Neisseria meningitidis
The bacterium Neisseria
meningitidis, the meningococcus, is a Gram-negative,
oxidase-positive diplococcus, identical in its staining and morphological
characteristics to Neisseria gonorrhoeae. However, at an ultrastructural
level, N. meningitidis has a prominent polysaccharide capsule not seen
in the gonococcus. The capsule is antiphagocytic and is an important virulence
factor in meningococcal disease. N. meningitidis strains are grouped on
the basis of their capsular polysaccharides, into 12 serogroups, some of which
are subdivided according to the presence of outer membrane protein and
lipopolysaccharide antigens.
Neisseria meningitidis is usually cultivated in a peptone-blood base medium in a
moist chamber containing 5-10% CO2. All media must be warmed to 37
degrees prior to inoculation as the organism is extremely susceptible to
temperatures above or below 37 degrees. This trait is rather unique among
bacteria. Also, the organism tends to undergo rapid autolysis after death, both
in vitro and in vivo. This accounts for the dissemination of lipopolysaccharide
(endotoxin) during septicemia and meningitis.
The organism tends to colonize the
posterior nasopharynx of humans, and humans are the only known host.
Individuals who are colonized are carriers of the pathogen who can transmit
disease to nonimmune individuals. The bacterium also colonizes the posterior
nasopharynx in the early stages of infection prior to invasion of the meninges.
Most individuals in close contact with a case of meningococcal meningitis
become carriers of the organism. This carrier rate can reach 20 percent of the
contact group before the first case is recognized, and may reach as high as 80
percent at the height of an epidemic.
Structure and Classification
Meningococcal capsular
polysaccharides provide the basis for grouping the organism. Twelve serogroups
have been identified (A, B, C, H, I, K, L, X, Y, Z, 29E, and W135). The most
important serogroups associated with disease in humans are A, B, C, Y, and W135.
The chemical composition of these capsular polysaccharides is known. The
prominent outer membrane proteins of N. meningitidis have been
designated class 1 through class 5. The class 2 and 3 proteins function as
porins and are analogous to gonococcal Por. The class 4 and 5 proteins
are analogous to gonococcal Rmp and Opa, respectively. Serogroup B and C
meningococci have been further subdivided on the basis of serotype determinants
located on the class 2 and 3 proteins. A handful of serotypes are associated
with most cases of meningococcal disease, whereas other serotypes within the
same serogroup rarely cause disease. All known group A strains have the same
protein serotype antigens in the outer membrane. Another serotyping system
exists based on the antigenic diversity of meningococcal LOS
(lipooligopolysaccharide).
Meningitis
The term meningitis refers
to inflammation the meninges of the brain or spinaL cord. Meninges are any of
the three membranes that envelope the brain and spinal cord. The disease meningitis
is caused by a number of different bacteria and viruses. Bacterial causes
include Haemophilus influenzae, Escherichia coli, Streptococcus
pneumoniae, Streptococcus pyogenes, Staphylococcus aureus, and Neisseria
meningitidis. Although a variety of cocci cause meningitis, the term meningococcus
is reserved for the Gram-negative, bean-shaped diplococcus, Neisseria
meningitidis. Like its relative N. gonorrhoeae, the organism tends
to occur intracellularly in the cytoplasm of neutrophils which are attracted to
the site of inflammation in the meninges, so this type of infection is called
pyogenic or suppurative, to mean pus-forming.
Marchiafava and Celli were the first
to report observing Gram-negative diplococci in cerebrospinal fluid of a fatal
case of meningitis in 1884. In 1887, Weichselbaum isolated the bacterium from
six cases of meningitis and established the isolates as a distinct species and
proven to be the cause of meningitis.
Pathogenesis
Infection with N. meningitidis
has two presentations, meningococcemia, characterized by skin lesions,
and acute bacterial meningitis. The fulminant form of disease (with or
without meningitis) is characterized by multisystem involvement and high
mortality.
Infection is by aspiration of
infective bacteria, which attach to epithelial cells of the nasopharyngeal and
oropharyngeal mucosa, cross the mucosal barrier, and enter the bloodstream. If
not clear whether blood-borne bacteria may enter the central nervous system and
cause meningitis.
