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paleoanthropology, genetics and evolution

body size

  • Stature estimates for Sima de los Huesos

    Tue, 2012-01-10 00:44 -- John Hawks

    José-Miguel Carretero and colleagues [1] report on the lengths of long bones from Sima de los Huesos, Spain. I've long been hoping this research would come out, because we've gotten interested in the pattern of body size as an aspect of evolution in early Homo.

    Sima de los Huesos is the single largest sample of fossil Homo, and Carretero and colleagues include 27 mostly complete long bones in their sample. That's around a dozen fewer than the entire sample of Neandertal long bones. This one site has more long bones than the rest of the Early and Middle Pleistocene combined.

    Here are the tibiae, for example:

    Tibiae from Sima de los Huesos

    Complete tibiae from Sima de los Huesos, from Carretero et al. [1], figure 2.

    The paper shows that the Sima hominins averaged a bit taller than Neandertals for most of the long bones.

    That conclusion isn't quite as simple as it might look, because the sample of male Neandertal femora actually average 3 mm longer than the Sima de los Huesos femora. Both samples have more than double the number of males as females, so the male comparison draws on a much larger sample size. The Neandertal male femoral sample is biased a bit high by the inclusion of both left and right femora from Amud, the tallest of the Neandertal skeletons. The tibia sample gives a substantially shorter stature for Neandertal males, both because Amud isn't there, and because the limb proportions of Neandertals have short tibiae relative to their femora.

    That's the problem of using stature estimates instead of simple bone lengths: Nothing's simple. Fossil samples impose some limits on the kind of analyses we can undertake. Carretero and colleagues address stature both because of its biological relevance and because estimating stature is the most reasonable way we can incorporate different long bones into a single size comparison. But considering stature introduces some problems of estimation. We can't be sure how many individuals are represented by the long bones. We can determine a minimum: Six right tibiae came from a minimum of six bodies, for example. But if two arm bones and a leg bone all came from the same skeleton, that individual will be represented three times within this sample, and we don't have a way to exclude that possibility. Worse, estimating stature requires a regression drawn from some population, but that population may have different proportions than the fossils. In this case, Neandertals and the Sima de los Huesos samples probably have different crural indices, the ratio of the length of the tibia to the length of the femur. So statures estimated from these bone lengths based on some recent human population will have systematic biases due to the different proportions in the fossil populations.

    Carretero and colleagues note that most of the bones (humerus, radius, tibia) have shorter average statures in the Neandertal sample compared to the Sima de los Huesos sample. The femora and ulnae are longer in the male Neandertals. All the bones that can be compared are shorter in the female Neandertals than the female Sima de los Huesos individuals. It's probably a good bet that the Sima people were a bit taller than Neandertals. Still, the tall West Asian Amud skeleton points to the possibility of variation among Neandertals from different regions.

    The differences between Neandertals and the Sima de los Huesos sample are quite small compared to the much taller statures attributed to modern humans from West Asia (Skhul and Qafzeh). These skeletons are more ancient than most of the Neandertal sample, but at 100,000 years old, much later than the other skeletal samples included in the paper including Sima de los Huesos. The authors make a strong point of this, suggesting that tall stature is a fundamentally new feature of the evolution of modern humans (which they equate with "early H. sapiens"):

    As we have shown here, ‘medium height’ and ‘above-medium height’ people seem to characterize the primitive Homo biotype, while a ‘very tall’ body characterizes the derived biotype. The heights proposed for all fossil human species, except early H. sapiens, seem to average around 165–170 cm, although tall individuals exist within all samples (e.g., Amud 1, Kabwe and Jinniushan). It is only the first H. sapiens that are consistently and dramatically taller. Therefore, the evolution of stature (and perhaps also body size and shape) in humans seems to have been characterized by a long period of stasis during which the primitive body plan shared by the different Homo species varied rather little in stature throughout the Pleistocene, until the rapid appearance 200 ka of a new species with a new biotype, the ‘light’ H. sapiens.

    The paper's broad assertion is that Early and Middle Pleistocene humans everywhere in the world shared the same basic body plan, with stature around 165-170 cm (for males) and relatively broad pelves. The reference to modern humans as "light" concerns the relatively narrower pelvis of recent humans.

    I have no disagreement about the issue of pelvic breadth, although it deserves a separate review. But the stature of the Skhul-Qafzeh sample is neither very extreme nor is it typical of other Late Pleistocene or Holocene modern human samples. I will reprint a quote from my 2007 post about the statures of the Dmanisi hominins ("News flash: Dmanisi hominids were not short"):

    Pretty and colleagues (1998) studied an archaeological sample of Aboriginal Australians from the Murray River region. Using stature estimation methods for the tibia, femur and humerus, they found that males in their sample (n=55) had an average stature of 166 cm and females (n=40) an average of around 153 cm. Wells (1952) reported a mean for !Khu (Northern Bushmen) males of 158 cm and females of 148 cm, both with standard deviations around 5 cm. Ruff (2000) puts the average stature of males at Pecos Pueblo at 161.2 cm with a range from 155 to 168 cm. In the KNM-WT 15000 monograph, Ruff and Walker (1993) report the average stature of African population samples, excluding Pygmies, as 162.3 cm. And although it is common knowledge that the Early Upper Paleolithic people of Europe were tall, the average male stature in the Late Upper Paleolithic was around 166 cm, and the average female stature around 153 cm (Formicola and Giannecchini 1999) -- virtually the same as Australians.

    The Skhul and Qafzeh people were indeed tall relative to these other human samples, with male skeletal elements yielding stature estimates from 170-190 cm. The average stature of American men today is 176 cm. Holliday [2] showed that early Upper Paleolithic males had an average stature around 170 cm. According to Carretero and colleagues, the average Sima de los Huesos adult male had a stature around 168-170 cm. And as they note, taller individuals with stature estimates of 180 cm or more are present in the Early and Middle Pleistocene sample -- most notably the large Kabwe tibia, but we can also mention KNM-ER 1808 and KNM-ER 736 from the Early Pleistocene of Kenya.

    I disagree with the paper's suggestion that modern humans represent a new pattern of tall stature compared to earlier humans. I propose instead as a null hypothesis that human stature has not changed systematically since the Early Pleistocene.

    That doesn't mean human stature hasn't evolved. Human populations today are variable in stature, and they were in the recent past. We have pygmy populations with statures that average 150 cm or less in males, and peoples with statures that average close to 180 cm. Tall and short-statured populations today live in nearly every region, or did so in early Holocene times. Some of the variation in stature among populations is nutritional, some is additive, and both sources of variation appear to have emerged repeatedly in different contexts in recent human evolution.

    I suggest that pattern of variability would also have been present in earlier populations of humans. The differences between Neandertals and early Upper Paleolithic Europeans and the Skhul-Qafzeh sample were substantial but do not exceed the differences among recent human populations. The human stature adaptation is variable within a relatively broad niche, and has been so for nearly 2 million years.

    References

    1. Carretero J-M, Rodríguez L, García-González R, Arsuaga J-L, Gómez-Olivencia A, Lorenzo C, Bonmatí A, Gracia A, Martínez I, Quam R. Stature estimation from complete long bones in the Middle Pleistocene humans from the Sima de los Huesos, Sierra de Atapuerca (Spain). Journal of human evolution. 2011.
    2. Holliday TW. Body size and postcranial robusticity of European Upper Paleolithic hominins. Journal of human evolution. 2002;43(4):513-28.
    Tags: 
    Atapuerca
    Sima de los Huesos
    stature
    body size
    Neandertals
    Synopsis: 
    The long bones of the Atapuerca people double our information about early human statures

  • Meet Gigantopithecus

    Tue, 2011-10-25 00:09 -- John Hawks
    Synopsis: 
    Laboratory introduction to the species Gigantopithecus blacki, with discussion of its body size relative to gorillas and robust australopithecines.

