Neisseria meningitidis causing meningococcal meningitis: Difference between revisions

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===Pathophysiology of the disease===
===Pathophysiology of the disease===


<br>  As a rapidly progressive disorder, meningococcal meningitis involves <br><i>Neisseria meningitidis</i> invading the subarachnoid space of the brain, where meninges become inflamed.  Before the bacteria enter the subarachnoid space, they significantly increase their numbers within the bloodstream, adapting to the environment, and if their numbers are great enough, cross the blood-brain barrier and take over the subarachnoid space [12].  While in the bloodstream, white blood cells attack <br><i>Neisseria meningitidis</i>, but unfortunately once the bacteria enter the subarachnoid space, the host's defense network is unable to control the infection developing in the cerebrospinal fluid (CSF) because the presence of safeguards (local antibodies and complement activity (aids in combating the invading pathogens) is lacking in the area.  As the numbers of bacteria and white blood cells increase in the CSF, a local inflammatory response is induced in the subarachnoid space due to the creating and releasing of inflammatory mediators.  These nasty compounds (what are they?) cause an increase in the number of white blood cells within the CSF and increase the accessibility of the blood-brain barrier, a key ingredient to the bacterial meningitis infection.  In response to the accessibility of a typically sterile environment to pathogens, mediators (including liposaccharides and cytotoxin-engaging receptors, including what are called Toll-like receptors) of endothelial cells activate downstream cascades that release white-blood cell precursors and other immune cell responses.  This allows for white blood cells (specifically neutrophils, shown in Figure 3) to move across the blood-brain barrier [6].  
<br>  As a rapidly progressive disorder, meningococcal meningitis involves <br><i>Neisseria meningitidis</i> invading the subarachnoid space of the brain, where meninges become inflamed.  Before the bacteria enter the subarachnoid space, they significantly increase their numbers within the bloodstream, adapting to the environment, and if their numbers are great enough, cross the blood-brain barrier and take over the subarachnoid space [12].  While in the bloodstream, white blood cells attack <br><i>Neisseria meningitidis</i>, but unfortunately once the bacteria enter the subarachnoid space, the host's defense network is unable to control the infection developing in the cerebrospinal fluid (CSF) because the presence of safeguards (local antibodies and complement activity (aids in combating the invading pathogens) is lacking in the area.  As the numbers of bacteria and white blood cells increase in the CSF, a local inflammatory response is induced in the subarachnoid space due to the creating and releasing of inflammatory mediators.  These nasty compounds (what are they?) cause an increase in the number of white blood cells within the CSF and increase the accessibility of the blood-brain barrier, a key ingredient to the bacterial meningitis infection.  In response to the accessibility of a typically sterile environment to pathogens, mediators (including liposaccharides and cytotoxin-engaging receptors, including what are called Toll-like receptors) of endothelial cells activate downstream cascades that release white-blood cell precursors and other immune cell responses.  This allows for white blood cells (specifically neutrophils, shown in Image 3) to move across the blood-brain barrier [6].  


[[Image:bacterialmeningitis.png|thumb|300px|right|Image 3.  How <br><i>Neisseria meningitidis</i> invades the meninges (http://www.qiagen.com/geneglobe/static/images/Pathways/Bacterial%20Meningitis.jpg).]]
[[Image:bacterialmeningitis.png|thumb|300px|right|Image 3.  How <br><i>Neisseria meningitidis</i> invades the meninges (http://www.qiagen.com/geneglobe/static/images/Pathways/Bacterial%20Meningitis.jpg).]]

Revision as of 03:40, 9 May 2013

Figure 1. Colored scanning electron micrograph (SEM) of
Neisseria meningitidis, gram-negative diplococci that cause meningococcal meningitis (magnified x 33000) (http://www.dailymail.co.uk/sciencetech/article-2197533/As-pretty-picture-lot-deadly--Killer-diseases-youve-seen-before.html).

