Deck 14: The Innate Immune Response

A) Skin
B) Antibody
C) Inflammation
D) Fever
E) Mucus membranes

A) specific antimicrobial factors.
B) immune enzymes.
C) nonspecific antimicrobial factors.
D) cytokines.
E) antipeptides.

A) macrophages.
B) monocytes.
C) mast cells.
D) neutrophils.
E) eosinophils.

A) Bacteria
B) Amoeba
C) Red blood cells
D) Starfish larvae
E) Humans

A) are cytokines, are embedded in cellular membranes, AND are part of adaptive immunity.
B) each recognize a specific "danger" molecule AND are cytokines.
C) are embedded in cellular membranes AND are part of adaptive immunity.
D) each recognize a specific "danger" molecule AND are embedded in cellular membranes.
E) each recognize a specific "danger" molecule AND are part of adaptive immunity.

A) is required by microorganisms.
B) binds to lactoferrin.
C) is necessary for the functioning of some enzymes.
D) binds to transferrin.
E) All of the answer choices are correct.

A) adaptive immunity.
B) innate immunity.
C) autoimmunity.
D) irregular immunity.
E) secondary immunity.

A) erythrocytes.
B) platelets.
C) leukocytes.
D) lymphocytes.
E) chondrocytes.

A) lymphocytes.
B) monocytes.
C) eosinophils.
D) neutrophils.
E) leukocytes.

A) Tear flow
B) Antibody production
C) T cells
D) B cells
E) Tear flow AND B cells

A) are the organisms that typically reside on and in your body.
B) protect against infection by pathogens.
C) enhance infection by pathogens.
D) play no role in affecting pathogen growth.
E) are the organisms that typically reside on and in your body AND protect against infection by pathogens.

A) erythrocyte stem cell.
B) leukocytic stem cell.
C) eosinophilic stem cell.
D) hematopoietic stem cell.
E) osteocytes (bone cells).

A) Monocytes and macrophages
B) Lymphocytes and basophils
C) Mast cells and eosinophils
D) Basophils and eosinophils
E) Neutrophils and macrophages

A) Pasteur.
B) Koch.
C) Metchnikoff.
D) Lister.
E) Hooke.

A) lymphocyte.
B) basophil.
C) monocyte.
D) macrophage.
E) eosinophil.

A) peripheral circulation.
B) bone marrow.
C) lymphatic vessels.
D) lymph nodes.
E) spleen.

A) surface receptors.
B) cytokines.
C) platelets.
D) antigens.
E) adhesion molecules.

A) innate immunity.
B) specific immunity.
C) irregular immunity.
D) immune metabolism.
E) adaption.

A) Erythrocytes AND neutrophils
B) Neutrophils AND megakaryocytes
C) Neutrophils AND macrophages
D) Megakaryocytes AND leukocytes
E) Macrophages AND erythrocytes

A) C1
B) C2
C) C3
D) C6
E) C9

A) Gram-positive bacteria
B) Gram-negative bacteria
C) Bacteriophages
D) Prions
E) Acid-fast bacteria

A) classical pathway.
B) alternate pathway.
C) C3 pathway.
D) mucociliary pathway.
E) All of the answer choices are correct.

A) prostaglandin complex.
B) leukotriene activating complex.
C) membrane attack complex.
D) histamine complex.
E) macrophage antibody complex.

A) complement.
B) lysozyme.
C) histamine.
D) interferon.
E) transferrin.

A) ingestion.
B) exocytosis.
C) extrusion.
D) budding.
E) lysis.

A) endoplasmic reticulum.
B) phagolysosome.
C) Golgi apparatus.
D) lysosome.
E) peroxisome.

A) Flare, wheals, fever, cough
B) Redness, heat, swelling, pain
C) Rash, pus, heat, rubor
D) Heat, pain, vesicles, fever
E) Heat, pain, redness, fainting

A) opsonization.
B) interferon production.
C) properdin activation.
D) endotoxin production.
E) inflammation.

A) indicates infection by any virus.
B) indicates exposure to mutagens.
C) induces synthesis of interferon.
D) indicates infection by a retrovirus.
E) indicates complement activity.

A) They may be activated through three different pathways.
B) They disrupt the cytoplasmic membrane of invading bacteria and foreign cells.
C) They are part of the specific immune defense system.
D) They are a group of blood proteins produced by the liver.
E) They are part of the innate immune response.

