Invasive serotype 35B pneumococci including an expanding serotype switch lineage, United States, 2015-2016.
After introduction of the 13-valent conjugate vaccine (PCV13) in 2010, 35B became the most common serotype in ABCs, associated with MICs [greater than or equal to] 2 [micro]g/mL for penicillin and amoxicillin in pediatric isolates (6) and in the adult population (B. Beall, unpub. data). Consistent with its status as a major cause of IPD in the post-PCV13 era, the 35B/ST558 lineage is currently commonly found in disease and asymptomatic pneumococcal carriage in many countries (7-11).
We provide a whole-genome sequence (WGS) pipeline-based resolution and description of current 35B lineages within current ABCs surveillance (6,12), including an invasive 35B variant of the historically successful ST156 lineage. Recently, we identified 2 different 35B isolates recovered during 2009 and 2012 that each appeared to have arisen through a unique capsular switch event involving the same 2 parental strains. This observation was made on the basis of the penicillin-binding protein (PBP) gene types flanking the 35B biosynthetic locus (cps35B) in each of the variants (6).
Only the 35B/ST156 variant detected during 2012 has emerged and has been detected within 6 states. ST156 has a remarkable history of conjugate vaccine evasion. Formerly the primary genotype of PCV7 serotype 9V in the United States during the preconjugate vaccine era (13), 9V greatly decreased after PCV7 implementation (1) and was partially replaced by resistant 19A/ST156 (14). To verify that these isolates originated from a single recombinational serotype switch event involving 35B/ST558 and 9V/ST156 parental strains, we analyzed regions flanking the cps35B locus during 2015-2016, 35B/ST156 progeny and the original strain detected during 2012.
The surveillance population of ABCs is [approximately equal to] 32 million persons in 10 states (http://www.cdc.gov/pneumococcal/ surveillance.html). Serotype 35B IPD isolates described include 132 recovered during 2015 and 67 recovered during ABCs in 2016 (Table 1, https://wwwnc.cdc.gov/EID/ article/23/6/17-0071-T1.htm). The listing of 35B isolates from 2016 is incomplete because we typically receive all ABCs isolates recovered during a given year by the following summer. Relevant ST156 lineage isolates f other serotypes recovered during this and previous periods are shown in Table 2. Total numbers of ABCs 35B isolates recovered during 1999-2015 and categorized by patient age, penicillin MIC, and IPD incidence are shown in Table 3.
WGS and WGS-Based Predictions
Library construction and sequencing was performed as described (12). WGS accessions for all 199 serotype 35B isolates from 2015-2016, two previous 35B switch strains from previous years, and relevant strains of other serotypes of ST156 from previous years are provided (online Technical Appendix Table, https://wwwnc.cdc.gov/EID/ article/23/6/17-0071-Techapp1.pdf). WGS pipeline data and quality metrics for all isolates are also provided (online Technical Appendix Table). Capsular serotypes, antimicrobial genotypes/phenotypes, MLST, sequence type (ST), and pili (presence or absence) for year 2015-2016 isolates were deduced through our bioinformatics pipeline (6,12,15).
Paired-end fastq files were trimmed with Cutadapt version 1.8.1 (17), and draft genome assemblies were constructed by using VelvetOptimiser version 2.2.5 with an optimal kmer value calculated by using VelvetK (18). Core genome single-nucleotide polymorphism (SNP) identification and alignment were performed by using kSNP3.0 (19). A maximum-likelihood phylogenetic tree was generated from the core SNP alignment by using RaxML version 7.3.0 (20). RaxML was run with an ASC_GTRGAMMA DNA substitution model and used the Lewis method for ascertainment bias correction. Node support was assessed by using 500 bootstrap replicates.
Conventional MIC Testing and Serotyping
Serotype 35B isolates recovered during 2015 were subjected to conventional broth dilution testing for determination of antimicrobial MICs. A selection of these isolates were also subjected to conventional serotyping by using CDC typing antisera as described (6).
A [chi square] test was performed to evaluate differences among groups. This test was performed by using OpenEpi Version 3.01 (http://www.openepi.com/Menu/OE_Menu.htm).
