john hawks weblog

paleoanthropology, genetics and evolution

A. africanus

  • Orangutan loris capture and meat-eating

    Fri, 2012-01-20 16:38 -- John Hawks

    Madeleine Hardus and colleagues [1] describe long-term observations of hunting by Sumatran orangutans.

    The paper is straightforward in its description of the hunting observations: They hunt slow lorises, the practice is rare, it occurs at times when their other preferred foods are scarce, some individuals hunt but most don't, and food sharing among individuals other than mother-infant pairs wasn't observed. This isn't the first time hunting has been reported by wild orangutans, what it does is report a longer-term observation of one hunting female, tying this case to earlier observations.

    I'm pointing to the paper because it includes some discussion about the requirements of meat eating for early hominins. These orangutans take a long time to chew up a slow lorus.

    Orangutans used more than twice the amount of time (160.9 g/h) to eat the same amount of meat than chimpanzees (348 g/h) (Wrangham 2009; Wrangham and Conklin-Brittain 2003). Other chimpanzee data shows that this species is able to consume meat at much higher rates, i.e., 1.9±1.2 kg/h (Gilby 2006). This difference between orangutans and chimpanzees may suggest that higher sociality in chimpan- zees influences intake rates, where individuals are surrounded by conspecifics when eating meat, and where meat is a highly preferred food item and stealing occurs (Boesch and Boesch 1989; Goodall 1986; Stanford 1999).

    I'll point out that orangutans may make a better model for early hominin jaw mechanics than chimpanzees do, because the sizes of jaw musculature and teeth are more comparable. Neither orangutans nor australopithecines have teeth that look well-made for reducing fibrous, tough meat into smaller pieces. Recent humans have been able to cook meat, which reduces its mechanical resistance to chewing. Early hominins didn't cook, so getting some high fraction of their caloric requirements from meat (even if only seasonally) might have taken a lot of time.

    According to orangutan data (ingestion rate of 185 kcal/h), Australopithecus africanus would have had to chew for ca. 2 h to achieve 25% of these caloric requirements purely from meat (Table III, orangutans×A. africanus), while achieving the remaining 75% of its caloric requirements from food sources with faster chewing/intake rates, e.g., leaves or insects. This constitutes a considerable period of the day for orangutans, which spend ca. 6 h/d feeding (Morrogh-Bernard et al. 2009), and does not include the time necessary for the collection of vertebrate prey.

    That sounds like a lot of chewing time, but it's not an insuperable barrier. The isotopic values for A. africanus and A. robustus suggest the possibility of up to 25% meat consumption, although they may have gotten C4 plant input by several different food sources (e.g., corms, edible stems, aquatic animals) as well as meat. Altogether, the chewing time analysis shuts off one line of argument that early hominins would have faced extreme constraints preventing them from moving to a more meat-intensive diet before the control and routine use of fire.

    References

    1. Hardus ME, Lameira AR, Zulfa A, Atmoko SUS, Vries H, and Wich SA. 2012. Behavioral, Ecological, and Evolutionary Aspects of Meat-Eating by Sumatran Orangutans (Pongo abelii). International Journal of Primatology.
    Tags: 
    orangutans
    diet
    apes
    hunting
    meat
    A. africanus
    Synopsis: 
    A discussion of early hominin meat-eating emerges from observations of orangutan hunting

  • Meet Homo habilis

    Mon, 2011-11-07 23:44 -- John Hawks
    Synopsis: 
    A tour of four crania of Homo habilis

    This station has several of the key cranial specimens of Homo habilis, together with Sts 5, the representative of Australopithecus africanus. The H. habilis specimens include:

    • KNM-ER 1470, from Koobi Fora, Kenya, 1.9 million years old.
    • KNM-ER 1813, from Ileret, Kenya, 1.65 million years old.
    • OH 24, from Olduvai Gorge, Tanzania, 1.8 million years old.

    Another skull, KNM-ER 1805, is also included here. This skull may also represent H. habilis, or it may be something else.

    What to do: Examine the H. habilis crania compared to A. africanus and early Homo erectus. What makes these skulls more like Homo than Australopithecus?

    KNM-ER 1470 and KNM-ER 1813 are very different in size. Are they male and female of the same species, or do you think they are different species?

    What is KNM-ER 1805?

    Study terms: 
    Homo habilis
    Homo erectus
    Koobi Fora
    Australopithecus africanus
    Olduvai Gorge
    Tags: 
    laboratory
    explainer
    Anthropology 105
    Homo
    Homo habilis
    Homo ergaster
    A. africanus

  • Meet Australopithecus africanus

    Mon, 2011-10-31 23:30 -- John Hawks
    Synopsis: 
    Laboratory giving some time with fossil casts of A. africanus.

    This station has several casts of remains attributed to the species, Australopithecus africanus. This was the first australopithecine species discovered, and for many years was the earliest known species of hominids. In another station you can see the morphology of the pelvis of A. africanus. In this station, you'll see some crania and mandibles.

    The fossils come from two sites in South Africa: Sterkfontein, which dates to around 2.6 million years ago, and Makapansgat, which is a bit older, around 2.8 million years old.

    What to do: Take some time to become familiar with the fossils.

    • Several of them have teeth. Are they all adult or are some juveniles?
    • Seriate the dentitions in order from largest to smallest. What do you make of the differences in molar dimensions?
    • Look at the skulls from behind. How would you describe the shape of the outline of the skull from this view?
    Study terms: 
    Australopithecus africanus
    Sterkfontein
    Makapansgat
    Taung
    Tags: 
    Anthropology 105
    laboratory
    explainer
    A. africanus

  • Aging juvenile fossil hominins

    Tue, 2011-10-25 00:27 -- John Hawks
    Synopsis: 
    Laboratory exercise giving the opportunity to examine the development of juvenile hominin jaws.

