Last data update: Dec 02, 2024. (Total: 48272 publications since 2009)
Records 1-14 (of 14 Records) |
Query Trace: Lucas CE[original query] |
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Large community outbreak of legionnaires disease potentially associated with a cooling tower - Napa County, California, 2022
Grossmann NV , Milne C , Martinez MR , Relucio K , Sadeghi B , Wiley EN , Holland SN , Rutschmann S , Vugia DJ , Kimura A , Crain C , Akter F , Mukhopadhyay R , Crandall J , Shorrock M , Smith JC , Prasad N , Kahn R , Barskey AE , Lee S , Willby MJ , Kozak-Muiznieks NA , Lucas CE , Henderson KC , Hamlin JAP , Yang E , Clemmons NS , Ritter T , Henn J . MMWR Morb Mortal Wkly Rep 2023 72 (49) 1315-1320 Legionnaires disease is a serious infection acquired by inhalation of water droplets from human-made building water systems that contain Legionella bacteria. On July 11 and 12, 2022, Napa County Public Health (NCPH) in California received reports of three positive urinary antigen tests for Legionella pneumophila serogroup 1 in the town of Napa. By July 21, six Legionnaires disease cases had been confirmed among Napa County residents, compared with a baseline of one or two cases per year. NCPH requested assistance from the California Department of Public Health (CDPH) and CDC to aid in the investigations. Close temporal and geospatial clustering permitted a focused environmental sampling strategy of high-risk facilities which, coupled with whole genome sequencing results from samples and investigation of water system maintenance, facilitated potential linking of the outbreak with an environmental source. NCPH, with technical support from CDC and CDPH, instructed and monitored remediation practices for all environmental locations that tested positive for Legionella. The investigation response to this community outbreak illustrates the importance of interdisciplinary collaboration by public health agencies, laboratory support, timely communication with the public, and cooperation of managers of potentially implicated water systems. Timely identification of possible sources, sampling, and remediation of any facility testing positive for Legionella is crucial to interrupting further transmission. |
Notes from the Field: Legionnaires disease in a U.S. traveler after staying in a private vacation rental house in the U.S. Virgin Islands - United States, February 2022
Mac VV , Labgold K , Moline HL , Smith JC , Carroll J , Clemmons N , Edens C , Ellis B , Harrison C , Henderson KC , Ishaq MK , Kozak-Muiznieks NA , Kunz J , Lawrence M , Lucas CE , Walker HL , Willby MJ , Ellis EM . MMWR Morb Mortal Wkly Rep 2023 72 (20) 564-565 On February 1, 2022, the U.S. Virgin Islands (USVI) Department of Health (VIDOH) was notified of a confirmed case of Legionnaires disease in an adult U.S. resident (Figure). The patient, a man aged 55 years, returned to his U.S. state of residence from leisure travel in USVI on January 22 and developed a cough, shortness of breath, and fatigue on January 23. On January 29, he was hospitalized for shortness of breath and received a positive SARS-CoV-2 test result at admission. The combination of the patient’s symptoms and recent travel history prompted administration of a urinary antigen test (UAT) for Legionnaires disease specific to Legionella pneumophila serogroup 1 (Lp1); a positive result was returned on January 31. Inpatient treatment administered for COVID-19 pneumonia and Legionnaires disease included remdesivir, oral levofloxacin, oral and intravenous steroid therapy, and as-needed use of a bronchodilator inhaler and an expectorant. Remdesivir was discontinued during inpatient treatment because of elevated liver enzymes. The patient recovered and was discharged on February 2. |
Comparative genome analysis reveals a complex population structure of Legionella pneumophila subspecies.
