Stem cells and regenerative medicine

Question 1

What are stem cells?

Answer 1

• Cells that can differentiate into many different cell types depending on signals they recieve
• Self-renewing by cell division
• Gives new cells and replaces cells that are damaged

Question 2

There are three main sources of stem cells.

Describe adult stem cells

Answer 2

• Rare, supplies new cells and replaces damaged cells
• Varies with different organs, skin has greater ability to replace damaged tissue than heart
• Tissue specific and multipotent
• Some ASC’s show plasticity e.g those in bm, can differentiate into variety of cells

Question 3

Describe embryonic stem cells

Answer 3

• Supply all cells of developing embryo
• Pluripotent can differentiate into every type of cell
• derived from embryos at blastocyst stage - stem cells are in inner cell mass
• give rise to cells in all 3 embryonic germ layers
• and each germ layer gives rise to specific tissue
  
  • ectoderm - produces nervous, epithelial and sensory tissue
  • mesoderm - skeletal, cardiac muscle and blood and connective tissues
  • endoderm - lungs, pancreas, stomach, liver, germ cells

Question 4

How are induced pluripotent stem cells produced?

Answer 4

• Made in lab
• Take normal differentiated tissues such as skin, reprogramme cells by exposure to pluripotency factors e.g OCT4,SOX2,KILF4,CMICK to produce pluripotent stem cells
• cells used for cell therapy, repairing mutations using gene editing like CRISPR, differentiated back to healthy cells then transplanted back into patients
• cells specific to patient so reduces graft rejection by host
• used in disease modelling, drug screening, 3D organoid models, developmental biology, cell replacement therapy, model for basic and translational studies

Question 5

What are stem cell niches? What are their specific features?

Answer 5

Tissue specific stem cells are maintained in special supportive microenvironments called stem cell niches.

• Supporting ECM (extracellular matrix molecules such as collagen)
• Neighbouring niche cells
• Secreted soluble signalling factors e.g growth factors and cytokines
• Physical parameters; shear stress, tissue stiffness and topography
• Environmental signals (metabolites, hypoxia, inflammation etc)

Question 6

What considerations do you need to take when assessing the suitability of a particular stem cell type for study or therapy?

Answer 6

Unregulated stem cell proliferation can produce tumours

• Likely with embryonic stem cells due to unlimited growth potential
• IPSC have less growth potential
• Adult stem cells even less growth potential so have lower risk of tumour production

Growth potential also affects number of cells available to work with, embryonic most available.

Risk of rejection

• low with ASCs and IPSCs as derived from and for speciifc patient
• embryonic likely to be genetically different - higher risk

Risk of disease causing mutation being in stem cell

• Embryonic stem cell has lower mutation rate and high genetic stability
• IPSC and ASM more at risk of spontaneous disease causing mutations

Ethical considerations

• human embryonic stem cells derived from surplus in vitro fertilised embryos
• some consider destruction of embryos to make stem cells unethical

Question 7

What are the four Yamanaka pluripotency factors?

Answer 7

Four transcription factors

• Oct4
• Sox2
• Kilf4
• C-Myc

NANOG can also play a role in reprogramming.

Question 8

How do the four Yamanaka pluripotency factors work?

Answer 8

• C-Myc promotes DNA replication and relaxes chromatin structure
• Allows Oct4 to access its target genes
• Sox2 and Klf4 also co-operate with Oct4 to activate target genes
• These encode transcription factors which establish the pluripotent transcription factor network
• Results in the activation of the epigenetic processes (more open chromatin) that establish the pluripotent epigenome
• The iPSCs cells have a similar global gene expression profile to that of ES cells

Question 9

How can stem cells be tracked in animal modes?

Answer 9

Manipulated in vitro, inserting a reporter gene e.g one that makes cells fluorescent.

Question 10

How can stem cells be used to promote neovascularisation?

Answer 10

• Stem cells that differentiate into new coronary vessels or by cell-three therapies
• improves circulation at injury site, which in turn promotes paracrine stimulation of endogenous cardiomyocytes

Question 11

What model organisms can regenerated cardiac tissue?

Answer 11

• Zebrafish, apex of heart is removed surgically or by cryoinjury, by two months entire injury site has been regenerated with new cardiomyocytes
• see free expression of developmental gene programmes early after the injury - Raldh2 and WT1

Other organisms like neonatal mice and amphibans can regenerate hearts. Larger mammals like pigs, primates cannot, instead forms fibrotic scar.

Question 12

How are lymphatics and immune response important in cardiac regeneration?