    The fossil record is not made up only of adults. We have abundant skeletal evidence from juvenile individuals of a broad range of ages. At this station you will find model mandibles and maxillae from human children of a range of ages. These provide a comparison for the casts at the station, each of which represents a fossil hominin specimen from Africa, between 3.6 million and 1.5 million years ago.

    The mandibles represent several different species. They include:

    1. OH 7, from Olduvai Gorge, Tanzania. This is the type specimen of Homo habilis, around 1.75 million years old.
    2. MLD 2, from Makapansgat, South Africa. This is an early specimen of Australopithecus africanus, around 2.7 million years old.
    3. LH 2, from Laetoli, Tanzania. An early specimen of Australopithecus afarensis, it is around 3.6 million years old.
    4. SK 47, from Swartkrans, South Africa. This is a juvenile specimen of Australopithecus robustus, around 1.5 million years old.

      5. A selection of other mandibles, including some adult mandibles of the same species, is also available. Examine these in comparison with the modern dental models. Which teeth are present in the fossil specimens? What teeth are in the process of eruption? What do they tell you about the ages of the individuals?

    Study terms: 
    eruption
    occlusion
    Laetoli
    Koobi Fora
    Swartkrans
    Homo habilis
    Australopithecus afarensis
    Australopithecus africanus
    Makapansgat
    Tags: 
    A. afarensis
    A. africanus
    Australopithecus
    Homo
    development

  • 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. 2011. Little Foot, Big Mystery. Science 333:1374 - 1374.
    Tags: 
    Sterkfontein
    A. africanus
    South Africa
    body size
    field sites

  • Through the early Homo archives

    Mon, 2011-08-29 22:32 -- John Hawks

    I've enabled the search function for the site, which you'll find at top right on each page of the site. The search index is still rebuilding, and as I write this has only indexed 4% of the site. That brings it up to late 2007, and it's interesting to go back through the history of paleoanthropology that way.

    For example, I ran across my comments ("Is a lack of fossils the problem with early Homo?") on a John Noble Wilford piece from four years ago. Seems very timely in many ways. For example, the paucity of the fossil record of Homo before 1.6 million years ago was a major feature of the article. I directed my attention to the supposed "gap" between 3 and 2 million years ago:

    [W]e actually have quite a lot of fossils from this time period. The entire South African A. africanus fossil record, with the exception of a few early specimens like STW 573, come from this "gap." A fairly extensive record of the appearance and evolution of early robust australopithecines comes from this time period in East Africa.

    And, here and there, a few specimens look Homo-like. Wilford's article discusses AL 666-1. To this we can add the Uraha mandible, Omo 75-14, an additional series of teeth from Omo, and possibly the Bouri BOU-VP 35/1 skeleton.

    Properly considered, the rarity of early Homo in these contexts is not a problem; it is information.

    Of course, dates have changed. We now have good dates for Dmanisi, which make those fossils the earliest well-attested Homo erectus sample at 1.8 million years. STW 573 now looks late, not early. But the fact remains that people were looking for pure representatives of Homo in the fragments instead of exploring morphological diversity within the large and fairly complete samples at hand.

    Tags: 
    Homo
    Homo erectus
    Sterkfontein
    A. africanus
    Hadar

  • Mailbag: Diet and isotopes

    Tue, 2011-03-29 19:34 -- John Hawks

    Re: "Tartar control and Neandertal plant use".

    In your review of the study on Neadertals and grain in dental calculi, you wrote the following:

    "The remains of starch grains and phytoliths tell us about diet breadth but not the proportions of different foods. They do note that nitrogen stable isotopes are most informative about protein-rich food sources, so that a substantial consumption of starchy plants such as grains and USOs might be hidden by isotope analysis."

    I also read this study, and I was curious about this comment in the discussion, as this is way outside my field of expertise. I was wondering if you could write a blog post commenting in more detail about what isotope data can and cannot tell us about the proportion of foods or food groups eaten by pre-historic populations, or if you have already done so, if you could direct me there.

    Many thanks for writing! You've been doing some nice work there.

    I have a long essay on the stable isotopes and diet:

    http://johnhawks.net/weblog/reviews/early_hominids/diet/stable_isotopes_...

    And two that deal more extensively with Neandertals and nitrogen isotopes:

    http://johnhawks.net/weblog/fossils/neandertal/neandertal_mammoth_diet_2...

    http://johnhawks.net/weblog/fossils/neandertal/neandertal_fish_drucker_2...

    And here's one about cave bears:

    http://johnhawks.net/weblog/reviews/behavior/non-primate/ursus/cave_bear...

    But all these are out of date in some respects. I've since had several conversations about the nitrogen isotopes. One thing that elevates 15N is breastfeeding, so the time of enamel formation relative to weaning makes a big difference. In more recent populations, the isotopes are often employed to give a picture of the place of birth relative to where the bones were found. A more comprehensive review is in order, but I'm not sure what the next find will be in hominins.

    Anyway, I hope that helps, and thanks again for the kind words!

    Tags: 
    A. robustus
    Neandertals
    A. africanus
    diet
    non-primate

  • What, if anything, is Australopithecus sediba?

    Thu, 2010-04-08 22:46 -- John Hawks

    Today we finally get to learn about the exceptional discovery of four partial hominin skeletons from Malapa Cave, South Africa. Two of the fossil skeletons are described by Lee Berger and colleagues in the current issue of Science, descriptions of two more are still forthcoming.

    A kind journalist sent me a copy of the research papers a few days ago, so my graduate students and I have had a chance to think about them a little bit and compare them with other material.

