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4. Kesem-Kebena-Dulecha Study Area, Ethiopia

Author

Beyin, A., Wright, D.K., Wilkins, J., Bouzouggar, A., Olszewski, D.I, Gilbert, W., H., Doronichev, V., B., Golovanova, L.V., Morgan, L.E., Nuñez, L., Rodriguez, L., Sala, N., Cusimano, D., Gaspar Simón, Ignacio de, Mazza, P., García García, Nuria, Beyin, A., Wright, D.K., Wilkins, J., Bouzouggar, A., Olszewski, D.I, Gilbert, W., H., Doronichev, V., B., Golovanova, L.V., Morgan, L.E., Nuñez, L., Rodriguez, L., Sala, N., Cusimano, D., Gaspar Simón, Ignacio de, Mazza, P., and García García, Nuria

Abstract

In 1988 and 1989, the Paleoanthropological Inventory of Ethiopia (PIE) field expedition discovered numerous localities of prehistoric significance across Ethiopia (WoldeGabriel et al., 1992). One of the regions surveyed by the Inventory team was the Dulecha administrative district (Gabi Rasu), Afar Zone (Fig. 1). The surveyed area (geographic reference: 9.407° N, 40.057° E) includes the watershed vicinity of the Kesem and Kebena Rivers (tributaries of the Awash River) where Plio-Pleistocene outcrops flank the Awash floodplain parallel to the river and west of the Dofan Volcano. The Fentale Vlcano lies SSW of the Kesem-Kebena-Dulecha area, immediately south of where the Main Ethiopian Rift opens into a floodplain, and offset drainages north of the Dulecha River delimit the area on the north. The Kesem-Kebena-Dulecha area was unknown paleoanthropologically prior to the PIE’s fieldwork, which designated localities with KK (Kesem Kebena) and a unique integer for the locality. The PIE named localities from KK 1 to KK 7, ranging in age from Pliocene (KK 1 and KK 2) through later Pleistocene. Localities are identified by the white, numbered circles on Fig. 1. We continue to follow the nomenclature established by the PIE for consistency’s sake. The most significant discovery of the PIE was the Acheulean lithic and faunal assemblages at the KK 6 locality (Table 1). The PIE took several geological samples, and those from the KK 6 area date to c. 1.0 million years ago (Ma), nearly identical in age to the Harreya Pumice Unit of the Daka Member of the Bouri Formation (Gilbert & Asfaw, 2008).

Published
2023

5. Lions and brown bears colonized North America in multiple synchronous waves of dispersal across the Bering Land Bridge

Author

Salis, AT, Bray, SCE, Lee, MSY, Heiniger, H, Barnett, R, Burns, JA, Doronichev, V, Fedje, D, Golovanova, L, Harington, CR, Hockett, B, Kosintsev, P, Lai, X, Mackie, Q, Vasiliev, S, Weinstock, J, Yamaguchi, N, Meachen, JA, Cooper, A, Mitchell, KJ, Salis, AT, Bray, SCE, Lee, MSY, Heiniger, H, Barnett, R, Burns, JA, Doronichev, V, Fedje, D, Golovanova, L, Harington, CR, Hockett, B, Kosintsev, P, Lai, X, Mackie, Q, Vasiliev, S, Weinstock, J, Yamaguchi, N, Meachen, JA, Cooper, A, and Mitchell, KJ

Abstract

The Bering Land Bridge connecting North America and Eurasia was periodically exposed and inundated by oscillating sea levels during the Pleistocene glacial cycles. This land connection allowed the intermittent dispersal of animals, including humans, between Western Beringia (far northeast Asia) and Eastern Beringia (northwest North America), changing the faunal community composition of both continents. The Pleistocene glacial cycles also had profound impacts on temperature, precipitation and vegetation, impacting faunal community structure and demography. While these palaeoenvironmental impacts have been studied in many large herbivores from Beringia (e.g., bison, mammoths, horses), the Pleistocene population dynamics of the diverse guild of carnivorans present in the region are less well understood, due to their lower abundances. In this study, we analyse mitochondrial genome data from ancient brown bears (Ursus arctos; n = 103) and lions (Panthera spp.; n = 39), two megafaunal carnivorans that dispersed into North America during the Pleistocene. Our results reveal striking synchronicity in the population dynamics of Beringian lions and brown bears, with multiple waves of dispersal across the Bering Land Bridge coinciding with glacial periods of low sea levels, as well as synchronous local extinctions in Eastern Beringia during Marine Isotope Stage 3. The evolutionary histories of these two taxa underline the crucial biogeographical role of the Bering Land Bridge in the distribution, turnover and maintenance of megafaunal populations in North America.

