BIO-333 Chapter 23 Guide 7e PDF

Summary

Chapter 23 Guide 7e from BIO-333 defines pathogens and microbiota, primary and opportunistic pathogens, and categories for successful pathogens. It discusses Gram-positive and Gram-negative bacteria, LPS, PAMPs, facultative and obligate pathogens, virulence genes, and virulence factors. It covers horizontal gene transfer, bacterial shapes, and pathogenic mechanisms.

Full Transcript

Name\_Isabel Hernandez Carrillo\_ BIO-333 Chapter 23 Guide 7e

1\. (pgs. 1313-1315, fig. 23-1 and 23-2) Define pathogen and microbiota.

- Pathogen- An organism, cell, virus, or prion that causes disease.

- Exploit the attributes of their host's cells in order to infect
them.

- Microbiota- Collective of microorganisms that resides in or on an
organism.

2\. (pgs. 1314-1315) Define primary and opportunistic pathogen. List the
four categories in which a pathogen must be able to do to be successful.

- Primary pathogen- Cause overt disease in most healthy people. Some
cause acute, life-threatening epidemic infections and spread rapidly
between hosts; other potential primary pathogens may persistently
infect a single individual for years w/out causing overt disease,
the host often being unaware of being infected.

- Opportunistic pathogen- Microbes of normal flora that can cause
disease only if the immune systems are weakened/if they gain access
to a normally sterile part of the body.

- Four categories in which a pathogen must be able to do to be
successful:

- Enter the host (break epithelial barrier)

- Find a nutritionally compatible niche in the host's body

- Avoid subvert/circumvent the host's innate and adaptive immune
responses

- Replicate using host resources and exit ones host and spread to
another

3\. (pgs. 1315-1317, fig. 23-3) Describe Gram-positive and Gram-negative
bacteria. What are LPS and PAMPs. Define facultative and obligate
pathogens. What are virulence genes and virulence factors?

- Gram (+): Bacteria that stain positive with Gram stain because of a
thick layer of peptidoglycan cell wall outside their inner (plasma)
membrane.

- Gram (-): Bacteria doesn't stain w/Gram stain as a result of having
a thin peptidoglycan cell wall outside their inner (plasma) membrane
that is covered by a second lipid-containing outer membrane.

- Lipopolysaccharide (LPS)- Outer membrane covering the cell wall
of a Gram (-) bacteria.

- Pathogen-associated molecular patterns (PAMPs)- Molecular
structures/molecules that are shared by most pathogenic bacteria
and some viruses.

- Include peptidoglycan and LPS

- Recognized by host immune system

- Both Gram (+) and (-) help protect the cell wall against lysis by
osmotic swelling and it is the target of antibacterial proteins
(lysozyme) and antibiotics (penicillin).

- Facultative pathogens- Bacteria that replicate in an environmental
reservoir such as water/soil and only cause disease if they happen
to encounter a susceptible host.

- Obligate pathogens- Bacteria that can only replicate inside the
host.

- Virulence genes- Contributes to an organism's ability to cause
disease.

- Virulence factors- Protein, encoded by virulence gene, that
contributes to an organism's ability to cause disease.

- They often cluster together on the bacterial chromosome→ large
clusters= pathogenicity islands

A diagram of a cell membrane Description automatically generated

**Figure 23-3: Bacterial shapes and cell-surface structures.**

4\. (pgs. 1317-1319, figs. 23-4 and 23-5) Understand figure 23-5.
Describe horizontal gene transfer and its three mechanisms. To what
degree do we see genomic variation within the same species?

- Horizontal gene transfer: Gene transfer between bacteria/archaea
via..

- 3 mechanisms:

- Natural transformation by released naked DNA

- Transduction (infection) by bacteriophages

- Sexual exchange by conjugation

- Ex: In E. coli a genomic variation of 25% can be seen

- Led to concept bacterial species have a core genome (common to all
isolates w/in species) and larger pangenome (all genes present in
full spectrum of isolates).

- Figure 23-5: A V. cholerae (Gram neg.)
bacterium strand cause a pandemic human disease to those infected
with a mobile bacteriophage (CTX) that encodes two subunits of
toxins that causes diarrhea. First six pandemics were caused by
periodic reemergence of classical strains. Similar to O1 surface
antigen that is part of the LPS. The seventh pandemic was caused by
a strain named El Tor (wave 1) that arose when O1-expressing strain
acquired CTX-1 and RS1 bacteriophages and @ least 2 new
pathogenicity islands. More strains emerged as seen in figure.

