Distribution of serogroups of Neisseria meningitidis and antigenic characterization of serogroup Y meningococci in Canada,January 1, 1999 to June 30, 2001

The relative frequency of serogroups of Neisseria meningitidis associated with meningococcal disease in Canada during the period January 1, 1999 to June 30, 2001 was examined. Of the 552 strains of N meningitidis collected from clinical specimens of normally sterile sites, 191 (34.6%), 276 (50.0%), 61 (11.1%) and 23 (4.2%) were identified by serological and molecular methods as serogroups B, C, Y and W135, respectively. About half (50.8%) of the serogroup Y isolates were isolated in the province of Ontario. The two most common serotypes found were 2c and 14. Most of the serogroup Y strains isolated from patients in Ontario were serotype 2c, while serotype 14 was the most common serotype associated with disease in the province of Quebec. The two most common serosubtypes found among the serogroup Y meningococci were P1.5 and P1.2,5. Laboratory findings, based on antigenic analysis, did not suggest that these serogroup Y strains arise by capsule switching from serogroups B and C strains. This study documented a higher incidence of finding serogroup Y meningococci in clinical specimens from patients in Ontario compared to the rest of Canada, and parallels the increase in serogroup Y meningococcal disease reported in some parts of the United States.Key Words: Meningococcal disease, Neisseria meningitidis, SerogroupsInvasive meningococcal disease (IMD) is a notifiable communicable disease that is monitored by a national surveillance program coordinated by the Division of Disease Surveillance and the Division of Respiratory Diseases, Centre for Infectious Disease Prevention and Control, Health Canada. Starting in 1971 and with the help of provincial public health officials, Health Canada began to collect data on the serogroup information on IMD cases. Also, isolates of meningococci collected from patients are routinely sent to Health Canada''s National Microbiology Laboratory (NML) in Winnipeg for further antigenic and genetic analyses.IMD is a serious disease globally but the serogroups of meningococci causing diseases in various countries may vary in frequency. For example, serogroup A is a major cause of disease in Africa and China (1), while serogroups B and C meningococci are the most frequent cause of IMD in Western countries (2). In Canada, most IMD cases are caused by meningococci belonging to serogroups B, C, Y and W135. Serogroups B and C account for over 75% of the isolates collected from patients (3).In the past decade, Neisseria meningitidis serogroup Y has emerged as a frequent cause of IMD in the United States (4,5). In view of these findings, it is important to monitor the incidence of serogroup Y disease. This report presents the frequency of isolation of serogroups of meningococci in normally sterile clinical specimens collected from patients (likely to be presented as IMD) in various parts of Canada and describes the distribution of serotypes and serosubtypes found among the serogroup Y isolates.     

Potential capsule switching from serogroup Y to B: The characterization of three such Neisseria meningitidis isolates causing invasive meningococcal disease in Canada