    Berger and colleagues have named a new species to contain the fossils, Australopithecus sediba. For anybody who follows paleoanthropology, the new species won't be surprising -- if I found a fossil, I'd surely make up a new name for it, even if I thought it was my great-great-grandmother. In this case, the morphological reasons for naming a new species aren't trivial, but I'll begin by approaching them skeptically, especially in comparison with the large samples of South African fossils both earlier and later than Malapa. I'll conclude that a new species within Australopithecus was probably the right call, but not an easy one.

    The press is running with a "new fossils provoke debate" storyline -- are they possible ancestors of Homo or not?

    The simple answer to that question is that the Malapa skeletons are too late to be ancestors of Homo. After all, we have early Homo nearly a half-million years earlier.

    A more complicated answer is that it depends what we mean by Homo. My feeling is that these skeletons don't comport with what most of us mean when we say "Homo". Most of us have in mind an adaptive shift from Australopithecus to Homo that included larger brain size as a significant element, and the MH1 skeleton has a small endocranial volume.

    But if we accept that model of Homo, we have to accept its consequences, as the Malapa skeletons now make clear. One important consequence is that, if we assume that MH1 isn't Homo, we can no longer say have any skeletal evidence of Homo from before 1.95 million years ago. Because the Malapa specimens are more like Homo in their dental and mandibular features than are earlier specimens that have usually been called Homo.

    And if we throw out all those earlier Homo specimens...well, then suddenly Malapa isn't too old to be an ancestor of Homo after all.

    How old are they?

    The fossils lay above a flowstone with a U-series and paleomagnetic date consistent with an age just around 2 million years ago. That's a maximum age for the fossils; they must be younger than that.

    The hominins are in water-deposited sediments, which are inferred to represent ancient washes of subterranean water flows through the cave system. Two elements above the flowstone contain the hominin specimens, called facies D and E, and both have normal magnetic polarity. The most likely interpretation is that they belong to the Olduvai paleomagnetic subchron, which occurred between 1.95 and 1.78 million years ago. A specimen of the sabertooth cat Megantereon in one of these facies has a last appearance elsewhere in Africa at 1.5 million years ago. So it appears that 1.78 million years is a very likely minimum age for the fossils.

    That's about as good as dating gets in South Africa, where we're used to seeing very wide age brackets on hominin-bearing localities. It means that the Malapa hominins lived at around the same time as KNM-ER 1470 in the Turkana basin, or OH 24 at Olduvai Gorge. Until today, I think we could justly claim that the only australopithecines still known to occur in this time interval were the robust species A. boisei and A. robustus -- although the first appearance of A. robustus might (might) be later than Malapa.

    Why aren't they A. africanus?

    To me, this is the hardest question to answer.

    The Sterkfontein Member 4 sample of A. africanus is tremendously variable. The postcrania of both Malapa skeletons are tremendously informative, but fall within the range of variation at Sterkfontein for almost every feature that the authors reported. The few exceptions (such as humeral torsion and femur neck/shaft angle) are right at the edge of the Sterkfontein range.

    Malapa skeletons

    In other words, it's my impression that the postcrania of the Malapa skeletons fit within A. africanus. The limits of my impression are that there are a whole lot of observations here, and the paper generally does not report metrics for the postcrania. Maybe the sequel will give us some more surprises.

    I would have added a comparison with the Swartkrans A. robustus sample, which overlaps nearly totally in body size with Sterkfontein and contains elements that are in some cases more comparable to the Malapa skeletons. In particular, the os coxa of MH1 looks a lot like SK 3155, and the proximal femur looks like SK 82 to me, at least in the tiny picture provided with the paper. On the whole, I don't think that the Malapa hominins are particularly like A. robustus, I just think that if you put together a reasonably large sample of australopithecine postcrania, these two skeletons don't stand out.

    I'll take up the discussion of proportions of the different elements below. My feeling is that the proportions aren't exceptional for Australopithecus, either, but we have to temper that against the observation that really only AL 288-1 (Lucy) is comparable, and it's more than a million years older.

    What about the teeth? Generally speaking, the teeth of MH1 and MH2 are both at the small end of the A. africanus range. In a couple of cases (the lower canine of MH1, the lower second molar of MH2), the teeth are absolutely smaller than any Sterkfontein individual. The canines are within the range of A. robustus (remember that the robust australopithecines have small anterior teeth), but the premolars are nothing like the large, molarized Swarktrans sample of premolars.

    They're a little small but within the range of those known for Homo habilis at Olduvai Gorge. For example, OH 7 -- the type specimen of Homo habilis has molars that are 1.5 mm larger than MH1 in both dimensions.

    But then, Homo habilis really doesn't differ much in tooth size from Sterkfontein.

    In size, the Malapa teeth are exactly what you would expect for Homo erectus. The first molars are smaller than those of Dmanisi D2700/D2735, for example. But unlike H. erectus dentitions, the molars of the Malapa hominins get bigger toward the back -- M3>M2>M1.

    The Malapa mandibles are strikingly gracile. The MH1 mandible has a relatively vertical symphysis with a small cross-section. The long, parallel upper and lower corpus borders really strike me like a mandible of Homo erectus, something like KNM-ER 993 or OH 22 -- but this impression may be exaggerated considering the M3 of MH1 has yet to erupt. Metrically, the corpus breadth and height are most like OH 13. There are small australopithecine specimens that compare to this, such as AL 277-1, and it is worth remembering that MH1 is a juvenile mandible. I can't compare the ramus heights with those of other samples because the authors don't report those measurements.

    An interesting question: If these mandibles had been found in isolation, would we call them Australopithecus? The Olduvai H. habilis mandibles OH 7 and OH 13 have M3>M2>M1, while OH 16 has M2>M3>M1. The Malapa mandibles look much more like later Homo than do early Turkana basin mandibles like KNM-ER 1801, KNM-ER 1802, or KNM-ER 1482, all of which are much more robust and have larger, more molar-shaped premolars than MH1, and all of which have M3>M2>M1 except KNM-ER 1802 which lacks M3. This is a quick comparison on my part, but I think the Malapa mandibles look more like Homo than does the existing hypodigm of Homo habilis. It's hard to imagine that the mandibles in isolation would have been referred to Australopithecus. More on that below.

