Easy In Vitro Synthesis of Optimised Functioning Reporter mRNA from Common eGFP Plasmid.

The extensive growth in number and importance of experiments and clinical-aimed techniques based solely or majorly on the activity of RNA strands, e.g. CRSPR/Cas9 and siRNA, has put emphasis on the necessity of standardisation of experiments with RNA. Considering RNA degradation during its handling seems to be a major hindrance in all RNA-based tools, the assessment of its integrity is of utmost importance. Furthermore, evaluating whether the RNA to be transfected is intact requires time-consuming electrophoresis protocol. In view of the RNA lability and the necessity for controlling experiments performed with this molecule, the transfection of a reporter mRNA may be of aid in optimising experiments. Nevertheless, commercial reporter mRNAs are far less available than plasmids for such purpose. Thus, in this work, we aimed at the optimisation of an easily performed protocol to produce a suitable eGFP mRNA. By utilising molecular biology kits customarily employed in molecular biology laboratories working with RNA-based techniques and starting from any eGFP coding vector, we produced four mRNA molecules: (1) eGFP mRNA (non-polyadenylated); (2) Kozak-eGFP mRNA (non-polyadenylated, produced from the Kozak-containing amplicon); (3) eGFP-PolyA mRNA (polyadenylated); (4) Kozak-eGFP-PolyA mRNA (containing both signals, Kozak sequence and poly(A) tail). These mRNA molecules were transfected into HEK 293 FT cells, readily transfectable, and into the MDBK bovine lineage, which has been observed as difficult-to-transfect DNA constructs. eGFP expression could be detected both by flow cytometry and by fluorescence microscopy after transfection with the polyadenylated mRNAs. Upon cytometric analysis, we noted a marked difference among the mRNA groups (p < 0.01), both in fluorescent population percentage and in florescence intensity. We showed here the necessity of the polyadenylation step in order to achieve cell expression of the eGFP observable under fluorescence microscopy. The presence of the Kozak sequence, as a 5' element, seems to augment significantly the level of protein produced upon mRNA transfection. We presented here an easy protocol to allow production of functioning mRNAs from any DNA construct. The molecules produced may aid in the standardisation and controlling most of the RNA-related experiments as well as it gives proper guidance for researchers performing expression of other proteins through mRNA transfection.

Importance of major histocompatibility complex of class I (MHC-I) expression for astroglial reactivity and stability of neural circuits in vitro.

MHC-I molecules are involved in the antigenic presentation of cytosol-derived peptides to CD8T lymphocytes. In the nervous system, MHC-I expression is low to absent, occurring only during certain phases of development and aging or after injuries. The involvement of MHC-I in synaptic plasticity has been reported and, following lesion, astrocytes become reactive, limiting tissue damage. Such cells also attempt to restore homeostasis by secreting cytokines and neurotrophic factors. Moreover, astrocytes modulate synapse function, by taking up and releasing neurotransmitters and by limiting the synaptic cleft. Thus, the aim of the present study was to evaluate if astrocyte activation and reactivity are related to MHC I expression and if astrogliosis can be downregulated by silencing MHC-I mRNA synthesis. Given that, we evaluated astrocyte reactivity and synaptogenesis in co-cultures of astrocytes and spinal neurons under MHC-I RNA interference. For that, the MHC-I ß2-microglobulin subunit (ß2m) was knocked-down by siRNA in co-cultures (ß2m expression <60%, p<0.001). As measured by qRT-PCR, silencing of ß2m decreased expression of the astrocytic marker GFAP (<60%, p<0.001), as well as neurotrophic factors (BDNF and GDNF) and pro-inflammatory cytokines (TNF-α, IL-1, IL-6, IL-12 and IL-17). No significant changes in synaptic stability indicate that neuron-neuron interaction was preserved after ß2m silencing. Overall, the present data reinforce the importance of MHC-I expression for generation of astrogliosis, what may, in turn, become a target for future CNS/PNS therapies following injury.

Triggering of protection mechanism against Phoneutria nigriventer spider venom in the brain.

