Shotgun sample sequence comparisons between mouse and human genomes.

A mixed 'clone-by-clone' and 'whole-genome shotgun' strategy will be used to determine the genomic sequence of the mouse. This method will allow a phase of rapid annotation of the contemporaneous human sequence draft, through whole-genome 'sample sequence comparisons'.

The genome sequence of Drosophila melanogaster.

The fly Drosophila melanogaster is one of the most intensively studied organisms in biology and serves as a model system for the investigation of many developmental and cellular processes common to higher eukaryotes, including humans. We have determined the nucleotide sequence of nearly all of the approximately 120-megabase euchromatic portion of the Drosophila genome using a whole-genome shotgun sequencing strategy supported by extensive clone-based sequence and a high-quality bacterial artificial chromosome physical map. Efforts are under way to close the remaining gaps; however, the sequence is of sufficient accuracy and contiguity to be declared substantially complete and to support an initial analysis of genome structure and preliminary gene annotation and interpretation. The genome encodes approximately 13,600 genes, somewhat fewer than the smaller Caenorhabditis elegans genome, but with comparable functional diversity.

Genetic selection for balanced retroviral splicing: novel regulation involving the second step can be mediated by transitions in the polypyrimidine tract.

Incomplete splicing is essential for retroviral replication; and in simple retroviruses, splicing regulation appears to occur entirely in cis. Our previous studies, using avian sarcoma virus, indicated that weak splicing signals allow transcripts to escape the splicing pathway. We also isolated a series of avian sarcoma virus mutants in which env mRNA splicing was regulated by mechanisms distinct from those of the wild-type virus. In vitro splicing experiments with one such mutant (insertion suppressor 1 [IS1]) revealed that exon 1 and lariat-exon 2 intermediates were produced (step 1) but the exons were not efficiently ligated (step 2). In this work, we have studied the mechanism of this second-step block as well as its biological relevance. Our results show that the second-step block can be overcome by extending the polypyrimidine tract, and this causes an oversplicing defect in vivo. The requirement for regulated splicing was exploited to isolate new suppressor mutations that restored viral growth by down-regulating splicing. One suppressor consisted of a single U-to-C transition in the polypyrimidine tract; a second included this same change as well as an additional U-to-C transition within a uridine stretch in the polypyrimidine tract. These suppressor mutations affected primarily the second step of splicing in vitro. These results support a specific role for the polypyrimidine tract in the second step of splicing and confirm that, in a biological system, uridines and cytosines are not functionally equivalent within the polypyrimidine tract. Unlike the wild-type virus, the second-step mutants displayed significant levels of lariat-exon 2 in vivo, suggesting a role for splicing intermediates in regulation. Our results indicate that splicing regulation can involve wither the first or second step.

Role of the constitutive splicing factors U2AF65 and SAP49 in suboptimal RNA splicing of novel retroviral mutants.

Retroviruses display a unique form of alternative splicing in which both spliced and unspliced RNAs accumulate in the cytoplasm. Simple retroviruses, such as avian sarcoma virus, do not encode regulatory proteins that affect splicing; this process is controlled solely through interactions between the viral RNA and the host cell splicing machinery. Previously, we described the selection and characterization of novel avian sarcoma virus mutants. These viruses were separated into two classes based upon analysis of splicing intermediates produced in infected cells and in a cell-free system. One class, which included mutants with altered polypyrimidine tract or branch point sequences, showed significant accumulation of intermediates, suggesting that splicing was regulated in step 2. The other class, which included mutants with deletions of exonic enhancer sequences, did not accumulate splicing intermediates, suggesting that splicing was regulated before step 1 of the splicing reaction. In this report, we show that a mutant blocked at step 1 fails to form a stable spliceosomal complex, whereas one blocked at step 2 shows a defect in its ability to transit through the last spliceosomal complex. Using UV cross-linking methods, we show that regulation at each step is associated with specific changes in the binding of cellular splicing factors. Regulation at step 1 is correlated with decreased cross-linking of the factor U2AF65, whereas regulation at step 2 is correlated with enhanced cross-linking of the factor SAP49. Because these mutations were isolated by selection for replication-competent viruses, we conclude that retroviral splicing may be regulated in vivo through altered binding of constitutive splicing factors.

The human transcript database: a catalogue of full length cDNA inserts.

SUMMARY: Full length cDNA sequences are an important resource for the research community but are currently intermingled with other sequences. We have identified the human full length insert cDNA sequences in GenBank and placed them in a single location, the Human Transcript Database. AVAILIBILITY: The Human Transcript Database is available at http://www.hgsc.bcm.tms.edu/HTDB/. CONTACT: John Bouck: jbouck@bcm.tmc.edu

Comparing vertebrate whole-genome shotgun reads to the human genome.

