alphaE-catenin controls cerebral cortical size by regulating the hedgehog signaling pathway

N-cadherin mediates cortical organization in the mouse brain

The cerebral cortex is a complex laminated structure generated by the sequential migration of developing neurons from the ventricular zone. One of the molecules that may play a role in cortical morphogenesis is N-cadherin since its blocking causes disruption of the ordered arrangement of cells in other neural tissues, such as the neural retina. Here, we show that when the N-cadherin gene had been conditionally deleted in the mouse cerebral cortex, the intra-cortical structures were nearly completely randomized; e.g., mitotic cells and postmitotic cells were scattered throughout the cortex without any order. These defects seemed to mainly originate from the disruption of the adherens junctions (AJs) localized in the apical end of neuroepithelial cells, where N-cadherin is normally most highly concentrated. In the absence of N-cadherin, neuroepithelial or radial glial cells could not expand their bodies or processes to span the distance between the ventricular and pial surfaces and therefore terminated them in the middle zone of the cortex. These results demonstrate that N-cadherin is essential for maintaining the normal architecture of neuroepithelial or radial glial cells and that their disruption randomizes the internal structures of the cortex.

Karl Pribram, The James Arthur lectures, and what makes us human

Background

The annual James Arthur lecture series on the Evolution of the Human Brain was inaugurated at the American Museum of Natural History in 1932, through a bequest from a successful manufacturer with a particular interest in mechanisms. Karl Pribram's thirty-ninth lecture of the series, delivered in 1970, was a seminal event that heralded much of the research agenda, since pursued by representatives of diverse disciplines, that touches on the evolution of human uniqueness.

Discussion

In his James Arthur lecture Pribram raised questions about the coding of information in the brain and about the complex association between language, symbol, and the unique human cognitive system. These questions are as pertinent today as in 1970. The emergence of modern human symbolic cognition is often viewed as a gradual, incremental process, governed by inexorable natural selection and propelled by the apparent advantages of increasing intelligence. However, there are numerous theoretical considerations that render such a scenario implausible, and an examination of the pattern of acquisition of behavioral and anatomical novelties in human evolution indicates that, throughout, major change was both sporadic and rare. What is more, modern bony anatomy and brain size were apparently both achieved well before we have any evidence for symbolic behavior patterns. This suggests that the biological substrate underlying the symbolic thought that is so distinctive of Homo sapiens today was exaptively achieved, long before its potential was actually put to use. In which case we need to look for the agent, perforce a cultural one, that stimulated the adoption of symbolic thought patterns. That stimulus may well have been the spontaneous invention of articulate language.

Cell-autonomous beta-catenin signaling regulates cortical precursor proliferation

Overexpression of beta-catenin, a protein that functions in both cell adhesion and signaling, causes expansion of the cerebral cortical precursor population and cortical surface area enlargement. Here, we find that focal elimination of beta-catenin from cortical neural precursors in vivo causes premature neuronal differentiation. Precursors within the cerebral cortical ventricular zone exhibit robust beta-catenin-mediated transcriptional activation, which is downregulated as cells exit the ventricular zone. Targeted inhibition of beta-catenin signaling during embryonic development causes cortical precursor cells to prematurely exit the cell cycle, differentiate into neurons, and migrate to the cortical plate. These results show that beta-catenin-mediated transcriptional activation functions in the decision of cortical ventricular zone precursors to proliferate or differentiate during development, and suggest that the cell-autonomous signaling activity of beta-catenin can control the production of cortical neurons and thus regulate cerebral cortical size.

Alpha N-catenin deficiency causes defects in axon migration and nuclear organization in restricted regions of the mouse brain

Alpha N-catenin is a cadherin-binding protein, widely expressed in the nervous system; and it plays a crucial role in cadherin-mediated cell-cell adhesion. Here we report the effects of alpha N-catenin gene deficiency on brain morphogenesis. In addition to the previously reported phenotypes, we found that some of the axon tracts did not normally develop, in particular, axons of the anterior commissure failed to cross the midline, migrating, rather, to ectopic places. In restricted nuclei, a population of neurons was missing or their laminar arrangement was distorted. The ventricular structures were also deformed. These results indicate that alpha N-catenin has diverse roles in the organization of the central nervous system, but only in limited portions of the brain.

Catenins: keeping cells from getting their signals crossed

Adherens junctions have been traditionally viewed as building blocks of tissue architecture. The foundations for this view began to change with the discovery that a central component of AJs, beta-catenin, can also function as a transcriptional cofactor in Wnt signaling. In recent years, conventional views have similarly been shaken about the other two major AJ catenins, alpha-catenin and p120-catenin. Catenins have emerged as molecular sensors that integrate cell-cell junctions and cytoskeletal dynamics with signaling pathways that govern morphogenesis, tissue homeostasis, and even intercellular communication between different cell types within a tissue. These findings reveal novel aspects of AJ function in normal tissues and offer insights into how changes in AJs and their associated proteins and cytoskeletal dynamics impact wound-repair and cancer.