Increase in Penicillin-Nonsusceptible 35B during the Conjugate Vaccine Era
During 1998-2001, penicillin-nonsusceptible 35B accounted for 67.6% (108) of serotype 35B ABCs isolates (Table 3). During 2002-2015, the proportion of penicillin-nonsusceptible IPD isolates with serotype 35B increased to 87.7% (1,237; p<0.001).
Population Snapshot of Ongoing ABCs for 35B IPD, 2015-2016
Among 2,710 IPD isolates obtained during 2015 and subjected to WGS, 132 (4.9%) were serotype 35B. Of 1,528 IPD isolates recovered from partial year 2016 IPD surveillance, 67 (4.4%) were serotype 35B. Most (168/199) of these isolates belonged to penicillin-nonsusceptible clonal complex (CC) 558 (168 isolates) and CC156 (21 isolates) (Figure 1; Table 1). Serotype 35B CC558 and CC156 isolates of all serotypes discussed were uniformly positive for the rrgA gene (Tables 1, 2), which encodes a pilus subunit that functions in epithelial adhesion (22). Ten isolates of long-standing penicillin-susceptible 35B/ST452 (3) were also recovered. Single 35B isolates were identified of ST1092, a lineage of conjugate vaccine serotypes 6A and 6B (http://pubmlst.org/spneumoniae/) and of ST11818 (highly related to 15A/ST63), an antimicrobial-resistant nonvaccine serotype lineage that has increased in the post-conjugate vaccine era (4).
Of 168 35B/CC558 isolates obtained, 147 were ST558, 20 were single-locus variants (SLVs) of ST558 corresponding to 13 STs, and 1 was a double-locus variant (Figure 1; Table 1). Within CC558, only ST558 had SLVs, which is consistent with initial successful establishment of 35B/ ST558 in its ecologic niche and subsequent rare shedding of closely related SLVs (21).
The increased incidence of 35B IPD during the post-PCV7 period (2.1-3.7 cases/million population during 2001-2009 vs. 1.2-1.3 cases/million population during 1998-1999) and the post-PCV13 period (3.3-4.8 cases/million population during 2011-2015), combined with the consistent trend of markedly increased proportions of penicillin-nonsusceptible 35B IPD isolates throughout the conjugate vaccine era (Table 2), is consistent with reported increased 35B/ST558 in IPD and carriage (4-11). ABCs surveillance sites increased after 2000, but 35B IPD incidence calculations did not vary whether including the expanded surveillance sites or by using only continuously participating ABCs sites during 1998-2015.
We analyzed PBP types (6,12,15) of 35B/ST558 (4:7:7) and 35B/ST156 (4:12:7) isolates. These PBP amino acid sequence types are used for predicting [beta]-lactam MICs and correspond to PBP transpeptidase domains from PBP1a, PBP2b and PBP2x, respectively. PBP genes pbp1a and pbp2x flank opposite ends of the capsular biosynthetic locus and are sometimes co-transferred during serotype switching events (6,23-25). The 35B/ST558 lineage has been nearly exclusively associated with PBP type 4:7:7 among isolates obtained since 1998, and the serotype 9V/ST156 lineage is similarly highly associated with PBP type 15:12:18 (6,15). However, 9V/ST156 is rare among IPD isolates in the post-PCV7 period.
In addition to the PBP2b-12 marker, mef gene, and FolA-I100L substitution, candidate cps35B recipient 9V/ ST156 strains contain the 2-codon insertion designated folPins178 (Table 2; Figures 2, 3). Such 1-2 codonfolP insertions, which together with FolA-I100L confer cotrimoxazole resistance, are categorized by specific location of the insertion and specific sequence flanking the insertions (12). These genomic features are also found within the 35B/ ST156 lineage isolates described (Table 1; Figures 2, 3), which are consistent with a 9V/ST156 (mef, FolA-I100L, folPins178) strain serving as the recipient strain for a 35B/ ST558 cps35B donor strain (Figure 3). Another potential recipient strain present before and after PCV13 introduction was 19A/ST156 (6,14). However, this lineage is associated with thefolPins189 insertion (Table 2; Figure 2).
