Primers were designed to amplify a 592-bp region within a conserved structural gene (g20) found in some cyanophages. The goal was to use this gene as a proxy to infer genetic richness in natural cyanophage communities and to determine if sequences were more similar in similar environments. Gene products were amplified from samples from the Gulf of Mexico, the Arctic, Southern, and Northeast and Southeast Pacific Oceans, an Arctic cyanobacterial mat, a catfish production pond, lakes in Canada and Germany, and a depth of ca. 3,246 m in the Chuckchi Sea. Amplicons were separated by denaturing gradient gel electrophoresis, and selected bands were sequenced. Phylogenetic analysis revealed four previously unknown groups of g20 clusters, two of which were entirely found in freshwater. Also, sequences with >99% identities were recovered from environments that differed greatly in temperature and salinity. For example, nearly identical sequences were recovered from the Gulf of Mexico, the Southern Pacific Ocean, an Arctic freshwater cyanobacterial mat, and Lake Constance, Germany. These results imply that closely related hosts and the viruses infecting them are distributed widely across environments or that horizontal gene exchange occurs among phage communities from very different environments. Moreover, the amplification of g20 products from deep in the cyanobacterium-sparse Chuckchi Sea suggests that this primer set targets bacteriophages other than those infecting cyanobacteria.Unicellular cyanobacteria are a major component of the prokaryotic biomass in the oceans (6, 15), account for more than half of the fixed carbon in some regions, and play a key role in the transfer of energy through the microbial loop (6,15,21). Consequently, knowledge of the regulation of cyanobacterial communities is required to understand global nutrient and energy cycles.Viruses are the most abundant biological entities in fresh and marine waters and are typically 5-to 10-fold more abundant than prokaryotes (1,19,29). As mortality agents of heterotrophic and photosynthetic microbes (8,25,37), they affect the abundance and diversity of host cell communities (13, 18) as well as the cycling of carbon and nutrients (37).The proportion of primary producers lost to viral lysis is uncertain; however, viruses infecting a single strain of the marine cyanobacterium Synechococcus are widespread and can reach levels of abundance of Ͼ10 5 ml Ϫ1 (16,27,36). Estimates from the proportions of visibly infected cells and viral decay rates suggest that approximately 3 to 10% of Synechococcus spp. are destroyed daily by viral lysis (19,26,37).The impact of viruses on host communities can be inferred from viral community diversity, as viral taxonomy can provide insights into the hosts that they infect. For example, phylogenetic analyses of algal virus DNA polymerase genes revealed that phycoviruses are monophyletic relative to other viral families and that genetically distinct groups are clearly resolved and correspond to the host taxon infected (3, 4). Subsequ...