A) Interleukin-1
B) Interleukin-2
C) Interferon
D) Tumor necrosis factor
E) Colony-stimulating factor

A) complement.
B) interferon.
C) glycoprotein.
D) lysozyme.
E) antibody.

A) It only works on a few specific types of virus.
B) It makes cells resistant to viral infection.
C) It is a species specific molecule.
D) It does not directly inactivate viruses.
E) IFNs regulate several immune responses.

A) inflammation AND fever.
B) interferon production AND attraction of phagocytes.
C) properdin activation AND inflammation.
D) attraction of phagocytes AND properdin activation.
E) inflammation AND attraction of phagocytes.

A) alternate pathway.
B) classical pathway.
C) properdin pathway.
D) inflammatory pathway.
E) lectin pathway.

A) prevent viral replication.
B) lyse when exposed to virus.
C) non-motile when infected with virus.
D) resistant to phagocytosis.
E) form endospores.

A) classical pathway.
B) alternative pathway.
C) C3 pathway.
D) lectin pathway.
E) properdin pathway.

A) Activation of rRNA
B) Movement of nuclear proteins to the cytoplasm
C) Production of glycolipids
D) Production of dsRNA
E) Production of dsDNA

A) produced by leukocytes.
B) important in both innate and adaptive immunity.
C) involved in directly killing tumor cells.
D) protein molecules.
E) produced by leukocytes AND protein molecules.

A) a rash.
B) fever.
C) pustules.
D) vesicles.
E) vomiting.

A) fever-inducing substances.
B) fever-inhibiting substances.
C) phagocytosis-enhancing substances.
D) complement activators.
E) pus-producing substances.

A) Production of antibodies AND engulfment/destruction of foreign cells.
B) Engulfment/destruction of foreign cells AND alerting the other cells of the immune system to an invader.
C) Alerting the other cells of the immune system to an invader AND serving as a physical barrier against microbial invasion.
D) Production of antibodies AND serving as a physical barrier against microbial invasion.
E) Alerting the other cells of the immune system to an invader AND production of antibodies.

A) parasitism.
B) infection.
C) phototaxis.
D) chemotaxis.
E) exotaxis.

A) It provides a highly specific response to very small and highly unique areas on an individual pathogenic microbe, providing the most specific and selective response possible.
B) It provides a general response to broad categories of molecules/cells that should NOT be in our system, as we don't have these molecules on our own cells.
C) These secreted molecules help bind pathogens and then direct them to receptors on the immune system cells that can eliminate them from our systems. 
D) TLRs are capable of directly lysing (destroying) the microbes, helping our immune responses by eliminating pathogens.
E) All of these statements are correct.

A) neutrophil.
B) monocyte.
C) macrophage.
D) basophil.
E) B cell.

A) inflammation.
B) reaction.
C) antibodies.
D) trauma.
E) fever.

A) inhibits bacterial growth AND speeds up the body's reactions.
B) enhances bacterial growth AND speeds up the body's reactions.
C) inhibits bacterial growth AND triggers complement activation.
D) speeds up the body's reactions AND triggers complement activation.
E) enhances bacterial growth AND triggers complement activation.

A) die because it is damaged and, as a result, cause an inflammatory response.
B) self-destruct and, as a result, cause an inflammatory response.
C) die because it is accidentally damaged, and, as a result, cause fever.
D) self-destruct without causing an inflammatory response.
E) divide to repair damaged tissue, leading to an inflammatory response.

A) They are produced by several cell types and bind directly to microbes to enhance their chance of being ingested, in a process called opsonization.
B) They are secreted by lysozomes into the phagosomes of neutrophils to enhance the killing of ingested microbes within those organelles.
C) They are secreted by one cell type, then work as a series of serum proteins to produce holes in the cytoplasmic membranes of microbes to directly lyse them.
D) They are secreted by microbes that have been engulfed by phagocytes, causing those cells to produce destructive enzymes and undergo apoptosis.
E) They are secreted by one cell type, then bind to a receptor on target cell causing a signal within that cell that turns on (or off) certain genes to achieve a response.

A) Host cells produce convertase 3b which changes C3b into C3a that does not activate the complement pathway.
B) Molecules in host cell membranes bind regulatory proteins that will inactivate any C3b molecules that attach to the membrane.
C) C3b triggers the alternative pathway in prokaryotes but not in eukaryotes.
D) Molecules in host cell membranes bind regulatory proteins that will stimulate the binding of C3b molecules to bacterial cells.
E) Molecules in host cell membranes bind any MACs, deactivating them and preventing the activation of the alternative pathway.

