A compilation of virulence-associated genes that are frequently reported in avian pathogenic Escherichia coli (APEC) compared to other E. coli.

Escherichia coli survive in various hosts and environments due to their highly diversified genome. These bacteria have coevolved with humans, colonized a broad range of hosts, and survive as a commensal organism or pathogen. Escherichia coli that adopted a pathogenic lifecycle in avian hosts typically belong to phylogroups B2 and D. Phylogenic investigations discovered these E. coli are noticeably overlapped with the phylogroup of E. coli infecting humans. This overlapping is possibly due to a parallel evolution in both hosts from a common ancestor, which indicates a high zoonotic potential of avian pathogenic E. coli (APEC). However, some contrasting evidence of other phylogroups infecting the avian host has also been reported in recent studies indicating phylogroups of E. coli are not definitive, only suggestive to their virulence in chickens. Furthermore, virulence-associated genes that contribute to bacterial features necessary to establish APEC infection, are predominantly located in plasmids. Therefore, phylogenetic classification based on chromosomal markers is often inadequate to identify APEC. Moreover, E. coli can obtain virulent plasmids from other bacteria, which further complicates the link between phylogenetic classification and pathotype. Previous research has reported an array of virulence-associated genes highly prevalent only in APEC isolates. Function of these genes are possibly a prerequisite to establishing APEC infections in chickens. Consequently, these genes can be used to distinguish APEC from environmental, commensal, intestinal, and other extraintestinal E. coli. Therefore, we have extensively reviewed previous literature to compile the virulence-associated genes that are highly prevalent in APEC compared to other E. coli. From this review, we have identified 10 key virulence-associated genes (iss,tsh,iroN, episomal/chromosomal ompT,iutA,cvaC,hlyF,iucD,papG allel(II/III), and papC) that are frequently reported in APEC isolates than nonpathogenic E. coli. A compilation of these research findings can be crucial to the molecular identification of APEC. Furthermore, it can serve as a guideline for future investigation and aid in formulation of intervention strategies.

Amblyomma maculatum-associated rickettsiae in vector tissues and vertebrate hosts during tick feeding.

Rickettsia parkeri, a causative agent of spotted fever rickettsiosis, is transmitted by Amblyomma maculatum (Gulf Coast tick), a tick that may also carry a non-pathogenic spotted fever group Rickettsia, "Candidatus Rickettsia andeanae". Here, we evaluated R. parkeri and "Candidatus R. andeanae" in tissues from A. maculatum prior to, during, and after blood feeding on rabbits. Using colony-reared A. maculatum that were capillary-fed uninfected cells, R. parkeri, "Candidatus R. andeanae", or both rickettsiae, we detected higher levels of Rickettsia spp. in the respective treatment groups. Rickettsial levels increased during blood feeding for both R. parkeri and "Candidatus R. andeanae", with a greater increase in R. parkeri in co-infected ticks compared to singly-infected ticks. We detected transovarial transmission of "Candidatus R. andeanae" in egg and larval cohorts and confirmed vertical transmission of R. parkeri in one group of larvae. Rabbits from all Rickettsia-exposed groups seroconverted on immunofluorescent antibody testing using R. parkeri antigen. Visualization of "Candidatus R. andeanae" in tick salivary glands suggested potential transmission via tick feeding. Here, rickettsial levels in artificially infected ticks demonstrate changes during feeding and transovarial transmission that may be relevant for interpreting rickettsial levels detected in wild A. maculatum.