Introduction

By Kelsey McMurtry

Neisseria meningitidis is a gram-negative, aerobic, non endospore forming [12] diplococcus of the Proteobacteria phylum [7]. Primarily affecting humans, this nonmotile (though covered in pili) [12] bacterium is enveloped with a carbohydrate capsule [13] that is covered with and distinguished by the polysaccharides attached to its surface. The host's immune system targets the carbohydrate capsule (elaborate). N.meningitidis is one of the three main bacteria that causes acute bacterial meningitis, along with Streptococcus pneumoniae and Haemophilus influenzae [1]. Of the forms of acute bacterial meningitis, Neisseria meningitidis causes meningococcal meningitis, which is among the top 10 causes of death due to infection across the globe, where one-third to half of people who survive the infection deal with permanent physical or mental side effects of the disease [2]. These side effects, also known as sequelae, can include chronic fatigue and insomnia, hearing loss and neurological disability, as well as loss of skin, fingers, toes, and even limbs by restricted blood supply to such tissues [2, 12]. In fact, these symptoms closely reflected those of individuals who experienced post-traumatic stress disorder following survival of septicaemia and septic shock, instances that occur with the invasion of bacteria into the normally sterile environment of the bloodstream [2].

What is bacterial meningitis?


Bacterial meningitis involves the invasion of bacteria into the typically sterile environment of the bloodstream, followed by infiltration of the meninges, causing meningeal inflammation [12]. In order to reach the bloodstream, the bacteria must first colonize the nasopharynx of the human host, and then attach to pili to cross the nasopharyngeal epithelium by endocytosis [12]. The meninges, a lining surrounding the central nervous system composed of the brain and spinal cord [13], are composed of the pia, the arachnoid, and the subarachnoid space (Figure 2). Many cases of meningitis involve the spread of bacteria from an infection in a completely different part of the body by traveling through the bloodstream to the brain and spinal cord. However, bacteria have been also known to spread throughout the body from a significant blow to the head, or from an infection initially located in the ear, nose, or teeth. Unfortunately, as the disease persists, the brain begins to swell and can possibly begin bleeding.

Metabolism

Pathophysiology of the disease


As a rapidly progressive disorder, meningococcal meningitis involves
Neisseria meningitidis invading the subarachnoid space of the brain, where meninges become inflamed. Before the bacteria enter the subarachnoid space, they significantly increase their numbers within the bloodstream, adapting to the environment, and if their numbers are great enough, cross the blood-brain barrier and take over the subarachnoid space [12]. While in the bloodstream, white blood cells attack
Neisseria meningitidis, but unfortunately once the bacteria enter the subarachnoid space, the host's defense network is unable to control the infection developing in the cerebrospinal fluid (CSF) because the presence of safeguards (local antibodies and complement activity (aids in combating the invading pathogens) is lacking in the area. As the numbers of bacteria and white blood cells increase in the CSF, a local inflammatory response is induced in the subarachnoid space due to the creating and releasing of inflammatory mediators. These nasty compounds (what are they?) cause an increase in the number of white blood cells within the CSF and increase the accessibility of the blood-brain barrier, a key ingredient to the bacterial meningitis infection. In response to the accessibility of a typically sterile environment to pathogens, mediators (including liposaccharides and cytotoxin-engaging receptors, including what are called Toll-like receptors) of endothelial cells activate downstream cascades that release white-blood cell precursors and other immune cell responses. This allows for white blood cells (specifically neutrophils, shown in Image 3) to move across the blood-brain barrier [6].

Image 3. How
Neisseria meningitidis invades the meninges (http://www.qiagen.com/geneglobe/static/images/Pathways/Bacterial%20Meningitis.jpg).

Although the host can show signs of symptoms such as confusion, stupor, coma, and seizures that correlate with bacterial meningitis, these conditions are not directly caused by bacterial invasion because the bacteria cannot invade the tissue located underneath the pia. Accessing the subpial tissue is a chemical response induced by proinflammatory cytokines, which are small signaling molecules used for cell signaling, that are released in response to the bacterial invasion and the breaking down of cells within the subarachnoid space (see Figure 3 for additional understanding).

Where, Who, What?


Neisseria meningitidis has the greatest outbreak potential of the three main bacteria causing acute bacterial meningitis, and regularly causes outbreaks in the "meningitis belt" of sub-Saharan Africa, where epidemics occur every 8-12 years, and can have a disease rate of greater than 1% [12]. Though Neisseria meningitidis affects a large range of ages, it can be found most frequently in children and college-aged individuals [2]. Children and young adults are especially at risk for contracting meningococcal meningitis, especially with its ability to cause the spread of infection not just throughout the bloodstream, but also in the organs (sepsis) as well as its ability to invade the typically bacteria-free environment of the blood [1]. Particularly when looking at young adults, college students seem to be particularly at risk due to living in close quarters with many other individuals with diverse backgrounds, and where when stress levels rise and the amount of sleep decreases, so too does the susceptibility to infection. The immune system's ability to fight off infection may be due to a number of activities that college students engage in, including drinking, partying at clubs, smoking, etc... Unfortunately, every year, 15 to 20 college students die due to bacterial meningitis [5]. And because there are varying symptoms for the disease, it is difficult to diagnose meningitis in the early stages of the infection [3].

