionary Rates and The Pancestormentioning

confidence: 99%