    Compared to the mandibles, the cranium of MH1 looks more like its counterparts from Sterkfontein. To be sure, it is an 11-13-year-old juvenile and more gracile in some respects than any of the Sterkfontein crania. But take a look at it next to Sts 71:

    MH1 next to Sts 71, frontal view

    MH1 (left) next to Sts 71 (right)

    They're not identical, naturally. Sts 71 has higher temporal lines, a slightly smaller vault, and more prominent cheeks. It also has more postorbital constriction compared to MH1, though that isn't obvious from this angle. MH1 has a true superorbital torus, Sts 71 has at best a shade of one. But you can see the similarities -- the angle of the zygomatic process of the maxilla, the narrow and concave interorbital region, the tall and narrow orbits. MH1 has no prominent anterior pillars (bony swellings on either side of the nasal aperture), but Sts 71 is not very different in this region. Sts 71 has bigger teeth.

    Consider also Sts 52:

    MH1 next to Sts 71, frontal view

    MH1 (left) next to Sts 52 (right)

    Again, Sts 52 has anterior pillars and bigger teeth, but the shape of the face is very comparable between these two. The nasal bones in particular are similar in this pair, almost "pinched" at the midline, with a lateral expansion both superiorly and inferiorly.

    We can do a similar exercise for most of the features of the MH1 cranium. What is exceptional, in the context of the Sterkfontein sample, is the overall gracility of the masticatory apparatus.

    One important thing that is not in the least bit exceptional: Its brain. An endocranial volume estimate of 420 ml (from CT reconstruction) puts MH1 at the bottom of the range of variation at Sterkfontein -- the best-known skull from Sterkfontein, Sts 5, has a volume of 485 ml, while STW 505 has a volume larger than 550 ml. Before MH1, the smallest of the South African crania were estimated to have volumes of 428 ml. This one seems to be smaller mainly by being flatter -- a shape that it shares with early Homo, but I wouldn't say it was without parallel in Australopithecus.

    But the smallest endocranial volume known for early Homo is KNM-ER 1813, at 510 ml. That specimen is extreme: the next smallest is 585.

    The vault fits in A. africanus, most of the facial features have comparable specimens in the Sterkfontein sample, with some exceptions, and the postcranial skeleton is unexceptional. The teeth are mostly within the range at Sterkfontein with some exceptions. But the mandible -- like those few facial characters -- stands out.

    Australopithecus sediba -- a new species within Australopithecus -- then seems like a fair diagnosis. The craniodental derived features are of the sort that would usually justify a new species. Heck, in the case of Kenyanthropus, even more minor differences in the face and size of teeth from contemporary A. afarensis caused Leakey and colleagues (2001) to name a new genus.

    Is MH1 really a male?

    Berger and colleagues (2010) infer that the MH1 skeleton (the one with the skull) is a male. It is large and more robust than the MH2 skeleton: Its teeth are bigger than the MH 2 skeleton, its mandible is more robust with a taller ramus, the articular ends of its limb bones are a bit larger. In addition, the greater sciatic notch on its preserved os coxa is narrower than other australopithecines like Lucy and Sts 14, and the pelvic inlet may (based on the anterior position of the auricular surface) have been smaller.

    But the skeleton isn't really very big. Its endocranial volume is small, its long bones are not nearly so robust as some australopithecines. There are large male australopithecine skeletons -- STW 431, for example -- and MH1 doesn't seem so large as these. Again, it's hard to tell without postcranial measurements, but the sex of this specimen isn't a clear call either way.

    The sex of the specimen is important to the way we interpret it, because the features that make it stand out from A. africanus concern masticatory gracility. If it's a female, it doesn't seem quite so different from A. africanus as if it's a male.

    Are they Homo?

    Let's start with the brain size, which at 420 ml seems to be the most obvious thing separating MH1 from our genus. Well, except for Liang Bua 1 -- with its endocranial volume of, um, 420 ml. Is brain size fundamental to Homo? Maybe. Maybe not.

    Alan Boyle's report on the fossils ("Fossils shake up our family tree") has an excellent letter from Don Johanson, who makes the argument that the Malapa fossils should be assigned to Homo. Of course, Johanson and Bill Kimbel in 1996 described a 2.33-million-year-old fossil from Hadar as the earliest clear maxilla of Homo. That maxilla, AL 666-1, resembles Homo in having a more vertical subnasal profile, a parabolic dental arcade, molars that are long relative to their breadth, and a "squared-off" jaw that is relatively straight across the anterior dentition. In other words, basically the dental features seen in the MH1 maxilla.

    We've got two choices. Maybe these are genuine shared derived features with these specimens and Homo -- in which case, we should probably name them Homo, as Kimbel and colleagues did for AL 666-1.

    Or, there were several australopithecines after 2.5 million years ago with these dental and maxillary (and for the Malapa hominins, we can add mandibular) characters. In which case, they're not signs of Homo at all. They may reflect parallel dental reduction in several australopithecine lineages, all of which faced niche differentiation from the emerging robust australopithecines. One of those lineages may have given rise to Homo, but we don't know which. Maybe it was South African, but it need not have been. It could even have been Asian.

    The question is just how important we think brain evolution was to the origin of our genus. If the brain was the key adaptation, then Malapa shows that the dental features are irrelevant to the brain -- because these skeletons have more dental reduction than most of the East African Homo habilis sample, but MH1 has a much smaller brain.

    What about tool manufacture?

