Body size and proportions in chimpanzees,with special reference toPan troglodytes schweinfurthii from Gombe National Park,Tanzania

Body weight, cranial capacity, linear and joint area data from ten free-ranging adult chimpanzees from Gombe National Park, Tanzania with known life histories allow study of variation in a local population and comparison to other populations ofPan troglodytes and toPan paniscus. Because individuals in the Gombe population are small compared to other common chimpanzees, they provide a useful comparison toPan paniscus. Body weight and some linear dimensions overlap withPan paniscus. However, cranial capacity, tooth size, and body proportions of Gombe individuals lie within the range of otherPan troglodytes and are distinct fromPan paniscus.     

Mobility of short interspersed repeats within the chimpanzee lineage

The PV subfamily of Alu repeats in human DNA is largely composed of recently inserted members. Here we document additional members of the PV subfamily that are found in chimpanzee but not in the orthologous loci of human and gorilla, confirming the relatively recent and independent expansion of this Alu subfamily in the chimpanzee lineage. As further evidence for the youth of this Alu subfamily, one PV Alu repeat is specific to Pan troglodytes, whereas others are present in Pan paniscus as well. The A-rich tails of these Alu repeats have different lengths in Pan paniscus and Pan troglodytes. The dimorphisms caused by the presence and absence of PV Alu repeats and the length polymorphisms attributed to their A-rich tails should provide valuable genetic markers for molecular-based studies of chimpanzee relationships. The existence of lineage-specific Alu repeats is a major sequence difference between human and chimpanzee DNAs. Correspondence to: C.W. Schmid     

Skeletal development in Pan paniscus with comparisons to Pan troglodytes

Fusion of skeletal elements provides markers for timing of growth and is one component of a chimpanzee's physical development. Epiphyseal closure defines bone growth and signals a mature skeleton. Most of what we know about timing of development in chimpanzees derives from dental studies on Pan troglodytes. Much less is known about the sister species, Pan paniscus, with few in captivity and a wild range restricted to central Africa. Here, we report on the timing of skeletal fusion for female captive P. paniscus (n = 5) whose known ages range from 0.83 to age 11.68 years. Observations on the skeletons were made after the individuals were dissected and bones cleaned. Comparisons with 10 female captive P. troglodytes confirm a generally uniform pattern in the sequence of skeletal fusion in the two captive species. We also compared the P. paniscus to a sample of three unknown‐aged female wild P. paniscus, and 10 female wild P. troglodytes of known age from the Taï National Park, Côte d'Ivoire. The sequence of teeth emergence to bone fusion is generally consistent between the two species, with slight variations in late juvenile and subadult stages. The direct‐age comparisons show that skeletal growth in captive P. paniscus is accelerated compared with both captive and wild P. troglodytes populations. The skeletal data combined with dental stages have implications for estimating the life stage of immature skeletal materials of wild P. paniscus and for more broadly comparing the skeletal growth rates among captive and wild chimpanzees (Pan), Homo sapiens, and fossil hominins. Am J Phys Anthropol 2012. © 2012 Wiley Periodicals, Inc.     

Sexual Dimorphism and Facial Growth Beyond Dental Maturity in Great Apes and Gibbons

