39. Haemophilus, Legionella, Bordetella

Question 1

species of haemophilus?

Answer 1

H.influenzae (most important childhood pathogen)

H.ducreyi (chanchroid - genital ulcerts)

H.parainfluenzae, H.haemolyticus are COMMENSALS and rarely cause disease

Question 2

haemophilus morphology?

Answer 2

small, non-motile gram negative coccobacilli

encapsulated strains have polysaccharide capsule

• 6 antigenic types (a-f)
• type b (Hib) predominant

many strains unencapsulated (non-typeable - NTHi)

Question 3

haemophilus growth/metab?

Answer 3

• facultative anaerobes

- require blood factors: hemin (X factor) & NAD (V factor) on chocolate agar

Question 4

haemophilus disease?

Answer 4

Unencapsulated: respiratory infections

• Otitis media
• sinusitis
• bronchitis & pna
• COPD

Encapsulated (Hib)

• meningitis in kids
• bacteremia (w/fever & no localization)
• cellulitis (face)
• epiglottitis
• arthritis

Age dependent susceptibility to Hib (6 mos to 3 years)

Question 5

haemophilus virulence factors?

Answer 5

Polysaccharide capsule (antiphagocytic)

• Hib = invasive
• polyribosyl ribitol phosphate (PRP)
• abs to ^ are protective
• C’ deficiency = risk factor

Adherence factors

• Pili (30%)
• non-pilus HMW adhesins in NTHi)

LOS (lipooligosaccharide) (adhere and invade epithelium; modified by addition of terminal sialic acid = molecular mimicry to evade immune response)

Biofilm (promoted by LOS sialylation, possible contributor to CF pathogenesis)

Question 6

haemophilus influenzae diagnosis

Answer 6

1. Culture from sterile site (blood, CSF) on chocolate agar (requires X and V factors)
2. latex particle agglutination test (for Hib capsule)

Question 7

haemophilus influenzae treatment and prevention?

Answer 7

1. amoxicillin for non-invasive infections (unencapsulated)
   - amoxicillin/ clavulanate for resistant strains
2. 3rd gen cephalosporin (cefotaxime or ceftriaxone) for invasive Hib (meningitis)
3. Immunization w/ polysaccharide-protein conjugates
4. New vaccines for nontypeable strains in clinical trial

Question 8

moraxella?

Answer 8

M. catarrhalis is most important species

gram negative coccobacilli

otitis media, sinusitis and conjunctivitis but rarely systemic

dx if otitis media but r/o H.flu or pneumococcus

treat w/ amoxicillin/clavulanate, cephalosporins

Question 9

legionella morphology?

Answer 9

L. pneumophila

• long, thin bacilli on lab media
• short coccobacilli in tissues
• gram (-) staining but poor staining w/common dyes

Question 10

legionella epidemiology?

Answer 10

1. present in natural waters, spread by aerosols (not person-to-person)
2. intracellular parasites of protozoa (amoebae)
3. oubreaks are newsworthy, but minority of cases
4. CA and nosocomial cases
5. elderly & immunocompomosed at highest risk
6. smoking, chronic lung disease, malignancy, and TLR5 polymorphism=RFs

Question 11

legionella diseases?

Answer 11

1. legionnaires Disease
   - severe pna
   - fever, non-productive cough, chills, headache (multi-organ inv. Poss)
   - cerebellar inv,
   - mortality 15-20%
   - low attack rate, no person-person spread
   - Abx therapy required
2. Pontiac Fever
   - flu-like illness (no pna)
   - high attack rate, low mortality (

Question 12

legionella pathogenesis?

Answer 12

Facultative intracellular parasites, multiply in alveolar macrophages

• can bind C’ components (C3b and C3bi) to gain access via C’ receptors on macrophages
• enter by “coiling phagocytosis” into membrane bound phagosome
• inhibit phagosome acidification and phagolysosome fusion, and establish isolated replication vacuole in ER markers (use Dot/Icm type IV secretion system, deplete aa’s and convert to virulent form, to escape from vacuole and cell

Question 13

legionella virulence factors?

