L11 Medically Important Bacteria Part 1 PDF

Summary

This document is a university lecture/class notes/set. It contains information about medically important bacteria, part 1. focusing on Gram-negative bacteria. The document covers their characteristics, classification, and the diseases they cause. Learning outcomes and relevant unit topics are included.

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Intro to Agricultural Microbiology

PHAR2921 COMMONWEALTHOFAUSTRALIA
Copyright
Regulation
WARNING
Medically-important This material has been reproduced and communicated to youbyor
onbehalf of the University of Sydney pursuant to Part VBof the
Bacteria Part 1. CopyrightAct 1968(the Act).
Thematerial in this communication may be subject to copyright
Gram negatives under the Act. Any further reproduction or communication of this
material by you may be the subject of copyright protection under
theAct.
Donotremovethis notice

Dr. Angela Sun
[email protected]

Page 345
Diversity of bacteria – Gram negatives
Learning Outcomes. Be able to…

Discuss the importance of bacteria in medicine and
human disease, with specific reference to examples

Name eight different medically-relevant Gram-
negative bacteria, and describe:

- their phylogeny

- their microscopic morphology

- their normal habitat

- the human disease(s) caused

- any distinctive/ unique features Page 346
Diversity of bacteria – Gram negatives
Relevant Unit of Study learning outcomes

LO1: understand the microbial world and its relationships
with other forms of life and the environment

LO2: describe and understand organism structures,
functions, and bio-relationships (in humans and the
environment) of major microbial groups (e.g., bacteria,
fungi, viruses, protozoa)

LO3: for each microbial group, describe the pathological
processes of infection in humans

Page 347
Revision: How are Bacteria Classified?
Phenetic (phenotype):
– Gram reaction and morphology
– Carbon sources, energy sources
– Electron acceptors (eg. aerobic/anaerobic)

Phylogenetic (genotype):
– Ribosomal RNA sequence
– Other DNA, RNA, protein sequence

Page 348
Classification of bacteria…
In *this* 2-lecture set, the bacteria will be organised by
their phylogeny – a systematic approach

Phenotypes will be discussed also, where this is
important for identification or pathogenicity

In some cases, systematics agrees with phenotype,
eg. all endospore formers are Gram positive

In other cases, the classifications disagree,
eg. anaerobic growth occurs in diverse bacteria

Both approaches are useful – it depends on the
question being asked ! Page 349
 Phylogenetic tree of the Bacteria
Tree based on alignment
 
Bacteroidetes

of 16S rRNA sequences Bacteroidetes
Spirochaetes Verrucomicrobia
Deinococcus/ Green sulfur
Thermus bacteria Planctomycetes
Green non-sulfur
bacteria Chlamydia
Cyanobacteria

Thermotoga Actinobacteria
Firmicutes

Thermodesulfobacterium Nitrospira

 Proteobacteria 
Aquifex


 
Bacterial names shown are phylum -level groups Page 350

Tree adapted from Brock
Diverse Gram-negative bacteria can cause disease
Proteobacteria Phylum
Escherichia
Genus
Salmonella
Vibrio
Pseudomonas
Neisseria
Rickettsia

Bacteroidetes
Bacteroides

Spirochaetes
Treponema Page 351
Escherichia
Facultative anaerobic, heterotrophic, G-ve rods

Found in gut of humans and animals

Part of family Enterobacteriaceae: contains many other
pathogens: Salmonella, Klebsiella, Yersinia

Widely used in microbiology as a model organism (E.
coli)

Motile by peritrichous flagella

Polar flagellum Peritrichous flagella.
eg. Pseudomonas eg. E.coli Page 352
Escherichia

E.coli
Most strains are normal flora, and beneficial
eg. E.coli K12 biosynthesizes vitamin K

Some strains pathogenic; these are food or water-
borne pathogens

O157 – infection by animal food, O111

Symptoms - diarrhoea, fever

Virulence factors: endotoxin (all G-), enterotoxin
(some)
Salmonella
Facultative anaerobic, heterotrophic, G-ve rods

Normal flora in animal gut, pathogenic to humans

S.enterica: food-borne infection, self-limiting diarrhoea

S.typhi: water-borne, typhoid fever, potentially fatal

Virulence factors: endotoxin, enterotoxin, cytotoxin

Salmonella enterica
False-colour transmission
electron micrograph

peritrichous
flagella → motile!
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Identifying Enterobacteriaceae
Selective + differential agars for identifying Enterobacteriaceae

E.coli on XLD
Salmonella on XLD
- lactose positive
- lactose negative
- H2S negative
- H2S positive
Vibrio
Facultative anaerobic, heterotrophic, G-ve curved rods
Motile, various flagella arrangements
Habitat is primarily marine, but can cause gut infection

V. cholerae
The most pathogenic Vibrio species
– causes cholera: severe diarrhoea -> transmission
– virulence factor:
cholera toxin (an
exotoxin)
– common in sewage
contamination Page 355

TEM of V.cholerae; curved cell, polar flagellum, bundles of pili
Vibrio
V. cholerae
Transmission usually by faecal contamination of water
→ How do the symptoms of cholera help its transmission?
V.cholerae is more rarely a food-borne disease (seafood)
SMH 16/3/98

