ABSTRACT
Elizabethkingia anophelis is an emerging global multidrug-resistant opportunistic pathogen. We assessed the diversity among 13 complete genomes and 23 draft genomes of E. anophelis derived from various environmental settings and human infections from different geographic regions around the world over past decades from 1950s. Thirty-one of these 36 strains harbor integrative and conjugative elements (ICEs). A total of 52 ICEs were identified, and categorized into three ICE types based on the architecture of signature genes in the conjugation module. The type II and III ICEs were found to integrate into regions adjacent to tRNA genes, while type I ICEs used a variety of integration sites, inserting into intergenic regions or even directly into a gene, sometimes disrupting gene function. Integrases such as tyrosine recombinases, serine recombinases and DDE transposases were found in most ICEs. The ICEs carry various cargo genes including transcription regulators and those involved in antibiotic resistance. The CRISPR-Cas system was found in nine strains, including four strains in which CRISPR-Cas machinery and ICEs co-exist. ICE distribution in the strains showed no geographic or temporal patterns. The ICEs in E. anophelis differ in gene structure and sequence from CTnDOT, a well-studied ICE prevalent in Bacteroides spp. This is the first set of ICEs identified in the family Flavobacteriaceae. As a prevalent type of mobile genetic elements in various strains of E. anophelis around the world, the categorization of ICEs will facilitate further investigations such as virulence, genome epidemiology and adaptation genomics of E. anophelis.
Importance Elizabethkingia anophelis is an opportunistic human pathogen, and the genetic diversity between strains from around the world becomes apparent as more genomes are sequenced. The Integrative Conjugative Element (ICE), found in many bacterial species, contains genes for transfer via conjugation and integration into the chromosome, along with various cargo genes. ICEs are identified in 31 of 36 strains and categorized into three types based on architecture of modular genes, integrases, and integration sites. ICE distribution in different strains displays no spatial and temporal patterns. Several ICE-containing strains also possessed CRISPR-Cas units, considered to be the bacterial adaptive immune system providing protection against phage and predatory mobile genetic elements. This co-existence suggests that ICEs are beneficial or at least not harmful to the bacterial cells they inhabit. ICEs as a component of the mobile genetic repertoire enable recipients to resist antibiotics, survive disinfecting agents, and adapt to various ecological niches.