Published
2022

6. Early cave art and ancient DNA record the origin of European bison

Author

Soubrier, J., Gower, G., Chen, Kefei, Richards, S., Llamas, B., Mitchell, K., Ho, S., Kosintsev, P., Lee, M., Baryshnikov, G., Bollongino, R., Bover, P., Burger, J., Chivall, D., Crégut-Bonnoure, E., Decker, J., Doronichev, V., Douka, K., Fordham, D., Fontana, F., Fritz, C., Glimmerveen, J., Golovanova, L., Groves, C., Guerreschi, A., Haak, W., Higham, T., Hofman-Kamińska, E., Immel, A., Julien, M., Krause, J., Krotova, O., Langbein, F., Larson, G., Rohrlach, A., Scheu, A., Schnabel, R., Taylor, J., Tokarska, M., Tosello, G., van der Plicht, J., van Loenen, A., Vigne, J., Wooley, O., Orlando, L., Kowalczyk, R., Shapiro, S., Cooper, A., Soubrier, J., Gower, G., Chen, Kefei, Richards, S., Llamas, B., Mitchell, K., Ho, S., Kosintsev, P., Lee, M., Baryshnikov, G., Bollongino, R., Bover, P., Burger, J., Chivall, D., Crégut-Bonnoure, E., Decker, J., Doronichev, V., Douka, K., Fordham, D., Fontana, F., Fritz, C., Glimmerveen, J., Golovanova, L., Groves, C., Guerreschi, A., Haak, W., Higham, T., Hofman-Kamińska, E., Immel, A., Julien, M., Krause, J., Krotova, O., Langbein, F., Larson, G., Rohrlach, A., Scheu, A., Schnabel, R., Taylor, J., Tokarska, M., Tosello, G., van der Plicht, J., van Loenen, A., Vigne, J., Wooley, O., Orlando, L., Kowalczyk, R., Shapiro, S., and Cooper, A.

Published
2016

7. Suggested guidelines for invasive sampling of hominid remains

Author

Hublin, J. j., Paabo, S., Derevianko, A. p., Doronichev, V. b., Golovanova, L. v., Friess, M., Froment, A., Hoffmann, A., Jillani Kachache, N. e., Kullmer, O., Lordkipanidze, D., Moncel, M. h., Potts, R., Radovcic, J., Rak, Y. z., Richards, M., Mendez, J. r., Rosas, A., Schmauder, M., Schmitz, R. w., Semal, P., Smith, T., Manzi, Giorgio, Tafuri, MARY ANNE, Tattersall, I., Tournepiche, J. f., Toussaint, M., Vassiliev, S., Vialet, A., White, T., and Ziegler, R.

Subjects
Ancient DNA, Evolutionary anthropology, History, Anthropology, Paleoanthropology, Sampling (statistics), invasive sampling, hominid remains, Data science, Ecology, Evolution, Behavior and Systematics
Abstract

The last few years have witnessed remarkable technical developments in paleoanthropology. On the one hand, accurate imaging techniques have limited the need to access actual specimens. On the other hand, direct dating, isotopic studies, and the study of ancient DNA, proteins, and microstructures have experienced great technical improvements but still require a degree of invasive sampling. The power of these invasive approaches for answering important questions in evolutionary anthropology brings forward the question of how to balance preservation of fossil hominid remains for the future against the application of current scientific analyses. In order to address these issues, a workshop was hosted by the Max-Planck Institute for Evolutionary Anthropology in Leipzig on April 26– 27, 2007 where the issues that emanate from the need for sampling of hominid remains versus the need for preservation of specimens for the future were discussed. At the end of the meeting, the participants produced a set of recommendations that might be useful to museums and other institutions as well as scientists that have to make decisions on requests for invasive sampling of hominid remains.

