Characterization of enterotoxigenic Escherichia coli (ETEC) has been based almost exclusively on the detection of phenotypic traits such as serotypes and virulence-associated factors: heat-labile (LT) and heat-stable (ST) toxins and colonization factors (CFs). In the present work we show that the analysis of band patterns generated by randomly amplified polymorphic DNA (RAPD) analysis and pulsed-field gel electrophoresis (PFGE) of digested chromosomal DNA can be used to detect genetic diversity among ETEC strains expressing identical phenotypic traits. The study included 29 ETEC isolates from Latin America and Spain expressing the phenotype O153:H45 CFA/I ST plus 1 rough derivative, 2 nonmotile derivatives, and 1 O78:H12 CFA/I ST isolate, and a representative of a genetically distinct ETEC group. The results showed that the O153:H45 CFA/I ST ETEC isolates belong to a single clonal cluster whose isolates share on average, 84% of the RAPD bands and 77% of the PFGE restriction fragments, while the O78:H12 isolate shared only 44 and 4% of the RAPD bands and PFGE fragments, respectively, with the isolates of the O153:H45 group. More relevantly, RAPD and PFGE fingerprints disclosed the presence of different clonal lineages among the isolates of the O153:H45 cluster. Some of the genetic variants were isolated from defined geographic areas, while places like São Paulo City in Brazil and the middle-eastern part of Argentina were populated by several genetic variants of related, but not identical, ETEC strains. These results show that molecular biology-based typing methods can disclose strain diversity, which is usually missed in studies restricted to phenotypic typing of ETEC.