    Part of the logic of pre-2-million-year-old Homo is the emergence of stone tool manufacture 2.6 million years ago. It stands to reason that this major shift in behavior and diet might have given rise to a new adaptive plateau for early hominins, and that would have been tied to the evolution of larger brains. The problem is that we don't have larger brains in any fossil remains until after 2 million years ago -- KNM-ER 1470 remains the earliest hominin with a brain larger than 600 ml. Up to now, people have conjectured that large-brained hominins may have existed earlier, even to the point of arguing about the brain size reflected by the otherwise-robust temporal bone from Chemeron. But it's worth pointing out that none of these pretenders to the Homo throne have smaller teeth than A. africanus. The diet shift that should have been made possible by a meat-eating stone tool economy didn't lead to smaller teeth until much later.

    And now we know that at least one small-toothed hominin also was a small-brained one.

    We don't know whether the Malapa hominins would have been toolmakers. The fact that they weren't found with tools isn't really evidence either way. Dirks and colleagues (2010) suggest that the skeletons were deposited by water washing them from an initial death trap into a secondary location. If true, it would be a miracle beyond belief for stone artifacts to have made the trip with them.

    We do know that stone tools are present in Sterkfontein Member 5 and Swartkrans Member 1, and cutmarked fauna are in the latter. Both these may be roughly contemporaneous with the Malapa hominins, depending on their date. So toolmaking hominins were in the immediate area, around the time that the Malapa hominins lived.

    SK 847 is from Member 1 of Swartkrans, and could be as old as the Malapa skeletons. Its endocranial volume isn't known, but facially it looks even more like Homo erectus than does MH1. It seems plausible that this skull represents the local toolmaking population, but even so, this skull does resemble MH1 in several respects, and again we don't know its volume. STW 53, probably a bit older than Sterkfontein Member 5, has also often been referred to Homo but it definitely doesn't have a substantially larger endocranial volume than MH1.

    So again, we seem to be faced with two choices: Broaden the definition of Homo to include this very australopithecine-like sample, or restrict it to later large-brained hominins. In either case, brain size and tool manufacture do not necessarily go together.

    What's the single most obvious thing that the paper doesn't describe?

    Which brings me to the fingertip. MH2 has a distal phalanx. The paper doesn't describe it, even though this bone element has taken on such importance in the evolution of Homo compared to Australopithecus. Big fingertips are supposed to be adaptations to force transfer through the fingertip grip used in tool manufacture.

    The picture of the thing is so tiny -- I mean, literally we're talking about two pixels of finger -- that I can't make anything out of it. Does it have a large apical tuft, like OH 7? Or is it like the Hadar distal phalanges, with narrow, apelike apical tufts?

    If one was wondering about whether the thing was Homo or not, I would think this is one of the first things you would check....

    What about those limb proportions?

    For fifteen years, a bunch of otherwise sensible paleoanthropologists have been engaged in a debate about the limb proportions of A. africanus and H. habilis. The reason why this particular question may not be sensible is because the debate is about the length of the arm relative to the leg, but there's no specimen of A. africanus that preserves both the length of the arm and the length of the leg.

    What there are: OH 62, a skeleton apparently of H. habilis that has a complete humerus and more than half the length of one femur, STW 431, which has an acetabulum and mostly complete humerus, and Sts 14, which has a partial femur, an acetabulum, and a piece of distal radius. On the basis of these fossils, we've seen some intense debate about the reconstruction of the OH 62 femur length, and a lot of discussion about whether the sizes of articular surfaces are relevant to the function of the limbs. Indirectly, it has appeared that A. africanus and H. habilis shared longer arms than were present in AL 288-1 (Lucy).

    Well, now we have two fossil skeletons with both hindlimb and forelimb elements. The paper doesn't address the issue directly, nor does it provide raw measuremnets that would lead to a quick answer. But the humerus is short relative to the size of the femur head, compared to earlier hominins, while a bit long relative to Homo by the same comparison. So it looks like the Malapa skeletons may be somewhere in between.

    The authors do argue that OH 62 is an odd skeleton in one respect: They consider the "diaphysial strength" of the humerus and femur. This is a cross-sectional measure of the area of cortical bone, and reflects the robusticity of both forelimb and hindlimb elements. In their estimation, OH 62 has a much stronger arm relative to its leg strength than the Malapa skeletons.

    It's not obvious how to interpret this observation. Is OH 62 more apelike in its locomotor pattern than Malapa? Or does the strength ratio vary allometrically with body size, and OH 62 is just at the smallest end of the comparison? Hard to tell without the length measurements.

    OK, what's the bottom line?

    Here's the important thing. From today forward, there are a bevy of features of the face, teeth and jaw that are no longer "derived characters" of Homo.

    Some people will want to fix this by broadening the definition to Homo to include the Malapa skeletons. Others will want to narrow the definition of Homo to include only large-brained specimens.

    Every specimen attributed to Homo before 2 million years ago is now up for grabs. Maybe they're Homo, or maybe their resemblances to Homo are just masticatory parallelism. We already know that parallelism explains many of the derived locomotor and masticatory resemblances of great apes, and many strongly suspect that parallelism explains the derived masticatory resemblances of robust australopithecines. If the dental reduction that once was a marker of Homo joins this list, it will hardly be surprising.

    If we follow the logic that connects tool use to dental reduction, however slowly and indirectly, then I think we have to conclude that A. sediba was likely a toolmaker and meat-eater. This hypothesis is testable, both by bone chemistry and dental morphology and wear.

    Malapa suggests the hypothesis that brain evolution followed the appearance of stone tool manufacture by a considerable delay. If so, I wonder what exactly caused the brain to expand. Did the diet shift to higher-quality foods unfold over a long time, allowing brains to expand only after 3/4 million year delay? Or was brain evolution caused mostly by non-dietary factors, such as social dynamics or climate instability?

