Growth of wild and laboratory born chimpanzees

The skeletal remains of a wild juvenile chimpanzee,Pan troglodytes verus, of known chronological age are measured and found to be smaller than laboratory born and fed juveniles of the same age. Other wild born immature skeletal materials of all the three subspecies ofPan troglodytes, including both known and estimated chronological ages, are also smaller than laboratory born chimpanzees when comparisons are made on corresponding age groups. Differences between wild and laboratory born chimpanzees are larger in the limb bones than in the cranium. Limb bones of laboratory individuals grow earlier than those of wild ones regardless of subspecies. Small limb bone size of wild chimpanzees is discussed in terms of life processes.     

comparison between the complete mitochondrial DNA sequences ofHomo and the common chimpanzee based on nonchimeric sequences

The complete mitochondrial DNA (mtDNA) molecules ofHomo and of the common chimpanzee were sequenced. Each sequence was established from tissue of one individual and thus nonchimeric. Both sequences were assembled in their entirety from natural (not PCR amplified) clones. Comparison with sequences in the literature identified the chimpanzee specimen asPan troglodytes verus, the West African variety of the species. The nucleotide difference between the complete human and chimpanzee sequences is 8.9%. The difference between the control regions of the two sequences is 13.9% and that between the remaining portions of the sequences 8.5%. The mean amino acid difference between the inferred products of the 13 peptide-coding genes is 4.4%. Sequences of the complete control regions, the complete 12S rRNA genes, the complete cytochromeb genes, and portions of the NADH4 and NADH5 genes of two other chimpanzee specimens showed that they were similar but strikingly different from the same regions of the completely sequenced molecule fromPan troglodytes verus. The two specimens were identified asPan troglodytes troglodytes, the Central African variety of the common chimpanzee.     

The “Phoca standard”: An external molecular reference for calibrating recent evolutionary divergences

Comparison of the complete mitochondrial DNA (mtDNA) of the high-Arctic ringed seal (Phoca hispida) and the sub-Arctic harbour (P. vitulina) and grey (Halichoerus grypus) seals shows that they are genetically equidistant from one another. We relate the evolutionary divergence of the three species to expanding glaciation in the Arctic Basin and establish, in conjunction with mtDNA data, a standard reference for calibration of recent divergence events among mammalian taxa. In the present study, we apply the “Phoca standard” to the dating of divergences within the hominid phylogenetic tree. After determining the relative rates of substitution over all mitochondrial protein-coding genes in the different evolutionary lineages, we estimate that humans and chimpanzees diverged from each other 6.1 Mya (95% confidence limits: 5.2–6.9 Mya). The corresponding lower-limit divergence between common chimpanzee,Pan troglodytes, and pygmy chimpanzee,P. paniscus, occurred 3 (2.4–3.6) Mya, and the primary split within theP. troglodytes complex 1.6 (1.3–2.0) Mya. The analyses suggest that the split betweenGorilla andPan/Homo occurred 8.4 (7.3–9.4) Mya. They also suggest thatPongo (orangutan) and the lineage leading to gorillas, chimpanzees, and humans diverged 18.1 (16.5–19.6) Mya. The present analysis is independent of the hominid paleontological record and inferential morphological interpretations and thus is a novel approach to the lower-limit dating of recent divergences. Correspondence to: U. Arnason     

Comparing infant and juvenile behavior in bonobos (Pan paniscus) and chimpanzees (Pan troglodytes): a preliminary study

The dichotomy between the two Pan species, the bonobo (Pan paniscus) and chimpanzee (Pan troglodytes) has been strongly emphasized until very recently. Given that most studies were primarily based on adult individuals, we shifted the “continuity versus discontinuity” discussion to the infant and juvenile stage. Our aim was to test quantitatively, some conflicting statements made in literature considering species differences between immature bonobos and chimpanzees. On one hand it is suggested that infant bonobos show retardation in motor and social development when compared with chimpanzees. Additionally it is expected that the weaning process is more traumatic to chimpanzee than bonobo infants. But on the other hand the development of behaviors is expected to be very similar in both species. We observed eight mother–infant pairs of each species in several European zoos. Our preliminary research partially confirms that immature chimpanzees seem spatially more independent, spending more time at a larger distance from their mother than immature bonobos. However, the other data do not seem to support the hypothesis that bonobo infants show retardation of motor or social development. The development of solitary play, environmental exploration, social play, non-copulatory mounts and aggressive interactions do not differ between the species. Bonobo infants in general even groom other group members more than chimpanzee infants. We also found that older bonobo infants have more nipple contact than same aged chimpanzees and that the weaning process seems to end later for bonobos than for immature chimpanzee. Additionally, although immature bonobos show in general more signs of distress, our data suggest that the weaning period itself is more traumatic for chimpanzees.     