The great apes and gibbons are characterized by extensive variation in degree of body size and cranial dimorphism, but although some studies have investigated how sexual dimorphism in body mass is attained in these species, for the majority of taxa concerned, no corresponding work has explored the full extent of how sexual dimorphism is attained in the facial skeleton. In addition, most studies of sexual dimorphism combine dentally mature individuals into a single “adult” category, thereby assuming that no substantial changes in size or dimorphism take place after dental maturity. We investigated degree and pattern of male and female facial growth in Pan troglodytes troglodytes, Pan paniscus, Gorilla gorilla gorilla, Pongo pygmaeus, and Hylobates lar after dental maturity through cross-sectional analyses of linear measurements and geometric mean values of the facial skeleton and age-ranking of individuals based on molar occlusal wear. Results show that overall facial size continues to increase after dental maturity is reached in males and females of Gorilla gorilla gorilla and Pongo pygmaeus, as well as in the females of Hylobates lar. In male Pongo pygmaeus, adult growth patterns imply the presence of a secondary growth spurt in craniofacial dimensions. There is suggestive evidence of growth beyond dental maturity in the females of Pan troglodytes troglodytes and Pan paniscus, but not in the males of those species. The results show the presence of statistically significant facial size dimorphism in young adults of Pan paniscus and Hylobates lar, and of near statistical significance in Pan troglodytes troglodytes, but not in older adults of those species; adults of Gorilla gorilla gorilla and Pongo pygmaeus are sexually dimorphic at all ages after dental maturity. The presence of sex-specific growth patterns in these hominoid taxa indicates a complex relationship between socioecological selective pressures and growth of the facial skeleton.     

Immunoglobulin Gm allotypes in apes: Comparison with man

Serum samples from 245 apes (184 Pan troglodytes, five Pan paniscus, 28 Gorilla gorilla, 23 Pongo pygmaeus abelei, and five Pongo pygmaeus pygmaeus) were tested for G1m (1,2,3,17), G2m (23), and G3m (5,6,10,11,13,14,15,16,21,24,28) immunoglobulin allotypes by the classical method of inhibition of hemagglutination. Some phenotypes are species specific while a few are shared by man and African apes.     

Sexual dimorphism in relative sacral breadth among catarrhine primates

As the sacrum contributes to the size and shape of the birth canal, the sexually dimorphic sacrum of humans is frequently interpreted within obstetric contexts. However, while the human sacrum has been extensively studied, comparatively little is known about sacral morphology in nonhuman primates. Thus, it remains unclear whether sacral sexual dimorphism exists in other primates, and whether potential dimorphism is primarily related to obstetrics or other factors such as body size dimorphism. In this study, sacra of Homo sapiens, Hylobates lar, Nasalis larvatus, Gorilla gorilla, Pongo pygmaeus, Pan troglodytes, and Pan paniscus were evaluated for sexual dimorphism in relative sacral breadth (i.e., the ratio of overall sacral breadth to first sacral vertebral body breadth). Homo sapiens, H. lar, N. larvatus, and G. gorilla exhibit dimorphism in this ratio. Of these, the first three species have large cephalopelvic proportions, whereas G. gorilla has small cephalopelvic proportions. P. pygmaeus, P. troglodytes, and P. paniscus, which all have small cephalopelvic proportions, were not dimorphic for relative sacral breadth. We argue that among species with large cephalopelvic proportions, wide sacral alae in females facilitate birth by increasing the pelvic inlet's transverse diameter. However, given the small cephalopelvic proportions among gorillas, an obstetric basis for dimorphism in relative sacral breadth appears unlikely. This raises the possibility that sacral dimorphism in gorillas is attributable to selection for relatively narrow sacra in males rather than relatively broad sacra in females. Accordingly, these results have implications for interpreting pelvic dimorphism among fossil primates, including hominins. Am J Phys Anthropol 152:435–446, 2013. © 2013 Wiley Periodicals, Inc.     

