Lzts1 controls both neuronal delamination and outer radial glial-like cell generation during mammalian cerebral development.

In the developing central nervous system, cell departure from the apical surface is the initial and fundamental step to form the 3D, organized architecture. Both delamination of differentiating cells and repositioning of progenitors to generate outer radial glial cells (oRGs) contribute to mammalian neocortical expansion; however, a comprehensive understanding of their mechanisms is lacking. Here, we demonstrate that Lzts1, a molecule associated with microtubule components, promotes both cell departure events. In neuronally committed cells, Lzts1 functions in apical delamination by altering apical junctional organization. In apical RGs (aRGs), Lzts1 expression is variable, depending on Hes1 expression levels. According to its differential levels, Lzts1 induces diverse RG behaviors: planar division, oblique divisions of aRGs that generate oRGs, and their mitotic somal translocation. Loss-of-function of lzts1 impairs all these cell departure processes. Thus, Lzts1 functions as a master modulator of cellular dynamics, contributing to increasing complexity of the cerebral architecture during evolution.

Gliogenesis in the outer subventricular zone promotes enlargement and gyrification of the primate cerebrum.

The primate cerebrum is characterized by a large expansion of cortical surface area, the formation of convolutions, and extraordinarily voluminous subcortical white matter. It was recently proposed that this expansion is primarily driven by increased production of superficial neurons in the dramatically enlarged outer subventricular zone (oSVZ). Here, we examined the development of the parietal cerebrum in macaque monkey and found that, indeed, the oSVZ initially adds neurons to the superficial layers II and III, increasing their thickness. However, as the oSVZ grows in size, its output changes to production of astrocytes and oligodendrocytes, which in primates outnumber cerebral neurons by a factor of three. After the completion of neurogenesis around embryonic day (E) 90, when the cerebrum is still lissencephalic, the oSVZ enlarges and contains Pax6+/Hopx+ outer (basal) radial glial cells producing astrocytes and oligodendrocytes until after E125. Our data indicate that oSVZ gliogenesis, rather than neurogenesis, correlates with rapid enlargement of the cerebrum and development of convolutions, which occur concomitantly with the formation of cortical connections via the underlying white matter, in addition to neuronal growth, elaboration of dendrites, and amplification of neuropil in the cortex, which are primary factors in the formation of cerebral convolutions in primates.

Comparative Action of Cardiotonic Steroids on Intracellular Processes in Rat Cortical Neurons.

Binding to Na+,K+-ATPase, cardiotonic steroids (CTS) activate intracellular signaling cascades that affect gene expression and regulation of proliferation and apoptosis in cells. Ouabain is the main CTS used for studying these processes. The effects of other CTS on nervous tissue are practically uncharacterized. Previously, we have shown that ouabain affects the activation of mitogen-activated protein kinases (MAP kinases) ERK1/2, p38, and JNK. In this study, we compared the effects of digoxin and bufalin, which belong to different subclasses of CTS, on primary culture of rat cortical cells. We found that CTS toxicity is not directly related to the degree of Na+,K+-ATPase inhibition, and that bufalin and digoxin, like ouabain, are capable of activating ERK1/2 and p38, but with different concentration and time profiles. Unlike bufalin and ouabain, digoxin did not decrease JNK activation after long-term incubation. We concluded that the toxic effect of CTS in concentrations that inhibit less than 80% of Na+,K+-ATPase activity is related to ERK1/2 activation as well as the complex profile of MAP kinase activation. A direct correlation between Na+,K+-ATPase inhibition and the degree of MAP kinase activation is only observed for ERK1/2. The different action of the three CTS on JNK and p38 activation may indicate that it is associated with intracellular signaling cascades triggered by protein-protein interactions between Na+,K+-ATPase and various partner proteins. Activation of MAP kinase pathways by these CTS occurs at concentrations that inhibit Na+,K+-ATPase containing the α1 subunit, suggesting that these signaling cascades are realized via α1. The results show that the signaling processes in neurons caused by CTS can differ not only because of different inhibitory constants for Na+,K+-ATPase.

Retinoblastoma protein controls growth, survival and neuronal migration in human cerebral organoids.