    Gigantopithecus blacki was, as its name implies, a gigantic ape from the Pleistocene of China. Its remains consist only of teeth and jaws, but these are of a tremendous size, with the largest specimens nearly twice the dimensions of male gorilla teeth and jaws. A similar, slightly smaller jaw is known from the Miocene of northern India, and has been called Gigantopithecus bilaspurensis [1].

    Here you see casts of some of the teeth of Gigantopithecus blacki. Assuming that Gigantopithecus had the same proportion of tooth size and body mass as living apes, these Chinese remains would suggest a body mass of over 400 kg for the largest individuals. But should we assume a model of body size like that of today's large great apes, such as the orangutan and gorilla? Or should we assume a model in which Gigantopithecus had enlarged jaws and teeth relative to its mass, as is the case in the extinct robust australopithecines?

    Examine the Gigantopithecus teeth in comparison to modern gorilla teeth and jaws, and the teeth and jaws of Australopithecus boisei and Australopithecus robustus. How do the femora of A. robustus compare to the gorilla femur? How do the molars of these species compare? Which do you think is the better model for Gigantopithecus, and what would you predict as the body mass of this extinct species?

    References

    1. Simons EL, Ettel PC. Gigantopithecus. Scientific American. 1970;222:77–85.
    Study terms: 
    Gigantopithecus blacki
    Gigantopithecus
    Gigantopithecus bilaspurensis
    Tags: 
    Gigantopithecus
    Miocene ape evolution
    Miocene
    body size
    China

  • A look at Little Foot

    Fri, 2011-09-09 13:00 -- John Hawks

    Along with the papers on the Malapa hominins, Science this week published a news story by Michael Balter that is a profile of Ron Clarke and his work on the "Little Foot" skeleton, StW 573 from Sterkfontein [1]. This specimen has been coming out of the ground for nearly seventeen years now, and Balter reports that the final pieces are to come out of the cave within two months. The article hits on the important issue of dating:

    Meanwhile, Clarke and three independent teams are getting divergent dating results. In 2000, Clarke's team, using known reversals of Earth's magnetic field, put the skeleton at 3.3 million years, making it a near contemporary of Lucy and the oldest hominin in South Africa. But since 2006, three other teams, using uranium-lead and paleomagnetic dating, have published dates ranging from 2.2 million to 2.6 million years, although they all regard the younger date to be more likely. That would make Little Foot about the age of the earliest known Homo and only a little older than Au. sediba. Clarke is now working with geologist Laurent Bruxelles of the University of Toulouse in France to produce their own new dates.

    It's striking that in an article about a complete hominin skeleton, the only informed commentary and opinion is about the foot anatomy. The foot is the only part that has yet been published in enough detail for intelligent comment, and as Balter points out, very few individuals have seen the specimens or casts of them. There are casts of the specimen in situ on display at Maropeng and the smaller museum at Sterkfontein, though. It struck me just how large the specimen is. I would describe it as the first human-sized australopithecine.

    References

    1. Balter M. Little Foot, Big Mystery. Science. 2011;333(6048):1374 - 1374.
    Tags: 
    Sterkfontein
    A. africanus
    South Africa
    body size
    field sites

  • Selection for smaller brains in Holocene human evolution

    Mon, 2011-08-22 18:32 -- John Hawks
    Research authors: 
    John Hawks
    Publication information: 

    This a pre-publication manuscript. Please contact the author for information about citation.

    Work status: 

    This is a completed manuscript in the process of submission and review. The findings have not been peer-reviewed, but I am confident in the analysis and quality of citations.

    Abstract: 

    Background: Human populations during the last 10,000 years have undergone rapid decreases in average brain size as measured by endocranial volume or as estimated from linear measurements of the cranium. A null hypothesis to explain the evolution of brain size is that reductions result from genetic correlation of brain size with body mass or stature. Results: The absolute change of endocranial volume in the study samples was significantly greater than would be predicted from observed changes in body mass or stature. Conclusions: The evolution of smaller brains in many recent human populations must have resulted from selection upon brain size itself or on other features more highly correlated with brain size than are gross body dimensions. This selection may have resulted from energetic or nutritional demands in Holocene populations, or to life history constraints on brain development.

    Tags: 
    my research
    brain
    brain size
    body size
    allometry
    recent
    Holocene

    Background

    An increase in brain size was one of the major trends of human evolution [1][2]. At the beginning of the Pleistocene, the average endocranial volume of fossil Homo specimens was approximately 750 ml [3]. By 30,000 years ago, this average value had increased to nearly 1500 ml [1][2]. Much of this increase occurred within the period following 800,000 years ago [1][2], during which mean endocranial volume in \emph{Homo} increased by approximately 70 ml per 100,000 years. This trend occurred in all regions of the Old World [2], which may have included either a single [4][2] or multiple species of archaic Homo [5][3].

    Less well known is that the terminal Pleistocene and Holocene (ca. 30,000 years ago to present) witnessed a substantial decline in endocranial volume [6][7][1]. This decrease occurred within modern \emph{Homo sapiens}, and has been observed in many parts of the world [6][7][8]. The scope of this decrease is remarkable: for example, within the past 10,000 years the average endocranial volume in European females reduced from a mean of 1502 ml to a recent value of 1241 ml [7]. This decrease of approximately 240 ml in 10,000 years is nearly 36 times the rate of increase during the previous 800,000 years.

    Brain size is related to body size both across higher taxa [9] and within humans [10]. This suggests the hypothesis that changes in human brain size may result from changes in body size. For example, the larger brain size in early Homo compared to Australopithecus may reflect the simple expansion in body size from earlier hominids [11]. This explanation cannot explain every change in brain size in humans: for example, the long increase in brain size during the Pleistocene did not coincide with increases in body size [3].

    What about the reduction in brain size during the last 10,000 years—can it be explained by a reduction in the size of the body? Human body size, as measured from skeletal dimensions, did reduce during the past 30,000 years, at least in some populations [6][7][1][12]. This reduction influenced both mass and stature [7][1][12]. A reduction in overall body size may have resulted from Late Pleistocene and Holocene subsistence strategies, which replaced close-contact ambush hunting of large mammals with projectile weapons, intensive collection of small animals, fish, and shellfish, and ultimately sedentary pastoralism and agriculture [13]. Nutritional inadequacies and disease during the Holocene also may explain reductions in body size [14]. Within Europe, where the trend has been most closely studied, body size rebounded within the past 1000 years as manifested by increases in stature [7].

    Several workers have suggested that recent reductions in brain size may have been caused by reductions in body size [6][7][1][15]. A coincidence of reduction in both these measures would lend some support to that hypothesis. However, for a reduction in body size to be a sufficient explanation for reduction in brain size, it is not enough that the reductions occurred at the same time. Natural selection on one character (like body size) will affect a correlated character (like brain size) only to the extent that the two characters are heritable and are genetically correlated. Therefore, to test the hypothesis that selection on body size accounts for reductions in brain size in recent human evolution, we must consider the relationship and genetics of these characters within human populations.

    Here, I apply a quantitative genetic model to test the hypothesis that Holocene evolution of brain size may be explained by reductions in body size. The reasons for reduction in body size are unclear, so I consider both body mass and stature as candidates for the target of selection in recent populations. This is a very limited approach, constrained to published estimates of endocranial volume in archaeological populations and estimates of phenotypic correlations and heritability from samples of living humans. No attempt is made to correlate brain size and body size in the same samples of archaeological specimens, as such data are not available at present. Instead, I estimate the amount of body size change that would be necessary to explain the observed change in endocranial volume. This estimate is then assessed for credibility as applied to archaeological samples.

    Results and Discussion

    Body mass

    Body mass is related to brain size in humans with a phenotypic correlation of r≈0.29. The standard deviation of male body mass within recent human populations ranges around 11 kg, a value near the midpoint of within-sex variation in other primate species [16]. Using these values along with the others listed in Table 1, selection on body mass would be expected to reduce the mean endocranial volume by 4.3 ml for each kilogram of reduction in body mass.