Answer 12

• In normal/control injury response lymphatic system doesn’t clear excess tissue fluid and inflammatory immune cells efficiently - leads to oedema and inflammation, produces poor cardiac repair and function
• If lymphatic system is stimulated with modified VEGFC there is increased lymphatic response, improves clearance of tissue fluid and inflammatory cells, reduces oedema and inflammation. - improves cardiac repair and function

Question 13

How are cardiac lineages made from iPSC cells?

Answer 13

• iPSCs specified towards precardiac mesoderm by inhibition of glycogen synthase kinase 3B /GSK-3B (beta)
• acts as downstream switch for signaling pathways
• Wnt signalling inhibited
• Leads to differentiation of cardiac progenitor cells
• Specific signalling molecules differentiates cells towards specialised cardiac lineages e.g epicardium, cardiac fibroblasts, cardiomyocytes, smooth muscle, endothelial cells

Question 14

What is myocardial thymosin Beta-4 necessary for?

What can its addition in adult hearts do?

Answer 14

It is a small molecule produced by cardiomyocytes.

Necessary for epicardial migration into myocardium where it forms coronary vasculature required for cardiomyocyte survival.

TB4 in adult hearts stimulates epicardial outgrowth and neovascularisation by reactivating epicardial gene programmes.

And by Tb4 priming there is re-expression of embryonic epicardial gene Wt1.

Question 15

How are stem cell based therapies used for cancer?

Answer 15

• Chemo/radiotherapy kills cancerous cells. Stem cell transplantation rescontitutes healthy cells e.g HSC transplant for blood cells and leukocytes, replaces cancerous blood cells with healthy blood cells and leukocytes (ASC, iPSC)
• Effector immune cells from iPSC/ESCs e.g NK and T cells, targeted immunotherapy against specific cancer cells.
  
  • engineered by treating with specific factors SCF, IL-7, FLT3L
• in anti-cancer vaccines, targets cancer - stem cells attracted to tumours
• Mesencymal/neural stem cells deliver genes, nanoparticles and oncolytic viruses to tumour niches

Question 16

How are stem cell based therapies used to treat burns?

Answer 16

Stem cells speeds up replacement of lost skin cells, speeds up endogenous healing by generating ECM and paracrine signals. Delivered by cell sprays, dressings, 3D printing of cell sheets.

• Fetal fibroblasts (ESCs); improve skin repair due to high expansion ability, low immunogenicity and intense secretion of bioactive substances such as as FGFs, VEGFs, KGFs
• Epidermal stem cells; high proliferation rate and easy access and keep their potency and differentiation potential for long periods. Generate most skin cell types for repair and regeneration
• Mesenchymal stem cells; they have a high differentiation potential and a certain degree of plasticity. Migrate to the injured tissues, differentiate and regulate the tissue regen by the production of growth factors, cytokines and chemokines
• IPSCs can be differentiated into all cell types of skin layers, including dermal fibroblasts, keratinocytes and melanocytes

Question 17

How are stem cell therapies used for eye injury/disease?

Answer 17

• Limbal stem cells at cornea responsible for making new corneal cells, replace damaged ones
• If lost due to injury/disease then cornea can’t be repaired, light can’t enter eye, significant loss of vision
• Limbal stem cells collected from healthy donor eye, grown in lab, transplanted back into damaged eye
• repairs cornea, permanently restores vision
• only works if patient has healthy secretion of limus from whch to collect limbal cells
• Or iPSCs can be induced to make corneal epithelial cells to transplant
• Or right signals can transfer fibroblast clls into limbal stem cells

Question 18

How are stem cells used to repair the retina?

Answer 18

Retina converts light into neural signals.

• Retinal pigment epithelium underlies photoreceptor cells (rods and cones) - single layer of post-mitotic cells
• RPE has role in retina maintenance and parts of retina can die without function RPE - loss of vision
• Can be damaged due to diseases e.g age-related macular generation, retinitis pigmentosa, Leber’s congenital anuerosis
• RPE cells have been made from ESC and iPSCs, cultured with GF, amplified via cell divsion - differentiated into RPE cells
• Replaced back in eye, restoring vision

Question 19

How are stem cells used in spinal injury?

Answer 19

• Somatic biopsies from patient, transform these into iPSC via reprogramming factors
• differentiated into neural stem cells, implanted at site of spinal cord injury
• differentiate into variety of cells necessary for neural regeneration e.g neural progenitor cells, oligodendrocytes, neurones, astrocytes, mesenchymal stromal cells

Question 20

How are neural stem/progenitor grafts used?

Answer 20

Can integrate into sites of spinal cord injury (SI) and generate neuronal relays across lesions.

NSPC grafts organise into localised and spontaneously active synaptic networks - seen by calcium imaging

Optogenetic stimulation of host axons produced a neuronal response in the graft