Both flankingpbp loci from 35B/ST558 were cotransferred with the cps35B locus to replace the cps9V, pbp1a-15 and pbp2x-18 determinants in the putative 9V/ST156 recipient, which resulted in PBP type 4:12:7 (Figure 3). This serotype switch progeny strain was obtained from a 4-year-old child during 2012 and is a potential progenitor of the current invasive 35B/CC156 lineage (isolate 2012221165) (Figures 2, 3). Antimicrobial resistance markers PBP2b-12, mef FolA-I100L, and folPins178, combined with the close phylogenetic relatedness of the 9V/ST156 isolates (Figure 2), suggest that a member of this lineage served as the recipient parental strain for the 35B/ST156 clade isolated in ongoing ABCs during 2015-2016 (Figure 3).
Analysis of the regions flanking the cps35B locus for all 35B/ST156 lineage isolates obtained during 2015-2016 showed identical recombinational sites at bases 6,453 (left coordinate of progeny reference) (Figure 3) and 10,836 (right coordinate), which is clearly indicative of a single event within a 35B/ST156 ancestral strain of the 19 progeny shown (Figure 3). Thus, a double-crossover event replaced the recipient strain cps9V locus and flanking PBP markers (2x-18 and 1a-15) with the cps35B locus and its flanking PBP markers (2x-7 and 1a-4). On the basis of available strain data, the original progeny strain is predicted to have been an ST156 strain with the PBP type 4:12:7; a total of 14 of the 19 35B/ST156 lineage strains still shared these characteristics (Table 1). Five isolates are SLVs or differ in PBP2b type.
We detected the small (491 bp) segment (bases 11349--11839 of progeny) (Figure 3) of clearly recipient lineage origin within the left side of the major recombinational fragment. During a single-double crossover event that facilitates a serotype switch, additional independent doublecrossover events appear to occur concurrently (27). However, these events probably do not occur simultaneously. It appears that the actual serotype switch event involved a shorter donor fragment bordering upon the right side of this small recipient lineage segment (base 11839), followed by a second double-crossover event that bordered upon the left side of the recipient lineage fragment (base 11349).
A single penicillin-susceptible 35B/ST162 (SLV of ST156) has the completely sensitive PBP type 0:0:0 (6,12) (Table 1). This strain arose through an independent serotype switch event that involved a penicillin-susceptible recipient strain.
Postserotype Switch Event Diversification of 35B/ST156 Progeny
Five of the 19 35B/ST156 lineage progeny showed indications of genetic diversification that occurred after the capsular switch event. Four of these isolates have 1 of 3 SLV MLSTs of ST156 (ST9910, ST11584, and ST12921) (Table 1). Although 18 of the 19 strains were PBP type 4:12:7, the SLV ST12921 variant had PBP type 4:11:7. For this particular strain, it is probable that recombination with a highly penicillin-resistant ST320 strain, prevalent during the post-PCV7 era and having PBP type 13:11:16 (6), simultaneously replaced the pbp2b locus and flanking ddl sequence to change the PBP type to 4:11:7 and the MLST type to ST12921 through transfer of ddl with the resistance-conferring selectable pbp2b allele (28). We also observed an increased MIC for amoxicillin for this PBP type 4:11:7 strain compared with MICs for PBP type 4:12:7 strains (Table 1).
Two isolates (20152877 and 20161763) underwent a postswitch intra-cps35 B gene deletion event within the wciG gene (Figure 3), which is predicted to encode an acetyltransferase (26). Although these 2 isolates were serotyped as 35B by using CDC typing antisera, they differed in reactivity with serologic factor 35a compared with the other 17 isolates of this lineage (Table 4). Typing antisera factors 29b and 35c are the CDC Quellung reagents definitive for serotype 35B. The original protocol (29,30) that CDC first followed for serogroup 35 resolution also used factor 35a along with factors 29b and 35c for identification of serotype 35B. We found that the 2 wciG deletion strains did not react with factor 35a, but the other 17 serotype 35B strains reacted strongly with factor 35a. These preliminary data is suggestive of a new serotype within serogroup 35 because this specific factor reactivity pattern has not been observed for serogroup 35 (31).
