Approximately 170 bacteriophages with morphologies similar to T4 have been identified (1). These T4-like phages have been isolated on a wide range of bacterial hosts that grow in diverse environments (1, 2, 72). T4, the type phage of this family, is probably the best-understood virulent phage. Its genome has been entirely sequenced, and its life cycle is extremely well understood; however, until recently little was known about all the other T4-type phages. Genomic hybridization and PCR analysis revealed that the T4-type phages vary considerably in their distance from T4 (54, 62, 72). Based on such data and limited sequence analysis, we can distinguish subgroups of the T4 type (54, 62, 72). The T-even subgroup shares considerable nucleic acid sequence homology with T4; for example, quantitative hybridization between the genomes of T2, T4, and T6 indicates that more than 90% of their sequences are nearly identical (18). As a result of their close relationship to T4, the T-even genomes can usually be analyzed and sequenced using PCR primers based on the T4 sequence (62, 71, 72). Although such comparisons confirmed that most of the T4-type phages were very close to T4, a few of them, such as RB69 (81) and SV14 (54), were clearly chimeras. The genomes of these phages have blocks of sequence that diverge significantly from T4. The origin of these sequences became obvious with the characterization of the pseudo-T-even phages (54). The members of this subgroup of the T4-type phages (e.g., RB49 and 44rr2.8t) are more diverse in their host range than the T-even phages, and their genomes are phylogenetically distant from T4 (54, 62). Only a few genes of phage RB49, for example, still retain sufficient homology to hybridize with T4 DNA under stringent conditions (54). The sequencing of the most conserved segments of the RB49 genome revealed that they encoded the structural proteins of the head (gp23 and gp24), the collar (gp20), and the contractile tail (gp18 and gp19) (54). Homologues of most of the structural components of the T4 virion were thought to be present in the pseudo-T-even phages (54). A small number of plasmids containing randomly cloned DNA of RB49 have been previously analyzed (54), and these had two sorts of sequences. A minority contained sequences that lacked homology to any entry in the NCBI database. The majority contained distant homologues to both nonstructural and structural genes of T4. Aside from their significant divergence in nucleotide sequence, the T-even and the pseudo-T-even phages also differ in the modifications of their DNA. The T-even genomes contain hydroxyl-methylcytosine in place of cytosine, and these residues are generally glucosylated, which provides additional protection against host restriction systems (12, 29). The DNA of the pseudo-T-even phages does not appear to have these nucleotide modifications (54). Consequently, the pseudo-T-even phages must have evolved a transcription and replication apparatus that was adapted to this difference in the DNA template they use. Furthermore, Southern analysis of several different pseudo-T-even phages revealed that they are as distant from each other as they are from T4 (54). Their phylogenetic distance from T4, and the genome plasticity that this implies, motivated us to further investigate the pseudo-T-even subgroup of phages. In this communication we have used an efficient partial sequencing strategy to compare the genomes of the T-even phage T4 and the pseudo-T-even phage RB49. Our snapshot of the RB49 genome indicates that it has diverged substantially and relatively uniformly from T4, and thus it is the first phage of this type to be analyzed. In addition to extensive random genomic sequencing, this study involved the targeted sequencing and characterization of two regions that contain the DNA replication genes. Although the genomes of T4 and RB49 share many features, they have important differences. A functional analysis of the RB49 promoters revealed a fundamental difference in the regulation of the gene expression in T4 and RB49. RB49 employs only two classes of temporally regulated promoters, rather than the three in T4. The evolutionary processes capable of generating such diversity within a phage family are discussed.