J. Youngblom

We have identified three new members of the olfactory receptor (OR) gene family within a large segment of DNA that is duplicated with high similarity near many human telomeres. This segment is present at 3q, 15q, and 19p in each of 45 unrelated humans sampled from various populations. Additional copies are present polymorphically at 11 other subtelomeric locations. The frequency with which the block is present at some locations varies among populations. While humans carry seven to 11 copies of the OR-containing block, it is located in chimpanzee and gorilla predominantly at a single site, which is not orthologous to any of the locations in the human genome. The observation that sequences flanking the OR-containing segment are duplicated on larger and different sets of chromosomes than the OR block itself demonstrates that the segment is part of a much larger, complex patchwork of subtelomeric duplications. The population analyses and structural results suggest the types of processes that have shaped these regions during evolution. From its sequence, one of the OR genes in this duplicated block appears to be potentially functional. Our findings raise the possibility that functional diversity in the OR family is generated in part through duplications and inter-chromosomal rearrangements of the DNA near human telomeres.

The Genomics Education Partnership offers an inclusive model for undergraduate research experiences incorporated into the academic year science curriculum, with students pooling their work to contribute to international data bases.

The two beta-tubulin genes of the unicellular green alga Chlamydomonas reinhardtii are expressed coordinately after deflagellation and produce two transcripts of 2.1 and 2.0 kilobases. Full-length cDNA clones corresponding to the transcript of each gene were isolated. DNA sequences were obtained from the cDNA clones and from cloned tubulin gene fragments. Both genes contained 1,332 base pairs of coding sequence, with only 19 nucleotide differences between the genes. Because all the differences occurred at the third base position of a codon and did not change the predicted amino acid sequence, we concluded that both beta-tubulin genes code for the same protein of 443 amino acids. The predicted amino acid sequence is 89 and 72% homologous with beta-tubulins from chicken and yeast cells, respectively. Each gene had three intervening sequences, which occurred at identical positions. Although the first two intervening sequences were not conserved between the two genes, the nucleotide sequence of the third intervening sequence was 89% conserved between the genes. The codon usage in the tubulin genes of C. reinhardtii was very biased: only 37 different codons were used. Striking differences occurred between the codons used in these nuclear genes and C. reinhardtii chloroplast genes.

Calmodulin is encoded in Chlamydomonas reinhardtii by a single gene that 1) has multiple intervening sequences, 2) has 5' structural motifs that are phylogenetically conserved, 3) contains 5' sequences that are similar to those found in genes of some transforming, cytoskeletal, and stress-response proteins, and 4) produces at both life cycle stages, a single size class of mRNA and proteins that are identical in amino acid sequence. Based on the amino acid sequence of calmodulin from the vegetative phase of the life cycle, synthetic oligonucleotide probes, containing inosine in order to reduce codon redundancy, were used to detect and isolate cloned cDNAs coding for the gametic phase calmodulin. The complete DNA sequence was elucidated and shown to code for a protein identical to the vegetative phase protein. Analysis of the production of calmodulin mRNA indicates that protein production is under quantitative regulation and possibly coupled with the synthesis of other proteins in the flagellar apparatus. The full length cDNA was used to isolate overlapping genomic clones that include the entire calmodulin transcriptional unit and 5' regulatory sequences. The complete DNA sequence of the gene, including all intron sequences, was elucidated. The DNA sequence of the coding regions shows some phylogenetic conservation. Finally, there are regions of 5' sequence reminiscent of sequence motifs recently identified as binding sites of transcriptional regulatory proteins. Overall, these studies suggest possible molecular genetic relationships between calmodulin, a transducer of intracellular calcium signals, and other proteins involved in eukaryotic cell structure, motility, and homeostasis.

We mapped three antigenic domains of continuous epitopes on human cytomegalovirus (CMV) glycoprotein B (gB) by reacting a panel of independently derived monoclonal antibodies with deletion mutants expressed transiently in COS-1 cells. One of these antigenic domains, DC2, maps in the last 75 amino acids of the carboxy terminus. These epitopes are conserved in strains Towne and AD169, as well as in 19 clinical CMV isolates. ELISAs of DC2-reactive antibodies with a set of overlapping synthetic oligopeptides from the carboxy terminus showed that the epitopes of antibodies CH405-1 and CH421-5 map between amino acids 833 and 852 and that the epitope of antibody CH28-2 maps between amino acids 878 and 898. These linear epitopes were grouped into domain DC3. The third antigenic domain, DC1v, maps at the amino-terminal end of CMV strain AD169 gB but is not contained in strain Towne or in 17 of 19 clinical isolates. Epitopes in this domain are likely to map between amino acids 28 and 67, an area where differences occur in the nucleotide sequence of the gB genes from AD169 and Towne. Analysis of CMV-infected cells by flow cytometry with antibodies to the amino- and carboxy-terminal domains revealed that the amino terminus of gB is extracellular and that the carboxy terminus is not exposed on the cell surface.