Further indication of chromosome-wide postswitch diversification of this single clade was shown in the left-flanking region of the cps35B locus. Two progeny strains showed diversification within the first 2-3.7 kb when compared with the other 17 progeny. The 6-kb region immediately to the left of base 1 in all of the progeny strains had [less than or equal to] 99.2% sequence identity with the most similar potential ST156 parental recipient strains that we analyzed. However, beyond this segment, progeny had sequence identity with the parental strain for [greater than or equal to] 8 kb.
35B/ST156 Variant Lineages Arising through Separate Serotype Switch Events
The 9V/ST156 clade also appears likely to have served as the recipient for an independent serotype switch from the same 2 parental strains (Figure 3) which resulted in 35B/ST10174, an SLV of ST156 (Figure 2) obtained from an infant during 2009 (isolate 2009219987). This isolate differs in the flankingp bp2x marker and distal pbp2b marker (PBP type 4:7:18). Features of this variant have been described (6), and we have not obtained additional 35B isolates with these distinguishing features. A third serotype switch event involving a CC156 recipient strain is intuitive from the pipeline data, which indicate that the 35B SLV of ST162 is featured by the [beta]-lactam-susceptible PBP type 0:0:0 (Table 1). ST162 has long been associated with penicillin-susceptible 9V strains (13) and more recently with PI-1 positive and penicillin-susceptible 23B, 15B, and 15C strains (6).
Nonserotype 35B Variants of ST156
Single ST156 isolates of serotypes 31 and 13 were obtained during 2015 (Figure 2) and showed high relatedness to different 9V subdivisions. Again, the likely recipient background for the presumed capsular switch does not appear likely to involve the 19A/ST156 lineage (Figure 2), which was well-represented during the 2000s after PCV7 implementation (6,14,32).
CCs of Remaining 35B Isolates Obtained during 2015-2016
Ten of the 12 isolates other than penicillin-nonsusceptible CC558 and CC156 (together composed of 187 isolates) were of the long-established penicillin-susceptible 35B/ ST452 lineage (3), which decreased in proportion during the 2000s (4) (Figure 1; Table 3). The 2 remaining 35B isolates obtained during 2015-2016 also appear to have originated through serotype switching events involving a 35B/ST558 cps35B donor, as implicated by the presence of the PBP1a-4 or PBP2x-7 determinants flanking the cps loci of these 2 progeny strains (35B/ST11818 and 35B/ ST1092) (Table 1). The 35B/ST11818 variant is an SLV of ST63 and has the same resistance features and accessory resistance genes (ermB and tetM) as the currently common 15A/ST63 clone (4,6,32). The 35B/ST1092 isolate is likely to have originated through serotype switching with a serogroup 6 recipient strain (6). The 14 remaining ST1092 isolates obtained during surveillance in 2015-2016 were serotype 6C. The 6 previously collected ST1092 IPD isolates (1999-2013) represented in our WGS collection are from serotype 6A, 6B, and 6C strains (6; B. Beall, unpub. data).
An increase of penicillin-nonsusceptible serotype 35B IPD and carriage caused by 35B/ST558 has been apparent in the United States since the introduction of PCV7 in 2000, and it has shown a major increase after PCV13 implementation (4-8). This finding is of concern because even strains that are rarely detected in IPD sometimes rapidly emerge. For example, the 19A/ST320 strain was not detected during extensive characterization of pre-PCV7 ABCs isolates (13), yet it became the predominant invasive pneumococcal strain during 2005-2009 (14,32). We have performed comprehensive strain characterization (MLST and WGS) of pediatric (from children <5 years of age) ABCs isolates obtained during 1999, 2001, 2002, 2008, 2009, and 2011-2013 (6,13) and WGS-based characterization of a large sampling of isolates from all age groups during 1998-2013 (4,6,13; B. Beall, unpub. data).