Kozak-Muiznieks NA , Morrison SS , Mercante JW , Ishaq MK , Johnson T , Caravas J , Lucas CE , Brown E , Raphael BH , Winchell JM . Infect Genet Evol 2018 59 172-185 The majority of Legionnaires' disease (LD) cases are caused by Legionella pneumophila, a genetically heterogeneous species composed of at least 17 serogroups. Previously, it was demonstrated that L. pneumophila consists of three subspecies: pneumophila, fraseri and pascullei. During an LD outbreak investigation in 2012, we detected that representatives of both subspecies fraseri and pascullei colonized the same water system and that the outbreak-causing strain was a new member of the least represented subspecies pascullei. We used partial sequence based typing consensus patterns to mine an international database for additional representatives of fraseri and pascullei subspecies. As a result, we identified 46 sequence types (STs) belonging to subspecies fraseri and two STs belonging to subspecies pascullei. Moreover, a recent retrospective whole genome sequencing analysis of isolates from New York State LD clusters revealed the presence of a fourth L. pneumophila subspecies that we have termed raphaeli. This subspecies consists of 15 STs. Comparative analysis was conducted using the genomes of multiple members of all four L. pneumophila subspecies. Whereas each subspecies forms a distinct phylogenetic clade within the L. pneumophila species, they share more average nucleotide identity with each other than with other Legionella species. Unique genes for each subspecies were identified and could be used for rapid subspecies detection. Improved taxonomic classification of L. pneumophila strains may help identify environmental niches and virulence attributes associated with these genetically distinct subspecies. |
Distribution of Legionella and bacterial community composition among regionally diverse US cooling towers
Llewellyn AC , Lucas CE , Roberts SE , Brown EW , Nayak BS , Raphael BH , Winchell JM . PLoS One 2017 12 (12) e0189937 Cooling towers (CTs) are a leading source of outbreaks of Legionnaires' disease (LD), a severe form of pneumonia caused by inhalation of aerosols containing Legionella bacteria. Accordingly, proper maintenance of CTs is vital for the prevention of LD. The aim of this study was to determine the distribution of Legionella in a subset of regionally diverse US CTs and characterize the associated microbial communities. Between July and September of 2016, we obtained aliquots from water samples collected for routine Legionella testing from 196 CTs located in eight of the nine continental US climate regions. After screening for Legionella by PCR, positive samples were cultured and the resulting Legionella isolates were further characterized. Overall, 84% (164) were PCR-positive, including samples from every region studied. Of the PCR-positive samples, Legionella spp were isolated from 47% (78), L. pneumophila was isolated from 32% (53), and L. pneumophila serogroup 1 (Lp1) was isolated from 24% (40). Overall, 144 unique Legionella isolates were identified; 53% (76) of these were Legionella pneumophila. Of the 76 L. pneumophila isolates, 51% (39) were Lp1. Legionella were isolated from CTs in seven of the eight US regions examined. 16S rRNA amplicon sequencing was used to compare the bacterial communities of CT waters with and without detectable Legionella as well as the microbiomes of waters from different climate regions. Interestingly, the microbial communities were homogenous across climate regions. When a subset of seven CTs sampled in April and July were compared, there was no association with changes in corresponding CT microbiomes over time in the samples that became culture-positive for Legionella. Legionella species and Lp1 were detected frequently among the samples examined in this first large-scale study of Legionella in US CTs. Our findings highlight that, under the right conditions, there is the potential for CT-related LD outbreaks to occur throughout the US. |
Lessons from an outbreak of Legionnaires' disease on a hematology-oncology unit