The mildest form of disease is a
transient bacteremic illness characterized by a fever and malaise; symptoms
resolve spontaneously in 1 to 2 days. The most serious form is the fulminant
form of disease complicated by meningitis. The manifestations of meningococcal
meningitis are similar to acute bacterial meningitis caused by other bacteria
such as Streptococcus pneumoniae, Haemophilus influenzae, and E.
coli. Chills, fever, malaise, and headache are the usual manifestations of
infection. Signs of meningeal inflammation are also present.
Clinical manifestations of N. meningitidis infection
The onset of meningococcal
meningitis may be abrupt or insidious. Infants with meningococcal meningitis
rarely display signs of meningeal irritation. Irritability and refusal to take
food are typical; vomiting occurs early in the disease and may lead to
dehydration. Fever is typically absent in children younger than 2 months of
age. Hypothermia is more common in neonates. As the disease progresses, apnea,
seizures, disturbances in motor tone, and coma may develop.
In older children and adults,
specific symptoms and signs are usually present, with fever and altered mental
status the most consistent findings. Headache is an early, prominent complaint
and is usually very severe. Nausea, vomiting, and photophobia are also common
symptoms.
Neurologic signs are common;
approximately one-third of patients have convulsions or coma when first seen by
a physician. Signs of meningeal irritation such as spinal rigidity, hamstring
spasms and exaggerated reflexes are common.
Petechiae (minute hemorrhagic spots
in the skin) or purpura (hemorrhages into the skin) occurs from the first to
the third day of illness in 30 to 60% of patients with meningococcal disease,
with or without meningitis. The lesions may be more prominent in areas of the
skin subjected to pressure, such as the axillary folds, the belt line, or the
back.
Fulminant meningococcemia occurs in
5 to 15% of patients with meningococcal disease and has a high mortality rate.
It begins abruptly with sudden high fever, chills, myalgias, weakness, nausea,
vomiting, and headache. Apprehension, restlessness, and delirium occur within
the next few hours. Widespread purpuric and ecchymotic skin lesions appear
suddenly. Typically, no signs of meningitis are present. Pulmonary
insufficiency develops within a few hours, and many patients die within 24
hours of being hospitalized despite appropriate antibiotic therapy and
intensive care.
Virulence Factors
For a time, the virulence of Neisseria
meningitidis was attributed to the production of an "exotoxin"
that could be recovered from culture filtrates of the organism. But when
studies revealed that antitoxin reacted equally well with washed cells as
culture filtrate, it was realized that the bacteria underwent autolysis during
growth and released parts of their cell walls in a soluble form. Hence, the
major toxin of N. meningitidis is its lipooligosaccharide, LOS,
and its mechanism is endotoxic. The other important determinant of virulence of
N. meningitidis is its antiphagocytic polysaccharide capsule.
The human nasopharynx is the only
known reservoir of N. meningitidis. Meningococci are spread via
respiratory droplets, and transmission requires aspiration of infective
particles. Meningococci attach to the nonciliated columnar epithelial cells of
the nasopharynx. Attachment is mediated by fimbriae and possibly by
other outer membrane components. Invasion of the mucosal cells occurs by a
mechanism similar to that observed with gonococci. Events involved after
bloodstream invasion are unclear and how the meningococcus enters the central
nervous system is not known.
Purified meningococcal LOS is highly
toxic and is as lethal for mice as the LOS from E. coli or Salmonella
typhimurium; however, meningococcal LOS is 5 to 10 times more effective
than enteric LPS in eliciting a dermal Shwartzman phenomenon (a characteristic
type of inflammatory reaction) in rabbits. Meningococcal LOS has been shown to
suppress leukotriene B4 synthesis in human polymorphonuclear leukocytes. The
loss of leukotriene B4 deprives the leukocytes of a strong chemokinetic and
chemotactic factor.
Host Defenses
N. mengingitidis establishes systemic infections only in individuals who
lack serum bacterial antibodies directed against the capsular or noncapsular
(cell wall) antigens of the invading strain, or in patients deficient in the
late-acting complement components.
The integrity of the pharyngeal and
respiratory epithelium appears to be important in protection from invasive
disease. Chronic irritation of the mucosa due to dust or low humidity, or
damage to the mucosa resulting from a concurrent upper respiratory
infection, may be predisposing factors for invasive disease.
The presence of serum bactericidal
IgG and IgM is probably the most important host factor in preventing invasive
disease. These antibodies are directed against both capsular and noncapsular
surface antigens. The antibodies are produced in response to colonization with
carrier strains of N. meningitidis, as well as N. lactamica, and
other nonpathogenic Neisseria species that are normal inhabitants of the
upper respiratory tract. Protective antibodies are also stimulated by
cross-reacting antigens on other bacterial species such as Escherichia coli.