    The decline in body mass in human populations during the last 10,000 years has been estimated as less than 5 kg, or less than a 10 percent reduction in mass from a Late Upper Paleolithic mean of some 63 kg [1]. A decline of 5 kg would predict a decrease in endocranial volume only around 22 ml. The observed decline in several regions (including Europe, China, Southern Africa, and Australia) is between 100 and 150 ml during the past 10,000 years. Therefore, the reduction in body mass would be expected to have decreased brain size by only one-fifth to one-seventh the observed decline.

    We can look at the inverse question: how much reduction in body mass would be required to cause a 150 ml reduction in endocranial volume? Using the same ratio (4.3 ml per kilogram body mass), the endocranial volume contrast would predict a reduction of 34 kg. This value is implausibly high, by more than a factor of five.

    The reduction of endocranial volume in these populations is not well explained by body mass according to equation 1. Selection for smaller mass is insufficient to account for reduction in brain size or vault dimensions.

    Stature

    Applying equation 1 to the parameters for stature and its correlation to brain size, endocranial volume would be expected to change approximately 9.5 ml per centimeter change in stature. This value is less extreme than the reduction in body mass that would be necessary to achieve the same reduction in brain size. But the skeletal record is inconsistent with any great decrease of mean male stature, particularly during the post-Neolithic time period.

    Stature estimates exist for a broad sample of ancient European populations, showing approximate stasis in stature during the last 4000–6000 years. Over the same time period, the estimated endocranial volume declined slightly more than 100 ml in Europe from an estimated 1496 ml to 1391 ml. This decline cannot be explained by decreases in stature, because the stature did not change. Additionally, although these early samples are small, Mesolithic Europeans had larger endocranial volumes than Upper Paleolithic Europeans, across the same interval when they underwent a substantial decline in stature. That Mesolithic change in endocranial volume is in the opposite direction expected from the change in stature.

    Likewise, the femur lengths of foragers in Southern Africa showed no net decrease over the last 10,000 years. From 5500 to 2500 years ago, both femur length and femur head diameter declined in this region, but they rebounded within the last 2500 years [17]. Across the same 10,000-year time period, Henneberg and Steyn [8] documented a decline in external and internal cranial module. The sample of LSA foragers (before 2000 years BP) had a mean external cranial module of 154.7, Iron Age (2000--200 years BP) had a mean of 149.6, while recent foragers had a mean of 150.3 --- roughly a standard deviation lower than the pre-2000 BP value. Under the hypothesis that change in endocranial volume is predicted by the change in stature, we should predict no net change in endocranial volume in this population. But the reduction in external module corresponds to a reduction in endocranial volume between 100 and 150 ml [8]. However, the LSA sample in that study is very small (n=12) and temporally dispersed.

    Early Holocene populations in Australia have produced a substantial sample of crania, but postcrania from this time period are rare or poorly preserved [18]. The net change in endocranial volume, roughly 130 ml from the terminal Pleistocene to late Holocene skeletal sample [19] would predict a reduction in stature of 13 cm, if the brain size had changed only because of correlated changes in stature. That degree of stature reduction is not biologically impossible although it would be extreme. Further investigation of the evolution of body size in recent Australian hunter-gatherers may be necessary to answer the question.

    Why did brain size reduce during the Holocene?

    The evidence suggests substantial reductions in brain size in some recent human populations, more than can be explained by correlated changes in body size. It is worth discussing two related points concerning the distribution and causes of this pattern of brain size evolution.

    First, was the change global or local in scope? The samples here cover several far-flung geographic areas, but they do not cover all regions of the world. Beals, Smith and Dodd [6] reviewed the global evidence for endocranial volume and showed a decline in the available terminal Pleistocene to Holocene skeletal sample. The Late Pleistocene skeletal sample was in that case strongly biased toward Europe, an area that in contemporary humans has a relatively large average endocranial volume. Thus, it was not obvious whether geographic differences in sampling might explain the reduction in endocranial volume noted in the study. This problem also characterizes the somewhat more course sampling by Ruff and colleagues [1]. Here, the samples of endocranial volumes and body sizes are matched in region to the extent possible; they do represent probable evolutionary trends within these populations. But there are few other comparable sequences of skeletal samples, so it may not be possible to conclude strongly that the reduction in brain size generalizes outside these regions.

    A large series of crania from ancient Nubia covers the period from roughly 3400 years ago to 600 years ago [20][21]. Samples show a slight trend toward decrease in the major length, breadth and height measurements from Iron Age (Meroitic, external cranial module 145.2) to Medieval (Christian, external cranial module 143.9) times, but the intermediate series of crania (X-Group, external cranial module 147.1) is somewhat larger in these dimensions than either of the other groups. In this context it would be misleading to speak of a reduction in cranial vault size in this region. Across the same time interval, these samples show a substantial reduction in facial and dental measurements [21].

    Second, given that the pattern is widespread if not global, how can we explain the reduction in brain size? Several hypotheses have been presented that may help to explain recent brain evolution. It is beyond the scope of this paper to test these hypotheses but here I review several of the adaptive and non-adaptive alternatives with some notes relating to the observed pattern.

    1. Chance. Genetic drift may be considered a null hypothesis for any slight morphological change. However, in the case of brain size evolution during the last 10,000 years, genetic drift is a markedly unlikely hypothesis. Endocranial volume changed by a standard deviation or more, rapidly and directionally, within some very numerous and growing post-agricultural populations.
    2. Plasticity. Somatic development in humans is plastic to some degree, depending on uterine and childhood nutritional and disease environments. This plasticity underlies most of the recent secular trend in body mass and stature. However, the brain size reaches 90 percent of its adult value very early in development and most of the variance in living populations is additive. This suggests that brain size may be less plastic than other components of body size. The pattern of decrease does not match stature or mass across the last several thousand years in these populations, suggesting that environmental effects were probably mediated by genetic factors.
    3. Climate. Beals, Smith and Dodd [6] presented correlations between endocranial volumes of populations and their local climate, as reflected by latitude or temperature. Smaller-brained populations live in warmer climates, and this relation cannot be explained entirely in terms of body size of contemporary populations. They proposed that post-glacial climate change may have favored smaller brains. However, if the link between climate and brain volume is not mediated through body mass (following Bergmann's rule), it is not obvious why climate should cause brain size reduction.
    4. Nutrition. The diets of early agriculturalists were nutritionally challenging in several ways: low in protein content, sometimes low in essential vitamins, and subject to fluctuating supply. The brain is an energetically expensive organ and nutritionally costly to develop. Smaller brains on balance should be advantageous under energetic or nutritional constraint, if they are functionally equivalent. Larger Holocene populations may have been selected for smaller brians for energetic reasons.
    5. Function. Smaller brains may have some functional implications, as white matter tracts are shorter and functional areas of the cortex may be more compact. Given the social and ecological changes of the Holocene, it is possible that a different mix of mental and cognitive functions was the target of selection. Despite the long Pleistocene history of human brain evolution, it would be fallacious to assume that larger brains were always adaptive in the context of cognitive changes.
    6. Development. Although adult brain size is attained relatively early in development compared to adult body size, brain development continues during adolescence and early adulthood. It is possible that the life history evolution of recent humans has involved changes in the maturation schedule that would impact the ontogeny of brain maturation. If so, then the schedule of brain development after it attains adult size might have been constrained by earlier events, in such a way that faster development or smaller completed size was advantageous.

    These hypotheses are not mutually exclusive. To assess them, it will be necessary to collect systematic data from a large sample of crania representing these and other regions of the world. This study represents only an early step toward understanding the cross-regional record of brain size evolution in the Holocene.

    Comparative data may also be useful to resolve these hypotheses. The decline of human endocranial volume during the last 10,000 years is paralleled most obviously by the reductions of brain size in domesticated animal species, including dogs, cattle and sheep, compared to their wild progenitors. Nutritional, developmental, and functional issues are all possible explanations for these parallel cases of brain size reduction. Humans are different in many ways from these domesticated species, but exhibit other parallel trends such as decreased skeletal robusticity.