Francois Watkins LK , Toews KE , Harris AM , Davidson S , Ayers-Millsap S , Lucas CE , Hubbard BC , Kozak-Muiznieks NA , Khan E , Kutty PK . Infect Control Hosp Epidemiol 2017 38 (3) 306-313 OBJECTIVES To define the scope of an outbreak of Legionnaires' disease (LD), to identify the source, and to stop transmission. DESIGN AND SETTING Epidemiologic investigation of an LD outbreak among patients and a visitor exposed to a newly constructed hematology-oncology unit. METHODS An LD case was defined as radiographically confirmed pneumonia in a person with positive urinary antigen testing and/or respiratory culture for Legionella and exposure to the hematology-oncology unit after February 20, 2014. Cases were classified as definitely or probably healthcare-associated based on whether they were exposed to the unit for all or part of the incubation period (2-10 days). We conducted an environmental assessment and collected water samples for culture. Clinical and environmental isolates were compared by monoclonal antibody (MAb) and sequence-based typing. RESULTS Over a 12-week period, 10 cases were identified, including 6 definite and 4 probable cases. Environmental sampling revealed Legionella pneumophila serogroup 1 (Lp1) in the potable water at 9 of 10 unit sites (90%), including all patient rooms tested. The 3 clinical isolates were identical to environmental isolates from the unit (MAb2-positive, sequence type ST36). No cases occurred with exposure after the implementation of water restrictions followed by point-of-use filters. CONCLUSIONS Contamination of the unit's potable water system with Lp1 strain ST36 was the likely source of this outbreak. Healthcare providers should routinely test patients who develop pneumonia at least 2 days after hospital admission for LD. A single case of LD that is definitely healthcare associated should prompt a full investigation. Infect Control Hosp Epidemiol 2017;38:306-313. |
Legionnaires' outbreaks preventable with water management programs
Lucas CE , Cooley LA , Kunz JM , Garrison LE . ASHRAE J 2016 58 (11) 84-86 The first documented outbreak of Legionnaires' disease was investigated by the Centers for Disease Control and Prevention (CDC) in 1976. Researchers of the time identified a novel bacterial agent responsible for causing the severe pneumonia that sickened or killed several of the American Legionnaires who attended a convention in Pennsylvania. In the ensuing years, scientists characterized the newly discovered bacterium, called Legionella in tribute to the first known victims. Since then we have discovered where the bacteria live, how they cause disease, and the ways they can be transmitted to humans. Most importantly, we learned that most of the disease caused by Legionella is preventable. |
Genomic resolution of outbreak-associated Legionella pneumophila serogroup 1 isolates from New York State.
Raphael BH , Baker DJ , Nazarian E , Lapierre P , Bopp D , Kozak-Muiznieks NA , Morrison SS , Lucas CE , Mercante JW , Musser KA , Winchell JM . Appl Environ Microbiol 2016 82 (12) 3582-90 A total of 30 Legionella pneumophila serogroup 1 isolates representing 10 separate legionellosis laboratory investigations ("outbreaks") that occurred in New York State between 2004 and 2012 were selected for evaluation of whole-genome sequencing (WGS) approaches for molecular subtyping of this organism. Clinical and environmental isolates were available for each outbreak and were initially examined by pulsed-field gel electrophoresis (PFGE). Sequence-based typing alleles were extracted from WGS data yielding complete sequence types (ST) for isolates representing 8 out of the 10 outbreaks evaluated in this study. Isolates from separate outbreaks sharing the same ST also contained the fewest differences in core genome single nucleotide polymorphisms (SNPs) and the greatest proportion of identical allele sequences in a whole-genome multilocus sequence typing (wgMLST) scheme. Both core SNP and wgMLST analyses distinguished isolates from separate outbreaks, including those from two outbreaks sharing indistinguishable PFGE profiles. Isolates from a hospital-associated outbreak spanning multiple years shared indistinguishable PFGE profiles but displayed differences in their genome sequences, suggesting the presence of multiple environmental sources. Finally, the rtx gene demonstrated differences in the repeat region sequence among ST1 isolates from different outbreaks, suggesting that variation in this gene may be useful for targeted molecular subtyping approaches for L. pneumophila This study demonstrates the utility of various genome sequence analysis approaches for L. pneumophila for environmental source attribution studies while furthering the understanding of Legionella ecology. IMPORTANCE: We demonstrate that whole-genome sequencing helps to improve resolution of Legionella pneumophila isolated during laboratory investigations of legionellosis compared to traditional subtyping methods. These data can be important in confirming the environmental sources of legionellosis outbreaks. Moreover, we evaluated various methods to analyze genome sequence data to help resolve outbreak-related isolates. |
Three Genome Sequences of Legionella pneumophila subsp. pascullei Associated with Colonization of a Health Care Facility.