Three group B Neisseria meningitidis isolates, recovered from meningococcal disease cases in Canada and typed as B:2c:P1.5, were characterized. Multilocus sequence typing showed that all three isolates were related because of an identical sequence type (ST) 573. Isolates typed as 2c:P1.5 are common in serogroup Y meningococci but rare in isolates from serogroups B or C. Although no serogroup Y isolates have been typed as ST-573, eight isolates showed five to six housekeeping gene alleles that were identical to that of ST-573. This suggested that the B:2c:P1.5 isolates may have originated from serogroup Y organisms, possibly by capsule switching.Key Words: Capsule switching, Neisseria meningitidis, Serogroup YNeisseria meningitidis is a significant pathogen that causes invasive meningococcal disease (IMD). The average case fatality rate of 9% to 12% remains high despite the availability of effective antibiotics and vaccines (1). Laboratory study and surveillance of N meningitidis involves the characterization of a number of surface markers of the bacterium, including its capsule and outer membrane proteins (OMPs). Most epidemiological studies of meningococcal disease rely on differentiating meningococcal isolates based on their serogroup, serotype and serosubtype. Serogrouping is determined by the demonstration of serologically distinct epitopes present on chemically and structurally different capsules. Serotyping and serosubtyping rely on the detection of distinct epitopes present on three of five different classes of OMPs of N meningitidis. Serotyping epitopes are found on the class 2 or class 3 OMP (also called PorB) of N meningitidis; these OMPs are expressed in a mutually exclusively manner (ie, a strain will only express either a class 2 or class 3 OMP but not both). Serosubtyping epitopes are present on the class 1 OMP (also called PorA). Based on this nomenclature scheme, a strain can therefore be characterized by its antigenic formula; for example, B:15:P1.7,16 refers to serogroup B, serotype 15 and serosubtype P1.7,16.One of the most important virulence factors of meningococci is the capsular polysaccharide antigen, which is also the basis for serogrouping and is the target antigen for the currently licensed vaccines against A, C, Y and W135 organisms. Of the 13 known serogroups, five (serogroups A, B, C, Y and W135) are responsible for most of the meningococcal disease worldwide (2). In North America, most endemic and epidemic strains belong to serogroups B, C, Y and W135 (3,4). Capsules of serogroups B, C, Y and W135 meningococci contain sialic acid, either as a homopolymer of sialic acids assembled by alpha-2,8 linkages (serogroup B) or alpha-2,9 linkages (serogroup C), or as a heteropolymer of sialic acids with glucose (serogroup Y) or galactose (serogroup W135). Besides demonstrating structural similarities, these four serogroups of meningococci also have very similar capsule polysaccharide synthesis (cps) gene loci (5). Because of this similarity, capsule switching has been demonstrated in vivo and in vitro by specific gene replacement within the cps loci between different serogroups. To date, a number of IMD cases have been described in the literature to be caused by organisms in which capsule switching between serogroup B and C meningococci occurred (6-8).In the present paper, the authors describe three unusual serogroup B meningococci isolated from separate IMD cases in Nanaimo, British Columbia, that presented with the OMP antigens 2c:P1.5, characteristic of serogroup Y strains found in Canada (4). This antigenic profile prompted the authors to examine the relationship of these three serogroup B strains with antigenically similar serogroup Y organisms isolated in Canada. The authors describe the characterization of these antigenically similar isolates and postulate that the B:2c:P1.5 isolates arose by capsule switching from serogroup Y organisms.     

Immunoepidemiology of meningococcal disease in military recruits. I. A model for serogroup independency of epidemic potential as determined by serotyping.

One hundred twenty strains of Neisseria meningitidis were serotyped with use of cross-absorbed rabbit antisera in a bactericidal test. Fifty-eight epidemic strains of serogroup B, C, and Y that occurred simultaneously among military recruits at two basic training centers during a period of epidemic meningococcal disease were compared with 62 strains of serogroups A, B, C, and Y isolated worldwide. Antisera to the six original antigenic factors of the Gold serotyping schema were adequate for typing 94% of strains, including all of the epidemic strains. The array of serotyping factors in the epidemic strains differed from those in the nonepidemic strains. Epidemic strains were almost exclusively of two serotypes, with type CII predominant among strains of groups B and C. Concurrent strains of groups B and C were invariably of the same serotype. A model for the epidemic potential of meningococcal strains, which is based on their serotype and serogroup antigens, and a modification of the original Gold typing schema are presented.     

Endotoxin release from invasive meningococci related to sulfonamide resistance, serogroup and serotype

The relationship between endotoxin liberation, sulfonamide resistance, serogroups and serotypes was studied in 28 Neisseria meningitidis strains isolated from patients with meningococcal disease. Sulfonamide resistance was present in 15/28 strains. 22 strains belonged to serogroup B, and 5 to group C; 1 strain was non-groupable. Free endotoxin activity in growing cultures of meningococci with endotoxin titre of greater than or equal to 10(2) was found in 27/28 strains. A high endotoxin activity was present in both sulfonamide-sensitive and -resistant invasive meningococci. A high endotoxin release with titre greater than or equal to 10(3) seemed to be more associated with serogroup C than B, and more to the serotypes 2 and 15/16 than to the non-typable strains.     

