Miriam Huerta

Zona Occludens-2 Inhibits Cyclin D1 Expression and Cell Proliferation and Exhibits Changes in Localization along the Cell Cycle

Here, we have studied the effect of the tight junction protein zona occludens (ZO)-2 on cyclin D1 (CD1) protein expression. CD1 is essential for cell progression through the G1 phase of the cell cycle. We have found that in cultures of synchronized Madin-Darby canine kidney cells, ZO-2 inhibits cell proliferation at G0/G1 and decreases CD1 protein level. These effects occur in response to a diminished CD1 translation and an augmented CD1 degradation at the proteosome triggered by ZO-2. ZO-2 overexpression decreases the amount of Glycogen synthase kinase-3beta phosphorylated at Ser9 and represses beta-catenin target gene expression. We have also explored the expression of ZO-2 through the cell cycle and demonstrate that ZO-2 enters the nucleus at the late G1 phase and leaves the nucleus when the cell is in mitosis. These results thus explain why in confluent quiescent epithelia ZO-2 is absent from the nucleus and localizes at the cellular borders, whereas in sparse proliferating cultures ZO-2 is conspicuously present at the nucleus.

Combined Optical and Electronic Sensing of Epithelial Cells Using Planar Organic Transistors

A planar, conducting-polymer-based transistor for combined optical and electronic monitoring of live cells provides a unique platform for monitoring the health of cells in vitro. Monitoring of MDCK-I epithelial cells over several days is shown, along with a demonstration of the device for toxicology studies, of use in future drug discovery or diagnostics applications.

Organic electrochemical transistors for cell-based impedance sensing

Electrical impedance sensing of biological systems, especially cultured epithelial cell layers, is now a common technique to monitor cell motion, morphology, and cell layer/tissue integrity for high throughput toxicology screening. Existing methods to measure electrical impedance most often rely on a two electrode configuration, where low frequency signals are challenging to obtain for small devices and for tissues with high resistance, due to low current. Organic electrochemical transistors (OECTs) are conducting polymer-based devices, which have been shown to efficiently transduce and amplify low-level ionic fluxes in biological systems into electronic output signals. In this work, we combine OECT-based drain current measurements with simultaneous measurement of more traditional impedance sensing using the gate current to produce complex impedance traces, which show low error at both low and high frequencies. We apply this technique in vitro to a model epithelial tissue layer and show that the data can be fit to an equivalent circuit model yielding trans-epithelial resistance and cell layer capacitance values in agreement with literature. Importantly, the combined measurement allows for low biases across the cell layer, while still maintaining good broadband signal.

The Tight Junction Protein ZO‐2 Blocks Cell Cycle Progression and Inhibits Cyclin D1 Expression

ZO‐2 is an adaptor protein of the tight junction that belongs to the MAGUK protein family. ZO‐2 is a dual localization protein that in sparse cultures is present at the cell borders and the nuclei, whereas in confluent cultures it is concentrated at the cell boundaries. Here we have studied whether ZO‐2 is able to regulate the expression of cyclin D1 (CD1) and cell proliferation. We have demonstrated that ZO‐2 negatively regulates CD1 transcription by interacting with c‐Myc at an E box present in CD1 promoter. We have further found that ZO‐2 transfection into epithelial MDCK cells triggers a diminished expression of CD1 protein and decreases the rate of cell proliferation in a wound‐healing assay.

Glutamate regulates eEF1A phosphorylation and ribosomal transit time in Bergmann glial cells

Glutamate, the major excitatory transmitter in the vertebrate brain, is involved in neuronal development and synaptic plasticity. Glutamatergic stimulation leads to differential gene expression patterns in neuronal and glial cells. A glutamate-dependent transcriptional control has been established for several genes. However, much less is known about the molecular events that modify the translational machinery upon exposure to this neurotransmitter. In a glial model of cerebellar cultured Bergmann cells, glutamate induces a biphasic effect on [(35)S]-methionine incorporation into proteins that suggests that the elongation phase of protein biosynthesis is the target for regulation. Indeed, after a 15 min exposure to glutamate a transient increase in elongation factor 2 phosphorylation has been reported, an effect mediated through the activation of the elongation factor 2 kinase. In this contribution, we sought to characterize the phosphorylation status of the eukaryotic elongation factor 1A (eEF1A) and the ribosomal transit time under glutamate exposure. A dose-dependent increase in eEF1A phosphorylation was found after a 60 min glutamate treatment; this phenomenon is Ca(2+)/CaM dependent, blocked with Src and phosphatidyl-inositol 3-kinase inhibitors and with rapamicyn. Concomitantly, the ribosomal transit time was increased with a 15 min glutamate exposure. After 60 more minutes, the average time used by the ribosomes to complete a polypeptide chain had almost returned to its initial level. These results strongly suggest that glutamate exerts an exquisite time-dependent translational control in glial cells, a process that might be critical for glia-neuron interactions.