Kozak-Muiznieks NA , Morrison SS , Sammons S , Rowe LA , Sheth M , Frace M , Lucas CE , Loparev VN , Raphael BH , Winchell JM . Genome Announc 2016 4 (3) e00335-16 Here, we report the complete genome sequences of three Legionella pneumophila subsp. pascullei strains (including both serogroup 1 and 5 strains) that were found in the same health care facility in 1982 and 2012. |
The importance of clinical surveillance in detecting Legionnaires' disease outbreaks: a large outbreak in a hospital with a Legionella disinfection system, Pennsylvania, 2011-2012
Demirjian A , Lucas CE , Garrison LE , Kozak-Muiznieks NA , States S , Brown EW , Wortham JM , Beaudoin A , Casey ML , Marriott C , Ludwig AM , Sonel AF , Muder RR , Hicks LA . Clin Infect Dis 2015 60 (11) 1596-602 BACKGROUND: Healthcare-associated Legionnaires' disease (LD) is a preventable pneumonia with a 30% case-fatality rate. The Centers for Disease Control and Prevention guidelines recommend a high index of suspicion for the diagnosis of healthcare-associated LD. We characterized an outbreak and evaluated contributing factors in a hospital using copper-silver ionization for prevention of Legionella growth in water. METHODS: Through medical chart review at a large, urban tertiary care hospital in November 2012, we identified patients diagnosed with LD during 2011-2012. Laboratory-confirmed cases were categorized as definite, probable, and not healthcare-associated based on time spent in the hospital during the incubation period. We performed an environmental assessment of the hospital, including collection of samples for Legionella culture. Clinical and environmental isolates were compared by genotyping. Copper and silver ion concentrations were measured in 11 water samples. RESULTS: We identified five definite and 17 probable healthcare-associated LD cases; six case-patients died. Of 25 locations (mostly potable water) where environmental samples were obtained for Legionella-specific culture, all but two showed Legionella growth; eleven isolates were identical to three clinical isolates by sequence-based typing. Mean copper and silver concentrations were at or above the manufacturer's recommended target for Legionella control. Despite this, all samples where copper and silver concentrations were tested showed Legionella growth. CONCLUSIONS: This outbreak was linked to the hospital's potable water system and highlights the importance of maintaining a high index of suspicion for healthcare-associated LD, even in the setting of a long-term disinfection program. |
Prevalence of sequence types among clinical and environmental isolates of Legionella pneumophila serogroup 1 in the United States from 1982 to 2012.
Kozak-Muiznieks NA , Lucas CE , Brown E , Pondo T , Taylor TH Jr , Frace M , Miskowski D , Winchell JM . J Clin Microbiol 2013 52 (1) 201-11 Since the establishment of sequence-based typing as the gold standard for DNA-based typing of Legionella pneumophila, the Centers for Disease Control and Prevention's (CDC) Legionella laboratory has conducted routine SBT analysis of all incoming L. pneumophila serogroup 1 (Lp1) isolates to identify potential links between cases and to better understand genetic diversity and clonal expansion among L. pneumophila. Retrospective genotyping of Lp1 isolates from sporadic cases and Legionnaires' disease (LD) outbreaks deposited into the CDC reference collection since 1982 has been completed. For this study, we compared the distribution of sequence types (STs) among Lp1 isolates implicated in 26 US outbreaks, 571 clinical isolates from US sporadic cases of LD and 149 environmental isolates with no known association with LD. The Lp1 isolates under study had been deposited into our collection between 1982 and 2012. We identified 17 outbreak-associated, 153 sporadic, and 49 environmental STs. We observed that Lp1 STs from outbreaks and sporadic cases are more similar to each other than either group is to environmental STs. The most frequent ST for both sporadic and environmental isolates was ST1, accounting for 25% and 49% of the total number of isolates, respectively. The STs shared by both outbreak-associated and sporadic Lp1 included ST1, ST35, ST36, ST37, and ST222. The STs most commonly found in sporadic and outbreak-associated Lp1 populations may have an increased ability to cause disease and thus may require special attention when detected. |
Identification of Legionella in the environment
Kozak NA , Lucas CE , Winchell JM . Methods Mol Biol 2013 954 3-25 Legionella is ubiquitous in freshwater systems worldwide and can also be found in soil. Legionellosis may be caused by inhalation of aerosolized water or soil particles containing Legionella. Isolation of Legionella from the environment is an essential step in outbreak investigation and may also be performed within the context of a hazard analysis and control risk management plan. Culture remains the gold standard for detection of Legionella in environmental samples. Specific properties of environmental sites that could be a source of Legionella contamination, collection of samples from such sites, and procedures for culture of these samples for Legionella are described in this chapter. |