Before 2015, we detected only 1 isolate of the 35B/ ST156 lineage that was recovered during 2012 (6). Thus, we feel justified in describing it as newly emergent isolate. A smaller study was recently published (during peer review of this article) that described 78 invasive and 48 noninvasive serotype 35B isolates obtained during 1994-2014 from 8 hospitals in 8 states (33). Our data, which included a population-based sampling of 199 35B isolates obtained during 2015-2016, clearly shows the current national predominance of 35B/ST558 and does not support the observation that 35B/ST156 is the major contributor to post-PCV13 antimicrobial-resistant 35B. Both studies noted the initial appearance and emergence of 35B/ST156 in the post-PCV13 period.
This recent identification of the antimicrobial-resistant
35B/ST156 lineage and its subsequent detection within 6 ABCs sites is a cause for concern. The ST156 lineage has shown a remarkable propensity to persist through undergoing serotype-switch events (12,23,25,32). The penicillin-resistant 9V/ST156 lineage was the predominant serotype 9V cause of IPD in the United States during the pre-PCV7 era (13,32). Soon after introduction of PCV7, serotype 9V IPD became rare (1,2), and 19A became the predominant representative of the ST156 lineage within ABCs (14,32). After introduction of PCV13, 35B has become the predominant serotype of the ST156 lineage within the United States (B. Beall, unpub. data).
A distinct antimicrobial-susceptible serotype 35B SLV of ST156 (35B/ST162) is included among 35B ABCs of 35B during 2015-2016 by the [beta]-lactam-susceptible PBP type 0:0:0. Thus, our data indicates that [greater than or equal to] 3 independent serotype switches involving the nonvaccine type cps35B locus and the broad ST156 clonal complex serving as recipient strains have previously occurred. In this study, we demonstrated that all penicillin-nonsusceptible 35B/ST156 lineage isolates obtained during current ABCs (2015-2016) arose through a single ancestral recombination event. This event was facilitated through detailed analyses of crossover points and comparisons of corresponding regions of all progeny isolates with likely parental 35B/ST558 and 9V/ ST156 strains. The genetic plasticity of the ST156 lineage is also highlighted in this study by detection of postserotype switch changes affecting [beta]-lactam resistance (PBP1a type) and capsular serotype (wciZ deletion), which is potentially reflective of recent antimicrobial drug pressure and immunologic selection pressure.
An additional 35B variant within a vaccine serotype lineage is shown with ST1092 that is typically associated with serogroup 6 strains (Figure 1). Because these putative 35B switch variants were not detected during extensive strain surveillance before and shortly after conjugate vaccine implementation (3,4,13), it is plausible that these serotype switches occurred after implementation of conjugate vaccine. The observation of a 35B variant within the antimicrobial 15A/ST63 lineage brings the number of serotype switch events generating 35B strains described in this study to 5; (35B/ST11818, 35B/ST156, 35B/ST162 from 2015-2016, and 35B/ST10174 from 2009). Except for the 35B/ST162 variant, these serotype switch events were predicted on the basis of progeny PBP type to involve the 35B/ ST558 strain as the cps35B donor (online Technical Appendix Table).
Although conjugate vaccines have a history of providing effective and durable protection against IPD (1,2), the continued emergence and expansion of serotype 35B into different clonal complexes supports continued development of wider spectrum pneumococcal vaccines. Serotype 19A IPD, although relatively uncommon in the pre-PCV7 era, rapidly became the predominant invasive serotype in the post-PCV7 period (14,32,34). Serotype 35B strains have several of the same features that were found among serotype 19A strains before implementation of PCV7 in 2000. These features that could predispose for serotype 35B to continue its increasing trend as a cause of IPD include its lack of inclusion within conjugate vaccine, high carriage rates within children, antimicrobial resistance, clonal expansion, and serotype switching. An experimental 15-valent conjugate vaccine in development includes serotypes 22F and 33F (35), which have increased as causes of IPD in the postconjugate vaccine era. Serotypes 15A, 15B, and 23A are expressed by moderately antimicrobial-resistant clones and are not uncommon causes of IPD (4,32). Although less resistant to [beta]-lactam antimicrobial drugs than 35B/ST558 and 35B/ST156, these strains also present a challenge to address through more encompassing pneumococcal vaccines.