    At present, the literature presents a relative hodge-podge of estimates of endocranial volume, based on different original measurements. Estimates taken from the same method are compatible with each other, but it is not obvious that estimates based on different methods can be reconciled. It would be valuable to replace this mixture of measurements with a standard morphometric profile. The size of the endocranial cavity is interesting because of the developmental and energetic aspects of brains. But size is only one aspect of recent brain evolution. A full accounting of the shape of the cranial vault or endocast will be necessary to test hypotheses about why and how the brain reduced in size in these Holocene populations.

    Conclusions

    The available skeletal samples show a reduction in endocranial volume or vault dimensions in Europe, southern Africa, China, and Australia during the Holocene. This reduction cannot be explained as an allometric consequence of reductions of body mass or stature in these populations. The large population numbers in these Holocene populations, particularly in post-agricultural Europe and China, rule out genetic drift as an explanation for smaller endocranial volume. This is likely to be true of African and Australian populations also, although the demographic information is less secure. Therefore, smaller endocranial volume was correlated with higher fitness during the recent evolution of these populations. Several hypotheses may explain the reduction of brain size in Holocene populations, and further work will be necessary to uncover the developmental and functional consequences of smaller brains.

    Methods

    Endocranial volume

    Studies of skeletal samples from different regions of the world are very consistent in finding reductions of endocranial volume during the last 10,000 years [6][22][7] [19] [23] [8][24]. However, there are discrepancies among studies in the both the method of estimation and the time periods for which skeletal samples are available. These are listed in Table 1.

    Estimation methods

    The literature on brain size in archaeological specimens refers to several different measurements:

    1. Endocranial volume: directly measured by mustard seed, shot or water displacement of endocasts, or estimated from tomographic (CT) or magnetic resonance (MRI) methods. These different measurement methods can lead to systematically different results and so should not be combined without accounting for the measurement bias. The endocranial volume is larger than the brain volume (because of the intervening fluid and meningeal membranes).
    2. Brain weight: directly measured from cadavers or estimated from CT or MRI based on brain volume and estimated tissue density.

      Some notable large-sample studies of variation within contemporary human populations have examined brain weight [25]. Brain weight and endocranial volume are strongly correlated but not identical. The volume of the skull includes fluid and tissue components that are not included with cadaver brain weights, while different means of preservation of cadaver brains may inflate the variability of some brain weight datasets. The problems of brain weight measurement are not directly relevant to archaeological samples, where there are no brains to weigh. But brain weight remains important because of the present-day samples in which we can estimate the phenotypic correlation of brain and body size. Where possible, I have included present-day samples that include either endocranial volume or cranial measurements, for direct comparability with the archaeological samples.

    3. Cranial module: The external cranial module is the arithmetic mean of three external measurements of the skull: maximum length (glabella-opisthocranion), maximum breadth (euryon-euryon) and cranial height (basion-bregma). These external measurements include not only the brain but also the thickness of cranial bones.

      In some populations considered here, the thickness of cranial vault bones declined during the Holocene. This means that a decrease in the external module may be explained in part by a decrease in thickness, and some correction must be made to consider endocranial volume. The effect of thickness can be quite substantial; a decrease of 5 mm of thickness around a skull with an external module of 160 mm would increase its endocranial volume by around 180 ml. Where measurements of thickness are available, one approach is to subtract twice the vault thickness from the external module, resulting in an internal cranial module. This is the approach taken by Henneberg [7], for example, who reports both internal cranial module and resulting estimates of endocranial volume derived from regression on internal module.

    The current paper uses the generic term ``brain size'' to refer to any of these estimation methods. Each of the four regions considered here is represented by at least one study that uses consistent estimation methods within the region. Even though different regions may be characterized by different methods of estimation, these differences should not bias the results within each region. But when different regions produce a common result, it remains possible that the magnitude of changes may actually diverge from each other due to differences in estimation methods.

    One fundamental problem remains. Estimates of heritability and brain-body phenotypic correlation within human samples typically involve brain weight (for autopsy studies) or brain volume (for MRI or CT studies). Estimates from skeletal samples typically involve endocranial volume or cranial module. We cannot know that the heritability of the skeletal measures is equal to that of the soft-tissue measures.

    Regions

    The literature includes sufficient data to consider the reduction of brain size in four regions of the world.

    The greatest temporal detail is available from Europe, reviewed by Henneberg [7]. Samples of up to several thousand skulls have estimates of endocranial volume. The largest set of these are based on external measurements, corrected for average vault thickness. The literature also includes a substantial number of direct measurements of endocranial volume by seed or water displacement. Henneberg [7] reports a Mesolithic mean endocranial volume for males of 1567 ml (based on internal cranial module of 144.1). This estimate is based on a relatively small sample of 35 individuals. For Neolithic and Eneolithic samples, with 1017 individuals, the mean endocranial volume estimate reduced to 1496 ml (internal cranial module 141.9), Bronze and Iron Age samples had a mean estimate of 1468 ml (internal cranial module 141.0), Roman period mean estimate 1452 ml (internal cranial module 140.5), and Early Middle Ages 1449 (internal cranial module 140.4). Late Middle Ages had a mean estimate 1418 (internal cranial module 139.4), and ``Modern Times'' (which comprises post-Medieval samples) corresponded to a mean estimate of 1391 ml (internal cranial module 138.5). Female samples across this time period exhibited a similar degree of size change; from a Neolithic mean of 1373 ml to 1210 ml in the ``Modern Times'' sample.

    Henneberg's study was notable for its discussion of the limitations of these data, which are compiled from many sources. The reliance on external dimensions does tend to increase the interstudy comparability of the values, but necessitates relying on regression predictions of endocranial volume, which necessarily involve some error. The overall change is substantial enough to overcome the plausible methodological inconsistencies, but it is appropriate to be cautious between time intervals (e.g., Early to Late Middle Ages) where the amount of change is minimal.

    Endocranial volume in southern Africa was considered by Henneberg and Steyn [8], estimating from measurements of external and internal cranial module. The sample covers the time period after 30,000 radiocarbon years BP, however, the vast majority of specimens date to the last 2000 years. Henneberg and Steyn [8] showed a statistically significant decline in both male and female crania, separated by morphological criteria.

    Much of this sample, together with a larger selection of archaeological crania, were included in a later study by Stynder and colleagues [26] using morphometric methods. This study demonstrated an increase in craniofacial size during the last 4000 years, which appears to contradict the findings of Henneberg and Steyn [8]. The resolution between these two results is twofold. Most obviously, Stynder and colleagues [26] did not include landmarks that would indicate cranial breadth across the parietals, as these are not easily digitized. The breadth values are those showing the most consistent decreases in the sample studied by [8]. Secondarily, Stynder et al. [26] included facial measurements in their sample, so that the centroid size of crania was determined by both facial and vault dimensions. The allometric shape analyses in this paper demonstrated that larger centroid size was associated with allometric increase in the face and relative decrease in the vault. The implications of this allometry for the absolute vault dimensions are not clear, although the direct measurements indicate a reduction in vault size for the sample measured by Henneberg and Steyn [8]. It would be valuable to look at these allometric questions comprehensively with both landmark and caliper measurements in the southern African sample.

    Brown and Maeda [22][19] reported on diachronic change of skeletal measurements in Holocene north China and Australia. They showed that the endocranial volume of males decreased from a mean of 1510 ml in early Neolithic (5500--6000 year old) samples down to 1400 ml in present-day Chinese. The change is consistent with a trend toward decrease across time intervals, despite relatively small sample sizes (n=10 to n=20 in the archaeological samples). Present-day Chinese people appear to vary in cranial size from north to south, possibly by more than 100 ml [19][6], and it is not obvious which samples of contemporary Chinese make the most relevant comparisons. So a decrease of 100 ml over the last 6000 years may either overstate or understate the actual change in endocranial volume in this population.