The role of bactericidal antibodies in prevention of invasive disease
explains why high attack rates are seen in infants from 6 to 9 months old, the
time at which maternal antibodies are being lost. Individuals with complement
deficiencies (C5, C6, C7, or C8) may develop meningococcemia despite protective
antibody. This emphasizes the importance of the complement system in defense
against meningococcal disease.
Epidemiology
The meningococcus usually inhabits
the human nasopharynx without causing detectable disease. This carrier state
may last for a few days to months and is important because it not only provides
a reservoir for meningococcal infection but also stimulates host immunity.
Between 5 and 30% of normal individuals are carriers at any given time, yet few
develop meningococcal disease. Carriage rates are highest in older children and
young adults. Attack rates highest in infants 3 months to 1 year old.
Meningococcal meningitis occurs both sporadically (mainly groups B and C
meningococci) and in epidemics (mainly group A meningococci), with the highest
incidence during late winter and early spring. Whenever group A strains become
prevalent in the population, the incidence of meningitis increases markedly.
Treatment
Penicillin is the drug of choice to
treat meningococcemia and meningococcal meningitis. Although penicillin does
not penetrate the normal blood-brain barrier, it readily penetrates the
blood-brain barrier when the meninges are acutely inflamed. Either
chloramphenicol or a third-generation cephalosporin such as cefotaxime or ceftriaxone
is used in persons allergic to penicillins.
Meningococcal disease is contracted
through association with infected individuals, as evidenced by the 500- to
800-fold greater attack rate among household contacts than among the general
population. Because such household members are at high risk, they require
chemoprophylaxis. Sulfonamides were the chemoprophylactic agent of choice until
the emergence of sulfonamide-resistant meningococci. At present, approximately
25 percent of clinical isolates of N. meningitidis in the United States
are resistant to sulfonamides; nowadays, rifampin is the chemoprophylactic
agent of choice.
Control
Groups A, C, AC, and ACYW135
capsular polysaccharide vaccines are available. However, the polysaccharide
vaccines are ineffective in young children (in children under 1 year old,
antibody levels decline rapidly after immunization) and the duration of protection
is limited in children vaccinated at 1 to 4 years of age. Routine
vaccination is not currently recommended because the risk of infection is low.
The group B capsular polysaccharide is a homopolymer of sialic acid and is not
immunogenic in humans. A group B meningococcal vaccine consisting of outer
membrane protein antigens has recently been developed, but is not licensed in
the United States.
Search for a universal vaccine for meningococcal meningitis
Search for a universal vaccine for meningococcal meningitis
There is an obvious need for a
universal vaccine for meningococcal meningitis, but the development of an
effective vaccine against all forms of N. meningitidis has been hampered
by the high degree of variation in the proteins on the surface of the bacterium
which leads to the occurrence of many different antigenic types.
More than 10% of the population may
be carrying the bacterium at any one time on the mucosal surfaces of the nose
and throat. The majority of these carriers will not have any symptoms of the
disease, but this continual exposure to the immune system puts pressure on the
bacterium to mutate its surface components in order to survive. Thus, natural
selection is the driving force for the emergence of new antigenic variants.
Among the class 2 and 3 outer
membrane proteins of N. meningitidis, Por A has been considered a
primary target for a vaccine-induced antibody. PorA is a major component
of the outer membrane of N. meningitidis, and anti-PorA antibodies are
thought to be a critical component in immunity. Interactions between
antibodies and PorA have been studied. Different strains of the bacterium
have different PorA amino acid sequences within the region of the protein that
specifically binds to antibody molecules. PorA has several large amino
acid "loop" regions that protrude from the surface, and it is these
loops that are targets for antibody binding.
In the laboratory, the
antigen-binding fragment (Fab) of anti-PorA antibodies can be crystallized and
reacted with the antigenic loop regions of PorA in order to determine the
specificity of binding between antigen and antibody. Slight changes in PorA
amino acid sequence have been shown to cause loss in the ability to bind to
antibody molecules. In nature, the bacterium mutates to insert new amino
acid residues into the tip of the loop, which alters or eliminates many of the
interactions with antibody and allows the bacterium to bypass previous
immune responses.