Answer 13

1. attachment and entry (C’ binding, type IV pilli)
2. vacuole formation (Dot/Icm type IV secretion system exports plasmid and putative virulence factors into host cell, Dot/Icm mutants are mistargeted to endosomal/lysosomal pathway)
3. intracellular replication
4. Intracellular spread

Question 14

legionella diagnosis?

Answer 14

1. difficult due to poor staining and slow fastidious growth in lab
   - gram stain ineffective
   - gimenez stain for smears
   - dieterle stain for tissue sections
   - culture on BCYE medium (buffer charcoal yeast extract - can’t grow on blood agar)
2. urine antigen test (detects LPS, so only serogroup 1 strains)
3. direct fluorescent Ab test from sputum

Question 15

legionella treatment/prevention?

Answer 15

1. B-lactam abx ineffective (produce B-lactamases)
2. fluoroquinolone (levofloxacin) or macrolide (azithromycin) for CA-pna
3. azithromycin if legionellosis diagnosed
4. prevention involves water system treatment

Question 16

coxiella - morphology, reservoirs, those at risk, pathogenesis, disease, diagnosis, and treatment?

Answer 16

Coxiella burnetti

gram(-) obligate intracellular bacillus most closely related to legionella

animal reservoirs include cattle, sheep, goats - disease seen in farmers, ranchers, veterinarians

env’t stable form w/very low infectious dose by aerosol route

causes Q fever in humans, self-limiting flu-like illness

chronic form includes endocarditis

serological dx (abs to this org’s ags)

treat w/ DOXYCYCLINE

Question 17

bordetella morphology?

Answer 17

B. pertussis most common (whooping cough)

Small, gram negative coccobacilli
- no polysaccharide capsule

Question 18

bordetella growth/metabolism?

Answer 18

• aerobes
• don’t utilize sugars
• slow growth in lab (3-4 days to see colonies)

Question 19

bordetella epidemiology?

Answer 19

highly contagious, spread by aerosols

• maj of cases (of severe disease) in infants
• most deaths in kids

Question 20

bordetella disease?

Answer 20

Catarrhal stage: cold-like sxs, highly infectious, 2 weeks
Paroxysmal stage: severe cough paroxysms, apnea, may cause hypoxia, striking leukocytosis, several other possible complications (pulm and CNS)
Convalescent stage: cough may persist for several months, bacteria absent
Critical pertussis in infants: lymphocytosis, apnea, can progress to respiratory failure and death

Question 21

bordetella pathogenesis?

Answer 21

• bacteria in aerosol droplets adhere to ciliated respiratory epithelium
• grow in upper and lower respiratory tract but do not disseminate
• produce several toxins that cause pathogenic effects (pertussis toxin, adenylate cyclase toxin, tracheal cytotoxin)

Question 22

bordetella virulence?

Answer 22

Pertussis toxin (PTX)
- ADP-ribosylating toxin
- target: G proteins
- inhibits innate immune response
- exacerbates airway inflammation and pathology
- responsible for systemic symptoms (lymphocytosis assoc w/poor outcome in infants)
Tracheal cytotoxin (TCT)
- spontaneously released peptidoglycan fragment
- tetrapeptide-disaccharide
- causes damage and deciliation of epithelial cells in combo w/LPS

Question 23

bordetella dignosis?

Answer 23

Pertussis:

• culture on Bordet-Gengou or Regan-Lowe agar plates
• PCR
• serology (shows lots of case underreporting)

Question 24

bordetella treatment and vaccines?

Answer 24

1. azithromycin to prevent further spread (no benefit to pt)
2. supportive therapy: hydration, nutrition, oxygen (mechanical ventilation, extracorporeal membrane oxygenation in critical infant pertussis)
3. anti-tussive medications ineffective
   Vaccines
   1st generation (1940’s, DTP vaccine, effective, waning immunity by adulthood, reactogenic)
   2nd generation
   (acellular vaccines, Tdap, much less reactogenic but immunity wanes rapidly [3-5 yrs], pertactin/PRN deficient mutant strains now prevalent = vaccine escape mutants)