In terms of case severity, the side effects of meningococcal meningitidis, including sepsis, which occurs when an infection spreads throughout the whole body, and not just the blood, but also the organs, as well as hypotension, the condition of having abnormally low blood pressure, are actually more severe than the disease itself [1].

Symptoms vary from person to person, but can include high fever, stiff neck, headaches, rash, fatigue, confusion, and sensitivity to light.

Unfortunately for those contracting the disease, acute bacterial meningitis can cause disability and death within one day of being infected.

Image 5. Global distribution of frequent meningococcal meningitis outbreaks (http://www.pharmainfo.net/reviews/comprehensive-review-meningococcal-meningitis).

Variety in Neisseria meningitidis

N. meningitidis has 12 serogroups, or forms distinguished by possessing the same set of antigens on their cell membrane, or capsular surface. Antigens are located on the cell membrane surface, and are important in their promotion of an immune response. These 12 strains of N.meningitidis are distinguished by the polysaccharide present on the bacterial capsid [13]. Most cases of meningitis are caused by the following 6 serogroups: A, B, C, W135, X, and Y [6].

Serogroup B infection is the most common form of the disease in countries across Europe and North America, and unfortunately cannot be treated by either conjugate capsular polysaccharide vaccines or outer membrane vesicle vaccines that target epidemic disease caused by a single clone of the bacterium [3]. Compared to serogroup A tendency to cause large-scale epidemics, serogroup B causes sporadic and isolated outbreaks of meningococcal meningitis [12]. Incidences have been found in Oregon, Cuba, and Norway [12].

Epidemics are found to be mainly associated with serogroup A meningococci. Rampant epidemics have found in a diverse collection of locations across the globe, including Brazil, North America, Finland, Nepal, and Saudi Arabia [12]. However, there have also been outbreaks correlated with serogroup C, and most recently, within the past decade, serogroups W135 and X [1].

Serogroup C and serogroup B are found most commonly to cause meningococcal meningitis in adolescents and adults in Canada, the United States, and Europe.
N. meningitidis serogroups B and C are composed of polysialic acid, and they only vary slightly in terms of their structure (specifics in [10]).

Carrying, Identifying, Diagnosing, and Treating Meningococcal Meningitis


About 1 in every 10 people carries a harmless form of meningococcus in their throat and nose. During a meningitis outbreak, approximately 95% of people will carry meningococcus, though fortunately many are resistant to its' deadly throes, with only 1% of the population contracting the disease [5].

In order for the bacteria to be transferred, if someone has the disease and shares their respiratory fluids with your own, such as through kissing, or the sharing of a drink, etc..., then it is very likely that you will contract the disease.

Identifying those individuals with meningococcal meningitis caused by Neisseria meningitidis, requires access to hospital care, specific criteria for performing lumbar punctures, as well as access to proper laboratory techniques, which are especially hard for middle- and lower-income countries to access [1].

To diagnose acute bacterial meningitis, the bacteria must be isolated from sterile body fluid (this is where the lumbar puncture comes in to play). Once a cerebrospinal fluid sample (/specimen) is obtained, the sample is cultured on a chocolate agar plate (look exactly at what the organism metabolizes, and how this works in the body) [7].

In order to be entirely certain that an individual has contracted acute bacterial meningitis, a lumbar puncture, also known as a spinal tap, must be performed. In this procedure, a needle is placed through the lower back and into the spinal cord, where spinal fluid is collected to determine if the meninges are truly inflamed as a result of bacteria (or in some cases viral) meningitis [5].

Because of the severity of the disease upon its onset, it needs to be treated as soon as possible with antibiotics. In a review of autopsy data, many deaths caused by N. meningitidis occurred within 12-24 hours of the onset of symptoms. After an individual has been treated with antibiotics, inflammation occurs because the bacteria are being broken down. To treat the inflammatory response, administration of corticosteroids can help to decrease the amount of swelling occurring the brain and the resultant increased pressure within the skull [6].

