A role of melanin-concentrating hormone producing neurons in the central regulation of paradoxical sleep

Background

Peptidergic neurons containing the melanin-concentrating hormone (MCH) and the hypocretins (or orexins) are intermingled in the zona incerta, perifornical nucleus and lateral hypothalamic area. Both types of neurons have been implicated in the integrated regulation of energy homeostasis and body weight. Hypocretin neurons have also been involved in sleep-wake regulation and narcolepsy. We therefore sought to determine whether hypocretin and MCH neurons express Fos in association with enhanced paradoxical sleep (PS or REM sleep) during the rebound following PS deprivation. Next, we compared the effect of MCH and NaCl intracerebroventricular (ICV) administrations on sleep stage quantities to further determine whether MCH neurons play an active role in PS regulation.

Results

Here we show that the MCH but not the hypocretin neurons are strongly active during PS, evidenced through combined hypocretin, MCH, and Fos immunostainings in three groups of rats (PS Control, PS Deprived and PS Recovery rats). Further, we show that ICV administration of MCH induces a dose-dependant increase in PS (up to 200%) and slow wave sleep (up to 70%) quantities.

Conclusion

These results indicate that MCH is a powerful hypnogenic factor. MCH neurons might play a key role in the state of PS via their widespread projections in the central nervous system.

     

All-cis helical polypeptides

The possibility of all-cis open-chain polypeptides is rarely addressed, owing to three main reasons, namely, (i) the extreme scarcity of cis peptide bonds in naturally occurring proteins and peptides, (ii) the lesser thermodynamic stability (by about 2.5 kcal/mol) of cis amide bonds with respect to their trans counterparts, and (iii) widely held preconceptions about the so-called "steric clash" between lateral chains borne by two successive alpha carbons. Quantum-chemistry calculations performed on alanine tridecamers show how the latter constraints can be efficiently relieved through proper phi/psi adjustments along the backbone, leading to several helical arrangements--presumably the only permitted regular structures. Four more-or-less regular helices were thus characterized, one of them, a superhelix, exhibiting intramolecular hydrogen bonds. Understanding and anticipating all-cis open-chain structures not only make use of the classical Ramachandran maps at each C alpha i, relating to E = f(phi i,psi i), but also require the profile of a new kind of conformational dependence, the plaque maps, relating to E = f(phi i,psi i-1). The obvious coupling between two such maps enforces conformational dependence between two consecutive C alpha's, somewhat questioning in this context the customary "local effects", and presumably reducing the whole chain plasticity. Whereas cis thermodynamic penalty cannot be abolished locally, energy clues indicate that assembling cis-prepared building units is an exothermic process. Besides, once built up, the all-cis backbone should be difficult to unlock, thus affording reasonable kinetic stability.     

Influence of 40 Hz and 100 Hz Vibration on SH-SY5Y Cells Growth and Differentiation—A Preliminary Study

(1) Background: A novel bioreactor platform of neuronal cell cultures using low-magnitude, low-frequency (LMLF) vibrational stimulation was designed to discover vibration influence and mimic the dynamic environment of the in vivo state. To better understand the impact of 40 Hz and 100 Hz vibration on cell differentiation, we join biotechnology and advanced medical technology to design the nano-vibration system. The influence of vibration on the development of nervous tissue on the selected cell line SH-SY5Y (experimental research model in Alzheimer’s and Parkinson’s) was investigated. (2) Methods: The vibration stimulation of cell differentiation and elongation of their neuritis were monitored. We measured how vibrations affect the morphology and differentiation of nerve cells in vitro. (3) Results: The highest average length of neurites was observed in response to the 40 Hz vibration on the collagen surface in the differentiating medium, but cells response did not increase with vibration frequency. Also, vibrations at a frequency of 40 Hz or 100 Hz did not affect the average density of neurites. 100 Hz vibration increased the neurites density significantly with time for cultures on collagen and non-collagen surfaces. The exposure of neuronal cells to 40 Hz and 100 Hz vibration enhanced cell differentiation. The 40 Hz vibration has the best impact on neuronal-like cell growth and differentiation. (4) Conclusions: The data demonstrated that exposure to neuronal cells to 40 Hz and 100 Hz vibration enhanced cell differentiation and proliferation. This positive impact of vibration can be used in tissue engineering and regenerative medicine. It is planned to optimize the processes and study its molecular mechanisms concerning carrying out the research.