Cloacibacillus sp., a Potential Human Pathogen Associated with Bacteremia in Quebec and New Brunswick

A 54-year-old woman was admitted to the Centre Hospitalier de l'Université de Montréal-Hôpital Saint-Luc (Montreal, QC, Canada) for vomiting, right iliac fossa pain and tenderness, and a temperature of 39.5°C for the last 24 h. The patient was known for obesity (118 kg) and a medical history of cholecystectomy. The medical exam revealed a positive McBurney point. Hematological investigations revealed leukocytosis with a white cell count of 17.5 × 10⁹/liter with 90% neutrophils, a hemoglobin level of 155 g/liter, a platelet count of 230 × 10⁹/liter, a creatinine level of 62 μmol/liter, and a total bilirubin level of 29.6 (normal, 7 to 23) μmol/liter. The aspartate aminotransferase, alanine transaminase, and alkaline phosphatase levels were normal. The urine biochemical analysis and bacterial culture were normal and negative, respectively. Two sets of blood cultures were done (BD Bactec). An abdomino-pelvic CT scan showed a 9-cm uterine fibroma, hepatic steatosis, and inflamed fat with gas bubbles around the appendix, compatible with acute appendicitis. Empirical antimicrobial therapy consisted of 3.375 g of intravenous piperacillin-tazobactam every 6 h. The patient improved progressively and became afebrile with a decrease in abdominal pain. One anaerobic bottle out of the two blood cultures was positive for a slowly growing, anaerobic, Gram-negative rod that was later isolated on fastidious anaerobe agar (Oxoid, Basingstoke, United Kingdom). No other organism was isolated. The strictly anaerobic, slowly growing, Gram-negative bacillus was identified as Cloacibacillus porcorum on the basis of 16S rRNA gene nucleotide sequence identity with the species type strain (CL-84^T) and was designated strain LSPQ-04226. On day 4, the white cell count was 8.6 × 10⁹/liter with 73% neutrophils, the hemoglobin level at 115 g/liter, the platelet count was 269 × 10⁹/liter, and the creatinine level was 62 μmol/liter. The intravenous antimicrobial agent was changed to oral amoxicillin-clavulanic acid at 875 mg every 12 h for 10 days. The patient continued to improve and was followed up at the outpatient clinic by the digestive surgeon. Three months later, a complete colonoscopy showed only slight sigmoid diverticular disease.

