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Query: EC:3.1.1.7 (
acetylcholinesterase
)
28,390
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The behavior of host and donor cell lines in human split-thickness skin grafts onto nude mice was studied by in situ hybridization (ISH) using genomic DNAs as probes, and immunohistochemically with species-specific or cross-species specific antibodies, at different stages ranging from day 3 to more than 1 year following grafting. Changes in the graft vascular and interstitial extracellular matrix were also assessed using species-specific or cross-species specific antibodies to human or murine type I, III, and IV collagens. Finally, transplant reinnervation was investigated using antibodies to various nerve cytoplasmic antigens and the thiocholine method to demonstrate
acetylcholinesterase
. Using these methods we were able to show the following: (1) the graft epidermis that is not replaced by mouse keratinocytes is progressively colonized by recipient Langerhans cells (LCs); (2) revascularization of the grafts begins soon by inoculation of the graft vessels with the host microcirculatory bed, and mouse endothelial cells growing into preexisting human capillary tubes produce a new basement membrane, prior to the replacement of the original one; (3) within 3-5 days following grafting, mouse fibroblasts migrate into the graft dermis. The density of the human and murine fibroblast populations then progressively increases. Characterization of the interstitial collagens identifies both human and murine type I and III collagens. Production of type III collagens decreases during the progression of fibrogenesis while human type I collagen becomes the predominant
matrix protein
; (4) transplant reinnervation is deficient, and neurites growing into severed graft nerve trunks were never detected.
...
PMID:Host-donor interactions in healing of human split-thickness skin grafts onto nude mice: in situ hybridization, immunohistochemical, and histochemical studies. 158 62
Aplysia, a marine mollusc, has significant amounts of
acetylcholinesterase
in its hemolymph, reaching maximum levels in the adults with reproductive maturity [Srivatsan M., et al. (1992) J.
comp
. Physiol. 162, 29-37]. Since hemolymph of mature Aplysia is neurotrophic to Aplysia neurons in culture [Schacher S. and Proshanski E. (1983) J. Neurosci. 3, 2403-2413], we examined whether
acetylcholinesterase
is a hemolymph neurotrophic factor. Dopaminergic neurons from the pedal ganglia of young adult Aplysia were maintained in culture in defined medium or defined medium supplemented with hemolymph. After 24 h, neurons in defined medium supplemented with hemolymph were well attached to the substratum and exhibited multiple, long neurites. In contrast, neurons in defined medium alone attached poorly and exhibited one or two short neurites. When
acetylcholinesterase
was inhibited with a specific, membrane-impermeable inhibitor (1,5-bis(4-allyldimethylammoniumphenyl)-pentan-3-one dibromide) which binds to its catalytic and peripheral anionic sites, the neurotrophic effect of hemolymph was significantly reduced. However, inhibition of the catalytic site alone with membrane impermeable echothiophate still resulted in enhanced neurite growth. An analogue of acetylcholine, carbachol, which is not hydrolysed by
acetylcholinesterase
, did not interfere with neurite growth when added to the supplemented medium. Acetylcholinesterase isolated from the hemolymph and highly purified human
acetylcholinesterase
also promoted neurite growth in Aplysia neurons. These results show that i)
acetylcholinesterase
circulating in the hemolymph promotes neurite growth of adult neurons in culture; ii) the growth promoting action of
acetylcholinesterase
is independent of its function of hydrolysing acetylcholine and iii) the peripheral anionic site of
acetylcholinesterase
appears to be involved in neurite regeneration.
...
PMID:Acetylcholinesterase promotes regeneration of neurites in cultured adult neurons of Aplysia. 907 Jul 63
The adhesive interactions that occur between bone cells and the developing matrix during bone formation help guide coupled remodeling and the maintenance of bone mass. Here, we provide evidence that
acetylcholinesterase
(
AChE
) is a novel osteoblast-derived mediator of cell-matrix interactions in bone. These findings complement an increasing body of evidence which suggests that
AChE
, in addition to its role in terminating cholinergic signaling, may be instrumental in regulating cellular differentiation and adhesion. We have shown, using RT-PCR, that osteosarcoma cell lines and primary cultures of osteoblasts express
AChE
mRNA. Expression appeared to be differentiation-dependent, and restricted to
AChE
splice variants containing the T subunit (exon 6). Immunofluorescent localization demonstrated that these osteoblastic cells expressed protein for
AChE
with an intracellular vesicular distribution. Immunohistochemistry on tissue sections confirmed
AChE
expression by osteoblasts in vivo, and revealed the presence of
AChE
along cement lines, also identified by enzyme histochemistry. In vitro functional studies indicated that osteoblast-like cells adhered specifically to and spread on
AChE
substrates, but did not interact with butyrylcholinesterase, a closely related protein. Our evidence strongly implicates
AChE
as a novel bone
matrix protein
, capable of mediating cell-matrix interactions, and as such may be a principal participant in organized bone formation and the regulation of remodeling.
...
PMID:Osteoblast-derived acetylcholinesterase: a novel mediator of cell-matrix interactions in bone? 1022 41
Although best known for its role in cholinergic signalling, a substantial body of evidence suggests that
acetylcholinesterase
(
AChE
) has multiple biological functions. Previously, we and others identified
AChE
expression in areas of bone that lacked expression of other neuronal proteins. More specifically, we identified
AChE
expression at sites of new bone formation suggesting a role for
AChE
as a bone
matrix protein
. We have now characterised
AChE
expression, secretion and adhesive function in osteoblasts. Using Western blot analysis, we identified expression of two
AChE
species in osteoblastic cells, a major species of 68 kDa and less abundant species of approximately 55 kDa.
AChE
colocalised with the Golgi apparatus in osteoblastic cells and was identified in osteoblast-conditioned medium. Further analyses revealed differentiation-dependent secretion by osteoblasts, with
AChE
secretion levels corresponding with alkaline phosphatase activity.
AChE
expression by osteoblastic cells was also found to be regulated by mechanical strain both in vitro and in vivo. Finally, we investigated the possibility of a functional role for
AChE
in osteoblast adhesion. Using specific inhibitors, blockade of sites thought to be responsible for
AChE
adhesive properties caused a concentration-dependent decrease in osteoblastic cell adhesion, suggesting that
AChE
is involved in regulating cell-matrix interactions in bone.
...
PMID:Characterization of acetylcholinesterase expression and secretion during osteoblast differentiation. 1545 88
