Bactericidal activity for Neisseria meningitidis in properdin-deficient sera

We investigated serum bactericidal reactions against Neisseria meningitidis (serogroups A, B, C, D, Y, W-135, 29E, X, and Z) in the sera of two healthy adults with properdin deficiency. Bactericidal reactions mediated via the classic complement pathway (unchelated system) were not impaired in properdin-deficient serum. The properdin-deficient sera supported alternative pathway-mediated killing (Mg++EGTA-chelated system) of some, but not all, of the strains investigated. Vaccination of the properdin-deficient individuals with serogroup A and C polysaccharide clearly increased the concentrations of antibody to meningococci. At least some of the antibodies induced by vaccination supported the bactericidal activity of properdin-deficient serum. Some antibodies to meningococci, probably of the IgM class, promoted alternative pathway-mediated bactericidal reactions in the absence of properdin. By contrast, presensitizing meningococci with IgG enhanced the alternative pathway-mediated reactions, but this was strictly a properdin-dependent effect.     

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.     

Safety,reactogenicity, and immunogenicity of a tetravalent meningococcal polysaccharide-diphtheria toxoid conjugate vaccine given to healthy adults

Healthy adults, 18-55 years old, were immunized once with a tetravalent (serogroups A, C, Y, and W-135) meningococcal vaccine conjugated to diphtheria toxoid at 1 of 3 doses and were monitored for safety, reactogenicity, and immunogenicity. No immediate reactions were observed. Only 1 of 89 subjects reported fever; only 1 reported any severe reactogenicity (local pain/soreness, chills, arthralgia, anorexia, and malaise). For each serogroup and in each dose group, the geometric mean serum bactericidal antibody (SBA) titer and immunoglobulin G concentration increased after immunization. In the 4- and 10-microg-dose groups, all subjects had SBA titers >/=8 against serogroups A and C, and 89% and 93% of subjects had SBA titers >/=8 against serogroups Y and W-135, respectively. The A, C, Y, and W-135 Neisseria meningitidis-diphtheria toxoid conjugate vaccine, when given to healthy adults as a single intramuscular injection of 1, 4, or 10 microg/serogroup, is acceptably tolerated and immunogenic and deserves further development.     

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 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.     

Complement deficiencies in selected groups of patients with meningococcal disease

We have examined 125 individuals who have earlier had meningococcal (mgc) disease. They belonged to one or more of the following groups: (1) 2 or more cases of mgc disease in the same family; (2) individuals with 2 episodes of mgc disease or with 1 episode of mgc disease and 1 or more episodes of purulent meningitis of another aetiology; and (3) infections with Neisseria meningitidis belonging to serogroups that are uncommon as causes of disease and presumably low-virulent (W-135, 29E, X, Y). Among these we found 15 complement (C)-deficient individuals (12%). The prevalence of C deficiency in the groups above was 7%, 41% and 19%, respectively. The first group (family cases), is very heterogeneous and may be further subdivided into 2 groups: families whose members fell ill within an interval of 30 days (in these the prevalence of C deficiency was 2%), and families in which the interval between mgc disease cases exceeded 30 days (in those the prevalence of C deficiency was 14%). We found a predominance of defects of the initiation pathways, with properdin deficiency being the most common.     

Deficient alternative complement pathway activation due to factor D deficiency by 2 novel mutations in the complement factor D gene in a family with meningococcal infections

The complement system is an essential element in our innate defense against infections with Neisseria meningitidis. We describe 2 cases of meningococcal septic shock, 1 of them fatal, in 2 children of a Turkish family. In the surviving patient, alternative pathway activation was absent and factor D plasma concentrations were undetectable. Concentrations of mannose-binding lectin (MBL), C1q, C4 and C3, factor B, properdin, factor H, and factor I were normal. Mutation analysis of the factor D gene revealed a T638 > G (Val213 > Gly) and a T640 > C (Cys214 > Arg) mutation in the genomic DNA from the patient, both in homozygous form. The consanguineous parents and an unaffected sister had these mutations in heterozygous form. In vitro incubation of factor-D-deficient plasma of the boy with serogroup B N meningitidis showed normal MBL-mediated complement activation but no formation of the alternative pathway C3-convertase C3bBbP, and severely decreased C3bc formation and terminal complement activation. The defect was restored after supplementation with factor D. In conclusion, this is the second report of a factor D gene mutation leading to factor D deficiency in a family with meningococcal disease. This deficiency abolishes alternative-pathway dependent complement activation by N meningitidis, and leads to an increased susceptibility to invasive meningococcal disease.     

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.     