A) Stomach-acid conditions and normal microbiota
B) Skin-salt, fatty acids, and normal microbiota
C) Respiratory tract-mucociliary escalator
D) Peroxidases-milk, saliva, mucus, and some phagocytes
E) Saliva-lysozyme, peroxidase, and lactoferrin

A) The actions of the cells in these areas help to propel pathogens out of the area, serving as a part of the physical barrier system. When they are impaired/slowed, bacteria and other pathogens have an easier time adhering to the tissues in the area and causing an infection.
B) Ciliated cells also line the digestive tract, and these cells secrete strong natural antibacterial compounds. When they are impaired, bacteria can more easily infect these areas.
C) Chemicals in cigarette smoke and the chemicals in painkillers impair our immune systems, making us generally more predisposed to infections (regardless of the tissue area).
D) Chemicals in cigarette smoke and the chemicals in painkillers impair the ability of our immune system cells to move into areas that are infected. As such, they can't perform their job of eliminating microbes as well as they should and infections result more easily.
E) The actions of the cells in these areas help to propel pathogens into the stomach, where they are destroyed by acid. When they are impaired/slowed, bacteria and other pathogens do not get destroyed by and can cause an infection.

A) Fever prevents microbes with lower optimum temperatures from growing, giving the immune system time to eliminate those cells.
B) A moderate fever reduces the inflammatory response but stimulates phagocytic activity in neutrophils and eosinophils.
C) Fever increases the inflammatory response, but reduces the production of interferons unless the invader is a dsRNA virus.
D) Fever increases the multiplication of lymphocytes and enhances the release of substances that attract basophils that then engulf the microbial invader.
E) Fever plays all of these roles in the body.

A) Peroxidases
B) Lactoferrins
C) Transferrins
D) Peroxidases AND lactoferrins
E) Lactoferrins AND transferrins

A) Phagocytic cells are recruited to the site of an injury by chemoattractants such as complement C3b. 
B) The phagocytic cell binds microbial invaders and engulfs them by means of pseudopodia, internalizing them in a phagosome.
C) If a phagocyte encounters something too large to engulf, it releases its toxic contents as a means of destroying that invader.
D) Within a phagolysosome, O₂ consumption decreases dramatically, allowing an enzyme to produce reactive oxygen species (ROS), which are toxic.
E) The phagolysosome releases undigested debris to the outside of the cell by fusing with the phagocyte's cytoplasmic membrane.

A) First line defenses-the barriers that separate and shield the interior of the body from the surrounding environment (skin and mucous membranes).
B) Sentinel cells-host cells that help the immune system detect signs of invasion by producing cytokines when their PRRs recognize an invading microbe.
C) Inflammatory response-coordinated innate response involved in containing a site of damage, localizing the response, eliminating the invader, and restoring tissue function.
D) Innate lymphoid cells-a group of lymphocytes that have increased specificity in their mechanism of antigen recognition (example: natural killer (NK) cells).
E) RIG-like receptors-a group of pattern recognition receptors within cells that recognize molecules associated with infecting viruses.

A) O antigen on Gram-negative bacteria
B) Peptidoglycan in Gram-positive cells
C) Flagellin and pilin
D) Double-stranded viral RNA
E) Enzymes involved in glycolysis

A) Malaria parasites produce strong antibacterial compounds (since they're eukaryotic in nature-they are trying to eliminate their competition for resources). This helps to eliminate ALL bacteria in and on the human body for a short period of time.
B) Malaria parasites track down and feed upon ALL bacterial cells in the human body as a part of their life cycle. This makes them a "natural antibiotic" of sorts, and highly effective at clearing the bacterial infection of syphilis.
C) One of the side effects of malarial infection is a massive overproduction of macrophages. This drives up the ability to ingest and destroy any microbe, including the bacterium that causes syphilis.
D) The effect of driving up the body temperature for periods of time can shut down the temperature-sensitive replication of the bacterium that causes syphilis. This gives the immune system time to eliminate it properly.
E) The bacteria that cause syphilis track down and destroy the protozoan that causes malaria. By doing this, the bacteria are "occupied" and do not cause damage to the human host.

