Monocytes and macrophages

Question 1

Monocyte nucleus shape

Answer 1

Bean-shape

Question 2

Blood concentration

Answer 2

10% of circulating cells

Question 3

Development of monocytes

Answer 3

Begin as hematopoietic cells
To common myeloid progenitor (CMP)
To granulocyte/monocyte progenitor
and finally differentiate into monocyte progenitor.

Question 4

Classical Monocytes

Answer 4

CD14+ CD16-, typically CCR2+.

Question 5

Intermediate Monocytes:

Answer 5

CD14+ CD16+, commonly CCR5+.

Question 6

Patrolling/Non-Classical Monocytes

Answer 6

CD14low CD16+, express CX3CR1+ and CD64+.

Question 7

Mice, Patrolling Monocytes

Answer 7

Ly6Clow.

Question 8

Mice, Classical Monocytes:

Answer 8

Ly6Chigh.

Question 9

Flow Cytometry Markers

Answer 9

Utilized to identify and differentiate between various monocyte populations.

Question 10

Monocyte Role

Answer 10

Monocytes perform phagocytosis, present antigens, and secrete cytokines.

Question 11

Monocyte Migration

Answer 11

Can migrate to tissues and transform into macrophages or dendritic cells.

Question 12

Monocyte maturation

Answer 12

Develop from progenitor cells in the bone marrow through various stages before becoming fully mature monocytes.

Question 13

How long do monocytes circulate in the blood

Answer 13

Circulate in the blood for 1-3 days before migrating to tissues.

Question 14

Surface markers of monocytes

Answer 14

CD14,CCR2, CCR5, CX3CR1

Question 15

CD14 surface marker function

Answer 15

A co-receptor for the detection of bacterial lipopolysaccharides (LPS).

Question 16

CCR2 surface marker function

Answer 16

A receptor that mediates chemotaxis toward sites of inflammation.

Question 17

CCR5 surface marker function

Answer 17

Involved in the inflammatory response and may play a role in cell migration and activation.

Question 18

CX3CR1 surface marker function

Answer 18

A receptor involved in adhesion and migration of monocytes.

Question 19

Monocyte Differentiation into

Answer 19

two types of macrophages—M1 (pro-inflammatory) and M2 (anti-inflammatory/healing)

Question 20

Monocyte and Cancer

Answer 20

Ongoing research investigates the role of monocytes in cancer, healing, and as vehicles for drug delivery, human and mouse monocytes serve as models to study immune response and pathology

Question 21

Balance of M1 and M2

Answer 21

The balance between M1 and M2 can influence the outcome of many diseases. (diseases, or hematological disorders.)

Question 22

High and low monocyte count

Answer 22

High monocyte counts can indicate chronic inflammation, while low counts may suggest bone marrow suppression or systemic lupus erythematosus (SLE).

Question 23

Functions of Non-classical/Patrolling Monocytes

Answer 23

Sense tissue damage, involved in tissue repair and angiogenesis.
Scavenge and respond to viruses/nucleic acid via endosomal TLR7/8 with cytokines such as TNF, IL-1β, CCL3.
Scavenge immune complexes and have a role in autoimmunit

Question 24

how do monocyte scavengers and respond to viruses/nucleic acid

Answer 24

via endosomal TLR7/8 with cytokines such as TNF, IL-1β, CCL3.

Question 25

Functions of Classical Monocytes

Answer 25

Exhibit antimicrobial activity through phagocytosis.
Produce reactive oxygen species (ROS), nitric oxide (NO), myeloperoxidase (MPO), and Type I Interferons.
Mediate inflammation and leukocyte recruitment, responding to cytokines like IL-1α, TNF, IL-6, IL-8, and CCL2.
Activate T cells due to the presence of MHC class II on their surface.

Question 26

What does classic monocytes produce

Answer 26

Produce reactive oxygen species (ROS), nitric oxide (NO), myeloperoxidase (MPO), and Type I Interferons.

Question 27

How do they mediate inflammation and leukocyte recruitment

Answer 27

responding to cytokines like IL-1α, TNF, IL-6, IL-8, and CCL2.