Published
2008

10. Anatomically modern human in the Châtelperronian hominin collection from the Grotte du Renne (Arcy-sur-Cure, Northeast France).

Author

Gicqueau A, Schuh A, Henrion J, Viola B, Partiot C, Guillon M, Golovanova L, Doronichev V, Gunz P, Hublin JJ, and Maureille B

Subjects
Animals, Infant, Newborn, Humans, France, Europe, Spain, Fossils, Hominidae anatomy & histology, Neanderthals
Abstract

Around 42,000 years ago, anatomically modern humans appeared in Western Europe to the detriment of indigenous Neanderthal groups. It is during this period that new techno-cultural complexes appear, such as the Châtelperronian that extends from northern Spain to the Paris Basin. The Grotte du Renne (Arcy-sur-Cure) is a key site for discussing the biological identity of its makers. This deposit has yielded several Neanderthal human remains in its Châtelperronian levels. However, the last inventory of the paleoanthropological collection attributed to this techno-complex allowed the identification of an ilium belonging to a neonate (AR-63) whose morphology required a thorough analysis to assess its taxonomic attribution. Using geometric morphometrics, we quantified its morphology and compared it to that of 2 Neanderthals and 32 recent individuals deceased during the perinatal period to explore their morphological variation. Our results indicate a morphological distinction between the ilia of Neanderthals and anatomically modern neonates. Although AR-63 is slightly outside recent variability, it clearly differs from the Neanderthals. We propose that this is due to its belonging to an early modern human lineage whose morphology differs slightly from present-day humans. We also explore different hypotheses about the presence of this anatomically modern neonate ilium among Neanderthal remains., (© 2023. Springer Nature Limited.)

Published
2023
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11. Lions and brown bears colonized North America in multiple synchronous waves of dispersal across the Bering Land Bridge.

Author

Salis AT, Bray SCE, Lee MSY, Heiniger H, Barnett R, Burns JA, Doronichev V, Fedje D, Golovanova L, Harington CR, Hockett B, Kosintsev P, Lai X, Mackie Q, Vasiliev S, Weinstock J, Yamaguchi N, Meachen JA, Cooper A, and Mitchell KJ

Subjects
Humans, Horses genetics, Animals, Phylogeny, DNA, Mitochondrial genetics, North America, Ursidae genetics, Lions
Abstract

The Bering Land Bridge connecting North America and Eurasia was periodically exposed and inundated by oscillating sea levels during the Pleistocene glacial cycles. This land connection allowed the intermittent dispersal of animals, including humans, between Western Beringia (far northeast Asia) and Eastern Beringia (northwest North America), changing the faunal community composition of both continents. The Pleistocene glacial cycles also had profound impacts on temperature, precipitation and vegetation, impacting faunal community structure and demography. While these palaeoenvironmental impacts have been studied in many large herbivores from Beringia (e.g., bison, mammoths, horses), the Pleistocene population dynamics of the diverse guild of carnivorans present in the region are less well understood, due to their lower abundances. In this study, we analyse mitochondrial genome data from ancient brown bears (Ursus arctos; n = 103) and lions (Panthera spp.; n = 39), two megafaunal carnivorans that dispersed into North America during the Pleistocene. Our results reveal striking synchronicity in the population dynamics of Beringian lions and brown bears, with multiple waves of dispersal across the Bering Land Bridge coinciding with glacial periods of low sea levels, as well as synchronous local extinctions in Eastern Beringia during Marine Isotope Stage 3. The evolutionary histories of these two taxa underline the crucial biogeographical role of the Bering Land Bridge in the distribution, turnover and maintenance of megafaunal populations in North America., (© 2021 John Wiley & Sons Ltd.)

Published
2022
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12. Early ontogeny of humeral trabecular bone in Neandertals and recent modern humans.