5\. (pgs. 1319-1321, figs. 23-6 and 23-7) Describe the mechanisms for how
anthrax and cholera toxins enter host cells. What are secretion systems?

- Cholera toxin: Secreted toxic protein of V. cholerae responsible for
causing water diarrhea associated w/cholera. Comprises an A subunit
w/enzymatic activity and a B subunit that binds to the host-cell
receptors to direct subunit A to the host-cell cytosol.

- The A subunit catalyzes transfer of ADP-ribose moiety from NAD+
to the trimeric G protein Gs. The ADP ribosylation alters the
G-protein A subunit so that it can no longer hydrolyze its bound
GTP causing it to remain in an active state stimulating adenylyl
cyclase indifferently. Result of prolonged elevation of cAMP
concentration w/in intestinal epithelial cells causing a large
efflux of Cl- and water into the gut→diarrhea

- Anthrax: Acute infectious disease of sheep, cattle, and occasionally
humans. Cause by contract w/spores of Gram (+) bacterium. Spore can
germinate and bacteria replications occurs when spores are ingested,
inhaled, or rubbed into breaks in the skin.

- Two toxins with identical B subunits but different A subunits

- B subunit binds to a host-cell surface receptor protein to
transfer two different A subunits into host cells.

- A subunits:

- Lethal factor- Protease that cleaves several activated
members of the MAP kinase kinase family and causes a
large fall in bp and death on entry into the bloodstream
of an animal.

- Edema factor- An adenylyl cyclase that catalyzes
production of cAMP, leading to ion imbalance and
consequent edema in the skin/lung.

- Secretion systems- Secrete effector proteins directly into host cell
targets.

- Two present in Gran (-) bacteria:

- Type III secretion- Delivers effectors proteins into host
cells in a contact-dependent manner.

- Extracellular pathogen= enables bacterium to block
phagocytosis by immune cells

- Intracellular pathogen= promote phagocytosis by
nonimmune cells/survival inside cells.

- Type IV secretion- Related to conjugation apparatus that
bacteria use to exchange genetic material


6\. (pgs. 1321-1322, figs. 23-8 and 23-9) Describe the phenomena of
dimorphism of pathogenic fungi. Describe the lifecycle of malaria
parasites.

- Dimorphism- Ability to grow in either yeast/mold form

- Associated with infection

- Protozoan parasites- Nonphotosyntheic, single-celled, motile
eukaryotic organism.

- Malaria: Protozoal disease cause by 1 of 4 species of Plasmodium,
which are transmitted to humans by the bite of the female Anopheles
mosquito.

- Lifecyle of malaria parasites seen in figure 28-9:

![A diagram of a person\'s life cycle Description
automatically generated](media/image8.png)

**Figure 23-9**

7\. (pgs. 1322-1325, figs. 23-10, 23-11, 23-12, and 23-13, Table 23-1)
Describe the six general categories that viruses rely on to be
successful. Be aware of the different viral morphologies. Describe how a
virus acquires an envelope. Understand figure 23-13.

- Six categories that viruses rely on to be successful:

- Entry to host cell

- Disassembly of the infectious virus particle

- Replication of the viral genome

- Transcription of viral genes and synthesis of viral proteins

- Assembly of viral components into progeny virus particles

- Release of progeny virions

- Single virion that infects a single host cell can produce
thousands of progeny.

- Viral genomes packed in a capsid than is enclosed in an envelope.
The capsid packaged w/viral genome (nucleocapsid) is enclosed by a
lipid bilayer membrane that the virus acquires in the process of
budding from the host-cell plasma membrane w/out disrupting the
membrane/killing the cell.

- Capsid- Protein coat of a virus, formed by self-assembly of one
or more types of protein subunit into a geometrically regular
structure.