Question 28

TLR4 ligands

Answer 28

trigger a response in patrolling monocytes

Question 29

TLR7/8 ligands

Answer 29

prompt a response in classical monocytes.

Question 30

Ly6C^low and Ly6C^high monocytes have different responses to

Answer 30

TLR4 and TLR7/8 stimulation.

Question 31

monocyte produce key inflammatory cytokines

Answer 31

like TNF, IL-1β, and CCL3 during this response.

Question 32

what do Classical monocytes release

Answer 32

They release antimicrobial molecules such as ROS, NO, MPO, and Type I Interferons to neutralize threats.

Question 33

Classical monocytes function

Answer 33

proficient phagocytes that engulf and destroy pathogens and key players in promoting inflammation and recruiting other leukocytes to sites of infection.

Question 34

Monocyte and MHC II

Answer 34

Antigen presentation, and different monocyte subsets respond to various TLRs, which recognize distinct pathogen-associated molecular patterns.

Question 35

TLR4

Answer 35

induces a pro-inflammatory reaction in patrolling monocytes.

Question 36

TLR7/8

Answer 36

Detects viral RNA within endosomes.

Question 37

What are the stimuli associated with the M1 macrophage phenotype?

Answer 37

LPS, IFNγ, TNFα.

Question 38

What are the biomarkers associated with the M1 macrophage phenotype?

Answer 38

TNF, IL-1β, IL-6, IL-12, IL-23, iNOS, COX-2, CCR7

Question 39

What are the functions associated with the M1 macrophage phenotype?

Answer 39

Associated with type 1 inflammation, antigen presentation, and angiogenesis.

Question 40

What are the stimuli associated with the M2a macrophage phenotype?

Answer 40

IL-4, IL-13

Question 41

What are the biomarkers associated with the M2a macrophage phenotype?

Answer 41

TGFβ, arginase-1, Ym1, Fizz1.

Question 42

What are the functions associated with the M2a macrophage phenotype?

Answer 42

with type 2 inflammation, eosinophil recruitment, stabilization of neovascularization.

Question 43

What are the stimuli associated with the M2b macrophage phenotype?

Answer 43

immune complexes, LPS

Question 44

What are the biomarkers associated with the M2b macrophage phenotype?

Answer 44

L-1β, IL-6, CCL1, CXCL1, CCL2

Question 45

What are the stimuli, biomarkers, and functions associated with the M2b macrophage phenotype?

Answer 45

antigen presentation, immune regulation.

Question 46

What are the stimuli associated with the M2c macrophage phenotype?

Answer 46

IL-10, glucocorticoids, TGFβ1

Question 47

What are the stimuli, biomarkers, and functions associated with the M2c macrophage phenotype?

Answer 47

CD163, SOCS3, VEGF, MMP9

Question 48

What are the stimuli, biomarkers, and functions associated with the M2c macrophage phenotype?

Answer 48

tissue remodelling, anti-inflammatory properties, and phagocytosis

Question 49

What are the stimuli associated with the M2d macrophage phenotype?

Answer 49

TLR agonists, IL-6, A2R agonist, tumor microenvironment

Question 50

What are the biomarkers associated with the M2d macrophage phenotype?

Answer 50

VEGF, IL-10, IL-12, NO2.

Question 51

What are the functions associated with the M2d macrophage phenotype?

Answer 51

Associated with tumor-associated immune regulation and angiogenesis.

Question 52

Endothelial Activation (for monocyte activation)

Answer 52

CD4+ T cells secrete CXCL10; endothelial cells express VCAM1.

Question 53

Recruitment(for monocyte activation)

Answer 53

Neutrophils and monocytes migrate to the site.

Question 54

monocyte activation

Answer 54

Monocytes differentiate into macrophages, expressing CCR2, CX3CR1, and produce IL-1β, TNFα.

Question 55

Fibroblast ACtivation

Answer 55

Driven by IL-13 from CD4+ T cells.

Question 56

Macrophage tissue repair

Answer 56

facilitate growth of new tissue and differentiate into M2 phenotype promoting healing.

Question 57

Where do tissue-resident macrophages originate from?