Genetic basis for nongroupable Neisseria meningitidis

Nongroupable Neisseria meningitidis may constitute one-third or more of meningococcal isolates recovered from the nasopharynx of human carriers. The genetic basis for nongroupability was determined in isolates obtained from a population-based study in which 60 (30.9%) of 194 meningococcal isolates from asymptomatic carriers were not groupable. Forty-two percent of nongroupable isolates were related to serogroup Y ET-508/ST-23 clonal complex strains, the most common groupable carrier isolate from the study population. Nongroupable isolates were all rapidly killed by 10% normal human serum. The capsule loci of 6 of the ET-508/ST-23 complex strains and of 25 other genetically diverse nongroupable meningococci were studied in detail. Serogroup A or novel capsule biosynthesis genes were not found. Nongroupable isolates were genetically serogroup Y, B, or C isolates that did not express capsule but were related to groupable isolates found in the population (class I); capsule deficient because of insertion element-associated deletions of capsule biosynthesis genes (class II); or isolates that lacked all capsule genes and formed a distinct genetic cluster not associated with meningococcal disease (class III).     

Another Swedish family with complete properdin deficiency: association with fulminant meningococcal disease in one male family member

Inherited deficiency of the complement component properdin is described in a Swedish family without any previous history of meningococcal infections. The properdin-deficient index patient died from a fulminant infection caused by Neisseria meningitidis serogroup Y. Family investigation revealed properdin deficiency in the patient's half-brother and in the maternal grandfather. The half-brother had a history of pneumococcal pneumonia and meningitis probably caused by Borrelia burgdorferi. Opsonic and bactericidal functions of serum were examined in the half-brother after immunization with tetravalent meningococcal vaccine. Vaccination promoted opsonization of N. meningitidis serogroups C and Y but not of serogroups A and W-135. The serum bactericidal activity increased against serogroup C and to some extent against serogroup W-135. This report emphasizes the importance of investigating the complement system even in families with single cases of fulminant meningococcal disease. Individuals with properdin deficiency might be protected from infection by immunization.     

Epidemiology of invasive meningococcal disease in 13 government hospitals in Thailand, 1994-1999.

This study was conducted to elucidate the magnitude of problem and the clinical course of invasive meningococcal infection from 13 government hospitals in Thailand between 1994 and 1999. Thirty-six strains of Neisseria meningitidis were isolated from 16 blood and 24 cerebrospinal fluid specimens; 4 patients had positive culture in both blood and CSF. Of the 16 strains, 9 (56.3%) were serogroup B. Seventy-one and eighty-four percent of the isolates were susceptible to penicillin and cefotaxime/ceftriaxone respectively. Five out of six penicillin-nonsusceptible strains were found to be relatively resistant to penicillin with the MIC of 0.125 microg/ml. Of 33 patients whose medical records were available, 21 were males and 12 were females, with a mean age of 11.2 years. Fifteen patients (45.5%) presented with meningococcemia and 18 patients (54.5%) presented with meningococcal meningitis. Hypotension and purpura were found in 24.2% and 33.3% of patients respectively. The overall mortality rate was 9.1%. In conclusion, meningococcal disease is not common in Thailand, meningococcemia is a life-threatening condition whereas meningococcal meningitis is much less severe. The prevalence of meningococci relatively resistant to penicillin seems to be increasing.     

Epidemiology of serogroup B invasive meningococcal disease in Ontario, Canada, 2000 to 2010

