Franz Weidenreich undertook a systematic study of the skulls of Sinanthropus by looking at the evolution of their base, comparing them with Homo sapiens and chimpanzees (Weidenreich 1943). The sphenoidal angle could not be measured on the fossils, since the anterior and middle brain fossae were missing in all the specimens. The angle was open in chimpanzees and closed in Homo sapiens. He suggested a geometrical reconstruction by referring to the position of several homologous cranial landmarks. On the external surface, he took the most anterior edge of the occipital great hole (basion) and the upper margin of the external auditory meatus (porion). On the internal surface, he took the internal auditory meatus, an aperture visible on the voluminous petrous pyramid that formed the anterior wall of the cerebellar fossa (Figure 2.3). What was the degree of straightening, or verticality, of the brain stem? Weidenreich had compared the position of these landmarks by orienting the skull on a line joining the root of the nose (nasion) to the furthest margin of the great occipital hole (opisthion). On Sinanthropus, the inner and external meatus are slightly above this line, whereas in Homo sapiens, they are much higher, with the anterior margin of the great occipital hole further forward.
He called this difference “deflection” and concluded that it was clearly more pronounced in Sinanthropus than in Paninae, but its sphenoidal angle should be more open than in Homo sapiens (Figure 2.2(A)). This difference between the late stages of growth in Sinanthropus and Homo sapiens corresponds to a lesser verticalization of the clivus and cerebellar surface of the pyramids. Then, by comparing adult cranial profiles of the gorilla, Sinanthropus and Homo sapiens, he highlighted a transverse axis of rotation passing through the center of the base of the skull (Figure 2.2(B)), just in front of the external auditory meatus. The face and neurocranium seem to roll up around this axis, the circles narrowing and all tissues contracting in its axial center. Later, at the American Museum of Natural History in New York, which he joined in 1941, he compared the degree of inclination of the pyramids of a skull of Ngandong (Java) with the gorilla and Homo sapiens, and found a cerebellar face of the pyramids more upright, but less vertical as on the Sinanthropus (Weidenreich 1951).
Figure 2.2. A: Diagram comparing the sagittal profile of Sinanthropus III and Sapiens (b: bregma, ba: basion, i: inion, kl: klition, l: lambda, op: opistocranion, or: infra-orbital, po: porion) (Weidenreich 1943, plate LXVIII). B: The rolling-up of the skull around a transverse axis of rotation at skull base compared between the gorilla, the Sinanthropus and Homo sapiens (Weidenreich 1939) (photo credit: Library of Institut de Paléontologie Humaine). For a color version of this figure, see www.iste.co.uk/dambricourt/embryogeny.zip
Weidenreich interpreted this “deflection” by considering the general shape of the vault. The brain of Homo sapiens is more coiled in its occipital part, so he supposed that the increase of the cerebral hemispheres would have pushed the cerebellum, and thus the cerebellar fossa with its great occipital hole, forward and downward. Nothing is said about the sphenoid.
2.8. A new paradigm: telencephalization
The degree of straightening of the pyramids and the clivus, which form the anterior wall of the lower cranial fossa, would simply be the consequence of a development of a brain and cerebellum that became more complex very gradually, passing from a hypothetical archaic stage Homo sapiens to modern Homo sapiens, or Cro-Magnon Man (Figure 2.3). Since this first comparison, paleoanthropologists and anatomists interested in the neurocranium of fossilized Hominids have taken this speculation for granted, as Grover (1962) reminds us. Telencephalization became the new paradigm of hominization.
Figure 2.3. Comparison of the straightening of the right petrous pyramid between Sinanthropus III (Homo erectus pekinensis) and Homo sapiens (white line on the internal auditory meatus) (photo: A. Dambricourt Malassé). For a color version of this figure, see www.iste.co.uk/dambricourt/embryogeny.zip
However, the comparison of Neanderthal skulls that were sufficiently well preserved at different stages of growth already invalidated this speculation, because their encephalization with a cranial capacity higher than Homo sapiens did not change the inclination of the pyramids. The cerebellum did not develop forward and downward, but backward, forming the famous “occipital bun” (see section 7.4). In other words, the sphenoid, the clivus and the pyramids did not change their degree of verticality compared to the 800,000-year-old Sinanthropus, while its brain was clearly less developed. With neandertalization, the brain and cerebellum extended their territory at the vault level, since the ossification of membranes took place from the lobes. On the other hand, the center of the base of the skull has no contact with the cerebral hemispheres and forms a block that precedes the telencephalization in the chronology of cerebral development. Its morphogenesis preceded the formation of the hemispheres.
To realize this, it would have been enough to look at the work of embryologists at the beginning of the 20th century who had already demonstrated this. For a reason that the history of science will certainly explain, embryologists and zoologists no longer cross-referenced their observations, and paleoanthropology had never heard of the work on the embryogenesis of the primordial cranium of Man, or the chondrocranium, published in 1900 by Giuseppe Levi (1872–1965) (Levi 1900). Levi had studied medicine and surgery at the Institute of Higher Studies of the University of Florence in 1889. In 1899, he pursued research at the University of Berlin with the embryologist Oscar Hertwig (1849–1922), a former medical student of Ernest Haeckel. Three former researchers from his laboratory at the University of Turin were awarded the Nobel Prize in Physiology or Medicine, including Rita Levi-Montalcini (1909–2012) in 1986 for the discovery of the Nerve Growth Factors. We will come back later to Levi’s work which is of primary importance.
Excavations at Zhoukoudian were suspended