Deck 17: Genetics of Immunity

A) 10
B) 20
C) 30
D) 40
E) 50

A) generality, diversity, and retention.
B) specificity, diversity, and memory.
C) prevention, protections, and memory.
D) antibody production, cytokine secretion, and walling off of infected areas.
E) suppression, activation, and transference.

A) secrete antibodies.
B) are types of red blood cells.
C) secrete cytokines.
D) divide to give rise to B cells.
E) constitute the clear part of blood.

A) T cell
B) macrophage
C) B cell
D) neutrophil
E) erythrocyte

A) about 10,000 cells that increase rapidly to trillions when an infection takes hold.
B) the heart and blood vessels and the blood cells within the vessels.
C) about 2 trillion cells, their secretions, and the organs where they are produced and stored.
D) all of the bacteria and viruses that are normally present in our bodies plus our blood cells.
E) the thyroid and thymus glands and their cells and secretions.

A) phospholipids.
B) lipoproteins.
C) glycolipids.
D) glycoproteins.
E) histamines.

A) any molecule that can elicit an immune response.
B) a protein only.
C) a nucleic acid only.
D) a protein or nucleic acid.
E) a protective protein that the immune system produces.

A) a single folded polypeptide chain.
B) 4 polypeptide chains, two large and two small.
C) 2 polypeptide chains, one large and one small.
D) 4 polypeptide chains of about equal size.
E) a triple helix.

A) the immune system mutates from season to season.
B) flu vaccines are not always effective.
C) secondary immune responses are only possible against bacteria.
D) the primary immune response is sufficient to protect against flu.
E) the virus mutates, so it is different each season.

A) Disulfide
B) Peptide
C) Hydrogen
D) Phosphodiester
E) Repulsive

A) rearranging of HLA proteins on B cell surfaces.
B) the huge number of antibody genes.
C) shuffling of antibody genes into different combinations during B cell development.
D) differential regulation of antibody gene expression under different circumstances.
E) the many types of viruses that exist in nature.

A) adaptive immunity is fast and generalized; innate immunity is slow and specific.
B) innate immunity targets cancers and transplants; adaptive immunity targets viruses and bacteria.
C) innate immunity is fast and generalized; adaptive immunity is slow and specific.
D) adaptive immunity releases cytokines; innate immunity produces antibodies.
E) innate immunity is present in fetuses and children whereas adaptive immunity is only present in adults.

A) interleukins.
B) interferons.
C) tumor necrosis factor.
D) colony stimulating factors.
E) collectins.

A) creating an environment in the body that is hostile to pathogens.
B) producing antibodies that kill viruses and bacteria.
C) shrinking tissues at the site of infection.
D) limiting the number of phagocytes at the infection site.
E) producing collectins, cytokines, and complement.

A) T and B cells.
B) A and B cells.
C) cytokines and antibodies.
D) thymus and spleen cells.
E) RBCs and WBCs.

A) the binding site for antigens.
B) part of the heavy chains only.
C) the same in all antibodies of a certain type.
D) at the tips of light chains only.
E) the binding site for two antigens.

A) HIV
B) CCR5
C) HLA
D) antibody
E) erythrocyte

A) idioblast.
B) idiotype.
C) idiot.
D) epitope.
E) intron.

A) serology.
B) genotyping.
C) gene therapy.
D) stem cell therapy.
E) phenotyping.

A) immune preparedness.
B) mandatory vaccination.
C) government-controlled health care.
D) herd immunity.
E) socialized medicine.

A) reverse transcriptase
B) DNA polymerase
C) RNA polymerase
D) DNA transcriptase
E) DNA ligase

A) causing pieces of antigen genes to form new combinations.
B) activating complement, inactivating pathogens, and clumping pathogens.
C) activating macrophages, stimulating mast cells, and increasing the white blood cell count.
D) creating a warm and swollen area near the site of infection, which harms the pathogens.
E) causing B cells to bind to T cells, forming clumps that are visible to the immune system.

A) cytotoxic T cells.
B) B cells.
C) helper T cells.
D) macrophages.
E) erythrocytes.

