CVD Flashcards

1
Q

Describe the three regions of the vasculature (tunica): describe which layer it is and what cells are present, and any extra that makes sense

A
  1. the initima: inner region; endothelial cells
  2. the media: middle region; smooth muscle cells (SMCs)
  3. the adventita: peripheral region; fibroblasts, adipocyotes, and ICs; the vaso vasorum is the network of small blood vessels that irrigate bigger blood vessels
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2
Q

How do Ly6Clow monocytes become this phenotype, what is the role of this monocyte, what chemokine directs its movement?

A

Ly6Chigh monocyte –> NR4A1-induced transition into a Ly6Clow monocyte –> CX3CL1 recruite this monocyte to the blood where they patrol the vasculature and clean up debris and dead endothelial cells –> if recruited to damaged tissues, they play reparative roles

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3
Q

For the following particles describe how much cholesterol they contain, how much TGA they contain, and their function: chylomicron, VLDL, LDL, and HDL (for LDL and HDL also describe their apoprotein)

A

chylomicron

  • low cholersterol
  • high TGA
  • transport of dietary (exogenous) TGA from gut to periphery

VLDL

  • low cholersterol
  • high TGA
  • transport of TGA synthesiszed in the liver (endogenous) to periphery

LDL

  • high cholesterol
  • low TGA
  • transport of cholesterol and fat-soluble vitamins to periphery
  • apoprotein: B100

HDL

  • high cholesterol
  • low TGA
  • reverse transport of cholesterol from periphery to the liver
  • apoprotein: A and E
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4
Q

What is athersclerosis?

A

a progressive thickening and hardening of the walls of medium-sized and large arteries as a result of fat deposits on their inner lining

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5
Q

Describe the sequence of atherscelorisis progression: nomenclature and main histology

A
  1. initial lesion: macrophage infiltration, isolated foam cells
  2. fatty streak: mainly intacellular lipid accumulation
  3. intermediate lesion: small extracellular lipid pools in initima
  4. atheroma: core of extracellular lipid
  5. fibroatheroma: single or multiple lipid cores
  6. complicated lesion: hemmorhage and thrombosis (i.e breaks)
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6
Q

Describe plaque states during atherosclereosis progression

A

earlth atheroma –> stabilized plaque (small lipid pool, thin fibrous cap) OR vulnerable plaque (thin fibrous cap, large lipid pool, many inflammatory cells)

vulnerable plaque –> stabalized cap OR thrombosis (ruptures plaque)

thrombosis –> healed reptured plaque (reabsorbed) OR blocks small arteries (in brain - stroke; in heart - myocardial infarction)

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7
Q

In athersclerosis, describe endothelial activation and monocyte recruitment (include comorbidities)

A

hypertension, dyslipidemia, smoking, diabetes –> high [LDL] –> LDL enters intima –> oxidation of LDL (oxLDL = DAMP) –> oxLDL activates LOX-1 activating endothelial cells (opening of tight junctions) –> activated endothelial cells secrete MCP-1 and CCL2 to recruit monocytes and increase monocyte adhesion molecules –> monocyte enters the intima where GM-CSF and M-CSF cause the monocyte to diffeerntiate into a macrophage

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8
Q

Describe how macrophages handle LDL and HDL

A

LDL

  • uptake of LDL cholesterol occurs via the LDLR, pinocytosis and phagocytosis
  • oxidation of LDL enhances internalization via a number of receptors, including CD36, SRAs, LOX, and TLRs (e.g. TLR4)

HDL

  • cholesterol can be cleared using two main pathways: 1o = transport of cholesterol to the pm; 2o efflux of cholesterol to lipid-poor apolipoproteins or HDL
  • 2o: the ApoA/ApoE disks and mature HDL cholesterol efflux via ABCA1, ABCG1, SR-B1 (CD36) or via diffusion –> exogenous lipid-free ApoA or endogenous ApoE interact with ABCA1 to stimulate the efflux of cholesterol to form nascent HDL particles (e.g. ApoA or ApoE containing phospholipid disks)
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9
Q

How is the control of cholesterol uptake and efflux deregulated in athersclerosis?

A
  • expression of SRs increases –> increased uptake of oxLDL (enhanced cholesterol uptake)
  • expression of cholesterol transporters ABCA1 and ABCG1 is suppressed –> diminished cholesterol efflux + promotes cholesterol deposition in macrophages (diminished cholesterol efflux)
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10
Q

What are foam cells?