Ontogeny and the evolution of adult body size dimorphism in apes

This analysis investigates the ontogeny of body size dimorphism in apes. The processes that lead to adult body size dimorphism are illustrated and described. Potential covariation between ontogenetic processes and socioecological variables is evaluated. Mixed-longitudinal growth data from 395 captive individuals (representing Hylobates lar [gibbon], Hylobates syndactylus [siamang], Pongo pygmaeus [orangutan], Gorilla gorilla [gorilla], Pan paniscus [pygmy chimpanzee], and Pan troglodytes [“common” chimpanzee]) form the basis of this study. Results illustrate heterogeneity in the growth processes that produce ape dimorphism. Hylobatids show no sexual differentiation in body weight growth. Adult body size dimorphism in Pongo can be largely attributed to indeterminate male growth. Dimorphism in African apes is produced by two different ontogenetic processes. Both pygmy chimpanzees (Pan paniscus) and gorillas (Gorilla gorilla) become dimorphic primarily through bimaturism (sex differences in duration of growth). In contrast, sex differences in rate of growth account for the majority of dimorphism in common chimpanzees (Pan troglodytes). Diversity in the ontogenetic pathways that produce adult body size dimorphism may be related to multiple evolutionary causes of dimorphism. The lack of sex differences in hylobatid growth is consistent with a monogamous social organization. Adult dimorphism in Pongo can be attributed to sexual selection for indeterminate male growth. Interpretation of dimorphism in African apes is complicated because factors that influence female ontogeny have a substantial effect on the resultant adult dimorphism. Sexual selection for prolonged male growth in gorillas may also increase bimaturism relative to common chimpanzees. Variation in female growth is hypothesized to covary with foraging adaptations and with differences in female competition that result from these foraging adaptations. Variation in male growth probably corresponds to variation in level of sexual selection. © 1995 Wiley-Liss, Inc.     

Inter-menstrual intervals in captive bonobosPan paniscus

In this study we provide new data on the duration of the inter-menstrual intervals of six captive female bonobos (Pan paniscus). We found that the mean duration of the inter-menstrual interval was about 34 days. This lies close to the average value of 37 days that has been reported for common chimpanzees (Pan troglodytes).     

The use of leafy twigs for rain cover by the pygmy chimpanzees of Wamba

Pygmy chimpanzees (Pan paniscus) of Wamba sometimes put leafy twigs on their bodies in a rain. In some cases, those twigs seemed to be effective against the rain-impact. There is no record that common chimpanzees (Pan troglodytes) show the same behaviour, but similar or more elaborate use of twigs as rain cover is recorded among orang-utans (Pongo pygmaeus).     

A quantitative comparison of terrestrial herbaceous food consumption by Pan paniscus in the Lomako Forest,Zaire, and Pan troglodytes in the Kibale Forest,Uganda

Differences in the social organization and dental morphology of Pan paniscus (bonobos) and Pan troglodytes (chimpanzees) have been related to differences in the spatiotemporal availability of food and its exploitation. The presence of abundant terrestrial herbaceous vegetation (THV) in the bonobo's habitat and the apparent greater reliance on herbs for food has been used to explain differences in party size and, by extension, social organization. Using fecal analysis, we assess quantitatively the amount of herbaceous foods consumed by Pan paniscus in the Lomako Forest, Zaire, compared to similar data for Pan troglodytes in the Kibale Forest, Uganda. We examine this data in the context of spatiotemporal patterns of availability of herbaceous foods and fruit, as well as their nutritional content. The results support the suggestion that bonobos consume more herbaceous food than do the Kibale chimpanzees and that these foods are more prevalent in the bonobo's habitat than in the Kibale Forest. However, temporal changes in fruit availability and herb consumption, along with nutritional analyses, suggest that chimpanzees consume herbs as a fallback source of carbohydrates, whereas bonobos consume herbs as a source of protein regardless of season or fruit abundance. Available data suggest that party size while feeding on terrestrial herbs is restricted at both sites, but a determination of the relative strength of this constraint is not possible at this time. Difficulties in methods used for data collection are discussed and areas where more information is needed are highlighted. © 1994 Wiley-Liss, Inc.     

Ultrasonographic monitoring of fetal development in unrestrained bonobos (Pan paniscus) at the Milwaukee County Zoo