    Or did the evolution of our genus happen somewhere else, far from the places where we currently have fossil samples? The Rift Valley and South African cave systems may have been wonderful for preserving fossils, but who's to say they weren't relative backwaters when it came to the evolution of Homo?

    Well, I'm running out of gas for this installment. More later....

    References:

    Berger LR, de Ruiter DJ, Churchill SE, Schmid P, Carlson KJ, Dirks PHGM, Kibii JM. 2010. Australopithecus sediba: A New Species of Homo-Like Australopith from South Africa. Science 328:195. doi:10.1126/science.1184944

    Dirks PHGM, Kibii JM, Kuhn BF, Steininger C, Churchill SE, Kramers JD, Pickering R, Farber DL, Mériaux A-S, Herries AIR, King GCP, Berger LR. 2010. Geological Setting and Age of Australopithecus sediba from Southern Africa. Science 328:205. doi:10.1126/science.1184950

    Tags: 
    Malapa
    A. sediba
    South Africa
    Homo erectus
    locomotion
    diet
    Homo habilis
    A. africanus
    tool manufacture
    Australopithecus
    Synopsis: 
    New skeletons from Malapa, South Africa, present surprising evidence about the evolution of our genus.

  • Ankles of the australopithecines

    Tue, 2009-04-14 16:54 -- John Hawks

    Recent University of Michigan Ph.D. Jeremy DeSilva gets some nice press about his work demonstrating that fossil hominins didn't climb like chimpanzees:

    "Frankly, I thought I was going to find that early humans would be quite capable, but their ankle morphology was decidedly maladaptive for the kind of climbing I was seeing in chimps," DeSilva told LiveScience. "It kind of reinvented in my mind what they were doing and how they could have survived in an African savannah without the ability to go up in the trees."

    This is a good example of the comparative method in paleoanthropology. We can't observe the behavior of extinct species; we can only observe the behavior of their living relatives. We can observe the anatomy of fossil specimens, but testing hypotheses about their behavior requires us to understand the relationship between anatomy and behavior in living species. We've known about the anatomy of fossil hominid ankles for a long time, but it's not so obvious how the anatomical differences between them and chimpanzee ankles relates to behavior.

    The paper's abstract:

    Whether early hominins were adept tree climbers is unclear. Although some researchers have argued that bipedality maladapts the hominin skeleton for climbing, others have argued that early hominin fossils display an amalgamation of features consistent with both locomotor strategies. Although chimpanzees have featured prominently in these arguments, there are no published data on the kinematics of climbing in wild chimpanzees. Without these biomechanical data describing how chimpanzees actually climb trees, identifying correlates of climbing in modern ape skeletons is difficult, thereby limiting accurate interpretations of the hominin fossil record. Here, the first kinematic data on vertical climbing in wild chimpanzees are presented. These data are used to identify skeletal correlates of climbing in the ankle joint of the African apes to more accurately interpret hominin distal tibiae and tali. This study finds that chimpanzees engage in an extraordinary range of foot dorsiflexion and inversion during vertical climbing bouts. Two skeletal correlates of modern ape-like vertical climbing are identified in the ankle joint and related to positions of dorsiflexion and foot inversion. A study of the 14 distal tibiae and 15 tali identified and published as hominins from 4.12 to 1.53 million years ago finds that the ankles of early hominins were poorly adapted for modern ape-like vertical climbing bouts. This study concludes that if hominins included tree climbing as part of their locomotor repertoire, then they were performing this activity in a manner decidedly unlike modern chimpanzees.

    DeSilva's conclusion is straightforward and easy to illustrate. Chimpanzees climb vertical tree trunks pretty much like a logger does. A logger slings a strap around the trunk and leans back on it. Friction from the strap holds him up as he moves his feet upward; spikes on his boots hold him while he moves the strap.

    Of course, chimpanzees don't have spikes on their feet, and they don't use a strap. Instead, their arms are long enough to wrap around the trunk, and they can wedge a foot against the trunk by flexing their ankle upward -- dorsiflexing it -- or grip the trunk by bending the ankle sideways -- inverting the foot -- around it. The paper includes a photo that shows the chimpanzee style of climbing clearly:

    Chimpanzee climbing a tree

    Photo of chimpanzee climbing a tree, from DeSilva (2008)

    You might wonder, yeah so what? Isn't it obvious that chimpanzees climb this way?

    Well, it wasn't so obvious which features of the ankle might adapt chimpanzees to this style of climbing. By watching the chimpanzees (and other apes) DeSilva was able to determine the average amount (and range) of dorsiflexion and inversion of the feet while climbing, and could also assess the extent to which dorsiflexion is accomplished at the ankle joint (as opposed to the midfoot). In this case, the observations were pretty obvious -- chimpanzees were habitually flexing their ankles in ways that would damage a human ankle. Then, by examining the bony limits on human ankle flexibility, DeSilva showed that fossil hominins shared the same constraints on ankle movement as recent people. They couldn't have climbed like chimpanzees.

    Human climbing

    I would say that the ankle-joint observations match the rest of the skeleton. It seems pretty obvious that Australopithecus afarensis and later hominids couldn't possibly have climbed in the chimpanzee-like manner described in DeSilva's paper, because the hominins' arms were too short. If a logger tried to climb with his arms instead of a strap, even spikes on his feet would be relatively ineffective holding him up. Dorsiflexion would be hopeless -- the normal component of force against the tree trunk would be insufficient to prevent slipping.

    Humans who aren't loggers use a different strategy to climb vertical tree trunks -- they put a large fraction of the surface area of their legs directly in contact with the trunk. Wrapping legs around and pressing them together gives the necessary friction to hold the body up.