    Wu and colleagues [27] confirmed the trend toward smaller cranial size from Bronze Age to recent northern Chinese populations. The study included a much larger sample of crania than examined by Brown and Maeda [22], but endocranial volume itself was not measured. The length, breadth and height of the skull all underwent significant reductions from the Bronze Age, roughly 3000 years ago, to the present.

    Brown [19] presented a comparison of 19 male Australian crania from the terminal Pleistocene and 23 contemporary crania of Aboriginal Australians. The terminal Pleistocene sample stretches across a substantial range of dates, the earliest specimens possibly older than 30,000 years, to as little as 9000 for the large Coobool Creek sample. The Pleistocene people were larger in body size than recent Australians, and exhibit larger teeth and greater skeletal robusticity. The mean endocranial volume of the terminal Pleistocene males is 1405 ml; the recent mean is 1272 ml, for a decrease of just over 130 ml.

    In qualitative terms, the strongest documentation of the decline in endocranial volume is from Europe, due to both sample size and sample preservation. The other three skeletal samples show a comparable magnitude of decrease. In China, this decline occurred over roughly the same time interval as in Europe; in South Africa and Australia the reductions may have unfolded over a longer period of time. In all cases, the estimated reduction of endocranial volume was greater than 100 ml within males, roughly 7 percent of the mean.

    Mass and stature

    Like brain size, stature and body mass provide challenges in the archaeological record.

    Mass is a parameter of fundamental biological interest, but it depends strongly on soft tissue body composition and is therefore estimated only with substantial error from skeletal samples. In a global survey of the Pleistocene human skeletal record, Ruff and colleagues [1] estimated a mean body mass for Late Upper Paleolithic humans as 62.9 kg; this estimate was derived from 71 skeletal specimens, mostly from Europe. The ``living worldwide'' value cited in that study was 58.2 kg, a reduction of less than 5 kg from the Late Upper Paleolithic value, although the samples are geographically inconsistent.

    Stature should be a better proxy for body size in the archaeological record, because it exhibits less phenotypic plasticity and because it relates more directly to measurable skeletal quantities such as long bone lengths. This increases the geographic sample available to test hypotheses of temporal change, because either long bone lengths or stature estimates exist for Europe, Southern Africa, and China.

    Frayer [13] reported an Upper Paleolithic male mean stature of 174 cm with a standard deviation of 9.4 cm. The Mesolithic male mean stature in that study was 165 cm with a standard deviation of 6.6 cm. The reduction in female stature values was concordant with the male values, with roughly half the number of sampled individuals. Maximum femur length reduced from 466 to 446 mm in male individuals between these time periods, with standard deviations of 38 and 29 mm, respectively.

    Henneberg [7] lists a series of stature estimates from rural Poland since the 13th century. Both male and female statures were in approximate stasis over that time period, until the 19th century. Koepke and Baten [28] put together a broader sample of anthropometric measures from across Europe during the last 2000 years, and also concluded that heights had been ``stagnant'' across that interval. Brief excursions of stature in some parts of Europe may nevertheless have occurred. Steckel [29] collated a series of stature estimates from Northern European skeletal samples dating from the 9th to the 19th centuries. Across this region, the mean male stature declined from roughly 173.4 to a low of 166.2 cm during the 18th century, a reduction of 7 cm. That decline may have been presaged by an increase in the post-classical period suggested by the data of Koepke and Baten [28]. Neither trend was noted in the samples considered by Frayer [30] or Henneberg [7].

    Sealy and Pfeiffer [31] measured and performed stable isotope composition analysis of femora from the Cape region of South Africa, dating to the last 10,000 years. The male-attributed femora with measurable lengths in this study date to the period between 6000 and 1000 years ago. They show no significant decline in maximal length across this period. Femoral head diameter reduced slightly and significantly between the earlier male sample (before 4000 years ago) and later males (between 1000 and 4000 years ago). Pfeiffer and Sealy [17] revisited this sample and added evidence from more recnet skeletal individuals. The results showed that stature tended to rebound to a larger mean within the last 2000 years, roughly equal to the initial sample before 6000 years ago. Across this entire time period, the stature and mass of the archaeological population was within the range exhibited by present-day Khoisan peoples.

    The documentation of stature by long bone lengths is the best available source of data on body size in archaeological samples. Conservatively, we can conclude that the skeletal record documents a modest reduction of stature since the Upper Paleolithic in Europe, most of which had occurred by the Mesolithic. In Europe and China, the skeletal record is consistent with approximate stasis of stature during the last 5000 years, with some geographic and temporal excursions from the broad pattern.

    Body mass is unlikely to have changed is a very different pattern from stature. Fatness is poorly documented skeletally and is at present the largest component of variation in within-sex mass in industrial populations, but this varied much less substantially in pre-industrial peoples.

    Quantitative genetic model

    For both body size parameters, the error of skeletal estimates is substantial. Therefore, here I adopt a very conservative test of the null hypothesis: (1) Determine the amount of change in body size that would minimally be required to explain the observed change in brain size; and (2) Evaluate whether that amount of change in body size is credible given the skeletal record. The skeletal record addresses point (2), but for point (1) we must turn to a quantitative genetic model relating the evolutionary dynamics of correlated characters.

    The allometry of brain and body size has been investigated extensively among both living and fossil organisms. From a quantitative genetic perspective, Lande [32] developed mathematical expectations for allometric change in the population mean of a single phenotypic character in response to selection on a correlated character. This change is given by Equation 2b in Lande (1979) [32]:

    Equation 1

    [note: HTML is difficult to represent bar over letters; these are z-bar in the manuscript]

    Δzizb indicates the change in the population mean zi of one character (here, endocranial volume) with a correlated change in the mean zb of a selected character (here, body size). The genetic correlation between the two characters is γib, while hiσi is the square root of the additive genetic variance of character i.

    For this study, the null hypothesis is that brain volume should be predicted by equation 1, given the parameter estimates and the change in body size. This is equivalent to the hypothesis that brain size has changed entirely due to its genetic correlation with body size. The parameters in equation 1 have all been estimated in one or more contemporary human populations.

    It is important to note that parameter estimates may be conservative or nonconservative in their effects under the null hypothesis. The genetic correlation of the two traits must be less than 1. So measuring change in units of standard deviations, the null hypothesis predicts that brain size should change relatively less than body size. However, the absolute change must be considered relative to heritability and variance of the two phenotypic traits. Brain size should change more relative to a given change in body size if:

    1. the genetic correlation of brain and body sizes is higher,
    2. the heritability of brain size is higher,
    3. the phenotypic variation of brain size is higher,
    4. the heritability of body size is lower, or
    5. the phenotypic variation of body size is lower.

    If the parameter estimates are in error in these directions, the test of the null hypothesis will be conservative to some degree—that is, the null hypothesis will be accepted in cases where the true parameter values would lead to rejection.

    Estimates of heritability and variances are available for humans and for some other species of primates, both for brain volume and for body mass and stature. The availability of different estimates makes it possible to consider their consistency with each other and the likely effects of error.

    Mass and stature are considered separately as independent variables in the analysis.

    Brain size variation

    The skeletal samples above allow estimates of standard deviations for each sample. However, because of the limited sizes of archaeological samples, these estimates of variability may either overstate or understate the variation of ancient populations.

    There is substantial sexual dimorphism of both brain and body size in humans. The simplest way to correct for variation due to sex is to consider males and females separately. All estimates of parameter values in living humans are reported from male- or female-specific samples. Archaeological samples often permit assessment of individual sex, although there is necessarily some error in these assessments. Where possible, this study reports values for males, and assumes that variation is distributed like that of males in living human populations.

    Additionally, phenotypic estimates in humans may include confounding age effects. A few cited studies use age-controlled samples, but many rely on postmortem measures in samples with a broad range of age-at-death. Archaeological samples always include age-related variability, although this is likely distributed differently than in many surveys of living humans.

