Backtransplantation of chick cardiac neural crest cells cultured in LIF rescues heart development

ML Kirby, DH Kumiski, T Myers, C Cerjan… - Developmental …, 1993 - Wiley Online Library
ML Kirby, DH Kumiski, T Myers, C Cerjan, N Mishima
Developmental dynamics, 1993Wiley Online Library
The cardiac neural crest is essential for normal development of the cardiovascular system.
Cardiac neural crest cells are derived from the neural folds located between the mid‐otic
placodes and the caudal limit of somite 3. These crest cells can differentiate into a variety of
mesenchymal cell types that support cardiovascular development, in addition to neurogenic
cells. When cultured, many expressα‐smooth muscle actin or neurofilaments and lose their
undifferentiated neural crest phonotype as shown by a decrease in HNK‐1 reactivity. We …
Abstract
The cardiac neural crest is essential for normal development of the cardiovascular system. Cardiac neural crest cells are derived from the neural folds located between the mid‐otic placodes and the caudal limit of somite 3. These crest cells can differentiate into a variety of mesenchymal cell types that support cardiovascular development, in addition to neurogenic cells. When cultured, many expressα‐smooth muscle actin or neurofilaments and lose their undifferentiated neural crest phonotype as shown by a decrease in HNK‐1 reactivity. We wanted to determine whether cultured cardiac neural crest cells maintained the potency to support normal heart development when backtransplanted into embryos lacking their native cardiac neural crest. Under usual circumstances removal of the cardiac neural crest results in 80–100% incidence of persistent truncus arteriosus. The present study report a system in which cardiac neural folds are cultured for 3 days and the cells backtransplanted into chick embryos after laser‐induced ablation of the intrinsic cardiac neural folds. Rescue of heart development was improved 50% when cultured cells were backtransplanted and almost 200% when the backtransplanted cells had been cultured in leukemia inhibitory factor (LIF). To determine whether the cultured cells are capable of following normal migratory routes, cultured homospecific cardiac neural crest cells were tagged with DiI. Initially, fluorescent cells were found concentrated around the neural tube. By the second day following backtransplantation, the cells had migrated to the circumpharyngeal crest, populated the pharyngeal arches and aortic arch arteries, and were in the region of the cardiac outflow tract. By the third day, the labeled cells had dispersed, but could be found around the neural tube, esophagus, cardiac outflow tract, and within the dorsal root ganglia. Interestingly, a cranial migration to the periphery of the eyes was also noted. With the exception of the cranial migration to the eyes, cultured and backtransplanted cardiac neural crest cells followed normal migratory pathways to the cardiac outflow tract. LIF is used for the in vitro maintenance of the pluripotential phenotype of embryonic stem cells. In an effort to understand why LIF improves the ability of cultured neural crest cells to support normal heart development, we have examined the relationship of neural crest expression of HNK‐1 antigen,α‐smooth muscle actin, and neurofilament protein in neural crest cells cultured in LIF. LIF treatment resulted in an expanded period of expression of HNK‐1 antigen, associated with a decrease in expression ofα‐smooth muscle actin. The expanded period of HNK‐1 expression is associated with proliferation of the HNK‐1 positive cell population. Expression of the neurofilament was the same in cells cultured with or without LIF. © 1993 Wiley‐Liss, Inc.
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