Answer 57

originate from embryonic precursors, particularly from the yolk sac and fetal liver monocytes, which migrate to tissues early in development

Question 58

Subtypes of monocytes

Answer 58

classical, intermediate, and non-classical/patrolling monocytes, each with distinct surface markers and functions.

Question 59

differentiation Classical monocytes (CD14+ CD16-)

Answer 59

migrate through the blood and can differentiate into various macrophage subtypes in tissues.

Question 60

What functions do tissue macrophages serve?

Answer 60

phagocytize microbes and dead cells, secrete cytokines that modulate immune responses, present antigens to T cells, and are involved in tissue remodeling and repair.

Question 61

What is the typical size of a monocyte and its nucleus shape?

Answer 61

Monocytes are typically 10-15μm in diameter with a characteristic bean-shaped nucleus.

Question 62

What factors differentiate Ly6Clow and Ly6Chigh monocytes in their response to TLR stimulation?

Answer 62

Ly6Clow responds differently to TLR4 and TLR7/8 stimulation, with TLR4 inducing a pro-inflammatory response and TLR7/8 making classical monocytes respond.

Question 63

What are the three populations of monocytes in humans and their markers?

Answer 63

Classical (CD14+ CD16-), Intermediate (CD14+ CD16+), and Patrolling/Non-classical (CD14low CD16+).

Question 64

Describe the transition of classical monocytes in tissue.

Answer 64

Classical monocytes can transition to patrolling monocytes. They are the first to arrive at an injury site and later become CX3CR1 positive, a transition driven by IL-4/IL-10 for repair.

Question 65

What are the two origins of tissue-resident macrophages?

Answer 65

Embryonic origin, where macrophages are established prenatally, and bone marrow hematopoiesis, leading to monocyte-derived macrophages.

Question 66

What are DOMs in the context of macrophage function?

Answer 66

DOMs refer to Delayed Onset Muscle Soreness, which is associated with the production of pro-inflammatory cytokines by macrophages

Question 67

What are the unique functions of tissue-resident macrophages?

Answer 67

What are the unique functions of tissue-resident macrophages?

Question 68

What are Synovial Tissue Macrophages (STMs)

Answer 68

STMs are specialized macrophages forming a protective layer in the synovial membrane of joints.

Question 69

Where do STMs arise from

Answer 69

fetal hematopoietic stem cells during embryonic development, indicating early specialization.

Question 70

STM function

Answer 70

maintain joint homeostasis and prevent autoimmune reactions, act as a crucial barrier to infection and are implicated in the pathogenesis and resolution of arthritis.

Question 71

STMs

Answer 71

Synovial Tissue Macrophage

Question 72

Role of Macrophage Polarization in Rheumatoid Arthritis (RA)

Answer 72

macrophages can exhibit M1 or M2 polarization, contributing to either inflammation (M1) or healing (M2)

Question 73

M1 in RA

Answer 73

pro-inflammatory and often exacerbate the destruction of joint tissue.

Question 74

What does it mean that macrophages are heterogeneous?

Answer 74

existence of diverse macrophage subtypes, each with unique functions and phenotypic markers.

Question 74

M2 in RA

Answer 74

facilitate tissue repair and regeneration, reducing inflammation.

Question 75

Balance of M1 and M2 in RA

Answer 75

influences the progression and resolution of RA symptoms.

Question 76

why is macrophages are heterogeneous essential

Answer 76

This plasticity is vital for responding appropriately to various pathological conditions.

Question 77

How do monocyte-derived and tissue-resident macrophages differentiation?

Answer 77

Monocyte-derived macrophages can differentiate into tissue-resident macrophages adapting to the needs of the local microenvironment.

Question 78

Tissue-resident macrophages originate from

Answer 78

both the embryo and the bone marrow, allowing a combination of innate immune memory and adaptive response.

Question 79

Integration of monocyte-derived and tissue-resident macrophages

Answer 79

Coordinated immune response, ranging from initial inflammation to subsequent healing processes.
Their collective activities are crucial in tissue repair, inflammation resolution, and maintenance of tissue homeostasis.