Survey of Legionella species found in Thai soil
Travis TC , Brown EW , Peruski LF , Siludjai D , Jorakate P , Salika P , Yang G , Kozak NA , Kodani M , Warner AK , Lucas CE , Thurman KA , Winchell JM , Thamthitiwat S , Fields BS . Int J Microbiol 2012 2012 218791 Members of the Gram-negative genus Legionella are typically found in freshwater environments, with the exception of L. longbeachae, which is present in composts and potting mixes. When contaminated aerosols are inhaled, legionellosis may result, typically as either the more serious pneumonia Legionnaires' disease or the less severe flu-like illness Pontiac fever. It is presumed that all species of the genus Legionella are capable of causing disease in humans. As a followup to a prior clinical study of legionellosis in rural Thailand, indigenous soil samples were collected proximal to cases' homes and workplaces and tested for the presence of legionellae by culture. We obtained 115 isolates from 22/39 soil samples and used sequence-based methods to identify 12 known species of Legionella represented by 87 isolates. |
Accuracy and precision of Legionella isolation by US laboratories in the ELITE program pilot study
Lucas CE , Taylor TH Jr , Fields BS . Water Res 2011 45 (15) 4428-36 A pilot study for the Environmental Legionella Isolation Techniques Evaluation (ELITE) Program, a proficiency testing scheme for US laboratories that culture Legionella from environmental samples, was conducted September 1, 2008 through March 31, 2009. Participants (n=20) processed panels consisting of six sample types: pure and mixed positive, pure and mixed negative, pure and mixed variable. The majority (93%) of all samples (n=286) were correctly characterized, with 88.5% of samples positive for Legionella and 100% of negative samples identified correctly. Variable samples were incorrectly identified as negative in 36.9% of reports. For all samples reported positive (n=128), participants underestimated the cfu/ml by a mean of 1.25 logs with standard deviation of 0.78 logs, standard error of 0.07 logs, and a range of 3.57 logs compared to the CDC re-test value. Centering results around the interlaboratory mean yielded a standard deviation of 0.65 logs, standard error of 0.06 logs, and a range of 3.22 logs. Sampling protocol, treatment regimen, culture procedure, and laboratory experience did not significantly affect the accuracy or precision of reported concentrations. Qualitative and quantitative results from the ELITE pilot study were similar to reports from a corresponding proficiency testing scheme available in the European Union, indicating these results are probably valid for most environmental laboratories worldwide. The large enumeration error observed suggests that the need for remediation of a water system should not be determined solely by the concentration of Legionella observed in a sample since that value is likely to underestimate the true level of contamination. |
Virulence factors encoded by Legionella longbeachae identified on the basis of the genome sequence analysis of clinical isolate D-4968
Kozak NA , Buss M , Lucas CE , Frace M , Govil D , Travis T , Olsen-Rasmussen M , Benson RF , Fields BS . J Bacteriol 2009 192 (4) 1030-44 Legionella longbeachae causes most cases of legionellosis in Australia and may be under-reported worldwide due to the lack of L. longbeachae-specific diagnostic tests. L. longbeachae displays distinctive differences in intracellular trafficking, caspase-1 activation, and infection of mouse models compared to L. pneumophila, yet both species have an indistinguishable clinical presentation in humans. Unlike other legionellae, which inhabit fresh water systems, L. longbeachae is found predominantly in moist soil. In this study, we sequenced and annotated the genome of a L. longbeachae clinical isolate, D-4968, from Oregon, US, and compared it to the published genomes of L. pneumophila. The study revealed that the D-4968 genome is larger with a gene order that is different from L. pneumophila. Genes encoding structural components of type II, type IV Lvh, and type IV Icm/Dot secretion systems are conserved. In contrast, only 42/140 homologs of L. pneumophila Icm/Dot substrates have been found in the D-4968 genome. L. longbeachae encodes numerous proteins with eukaryotic motifs and eukaryotic-like proteins unique to this species, including 16 ankyrin repeat-containing proteins and a novel U-box protein. We predict that these proteins are secreted by the L. longbeachae Icm/Dot secretion system. In contrast to L. pneumophila, the L. longbeachae D-4968 genome does not carry flagellar biosynthesis genes, yet contains a chemotaxis operon. The lack of a flagellum explains the failure of L. longbeachae to activate caspase-1 and trigger pyroptosis in murine macrophages. These unique features of the L. longbeachae genome may reflect adaptation of this species to life in soil. |
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