    Peper and colleagues [33] reviewed heritability estimates for total and regional brain volume based on MRI studies of twins. Most studies have yielded high estimates for the heritability of total brain volume, ranging from 0.97 [34], 0.94 [35], 0.90 [36] and 0.89 [37]. One outlier study reported a lower estimate of heritability (0.66), but this came from a sample of only 10 MZ and 10 DZ twin pairs [38]. In the current study, the use of a high estimate of heritability will tend to bias the result toward accepting the null hypothesis, since a more heritable character will be expected to change more under the effect of correlation with body size.

    Brain-body genetic correlation

    The genetic correlation between brain size and body size is not known for humans. However, the phenotypic correlations between brain volume or mass and body mass or stature have been extensively studied. The largest sample of these metrics was published from Danish autopsies by Pakkenberg and Voight [25]. Holloway [10] computed correlations between brain mass, stature and body mass in this dataset; these are reported in Table 1.

    Ankney [39], using the data from Ho et al. [40], reports phenotypic correlations between brain mass and stature as r=0.20 for white males and r=0.24 for white females, r=0.20 for black males and r=0.15 for black females. These values are lower than those computed from the Danish data. Both sets of estimates should be regarded as underestimates because of the confounding effect of age variation in the sample. On the other hand, these are phenotypic correlations, and the genetic correlation may be lower than the phenotpic values due to effects induced by the environment or gene-environment interactions. Here, I employ the higher reported estimates of correlations because they have a conservative effect on the hypothesis test: A higher correlation predicts a more substantial change in brain size.

    Parameter Value Source
    Brain volume heritability (h2 0.94 [35]
    Stature heritability (h2) 0.80 a [41]
    Body mass heritability (h2) 0.52 b [42]
    Brain size--stature correlation 0.47 c [10]
    Brain size--body mass correlation 0.29 [10]

    Table 1 - Estimates of quantitative genetic parameters. Correlations and heritabilities of human brain and body dimensions used in this study. Values are from combined-sex samples. a Based on a range of estimates from several countries. b Age-matched sample. c Correlations taken from [10] based on original data from [25] and other sources cited therein.

    Parameter values in nonhuman primates

    Estimates of brain-body correlations and heritabilities in humans have mostly been taken in European or American population samples. These estimates may therefore be biased dietary Westernization and concomitant changes in body mass index. To address this possibility, we can consider these relationships in non-human primates.

    Rogers and colleagues [43] measured brain volume and body mass in captive free-ranging baboons (Papio hamadryas) with known pedigrees. They found brain-body phenotypic correlation of r=0.29 (r2=0.086) for males and r=0.16 (r2=0.026) for females. The heritability of brain volume was estimated as 0.52. The heritability of body mass in this captive population was previously estimated as 0.50 [44].

    Falk and colleagues [45] found phenotypic correlations in rhesus macaques (Macaca mulatta) between brain volume and body mass to be r=0.54 for males and r=0.40 for females.

    Stature is not strictly comparable between humans and other primates, because of the obvious difference in locomotor anatomy.

    These comparisons allow several conclusions:

    1. The heritability of body mass is approximately the same in humans as in other primates.
    2. Heritability of brain size in humans is substantially higher than reported in other primates. Using a high estimate should bias against rejection of the null hypothesis.
    3. The phenotypic correlations between brain size and mass in these primates are within the range reported for humans.

    Thus, as near as possible, using the human values for these parameter estimates will provide an appropriate test of the null hypothesis, that changes in brain size were caused by changes in body size in recent human populations.

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  • Gene expunction

    Fri, 2010-09-24 09:13 -- John Hawks

    So, it's a perfectly ordinary story about epigenetics and how the methylation of some genes may be correlated with BMI. But what I don't understand is the headline:

    Study: Can We Tell Our Genes to Make Us Fat?

    YES! That's exactly what I need -- to tell my genes to make me fat. Please tell me more!

    Tags: 
    humor
    epigenetics
    body size
    media

  • The shrinking youth

    Fri, 2010-09-17 13:59 -- John Hawks

    Yesterday the Journal of Human Evolution released a new paper by Rhonda Graves and colleagues, titled “Just how strapping was KNM–WT 15000?” [1]. The paper challenges almost 25-year-old estimates for the body size of this important 1.5 million year old skeleton.

    For all this time, the textbooks have reported that early Homo in Africa had the same tall and elongated physique as current East African people like the Maasai. The new paper says that the textbooks are wrong -- the skeleton doesn't represent an individual who would have grown to be 6'1" (185 cm), instead it was near the end of its growth trajectory, for an adult height of around 5'4" (163 cm).

    That's a pretty massive change, and when the authors presented this work at the AAPA meetings last spring, it wasn't without controversy. So naturally we should look closely at the paper, understand its conclusions, and assess what this new estimate means for our understanding of early Homo. As you might guess from reading some of my earlier posts, I've been thinking that the body sizes of the rest of the Pleistocene record add up to a fairly simple picture. One of the few outliers from this picture was KNM-WT 15000. I'm inclined to think that the new estimate fits the bigger picture -- for example, I wrote this spring about "Shrinking erectus".

    Which means, of course, that I should be even more skeptical.

    KNM-WT 15000 was a juvenile at the time of death, and so any estimate of body size involves some assessment of the skeleton's state of development. This has presented a problem for assessing how much the individual had still to grow at the time of its death. The eruption and development of the teeth appear to be consistent with a fairly young age at death, by most estimates younger than 11 years, and by some as young as eight. That's using a human frame of reference. If we turn to a frame of reference drawn from chimpanzees or other apes, the estimated age at death from tooth development is even a bit younger. In contrast, the state of bone development seems to indicate a somewhat higher age at death: older than 11, and by some estimates as old as 15 years.

    KNM-WT 15000 skeleton

    Graves and colleagues, looking at this apparent mismatch between dental and skeletal development in this specimen, suggests that we need to look at a broader range of possible developmental models for early Homo erectus. A modern human developmental model is not a good fit, and neither is an ape developmental model. So their study involves creating a range of possible developmental trajectories for early Homo. These trajectories are based on data from living apes and humans, but altered by accelerating some phases or changing the intensity of the adolescent growth spurt.

    The growth spurt is very important to this issue, because it's one way that humans and most other primates differ greatly. Growth during that phase of development contributes disproportionately to the tall stature of modern humans. If Homo erectus didn't have the same kind of growth spurt as we do, then the stature of this specimen would have been a lot shorter than we would estimate for a human of the same age.

    The section of Graves and colleagues' discussion that covers the adolescent growth spurt is, to my mind, the central issue in the paper. Their review begins with a survey of literature on why a growth spurt exists. Most assume that there is some kind of trade-off between early weaning in humans, brain growth, and a large adult body size–with the optimal solution being slow juvenile somatic growth, fast juvenile brain growth, and they “catch up” of somatic growth during adolescence. Graves and colleagues assert that this pattern was not present in early Homo erectus, and that a more chimpanzee like growth spurt may be a better model.

    The velocity growth curves for human stature and chimpanzee total body length (summed length of crown-rump, femur, and tibia) highlight the difference between modern human and chimpanzee growth and development (Fig. 1). Both species exhibit growth spurts, but these spurts differ in rate, timing, and duration (Leigh, 1996). Pre-pubertal growth spurts in mass have been documented in many primates ([Tanner, 1962], [Laird, 1967], [Timiras and Valcana, 1972], [Leigh, 1996], [Leigh and Shea, 1996] and [Hamada et al., 1996]), but to date only slight increases in crown-rump length and total body length have been observed in chimpanzees (Hamada and Udono, 2002). Male chimpanzees (and possibly macaques) undergo a small growth spurt in length during the period between emergence of the first and third molars ([Watts and Gavan, 1982] and [Tanner et al., 1990]), but peak velocity is not as high and the growth spurt not as extended as in modern human adolescence. The velocity of chimpanzee growth decreases slightly between the ages of four and eight, and then begins to decline rapidly until adult total body length is reached at between 12 and 13 years of age. Chimpanzee growth spurts therefore differ in their onset, offset, and intensity compared to the modern human adolescent growth spurt (see Fig. 1; [Bogin, 1993] and [Bogin, 1996]). The growth spurts in the “ALH 12.3/25%” and “ALH 12.3/50%” curves approximate the juvenile pre-pubertal growth spurt exhibited by chimpanzees, which is of shorter duration and lesser magnitude than the full-blown modern human adolescent growth spurt. We contend that these curves most closely match what is currently known about growth and development in H. erectus but acknowledge that the data currently available limit our ability to choose a single curve. It is also possible that future studies documenting growth in wild chimpanzee length may provide evidence to support a different set of growth curves.