The tumor suppressor retinoblastoma protein (RB) regulates S-phase cell cycle entry via E2F transcription factors. Knockout (KO) mice have shown that RB plays roles in cell migration, differentiation and apoptosis, in developing and adult brain. In addition, the RB family is required for self-renewal and survival of human embryonic stem cells (hESCs). Since little is known about the role of RB in human brain development, we investigated its function in cerebral organoids differentiated from gene-edited hESCs lacking RB. We show that RB is abundantly expressed in neural stem and progenitor cells in organoids at 15 and 28 days of culture. RB loss promoted S-phase entry in DCX+ cells and increased apoptosis in Sox2+ neural stem and progenitor cells, and in DCX+ and Tuj1+ neurons. Associated with these cell cycle and pro-apoptotic effects, we observed increased CCNA2 and BAX gene expression, respectively. Moreover, we observed aberrant Tuj1+ neuronal migration in RB-KO organoids and upregulation of the gene encoding VLDLR, a receptor important in reelin signaling. Corroborating the results in RB-KO organoids in vitro, we observed ectopically localized Tuj1+ cells in RB-KO teratomas grown in vivo Taken together, these results identify crucial functions for RB in the cerebral organoid model of human brain development.

Induction of Expansion and Folding in Human Cerebral Organoids.

An expansion of the cerebral neocortex is thought to be the foundation for the unique intellectual abilities of humans. It has been suggested that an increase in the proliferative potential of neural progenitors (NPs) underlies the expansion of the cortex and its convoluted appearance. Here we show that increasing NP proliferation induces expansion and folding in an in vitro model of human corticogenesis. Deletion of PTEN stimulates proliferation and generates significantly larger and substantially folded cerebral organoids. This genetic modification allows sustained cell cycle re-entry, expansion of the progenitor population, and delayed neuronal differentiation, all key features of the developing human cortex. In contrast, Pten deletion in mouse organoids does not lead to folding. Finally, we utilized the expanded cerebral organoids to show that infection with Zika virus impairs cortical growth and folding. Our study provides new insights into the mechanisms regulating the structure and organization of the human cortex.

The protective activity of imperatorin in cultured neural cells exposed to hypoxia re-oxygenation injury via anti-apoptosis.

Apoptosis is believed to play important roles in neuronal cell death associated with cerebral ischemia. We now provided evidence that imperatorin (IMp), the main composition of the dried root or rhizome of R Radix Angelicae Dahuricae, took advantage on oxygen glucose deprivated/reperfusion (OGD-R) SH-SY5Y cell line through neuronal apoptosis inhibition. Our data had shown that imperatorin reduced the number of apoptosis cells after OGD-R, this effect was associated with the inhibition of the apoptosis factors Bax and caspase-3, and the upregulation of anti-apoptosis factor Bcl-2. In the meantime, the protective factor BDNF was upregulated significantly by imperatorin treatment. In our experiment in vivo, imperatorin decreased the infract volume significantly in dose of 5 mg/kg and 10 mg/kg, and the behavior ability was increased in the 10mg/kg of imperatorin. Our observations show that imperatorin exerted protective effect on cerebral ischemia both in vitro and in vivo, this effect is associated with its anti-apoptosis function.

TNF-α promotes cerebral pericyte remodeling in vitro, via a switch from α1 to α2 integrins.

BACKGROUND: There is increasing evidence to suggest that pericytes play a crucial role in regulating the remodeling state of blood vessels. As cerebral pericytes are embedded within the extracellular matrix (ECM) of the vascular basal lamina, it is important to understand how individual ECM components influence pericyte remodeling behavior, and how cytokines regulate these events. METHODS: The influence of different vascular ECM substrates on cerebral pericyte behavior was examined in assays of cell adhesion, migration, and proliferation. Pericyte expression of integrin receptors was examined by flow cytometry. The influence of cytokines on pericyte functions and integrin expression was also examined, and the role of specific integrins in mediating these effects was defined by function-blocking antibodies. Expression of pericyte integrins within remodeling cerebral blood vessels was analyzed using dual immunofluorescence (IF) of brain sections derived from the animal model of multiple sclerosis, experimental autoimmune encephalomyelitis (EAE). RESULTS: Fibronectin and collagen I promoted pericyte proliferation and migration, but heparan sulfate proteoglycan (HSPG) had an inhibitory influence on pericyte behavior. Flow cytometry showed that cerebral pericytes express high levels of α5 integrin, and lower levels of α1, α2, and α6 integrins. The pro-inflammatory cytokine tumor necrosis factor (TNF)-α strongly promoted pericyte proliferation and migration, and concomitantly induced a switch in pericyte integrins, from α1 to α2 integrin, the opposite to the switch seen when pericytes differentiated. Inhibition studies showed that α2 integrin mediates pericyte adhesion to collagens, and significantly, function blockade of α2 integrin abrogated the pro-modeling influence of TNF-α. Dual-IF on brain tissue with the pericyte marker NG2 showed that while α1 integrin was expressed by pericytes in both stable and remodeling vessels, pericyte expression of α2 integrin was strongly induced in remodeling vessels in EAE brain. CONCLUSIONS: Our results suggest a model in which ECM constituents exert an important influence on pericyte remodeling status. In this model, HSPG restricts pericyte remodeling in stable vessels, but during inflammation, TNF-α triggers a switch in pericyte integrins from α1 to α2, thereby stimulating pericyte proliferation and migration on collagen. These results thus define a fundamental molecular mechanism in which TNF-α stimulates pericyte remodeling in an α2 integrin-dependent manner.