We thank A. Reingold, S. Brooks, H. Randel, L. Miller, B. White, D. Aragon, M. Barnes, J. Sadlowski, S. Petit, M. Cartter, C. Marquez, M. Wilson, M. Farley, S. Thomas, A. Tunali, W. Baughman, L. Harrison, J. Benton, T. Carter, R. Hollick, K. Holmes, A. Riner, Ruth Lynfield, Anita Glennen, C. Holtzman, R. Danila, K. MacInnes, K. Scherzinger, K. Angeles, J. Bareta, L. Butler, S. Khanlian, R. Mansmann, M. Nichols, N. Bennett, S. Zansky, S. Currenti, S. McGuire, A. Thomas, M. Schmidt, J. Thompson, T. Poissant, W. Schaffner, B. Barnes, K. Leib, K. Dyer, L. McKnight, R. Gierke, O. Almendares, J. Hudson, L. McGlone, Tamara Pilishvili, G. Langley, and Cynthia Whitney for their contributions to establishment and maintenance of the ABCs system; Rebecca Gladstone, Stephen Bentley, and Paulina Hawkins for providing genome sequences through the Global Pneumococcal Sequencing Project (http://www.pneumogen.net) from isolates obtained during 1998-1999, 2009, and 2012; the Minnesota Department of Public Health laboratory for performing susceptibility testing of all isolates from Minnesota; and Robert E. Gertz, Jr for providing insights into CDC pneumococcal typing serum factors.
This study was supported by the Centers for Disease Control and Prevention and used data from the Streptococcus pneumoniae MLST website (http://pubmlst.org/_spneumoniae) at the University of Oxford (Oxford, UK).
Development of the Streptococcus pneumoniae MLST website was supported by the Wellcome Trust.
Dr. Chochua is a researcher in the Streptococcus Laboratory, National Center for Immunization and Respiratory Diseases, Centers for Disease Control and Prevention, Atlanta, GA.
Her research interests are next-generation sequencing, characterization of clinical streptococcal isolates, antimicrobial resistance, genetic adaptations, and outbreak responses.
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Sopio Chochua, Benjamin J. Metcalf, Zhongya Li, Hollis Walker, Theresa Tran, Lesley McGee, Bernard Beall
Author affiliation: Centers for Disease Control and Prevention, Atlanta, Georgia, USA
Address for correspondence: Bernard Beall, Centers for Disease Control and Prevention, 1600 Clifton Rd NE, Mailstop C02, Atlanta, GA 30329-4017, USA: email email@example.com
Caption: Figure 1. Population snapshot of 199 serotype 35B pneumococcal isolates obtained by ongoing Active Bacterial Core surveillance, United States, 2015-2016, configured by using eBURST (21). Diameters are proportional to number of isolates. Solid lines indicate single-locus variants, and the single dashed line indicates a double-locus variant of ST558. ST, sequence type.
Caption: Figure 2. Phylogenetic analysis of potential recipient and serotype switch pneumococcal progeny strains within the ST56 lineage based upon a total alignment of 10,409 core single-nucleotide polymorphisms, United States, 2015-2016. All 20 serotype 35B progeny shown were recovered through Active Bacterial Core surveillance, and all but 2 indicated strains were obtained during 2015-2016. Isolate features are depicted for the 2 major nodes, with exceptions indicated by asterisks within the tree. Bootstrap values are indicated at key nodes. The serotype 9V isolate that was used for the reference recipient sequences described in Figure 3 is indicated as the third isolate from bottom. All isolates above the 9V recipient reference within this major cluster, except where indicated, are also 9V/ST156. Three additional serotype switch ST156 strain types detected by Active Bacterial Core surveillance during 2015-2016 are indicated by asterisks (single isolates of serotypes 31 and 13 and 4 serotype 19A isolates). Scale bar indicates nucleotide substitutions per site.