    Their small stature estimate for KNM-WT 15000 doesn't entirely hang on this point, but this assumption about the growth spurt makes more difference than any other single factor.

    We can reasonably ask: is there any other support for this assumption?

    The apparent mismatch between dental and skeletal developmental patterns in the specimen is consistent with the lack of a humanlike growth spurt. But evidence from the skeleton itself is weakened by the fact that KNM-WT 15000 appears to have suffered from some kind of growth pathology, as argued by Latimer and Ohman [2]. The pathology argument has mostly come into play over the issue of vertebral canal size in the specimen, but anything that affected skeletal growth may well have affected the relation between epiphyseal closure and dental eruption. Naturally, if the developmental pathology was a significant influence on growth, then we shouldn't be using WT 15000 as a model for early Homo erectus stature anyway.

    A more relevant argument is that KNM-WT 15000 is really an outlier when we assume that it would have grown to a very tall stature. On first appearance, this seems correct. We have quite a number of femora from Homo erectus, both inside and outside of Africa. Only two of them approach the length that had been estimated for the Nariokotome adult stature estimate. KNM-WT 15000's former adult estimate is the extreme.

    But looking more closely, both those tall individuals come from generally the same time and place as KNM-WT 15000. KNM-ER 1808 and KNM-ER 736 both preserve partial femur shafts with estimated lengths above 480 mm. Both specimens are a bit older than Nariokotome, between 1.6 and 1.7 million years old. KNM-ER 1808 in particular contributed heavily to the argument that early Homo erectus had a very tall stature, because the partial skeleton includes a fragment of pelvis, argued to be female. A tall woman makes for a very tall species.

    Still, these two specimens don't seem as significant in 2010 as they did twenty years ago. The Gona pelvis suggests that we don't really know the sex of KNM–ER 1808. Its pelvic fragment looks female in the context of living human dimorphism, but quite possibly male compared to the Gona individual. Henry McHenry [3] estimated adult statures for the KNM–ER 1808 and KNM–PR 736 femurs, both around 5'10" (180 cm). Those are the tall end of stature estimates for Homo erectus, both taller than average for living humans. But perhaps neither is surprising when taken as the largest and of the distribution that on the whole is relatively small bodied. An estimate of 163 cm for the adult height of KNM-WT 15000, as suggested by Graves and colleagues, would not be an outlier in this population, but neither would an estimate as large as 180 cm.

    So I think the comparative evidence is equivocal. Revisiting the specimen with a smaller estimate is reasonable, but I think our ability to assess the accuracy of any estimate is very limited. In light of the pathology of KNM-WT 15000, it may not be very relevant to understanding body size evolution in early Homo, anyway.

    The main problem facing us with understanding body size in early Homo is deciding which specimens should be included in which taxa. If we exclude everything except the relatively tall ones, like KNM–ER 1808 and KNM–ER 736, then we are going to end up with a tall stature estimate for a population, putatively H. erectus. But if we include some of the smaller specimens, like KNM–ER 993, or KNM–ER 803 – both contemporaries of the Nariokotome skeleton – than the average for this more inclusive population will be a lot lower. In East Africa 1.5 million years ago we can't assign an isolated femur to a species, and we won't have a good answer for this issue until we have many more associated specimens.

    I tend to think that small stature is the null hypothesis now, given our knowledge of the small stature of the Dmanisi hominins, and the moderate body size of middle Pleistocene Homo everywhere else. There are a few specimens that represent individuals as tall as those indicated by KNM-ER 736 and KNM-ER 1808, but none taller, and many much shorter.

    It's a much deeper topic than one skeleton, but the problems assessing stature in that skeleton help to highlight the difficulty of the problem in a global sense.

    UPDATE (2010-09-18): A reader suggests that I give a link to a 2004 paper by Shelley Smith, which compared the dental and skeletal maturation of KNM-WT 15000 to a large growth series of modern Canadians [4]. She found cases in the sample with comparable mismatches of dental and epiphyseal age estimates, and argued that we can't exclude a humanlike growth spurt for early Homo. That's one reason why I think this issue can't be resolved -- the variation in humans is great enough to encompass the known fossil specimens.

    A similar lack of resolution applies to enamel growth increments in KNM-WT 15000 ("Dental growth in early Homo"). The specimen can't be distinguished from Australopithecus, but the range in modern humans is very extensive.

    At the moment, skeletal correlates of growth don't give us the resolution to answer these questions definitively about early Homo. If we had more specimens, we could at least reduce the component of error from sampling, which would help considerably. But we can't expect that anytime soon.

    References

    1. Graves RR, Lupo AC, McCarthy RC, Wescott DJ, Cunningham DL. Just how strapping was KNM-WT 15000?. Journal of Human Evolution. 2010;59(5):542 - 554.
    2. Latimer BM, Ohman JC. Axial Dysplasia in Homo erectus. Journal of Human Evolution. 2001;40:A12.
    3. McHenry HM. Femoral lengths and stature in Plio-Pleistocene hominids. American Journal of Physical Anthropology. 1991;85:149–158.
    4. Smith SL. Skeletal age, dental age, and the maturation of KNM-WT 15000. Am. J. Phys. Anthropol. [Internet]. 2004;125:105–120. Available from: http://dx.doi.org/10.1002/ajpa.10376
    Tags: 
    body size
    Homo erectus
    Nariokotome
    Africa
    Early Pleistocene
    Kenya
    stature
    Synopsis: 
    The Nariokotome skeleton once defined the tall linear body form for early Homo. Now it's 5'4".

  • Shrinking erectus

    Tue, 2010-04-27 10:02 -- John Hawks

    Ann Gibbons reports on the AAPA meetings with a story about all the Homo erectus pelvis and stature papers ("Human ancestor caught in the midst of a makeover," subscription required). Research on the proportions of early Homo was the main event of the meetings, and Gibbons really caught the highlights of the story.

    I wrote about body size in Homo erectus a few months ago, and much of the story follows from the basics I outlined there ("The changing height of Homo erectus"). But there I emphasized that the estimated adult height of KNM-WT 15000 was an outlier in a relatively small body size distribution.

    What I didn't anticipate is that some interesting work might come along to question the tall adult stature estimate for that skeleton. Gibbons describes the work of Ronda Graves and colleagues, presented at the meetings:

    Using intermediate growth rates, graduate student Ronda Graves of Stony Brook University in New York state calculated that Nariokotome Boy would have had less time than originally predicted to reach his adult height when he died. She estimated at the meeting that he would have reached 163 cm in height and 56 kg in weight as an adult—"shorter and wider" than previously thought.

    This seems very short, at least when I first saw it. On reflection, Ohman and colleagues (2002) had provided a stature estimate at death of KNM-WT 15000, as only 147 cm, and they suggested it might have been as short as 141 cm. That's an awful lot shorter than had previously been estimated on the basis of regressions.

    If Graves and colleagues are right about the lack of a human-like growth spurt, an additional 20 cm (8 inches) wouldn't be unusually small for an adult stature. Those stature estimates would put KNM-WT 15000 between the 50th and 90th percentiles for American 10-year-old boys, or between the 25th and 75th percentiles for 11-year-olds. By contrast, an adult stature of 163 would be around the 3rd percentile for adult American men. The assumptions about growth totally determine the outcome for adult height.

    The credibility of the growth assumptions can only be tested by looking at other adult and juvenile remains. There is much more to say on this topic, but I'll point out one relevant comparison: The estimated stature of the adult skeleton from Dmanisi, including the complete D4167 femur and D3901 tibia, is between 145 and 166 cm. Graves' KNM-WT 15000 stature estimate is right within this range.