- Figure 23-13: ↑ vaccinations/immunization = ↓ disease incidence

A diagram of a virus Description automatically
generated

**Figure 23-10: Viral life cycle**

![A table with text on it Description automatically
generated](media/image12.png)

8\. (pgs. 1325-1328, figs. 23-14, 23-15, and 23-16) Generally describe
how some pathogens enter their host. Describe the entry strategy for
*Yersinia pestis*. How does *H. pylori* persist in the stomachs of its
host and how was this bacterium identified as the cause of stomach
ulcers?

- Pathogenic entry to their host: Wounds in barrier epithelia allows
direct access to unoccupied niches (requires little specialization).
Another way is to enter along with saliva of a biting arthropod.
Vectors used for transmission. Vectors requires that an individual
insect consumes a blood meal from an infected host and transfers the
pathogen to a nonimmune host.

- *Yersinia pestis*: Multiplies in the flea's foregut to form
aggregated masses that physically block the digestive tract. During
each attempt at feeding some of the bacteria in the foregut are
flushed into the bite site thus transmitting plague to a new host.

- *Yersinia pestis*= Bubonic plague

- *H. pylori*: Persists for life as part of the stomach microbiota.
Doesn't cause disease in most individuals but can cause stomach
ulcers and caners. Several adaptations that allow it to colonize the
harsh environment: 1)Uses its flagella for chemotactic motility
allowing it to penetrate mucus and seek out more neutral pH near the
surface of gastric epithelial cells. 2) Produces urease that
converts urea to ammonia to neutralize the acid in its immediate
vicinity.

- ID to cause stomach ulcers because an Australian doc drank pure
culture of bacteria and developed inflammation of the stomach
and therefore developed ulcers.

![Diagram of a structure of a mucus Description automatically
generated](media/image14.png)

**Figure 23-15: Pathogenic** **E. coli** **in**

**the infected bladder of a mouse.**

9\. (pgs. 1328-1329, fig. 23-17) Describe the mechanism for how
*Bordetella pertussis* causes an infection. Describe the mechanism for
how EPEC causes an infection.

- Extracellular pathogens- Disturb host cells and can cause serious
disease without replicating in host cells.

- *Bordetella pertussis*: Colonizes the respiratory epithelium and
circumvents normal mechanism that clears respiratory tract by
expressing adhesins that blind ciliated epithelial cells. Adherent
bacteria produce a toxins that will eventually kill the ciliated
cells, compromising the host's ability to clear the infection.

- *Pertussis toxin*: Has an A subunit that ADP-ribosylates the
alpha subunit of the G protein Gi, causing G protein to remain
in the inactive GDP-bound state and preventing it from
inhibiting activity of host cell's adenylyl cyclase. It
increases the production of cyclic AMP. It can also interfere
w/chemotactic pathway that neutrophils use to seek out and
destroy bacteria.

- *Bordetella pertussis*= Whooping cough

- Enteropathogenic E. coli (EPEC): Uses a type III secretion system to
deliver its own special receptor protein (Tri) into the plasma
membrane of a host intestinal epithelial cell. The extracellular
domain of Tri binds to the bacterial surface protein (intimin)
triggering actin polymerization in host cell. This results in
formation of unique cell-surface protrusion (pedestal). The pedestal
pushes the tightly adherent bacteria from the host-cell membrane
promoting bacterial movement along the cell surface by a mechanism
for actin-based motility of intracellular pathogens.

- It causes diarrhea and can be lethal to young children.

A diagram of a structure Description automatically generated

**Figure 23-17: Interaction of EPEC w/host intestinal epithelial
cells.**

10\. (pgs. 1329-1333, figs. 23-18, 23-19, and 23-20) Describe the
mechanisms for HIV infection. Who might be immune to this virus?
Describe the four viral entry strategies. Describe the zipper and
trigger mechanisms.

- HIV infection: Primary receptor CD4 a cell-surface protein on helper
T cells and macrophages that is involved in immune recognition. CD4
uses a co-receptor that is either CCR5 (receptor for B-chemokines)
or CXCR4 (receptor for a-chemokines). In early stages HIV invariably
use CCR5 and in later stages of infection viruses switch to use
CXCR4 or adapt to use both co-receptors through accumulation of
viral mutations.