A) humoral and cellular immunity
B) the thymus and thyroid glands.
C) white blood cells and red blood cells.
D) mast cells and macrophages.
E) helper B cells and cytotoxic B cells.

A) extra T cells.
B) deletions in the genes encoding the CCR5 co-receptor.
C) a gene encoding a protein that attacks the virus.
D) antibodies to HIV.
E) anti-HIV antigens.

A) chickenpox virus
B) swine flu virus
C) cowpox
D) hepatitis C virus
E) measles virus

A) IgE antibodies on mast cell surfaces
B) IgG antibodies on B cell surfaces
C) allergy genes on chromosome 5
D) histamines on mast cell surfaces
E) pollen granules

A) cytokines.
B) antibodies.
C) antigens.
D) immunoglobulins.
E) autoantibodies.

A) she and the fetus are both Rh^-.
B) she is Rh⁺ and the fetus is Rh^-.
C) she is Rh^- and the father is Rh⁺.
D) she is Rh⁺ and the father is Rh^-.
E) she and the father are both Rh^-.

A) retained fetal cells with surfaces that are similar to the mother's.
B) retained fetal cells with surfaces that are very different from those of the mother.
C) retained fetal cells with surfaces that are similar to the father's.
D) repeated exposure to the scleroderma virus.
E) receiving a transplant of a vital organ from someone with closely-matched cell surfaces.

A) bind antigens.
B) are engulfed by macrophages.
C) become T cells.
D) are stimulated by activated T cells.
E) undergo apoptosis.

A) AIDS.
B) hay fever.
C) severe combined immune deficiency.
D) systemic lupus erythematosis.
E) colon cancer.

A) found on B cells, where they determine the antibody types that are made.
B) found on B cells, where they make recognition of self antigens on macrophages possible.
C) found on T cells, which they enable to recognized foreign antigens on macrophages.
D) found on macrophages, which they enable to link with both B and T cells.
E) found on bacteria that cause infection, enabling the immune system to recognize them.

A) in a fetus as its bone marrow develops.
B) in a fetus in response to maternal antigens.
C) immediately after birth.
D) after birth, a few months after exposure to foreign antigens.
E) at the embryo stage.

A) cancer cells and virally infected cells.
B) skin cells and blood cells.
C) bacterial cells and fungal cells.
D) B cells and macrophages.
E) antigens and antibodies.

A) the person encounters an immunodeficiency virus.
B) the person inhales an allergen.
C) a nonself antigen coincidentally resembles a self antigen.
D) too many T cells die in the thymus.
E) a person has too many organ transplants.

A) primary immune
B) secondary immune
C) tertiary immune
D) inflammatory
E) anaphylactic

A) B cell and a cancer cell.
B) B cell and a T cell.
C) human spleen cell and a sheep B cell.
D) mast cell and a macrophage.
E) T cell and a plasma cell.

A) has normal numbers of T and B cells.
B) makes antibodies that attack the body's own tissues.
C) has no white blood cells.
D) has some T cells but lacks B cells.
E) lacks both T and A B cells.

A) antibodies come from a twin.
B) antibodies are identical.
C) cancer cells are all of one type.
D) antigens are from a single source.
E) fused cells are from the same species.

A) considering how rapidly pathogens divide in laboratory culture.
B) culturing pathogens in laboratory glassware.
C) targeting genes of pathogens that cannot be cultured.
D) exposing pathogens to panels of antibiotic drugs to select those that work.
E) injecting human antigens into pathogen genomes.

A) a formerly isolated population is exposed to pathogens that only affect non human animals.
B) a formerly isolated population is exposed to pathogens that have been in other human populations for so long that the people there are immune.
C) too many people crowd an area and sneeze uncontrollably on each other.
D) people refuse to have their children vaccinated.
E) members of isolated populations visit crowded areas, bringing unfamiliar infectious diseases.

A) T cells.
B) B cells.
C) macrophages.
D) mast cells.
E) erythrocytes.

A) autograft.
B) isograft.
C) allograft.
D) xenograft.
E) unmatched recipient.

A) the recipient.
B) a non-relative.
C) a dizygotic twin.
D) a member of a different species.
E) a monozygotic twin.