Neisseria meningitidis serogroup W-135 carriage among US travelers to the 2001 Hajj

In 2000, a large international outbreak of meningococcal disease caused by Neisseria meningitidis serogroup W-135 was identified among pilgrims returning from the Hajj in Saudi Arabia. To assess ongoing risk, we evaluated N. meningitidis carriage among US travelers to the 2001 Hajj. Of 25 N. meningitidis isolates obtained, 15 (60%) were nongroupable and 8 (32%) were serogroup W-135 when tested by standard slide-agglutination techniques. Two additional nongroupable isolates were characterized as serogroup W-135 when tested by polymerase chain reaction. Nine of 10 serogroup W-135 isolates were indistinguishable from the Hajj-2000 clone. None of the departing, but 9 (1.3%) of the returning, pilgrims carried serogroup W-135 (P=.01); all carriers reported previous vaccination. Carriage of N. meningitidis serogroup W-135 increased significantly in pilgrims returning from the Hajj. Although the risk of disease to pilgrims appears to be low, the risk of spread to others of this pathogenic strain remains a concern.     

Antibody persistence 3 years after immunization of adolescents with quadrivalent meningococcal conjugate vaccine

BACKGROUND: A quadrivalent meningococcal conjugate vaccine (MCV-4) is recommended for United States teenagers. The duration of protective immunity is unknown. We investigated serum antibody persistence 3 years after vaccination of adolescents. METHODS: Serum samples from participants of a randomized trial who had received MCV-4 (n=52) or polysaccharide vaccine (MPSV-4; n=48) and from unvaccinated controls (n=60) were assayed for serogroups C, W-135, and Y anticapsular antibody concentrations by use of a radioantigen binding assay and for bactericidal activity (in a human complement assay) and passive protection against serogroup C bacteremia in an infant rat model. RESULTS: A higher proportion of participants in the vaccine groups had protective bactericidal titers (> or =1 : 4), compared with that in the control group (for MCV-4 recipients vs. controls, P<.01; for MPSV-4 recipients vs. controls, P< or =.06). More MCV-4 recipients had W-135 bactericidal titers > or =1 : 4 than did MPSV-4 recipients (P=.01). More MCV-4 recipients had passive protective activity against serogroup C bacteremia than did MPSV-4 recipients (76% vs. 49%; P<.01). The differences in protective activity were largest between participants in the vaccine groups with bactericidal titers <1 : 4 (63% protective in MCV-4 recipients vs. 31% protective in MPSV-4 recipients; P=.01). CONCLUSIONS: Compared with MPSV-4, MCV-4 elicited greater persistence of antibody activity against serogroups C and W-135 at 3 years after vaccination in adolescents. On the basis of passive protection data in an infant rat model, bactericidal titers > or =1 : 4 underestimate protective immunity.     

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.     

Subacute septicemia caused by Meningococcus of serogroup Y and acquired deficiency of complement C3 fraction

The high frequency of meningococcal infections in patients with congenital deficiency of a component of the complement terminal pathway emphasizes the critical role of this system in host resistance against Neisseriaceae. We report the observation of a subacute septicaemia due to N. meningitidis serogroup Y. This girl had an acquired deficit of the C3 fraction of complement due to a high titre of C3 nephritic factor (C3NeF). There was no evidence of partial lipodystrophy or biological symptoms of glomerular disease. The meningococcal infection revealed this biological abnormality.     

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.     

Fulminant meningococcal infections in a family with inherited deficiency of properdin

Three males in a large kindred died of meningococcal infections. In the index patient, properdin (P) was not detectable in serum. Two healthy males with a selective P deficiency were found in the family. There was no general susceptibility to infections, nor to other diseases as suggested by the family history. The serum bactericidal activity for Neisseria meningitidis group C, isolated from the index patient, was moderately reduced in P deficient serum, and was improved by addition of purified P.     

Complement deficiency states and infection: epidemiology, pathogenesis and consequences of neisserial and other infections in an immune deficiency

Inherited deficiencies of the complement proteins are rare in unselected populations. Examination of patients with the clinical correlates of complement deficiency (autoimmune disease and certain bacterial infections) shows the frequency of inherited complement deficiency to rise enormously (5.9% of patients with systemic lupus erythematosus, 10 to 25% of adults with sporadic meningococcal disease). Autoimmune diseases of all types, but especially systemic lupus erythematosus, discoid lupus and glomerulonephritis, are seen in all categories of complement deficiency, most typically in those of the early classical pathway (C1, C4, C2). Pneumococcal infections are characteristic of deficiencies of the early classical pathway, as well. Deficiencies of C3 are associated with severe disease including autoimmune phenomena, pneumococcal and neisserial infections. C3-deficient patients become ill substantially earlier in life. Infections with N. meningitidis and N. gonorrhoeae are most typical of the late component deficiencies, with over 40% of homozygotes affected. Despite the presence of this deficiency from birth and the peak age-specific incidence of meningococcal disease in the general population at ages 3-8 months, the median age of first infection in the late component-deficient patients is 17 years. Relapse of infection is ten times more common in these patients, and discrete recurrences are seen in 45% of affected individuals. An unusual and unexplained predilection for infection with serogroup Y N. meningitidis exists. Despite an immune deficiency, and problems with ascertainment bias, it appears that persons with late component complement deficiency enjoy less mortality than normals who contract meningococcal disease. Attempts to explain the pathogenesis of neisserial infection in late component deficiencies have focused on the concept that normally non-pathogenic serum-sensitive bacteria are etiologic in the absence of serum bactericidal activity. Data to support this concept remain to be developed and contrary data exist. A separate mechanism may predispose properdin-deficient patients to meningococcal infection, since they appear to develop fulminant infections with high mortality.     