Enhanced nerve-mast cell interaction by a neuronal short isoform of cell adhesion molecule-1.

Close apposition of nerve and mast cells is viewed as a functional unit of neuro-immune mechanisms, and it is sustained by trans-homophilic binding of cell adhesion molecule-1 (CADM1), an Ig superfamily member. Cerebral nerve-mast cell interaction might be developmentally modulated, because the alternative splicing pattern of four (a-d) types of CADM1 transcripts drastically changed during development of the mouse cerebrum: developing cerebrums expressed CADM1b and CADM1c exclusively, while mature cerebrums expressed CADM1d additionally and predominantly. To probe how individual isoforms are involved in nerve-mast cell interaction, Neuro2a neuroblastoma cells that express CADM1c endogenously were modified to express additionally either CADM1b (Neuro2a-CADM1b) or CADM1d (Neuro2a-CADM1d), and they were cocultured with mouse bone marrow-derived mast cells (BMMCs) and BMMC-derived cell line IC-2 cells, both of which expressed CADM1c. BMMCs were found to adhere to Neuro2a-CADM1d neurites more firmly than to Neuro2a-CADM1b neurites when the adhesive strengths were estimated from the femtosecond laser-induced impulsive forces minimally required for detaching BMMCs. GFP-tagging and crosslinking experiments revealed that the firmer adhesion site consisted of an assembly of CADM1d cis-homodimers. When Neuro2a cells were specifically activated by histamine, intracellular Ca(2+) concentration was increased in 63 and 38% of CADM1c-expressing IC-2 cells that attached to the CADM1d assembly site and elsewhere, respectively. These results indicate that CADM1d is a specific neuronal isoform that enhances nerve-mast cell interaction, and they suggest that nerve-mast cell interaction may be reinforced as the brain grows mature because CADM1d becomes predominant.

Layer I as a putative neurogenic niche in young adult guinea pig cerebrum.

A considerable number of cells expressing typical immature neuronal markers including doublecortin (DCX+) are present around layer II in the cerebral cortex of young and adult guinea pigs and other larger mammals, and their origin and biological implication await further characterization. We show here in young adult guinea pigs that these DCX+ cells are accompanied by in situ cell division around the superficial cortical layers mostly in layer I, but they co-express proliferating cell nuclear antigen (PCNA) and an early neuronal fate determining factor, PAX6. A small number of these DCX+ cells also colocalize with BrdU following administration of this mitotic indicator. Cranial X-ray irradiation causes a decline of DCX+ cells around layer II, and novel environmental exploration induces c-Fos expression among these cells in several neocortical areas. Together, these data are compatible with a notion that DCX+ cortical neurons around layer II might derive from proliferable neuronal precursors around layer I in young adult guinea pig cerebrum, and that these cells might be modulated by experience under physiological conditions.

Attachment of stem cells to scaffold particles for intra-cerebral transplantation.

Cell-replacement therapy and tissue regeneration using stem cells are of great interest to recover histological damage caused by neuro-degenerative disease or traumatic insults to the brain. To date, the main intra-cerebral delivery for these cells has been as a suspension in media through a thin needle. However, this does not provide cells with a support system that would allow tissue regeneration. Scaffold particles are needed to provide structural support to cells to form de novo tissue. In this 16-d protocol, we describe the generation and functionalization of poly (D,L-lactic-co-glycolic) acid (PLGA) particles to enhance cell attachment, the attachment procedure to avoid clumping and aggregation of cells and particles, and their preparation for intra-cerebral injection through a thin needle. Although the stem cell-scaffold transplantation is more complicated and labor-intensive than cell suspensions, it affords de novo tissue generation inside the brain and hence provides a significant step forward in traumatic brain repair.