Multi-species sequence comparisons are a very efficient way to reveal conserved genes. Because sequence finishing is expensive and time consuming, many genome sequences are likely to stay incomplete. A challenge is to use these fragmented data for understanding the human genome. Methods for using cross-species whole-genome shotgun sequence (WGS) for genome annotation are described in this paper. About one-half million high-quality rat WGS reads (covering 7.5% of the rat genome) generated at the Baylor College of Medicine Human Genome Sequencing Center were compared with the human genome. Using computer-generated random reads as a negative control, a set of parameters was determined for reliable interpretation of BLAST search results. About 10% of the rat reads contain regions that are conserved in the human genomic sequence and about one-third of these include known gene-coding regions. Mapping the conserved regions to human chromosomes showed a 23-fold enrichment for coding regions compared with noncoding regions. This approach can also be applied to other mammalian genomes for gene finding. These data predicted approximately 42,500 genes in the human, slightly more than reported previously.

In vivo selection for intronic splicing signals from a randomized pool.

Retroviruses utilize balanced splicing to express multiple proteins from a single primary transcript. A number of cis -acting signals help maintain this balance, including the branch point sequence (BPS), polypyrimidine tract (PPyT) and sequences within the downstream exon. In general, regulated splicing requires weak splicing signals and we have previously shown the same requirement for the simple retrovirus, avian sarcoma virus (ASV). Here we take advantage of the requirement for balanced splicing in retroviral replication to examine the sequence constraints of an intronic splicing element. Selection for replication competence makes it possible to amplify and identify functional sequences from a pool of all possible sequences. In this report we examine the role of pyrimidines within the PPyT. Our results provide in vivo confirmation that the functional strength of a PPyT is related to its length and uridine content and that the PPyT plays a role in the second step of the splicing reaction. We also show that the minimal distance between the 3'-splice site and the BPS in this system is 16 nt. With modification, the selection system described here can be used to examine the sequence constraints of other exonic or intronic splicing elements in vivo .

Analysis of the quality and utility of random shotgun sequencing at low redundancies.

The currently favored approach for sequencing the human genome involves selecting representative large-insert clones (100-200 kb), randomly shearing this DNA to construct shotgun libraries, and then sequencing many different isolates from the library. This method, entitled directed random shotgun sequencing, requires highly redundant sequencing to obtain a complete and accurate finished consensus sequence. Recently it has been suggested that a rapidly generated lower redundancy sequence might be of use to the scientific community. Low-redundancy sequencing has been examined previously using simulated data sets. Here we utilize trace data from a number of projects submitted to GenBank to perform reconstruction experiments that mimic low-redundancy sequencing. These low-redundancy sequences have been examined for the completeness and quality of the consensus product, information content, and usefulness for interspecies comparisons. The data presented here suggest three different sequencing strategies, each with different utilities. (1) Nearly complete sequence data can be obtained by sequencing a random shotgun library at sixfold redundancy. This may therefore represent a good point to switch from a random to directed approach. (2) Sequencing can be performed with as little as twofold redundancy to find most of the information about exons, EST hits, and putative exon similarity matches. (3) To obtain contiguity of coding regions, sequencing at three- to fourfold redundancy would be appropriate. From these results, we suggest that a useful intermediate product for genome sequencing might be obtained by three- to fourfold redundancy. Such a product would allow a large amount of biologically useful data to be extracted while postponing the majority of work involved in producing a high quality consensus sequence.

PipMaker--a web server for aligning two genomic DNA sequences.

PipMaker (http://bio.cse.psu.edu) is a World-Wide Web site for comparing two long DNA sequences to identify conserved segments and for producing informative, high-resolution displays of the resulting alignments. One display is a percent identity plot (pip), which shows both the position in one sequence and the degree of similarity for each aligning segment between the two sequences in a compact and easily understandable form. Positions along the horizontal axis can be labeled with features such as exons of genes and repetitive elements, and colors can be used to clarify and enhance the display. The web site also provides a plot of the locations of those segments in both species (similar to a dot plot). PipMaker is appropriate for comparing genomic sequences from any two related species, although the types of information that can be inferred (e.g., protein-coding regions and cis-regulatory elements) depend on the level of conservation and the time and divergence rate since the separation of the species. Gene regulatory elements are often detectable as similar, noncoding sequences in species that diverged as much as 100-300 million years ago, such as humans and mice, Caenorhabditis elegans and C. briggsae, or Escherichia coli and Salmonella spp. PipMaker supports analysis of unfinished or "working draft" sequences by permitting one of the two sequences to be in unoriented and unordered contigs.