The bonobo, Pan paniscus, is one of the most endangered primate species. In the context of the Bonobo Species Survival Plan^®, the Milwaukee County Zoo established a successful breeding group. Although the bonobo serves as a model species for human evolution, no prenatal growth curves are available. To develop growth graphs, the animals at the Milwaukee County Zoo were trained by positive reinforcement to allow for ultrasound exams without restraint. With this method, the well being of mother and fetus were maintained and ultrasound exams could be performed frequently. The ovulation date of the four animals in the study was determined exactly so that gestational age was known for each examination. Measurements of biparietal diameter (BPD), head circumference (HC), abdominal circumference (AC), and femur length (FL) were used to create growth curves. Prenatal growth of P. paniscus was compared with the data of humans and the common chimpanzee, P. troglodytes. With respect to cranial structures, such as BPD and HC, humans have significant acceleration of growth compared with P. paniscus and P. troglodytes. In P. paniscus, growth of AC was similar to HC throughout pregnancy, whereas in humans AC only reaches the level of HC close to term. Growth rate of FL was similar in humans and the two Pan species until near day 180 post‐ovulation. After that, the Pan species FL growth slowed compared with human FL. The newly developed fetal growth curves of P. paniscus will assist in monitoring prenatal development and predicting birth dates of this highly endangered species. Zoo Biol 30:241–253, 2011. © 2010 Wiley‐Liss, Inc.     

Grouping of the pygmy chimpanzees

The group formation inPan paniscus is flexible as inP. troglodytes. A group consisted of 16.9 chimps on the average, and a large groups of more than 30 chimps were often observed. The most frequent groups are of the mixed group type, which occupied 80% of the observed cases. The group size varies in accordance with the seasonal changes of the abundance and distribution of food resources, but in general it is larger than that ofP. troglodytes. The socionomic sex ratio does not seem to be highly correlated with the group size, and was around 76 on the average. And neither the proportion of females with infants in a group nor that of estrous females seems to be correlated with the group size. Therefore, the group composition appears to be rather uniform. This uniformity may be attributable toP. paniscus's concentrative nature and high male/female affinity. In comparison with the other African anthropoid apes,P. paniscus shows less sexual differentiation in its social structure. This study was financed by the Scientific Research Fund of the Ministry of Education, Science, and Culture of the Japanese Government.     

The behavior of a group of captive pygmy chimpanzees (Pan paniscus)

A group of captive pygmy chimpanzees (Pan paniscus) was studied in the San Diego Zoological Gardens. The behavior patterns that these animals exhibit are described. Each of these behavior patterns is compared to those described for wild and captive common chimpanzees (P. troglodytes). Differences in behavior between these two species are attributed to specialization of the pygmy chimpanzee to a rain forest habitat and to a monogamous social system.     

A chimpanzee-derived chromosome-specific alpha satellite DNA sequence conserved between chimpanzee and human

We describe a cloned 2.7 kb alpha satellite sequence, Pan-3, from the pygmy chimpanzee (Pan paniscus) that specifically hybridizes in situ to chromosome 19 in the pygmy chimpanzee and to the homeologous human chromosome, no. 17. Using high stringency conditions of hybridization on Southern blots, this sequence hybridized to DNA from both species of chimpanzee (P. paniscus and P. troglodytes) and from human but not to DNA from gorilla (Gorilla gorilla) or orangutan (Pongo pygmaeus). Partial sequence analysis showed that Pan-3 and a previously described human chromosome 17-specific clone have up to 91% sequence identity. To our knowledge this is the highest sequence similarity reported between alphoid subsets from human and any other primate.by T.C. Hsu     

Red cell enzymes of the Pongidae

Summary The red cell enzymes acid phosphatase, adenylate kinase, adenosine deaminase and phosphoglucomutase were analyzed by horizontal starch gel electrophoresis in 43 members of the family Pongidae: Pongo pygmaeus (n=10), Gorilla g. gorilla (n=8), Pan troglodytes (n=22) and Pan paniscus (n=3).In all the Pongidae a red cell acid phosphatase zymogram corresponding to the phenotype B in man was found. The adenylate kinase corresponded to the human phenotype AK 1. All the Pongidae showed the same homozygous adenosine deaminase phenotype which was different from the zymograms in man and was designated ADA ape. In all Pongidae the allele PGM ₁ ¹ was present, in addition in Gorilla g. gorilla a second allele was demonstrated, PGM ₁ ^Go . In Pan troglodytes a second allele, PGM ₁ ^Pan was recognized. In Pongo pygmaeus and Gorilla g. gorilla the PGM₂ patterns differed in their migration rates from PGM₂ 1 in man. In one individual of the species Pan troglodytes a PGM₂ zymogram was found resembling the heterozygous phenotype PGM₂ 3–1, PGM ₂ ¹ PGM ₂ ³, (type Palmer) in man. In all the other individuals of the species Pan troglodytes and in those of the species Pan paniscus the PGM₂ zymogram corresponded to the phenotype PGM₂ 1 in man.