External body dimensions ofPan paniscus andPan troglodytes chimpanzees

Postcranial skeletal studies have demonstrated thatPan paniscus is a more gracile animal thanPan troglodytes, with different arm to leg proportions. Published data on external body dimensions are extremely rare forPan paniscus, however. We present here a series of such measures for a sample ofpaniscus, and we compare these to similar measures forPan troglodytes. This comparison further clarifies the morphological distinctions between the two chimpanzee species, and indicates that bonobos have longer legs and smaller chest girths relative to overall body height than doPan troglodytes chimpanzees.     

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.     

Party composition and dynamics inPan paniscus

The pygmy chimpanzee, or bonobo, Pan paniscus,diplays a fission-fusion social organization in which individuals associate in parties that vary in size and composition. Data from a 2-year field study of nonprovisioned P. paniscusshow that party composition varies with party size. Although females, on average, outnumber males, the proportion of males in the party increases in larger parties. This effect was not due to the greater number of known females. Both females and males will join and leave a party in the company of others, but only males appear frequently to join or leave as lone individuals. All-male parties were not observed, but all-female (nonnursery) parties were relatively common. These trends reflect greater cohesion among females than observed in P. troglodytes schweinfurthii.Cohesion between males and female P. paniscusmay increase with party size.     

Die «Neuen Regeln» der Zoologischen Nomenklatur,Ausgearbeitet von der Internationalen Nomenkla-turkommission Anlässlich des XV. Internationalen Kongresses für Zoologie,London 1958

Summary The report gives a preliminary account of the decisions made by the International Commission of Zoological Nomenclature during the XVth International Congress of Zoology held in London in 1958. — The most important of these resolutions deal especially with the newrange of application of the rules of nomenclature (validity from subspecies up to superfamily), thesecondary homonyms (rescission of the permanent invalidity), theprocedure of naming the types (onlyholo-, lecto- andneotypus, as well as thesyntypes are of documentary value for the interpretation of a species; severer regulations were made for the nomination ofneotypes) and finally with theprinciple of priority, which — with certain limitations — found its full confirmation contrary to the principles of continuity and conservation.      

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.     

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     

Patterns of microsatellite polymorphism in the range-restricted bonobo (Pan paniscus): considerations for interspecific comparison with chimpanzees (P. troglodytes)

The endangered great ape, Pan paniscus (bonobo) has the smallest range of the African apes. Virtually nothing is known about the genetic diversity or genetic structure of this species, while substantial amounts of polymorphism have been reported for the bonobo’s widespread congener, the chimpanzee (P. troglodytes). Given its restricted range, what is the extent of genetic variation in the bonobo relative to the chimpanzee, and is the bonobo genetically depauperate? To investigate patterns of genetic polymorphism, bonobos of wild origin were genotyped for 28 microsatellite loci. The mean number of alleles per locus (5.2) and the mean observed heterozygosity (0.52) in bonobos were similar to variation observed in a wild chimpanzee community (P. t. schweinfurthii). The rarer bonobo is not genetically depauperate and may have genetic diversity comparable to the eastern chimpanzee subspecies. Bonobos have approximately 55% of the allelic diversity and 66% of the observed heterozygosity exhibited by all three chimpanzee subspecies sampled across equatorial Africa. Resampling techniques were used to quantify the effects of sample size differences and number and choice of loci between bonobos and chimpanzees. The examination of these variables underscores their importance in accurately interpreting interspecific comparisons of diversity estimates.     