Caption: Figure 3. Diagrammatic representation of cps loci and adjacent regions from donor, recipient and progeny strains depicting serotype switch event for pneumococcal isolates, United States, 2015-2016. Red and green lines in progeny indicate regions of sequence identity or near identity (<2 single-nucleotide polymorphisms/10,000 bp) to the above corresponding donor and recipient sequences, respectively. Rectangles indicate relative locations of PBP gene types for pbp2x and pbpla. Below each cps locus, a representative reference strain is indicated along with relevant features determined through a bioinformatics pipeline (MLST, PBP type, resistance markers). Junctions between donor and recipient sequences involved in the 2 single recombinational crossovers in the gene replacement event are indicated with blue arrowheads above the progeny diagram, although a single short internal region with sequence identity to the recipient nested within the donor fragment (left coordinates 11349-11839) is also present. Below each green or red segment of the progeny, the level of sequence identity to donor and recipient is provided. The list of each progeny strain, date of isolation, and state is provided. Where MLST is not ST156, its single locus variants (ST9910, ST11584, and ST12921) are included. Two exceptions indicating flanking post-switch recombination within left coordinates 1-6453 are indicated in isolates 20152884 and 20161413 (asterisks): isolate 20152884 had only 99.3%-99.5% identity to recipient and donor over bases 1-3715, and isolate 20161413 had only 99.5%-99.7% identity to recipient and donor over bases 1-2143. Two strains on the right indicate a post-switch deletion event within the wciG putative acetyltransferase gene, which putatively contributes to the acetylation pattern of the serotype 35B polysaccharide (26). MLST, multilocus sequence type; PBP, penicillin-binding protein; ST, sequence type.
Table 2. Nonserotype 35B isolates of ST156 lineage included in study of penicillin-nonsusceptible 35B pneumococcal isolates causing IPD, United States, 1998-2015 * Serotype/ PBP type Non-PBP resistance MLST type ([double determinants (no.) ([dagger]) No. dagger]) ([section]) 9V/156 (25) 12 15:12:18 folAI100L, folPins178 9 15:12:18 mef, folAI100, folPins178 2 15:12:18 ermB, tetM, folAI100L, folAins178 1 15:12:18 mef, tetM, folA I100L, folPins178 1 15:12:228 Mef, folA I100L, folPins178 19A/156 (4) 3 29:12:26 mef, folA I100L, folAins189 1 8:12:36 mef, folA I100L, folAins189 13/156 (1) 1 15:12:173 folAI100L, folPins178 31/156 (1) 1 15:12:18 mef, folA I100L, folPins178 Serotype/ Antimicrobial resistance phenotype, MIC, MLST type [micro]g/mL [paragraph] (no.) ([dagger]) No. Pen Amo Tax Cft Cfx Mer 9V/156 (25) 12 4 2 1 2 >2 0.5 9 4 2 1 2 >2 0.5 2 4 2 1 2 >2 0.5 1 4 2 1 2 >2 0.5 1 4 2 1 2 >2 0.5 19A/156 (4) 3 4 2 8 4 >2 0.5 1 1 2 0.5 0.5 2 0.25 13/156 (1) 1 1 1 0.25 0.25 1 0.5 31/156 (1) 1 4 2 1 2 >2 0.5 Serotype/ Antimicrobial resistance MLST type phenotype, MIC, State (year (no.) ([dagger]) No. [micro]g/mL [paragraph] isolated) Ery Cli + Cot Fq Tet 9V/156 (25) 12 S S R S CA, GA, MD, MN, NY, TN (1998-1999) 9 R S R S CA, CT, MD, MN, OR, TN (1998,1999, 2015) 2 R R R S CA (2015) 1 R S R S CT (2015) 1 R S R S MD (2016) 19A/156 (4) 3 R S R S CA,GA (2009) 1 R S R S GA (2015) 13/156 (1) 1 S S R S TN (2015) 31/156 (1) 1 R S R S MN (2015) * All isolates were positive for pilus PI-type 1 and negative for pilus PI-type 2. IPD, invasive pneumococcal disease; MLST, multilocus sequence type; PBP, penicillin-binding protein; R, resistant; S, susceptible; ST, sequence type. ([dagger]) Types that probably arose through serotype switching are indicated in bold. ([double dagger]) See Li et al.