To administer antibiotics, there are three things that should be accounted for: the trends in certain areas/regions in terms of health and disease, the patient age, and if any other factors will affect the ability of the patient to be treated (if they have other health complications, cancer, etc...) [8].

There has been a sufficient lack of randomized studies used to evaluate treatment strategies, especially in lower-income countries.

Additionally, the progress of discoveries allowing for the treatment of acute bacterial meningitis seem only to help those in higher-income areas, where those in lower-income areas are suffering in terms of their available medical resources. There needs to be a much higher prevalence of affordable alternatives of treatment options, especially for those lacking the resources to be treated by expensive vaccines [4].

Figure 4. The cell wall structure of Neisseria meningitidis. Significance lies in the capsular polysaccharides and outer membrane proteins that are the current targets of vaccine research (http://www.chori.org/Principal_Investigators/Moe_Gregory_R/moe_research.html).

Progress and challenges in acute bacterial meningitis

Unfortunately, the diversity of global patterns of meningococcal disease is greater because of the higher likelihood of an epidemic. For those that survive the disease, they are fortunate in that Neisseria meningitidis has a lower risks associated with its contraction than the other two bacteria that cause acute bacterial meningitis (Streptococcus pneuomoniae and Haemophilus influenzae). When looking at cases of meningococcal meningitis across the globe, Africa records the highest incidence of the disease with greater than 100 (endemic, where the disease is found only in particular location or region), and greater than 1000 (epidemic, when there is an outbreak of a new disease that affects an abnormally large amount of the population) per 100,000 people in a population per year. The lowest incidence region is Europe with 1-2 (endemic) and 2-10 (epidemic) per 100,000 people per year. Fortunately, no deaths have been reported (2012), but in terms of morbidity, 7% of survivors experience major long-term sequelae, as discussed above.

With the mortality rate remaining relatively high despite advances in treatment of acute bacterial meningitis, there are several issues that complicate the medical community’s ability to diagnose and treat the disease. Because meningococci can easily circumvent the body's response to the infection by the exchange of genetic material, there has been concern that meningococci (as well as pneumococci of Streptocococcus pneumoniae) could replace their usual serotypes by responding to a conjugate vaccination, particularly where there is a significant number of individuals with the disease/a significant proportion of the population that has contracted the disease, and it is furthermore easily transferrable [1,4]. Lack of surveillance in low-income countries allows for a higher prevalence of the deadly infection.

The amount of protection time that is given by a vaccine, as well as a vaccine's ability to create immunity to an infection, or particular antibodies, while an individual is exposed to it, has created controversy in the treatment of acute bacterial meningitis [4]. There has been a lot of discussion regarding the need for additional booster doses for conjugate meningococcal vaccines, as their has been evidence that serogroup B antibody concentrations decrease significantly for children provided their first dose at (and after) 1 year of being vaccinated [1].

According to D. Van De Beek and colleagues, there are two particular issues relating to bacterial meningitis [3,8]. One of the issues pertains to making sure that the delivery of the particular drug is as effective as possible, in terms of cost, amount of material required, the reactivity, etc... Secondly, the effectiveness of the antibiotics administered to a given patient is very important. The given antibiotic must penetrate the blood-brain barrier in order for it to be a successful treatment. This administration is according to how much the blood-brain barrier was disrupted by inflammation (see the section regarding pathophysiology above), as well as the size, charge, interaction with the membrane, ability to bind with proteins, and the interaction with pumps that move material outside the body [3,8]. The clinical effectiveness of the antibiotic is furthermore dependent upon the antibiotic cerebrospinal fluid concentration and its ability to combat the bacteria that caused the infection. Furthermore, the antibiotics require a proper amount of time to eradicate all of the bacteria that caused the infection and to prevent the disease from recurring [3,8]. However, it is hard to predict the timescale to use, depending on the bacteria causing the disease (as mentioned before, there are other bacteria besides Neisseria meningitidis that cause acute bacterial meningitis), how severe the disease is, in addition to the antimicrobial agent used. In high-income countries, many authorities recommend a minimum of 7 days of treatment for meningococcal meningitis.

Designing protein-based meningococcal vaccines is difficult due to the increased amount of genetic and antigenic diversity of Neisseria meningitidis. Because this bacterium is readily able to allow for genetic transformation and recombination, it has a variable population structure that reflects its accumulated mutations and horizontal genetic exchange. Therefore, there is a lot of variability in terms of the virulence of the meningococci, and thus there needs to be a vaccine that allows for complete coverage of both “hyperinvasive” bacterial lineages, as well as those bacteria who are commensalists [11].