TNF activates P-glycoprotein in cerebral microvascular endothelial cells.

BACKGROUND/AIMS: Multidrug resistance proteins (MDRs, including P-glycoproteins) are efflux pumps that serve important biological functions but hinder successful drug delivery to the CNS. Many chemotherapeutic agents, anti-epileptics, anti-HIV drugs, and opiates are substrates for MDRs. Therefore, understanding the regulation of MDRs in the endothelial cells composing the blood-brain barrier has therapeutic implications. METHODS: We used microarray, real time RT-PCR, Western blotting, and uptake of vinblastine by RBE4 cerebral endothelial cells to test the effects of tumor necrosis factor alpha (TNF) on the expression and functions of P-glycoprotein (MDR1). RESULTS: The proinflammatory cytokine TNF specifically induced the expression and enhanced the function of MDR1 in RBE4 cells. The persistent upregulation of MDR1 mRNA was shown by cDNA microarray at 6, 12, and 24 h after TNF treatment. This was confirmed by real-time RT-PCR between 2 and 24 h. MDR1 protein expression was increased 6 to 24 h after TNF treatment and resulted in a significant reduction in the cellular uptake of (3)H-vinblastine. CONCLUSION: The drug efflux transporter in cerebral endothelial cells can be upregulated by TNF. This suggests that adjunctive anti-TNF treatment has novel therapeutic potential in conditions such as brain cancer, epilepsy, neuroAIDS, and chronic pain.

Tissue expression of platelet endothelial cell adhesion molecule-1 at pre and postnatal murine development

Endothelial cells, at the cell-cell borders, express PECAM-1, and have been implicated in vascular functions. The monoclonal antibody MEC 13.3 recognizers PECAM-1 molecule from mouse vessels and allows to analyse the ontogeny of mouse endothelium. At the present, little is known about the molecular basis of differentiation pathways of endothelial cells, that enables its morphological heterogeneity. The purpose of this study was to analyze the pattern of PECAM-1 expression, employing monoclonal antibody MEC 13.3, in cellular suspensions obtained from different mouse organs at pre and postnatal stages. Fluorescence activated cell sorter analysis showed a different profile of the glycoprotein expression in a cell population with size and granularity selected by 1G11 endothelial cell line. The expression differs from prenatal to postnatal developmental stages in a given organ, and among the organs studied. Another cell population, with a size and granularity higher than 1G11 endothelial cell line, coexists in cellular suspensions obtained from liver, gut and brain. These cells could be related to those detected by means of immunoenzyme methods which showed a non-differentiated morphology. The different PECAM-1 pattern expression could reflect potential organ-specific differentiation pathways during development and according to organs environment. The existence of another cell population with a size and granularity higher than 1G11 endothelial cell line required a phenotypic characterization.

Biología celular y molecular del envejecimiento neuronal: estado actual y perspectivas / Cellular and molecular biology of neural aging: actual situation and perspectives

En el presente trabajo se analiza el problema del envejecimiento con énfasis en sus causas y en el curso que toma en el sistema nervioso. Se revisa la evidencia experimental que muestra que tanto la esperanza de vida como el límite biológico de la duración de la misma, pueden alargarse por medio de la manipulación genética. Se discute el significado biológico del envejecimiento y de la muerte desde la perspectiva de la selección natural. Se establecen las diferencias objetivas entre envejecimiento normal y enfermedades neurodegenerativas. Este último constituye uno de los puntos más importantes dado que es común, incluso en ambientes médicos, confundir al envejecimiento normal con las enfermedades neurodegenerativas, particularmente con la enfermedad de Alzheimer. Se analizan el colapso de dos viejos dogmas de la neurobiología: 1) la ausencia de neurogénesis en el cerebro humano adulto y 2) que el deterioro característico de las funciones mentales durante el envejecimiento normal resulta de la pérdida en el número de neuronas. Por mucho tiempo se mantuvo que la pérdida en el número de neuronas en el cerebro humano adulto era irreversible. Se sostuvo que la incapacidad neurogénica aunada a la pérdida progresiva de neuronas constituían el devenir de muchas enfermedades neurológicas y en el proceso de envejecimiento cerebral. Estos puntos de vista deben ser revaluados a la luz de descubrimientos recientes que muestran la formación de nuevas neuronas en el cerebro humano adulto a partir de células progenitoras. Estos hallazgos se relacionan con otros que prueban que la escasa muerte neuronal que ocurre durante el envejecimiento normal, no explica el deterioro en las funciones mentales que le es característico. Este declinar se debe a cambios sutiles, morfológicos y funcionales, en ciertos circuitos clave...