ABSTRACT: BACKGROUND: Invasive meningococcal disease (IMD) caused by serogroup B is the last major serogroup in Canada to become vaccine-preventable. The anticipated availability of vaccines targeting this serogroup prompted an assessment of the epidemiology of serogroup B disease in Ontario, Canada. METHODS: We retrieved information on confirmed IMD cases reported to Ontario's reportable disease database between January 1, 2000 and December 31, 2010 and probabilistically-linked these cases to Public Health Ontario Laboratory records. Rates were calculated with denominator data obtained from Statistics Canada. We calculated a crude number needed to vaccinate (NNV) using the inverse of the infant (<1 year) age-specific incidence multiplied by expected vaccine efficacies between 70 % and 80 %, and assuming only direct protection (no herd effects). RESULTS: A total of 259 serogroup B IMD cases were identified in Ontario over the 11-year period. Serogroup B was the most common cause of IMD. Incidence ranged from 0.11 to 0.27/100,000/year, and fluctuated over time. Cases ranged in age from 13 days to 101 years; 21.4 % occurred in infants, of which 72.7 % were <6 months. Infants had the highest incidence (3.70/100,000). Case-fatality ratio was 10.7 % overall. If we assume that all infant cases would be preventable by vaccination, we would need to vaccinate between 33,784 and 38,610 infants to prevent one case of disease. CONCLUSIONS: Although rare, the proportion of IMD caused by serogroup B has increased and currently causes most IMD in Ontario, with infants having the highest risk of disease. Although serogroup B meningococcal vaccines are highly anticipated, our findings suggest that decisions regarding publicly funding serogroup B meningococcal vaccines will be difficult and may not be based on disease burden alone.     

Genetic analysis of meningococci carried by children and young adults

BACKGROUND: Neisseria meningitidis is a diverse commensal bacterium that occasionally causes severe invasive disease. The relationship between meningococcal genotype and capsular polysaccharide, the principal virulence factor and vaccine component, was investigated in carried meningococci isolated from 8000 children and young adults in Bavaria, Germany. METHODS: Of the 830 meningococci isolated (carriage rate, 10.4%) by microbiological techniques, 822 were characterized by serogrouping, multilocus sequence typing, and genetic analysis of the capsule region. Statistical and population genetic analyses were applied to these data. RESULTS: The rapid increase in carriage rates with age of carrier, the low prevalence of hyperinvasive meningococci, and the relative prevalence of the 4 disease-associated serogroups were consistent with earlier observations. There was no genetic structuring of the meningococcal population by age of carrier or sampling location; however, there was significant geographic structuring of the meningococci isolated in civil, but not military, institutions. The rate of capsule gene expression did not vary with age of carrier or meningococcal genotype, except for serogroup C, for which increased expression was associated with ST-11 (formerly ET-37) complex meningococci. CONCLUSIONS: Serogroup C capsule expression during carriage may contribute to the invasive character of ST-11 complex meningococci and to the high efficacy of meningococcal serogroup C conjugate polysaccharide vaccine.     

Meningococcal disease

Due to a high complication and case fatality rate, meningococcal diseases are important health problems both in tropical countries experiencing severe epidemics as well as in countries of moderate climate zones. Worldwide N. meningitidis of sero-groups A, B, and C are predominant and to a lesser extent serogroups W (135) and Y play a role, whereas in Europe more than 90 % of meningococcal diseases are caused by serogroups B and C of N. meningitidis. In Germany and other developed countries the majority of cases occur in very young children and adolescents. Since many years, meningococcal polysaccharide vaccines against diseases due to N.meningitidis serogroup A, C, Y and W (135) are commercially available. Unfortunately, a vaccine against diseases caused by N. meningitidis serogroup B is still under development. The recently developed and licensed conjugated meningococcal vaccines against N. meningitidis serogroup C are also protective against disease in very young children. Eight countries in Western Europe as well as Australia have already established country-wide immunization programs for children and adolescents. Within only 2 to 3 years, well managed programs have achieved far-reaching control of meningococcal C disease in UK and the Netherlands. In Germany, the Advisory Committee on Immunization (STIKO recommends immunization for selected risk groups. The current increase of the percentage of meningococcal C diseases to 28 - 30 % gives reason for further discussion regarding immunization strategies. How-ever, the STIKO expressively declares, that in addition to the recommendation for risk groups, the physician can use all vaccines licensed in Germany without any restriction. It is his/her responsibility to advice the patients regarding immunization possibilities against the life-threatening meningococcal disease, particularly if cases are occurring.     