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Zusammenfassung Bei 43 Vertretern der Familie Pongidae, Pongo pygmaeus (n=10), Gorilla g. gorilla (n=8), Pan troglodytes (n=22) und Pan paniscus (n=3), wurden die Erythrocytenenzyme saure Phosphatase, Adenylatkinase, Adenosindeaminase und Phosphoglucomutase mit der horizontalen Stärkegelelektrophorese analysiert. Bei allen Pongiden fanden wir eine saure Phosphatase, die dem Phänotyp B des Menschen entsprach, und eine Adenylatkinase, die dem Phänotyp AK 1 des Menschen glich. Alle Pongiden besaßen das gleiche, einem homozygoten Phänotyp entsprechende Adenosindeaminase-Zymogramm, das sich von den Zymogrammen des Menschen unterschied; wir bezeichnen diesen Phänotyp mit ADA ape. Bei allen Pongiden kommt das Allel PGM ₁ ¹ vor, bei Gorilla g. gorilla zusätzlich ein zweites Allel, PGM ₁ ^Go , und bei Pan troglodytes ein zweites Allel, PGM ₁ ^Pan . Die PGM₂-Zymogramme von Pongo pygmaeus und Gorilla g. gorilla unterschieden sich in ihrer elektrophoretischen Wandergeschwindigkeit vom Phänotyp PGM₂ 1 des Menschen. Bei einem Individuum der Species Pan troglodytes fanden wir ein heterozygotes PGM₂-Zymogramm, das an den heterozygoten Phänotyp PGM₂ 3–1, PGM ₂ ¹ PGM ₂ ³ (Typ Palmer) des Menschen erinnerte, bei allen übrigen Individuen der Species Pan troglodytes und bei denen der Species Pan paniscus ein homozygotes PGM₂-Zymogramm, das dem Phänotyp PGM₂ 1 des Menschen entsprach.

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Supported by the Deutsche Forschungsgemeinschaft.     

Redescription of Enterobius anthropopitheci (Gedoelst, 1916) (Nematoda,Oxyurida), a parasite of chimpanzees

Enterobius anthropopitheci (Gedoelst, 1916), a parasite of the chimpanzees Pan troglodytes and P. paniscus, is redescribed. E. anthropopitheci can be distinguished from the two closely related species parasitic in man, E. vermicularis (L., 1758) and E. gregorii Hugot, 1983, by the following characters: in the males, the cuticular pericloacal ornamentation, and the size and shape of the spicule; in the females, the lateral alae, which are simple in the pinworms of man, are simple only anteriorly and divided into two crests at the mid-oesophageal level in the parasite of chimpanzees. Enterobius anthropopitheci (Gedoelst, 1916), parasite des chimpanzés, Pan troglodytes et P. paniscus, dans toute leur aire de répartition est redécrite. E. anthropopitheci est très proche par sa morphologie des deux oxyures de l'Homme, E. vermicularis (L., 1758) et E. gregorii Hugot, 1983, dont il diffère toutefois par les caractères suivants: chez le mâle, ornementation cuticulaire péricloacale, taille et forme du spicule; chez la femelle, aile latérale simple sur toute sa longuer chez les oxyures de l'Homme, simple dans la région antérieure se dédoublant en deux crêtes au milieu de l'oesophage, chez l'oxyure parasite des chimpanzés.     