Age-dependent morphological changes in dBcAMP-treated astrocytes

Since changes in cell morphology are conspicuous features of astrocyte reaction, we resorted to an histometric approach to evaluate age influence on such morphological response to activating stimuli. To this end, first subculture of rat brain astrocytes at 1, 9 or 21 days in vitro (DIV) were treated during 2 hs with l mM of dBcAMP, a chemical compound known to induce cell differentiation. Following treatment, immunoperoxidase labeling of GFAP, specific marker of astrocyte activation, was carried out. Although total count of GFAP-positive cell foci was greater in treated samples in all times tested, when such cell foci were evaluated by image analysis, differences between perimeter/area ratios of such foci were only statistifically significant at l DIV. It may be concluded that while dBcAMP effect is maintained despite astrocyte aging, the morphological pattern of response varies markedly along the observation period.

Insulin and IGF-I stimulated RNA synthesis in primary cultures of neuronal cells: involvement of cyclic AMP and protein kinase-c

La insulina y el IGF-I promueven el crecimiento de las células neuronales de rata en cultivo primario. Con el objeto de investigar el mecanismo de transducción de señales hormonales en este sistema biológico, estudiamos el efecto de agonistas de AMP cíclico y un estimulador de la proteína kinasa-C sobre la síntesis de ARN basal e inducida por hormonas. Los agentes que aumentan los níveles de AMP cíclico endógenos (foraskolina, dibutiril-AMP cíclico, toxina colérica) bloquearon los efectos estimuladores de la insulina y el factor de crecimiento; el dibutiril AMP cíclico, sin embargo, no alteró la unión de las hormonas a sus receptores. Aunque a diferencia de los agentes antes mencionados, el ester de forbol elevó significativamente la síntesis de ARN basal; este, no obstante, inhibió la estimulación por la insulina. Este último efecto probablemente fue mediado por un incremento en los niveles de AMP cíclico, como se ha encontrado en otros tipos de células. La estaurosporina, un inhibidor de la proteína kinasa-C, también bloqueó los efectos de la insulina sobre la síntesis de RNA

Morphological characterization of brain cell cultures by controlled silver impregnation

Dada la heterogeneidad del tejido nervioso, el uso de cultivos neurales como modelo de estudios neurobiológicos exige una caracterización precisa, tanto de los tipos celulares presentes en las monocapas como de su grado de diferenciación. Si bien la microscopía de contraste de fase ha sido el recurso más empleado en el análisis morfológico de los cultivos neurales, es reconocida la superioridad de la tinción con plata. Con el objeto de lograr una más fina caracterización celular, recurrimos a una técnica que habíamos desarrollado años atrás para la impregnación argéntica de fibras colágenas y reticulares. El procedimiento debió adecuarse a su aplicación a neuronas y astrocitos cultivados y, por tanto, inmaduros o en vías de maduración. Los pasos fundamentales consistieron en el uso de dicromato de potasio como mordiente, en forma previa a la impregnación argéntica, la que era seguida por reducción en solución formólica de gelatina, que actuaba como coloide protector. Los lavados posteriores se realizaron con etanol 95- cuando se pretendía destacar neuronas, o con agua piridinada cuando se trataba de astrocitos. En cultivos derivados de encéfalo de embrión de ratón, la plata precisó los variados tipos neuronales y su grado de maduración morfológica. Asimismo, en cultivos obtenidos de cerebro de ratón recien nacido, se logró caracterizar las sucesivas etapas de diferenciación astrocitaria. En neuronas y astrocitos madurados, la identificación fue confirmada por marcación (método PAP) de enolasa específica de neurona y proteína gliofibrilar ácida, respectivamente. La técnica propuesta, que puede definirse como impregnanción argéntica controlada, parece ser indicada para la caracterización morfológica de células neurales en cultivo, particularmente antes de la expresión de los marcadores específicos en toda la extensión de la monocapa