Cloning and Comparative Characterization of the rIGS Regulatory Regions in Human and Pygmy Chimpanzee Pan paniscus

Investigation of randomly cloned genomic and chromosome-specific sequences of ribosomal DNA (rDNA) from different organisms show that different regions of this long repeat unit evolve at different rates. This proves to be true not only with regard to evolutionary variability of transcribed and nontranscribed intergenic (spacer) regions of rDNA. The intergenic spacer (rIGS) of human ribosomal DNA contains both highly variable and more conservative regions with putative regulatory functions. In the present study a comparative analysis of some segments of the rIGS pre-promoter (regulatory) region in human and pygmy chimpanzee (Pan paniscus) was carried out. For these purposes, the corresponding DNA fragments were amplified in PCR with oligonucleotide primers specific to human rIGS and sequenced. Our results show that at the background of substantial structural similarity of these regions in man and chimpanzee, i.e., the presence of highly homologous sequences and similar repetitive units, there are substantial differences between them. These differences are associated with point mutations, insertions, deletions, and complex structural rearrangements.     

Cloning and comparative characterization of the rIGS regulatory regions in humans and the pygmy chimpanzee Pan paniscus

Investigation of randomly cloned genomic and chromosome-specific sequences of ribosomal DNA (rDNA) from different organisms show that different regions of this long repeat unit evolve at different rates. This proves to be true not only with regard to evolutionary variability of transcribed and nontranscribed intergenic (spacer) regions of rDNA. The intergenic spacer (rIGS) of human ribosomal DNA contains both highly variable and more conservative regions with putative regulatory functions. In the present study a comparative analysis of some segments of the rIGS pre-promoter (regulatory) region in human and pygmy chimpanzee (Pan paniscus) was carried out. For these purposes, the corresponding DNA fragments were amplified in PCR with oligonucleotide primers specific to human rIGS and sequenced. Our results show that at the background of substantial structural similarity of these regions in man and chimpanzee, i.e., the presence of highly homologous sequences and similar repetitive units, there are substantial differences between them. These differences are associated with point mutations, insertions, deletions, and complex structural rearrangements.     

Comparison of cranial ontogenetic trajectories among great apes and humans

Molecular data suggest that humans are more closely related to chimpanzees than either is to the gorillas, yet one finds the closest similarity in craniofacial morphology to be among the great apes to the exclusion of humans. To clarify how and when these differences arise in ontogeny, we studied ontogenetic trajectories for Homo sapiens, Pan paniscus, Pan troglodytes, Gorilla gorilla and Pongo pygmaeus. A total of 96 traditional three-dimensional landmarks and semilandmarks on the face and cranial base were collected on 268 adult and sub-adult crania for a geometric morphometric analysis. The ontogenetic trajectories are compared by various techniques, including a new method, relative warps in size-shape space. We find that adult Homo sapiens specimens are clearly separated from the great apes in shape space and size-shape space. Around birth, Homo sapiens infants are already markedly different from the great apes, which overlap at this age but diverge among themselves postnatally. The results suggest that the small genetic differences between Homo and Pan affect early human ontogeny to induce the distinct adult human craniofacial morphology. Pure heterochrony does not sufficiently explain the human craniofacial morphology nor the differences among the African apes.     

Molecular cloning, cDNA structure and tissue-specific expression of the human regulatory subunit RI beta of cAMP-dependent protein kinases.

Complementary DNA clones for the regulatory subunit RI beta of cAMP-dependent protein kinases were isolated from a human testis cDNA library using a mouse RI beta cDNA probe. One clone 2.4 kilobases (kb) in length contained an open reading frame of 1137 bases, and encoded a protein of 379 amino acids (excluding the initiator methionine). The human RI beta protein was one amino acid shorter than the corresponding protein in mouse and rat. The nucleotide similarity to mouse and rat sequences was 85.6% and 84.8%, respectively, while the amino acid similarity was 97.6% and 97.3%, respectively. Northern blot analyses revealed a 2.7 kb mRNA in human tissues and a 2.8 kb mRNA in mouse tissues. Both mouse and human RI beta mRNA were found to be expressed in most tissues, and not restricted to brain and testis as reported by others.