Author

Chevalier T, Colard T, Colombo A, Golovanova L, Doronichev V, and Hublin JJ

Subjects
Adolescent, Animals, Child, Child, Preschool, Female, Humans, Infant, Male, Pan troglodytes, Cancellous Bone growth & development, Fossils, Humerus growth & development, Neanderthals
Abstract

Trabecular bone ontogeny is well known in modern humans and unknown in Neandertals. Yet the bone developmental pattern is useful for interpreting fossils from evolutionary and functional perspectives. Interestingly, microstructure in early ontogeny is supposedly not influenced by high and specific mechanical loading related to the lifestyle of a human group and consequently does not directly depend on the activities of hunter-gatherers. Here, we specifically explored the early growth trajectories of the trabecular bone structure of the humerus and emphasized in particular how bone fraction (bone volume/total volume [BV/TV]) was built up in Neandertals, given the specific modern human bone loss after birth and the use of BV/TV in functional studies. Six Neandertals and 26 recent modern humans ranging from perinates to adolescents were included in this study. Six trabecular parameters were measured within a cubic region of interest extracted from the proximal metaphysis of the humerus. We found that the microstructural changes in Neandertals during early ontogeny (<1 year) fit with modern human growth trajectories for each parameter. The specific bone loss occurring immediately after birth in modern humans also occurred in Neandertals (but not in chimpanzees). However, the early childhood fossil Ferrassie 6 presented unexpectedly high BV/TV, whereas the high BV/TV in the Crouzade I adolescent was predictable. These results suggest that Neandertals and modern humans shared predetermined early growth trajectories and developmental mechanisms. We assume that the close relationship between skeletal characteristics in early ontogeny and adults in modern humans also existed in Neandertals. However, it was difficult to ensure that the high BV/TV in Neandertal early childhood, represented by only one individual, was at the origin of the high BV/TV observed in adults. Consequently, our study does not challenge the mechanical hypothesis that explains the trabecular gracilization of the humerus during the Holocene., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published
2021
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13. Early development of the Neanderthal ribcage reveals a different body shape at birth compared to modern humans.

Author

García-Martínez D, Bastir M, Gómez-Olivencia A, Maureille B, Golovanova L, Doronichev V, Akazawa T, Kondo O, Ishida H, Gascho D, Zollikofer CPE, de León MP, and Heuzé Y

Abstract

Ontogenetic studies provide clues for understanding important paleobiological aspects of extinct species. When compared to that of modern humans, the adult Neanderthal thorax was shorter, deeper, and wider. This is related to the wide Neanderthal body and is consistent with their hypothetical large requirements for energy and oxygen. Whether these differences were already established at birth or appeared later during development is unknown. To delve into this question, we use virtual reconstruction tools and geometric morphometrics to recover the 3D morphology of the ribcages of four Neanderthal individuals from birth to around 3 years old: Mezmaiskaya 1, Le Moustier 2, Dederiyeh 1, and Roc de Marsal. Our results indicate that the comparatively deep and short ribcage of the Neanderthals was already present at birth, as were other skeletal species-specific traits. This morphology possibly represents the plesiomorphic condition shared with Homo erectus , and it is likely linked to large energetic requirements., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published
2020
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14. A uniquely modern human pattern of endocranial development. Insights from a new cranial reconstruction of the Neandertal newborn from Mezmaiskaya.

Author

Gunz P, Neubauer S, Golovanova L, Doronichev V, Maureille B, and Hublin JJ

Subjects
Adult, Animals, Anthropology, Physical, Brain growth & development, Computer Simulation, Cross-Sectional Studies, Humans, Imaging, Three-Dimensional, Infant, Pan troglodytes anatomy & histology, Pan troglodytes growth & development, Principal Component Analysis, Russia, Tomography, X-Ray Computed, Biological Evolution, Neanderthals anatomy & histology, Neanderthals growth & development, Skull anatomy & histology, Skull growth & development
Abstract

The globular braincase of modern humans is distinct from all fossil human species, including our closest extinct relatives, the Neandertals. Such adult shape differences must ultimately be rooted in different developmental patterns, but it is unclear at which point during ontogeny these group characteristics emerge. Here we compared internal shape changes of the braincase from birth to adulthood in Neandertals (N = 10), modern humans (N = 62), and chimpanzees (N = 62). Incomplete fossil specimens, including the two Neandertal newborns from Le Moustier 2 and Mezmaiskaya, were reconstructed using reference-based estimation methods. We used 3D geometric morphometrics to statistically compare shapes of virtual endocasts extracted from computed-tomographic scans. Throughout the analysis, we kept track of possible uncertainties due to the missing data values and small fossil sample sizes. We find that some aspects of endocranial development are shared by the three species. However, in the first year of life, modern humans depart from this presumably ancestral pattern of development. Newborn Neandertals and newborn modern humans have elongated braincases, and similar endocranial volumes. During a 'globularization-phase' modern human endocasts change to the globular shape that is characteristic for Homo sapiens. This phase of early development is unique to modern humans, and absent from chimpanzees and Neandertals. Our results support the notion that Neandertals and modern humans reach comparable adult brain sizes via different developmental pathways. The differences between these two human groups are most prominent directly after birth, a critical phase for cognitive development., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published
2012
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15. Neanderthal brain size at birth provides insights into the evolution of human life history.