Cdc42 deficiency causes Sonic hedgehog-independent holoprosencephaly

The telencephalic neuroepithelium (NE) of mammalian brain has an apical-basal polarity that is marked by the positioning of neural progenitors and adherens junctions on the apical/ventricular surface and the ascending of radial glia/progenitor fibers toward the pial/basal surface. The signaling pathway that establishes this apical-basal polarity of NE is not completely understood, but the Rho-family GTPase Cdc42 may play a critical role because it controls cadherin-based intercellular junctions and cell polarity in many species. Here, we tested this hypothesis by a conditional gene-targeting strategy by using the Foxg1-Cre line to delete Cdc42 in the telencephalic neural progenitors in mouse embryos. We found that Cdc42-deletion abolishes the apical localization of PAR6, aPKC, E-cadherin, beta-catenin, and Numb proteins in the NE, and severely impairs the extension of nestin-positive radial fibers. Consequently, neural progenitors were scattered throughout the entire depth of the NE, and the Cdc42-deficient telencephalon failed to bulge or separate into two cerebral hemispheres, resulting in holoprosencephaly. However, neither the midline expression of Sonic hedgehog nor the dorso-ventral patterning of the telencephalon was affected by Cdc42-deletion. Taken together, these results indicate that Cdc42 has an essential role in establishing the apical-basal polarity of the telencephalic NE, which is needed for the expansion and bifurcation of cerebral hemispheres.

Interdependence of cell attachment and cell cycle signaling

Adult metazoans represent the culmination of an intricate developmental process involving the temporally and spatially orchestrated division, migration, differentiation, attachment, polarization and death of individual cells. An elaborate infrastructure connecting the cell cycle and cell attachment machinery is essential for such exquisite integration of developmental processes. Integrin-, cadherin-, Merlin- and planar cell polarity (PCP)-dependent signaling cascades quantitatively and qualitatively program cell division during development. Proteins in this signaling infrastructure may represent an important source of cancer vulnerability in metazoans, as their dysfunction can pleiotropically promote the oncogenic process.

Regulation of cell–cell junctions by the cytoskeleton

A major form of animal cell-cell adhesion results from the dynamic association of cadherin molecules, cytosolic catenins and actin microfilaments. Cadherins dynamically regulate the cytoskeleton. In turn, the actin cytoskeleton contributes to cadherin molecule oligomerization at cell contacts and to cell reshaping in response to environmental changes. Over the past two years, this evolutionarily conserved adhesion system has been intensively revisited in both its structural and functional aspects; this is illustrated by the remarkable progress in the determination of physical parameters of cadherin bonds (including force measurement) and the new insights into the role of alpha-catenin and the regulation of actin dynamics at cadherin contacts. Other recent studies uncover the important contribution of acto-myosin, microtubules and cell tension to adherens junction formation, cell differentiation and tissue reshaping/remodeling. An open challenge is now to integrate these new data with the diversity of cadherin adhesive complexes.

Building Complex Brains – Missing Pieces in an Evolutionary Puzzle

The mechanisms underlying evolution of complex nervous systems are not well understood. In recent years there have been a number of attempts to correlate specific gene families or evolutionary processes with increased brain complexity in the vertebrate lineage. Candidates for evocation of complexity include genes involved in regulating brain size, such as neurotrophic factors or microcephaly-related genes; or wider evolutionary processes, such as accelerated evolution of brain-expressed genes or enhanced RNA splicing or editing events in primates. An inherent weakness of these studies is that they are correlative by nature, and almost exclusively focused on the mammalian and specifically the primate lineage. Another problem with genomic analyses is that it is difficult to identify functionally similar yet non-homologous molecules such as different families of cysteine-rich neurotrophic factors in different phyla. As long as comprehensive experimental studies of these questions are not feasible, additional perspectives for evolutionary and genomic studies will be very helpful. Cephalopod mollusks represent the most complex nervous systems outside the vertebrate lineage, thus we suggest that genome sequencing of different mollusk models will provide useful insights into the evolution of complex brains.

Cadherin-catenin proteins in vertebrate development

Cadherin-catenin adhesion is pivotal for the development of multicellular organisms. Features such as a large repertoire of homotypically interacting cadherins, rapid assembly and disassembly, and a connection to a force-generating actin cytoskeleton make cadherin-mediated junctions ideal structures for the execution of complex changes in cell and tissue morphology during development. Recent findings highlight the role of cadherin-catenin proteins as critical regulators of major developmental pathways. We re-evaluate the significance of cadherin-catenin adhesion structures and propose that in addition to intercellular adhesion, they may be used as biosensors of the external cellular environment that help adjust the behavior of individual cells to ensure survival of the entire organism.