Neisseria Microbiology PDF

Summary

This document provides a detailed overview of Neisseria, including its morphology, culture conditions, and growth characteristics. It also discusses important aspects like pathogenesis and diagnostic tests.

Full Transcript

**1. Neisseria**

\- Gram-negative cocci, occur in pairs (diplococci).

*Neisseria gonorrhoeae* (**gonococci**) and *Neisseria meningitidis*
(**meningococci**) are exclusively pathogenic for humans and typically
are found associated with or inside polymorphonuclear cells (PMNs).

**Morphology and Identification**

**A. Typical Organisms**: Neisseria is (aerobic, Gram-negative,
nonmotile diplococcus, approximately 0.8 µm in diameter. Individual
cocci are **kidney** **bean** shaped; when the organisms occur in pairs,
the flat or **concave sides** are **adjacent**.

**B. Culture**: -grow on **sheep blood agar**, **chocolate agar**, and
**selective agar media** (eg, modified Thayer-Martin agar, Martin-Lewis
agar and New York City medium).

*N. meningitis* grows on **sheep blood agar** as well as selective
media.

 *N. gonorrhoeae* **requires** **enriched**
**chocolate** agar and/or selective media for optimal growth.

The selective media contain:

-**vancomycin** (suppression of Gram-positive bacteria).

\- **colistin** (suppression of Gram-negative bacteria).

\- and other **inhibitory** substances to suppress the growth of many of
the commensal microorganisms from these clinical sites.

(*N. gonorrhoeae, N. meningitides*, and *N. lactamica* are
**colistin**-**resistant**, and are therefore able to grow on these
selective media).

**C. Growth Characteristics**: The neisseriae grow best under
**aerobic** conditions; however, some Neisseria species (eg, *N.
gonorrhoeae*) are capable of growing under **anaerobic** conditions as
well. The neisseriae produce **acid** but **not gas** by
**[oxidation]** of various carbohydrates ([not by
fermentation]!); the **oxidase** test is hence a key test
for identifying neisseriae. Furthermore, all Neisseria species, with the
exception of *N. elongata*, are **catalase** **positive**.

Neisseria species are grow **best** on media containing complex organic
substances, such as **heated** **blood**, **hemin**, and **animal**
**proteins**, and in an atmosphere containing **5% CO~2~**. These
organisms are also rapidly killed by **drying**, prolonged exposure to
**sunlight**, **moist** **heat**, and many **disinfectants**. They
produce **[autolytic]** **[enzymes]** that
result in rapid **[swelling]** and **[lysis]**
in vitro at **25**°C and at an **alkaline** pH.

*NEISSERIA GONORRHOEAE* Gonococci oxidize only **[glucose]**
and differ antigenically from the other neisseriae.

**Antigenic Structure** *N. gonorrhoeae* is antigenically heterogeneous
and **capable** of **changing** its surface structures in vitro---and
presumably in vivo---to avoid host **defenses**. Surface structures
include the following.

A. **Pili (Fimbriae):** Pili are the hairlike appendages. They
**enhance** **attachment** to host cells and **resistance** to
phagocytosis. They are made up of stacked **pilin** proteins

B. **Por:** Por protein extends through the gonococcal cell membrane.
It forms **pores** in the surface through which some **nutrients**
**enter** the cell. Por proteins may impact **intracellular**
killing of gonococci **within** neutrophils by **preventing**
**[phagosome-- lysosome fusion]**.

C. **Opa Proteins: adhesion** of gonococci within **colonies** and in
**attachment** of gonococci to **host cell receptors**.

D. **Rmp (Protein III): is a** reduction-modifiable protein (Rmp) and
changes its apparent MW when in a **reduced state**. It
**associates** with Por in the formation of pores in the cell
surface.

E. **Lipooligosaccharide:** In contrast to the enteric Gram-negative
rods, gonococcal lipopolysaccharide (LPS) does not have long
O-antigen side chains and is called a lipooligosaccharide (LOS).
**Toxicity** in gonococcal infections is largely attributable to the
**endotoxic** effects of LOS.

F. **Other Proteins:** Lip (H8) is a surface exposed protein that is
heat modifiable like Opa. The Fbp (ferric-binding protein).

A. **Specimens: Pus** and **secretions** are taken from the urethra,
cervix, rectum, conjunctiva, throat, or synovial fluid for culture
and smear. **Blood** culture is necessary in systemic illness.

B. **Smears**: Gram-stained smears of urethral or endocervical exudates
typically reveal many diplococci within PMNs, therefore providing a
presumptive diagnosis.