A

macrophages all filled with lipids, especially cholesterol

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11
Q

Describe how plaques form in athersclerosis

A
  1. migration of SMCs, from the media to the intima, the proliferation of resident initial SMCs and media-derived SMCs, and the heightened synthesis of ECM macromolecules such as collagen, elastin, and proteoglycans –> lesions
  2. plaque macrophages and SMCs can die in advancing lesions
  3. extracellular lipid derived from dead and dying cells can accumulate in the central relgion of a plaque –> “lipid/nectroic core”
  4. advancing plaques also contain cholesterol crystals and microvessles
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12
Q

The balance of pro-inflammatory and anti-inflammatory processes controls the resolution of the lipid-driven inflammation in athersclerotic lesions. Describe what happened if the balance shifts towards pro-inflammatory state vs the anti-inflammatiory state.

A

pro-inflammatory

  • resolving mechanisms fail
  • pyroptosis (mediated by inflammasome activation) or necroptosis can ensue
  • these pro-inflammatory forms of cell death further promote inflammation and generation of a nectrotic/lipid core

anti-inflammatory

  • pro-resolving mediators, apoptosis, autophagy-associated cell death, and cholesterol efflux from the lesions are favoured
  • efferocytosis of dead cells –> resolution
  • these process promote the formation of a stable plaque with a small necrotic/lipid core
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13
Q

What promotes a vulnerable plaque to stabalize?

A

behaviour changes + low LDL drugs

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14
Q

Recall: what are the lipid-mediator class switch from inflammation to resolution effects? i.e. what lipid-mediated anti-inflammatory processes occur

A
  • feedback on lipid mediator synthesis
  • less oxidative stress
  • more efferocytosis
  • less oxLDL uptake
  • more collage production
  • fewer proteases
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15
Q

Describe pro-inflammatory feedback in atherscelerosis

A
  1. uptake of modified LDL partciles such as oxLDL through SRs –> intracellular accumulation of cholesterol crystals that can activate the inflammasome –> IL-1B secretion
  2. components of modified LDL can also ligate TLRs, triggering an intracellular signaling cascade that –> expression of a series of genes encoding pro-inflammaotry molecules (including cytokines, chemokines, eicosanoids, proteinases, oxidases, and co-stim molecules)
  3. ultimately, old foam cells die via apoptotic or non-apoptotic forms of regulated cell death
  4. pyropoptosis and necroptosis are pro-inflammaotry via release of pro-inflammaotry mediators
  5. unless foam cells and the macrophages that have consumed them return to the blood, all cholsteryl-ester-loaded cells contribute to the generation and growth of a pro-inflammatory necrotic lipid core (if no one cleans up the apoptotic debris –> bodies may repture –> inflammation)
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16
Q

Describe the conditions that would allow for deficient efferocytosis

A

increase of don’t-eat-me signals

  • inappropriate expression of CD47 on apoptotic cells –> CD47-SIRPa interaction

decrease of eat me signals

  • cleavage of MERTK by the protease ADAM17 on the macrophage
  • decrease surface levels of calreticulin on apoptotic cells
17
Q

What protein from oxLDL particles get taken in, processed and presented by APCs to T cells

A

ApoB100

18
Q

Describe how plaque rupture occurs and what the outcomes of rupture are

A

increase plaque fragility can –> rupture and release of the necrotic core to the lumen of the vasculature –> quickly surrounded by platelets and coagulation factors forming a thrombus/clot

thrombus can become associated to the endothelium where it is assimilated –> narrowing of blood vessels

thrombus can be released to the blood stream where it can –> blockade of narrow (or narrowed) blood vessels –> MI or stroke

19
Q

What is myocardial infarction?

A

ventricle of the heart becomes noxic –> cell death

20
Q

describe cardiac remodelling vs adverse cardiac remodelling

A

cardiac remodelling –> scar formation, fibrosis (holds dead cells in place)

adverse cardiac remodelling –> ventricle becomes saggy –> heart failure

21
Q

What type of macrophages promote repair and which cells do their pro-regenerative factors affect?

A

Gata6+ macrophage –> pro-regenerative factors –> cardiomyocytes, endothelial cells, SMCs, fibroblasts

22
Q

what are the repair functions of cardiac macrophages?

A
  • Treg induction
  • fibrosis
  • repair angiogenesis
23
Q

Describe how MI can break tolerance of cardiac Ags

A
  1. there is a consititutive presentation of myocardial Ags in the context of MHC-II in s.s in myocardium
  2. resting/tolerogenic APCs prevent CD4+ T-cell activation and subsequent induction of autoimmunity in heart draining lymph nodes
  3. activation of APCs, for example, by PRR ligands released from injured myocardium or expression of pro-inflammatory cytokines –> increase co-stim molecules –> transitly breaks tolerance against myocardial Ags
24
Q

What determined a good outcome of inflammation in the context of antherscelerosis?

A
  • efficient efferocytosis
  • switch to anti-inflammatory mediators
  • efflux of cholesterol and inflammatory cells
  • lack of autoreactive responses
  • angiogenesis and moderative fibrosis