Staphylococci PDF - Microbiology Lecture Notes 2024-2025

Summary

This document is a lecture about staphylococci, covering various aspects of this bacterial genus, including their species, morphology, and virulence factors. It details the processes of laboratory identification, treatment strategies, and epidemiology related to staphylococcal infections. It's from Ninevah University, College of Medicine, and covers the 2024-2025 academic year.

Full Transcript

Staphylococci

Dr. Mohammed Ameer Abdullah
Ninevah University
College of Medicine
Department of Medical Microbiology
2024-2025
Learning Objectives
Species of Staphylococcus.
Morphology and Culture characteristics of Staphylococcus aureus.
Virulence factors of Staphylococcus aureus.
Laboratory diagnosis of infections caused by Staphylococcus
aureus.
Coagulase-negative staphylococci (CNS).
Treatments.
Staphylococci
The staphylococci are Gram-positive spherical cells, usually arranged in grapelike
clusters.
They grow readily on many types of media, fermenting carbohydrates and
producing pigments that vary from white to deep yellow.
Some are members of the normal microbiota of the skin and mucous membranes
of humans; others cause abscess formation, a variety of pyogenic infections, and
even fatal septicemia.
The genus Staphylococcus has at least 45 species. The most frequently species of
clinical importance are Staphylococcus aureus, Staphylococcus epidermidis
and Staphylococcus saprophyticus.
Staphylococcus aureus, is one of the most common causes of bacterial infections,
and is also an important cause of food poisoning and toxic shock syndrome.
Among less virulent staphylococcal species, Staphylococcus epidermidis is an
important cause of prosthetic implant infections, whereas Staphylococcus
saprophyticus causes urinary tract infections, especially cystitis in women.
GENERAL FEATURES
Staphylococci generally stain gram positive. They are round rather than oval and
tend to occur in bunches like grapes.
Staphylococci are facultatively anaerobic organisms.
They produce catalase, which is one feature that distinguishes them from the
catalase- negative streptococci.
The most virulent species of staphylococcus is S. aureus, almost all isolates of
which secrete coagulase, an enzyme that causes plasma to clot. Other species that
cause disease and lack coagulase are often referred to as Coagulase Negative
Staphylococci.
Staphylococci are hardy, being resistant to heat and drying, and thus can persist
for long periods on fomites (inanimate objects), which can then serve as sources
of infection.
Staphylococcus aureus
Generally, significant host compromise is required for S. aureus infection, such as
a break in the skin or insertion of a foreign body (for example, wounds, surgical
infections, or central venous catheters), an obstructed hair follicle (folliculitis), or
a compromised immune system.
S. aureus disease may be:
1) The result of actual invasive infection, overcoming host defense mechanisms, and
the production of extracellular substances which facilitate invasion;
2) a result of toxins in the absence of invasive infection ; or
3) a combination of invasive infection and intoxication.
Epidemiology
S. aureus is carried by healthy individuals on the skin and mucous
membranes.
Carriers serve as a source of infection to themselves and others; for
example, by direct contact, contamination of fomites or
contamination of food, which can then result in food poisoning.
Pathogenesis
Virulence factors are the genetic, biochemical, or structural features that enable an
organism to produce disease.
The clinical outcome of an infection depends on the virulence of the pathogen
and the opposing effectiveness of the host defense mechanisms.
S. aureus expresses many potential virulence factors. For the majority of diseases
caused by S.aureus, pathogenesis depends on the combined actions of several
virulence factors, so it is difficult to determine the role of any given factor.
1. Cell wall virulence factors:
a. Capsule: Most clinical isolates express a polysaccharide “microcapsule”. The
capsule layer is very thin but has been associated with increased resistance to
phagocytosis.
b. Peptidoglycan: Provides osmotic stability; stimulates production of endogenous
pyrogen (endotoxin-like activity); leukocyte chemoattractant (abscess formation);
inhibits phagocytosis.
c. Teichoic acid : Binds to fibronectin.
d. Protein A: is a major component of the S. aureus cell wall. It binds to the Fc
region of IgG, exerting an anti-opsonin (and therefore strongly antiphagocytic
effect).
e. Fibronectin-binding protein: Fibrinectin-binding protein (FnBP) and other
staphylococcal surface proteins promote binding to mucosal cells and tissue
matrixe.
f. Clumping factor: is a fibrinogen-binding protein present on the surface of
S.aureus that binds to fibrinogen converts it to insoluble fibrin causing the
staphylococci to clump.
2. Enzymes
S. aureus produces an extracellular coagulase, an enzyme like protein that clots
plasma. Coagulase binds to prothrombin; together they become enzymatically
active and initiate fibrin polymerization. Coagulase may deposit fibrin on the
surface of staphylococci, perhaps altering their ingestion by phagocytic cells or
their destruction within such cells.

