Microdissection molecular copy-number counting (microMCC)--unlocking cancer archives with digital PCR.

Most cancer genomes are characterized by the gain or loss of copies of some sequences through deletion, amplification or unbalanced translocations. Delineating and quantifying these changes is important in understanding the initiation and progression of cancer, in identifying novel therapeutic targets, and in the diagnosis and prognosis of individual patients. Conventional methods for measuring copy-number are limited in their ability to analyse large numbers of loci, in their dynamic range and accuracy, or in their ability to analyse small or degraded samples. This latter limitation makes it difficult to access the wealth of fixed, archived material present in clinical collections, and also impairs our ability to analyse small numbers of selected cells from biopsies. Molecular copy-number counting (MCC), a digital PCR technique, has been used to delineate a non-reciprocal translocation using good quality DNA from a renal carcinoma cell line. We now demonstrate microMCC, an adaptation of MCC which allows the precise assessment of copy number variation over a significant dynamic range, in template DNA extracted from formalin-fixed paraffin-embedded clinical biopsies. Further, microMCC can accurately measure copy number variation at multiple loci, even when applied to picogram quantities of grossly degraded DNA extracted after laser capture microdissection of fixed specimens. Finally, we demonstrate the power of microMCC to precisely interrogate cancer genomes, in a way not currently feasible with other methodologies, by defining the position of a junction between an amplified and non-amplified genomic segment in a bronchial carcinoma. This has tremendous potential for the exploitation of archived resources for high-resolution targeted cancer genomics and in the future for interrogating multiple loci in cancer diagnostics or prognostics.

The genome of the social amoeba Dictyostelium discoideum.

The social amoebae are exceptional in their ability to alternate between unicellular and multicellular forms. Here we describe the genome of the best-studied member of this group, Dictyostelium discoideum. The gene-dense chromosomes of this organism encode approximately 12,500 predicted proteins, a high proportion of which have long, repetitive amino acid tracts. There are many genes for polyketide synthases and ABC transporters, suggesting an extensive secondary metabolism for producing and exporting small molecules. The genome is rich in complex repeats, one class of which is clustered and may serve as centromeres. Partial copies of the extrachromosomal ribosomal DNA (rDNA) element are found at the ends of each chromosome, suggesting a novel telomere structure and the use of a common mechanism to maintain both the rDNA and chromosomal termini. A proteome-based phylogeny shows that the amoebozoa diverged from the animal-fungal lineage after the plant-animal split, but Dictyostelium seems to have retained more of the diversity of the ancestral genome than have plants, animals or fungi.

A high-resolution HAPPY map of Dictyostelium discoideum chromosome 6.

We have made a high-resolution HAPPY map of chromosome 6 of Dictyostelium discoideum consisting of 300 sequence-tagged sites with an average spacing of 14 kb along the approximately 4-Mb chromosome. The majority of the marker sequences were derived from randomly chosen clones from four different chromosome 6-enriched plasmid libraries or from subclones of YACs previously mapped to chromosome 6. The map appears to span the entire chromosome, although marker density is greater in some regions than in others and is lowest within the telomeric region. Our map largely supports previous gene-based maps of this chromosome but reveals a number of errors in the physical map. In addition, we find that a high proportion of the plasmid sequences derived from gel-enriched chromosome 6 (and that form the basis of a chromosome-specific sequencing project) originates from other chromosomes.

Ribonuclease k6: chromosomal mapping and divergent rates of evolution within the RNase A gene superfamily.

We have localized the gene encoding human RNase k6 to within approximately 120 kb on the long (q) arm of chromosome 14 by HAPPY mapping. With this information, the relative positions of the six human RNase A ribonucleases that have been mapped to this locus can be inferred. To further our understanding of the individual lineages comprising the RNase A superfamily, we have isolated and characterized 10 novel genes orthologous to that encoding human RNase k6 from Great Ape, Old World, and New World monkey genomes. Each gene encodes a complete ORF with no less than 86% amino acid sequence identity to human RNase k6 with the eight cysteines and catalytic histidines (H15 and H123) and lysine (K38) typically observed among members of the RNase A superfamily. Interesting trends include an unusually low number of synonymous substitutions (Ks) observed among the New World monkey RNase k6 genes. When considering nonsilent mutations, RNase k6 is a relatively stable lineage, with a nonsynonymous substitution rate of 0.40 x 10(-9) nonsynonymous substitutions/nonsynonymous site/year (ns/ns/yr). These results stand in contrast to those determined for the primate orthologs of the two closely related ribonucleases, the eosinophil-derived neurotoxin (EDN) and eosinophil cationic protein (ECP), which have incorporated nonsilent mutations at very rapid rates (1.9 x 10(-9) and 2.0 x 10(-9) ns/ns/yr, respectively). The uneventful trends observed for RNase k6 serve to spotlight the unique nature of EDN and ECP and the unusual evolutionary constraints to which these two ribonuclease genes must be responding. [The sequence data described in this paper have been submitted to the GenBank data library under accession nos. AF037081-AF037090.]