C. Culture Immediately after collection, pus or mucus is streaked on
enriched selective medium (eg, modified Thayer-Martin medium
\[MTM\]) and incubated in an atmosphere containing 5% CO~2~ at 37°C.
To avoid overgrowth by contaminants, selective media contain
antimicrobial drugs (eg, vancomycin, colistin, nystatin, and
trimethoprim). If immediate incubation is not possible, the specimen
should be placed in a CO~2~ - containing transport-culture system.
Forty-eight hours after culture, identified presumptive
identification can be achieved by the organisms' appearance on a
Gram-stained smear and by a positive oxidase test. The definitive
species level of the sub-cultured bacteria may be determined by
their ability to produce acid from certain carbohydrates by
oxidation; the only carbohydrate used by *N*. *gonorrhoeae* is
glucose

**NEISSERIA MENINGITIDIS**

**Antigenic Structure**

Capsular polysaccharides: The six most important serogroups
associated with disease in humans, worldwide, are A, B, C, X, Y, and
W-135. Incorporation of human sialic acid derivatives such as NANA
into the meningococcal capsules allows the organism to be overlooked
by the host immune system (often referred to as "molecular
mimicry").

The outer membrane of *N. meningitidis* consists of proteins and LPS
that play major roles in organism virulence. There are two porin
proteins (Por A and Por B), interact with host cells.

The opacity proteins (Opa) are comparable to Opa of the gonococci
and play a role in attachment. Meningococci are piliated and these
structures initiate binding to nasopharyngeal epithelial cells and
other host cells such as endothelium and erythrocytes. The lipid A
disaccharide of meningococcal LPS is responsible for many of the
toxic effects found in meningococcal disease. The highest levels of
endotoxin.

**Pathogenesis, Pathology, and Clinical Findings**:

The **nasopharynx** is the portal of entry. There, the organisms
**attach** to epithelial cells with the aid of **pili**; they may
form part of the transient microbiota without producing symptoms
and/or disease. **Invasive** **meningococcal** **diasease** (IMD)
occurs in only a small number of individuals who acquired the
organism and are transient carriers; infants and adolescents have
the highest incidence of IMD in developed countries. From the
**nasopharynx**, organisms may reach the **bloodstream**, producing
meningococcal **bacteremia**; the initial symptoms during this stage
of the actual infection may be similar to those of an upper
respiratory tract, "flu-like" infection, but IMD quickly ensues. IMD
typically presents as **meningitis**, **sepsis** (ie,
meningococcemia), or as a combination of both. **Meningitis** is the
most common complication of menigococcal bacteremia. It usually
begins suddenly with an **intense headache**, **vomiting**,
**photophobia**, **confusion**, and **stiff neck**; it may progress
to **coma** within a few hours. Fulminant meningococcemia is more
severe, presenting with a high **fever** and a **hemorrhagic**
**rash**; the patient may also develop disseminated intravascular
coagulation and ultimate circulatory collapse with bilateral
**hemorrhagic necrosis** of the adrenal glands with subsequent
adrenal failure (Waterhouse-Friderichsen syndrome). In meningitis,
the meninges are acutely inflamed, with thrombosis of blood vessels
and exudation of polymorphonuclear leukocytes, so that the surface
of the brain is covered with a thick purulent exudate. The exact
mechanisms that transform an asymptomatic colonization of the
nasopharynx into meningococcal bacteremia, subsequently leading to
meningococcemia and meningitis, are not very well understood.

**Diagnostic Laboratory Tests**

**A. Specimens**: The typical specimens for isolation of *N.
meningitides* include blood for culture and cerebrospinal fluid
(CSF) for smear and culture. Puncture material or biopsies from
petechiae may be taken for smear and culture. Nasopharyngeal swab
cultures are suitable for carrier surveys.

**B. Smears**: Gram-stained smears of the sediment of centrifuged
spinal fluid or of petechial aspirate often show typical neisseriae
within polymorphonuclear leukocytes or extracellularly.

**C. Culture**: Although neisseriae are inhibited by certain **toxic
factors** present in media and **polyanethole sulfonate**
(anticoagulant) present in commercial blood culture broths, this
seems to be of a lesser problem for the ability to recover *N.
meningitis* from blood cultures, compared to *N. gonorrhoeae*. CSF
specimens are plated on sheep blood agar and chocolate agar and then
incubated at 37°C in an atmosphere of 5% CO~2~. A MTM agar favors
the growth of neisseriae, inhibits many other bacteria, and is used
for nasopharyngeal cultures. Colonies of *N.* *meningitidis* are
gray, convex, and glistening, with entire edges; a positive oxidase
test together with a Gram-stain showing Gram-negative diplococci
provides presumptive organism identification. Spinal fluid and blood
generally typically yield pure cultures that can be further
identified by carbohydrate oxidative reactions and subsequent
agglutination with type-specific or polyvalent serum.

**D. Serology**: Antibodies to meningococcal polysaccharides can be
measured by latex agglutination or hemagglutination tests or by
their bactericidal activity.