    Meanwhile, there was a lot of disagreement about hips.

    [Scott] Simpson and Linda Spurlock of the Cleveland Museum of Natural History realigned the pieces of Nariokotome Boy's pelvis, guided by a female H. erectus pelvis from Gona, Ethiopia, that Simpson reported 2 years ago (Science, 14 November 2008, p. 1089). They found that the widest measure from side to side on the boy's pelvis is 255 to 260 millimeters rather than 225 to 230 mm. This would give the boy an adult hip breadth of 295 to 301 mm rather than the 266 mm originally proposed, and would match those of the short, wide-hipped female from Gona, whose pelvic breadth was 288 mm. "H. erectus was not simply a small-brained modern human," says Simpson.

    Simpson's reconstruction seemed reasonable, and it's actually not that big a difference -- roughly an inch and a half (3 cm) in bi-iliac breadth. The main differences were in the overall shape of the pelvis, being shorter with a more flaring iliac blade.

    Gibbons describes the disputation that happened after Chris Ruff's presentation. Ruff has suggested that the Gona pelvis may not represent Homo -- that its broad proportions and small acetabula (hip sockets) suggest it may have belonged to an australopithecine (presumably, A. boisei).

    Much of the disagreement comes down to the estimation of femur head diameter from acetabulum breadth -- Ruff (2010) gave an estimate of 32.6 mm, Simpson and colleagues estimated between 35 and 36 mm, based on a different method. What you would want is enough acetabula of both genera to be able to examine their variation directly. We don't have such a sample; what we have are a few acetabula and several femur heads. We have the additional problem that living people seem to have a different relation of femur head and acetabulum diameters than in other anthropoids, and it's not obvious which should be applied to early hominins.

    I guess (in the relative absence of data) that this acetabulum diameter of the Gona pelvis was in the zone of overlap between Homo and Australopithecus. There's no question that later Homo -- say after 1 million years ago -- is substantially larger in acetabulum diameter, from every specimen so far described. But there are occasional small specimens of Homo even in the Middle Pleistocene. At 1.15 million years old, the Gona specimen is more than 300,000 years later than the last known occurrence of Australopithecus. The femur head that would fit the Gona acetabulum would be smaller than KNM-ER 1472 or D4167 from Dmanisi, both around 40 mm. At least one australopithecine femur head (AL 333-3) is that large, so the femur head diameter distributions do overlap. The STW 431 acetabulum diameter is a sliver larger than that of the Gona pelvis (Ruff 2010 makes it 3 mm bigger, but other workers have given a smaller estimate). SK 3155 may well be Homo and has a smaller acetabulum.

    Of course, if we go as far as SK 3155, we have to consider the topic of the Malapa innominate. Can we tell small-bodied Homo from Australopithecus on the basis of pelvic morphology? Several people writing about the Gona pelvis have made it sound like a bigger version of Lucy's. But that's not really true. The australopithecine-like appearance comes from its breadth and consequent features, including the long pubes and flaring anterior ilia. The rest? Maybe there's something here for a clever anatomist.

    UPDATE (2010-04-27): I have some e-mail about the last occurrence of A. boisei, which I wrote above was more than 300,000 years older than the Gona pelvis.

    The most potent counterargument is Swartkrans Member 1, which has uranium-lead dates around 830,000 years ago, and has been placed by many workers around a million years ago. I actually hadn't been thinking of South Africa. But it is relevant, as the East African record between 1.4 and a million years ago may not be strong enough to argue that the last occurrence of A. boisei is really very close to the extinction time.

    Meanwhile, there is OH 36, an ulna from Olduvai Gorge that may represent A. boisei. Since it's (obviously) not cranial, and is quite large and robust compared to postcranial remains that are associated with A. boisei, I've always been very skeptical of that assessment. If there's one feature of the ulna that actually has some phylogenetic importance in the Early Pleistocene, I figure it's size.

    But given the current question about body size, that reason for skepticism may have receded in importance. On the other hand, OH 36 seems to represent a substantially bigger individual than the Gona pelvis, so maybe introducing robust australopithecines into the mix doesn't help anything.

    Several things puzzle me. Even into Member 1 times, Swartkrans is dominated by A. robustus, with very little Homo. In East Africa, A. boisei is never quite so predominant in the hominin assemblage as the case in South Africa, but was nevertheless very common up to 1.5 million years ago. Did it persist much later? Was it cryptic from the point of view of the fossil record? Are the Swartkrans dates older than we think?

    References:

    Gibbons A. 2010. Human ancestor caught in the midst of a makeover. Science 328:413. doi:10.1126/science.328.5977.413

    Ohman JC, Wood C, Wood B, Crompton RH, Günther MM, Yu L, Savage R, Wang W. 2002. Stature-at-death of KNM-WT 15000. Hum Evol 17:129-141. doi:10.1007/BF02436366

    Ruff C. 2010. Body size and body shape in early hominins -- implications of the Gona pelvis. J Hum Evol (in press) doi:10.1016/j.jhevol.20 09.10.0 03

    Tags: 
    body size
    stature
    East Africa
    Homo erectus
    Malapa
    A. robustus
    pelvis
    Early Pleistocene
    Swartkrans
    Gona
    KNM-WT 15000
    A. boisei
    meetings
    Synopsis: 
    The 2010 AAPA meetings featured a fight about the Nariokotome and Gona pelves.

  • Body size in Holocene southern Africa

    Mon, 2006-02-13 23:04 -- John Hawks

    I was just taking notes on this paper by Sealy and Pfeiffer (2000), and found some good quotes about body size in the Bushmen, both historically and in archaeological samples:

    Historical and ethnographic sources consistently indicate that Khoisan peoples were and continue to be petite. A group of early-20th-century San studied by Dart (1937a, b) had mean statures of 155.8 cm (males) and 146.1 cm (females). Decades later, the Harvard Kalahari study found mean statures of 160.9 cm (males) and 150 cm (females). These values are comparable to the fifth centile of adult stature for contemporary North Americans (Abraham 1979). Adult weights reported for the more recent individuals are 47.9 kg (males) and 40.1 kg (females) (Truswell and Hanson 1976).

    It has been claimed that environmental stressors, especially shortages of food, affected growth (Dornan 1975:80; Almeida 1965:6). The secular trend towards increasing stature among mid-20th-century Khoisan (Tobias 1978) could be seen as evidence for the influence of environmental factors.

    At the same time, there is a genetic component. Low stature persists even under apparently favourable health conditions. The small body size and lean physique of living Khoisan peoples are often cited in human population biology texts as exemplary of adaptation to a hot, sometimes specifically desert, climate. Their low body-mass index is portrayed as support for Bergmann's and Allen's rules (cf. Molnar 1998, Relethford 1997). Through study of archaeologically derived materials, these hypotheses can be explored.

    That's on the historic record. They examine a number of skeletons from archaeological sites and report this:

    Dimensions of selected bones from the southern Cape sample are summarized in table 2. Data from one exceptionally small skeleton (UCT 345, probably a dwarf) and the three most recent skeletons with anomalous isotope values (Sealy 1997) are not included in the summary statistics for body size. The mean stature calculated from 20 male femora is 157.8 cm (s.d. = 7.9). Twenty-three female femora have a mean estimated stature of 146.9 cm (s.d. = 10.5). Greater variability among females results from some very small individuals between 4,000 and 2,000 B.P. (see fig. 4). Body size, represented by femoral head diameter to maximize sample size and divided into five sex categories, is plotted against radiocarbon date in figure 5. This figure illustrates that the smallest individuals (femora

    That's 4'10'' for females; 5'2'' for males in the archaeological sample. Bi-iliac diameter for males was 214.6 ± 16.8, for females 209.0 ± 12.3.

    Tags: 
    recent evolution
    Africa
    Holocene
    body size
    hunter-gatherers
    South Africa
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