- Macrophages are only susceptible to HIV variants that use CCR5
for entry

- Helper T cells most efficiently infected by variants that use
CXCR4

- Immunity?= Individuals with an altered CCR5 gene


- 4 viral entry strategies:

- Fusion w/plasma membrane→ release their RNA genome and capsid
proteins into the cytosol

- Ex: HIV

- Fusion w/membrane after endocytosis→ when endosome acidifies the
virus envelope fuses w/endosomal membrane releasing viral RNA
genome and capsid proteins into cytosol

- Ex: Influenza virus

- Pore formation

- Ex: Poliovirus

- Endosomal membrane disruption→ it then disrupts the endosomal
membrane releasing capsid including its DNA genome into the
cytosol

- Ex: Adenovirus

A diagram of a cell division Description automatically generated

- Zipper mechanism- Bacteria express an invasion protein that binds
w/high affinity to a host-cell receptor

- Trigger mechanism-Bacterium injects a set of effector molecules into
the host-cell cytosol through a type III secretion system.

- Zipper and trigger mechanisms cause polymerization of actin at the
site of bacterial attachment by activating Rho family small GTPases
and Arp2/3 complex.


11\. (pgs. 1333-1334, figs. 23-21 and 23-22) Describe how the eukaryotes
*T. gondii* and *T. cruzi* (two methods) gain entry to their host cells.

- *T. gondii*: Protrudes a microtubule-based structure called a conoid
that facilitates host-entry. At the point of contact the parasite
discharges effector proteins into the host cell from specialized
secretory organelles. One effector inserts into the host-cell plasma
membrane and binds to a parasite surface protein. The other effector
forms a ring-like moving junction in which the parasite squeezes
using forces generated by its own unusual actin and myosin
cytoskeleton. Parasite invades removing host transmembrane proteins
from surrounding membrane so that it eventually protected in a
membrane-enclosed compartment (parasitophorous vacuole) that doesn't
fuse w/lysosomes and doesn't participate in host-cell membrane
trafficking processes.

- Membrane is selectively porous allowing it to take up small
metabolic intermediate and nutrients from host but excluding
macromolecules.

- Cat parasite that cause infection in pregnant and
immunocompromised individuals.

- *T*. *cruzi*: Causes Chagas disease

- Lysosome-dependent pathway- Parasite attaches to the host's
cell-surface receptors including a local increase in Ca2+ in the
host cell's cytosol. Ca2+ signal recruits lysosomes to site of
parasite attachment and then lysosome fuses w/host cell's plasma
membrane. Allows for rapid access to lysosomal compartment.

- Lysosome-independent pathway- Parasite penetrates host-cell
plasma membrane by inducing the membrane to invaginate w/out
lysosome recruitment.

A diagram of a cell cycle Description automatically generated

**Figure 23-21: Life cycle of intracellular parasite T. gondii.**

![A diagram of lysosome Description automatically
generated](media/image20.png)

**Figure 23-22: Two alternative strategies that T. cruzi uses to invade
host cells.**

12\. (pgs. 1334-1335, figs. 23-23 and 23-24) Describe the general
strategies that intracellular pathogens employ to escape the effects of
a lysosome? Describe how *L. monocytogenes* escapes the phagosome.

- Escaping effects of lysosome:

- Some escape endosomal compartment before fusion

- Others remain in the endosome compartment but modify it to no
longer fuse w/lysosome

- Finally, others evolve to weather the harsh conditions in the
lysosomes.

- *L. monocytogenes*: After phagocytosis by the zipper mechanism, it
secretes listeriolysin O that helps disrupt the phagosomal membrane
releasing the bacteria into the cytosol (must be in a low pH). Once
inside it begins to replicate and continues to secrete
listeriolysin O. Until the pH is above 6 making it less active. It
is then rapidly degraded by proteasomes.

A diagram of a lysosomes Description automatically generated

**Figure 23-23: Choices that intracellular
pathogen faces**

13\. (pgs. 1335-1338, figs. 23-25, 23-26, 23-27, and 23-28) Describe how
*M. tuberculosis*, *S. enterica*, and *L. pneumophila* evade the
phagosome. Describe the strategies for viral envelope acquisition.

- *M. tuberculosis*: Prevents maturation of early endosome that
contains the bacteria so the endosome never acidifies/acquires other
characteristics of a late endosome/lysosome.