The genus Cloacibacillus was first described by Ganesan et al. (1) and comprises two validly described species, C. evryensis and C. porcorum (2). Cells of the genus Cloacibacillus are strictly anaerobic, Gram-negative bacilli that are nonmotile and were originally isolated from environmental sources. C. evryensis was isolated from an anaerobic digester of a wastewater treatment plant (1); C. porcorum was isolated from the mucosal lining of a pig cecum (2). Members of this genus can be identified by 16S rRNA gene sequencing, cellular fatty acid profiles, DNA G+C content, and metabolic end product analysis (1). The genus Cloacibacillus is a member of the family Synergistaceae in the phylum Synergistetes, which was described in 2009 (3). The phylum contains 12 genera, Aminiphilus, Aminobacterium, Aminomonas, Anaerobaculum, Cloacibacillus, Dethiosulfovibrio, Fretibacterium, Jonquetella, Pyramidobacter, Synergistes, Thermanaerovibrio, and Thermovirga (4). Previously, most of the 16S rRNA gene sequences available from this phylum were obtained from culture-independent studies (3, 5–11). A small number of isolates were shown to be present in human infections, including soft tissue infections, abscesses, blood, peritoneal fluid, and dental infections (5–11). However, the lack of identification of Synergistetes isolates at the genus level led to the generic grouping under the Synergistes group of organisms (SGO) (3, 7, 11–13). With the initial description of the genus Cloacibacillus in 2008, 16S rRNA gene sequencing and phylogenetic analysis are now available for the proper identification of Cloacibacillus species (1, 2). We report here the first clinical description of Cloacibacillus bacteremia in three patients from whom either C. evryensis or C. porcorum was isolated. The three isolates, LSPQ-04215, LSPQ-04216, and LSPQ-04226, were identified by 16S rRNA gene sequencing with the BigDye Terminator v3.1 Cycle Sequencing kit on an ABI3130 XL genetic analyzer (Applied Biosystems, Foster City, CA, USA) (14). To identify the taxonomic neighbors of the three clinical isolates, the 16S rRNA gene sequences were used for an initial BLAST search (http://www.ncbi.nlm.nih.gov/BLAST) against GenBank. Phylogenetic and molecular evolutionary analyses with genera of the phylum Synergistetes were performed on 1,136 nucleotides with MEGA version 5 (15). Isolates LSPQ-04215 and LSPQ-04216 showed 100% nucleotide sequence identity with C. evryensis strain 158^T (GenBank accession no. CU463952). Likewise, LSPQ-04226 showed 100% nucleotide sequence identity with C. porcorum strain CL-84^T (GenBank accession no. JQ809697). The two C. evryensis isolates, LSPQ-04215 and LSPQ-04216, showed 97% nucleotide sequence identity with the 16S rRNA gene sequences of both C. porcorum CL-84^T and LSPQ-04226. A neighbor-joining phylogenetic tree showed that isolates LSPQ-04215 and LSPQ-04216 clustered with C. evryensis 158^T while LSPQ-04226 clustered with C. porcorum CL-84^T (Fig. 1). Interestingly, we found that several isolates previously named Synergistes sp., Synergistes bacterium, or simply “bacterium” in the features contained in their annotation sequences submitted to GenBank clearly belonged to the species C. evryensis or C. porcorum (Fig. 1). Several Cloacibacillus-like strains were isolated from human infections, but the use of older taxonomic classification positioned them on various branches of the SGO phylogeny (Fig. 1). In the three university hospitals where isolates LSPQ-04215, LSPQ-04216, and LSPQ-04226 originated, conventional anaerobic characterization was performed according to reference 16 and was based on growth under anaerobic conditions; Gram staining; commercially available anaerobe identification substrates; testing for susceptibility to kanamycin, colistin, and vancomycin; and growth on bile medium. Cloacibacillus species are obligate anaerobes that grow slowly (1, 2). The calculated doubling time previously reported varies from 8 h for C. porcorum to 15 h for C. evryensis (1, 2), which could explain the rare Gram-negative bacilli observed in blood cultures after more than 3 days of incubation in the cases reported here. All three isolates, LSPQ-04215, LSPQ-04216, and LSPQ-04226, are susceptible to kanamycin and resistant to colistin and vancomycin, like C. evryensis 158^T and C. porcorum CL-84^T (1, 2). The conventional phenotype-based methods for anaerobes failed to identify Cloacibacillus species. The three isolates could not be identified by Vitek MS matrix-assisted laser desorption ionization–time of flight (MALDI-TOF) mass spectrometry (bioMérieux Canada, Saint-Laurent, QC, Canada). A single isolate, C. evryensis LSP-04215, was tested on a Bruker MALDI Biotyper (Bruker, Madison, WI, USA). It could not be identified. The genus Cloacibacillus was not included in Vitek MS IVD version 2.0 (bioMérieux Canada), a clinically relevant species database; SARAMIS (spectral archive and microbial identification system) version 4.1 (bioMérieux Canada); or in the Bruker MALDI Biotyper databases. New spectrum entries were added to the SARAMIS database by using cultures from three different times of incubation (3, 7, and 10 days) for each of the three isolates. On the basis of this newly updated library, the SARAMIS database was capable of identifying the three isolates and assigned them to either C. evryensis or C. porcorum, respectively. We are planning to add both type strains (C. evryensis 158^T and C. porcorum CL-84^T) to the SARAMIS database in the near future. The antimicrobial susceptibilities of the three isolates were determined by the agar dilution method after 48 h of anaerobic incubation on prereduced laked sheep blood agar supplemented with hemin (5 μg/ml) and vitamin K (1 μg/ml), as recommended by the Clinical and Laboratory Standards Institute (17). The MICs for each isolate are reported in Table 1. As human infections with both Cloacibacillus species have remained largely uncharacterized, we reviewed the patients' charts for symptoms of infection, inflammation parameters such as fever, leukocyte counts, monomicrobial bacteremia, and clinical diagnosis. We also compared the isolation sites and clinical diagnoses of our three cases to the previous cases of Cloacibacillus-like strains by using the features contained in the annotation of the sequence data submitted to GenBank (Table 2). The latter were isolated from the environment and from human blood, peritoneal fluid, and the digestive tract (Table 2). The patients in cases 1 and 3 had proctitis and appendicitis, respectively, indicating a probable intestinal origin of their bacteremia. The probable intestinal origin of the Cloacibacillus bacteremia in our three case reports is in accordance with the isolation sites of several Cloacibacillus-like strains reviewed in Table 2. The antimicrobial susceptibility testing of the three Cloacibacillus isolates showed susceptibility to antibiotics commonly used for anaerobic infections. The patients all improved clinically after initiation of antibiotherapy. The three cases presented suggest that Cloacibacillus species are low-virulence, opportunistic pathogens associated with elderly or otherwise debilitated hosts. It is noteworthy that the patient described in case 2 made a full clinical recovery despite receiving only ceftriaxone and TMP-SMX, two antibiotics with limited uses against anaerobes. None of the patients described relapsed with Cloacibacillus bacteremia, and none of the patients died within 30 days.

Physicians should be aware that Cloacibacillus species can be opportunistic human pathogens associated with intestinal infections.

The GenBank accession numbers for isolates LSPQ-04215, LSPQ-04216, and LSPQ-04226 are KM881707, KM881708, and KP851977, respectively.