Population systematics of chimpanzees using molar morphometrics

When dental morphological variation within extant species is used as a guideline to partition variation within fossil samples into species, the underlying assumption is that fossil species are equivalent to extant species. This is the case despite the fact that dental morphology, which is commonly used to differentiate fossil species, is rarely used to differentiate extant species. Aspects of external morphology, ecology, behavior, breeding patterns, and molecular structure that are used to delineate living species are generally not available for fossils. In this paper, the utility of dental evidence for sorting fossil samples into species is evaluated by testing whether molar occlusal morphology is capable of sorting populations of Pan into the species and subspecies already well-established by nondental evidence. The dentitions of 341 chimpanzee individuals, sampled from regions throughout equatorial Africa, were sorted into 16 populations using rivers to demarcate the boundaries between populations. Digital-imaging software was used to measure 15 traits on the occlusal surface of each upper molar and 19 on each lower molar. After applying size adjustments, size-transformed and untransformed variables were subjected to discriminant analysis, with separate analyses carried out for each molar type. Results indicate that populations of Pan troglodytes and Pan paniscus are well differentiated at all molar positions. Populations of P. t. verus are distinct from other populations of P. troglodytes. Populations of P. t. troglodytes and P. t. schweinfurthii show close dental similarity. A distinct population is recognized at the Nigeria-Cameroon border, indicating the presence of P. t. vellerosus. The concordance between the patterns of diversity recognized by this study and other molecular and nonmolecular studies indicates that paleontological species that are similar to species of Pan in terms of size and patterns of diversification may be differentiated using molar morphology.     

Taxonomy and distribution ofPresbytis melalophos group in Sumatera,Indonesia

Taxonomy of thePresbytis melalophos group in Sumatera has been based solely on the distinction in the pelage coloration and has been a subject of controversy. In the present study, extensive field observations were undertaken. Three species, i. e.P. melalophos, P. thomasi, andP. femoralis, are recognized in Sumatera based on the cranial morphology, pelage coloration, and vocalization. Subspecies of each species are revised, a new classification is proposed, and a new subspecies,Presbytis melalophos bicolor, is described. A detailed distribution map of species and subspecies is presented. No sympatry occurs between the species. Finally, a cladistic analysis is presented for the three species, based on the cranial characters; the branching sequence is first between theP. melalophos clade and theP. femoralis- P. thomasi clade and second between theP. femoralis clade and theP. thomasi clade.     

Avian Haematozoa: Some Taxonomic and Nomenclatural Problems Arising from the Russian Literature*

SYNOPSIS. It is evident from a survey of the Russian literature that many species of avian haematozoa recorded do not meet the basic criteria required by the International Code of Zoological Nomenclature. Thus 28 species of Haemoproteus and 4 species of Leucocytozoon are considered to be nomina nuda, while 1 species, Leucocytozoon turtur orientalis is a synonym of L. marchouxi.     

Female Coalitions Against Male Aggression in Wild Chimpanzees of the Budongo Forest

In the wild, female chimpanzees (Pan troglodytes) are subject to male aggression that at times can be prolonged or particularly violent. There are no reports of cooperative retaliation to such aggression, a strategy observed in the congeneric Pan paniscus, from the wild despite >4 decades of detailed behavioral study across a number of populations and its occurrence among captive female chimpanzees. If the reports from captivity represent an inherent capacity, then the absence of similar reports from wild populations suggests that females may be able to form coalitions only under appropriate ecological and demographic conditions. During a study of male and female aggressive interactions among chimpanzees of the Budongo Forest, Uganda, wild adult female chimpanzees sometimes formed coalitions with one another to retaliate against male aggression. This may be possible because these females tend to be more gregarious than in other populations of East African chimpanzees, as other studies of the same population have suggested; the extent and variation of female chimpanzee social strategies may, therefore, need reconsideration. Further, my observations strengthen the argument that at least some of the differences between chimpanzees and bonobos may be more of degree than of kind.     

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).     

Type specimens of Mitridae (Mollusca:Gastropoda) described by Linnaeus in the genera Voluta, Buccinum and Bulla between 1758 and 1771

From the 16 species of Mitridae described by Linnaeus between the years 1758-71 11 species are considered valid and available for taxonomic use; four specific names have been suppressed by the International Commission on Zoological Nomenclature for taxonomic usage (1968). One specific name, i.e. Voluta mitra episcopalis Linnaeus, has appeared in various combinations in malacological literature over the years. From the style of listing in the 10th edition of the Systerna Naturae , it is evident that 'episcopalis' has to be treated as of infraspecific rank; there is no evidence that 'episcopalis' is even a valid subspecies of Voluta mitra.
Three holotypes and five lectotypes designated in this paper are extant in the Linnaean collection; illustrations representing three Linnaean species have been selected as lectotypes.