Discrepancies in treatment

Based on available resources

Based on genetic factors

Conjugate versus Polysaccharide Vaccines

Current Treatment Options

Vaccinations for Prevention of the Disease

I

References

[6] "Bacterial Meningitis." Qiagen: Sample & Assay Technologies. 2013. Web. 22 Apr. 2013. <http://www.qiagen.com/products/genes%20and%20pathways/Pathway%20Details.aspx?pwid=50>.

[9] Bertrand, Sophie, Francoise Carion, Rene Wintjens, Vanessa Mathys, and Raymond Vanhoof. "American Society for MicrobiologyAntimicrobial Agents and Chemotherapy." Evolutionary Changes in Antimicrobial Resistance of Invasive Neisseria Meningitidis Isolates in Belgium from 2000 to 2010: Increasing Prevalence of Penicillin Nonsusceptibility. Web. 22 Apr. 2013. <http://aac.asm.org/content/56/5/2268.full.pdf html>.

[2] Chaudhuri, A. "Adjunctive Dexamethasone Treatment in Acute Bacterial Meningitis." The Lancet Neurology 3.1 (2004): 54-62. Print. <http://www.sciencedirect.com/science/article/pii/S1474442203006239>.

[11] Feavers, Ian M., and Mariagrazia Pizza. "Meningococcal Protein Antigens and Vaccines." Elsevier (2009): B42-50. ScienceDirect. Web. 15 Apr. 2013. <http://www.sciencedirect.com/science/article/pii/S0264410X09006665>.

[3] Johnson, Steven, Lionel Tan, Stijn Van Der Veen, Joseph Caesar, Elena Goicoechea De Jorge, Rachel J. Harding, Xilian Bai, Rachel M. Exley, Philip N. Ward, Nicola Ruivo, Kaushali Trivedi, Elspeth Cumber, Rhian Jones, Luke Newham, David Staunton, Rafael Ufret-Vicenty, Ray Borrow, Matthew C. Pickering, Susan M. Lea, and Christoph M. Tang. "Design and Evaluation of Meningococcal Vaccines through Structure-Based Modification of Host and Pathogen Molecules." PLOS Pathogens 8.10 (2012): 1-13. PLOS. Web. 16 Apr. 2013. <http://www.plospathogens.org/article/info%3Adoi%2F10.1371%2Fjournal.ppat.1002981>.

[1] McIntyre, Peter B., Katherine L. O'Brien, Brian Greenwood, and Diederik Van De Beek. "Effect of Vaccines on Bacterial Meningitis Worldwide." The Lancet 380 (2012): 1703-711. Print.<http://www.sciencedirect.com/science/article/pii/S0140673612611878>.

[7] "Neisseria Meningitidis." Wikipedia. Wikimedia Foundation, 22 Apr. 2013. Web. 22 Apr. 2013. <http://en.wikipedia.org/wiki/Neisseria_meningitidis>.

[10] Peterson, D. C., G. Arakere, J. Vionnet, P. C. McCarthy, and W. F. Vann. "Characterization and Acceptor Preference of a Soluble Meningococcal Group C Polysialyltransferase." Journal of Bacteriology 193.7 (2011): 1576-582. Print. <http://jb.asm.org/content/193/7/1576.full>.

[4] "Progress and Challenges in Bacterial Meningitis." The Lancet 380 (2012): 1623-624. Web. 15 Apr. 2013. <http://www.sciencedirect.com/science/article/pii/S014067361261808X>.

[8] Van De Beek, Diederik, Matthijs C. Brouwer, Guy E. Thwaites, and Allan R. Tunkel. "Advances in Treatment of Bacterial Meningitis." The Lancet 380 (2012): 1693-702. 10 Nov. 2012. Web. 14 Apr. 2013. <http://www.sciencedirect.com/science/article/pii/S0140673612611866>.

[5] "What Are the Facts About Meningitis?" Meningitis Symptoms. Web. 13 Apr. 2013. <http://www.chacha.com/gallery/4869/what-are-the-facts-about-meningitis/46227>.

[12] "Neisseria Meningitidis." Microbe Wiki. N.p., n.d. Web. 8 May 2013. <http://microbewiki.kenyon.edu/index.php/Neisseria_meningitidis>.

Edited by student of Joan Slonczewski for BIOL 238 Microbiology, 2013, Kenyon College.