- *S. enterica*: Acidify and acquire markers of late endosomes and
lysosomes but the bacteria slow the process of phagosome maturation.
This is done by injecting effector proteins through a second type
III secretion system, distinct from that involved in invasion by the
trigger mechanism. Some bacterial effectors activate host kinesin
motor proteins to pull membrane tubules outward from the phagosome
along cytoplasmic microtubules, forming a specialized compartment
called Salmonella-containing vacuole.

- *L. pneumophila*: Use a type IV secretion systems to inject effector
proteins into the phagocyte that modulate the accumulation of
phosphoinositides and the activity of proteins that regulate
vesicular traffic including SNARE proteins and Rab and Arf family
small GTPase. Effectors prevent phagosomes from fusing w/endosomes
that promote its fusion w/ER, converting the phagosome into a
compartment that resembles the rough ER.

- Strategies for viral envelope acquisition through budding from the
cell membrane (plasma membrane, ER, Golgi, or nuclear membrane).

![A diagram of a cell Description automatically
generated](media/image24.png)

**Figure 23-25: Modifications of membrane traffic in host cells by**

**bacterial pathogens to slow/prevent normal fusing of endosome**

**w/lysosomes.**

A diagram of a cell Description automatically
generated

**Figure 23-28: Complex strategies for viral envelope acquisition.**

14\. (pgs. 1338-1339, figs. 23-29, 23-30, and 23-31) Describe the
pathogen strategy for actin-based movement in the host's cytoplasm.
Describe the mechanisms that bacteria employ for actin nucleation.
Describe microtubule-based movement of viruses.

- Pathogens induce nucleation and assembly of host-cell actin
filaments @ one pole of the microbe. Growing filaments generate
force and push the pathogens through the cytosol at rates of up to 1
um/min. New filaments form @ the rear of each pathogen and are left
behind like a rocket tail as microbe advances. Moving bacteria
collide w/membrane and move outward inducing formation of long,
thin, host-cell protrusions w/bacteria @ their tip. Neighboring
cells engulf projections allowing bacteria to enter neighbor's
cytoplasm w/out exposure to extracellular environment.

- Secrete effector proteins that mimic/directly interact w/host cell
actin nucleators such as Arp2/3 complex/formins. Effectively
hijacking host cell machinery to polymerize actin filaments for
their own movement w/in cell.

- Enter sensory neurons @ tips of their axon and move by retrograde
(backward) axonal transport along the axon toward the microtubule
minus end. Transport mediated by attachment of viral capsid protein
to motor protein dynein. Viruses then establish productive/latent
infection in nuclei of neurons of PNS. After they are carried by
anterograde (forward) axonal transport along microtubules to axon
tips w/transport mediated by attachment of different viral capsid
protein to a kinesin motor protein.

- Others associate w/either dynein/kinesin motor proteins to move
along microtubules @ some stage of replication.

- Some alter dynamic assembly and disassembly of microtubules.

![A diagram of a cell Description automatically
generated](media/image30.png)

**Figure 23-29: Actin-based movement**

**of bacterial pathogens w/in and**

**between host cells.**

15\. (pgs. 1340-1341, fig. 23-32) Describe the mechanisms for how
microbes manipulate autophagy. Be familiar with the various ways that
viruses use their host's DNA and RNA replication machinery.

- Manipulation of autophagy:

- Deploy a protective shield that prevents detection of microbe by
host cells

- Secrete bacterial enzymes and harness actin-based movement to
avoid enclosure of autophagosomes.

- Replication inside a membrane-bound compartment that recruits
and fuses w/autophagosomes to deliver nutrients as well as lipid
for other compartment expansion.

- Promotes virus trafficking

- Ways viruses use their host's DNA and RNA:

- Encode proteins that modify host transcription/translation
apparatus to favor synthesis of viral RNAs and proteins over
those of the host cell shifting to synthetic capacity of cell
toward production of new virus particles.

- Initiation process inhibited so host cell ribosomes can be used
more effectively for synthesis of viral proteins. Some encode
endonucleases that cleave off 5' cap from host-cell mRNAs.

- Initiation= Recognition of 5'cap by translation initiation
factors

A diagram of a cell membrane Description automatically generated

**Figure 23-32: Microbial manipulation of autophagy.**

16\. (pgs. 1340-1343, fig. 23-33) What are two main advantages that
pathogens have that enable them to evolve rapidly? Describe the purpose
and function of antigenic variation in trypanosomes.