Molecular epidemiology and emergence of worldwide epidemic clones of Neisseria meningitidis in Taiwan

Background  

Meningococcal disease is infrequently found in Taiwan, a country with 23 million people. Between 1996 and 2002, 17 to 81 clinical cases of the disease were reported annually. Reported cases dramatically increased in 2001–2002. Our record shows that only serogroup B and W135 meningococci have been isolated from patients with meningococcal disease until 2000. However, serogroup A, C and Y meningococci were detected for the first time in 2001 and continued to cause disease through 2002. Most of serogroup Y meningococcus infections localized in Central Taiwan in 2001, indicating that a small-scale outbreak of meningococcal disease had occurred. The occurrence of a meningococcal disease outbreak and the emergence of new meningococcal strains are of public health concern.     

Neisseria meningitidis serogroups A and W-135: carriage and immunity in Burkina Faso, 2003

OBJECTIVES: We sought to describe Neisseria meningitidis immunity and its association with pharyngeal carriage in Burkina Faso, where N. meningitidis serogroup W-135 and serogroup A disease are hyperendemic and most of the population received polysaccharide A/C vaccine during 2002. METHODS: We collected oropharyngeal swab samples from healthy residents of Bobo-Dioulasso (4-14 years old, n=238; 15-29 years old, n=250) monthly during February-June 2003; N. meningitidis isolates were analyzed using polymerase chain reaction and serogrouped using immune sera. Serum samples were collected at the first and last clinic visit and analyzed for anti-A, anti-C, anti-W-135, and anti-Y immunoglobulin G (IgG) concentrations and anti-A and anti-W-135 bactericidal titers. RESULTS: N. meningitidis was carried at least once by 18% of participants; this carriage included strains from serogroups W-135 (5%) and Y and X (both <1%) but not from serogroups A, B, or C. At baseline, the prevalence of putatively protective specific IgG concentrations (> or =2 microg/mL) and bactericidal titers (> or =8) was 85% and 54%, respectively, against serogroup A, and 6% and 22%, respectively, against serogroup W-135. Putatively protective anti-W-135 IgG concentrations and bactericidal titers were of short duration and were not associated with carriage. CONCLUSION: N. meningitidis serogroup W-135 strains did not induce immunity, despite their circulation. Carriage of serogroup A strains was rare despite the hyperendemic incidence of serogroup A meningitis during 2003 in Bobo-Dioulasso. A vaccine that includes serogroup W-135 antigen and eliminates serogroup A carriage is needed for sub-Saharan Africa.     

Meningococcal disease in The Netherlands, 1959-1981: the occurrence of serogroups and serotypes 2a and 2b of Neisseria meningitidis

By means of a filter radioimmunoassay and the use of monoclonal anti-2a and anti-2b antibodies, we have serotyped 3164 of 3688 strains of Neisseria meningitidis isolated from patients in The Netherlands between 1959 and 1981. Serotypes 2a and 2b were distributed differently among the major serogroups A, B, C, and W-135. Neither of the types was found among group A strains. Type 2b strains of serogroup B emerged in 1965, causing a country-wide epidemic which reached a peak incidence in March and April of 1966 and continued to predominate within group B until 1979. Type 2a strains of serogroup C were responsible for a substantial number of sporadic cases over a long period without any association with outbreaks or with a shift in the pattern of the serogroup. After the appearance of group W-135 in 1971, W-135 strains caused a small non-focal epidemic wave. The upsurge of disease due to virulent sub-populations of strains B:2b and C:2a appeared to be closely related to a basic pattern of regular cyclical waves with peak intervals which differed for serogroups A, B, and C. In recent years both serotype 2a and 2b strains within the different serogroups fell to insignificant numbers. Our results show that retrospective large-scale serotyping of collected strains provides insight into the epidemiological patterns of endemic meningococcal disease.     

PCR identification of the group A Neisseria meningitidis gene in cerebrospinal fluid

The aim of this study was to develop a PCR method for direct identification of Neisseria meningitidis serogroup A in cerebrospinal fluid. The assay makes use of unique sites within the gene cassette responsible for expression of the (alpha1 --> 6)-linked N-acetyl-D-mannosamine-1-phosphate serogroup A capsule. A total of 67 different N. meningitidis strains and 12 clinical samples of CSF, culture positive for N. meningitidis, were examined. All the strains and samples of N. meningitidis serogroup A were correctly identified by an amplified PCR product of 519 bp. The PCR method for identification is specific for the group A gene of N. meningitidis. The assay may contribute to reducing recurrent, devastating epidemics of meningococcal infection by providing a diagnostic tool for grouping in developing countries where problems with false negative cultures are common and vaccination against serogroup A meningococci may be required.     