A high-resolution metric HAPPY map of human chromosome 14.

We have mapped 1001 novel sequence-tagged sites on human chromosome 14. The mean spacing between markers is approximately 90 kb, most markers are mapped with a resolution of better than 100 kb, and physical distances are determined. The map was produced using HAPPY mapping, a simple and widely applicable in vitro approach that is analogous to linkage or to radiation hybrid mapping, but that circumvents many of the difficulties and potential artifacts associated with these methods. We show also that the map serves as a robust scaffold for building physical maps using large-insert clones.

A HAPPY map of Cryptosporidium parvum.

We have constructed a HAPPY map of the apicomplexan parasite Cryptosporidium parvum. We have placed 204 markers on the 10.4-Mb genome, giving an average marker spacing of approximately 50 kb, with an effective resolution of approximately 40 kb. HAPPY mapping (an in vitro linkage technique based on screening approximately haploid amounts of DNA by the polymerase chain reaction) is fast and accurate and is not subject to the distortions inherent in cloning, meiotic recombination, or hybrid cell formation. In addition, little genomic DNA is needed as a substrate, and the AT content of the genome is largely immaterial, making it an ideal method for mapping otherwise intractable parasite genomes. The map, covering all eight chromosomes, consists of 10 linkage groups, each of which has been chromosomally assigned. We have verified the accuracy of the map by several methods, including the construction of a >140-kb PAC contig on chromosome VI. Less than 1% of our markers detect non-rDNA duplicated sequences.

The DNA sequence of the human cytomegalovirus genome.

In the first part of this article we review what has been learnt from the analysis of the sequence of HCMV. A summary of this information is presented in the form of an updated map of the viral genome. HCMV is representative of a major lineage of herpesviruses distinct from previously sequenced members of this viral family and demonstrates striking differences in genetic content and organization. The virus encodes approximately 200 genes, including nine gene families, a large number of glycoprotein genes, and homologues of the human HLA class I and G protein-coupled receptor genes. The HCMV sequence thus provides a sound basis for future molecular studies of this highly complex eukaryotic virus. The second part discusses the practical rate of DNA sequencing as deduced from this and other studies. The 229 kilobase pair DNA genome of human cytomegalovirus (HCMV) strain AD169 is the largest contiguous sequence determined to date, and as such provides a realistic benchmark for assessing the practical rate of DNA sequencing as opposed to theoretical calculations which are usually much greater. The sequence was determined manually and we assess the impact of new developments in DNA sequencing.

Semiautomated preparation of DNA templates for large-scale sequencing projects.

The rate limiting step in a large-scale sequencing project is the generation of single-stranded DNA templates. We describe a fast, semiautomated procedure, using 96-well microtitre plates, in which 192 templates can be readily prepared in 1 day. The technique can be carried out manually or can be semiautomated using a robot pipetting device. We also provide evidence for the reliability and applicability of this method to a large-scale sequencing project.

An immediate early gene of human cytomegalovirus encodes a potential membrane glycoprotein.

The sequence of a region of the HCMV genome transcribed during the immediate early (IE) transcriptional phase has been determined. Transcription analysis of this region at the junction between fragments HindIII Z and J has identified three moderately abundant mRNAs of 3.4, 1.7, and 1.65 kb. The 3.4-kb RNA is expressed only under IE conditions of infection. It is composed of four exons and its predicted translation product has features characteristic of a membrane-bound glycoprotein. The 1.7-kb RNA is transcribed at both IE and late times postinfection. It is expressed from the same promoter as the 3.4-kb RNA and does not appear to be spliced. The 1.65-kb RNA is present at the IE phase, but is more abundantly transcribed at late times. It is composed of two exons and is 3' coterminal to the 3.4-kb RNA. Within the predicted translation product of the 1.65-kb RNA there are three regions which show homology to a family of related open reading frames found within the short unique region of HCMV.