Question 80

How do macrophages assist in the resolution of inflammation

Answer 80

secreting anti-inflammatory cytokines and growth factors such as VEGF-A, promoting angiogenesis.

Question 81

How do Tissue repair macrophages help resolve inflammation

Answer 81

display receptors like IL-4R and CD206 and can derive from both local proliferation and recruitment of circulating monocytes.

Question 82

What is Macrophage Polarization?

Answer 82

dynamic changes in macrophage function in response to environmental cues, resulting in diverse phenotypes: pro-inflammatory (M1) or anti-inflammatory (M2).

Question 83

M1 macrophages are stimulated by

Answer 83

LPS and IFNγ, leading to an inflammatory response critical for defense against pathogens.

Question 84

M2 macrophages, induced by

Answer 84

IL-4 and IL-13, play roles in tissue repair, immune regulation, and resolution of inflammation.

Question 85

What characterizes pro-inflammatory (M1) macrophages?

Answer 85

produce inflammatory cytokines (TNF-α, IL-1β, IL-6), reactive nitrogen and oxygen species, and present antigens to T cells, fueling the inflammatory response.

Question 86

M1 involved in

Answer 86

initial defense mechanism against pathogens and are associated with the progression of inflammatory diseases.

Question 87

M1 express

Answer 87

high levels of surface molecules like CSF1R and produce enzymes such as iNOS.

Question 88

What characterizes anti-inflammatory (M2) macrophages?

Answer 88

contribute to the resolution phase of inflammation, tissue remodeling, and repair, as well as the maintenance of homeostasis.

Question 89

M2 produce

Answer 89

anti-inflammatory cytokines like IL-10 and growth factors including TGF-β to facilitate healing.

Question 90

M2 arise from

Answer 90

arious signals such as IL-4, IL-13, and immune complexes, influencing their specific roles in the immune response.

Question 91

How do macrophages diversify and specialize?

Answer 91

Macrophages exhibit remarkable plasticity, with the ability to switch between M1 and M2 phenotypes depending on the microenvironmental context.

Question 92

Macrophage specialization

Answer 92

influenced by factors such as tissue of residence, length of stay in the tissue, and the nature of the inflammatory respons

Question 93

What is TGF-β and its role in the immune system?

Answer 93

regulator in wound healing, fibrosis, and immune cell regulation, helping to suppress inflammation and facilitate tissue remodeling.

Question 94

TGF-β

Answer 94

Transforming Growth Factor-Beta

Question 95

Function of VEGF in tissue repair?

Answer 95

stimulates angiogenesis, the formation of new blood vessels, crucial for supplying nutrients and oxygen to healing tissues.

Question 96

VEGF

Answer 96

Vascular Endothelial Growth Factor

Question 97

FGF

Answer 97

Fibroblast Growth Factor

Question 98

role of FGF in the healing process?

Answer 98

involved in cell proliferation and differentiation during wound healing and tissue regeneration.

Question 99

What does PDGF do in tissue repair?

Answer 99

recruits cells like fibroblasts to the injury site to proliferate and produce extracellular matrix, contributing to the repair.

Question 100

PDGF

Answer 100

Platelet-Derived Growth Factor

Question 101

How does EGF contribute to tissue regeneration?

Answer 101

promotes cell growth and differentiation, especially epithelial cell repair, aiding in the healing of wounds.

Question 102

EGF

Answer 102

Epidermal Growth Factor

Question 103

IGF

Answer 103

Insulin-Like Growth Factor

Question 104

IGF’s importance in muscle and bone repair?

Answer 104

aids in cell survival and growth, playing a key role in muscle and bone repair.

Question 105

Macrophages contribute to tissue repair and regeneration by releasing a variety of growth factors;

Answer 105

TGF-β - Transforming Growth Factor-Beta
VEGF - Vascular Endothelial Growth Factor
FGF - Fibroblast Growth Factor
PDGF - Platelet-Derived Growth Factor
EGF - Epidermal Growth Factor
IGF - Insulin-Like Growth Factor

Question 106

Necrotic EC

Answer 106

necrotic endothelial cells

Question 107

Necrotic EC

Answer 107

death of cells in an organ or tissue due to disease, injury, or failure of the blood supply.