Author

Ponce de León MS, Golovanova L, Doronichev V, Romanova G, Akazawa T, Kondo O, Ishida H, and Zollikofer CP

Subjects
Adult, Animals, Child, Child, Preschool, Female, Humans, Infant, Infant, Newborn, Organ Size, Parturition, Russia, Skeleton, Skull anatomy & histology, Syria, Biological Evolution, Brain anatomy & histology, Brain growth & development, Fossils, Hominidae anatomy & histology, Hominidae growth & development
Abstract

From birth to adulthood, the human brain expands by a factor of 3.3, compared with 2.5 in chimpanzees [DeSilva J and Lesnik J (2006) Chimpanzee neonatal brain size: Implications for brain growth in Homo erectus. J Hum Evol 51: 207-212]. How the required extra amount of human brain growth is achieved and what its implications are for human life history and cognitive development are still a matter of debate. Likewise, because comparative fossil evidence is scarce, when and how the modern human pattern of brain growth arose during evolution is largely unknown. Virtual reconstructions of a Neanderthal neonate from Mezmaiskaya Cave (Russia) and of two Neanderthal infant skeletons from Dederiyeh Cave (Syria) now provide new comparative insights: Neanderthal brain size at birth was similar to that in recent Homo sapiens and most likely subject to similar obstetric constraints. Neanderthal brain growth rates during early infancy were higher, however. This pattern of growth resulted in larger adult brain sizes but not in earlier completion of brain growth. Because large brains growing at high rates require large, late-maturing, mothers [Leigh SR and Blomquist GE (2007) in Campbell CJ et al. Primates in perspective; pp 396-407], it is likely that Neanderthal life history was similarly slow, or even slower-paced, than in recent H. sapiens.

Published
2008
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16. ESR dating at Mezmaiskaya Cave, Russia.

Author

Skinner AR, Blackwell BA, Martin S, Ortega A, Blickstein JI, Golovanova LV, and Doronichev VB

Subjects
Age Determination by Skeleton methods, Age Determination by Teeth methods, Animals, Archaeology, Dental Enamel chemistry, Dentin chemistry, Humans, Infant, Russia, Skeleton, Skull chemistry, Electron Spin Resonance Spectroscopy methods, Fossils, Hominidae, Paleontology methods
Abstract

Mezmaiskaya Cave has yielded more than 10,000 artifacts, thousands of very well preserved faunal remains, and hominin remains, found in seven Middle Paleolithic (Mousterian) and three Upper Paleolithic levels. A complete Neanderthal infant skeleton was preserved in anatomical juxtaposition lying on a large limestone block, overlain by the earliest Mousterian layer, Layer 3. Twenty-four skull fragments from a 1-2 year-old Neanderthal infant, showing post-mortem deformation, occurred in a pit originating in the Mousterian Layer 2 and penetrating into underlying layers 2A and 2B(1). Bone from Layer 2A was dated by AMS 14C at 35.8-36.3+/-0.5 kyr BP. Direct dating of Neanderthal bone from Layer 3 gave an age of 29 kyr, but that is now considered to be due to contamination by modern carbon. Fourteen large mammal teeth from Layers 2 through 3 have been dated by standard electron spin resonance (ESR). Low U concentrations in both the enamel and dentine ensure that ESR ages do not depend significantly on the U uptake model, but do depend strongly on the sedimentary dose rates. Assuming a sedimentary water concentration equal to 20 wt%, ESR ages for the Mousterian layers range from 36.2 to 73.0+/-5.0 ka.

Published
2005
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