Heterogenity of serotypes of Neisseria meningitidis that cause endemic disease.

Three collections of strains of Neisseria meningitidis that caused meningococcal disease during nonepidemic periods were serotyped to determine whether serotypes that cause endemic disease are more heterogeneous than those responsible for epidemic disease. Thirty-four strains isolated from pediatric patients in Houston, Texas, from February 1977 to March 1978 were of three separate serogroups and 11 serotypes; 27 contemporary (1977-1978) strains from predominantly military populations, obtained nationwide, were of six serogroups and six serotypes, while 11 strains isolated at military posts in the southwest United States from 1970 through 1976 were of four serogroups and five serotypes. Between 9% and 20% of the strains were nontypable, while type II strains which were responsible for the epidemics in the Northern and Western Hemispheres earlier in the 1970's, accounted for only 20%-44% of the strains. In contast to epidemics, which appear to be caused by a single serotype, endemic meningococcal disease appears to be caused by a broad, heterogeneous distribution of serotypes. Thus, development of a serotype-specific vaccine may have limited application to the prevention of endemic meningococcal disease.     

Carriage of Neisseria meningitidis in a semi-isolated arctic community.

The carriage of Neisseria meningitidis was examined in the Norwegian population of Svalbard (1150 persons) after a fatal case of meningococcal septicaemia. The overall carrier rate was 39.0%. The rate was highest among males (47.8%), with a maximum of 63.4% in the age group 15-24 years. The carrier rate was low among children aged 3 to 15 years (6.5%). Children below 3 years were frequent meningococcal carriers, however (37.5%). Sulphonamide-resistant strains were often found, 22.6% of the total material being resistant. Group B was the most frequent serogroup, and accounted for 44.5% of the isolated strains. Non-groupable strains were second in frequency (23.8%), followed by group Y (15.8%). Only a few strains belonged to the serogroups A, C, X and Z. N. lactamica was isolated from 26.9% of children below 15 years, but seldom in older age groups.     

Clonal and variable properties of Neisseria meningitidis isolated from cases and carriers during and after an epidemic in The Gambia, West Africa

A representative collection of meningococci was isolated from cases and healthy carriers in The Gambia between 1982 and 1988, during and after an epidemic of meningococcal meningitis. These bacteria were subjected to a clonal analysis. All serogroup A bacteria from both cases and carriers were of one clone (A IV-1). Several unrelated clones were observed among serogroup 29E and serogroup Y carrier strains. The serogroup A strains were uniform for serotype and subtype antigens (serotype 4, subtype P1.7) and antibiotic sensitivity pattern. Occasional strains varied in their lipopolysaccharide (LPS), DNA fingerprint pattern, and/or the quantitative expression of the class 1 protein. A high degree of strain-specific variation was found for the expression of class 5 proteins, pili, and sulfonamide sensitivity. The frequency of strains expressing reduced amounts of the class 1 protein, altered LPS, and/or increased amounts of capsular polysaccharide rose among case strains obtained after the epidemic had ceased. These strains seem to be generally resistant to antibody-mediated bactericidal activity.     

Genotype-specific carriage of Neisseria meningitidis in Georgia counties with hyper- and hyposporadic rates of meningococcal disease

Carriage of Neisseria meningitidis in a Georgia county with hypersporadic incidence of meningococcal disease ("hypersporadic county") and in a county with no cases of meningococcal disease was determined by a cross-sectional pharyngeal culture study of high school students. Among 2730 students from whom culture samples were obtained, meningococcal carriage was 7.7% (140/1818) in the hypersporadic county and 6.1% (56/912) in the comparison county. Carriage rates by serogroup and genetic type (i.e., electrophoretic type [ET]) did not differ significantly between counties, but apartment or mobile home residency was a risk factor for carriage in the hypersporadic county. Although most cases of meningococcal disease in the hypersporadic county were caused by members of the serogroup C ET-37 clonal group, no ET-37 meningococcal isolates were recovered from carriers in this county. However, 38% of all meningococcal isolates recovered from carriers in both counties were members of the serogroup Y ET-508 clonal group, an emerging cause of meningococcal disease in Georgia and throughout the United States during 1996-2001. Shifts in carriage and transmission of meningococcal strains with different pathogenic potential are important determinants of meningococcal disease incidence.     