    If you're like me, you'll remember this climbing strategy ruefully from gym class, where "rope climbing" is the lowest common denominator of fitness tests. The sad fact is that many otherwise-normal humans fall on the wrong side of the line between mass and muscle power. Straining my groin muscles to the max, I still could never pull my way up a rope.

    There's nothing magical about getting a human to climb. Ladders, after all, are relatively easy for the large fraction of the population who can't climb a rope or tree trunk. The trick with a ladder is that friction is organized in a more effective way for our ankle mechanics and arm length. But you don't need to schlep a ladder, if you can manage a little extra arm strength and a low enough body mass.

    Early hominin climbing

    Australopithecines were light in mass, and from what we can tell, they had strong arms. So they had what it takes for humans today to climb trees effectively -- not like chimpanzees, but like humans. Up to A. afarensis, every early hominin we know about lived in an environment that was at least partially wooded.

    In his comments about the paper, DeSilva hypothesizes a trade-off between climbing ability and effective bipedality, so that early hominins could not have effectively adapted to both. I don't think a chimpanzee-like ankle would have been any use with arms as short as australopithecines'. So I don't see the necessity of a trade-off in ankle morphology. A. afarensis -- long before any evidence of stone tool manufacture -- had very non-apelike arms, hands and thumbs.

    But there's one significant question that DeSilva omits discussing: StW 573. Clarke and Tobias (1995) describe the foot of StW 573 as having a big toe that is abducted (sticks out) from the foot, intermediate between the chimpanzee and human condition. They conclude:

    [W]e now have the best available evidence that the earliest South African australopithecine, while bipedal, was equipped to include arboreal, climbing activities in its locomotor repertoire. Its foot has departed to only a small degree from that of the chimpanzee. It is becoming clear that Australopithecus was not an obligate terrestrial biped, but rather a facultative biped and climber (Clarke and Tobias 1995:524).

    DeSilva studied the talus, not the toe. StW 573 has a talus, and although it is not in DeSilva's sample, it probably would place very close to the other hominins in his comparison. Even Clarke and Tobias described its talus as humanlike -- their argument for an intermediate form was based mostly on the toe.

    But still, it's hard to believe that australopithecines would retain a chimpanzee-like big toe, if they couldn't use that big toe by inverting or dorsiflexing their foot in any significant way. By all other accounts, an abducted hallux would only impede effective bipedality. It is of no use at all for a human-like pattern of climbing. The only remaining utility would be for small-branch grasping, but small branches would seem unlikely as a support for hominin arboreality.

    One possibility is that Clarke and Tobias were simply mistaken. That appears to be the explanation favored by Harcourt-Smith and Aiello (2004:412), who cited Harcourt-Smith's 2002 thesis:

    Recent multivariate analyses of the Stw 573 tarsal bones (medial cuneiform, navicular and talus) using geometric morphometric techniques demonstrate that this fossil had a very ape-like talus, a navicular that was intermediate between apes and modern humans, and a human-like medial cuneiform inferring a lack of any hallux opposability (Harcourt-Smith, 2002). This finding contrasts with the findings of Clarke & Tobias (1995), but is does not change the fact that Stw 573 would still have a different combination of morphologies in the foot than does A. afarensis.

    This view was also supported by McHenry and Jones (2006), who concluded that all known hominin feet appear to lack any "ape-like ability to oppose the big toe." They also point to the Laetoli footprint trails, most observers of which agree that the big toe was adducted, not abducted.

    I tend to favor that explanation -- australopithecines simply didn't have a grasping foot. But they may not have shared the medial longitudinal arch, at least not in the human configuration, and without it one might doubt that their gait featured as strong a toe-off as that of later humans. Who knows?

    Meanwhile I can recommend Harcourt-Smith and Aiello's review for those who want to read more about bipedality and climbing in early hominins. It's not the last word but it is a good introduction to the literature.

    UPDATE (2009/04/15): A reader writes to suggest also the 1987 paper by Bruce Latimer, James Ohman and Owen Lovejoy. I recommend it for anyone who wants to dig deeper into australopithecine ankle morphology. I've added it to the bibliography below.

    References:

    DeSilva JM. 2009. Functional morphology of the ankle and the likelihood of climbing in early hominins. Proc Nat Acad Sci USA 106:6567-6572. doi:10.1073/pnas.0900270106

    Clarke RJ, Tobias PV. 1995. Sterkfontein Member 2 foot bones of the oldest South African hominid. Science 269:521-524.

    Harcourt-Smith WEH, Aiello LC. 2004. Fossils, feet and the evolution of human bipedal locomotion. J Anat 204:403-416. doi:10.1111/j.0021-8782.2004.00296.x

    Latimer B, Ohman JC, Lovejoy CO. 1987. Talocrural joint in African hominoids: Implications for Australopithecus afarensis. Am J Phys Anthropol 74:155-175.

    McHenry HM. Jones AL. 2006. Hallucial convergence in early hominids. J Hum Evol 50:534-539. doi:10.1016/j.jhevol.2005.12.008

    Tags: 
    A. africanus
    chimpanzees
    A. afarensis
    bipedalism
    locomotion

  • Average diet versus extreme diet in robust australopithecines

    Wed, 2008-05-07 00:38 -- John Hawks

    I've followed the literature on early hominid diets from the beginning of the weblog. In 2005 I discussed Peter Ungar's analyses of dental occlusal morphology in A. afarensis versus Homo, concluding:

    The contrast between Homo and A. afarensis is in the same direction as the contrast in occlusal morphology between primarily meat-eating carnivores like felids and canids as opposed to more omnivorous carnivores like bears. Another observation is that meat is a major food resource of chimpanzees, although this is hardly a fallback resource. Indeed, if meat eating was indeed an important component of the behavioral repertoire of early Homo, it probably is not fair to assert that the difference in diet between Homo and Australopithecus was primarily a difference in fallback resources. It may be true that australopithecines and early Homo overlapped in their food resources, particularly in plant species consumed. But considering the likely effectiveness of early humans as predators, I think it likely that the fallback foods of early humans--when hunting was ineffective--may well have been the preferred foods of australopithecines. And when australopithecines were forced to abandon their preferred foods by early humans, they were forced to fall back upon resources that either were common or were difficult for early Homo to exploit. The disappearance of early small-bodied Homo by around 1.6 million years ago, and the ultimate extinction of the robust australopithecines after a progressive increase in their molar sizes (Wood and Lieberman 2001) indicate that this fallback strategy could not be maintained in the face of increased hunting effectiveness by large-bodied Homo.