Catalase this enzyme converts H2O2 to water, and oxygen.

Hyaluronidase (spreading factor) it hydrolyzes hyluronic acid (a component of
extracellular matrix of connective tissues) though promoting the spread of bacteria.

Fibrinolysin, also called staphylokinase, can dissolve fibrin clots.

Lipases that hydrolyze lipids and ensure survival of staphylococci in the sebaceous
areas of the body.

Nuclease (DNAase) that can hydrolyze viscous deoxyribonucleic acid (DNA).
3. Toxins
Cytolytic exotoxins: α, β, γ, and δ Toxins attack mammalian cell (including RBC)
membranes, and are often referred to as hemolysins.
Panton-Valentine leukocidin: This pore-forming toxin lyses Polymorphonuclear
leukocytes (PMNs). Production of this toxin makes strains more virulent.

Superantigen exotoxins: These toxins have an affinity for the T-cell receptor–
major histocompatibility complex Class II antigen complex. They stimulate
enhanced T-lymphocyte response. This major T-cell activation can cause toxic shock
syndrome, primarily by release into the circulation large amounts of T-cell
cytokines, such as interleukin-2 (IL- 2), interferon-γ (IFN-γ), and tumor necrosis
factor-α (TNF-α).
A. Enterotoxins: Enterotoxins are produced by
approximately half of all S.aureus isolates. When
these bacteria contaminate food and are allowed to
grow, they secrete enterotoxin, ingestion of which
can cause food poisoning.
B. Toxic shock syndrome toxin (TSST –1): This is
the classic cause of toxic shock syndrome (TSS).
the toxin are superantigens.
C. Exfoliatin (ET) is also a superantigen. It causes
scalded skin syndrome in children. The toxin attacks
the intercellular adhesive of the stratum
granulosum, causing marked epithelial
desquamation. Cleavage results in loss of the
superficial skin layer.

Virulence factors that may play
a role in the pathogenesis of
staphylococcal infections.
Clinical significance
S. aureus causes disease by infecting tissues. A common
entry point into the body is a break in the skin, which may
be a minute needlestick or a surgical wound.
Another portal of entry is the respiratory tract. For example,
staphylococcal pneumonia is a important complication of
influenza.
The localized host response to staphylococcal infection is
inflammation, characterized by swelling, accumulation of
pus, and necrosis of tissue. Fibroblasts and their products
may form a wall around the inflamed area, which contains
bacteria and leukocytes. This creates a characteristic pus-
filled abscess.
Serious consequences of staphylococcal infections occur
when the bacteria invade the bloodstream. The resulting
septicemia (the presence and persistence of pathogenic
microorganisms or their toxins in the blood) may be rapidly
fatal. Bacteremia (the presence of viable bacteria circulating
in the bloodstream) may result in seeding internal abscesses,
skin lesions, or infections in the lung, kidney, heart, skeletal
muscle, or meninges.
1. Localized skin infections:
The most common S. aureus infections are small, superficial abscesses involving
hair follicles (folliculitis) or sweat or sebaceous glands
Subcutaneous abscesses called furuncles (boils) often form around foreign bodies
such as splinters..
Carbuncles are larger, deeper, multiloculated skin infections that can lead to
bacteremia and require antibiotic therapy and debridement.
Impetigo is usually a localized, superficial, spreading crusty skin lesion generally
seen in children.

folliculitis furuncles Carbuncles Impetigo
2. Deep, localized infections:
These may be metastatic from superficial infections or may result from trauma.
S. aureus is the most common cause of acute and chronic infection of bone
marrow. S. aureus is also the most common cause of acute infection of joint space
in children (Septic arthritis).

3. Acute endocarditis: is caused by injection of contaminated preparations or by
needles contaminated with S. aureus.
4. Septicemia is a generalized infection with sepsis.
5. Pneumonia: S. aureus is a cause of severe, necrotizing pneumonia.
6. Nosocomial infections: S. aureus is one of the most common causes of
hospital-associated infections, often of wounds or bacteremia associated with catheters.
Progressive to septicemia is often a terminal event.