(15) and MIC correlates for PBP types (http://www.cdc.gov/streplab/mic-tables.html). ([section]) For a description of WGS-based bioinformatic pipeline for deduction of all features shown, see Metcalf et al.(6,12).For a description of folP insertions (folPins178, folP189), see Figure 1 in Metcalf et al.(12). ([paragraph]) Predicted MICs for [beta]-lactam antimicrobial drugs were based on transpeptidase domain sequences of PBPs 1a, 2b, and 2x (http://www.cdc.gov/streplab/mic-tables.html).For penicillin (meningitis only), nonsusceptible is considered [greater than or equal to] 0.12 [micro]g/mL (16).Currently applied clinical cutoffs are also provided for the other 5 [beta]-lactams shown (16).Where shown, R and S correspond to breakpoint MIC values (16).Amo, amoxicillin; Cft, ceftriaxone; Cfx, cefuroxime; Cli, clindamycin; Cot, cotrimoxazole; Ery, erythromycin; Fq, fluoroquinolones levofloxacin and ciprofloxacin; Mer, meropenem; Pen, penicillin; Tax, cefotaxime. Table 3. Annual incidence and proportions of penicillin-nonsusceptible 35B pneumococcal isolates causing IPD, United States, 1999-2015 * Year Surveillance % CIS No. 35B isolates from Relative population patients by age, y incidence of 35B IPD <5 [greater than or ([dagger]) equal to] 5 1998 17,383,935 86.1 3 18 1.40 1999 18,550,681 87.0 2 18 1.24 2000 19,821,607 86.3 4 21 1.46 2001 22,479,308 88.1 2 40 2.12 2002 25,051,246 87.6 2 34 1.64 2003 25,264,246 91.4 11 49 2.56 2004 27,419,898 87.9 15 69 3.49 2005 27,816,784 89.5 11 57 2.73 2006 28,204,455 86.7 1 65 2.70 2007 28,579,312 87.5 5 83 3.52 2008 28,856,774 86.7 12 80 3.68 2009 29,206,528 89.8 8 70 2.97 2010 29,757,552 90.2 4 67 2.65 2011 30,075,050 90.3 11 77 3.28 2012 30,356,544 90.6 13 101 4.14 2013 30,604,240 88.7 15 114 4.75 2014 31,328,211 88.2 16 116 4.78 2015 31,977,800 92.0 10 121 4.45 Year Pen MIC, ug/mL penNS 35B isolates/penS [greater than 0.12-1 [less than or 35B or equal to] 2 equal to] 0.06 isolates 1998 9 5 7 2.0 1999 8 3 9 1.2 2000 7 9 9 1.8 2001 14 18 10 3.2 2002 20 8 8 3.5 2003 22 26 11 4.4 2004 44 25 15 4.6 2005 35 18 15 3.5 2006 37 15 14 3.7 2007 51 23 14 5.3 2008 62 16 14 5.6 2009 45 16 17 3.6 2010 52 14 5 13.2 2011 71 7 10 7.8 2012 94 14 6 18.0 2013 94 25 10 11.9 2014 104 22 6 21.0 2015 101 24 6 20.8 * CIS, case isolates serotyped; IPD, invasive pneumococcal disease. ([dagger]) Estimated cases/million = total 35Bs x 100/% CIS surveillance population/1,000,000. Table 4. Serologic comparison of 35B/ST156 lineage strains with CDC Quellung reagents for resolution of serogroup 35B invasive serotype pneumococci including an expanding serotype switch lineage, United States, 2015-2016 * Quellung factor Strain 35b 29b 35c 42a 35a cps35B ([dagger]) - + + - + cps35B (wciG deletion) - + + - - ([double dagger]) * CDC, Centers for Disease Control and Prevention; ST, sequence type; -, negative; +, positive. ([dagger]) Refers to 17 progeny resulting from recombination indicated in left column under progeny lineage diagram in Figure 3. ([double dagger]) Refers to 2 indicated wciG deletion isolates in right column under progeny lineage diagram in Figure 3.
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|Author:||Chochua, Sopio; Metcalf, Benjamin J.; Li, Zhongya; Walker, Hollis; Tran, Theresa; McGee, Lesley; Bea|
|Publication:||Emerging Infectious Diseases|
|Date:||Jun 1, 2017|
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