Severe accidents caused by the "armed" spider Phoneutria nigriventer cause neurotoxic manifestations in victims. In experiments with rats, P. nigriventer venom (PNV) temporarily disrupts the properties of the BBB by affecting both the transcellular and the paracellular route. However, it is unclear how cells and/or proteins participate in the transient opening of the BBB. The present study demonstrates that PNV is a substrate for the multidrug resistance protein-1 (MRP1) in cultured astrocyte and endothelial cells (HUVEC) and increases mrp1 and cx43 and down-regulates glut1 mRNA transcripts in cultured astrocytes. The inhibition of nNOS by 7-nitroindazole suggests that NO derived from nNOS mediates some of these effects by either accentuating or opposing the effects of PNV. In vivo, MRP1, GLUT1 and Cx43 protein expression is increased differentially in the hippocampus and cerebellum, indicating region-related modulation of effects. PNV contains a plethora of Ca(2+), K(+) and Na(+) channel-acting neurotoxins that interfere with glutamate handling. It is suggested that the findings of the present study are the result of a complex interaction of signaling pathways, one of which is the NO, which regulates BBB-associated proteins in response to PNV interference on ions physiology. The present study provides additional insight into PNV-induced BBB dysfunction and shows that a protective mechanism is activated against the venom. The data shows that PNV has qualities for potential use in drug permeability studies across the BBB.

Preservação da proteína verde fluorescente no tecido ósseo descalcificado / Preservation of the green fluorescent protein on decalcified bone tissue

A proteína verde fluorescente (GFP) foi originalmente descoberta no cnidário Aequorea victoria. Células-tronco GFP positivas podem ser rastreadas in vivo quando usadas na terapia de doenças. No entanto, no osso, a fluorescência gerada pela GFP pode ser perdida durante o processo de descalcificação, dificultando o rastreamento das células-tronco usadas no tratamento de doenças ou defeitos ósseos. O objetivo deste estudo foi comparar diferentes técnicas de preservação da GFP no tecido ósseo descalcificado. Foram utilizados fêmures de ratas GFP Lewis distribuídos em quatro grupos: 1) descalcificado em ácido fórmico e incluído em parafina; 2) descalcificado em ácido fórmico e submetido à criomicrotomia; 3) descalcificado em EDTA e incluído em parafina; e 4) descalcificado em EDTA com criomicrotomia. Secções de tecido ósseo de todos os grupos foram analisadas para identificação da fluorescência natural e posteriormente submetidas à imunofluorescência, sendo utilizados anti-GFP e Alexa Flúor 555. As imagens foram obtidas por microscopia confocal. Osteócitos, osteoblastos e células da medula óssea de ratos GFP somente tiveram sua fluorescência natural preservada no tecido ósseo descalcificado em EDTA e submetido à microtomia por congelação. Nos demais grupos, houve perda da fluorescência natural, e as células GFP somente puderam ser identificadas com o uso da reação de imunofluorescência com anti-GFP. Conclui-se que a descalcificação em EDTA e a criomicrotomia são as melhores técnicas para preservar a fluorescência natural das células GFP no tecido ósseo e que a visualização de células GFP em tecido ósseo descalcificado em ácido fórmico e incluído em parafina somente pode ser realizada com o uso da técnica de imunofluorescência.

Green fluorescent protein (GFP) was originally derived from the cnidarians Aequorea victoria. GFP-positive stem cells can be tracked in vivo when used in the therapy of diseases. However, in the bone, the fluorescence generated by GFP can be lost during the decalcification process, hindering the tracking of stem cells used in the treatment of diseases or bone defects. The aim of this study was to compare different techniques of preservation of GFP in the decalcified bone tissue. Femurs of female Lewis GFP rats were distributed in four groups: 1) decalcified in formic acid and paraffin-embedded; 2) decalcified in formic acid submitted to cryomicrotomy; 3) decalcified in EDTA and paraffin-embedded and 4) decalcified in EDTA with cryomicrotomy. Sections of bone tissue of all the groups were analyzed for identification of the natural fluorescence and subsequently submitted to the immunofluorescence using anti-GFP and Alexa Flúor 555. The images were obtained by confocal microscopy. Osteocytes, osteoblasts and bone marrow cells of GFP rats only had natural fluorescence preserved in the bone tissue decalcified in EDTA and submitted to cryomicrotomy. In others groups there were loss of the natural fluorescence and the GFP cells could be only identified with the use of the immunofluorescence with anti-GFP. In conclusion, the decalcification in EDTA and the cryomicrotomy are the best techniques to preserve the natural fluorescence of the GFP cells in the bone tissue and the GFP cells in bone tissue decalcified in formic acid and paraffin-embedded can be visualized only with the use of the immunofluorescence with anti-GFP.