7. Toxinoses: These are diseases caused by the action of a toxin.
Toxinoses caused by S. aureus include:
a. Toxic shock syndrome: TSS results in high fever, rash , vomiting, diarrhea,
hypotension, and multiorgan involvement damage (especially Gastrointestinal , renal
and hepatic).
b. Staphylococcal gastroenteritis: This is caused by ingestion of food contaminated
with enterotoxin-producing S.aureus.
Symptoms, such as nausea, vomiting, and diarrhea, are acute following a short
incubation period (less than 6 hours) and are triggered by local actions of the toxin on
the GI tract rather than from infection.

c. Scalded skin syndrome: This involves the appearance of superficial bullae
resulting from the action of an exfoliative toxin that attacks the intercellular adhesive
of the stratum granulosum, causing marked epithelial desquamation.
Laboratory identification
Identification of an isolate as a staphylococcus relies largely on
microscopic and colony morphology and catalase positivity.
Bacteria stain strongly gram-positive, and are frequently seen in
grapelike clusters.
S. aureus is distinguished from the coagulase-negative
staphylococci primarily by coagulase positivity.
S. aureus colonies tend to be yellow and hemolytic , rather than
gray and nonhemolytic like the coagulase-negative
staphylococci.

S. aureus is also distinguished from most coagulase-negative
staphylococci by being mannitol-positive.
Automated systems such as VITEK can also be used for rapid
identification.
 Catalase Test (Positive )

Coagulase Test (Positive)

Negative
Positive

Positive
Negative

Slide method Tube method
Treatment
Serious S. aureus infections require aggressive treatment, including incision and
drainage of localized lesions, as well as systemic antibiotics. Choice of antibiotics
is complicated by the frequent presence of acquired antibiotic resistance
determinants.

Virtually all community and hospital-acquired S. aureus infections are now
resistant to penicillin G due to penicillinase-encoding plasmids or transposons.

This has required the replacement of the initial agent of choice, penicillin G, by
β-lactamase-resistant penicillins, such as methicillin or oxacillin.

However, increased use of methicillin and related antibiotics has resulted in S.
aureus that is resistant to a number of β-lactam antibiotics, such as methicillin,
oxacillin and amoxicillin. These strains are known as methicillin-resistant
S.aureus.
1. Hospital-acquired methicillin-resistant S. aureus (MRSA):

In recent decades, a high percentage (often in the range of 50 percent) of hospital
S.aureus isolates has been found to be also resistant to methicillin or oxacillin.

Antibiotic resistance is caused by chromosomal acquisition of the gene for a
distinct penicillin binding protein (PBP), PBP-2a. This protein codes for a new
Peptidoglycan Transpeptidase with a low affinity for all currently available β-
lactam antibiotics, and thus renders infections with MRSA unresponsive to β-
lactam therapy.

MRSA infections are associated with worse outcomes, including longer hospital
and intensive care unit stays, and higher mortality rates.

MRSA strains are also frequently resistant to many other antibiotics, some being
sensitive only to glycopeptides such as vancomycin.
2. Community-acquired MRSA (CA-MRSA):

Community acquired MRSA infections were documented in the mid-1990s,
occurring in individuals who had no previous risk factors for MRSA infections,
such as exposure to hospital.

The most common clinical manifestations of CA-MRSA are skin and soft tissue
infections such as abscesses or cellulitis.

Less commonly, CA-MRSA can also cause severe diseases such as necrotizing
pneumonia, osteomyelitis, and septicemia.
3. Vancomycin resistance:
Vancomycin has been the agent of choice for treatment of life-threatening MRSA
S. aureus infections.
in 1997, several MRSAs were isolated that had also acquired low-level
vancomycin resistance.
The incidence of vancomycin resistance has increased steadily, prompting the use
of alternative drugs such as linezolid and daptomycin. These agents have good in
vitro activity against MRSA and most other clinically important gram-positive
bacterial pathogens.
Prevention
There is no effective vaccine against S. aureus.
Infection control procedures, such as disinfection of hands and fomites, are
important in the control of nosocomial S. aureus epidemics.
COAGULASE-NEGATIVE STAPHYLOCOCCI (CNS)
CNS species are important agents of hospital-acquired infections associated with the use of
implanted prosthetic devices and catheters.
Staphylococcus epidermidis
S. epidermidis is present in large numbers as part of the normal flora of the skin.
Despite its low virulence, it is a common cause of infection of implants such as heart
valves and catheters.
vancomycin-resistant isolates have been reported.
S. epidermidis produces an extracellular polysaccharide material called polysaccharide
intercellular adhesin , that facilitates adherence to bioprosthetic material surfaces, such
as intravenous catheters, and acts as a barrier to antimicrobial agents.
Staphylococcus saprophyticus
This organism is a frequent cause of cystitis in women, probably related to its occurrence
as part of normal vaginal flora. It tends to be sensitive to most antibiotics, even penicillin
G.
S. saprophyticus can be distinguished from S. epidermidis and most other coagulase-
negative staphylococci by its natural resistance to novobiocin.
it is concluded that the Van@citrate-AgNP is more potent than the single entity
vancomycin towards both S. aureus and E.coli
Thank you