A) Some pathogens produce C5a peptidase that destroys complement C5a, a chemoattractant that recruits phagocytes to the area of infection.
B) Some pathogens hijack the host's regulatory membrane proteins that inactivate C3b, preventing the triggering of the alternative activation pathway.
C) Some pathogens produce C5a peptidase that causes destruction of phagoctyes recruited to the area of infection.
D) Some pathogens hijack the host's regulatory membrane proteins that inactivate C3b, preventing the triggering of the alternative activation pathway AND some pathogens produce C5a peptidase that destroys complement C5a, a chemoattractant that recruits phagocytes to the area of infection.
E) Some pathogens hijack the host's regulatory membrane proteins that inactivate C3b, preventing the triggering of the alternative activation pathway AND some pathogens produce C5a peptidase that causes destruction of phagoctyes recruited to the area of infection.

A) 1, 2, 3, 4, 5
B) 2, 4, 3, 5, 1
C) 3, 2, 1, 5, 4
D) 1, 3, 5, 2, 4
E) 1, 5, 2, 4, 3

A) Lactoferrin
B) Transferrin
C) Colicin
D) Defensin
E) Mucus

A) 2, 4, 1, 5, 3
B) 1, 2, 3, 4, 5
C) 3, 1, 2, 5, 4
D) 5, 4, 1, 2, 3
E) 2, 1, 4, 3, 5

A) Activation of complement proteins.
B) Binding of microbial products to PPRs.
C) Tissue damage caused by microbial invasion.
D) Induction of antiviral protein synthesis by IFNs.
E) Release of TNF by macrophages.

A) B cells
B) T cells
C) NK cells
D) B cells AND T cells
E) B cells, T cells, AND NK cells

A) No; interferon is just an evolutionary leftover from a much earlier form of antiviral activity. It has no function now. Virus infections are always treated with medications.
B) Yes; when the interferon acts on a virally infected cell, it shuts down virus replication. Without interferon, the virus will eventually kill the cell, but only after it has replicated many times. IFNs may kill the host cell, but they will also prevent it from being used to replicate virus.
C) Yes; by killing host cells, the number of cells that are available targets for viral infection is limited. This is a good way of preventing viral infection.
D) No; viruses will replicate in cells regardless of the effects of interferons, so their action of killing the cell has no benefit to the host organism during the infection process.
E) Yes; IFN is needed to activate complement which stimulates otherwise phagocytes in the host so that they recognize and destroy not only the virus but also any infected cells. Without complement, all phagocytes are inert.

A) Macrophages and neutrophils both circulate in the blood. Macrophages are phagocytic cells while neutrophils are granulocytes but not phagocytes.
B) Macrophages and neutrophils are both phagocytic cells. Macrophages reside in the tissues while neutrophils typically circulate in the blood.
C) Macrophages and neutrophils are both abundant cell types in tissues. Macrophages are phagocytic cells while neutrophils are not.
D) Macrophages and neutrophils are both phagocytic cells. Macrophages are granulocytes while neutrophils are effector cells.
E) Macrophages and neutrophils are both leukocytes. Macrophages are granulocytes and neutrophils are lymphocytes.

A) CSF is a strong inducer of antiviral activities in our cells, and may help our immune system fight off the effects of an HIV infection for a longer period of time.
B) CSF will help to stimulate the production of new lymphocytes, the very cells that are affected by HIV. This may help to keep the patients' immune responses "normal" for a period of time.
C) CSF will hyperstimulate the activities of the macrophages, leading to aggressive ingestion and successful destruction of HIV-infected cells.
D) CSF will drive up the production of lactoferrin and transferrin, strong antiviral compounds produced in our mucus membrane secretions that trap and destroy viruses.
E) CSF is a cytokine that allows cells to communicate. If levels of CSF are elevated, HIV-infected cells can alert other healthy cells so that they produce protective IFNs.

A) Kupffer cells-liver
B) Microglial cells-brain
C) Alveolar macrophages-lungs
D) Mesangial macrophages-kidneys
E) Peritoneal macrophages-meninges

A) A number of different TLRs have been described, all of which are found in the phospholipid membranes of endosomes and phagosomes.
B) TLRs anchored in the membrane of endosomes generally detect components of the outermost layers of microbial cells, including lipopolysaccharide (LPS), lipoproteins, and flagellin.
C) TLRs allow cells to detect patterns associated with microbes, indicating that the innate immune responses involve some specificity (although not the specificity of adaptive immunity).
D) TLRs represent a very important early-warning system for viral infections. They allow any virally infected cell to alert neighboring cells that a virus is present.
E) All of these statements are True of TLRs.