Capsule switching of Neisseria meningitidis

The different sialic acid (serogroups B, C, Y, and W-135) and nonsialic acid (serogroup A) capsular polysaccharides expressed by Neisseria meningitidis are major virulence factors and are used as epidemiologic markers and vaccine targets. However, the identification of meningococcal isolates with similar genetic markers but expressing different capsular polysaccharides suggests that meningococcal clones can switch the type of capsule they express. We identified, except for capsule, isogenic serogroups B [(α2→8)-linked polysialic acid] and C [(α2→9)-linked polysialic acid] meningococcal isolates from an outbreak of meningococcal disease in the U. S. Pacific Northwest. We used these isolates and prototype serogroup A, B, C, Y, and W-135 strains to define the capsular biosynthetic and transport operons of the major meningococcal serogroups and to show that switching from the B to C capsule in the outbreak strain was the result of allelic exchange of the polysialyltransferase. Capsule switching was probably the result of transformation and horizontal DNA exchange in vivo of a serogroup C capsule biosynthetic operon. These findings indicate that closely related virulent meningococcal clones may not be recognized by traditional serogroup-based surveillance and can escape vaccine-induced or natural protective immunity by capsule switching. Capsule switching may be an important virulence mechanism of meningococci and other encapsulated bacterial pathogens. As vaccine development progresses and broader immunization with capsular polysaccharide conjugate vaccines becomes a reality, the ability to switch capsular types may have important implications for the impact of these vaccines.     

Meningococcal disease caused by Neisseria meningitidis: epidemiological, clinical, and preventive perspectives

Bacterial meningitis constitutes a significant global public health problem. In particular, Neisseria meningitidis continues to be a public health problem among human populations in both developed and developing countries. Meningococcal infection is present as an endemic and an epidemic disease. Meningococcal disease is manifested not only as meningitis, but also as meningococcemia. The latter is usually fulminant. The global persistence of N. meningitidis is due to the significant number of carriers and the dynamics of transmission and disease. Approximately 500 million people worldwide are carriers of the bacterium in their nasopharynx. Multiple factors have been identified that predispose to the transmissibility of N. meningitidis, including active or passive inhalation tobacco smoking, upper viral respiratory tract infections, drought seasons, and overcrowding. These factors explain the frequent occurrence of outbreaks in military barracks, schools, prisons, and dormitories. Some of the determinants of invasiveness of the bacteria include nasopharyngeal mucosal damage in colonized individuals, virulence of the strains, absence of bactericidal antibodies, and deficiencies of the complement system. During both endemic and epidemic scenarios of meningococcal disease, control measures should include treating the cases with appropriate antimicrobial therapy (penicillin, ceftriaxone, or chloramphenicol); providing chemoprophylactic drugs to contacts (rifampin or ciprofloxacin), and close observation of contacts. Nevertheless, the key to effective control and prevention of meningococcal disease is immunoprophylaxis. Available vaccines include the polysaccharide monovalent, bivalent (serogroups A, C), or tetravalent (A, C, Y, W-135 serogroups) vaccines; conjugate vaccine (serogroup C); and the combined vaccine with outer membrane proteins and polysaccharide (serogroups B, C). Due to a recent increase in case reporting of serogroup C N. meningitidis in Mexico, we have developed a national response strategy that includes availability of vaccines and medications for chemoprophylaxis. This review aims at providing health care workers with updated information regarding the epidemiological, clinical, and preventive aspects of meningococcal disease. The English version of this paper is available at: http://www.insp.mx/salud/index.html.