Angiocrine growth factors

Angiocrine growth factors are molecules found in

endothelial cells that can stimulate organ-specific repair activities in damaged or diseased organs. Endothelial cells possess tissue-specific genes that code for unique growth factors, adhesion molecules and factors regulating metabolism.^[1]^[2]

The discovery emerged after the entirety of active genes in endothelial cells was decoded, resulting in an atlas of organ-specific blood vessel cells. The atlas documented hundreds of already-known genes that had never been associated with these cells. Organs dictate the structure and function of their own blood vessels, including the repair molecules they secrete. Each organ produces blood vessels with unique shape and function that comply that organ's metabolic demands.[1]^[3]

Organ repair

When an organ is injured, its blood vessels may not be able to repair the damage because they may themselves be damaged or inflamed. An infusion of engineered endothelial cells may be able to engraft into injured tissue and acquire the capacity to repair the organ.^[1]

Endothelial cells generated from mouse embryonic stem cells were functional, transplantable and responsive to microenvironmental signals. Such cells can be transplanted into different tissues, become educated by the tissue and acquire the characteristic phenotype of that organ type's endothelials. Such cells were transplanted into the liver and kidney of mice and found became indistinguishable from existing endothelial cells.^[1]

In a clinical setting the cells must be immunocompatible with the recipient patient. They could be derived from the patient's embryonic pluripotent stem cells as well as by somatic cell nuclear transfer (SCNT). In SCNT the nucleus is introduced into a human egg producing embryonic stem cells that are a genetic match of the patient. Another approach takes cells discarded after a diagnostic prenatal amniocentesis.^[1]

Additional preclinical investigation is required before investigation with humans.^[1]

References

^ ^a ^b ^c ^d ^e ^f "Blood vessel cells can repair, regenerate organs, scientists say". Medicalxpress.com. Retrieved 2013-10-11.
PMID 23871589
.

PMID 23963623
.

v
t
e
Epithelial tissue
Cells

Squamous

Cuboidal

Columnar

Types
Simple

Simple squamous epithelium
Endothelium

Mesothelium

Simple cuboidal epithelium

Simple columnar epithelium

stratified

Stratified squamous epithelium

Stratified cuboidal epithelium

Stratified columnar epithelium

Other

Pseudostratified columnar epithelium
Respiratory epithelium

Transitional epithelium
Urothelium

Glands
Types
Mechanism

Merocrine
Eccrine

Apocrine

Holocrine
Sebaceous

Meibomian

Shape

Tubular gland

Alveolar gland

Secretion

Serous glands

Mucous glands

Components

Myoepithelial cell

Serous demilune

Ducts
Intralobular

Striated

Intercalated

Acinus/Lobe

v
t
e
Arteries and veins
Vessels
Arteries

Nutrient artery

Arteriole
Metarteriole

Elastic artery

Capillaries

Types
Continuous

Fenestrated

Sinusoidal

Precapillary sphincter

Precapillary resistance

Veins

Vena comitans

Superficial vein

Deep vein

Perforator vein

Emissary veins

Venous plexus

Venule

Lymph

Lymphatic vessel

Lymph

Lymph capillary

Circulatory system
Systemic
Left heart → Aorta → Arteries → Arterioles → Capillaries → Venules → Veins → Vena cava → (Right heart)
Pulmonary
Right heart → Pulmonary arteries → Lungs → Pulmonary vein → (Left heart)
Microanatomy

Microvessel

Microcirculation

Tunica intima
Endothelium

Internal elastic lamina

Tunica media

Tunica externa

Vasa vasorum

Vasa nervorum

Vascular nerves

Rete mirabile

Circulatory anastomosis

Retrieved from "https://en.wikipedia.org/w/index.php?title=Angiocrine_growth_factors&oldid=932008463"

[me1013-1] ^ ^a ^b ^c ^d ^e ^f "Blood vessel cells can repair, regenerate organs, scientists say". Medicalxpress.com. Retrieved 2013-10-11.

[2] PMID 23871589
.

[3] PMID 23963623
.

[1]

[2]

[3]