Arsenite Exposure Downregulates EAAT1/GLAST Transporter Expression in Glial Cells

Chronic exposure to inorganic arsenic severely damages the central nervous system (CNS). Glutamate (GLU) is the major excitatory amino acid and is highly neurotoxic when levels in the synaptic cleft are not properly regulated by a family of Na⁺-dependent excitatory amino acid transporters. Within the cerebellum, the activity of the Bergmann glia Na⁺-dependent GLU/aspartate transporter (GLAST) excitatory amino acid transporter 1 (EAAT1/GLAST) accounts for more than 90% of GLU uptake. Because exposure to the metalloid arsenite results in CNS toxicity, we examined whether EAAT1/GLAST constitutes a molecular target. To this end, primary cultures of chick cerebellar Bergmann glial cells were exposed to sodium arsenite for 24 h, and EAAT1/GLAST activity was evaluated via ³H-D-aspartate uptake. A sharp decrease in GLU transport was observed, and kinetic studies revealed protein kinase A, protein kinase C, and p38 mitogen-activated protein kinase-dependent decreases in K(M) and V(max) concomitant with diminished chglast transcription. To gain insight into the molecular mechanisms involved in these phenomena, we investigated the generation of reactive oxidative species and the lipid peroxidative damage caused by arsenite exposure. None of these responses were found, although we did observe an increase in nuclear factor (erythroid-derived 2)-like 2 DNA-binding activity correlated with a rise in total glutathione levels. Our results clearly suggest that EAAT1/GLAST is a molecular target of arsenite and support the critical involvement of glial cells in brain function and dysfunction.

Using white noise to gate organic transistors for dynamic monitoring of cultured cell layers

Impedance sensing of biological systems allows for monitoring of cell and tissue properties, including cell-substrate attachment, layer confluence, and the “tightness” of an epithelial tissue. These properties are critical for electrical detection of tissue health and viability in applications such as toxicological screening. Organic transistors based on conducting polymers offer a promising route to efficiently transduce ionic currents to attain high quality impedance spectra, but collection of complete impedance spectra can be time consuming (minutes). By applying uniform white noise at the gate of an organic electrochemical transistor (OECT), and measuring the resulting current noise, we are able to dynamically monitor the impedance and thus integrity of cultured epithelial monolayers. We show that noise sourcing can be used to track rapid monolayer disruption due to compounds which interfere with dynamic polymerization events crucial for maintaining cytoskeletal integrity, and to resolve sub-second alterations to the monolayer integrity.

TJ Proteins That Make Round Trips to the Nucleus

The tight junction (TJ) located at the limit between the apical and basolateral plasma membranes, is a multiprotein complex integrated by both integral and cortical proteins. Through TJ epithelial cells establish a link with their neighbors that seals the paracellular pathway. Lately some TJ proteins like the MAGUK ZO-1 and ZO-2, MAGI 1c, as well as the unrelated proteins symplekin and ubinuclein, have been found to concentrate at the nucleus. In this chapter we describe such proteins and how their arrival to the nucleus is connected to the degree of cell-cell contact. We analyze the signals present in these TJ proteins that may be responsible for their movement from the membrane to the nucleus and vice-versa. We then detail, the interaction of these proteins to nuclear molecules involved in gene transcription, chromatin remodeling, RNA processing and polyadenylation.

Identification of ZASP, a novel protein associated to Zona occludens-2

With the aim of discovering new molecular interactions of the tight junction protein ZO-2, a two-hybrid screen was performed on a human kidney cDNA library using as bait the middle segment of ZO-2. Through this assay we identified a 24-kDa novel protein herein named ZASP for ZO-2 associated speckle protein. ZO-2/ZASP interaction further confirmed by pull down and immunoprecipitation experiments, requires the presence of the intact PDZ binding motif SQV of ZASP and the third PDZ domain of ZO-2. ZASP mRNA and protein are present in the kidney and in several epithelial cell lines. Endogenous ZASP is expressed primarily in nuclear speckles in co-localization with splicing factor SC-35. Nocodazole treatment and wash out reveals that ZASP disappears from the nucleus during mitosis in accordance with speckle disassembly during metaphase. ZASP amino acid sequence exhibits a canonical nuclear exportation signal and in agreement the protein exits the nucleus through a process mediated by exportin/CRM1. ZASP over-expression blocks the inhibitory activity of ZO-2 on cyclin D1 gene transcription and protein expression. The identification of ZASP helps to unfold the complex nuclear molecular arrays that form on ZO-2 scaffolds.

Conducting Polymer Scaffolds for Hosting and Monitoring 3D Cell Culture

This work reports the design of a live‐cell monitoring platform based on a macroporous scaffold of a conducting polymer, poly(3,4‐ethylene dioxythiophene):poly(styrenesulfonate). The conducting polymer scaffolds support 3D cell cultures due to their biocompatibility and tissue‐like elasticity, which can be manipulated by inclusion of biopolymers such as collagen. Integration of a media perfusion tube inside the scaffold enables homogenous cell spreading and fluid transport throughout the scaffold, ensuring long term cell viability. This also allows for co‐culture of multiple cell types inside the scaffold. The inclusion of cells within the porous architecture affects the impedance of the electrically conducting polymer network and, thus, is utilized as an in situ tool to monitor cell growth. Therefore, while being an integral part of the 3D tissue, the conducting polymer is an active component, enhancing the tissue function, and forming the basis for a bioelectronic device with integrated sensing capability.