Padronização de um método alternativo para diferenciação de células de neuroblastoma utilizando matriz extracelular rica em laminina para avaliação de ADAM10 e IDE em meios de cultivo hiperglicêmico e normoglicêmico
Resumen
Alzheimer’s disease (AD) is a gradual and progressive neurodegenerative disease
characterized by cortical atrophy predominantly in the medial temporal lobe and,
microscopically, by extensive neuronal losses and deposits called neurofibrillary tangles
and senile plaques. Since the results of the Rotterdam study in 1992, it has been known
that type 2 diabetes mellitus (T2DM) increases the risk of dementia. Patients with T2DM
present structural brain changes and cognitive impairment, with a high risk of developing
AD. These data suggest that insulin may play a fundamental role in brain activity and
memory formation. Based on these findings, AD has been called “type 3 diabetes”
(T3DM) or “cerebral diabetes” by some researchers. Some research groups have shown
that ADAM10, the α-secretase that inhibits the formation of senile plaques and, therefore,
is protective against AD, is altered in the blood of older adults with this dementia
compared to cognitively healthy older adults. In this sense, the objective of this study was
to verify whether there are differences in the levels and activity of ADAM10 in
neuroblastoma cells (SH-SY5Y), differentiated and undifferentiated, cultured in regular
and hyperglycemic cellular media, in a condition that simulates T2DM, as well as
concomitant changes in the levels of proteins involved in the insulin pathway, particularly
the insulin-degrading enzyme (IDE). The results showed that the extracellular matrix
(ECM) maintains the differentiation of neuronal cells for a more extended period, even
in an environment with a high glucose content. Furthermore, it was also possible to
observe a reduction in ADAM10 and IDE levels in SH-SY5Y cells differentiated and
cultured in a hyperglycemic environment. The results of this study highlight the
importance of the ECM in maintaining neuronal differentiation in vitro. Furthermore,
these results contribute to a deeper understanding of the molecular interactions between
T2DM and AD and provide valuable suggestions for future research in these areas. The
impact of this study is related to a better understanding of the biology of these diseases,
highlighting the need for more studies related to the implementation of new clinical
approaches to the treatment of AD, also observing the metabolic status of patients.
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