    The concept of "fallback foods" has captured a large mindshare in explaining early hominid diets. The idea is that a species may depend on preferred, staple foods for most of the year, but adopt less preferred, "fallback" foods when their staple is not available -- for instance, during the dry season.

    What can fallback foods explain about early hominids? For one thing, they could explain the difference between robust and non-robust australopithecines. We know from isotope data (reviewed in this 2005 post about Matt Sponheimer's work) that A. africanus and A. robustus had similar fractions of C3 and C4 plant source foods in their diets. Across the year, they may have eaten roughly the same mix of foods. A 2005 paper by Greg Laden and Richard Wrangham (discussed here) explored the idea of underground storage organs of plants, or tubers, as fallback foods for australopithecines. Later studies of isotope data using laser ablation of small segments of the enamel (discussed here) showed that diet proportions may have substantially varied across the time that teeth were developing -- possibly concordant with the idea of seasonal or longer-period fallback foods. An earlier analysis of dental microwear in the two hominids by Scott and colleagues (discussed here) came to a similar result: there was great variability in wear properties, especially within A. robustus, although the average in the two species showed a possibly greater fraction of brittle, hard foods consumed by the robust australopithecines.

    So I've written about the topic a lot, and followed it closely.

    Now, Peter Ungar, Frederick Grine and Mark Teaford have examined the wear properties of the molars of Australopithecus (Paranthropus) boisei. They find that -- unlike A. robustus -- none of the seven specimens showed any evidence of having eaten hard or brittle foods:

    Comparisons with the extant baseline series suggest that none of the Paranthropus boisei individuals examined consumed extremely hard or extremely tough foods in the days before death. All of these specimens lacked the extremes of Asfc evinced by Lophocebus albigena and especially Cebus apella, both known to consume hard, brittle foods. Paranthropus boisei molars also lacked the extremes of epLsar seen in Trachypithecus cristata and Alouatta palliata, both known to consume tough leaves and stems. The P. boisei individuals examined evidently avoided such metabolically challenging foods, at least in the days before death. This is notably consistent with Walker's [23] early assertion that P. boisei microwear patterns resemble those of living frugivores, and differ from those of living grazers, leaf browsers, and bone feeders.

    Comparisons with the South African hominins suggest that while Paranthropus boisei may have consumed foods with similar ranges of toughness as those eaten by Australopithecus africanus, the eastern African "robust" hominin did not eat harder and brittler foods than the South African "gracile" form. Further, the patterns for P. boisei and P. robustus are very different. Paranthropus robustus likely ate foods that were on average much harder and less tough than P. boisei. The differences in both central tendencies and ranges of variation suggest different feeding strategies, and by implication, that the two species of Paranthropus probably had markedly different diets or foraging strategies (Ungar et al. 2008, italics lost).

    That is very interesting that A. robustus and A. boisei are so different in their microwear patterns. It makes me wonder whether there may have been substantial habitat variation in the use of hard foods -- maybe the extant A. robustus sample, mainly drawn from a small area of South Africa, had access to some food items that were rare or absent across the larger East African range of A. boisei. But if some A. boisei populations had also depended on such hard resources some of the time, you might expect that we would have found one, or at least a bit more variability. Yet the sampled specimens, drawn from a distance from Ethiopia to Tanzania and well over a half million years of time, are pretty uniform in their microwear, showing some variability in the anisotropy dimension (here, high values have mostly parallel striations, attributed to fibrous food consumption).

    So we can return to the question: the major hominid competitor of A. boisei was Homo. Both lineages appeared in the period around 2.5 million years ago, and remained sympatric throughout the next million years. Some of the dynamics of that interaction must have involved diet (considering the different dietary adaptations of the two). We can speculate that A. boisei didn't get much meat, which would then be an important difference. But what else was A. boisei eating?

    Meanwhile, the data are still consistent with the idea of fallback foods in A. robustus as a driver of dental morphology, but the story for A. boisei now seems less clear. With only seven specimens, there is almost certainly not enough data to test the hypothesis -- which after all predicts that the use of hard brittle foods may be rare. But that's not positive evidence either. Is there some other food that might explain the hyperrobust craniodental morphology?

    References:

    Ungar PS, Grine FE, Teaford MF (2008) Dental Microwear and Diet of the Plio-Pleistocene Hominin Paranthropus boisei. PLoS ONE 3(4): e2044. doi:10.1371/journal.pone.0002044

    Tags: 
    A. boisei
    diet
    A. afarensis
    A. africanus
    A. robustus

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Neandertals

For years, I've worked on their bones. Now I'm working on their genes. Read more about the science studying these ancient people.

Denisova

From a finger bone of an ancient human came the record of a completely unexpected population. My lab is working on the science of the Denisova genome.

Acceleration

The advent of agriculture caused natural selection to speed up greatly in humans. We're uncovering some of the ways that populations have rapidly changed during the last 10,000 years.

Malapa

Just outside Johannesburg, the Malapa site is producing some of the most exciting finds in human evolution. This site is the headquarters of the Malapa Soft Tissue Project.