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Pseudomonas
Aerobic, heterotrophic G-ve rods, motile (polar flag.)
Ubiquitous in soil and water, opportunistic pathogens
Large genome (6 Mb) → Metabolically versatile
P. aeruginosa
Nosocomial infection (hospital acquired) – esp. burns.
Virulence factors: innate antibiotic resistance
(low membrane permeability), haemolysin,
proteases

P.aeruginosa infection
 from contact lens
in burned skin tissue →
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Pseudomonas

P. aeruginosa
Virulence factors
innate antibiotic resistance (low membrane
permeability)
Haemolysin
Proteases

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Pseudomonas
P. aeruginosa Aust. Doctor 19/10/01
eg. Nosocomial infection:
P. aeruginosa transmitted *
from nurse’s finger nail to
many heart surgery patients

Metabolic versatility helps
P.aerug. to colonise diverse
niches (eg. fingernail, heart)

* P.aeruginosa infections
are common, but person-
person transmission is rare
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Neisseria
Aerobic, heterotrophic, G-ve diplococci
Habitat: mammalian mucous membranes
Carrier - Back of throat, nose
Pathogenic species
– N. gonorrhoeae → Causes ???
– N. meningitidis → Causes ???

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https://microbenotes.com/differences-between-neisseria-meningitidis-and-
neisseria-gonorrhoeae/
Neisseria
Virulence factors
– capsule: evasion of immune response
– fimbriae: adhesion to tissues
Pathogenic species
– N. gonorrhoeae → gonorrhoea
– N. meningitidis → meningitis (meningococcal disease)

N.meningitidis cells adhering to
cilia in the respiratory tract

SEM
Neisseria
N.meningitidis
Meningitis: inflammation of meninges (membrane around
brain) → fever, rash, headache, confusion, death
Serious, rapidly progressing disease – needs rapid
diagnosis and treatment (antibiotics)
Analysis: microscopic examination of CSF
Crystal violet stain: both white blood cell
nuclei and Neisseria cells appear purple

Neisseria

Lumbar puncture to
white bloPao d cell
ge 360

obtain cerebrospinal fluid
Neisseria
N.gonorrhoeae
Gonorrhoea: a sexually
transmitted disease
collect urethral
Diagnose by microscopic the happy couple exudate (pus)
examination

Safranin : epithelial cells Neisseria
and Neisseria appear pink

Note adherence of epithelial
Neisseria cells to the cell
epithelial cells

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Rickettsia
Aerobic, heterotrophic, G-ve, coccobacilli

Cannot be grown in vitro – only in tissue culture.

Bacteria are very dependent on host metabolism

Intracellular parasites of arthropods – eg. fleas, lice, ticks

Small ‘degenerate’ genome (1 Mb) → specialised lifestyle

Related to mitochondrion – significance?

Zoonotic

Rickettsia inside a
eukaryotic cell (from tick)
Light micrograph, with
carbol fuschin stain
Page 362 1 m
 Rickettsia
Transmission to humans occurs via bites or faeces of
arthropods → various fever diseases

R.prowazekii → epidemic typhus
– headache, fever, rash (up to 50% mortality)
– overcrowded conditions → transmitted by body louse
– virulence factors: adhesin, phospholipase

Human body louse Pediculus humanus
is a vector for spreading R.prowazekii

Page 363

SEM
Bacteroides
Obligate anaerobe, heterotrophic, G –ve rods
Normal flora, but can be opportunistic pathogens
Bacteroides are most abundant cells in human body
Several beneficial species: digestion of carbohydrates,
exclude pathogens by competition (Salmonella)

Bacteroides
Gram stain Capsule stain→

Page 364
Bacteroides
B.fragilis
Opportunistic pathogen: cause infection if it escapes the
gut eg. abcesses, septicemia, appendicitis
Virulence factors: capsule, antibiotic resistance

Salyers et al.(1995) J.Bact 177:5727
donor cell recipient cell

Tcr: tetracycline resistance
Exc: excision Tra: Transfer Int: integration
Treponema

Anaerobic, heterotrophic, G-ve, spirochaetes.

Obligate parasites, require animal cells for growth

Dark field microscopy
of spirochaetes

Spirochaete
cell structure

Page 366
 Use axial filament for structure and corkscrew motility

Great to move through viscous fluid
Treponema
T.pallidum
Causes Syphilis: a sexually transmitted disease (STD)

Effects: 10: chancres, 20: rash,
30: nervous system damage
Can’t be grown in standard media
‘Degenerate’ small genome (1 Mb)
they’re at it again!

collect sample from
Page 367

Silver stain of T.pallidum cells chancres (sores)
References
Prescott ‘Microbiology’, 6th ed. Ch 21-22
Madigan et al. ‘Brock. Biol.of Microorgs’ Ch 12, 26, 27

Picture credits
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Picture credits…cont…
commtechlab.msu.edu/sites/dlc-me/zoo/zdrs0232.jpg
www.apsnet.org/online/Archive/1998/cepacia.jpg
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Schultz et al. (1999) Science 284:493

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