- Two main advantages:

- Replicate quicky providing great deal of mutational variation
for natural selection to work with.

- Selective pressures act rapidly on genetic variation. Host's
adaptive immune system and modern microbial drugs both which
destroy pathogens fail to change= main sources of selective
pressures.

- Antigenic variation in trypanosomes:

- Antigenic variation- Ability to change antigens displayed on
cell surface.

- T. brucei is covered by single multi variant glycoprotein (VSG)
that express one Vsg gene at any one time. Thereby altered
trypanosomes w/altered VSG escape initial antibody-mediated
clearance, replicate, and cause disease to recur leading to
chronic cyclic infection.

- 20 possible expression sites


17\. (pgs. 1343-1344, figs. 23-34 and 23-35) Why is DNA/RNA replication
so error prone among viruses? How does this speed up their evolution?
Describe the evolution of pandemic strains of the influenza virus.

- Retroviral genomes (RNA genome) lacks proofreading activity of DNA
polymerases. Therefore, leads to high mutation rates that speed up
their evolution by providing constant stream of genetic variation
for natural selection to act upon.

- Influenza virus:

- (Spanish flu) 1918: Virulent form of the virus crosses species
barrier from birds to humans

- H1N1 (hemagglutinin and neuraminidase)

- (Asian flu) 1957: New pandemic when 3 genes replaced by
equivalent genes from different avian virus. New strains wasn't
effectively cleared by antibodies in ppl who had previously
contracted only H1N1 forms of influenza.

- H2N2

- (Hong Kong flu) 1968: Two genes replaced from yet another avian
virus

- H3N2

- (Russian flu) 1977: Resurgence of H1N1 influenza that had
previously been almost completely replaced by N2 strains.

- Might have been due to accidental release of lab strains or
by vaccine study

- 2009: New H1N1 swine virus emerged that had derived 5 genes from
pig influenza viruses, two from avian, and one from human
influenza.

- Most human influenza today is caused by H1N1 and H3N2 strains.

A diagram of a virus Description automatically generated

**Figure 23-35: Model of evolution of pandemic strains of influenza
virus by recombination.**

18\. (pgs. 1344-1346, figs. 23-36 and 23-37) List the antibiotic targets
that display selective toxicity. Describe the three general mechanisms
of antibiotic resistance.

- Target bacterial enzymes that either are distinct from their
eukaryotic compartments/involved in pathways such as cell-wall
biosynthesis that are absent in animals.

- Targets: Cell membrane, DNA gyrase, RNA polymerase, Protein
synthesis (30S and 50S ribosome inhibitors), Folic acid
biosynthesis, and Cell-wall synthesis.

- Three general mechanisms of antibiotic resistance:

- Alter molecular target of drug so that it is no longer sensitive
to the drug

- Produce an enzyme that modifies/destroys the drug

- Prevent drug's access to drug target by...(ex: pumping drug out
of pathogen).

A diagram of a dna gyrase Description
automatically generated

**Figure 23-36: Antibiotic targets.**

19\. (pgs. 1347-1349, figs. 23-38 and 23-39) Define pathogen, microbiota,
normal flora, microbiome, mutualism, commensalism, and parasitism. What
are some of the benefits humans receive from their microbiome?

- Pathogen- Agents that are capable of causing infectious disease.

- Microbiota- Collective of microorganisms that reside in/on an
organism.

- Normal flora- Non-disease-causing microbiota of an organism.

- Microbiome- Combined genomes of various species of a defined
microbiota.

- Mutualism- Ecologic relationship between microbes and their host in
which both microbe and host benefit.

- Commensalism- Ecologic relationship between microbes and their host
in which the microbe benefits but offers no benefit and causes no
harm.

- Parasitism- Ecologic relationship between microbes and their host in
which the microbe benefits to the detriment of the host, as is often
the case for pathogens.

- Benefits humans receive from their microbiome: Assistance
w/digestion, protection against harmful bacteria, immune system
regulation, and production of essential nutrients (ex: vitamins)

A cartoon of a child Description automatically
generated

**Figure 23-38: Sites in human body that harbor the microbiota**

**Include skin, mouth, and digestive tract.**