Birth of a gene: locus of neuronal BC200 snmRNA in three prosimians and human BC200 pseudogenes as archives of change in the Anthropoidea lineage.

The gene encoding brain-specific dendritic BC200 small non-messenger RNA is limited to the primate order and arose from a monomeric Alu element. It is present and neuronally expressed in all Anthropoidea examined. By comparing the human sequence of about 13.2 kb with each of the prosimian (lemur 14.6 kb, galago 12 kb, and tarsier 13.8 kb) orthologous loci, we could establish that the BC200 RNA gene is absent from the prosimian lineages. In Strepsirhini (lemurs and lorises), a dimeric AluJ-like element integrated very close to the BC200 insertion point, while the corresponding tarsier region is devoid of any repetitive element. Consequently, insertion of the Alu monomer that gave rise to the BC200 RNA gene must have occurred after the anthropoid lineage diverged from the prosimian lineage(s). Shared insertions of other repetitive elements favor proximity of simians and tarsiers in support of their grouping into Haplorhini and the omomyid hypothesis. On the other hand, the nucleotide sequences in the segment that is available for comparison in all four species reveal less exchanges between Strepsirhini (lemur and galago) and human than between tarsier and human. Our data imply that the early activity of dimeric Alu sequences must have been concurrent with the activity of monomeric Alu elements that persisted longer than is usually thought. As BC200 RNA gave rise to more than 200 pseudogenes, we used their consensus sequence variations as a molecular archive recording the BC200 RNA sequence changes in the anthropoid lineage leading to Homo sapiens and timed these alterations over the past 35-55 million years.

DNA-protein interactions between mammalian nuclear proteins and a GCC-element included in a composite cis-acting element of mouse ribosomal protein L32 promoter.

DNA-protein complex formation between the sequence GC(GCC)4 (GCC-element) of mouse ribosomal protein L32 (rpL32) promoter and nuclear proteins of mouse and human cells has been studied using gel retardation and South-Western blotting methods. The rpL32 promoter fragment (-24.+11) was able to form specific complexes with mouse and human nuclear proteins mainly due to the presence of the GCC-element (-19.-6). DNA-protein complex patterns exhibited marked tissue-specificity. Three nuclear polypeptides of approximately 18, 28, and 50 kD that bind to the rpL32 promoter region (-24.+11) have been detected in HeLa cells by ligand blotting. At least one of them (18 kD) interacted with the GCC-element directly. The same fragment of the promoter interacted only with one nuclear polypeptide (28-31 kD) from human fibroblasts. DNA-protein complex formation between the investigated rpL32 promoter fragment containing the GCC-element and human fibroblast nuclear proteins is Zn2+-dependent. The method of functional titration (in vivo competition in the CAT-test) revealed that the GCC-element within the rpL32 promoter functions as a positive cis-acting transcriptional element in NIH 3T3 cells. Thus, our data characterize the sequence GC(GCC)4 as a functionally active cis-element included as a component in the more complex (composite) cis-element of mouse rpL32 promoter exhibiting tissue-specific properties. In various mammalian cell types the GCC-element can interact with various nuclear proteins, and the mode of these interactions can be determined by its relative position to other cis-elements in the regulatory sites of the genome.