Serologic response to meningococcal vaccination in patients with paroxysmal nocturnal hemoglobinuria (PNH) chronically treated with the terminal complement inhibitor eculizumab

Eculizumab is indicated for the therapy of patients with symptomatic paroxysmal nocturnal hemoglobinuria (PNH). Due to inhibition of terminal complement cascade, patients on eculizumab are susceptible to Neisseria meningitidis infections. The two mainstays to reduce the risk of infection are vaccination and antibiotic prophylaxis. In this retrospective study, serologic response was analyzed after vaccination with a meningococcal vaccine in 23 PNH patients (median age 36 years; range 25 - 88 years; 15 males, 8 females) by measuring serum bactericidal assay (SBA) using rabbit complement (rSBA) titers against meningococcal serogroups A, C, W, and Y. Serologic protection was defined by an rSBA titer ≥1:8. Forty-three percent (10/23) were vaccinated more than once due to chronic eculizumab treatment. Overall serologic response for the meningococcal serogroups was A: 78% (18/23), C: 87% (20/23), W: 48% (11/23), and Y: 70% (16/23). No meningococcal infections have been observed. As immunological response to vaccines varies, the use of serologic response analyses is warranted. Re-vaccination with a tetravalent conjugate vaccine under eculizumab therapy every 3 years is essential or should be based on response rates. If meningococcal infection is suspected, standby therapy with ciprofloxacin and immediate medical evaluation are recommended. The novel vaccines covering serogroup B may even further reduce the risk for infection.     

Meningococcal vaccines

Global control and prevention of meningococcal disease depends on the further development of vaccines that overcome the limitations of the current polysaccharide vaccines. Protein-polysaccharide conjugate vaccines likely will address the marginal protective antibody responses and short duration of immunity in young children derived from the A, C, Y, and W-135 capsular polysaccharides, but they will be expensive to produce and purchase, and may not offer a practical solution to the countries with greatest need. In addition, OMP vaccines have been tested extensively in humans and hold some promise in the development of a serogroup B vaccine, but are limited by the antigenic variability of these subcapsular antigens and the resulting strain-specific protection. Elimination of meningococcal disease likely will require a novel approach to vaccine development, ideally incorporating a safe and effective antigen or antigens common to all meningoccocal serogroups. As a solely human pathogen, however, N. meningitidis has developed many tools with which to evade the human immune system, and likely will pose a formidable challenge for years to come.     

Carriage of serogroup W-135, ET-37 meningococci in The Gambia: implications for immunisation policy?

We found high levels of symptomless carriage of a hyperinvasive Neisseria meningitidis strain (electrophoretic type 37 [ET-37], serogroup W-135) during a vaccine trial in Gambian children in 1996. Serogroup C, ET-37 complex meningococci cause 30-40% of meningococcal disease in countries such as the UK, and have a point prevalence of 0.5-1.0%. The recent Haj-associated spread of serogroup W-135, ET-37 complex meningococci, which has been accompanied by numerous secondary cases, might be explained by the apparently raised carriage rates reported here.     

Epidemiological patterns of meningococcal meningitis in Niger in 2003 and 2004: under the threat of N. meningitidis serogroup W135

Since the Neisseria meningitidis serogroup W135 epidemic in Burkina Faso in 2002, the neighbouring countries dread undergoing outbreaks. Niger has strongly enhanced the microbiological surveillance, especially by adding the polymerase chain reaction (PCR) assay to the national framework of the surveillance system. During the 2003 epidemic season, 8113 clinically suspected cases of meningitis were notified and nine districts of the 42 crossed the epidemic threshold, while during the 2004 season, the number of cases was 3521 and four districts notified epidemics. In 2003 and 2004, serogroup A was identified in most N. meningitidis from cerebrospinal fluid (CSF) specimens (89.7% of 759 and 87.2% of 406, respectively). Although serogroup W135 represented only 8.3% of the meningococcal meningitis in 2003 and 7.9% in 2004, and was not involved in outbreaks, it was widespread in various areas of the country. In the regions that notified epidemics, the proportion of serogroup W135 was tiny while it exceeded 40% in several non-epidemic regions. Despite the wide distribution of W135 serogroup in Niger and the fears expressed in 2001, the threat of a large epidemic caused by N. meningitidis W135 seems to have been averted in Niger so far. There is no clear indication whether this serogroup will play a lasting role in the epidemiology of meningococcal meningitis or not. As early as in the 1990s, a significant but transient increase in the incidence of N. meningitidis serogroup X was observed. Close microbiological surveillance is crucial for monitoring the threat and for identifying at the earliest the serogroups involved in epidemics.     

Bacteremic W-135 meningococcal pneumonia

Two epidemiologically unrelated cases of bacteremic meningococcal pneumonia are reported. Both patients were civilians without antecedent viral illness. The organism involved was Neisseria meningitidis, Group W-135, a serogroup of rapidly increasing importance in the United States. The difficulties in diagnosis and scope of meningococcal pneumonia are discussed.