A major histocompatibility complex class I allele shared by two species of chimpanzee

 Little is known regarding the rates at which natural selection can modify or retain antigen presenting alleles at the major histocompatibility complex (MHC). Discovery of identical [1101 base pairs (bp)] coding regions at the MHC class I C locus in Pan troglodytes and Pan paniscus, chimpanzee species that diverged ∼2.3 million years ago, now indicates that a class I allotype can survive for at least this period. Remarkable conservation was also reflected in the (1799 bp) introns where a maximum of only six substitutions distinguished five alleles (three from P. troglodytes and two from P. paniscus) that encoded the identical heavy chain allotype. Analysis of a more distantly related human allele, HLA-Cw ^* 0702, corroborated that intron variation was non-uniform along the gene. Thus we provide a clear reference frame for the lifetime of an MHC class I allotype, a direct estimate of allelic substitution rates, and evidence for an unusual evolution of MHC class I introns. Received: 13 August 1997     

Observations on the meat-eating behavior of wild bonobos (Pan paniscus) at Wamba,Republic of Zaire

Meat-eating behavior of wild bonobos (Pan paniscus) was witnessed on two occasions at Wamba, Republic of Zaire. Only flying squirrels were observed to be eaten by the bonobos. Several bonobos gathered around the possessor of the meat and showed interest in the meat on all occasions. Begging behavior was noted on one of the two occasions, but the possessor of the meat ignored it. No sharing of meat was seen on either occasion. The exclusive targets of hunting by bonobos are apparently small mammals, such as flying squirrels and infant duikers, since evidence of meat eating by wild bonobos, which have been studied for more than fifteen years, has been restricted to these mammals. The bonobos at Wamba may have a specialized “prey image”, as in the case of the chimpanzees (Pan troglodytes) of the Tai forest, and certain medium-sized or small mammals may not conform to this image.     

On the Diversity of Malaria Parasites in African Apes and the Origin of Plasmodium falciparum from Bonobos

The origin of Plasmodium falciparum, the etiological agent of the most dangerous forms of human malaria, remains controversial. Although investigations of homologous parasites in African Apes are crucial to resolve this issue, studies have been restricted to a chimpanzee parasite related to P. falciparum, P. reichenowi, for which a single isolate was available until very recently. Using PCR amplification, we detected Plasmodium parasites in blood samples from 18 of 91 individuals of the genus Pan, including six chimpanzees (three Pan troglodytes troglodytes, three Pan t. schweinfurthii) and twelve bonobos (Pan paniscus). We obtained sequences of the parasites'' mitochondrial genomes and/or from two nuclear genes from 14 samples. In addition to P. reichenowi, three other hitherto unknown lineages were found in the chimpanzees. One is related to P. vivax and two to P. falciparum that are likely to belong to distinct species. In the bonobos we found P. falciparum parasites whose mitochondrial genomes indicated that they were distinct from those present in humans, and another parasite lineage related to P. malariae. Phylogenetic analyses based on this diverse set of Plasmodium parasites in African Apes shed new light on the evolutionary history of P. falciparum. The data suggested that P. falciparum did not originate from P. reichenowi of chimpanzees (Pan troglodytes), but rather evolved in bonobos (Pan paniscus), from which it subsequently colonized humans by a host-switch. Finally, our data and that of others indicated that chimpanzees and bonobos maintain malaria parasites, to which humans are susceptible, a factor of some relevance to the renewed efforts to eradicate malaria.     

Chromosomal distribution of rDNA in Pan paniscus,Gorilla gorilla beringei,and Symphalangus syndactylus: Comparison to related primates

Hybridization in situ was used to identify rDNA in chromosomes of the pygmy chimpanzee, mountain gorilla, and siamang gibbon. In contrast to other Pongids, and man, the gorilla has only two pairs of rDNA-containing chromosomes. The single pair in the siamang bears no resemblance to the nucleolar chromosome of the closely related lar gibbon. Pan paniscus and P. troglodytes have the same rDNA distribution, and similar karyotypes except in the structure of chromosome 23p. Grain counts over unbanded preparations show that the human, orangutan, and both chimpanzees have about the same total rDNA multiplicity.