Thomas J. Bell

Differential Distribution of Ca2+-Activated K+ Channel Splice Variants among Hair Cells along the Tonotopic Axis of the Chick Cochlea

We have cloned from the receptor epithelium of the chick cochlea a family of alternatively spliced cDNAs derived from cslo, which encodes a Ca2+-activated K+ channel like those shown to help determine the resonant frequency of electrically tuned hair cells. Our results from PCRs using template RNAs from both tonotopically subdivided receptor epithelia and single hair cells demonstrate differential exon usage along the frequency axis of the epithelium at multiple splice sites in cslo. We also show that single hair cells express more than one splice variant at a given splice site. Since channel isoforms encoded by differentially spliced slo transcripts in other species are functionally heterogeneous, these data suggest that differential processing of slo transcripts may account, at least in part, for the systematic variation in hair-cell membrane properties along the frequency axis of electrically tuned auditory receptor epithelia.

Cytoplasmic Intron Sequence-Retaining Transcripts Can Be Dendritically Targeted via ID Element Retrotransposons

RNA precursors give rise to mRNA after splicing of intronic sequences traditionally thought to occur in the nucleus. Here, we show that intron sequences are retained in a number of dendritically-targeted mRNAs, by using microarray and Illumina sequencing of isolated dendritic mRNA as well as in situ hybridization. Many of the retained introns contain ID elements, a class of SINE retrotransposon. A portion of these SINEs confers dendritic targeting to exogenous and endogenous transcripts showing the necessity of ID-mediated mechanisms for the targeting of different transcripts to dendrites. ID elements are capable of selectively altering the distribution of endogenous proteins, providing a link between intronic SINEs and protein function. As such, the ID element represents a common dendritic targeting element found across multiple RNAs. Retention of intronic sequence is a more general phenomenon than previously thought and plays a functional role in the biology of the neuron, partly mediated by co-opted repetitive sequences.

Cytoplasmic BKCa channel intron-containing mRNAs contribute to the intrinsic excitability of hippocampal neurons

High single-channel conductance K+ channels, which respond jointly to membrane depolarization and micromolar concentrations of intracellular Ca2+ ions, arise from extensive cell-specific alternative splicing of pore-forming α-subunit mRNAs. Here, we report the discovery of an endogenous BKCa channel α-subunit intron-containing mRNA in the cytoplasm of hippocampal neurons. This partially processed mRNA, which comprises ≈10% of the total BKCa channel α-subunit mRNAs, is distributed in a gradient throughout the somatodendritic space. We selectively reduced endogenous cytoplasmic levels of this intron-containing transcript by RNA interference without altering levels of the mature splice forms of the BKCa channel mRNAs. In doing so, we could demonstrate that changes in a unique BKCa channel α-subunit intron-containing splice variant mRNA can greatly impact the distribution of the BKCa channel protein to dendritic spines and intrinsic firing properties of hippocampal neurons. These data suggest a new regulatory mechanism for modulating the membrane properties and ion channel gradients of hippocampal neurons.

Intron retention facilitates splice variant diversity in calcium-activated big potassium channel populations

We report that the stress axis–regulated exon (STREX)-containing calcium-activated big potassium (BKCa) channel splice variant expression and physiology are regulated in part by cytoplasmic splicing and intron retention. NextGen sequencing of the mRNA complement of pooled hippocampal dendrite samples found intron 17a (i17a), the intron immediately preceding STREX, in the BKCa mRNA. Further molecular analyses of i17a revealed that the majority of i17a-containing BKCa channel mRNAs associate with STREX. i17a siRNA treatment followed by STREX protein immunocytochemistry demonstrated both reduced levels and altered subcellular distribution of STREX-containing BKCa channel protein. Selective reduction of i17a-BKCa or STREX-BKCa mRNAs induced similar changes in the burst firing properties of hippocampal neurons. Collectively, these data show that STREX splice variant regulation via cytoplasmic splicing and intron retention helps generate STREX-dependent BKCa current diversity in hippocampal neurons.

Subcellular neuropharmacology: the importance of intracellular targeting

Few cell types are more adapted for cell-cell signaling than neurons. Their responsiveness lies in the formation of highly specialized compartments composed of unique repertoires of selectively distributed protein complexes generated, in part, by the local translation of mRNAs and regulated by their RNA-binding proteins. Utilizing the selective distribution of these neuronal proteins and the underlying mechanisms that generate the differential patterns of expression as central facets of drug design promises to enhance the therapeutic ratio of a drug. It is in this context that we discuss the unique arrangement of mRNAs, RNA-binding proteins and the protein macromolecular complexes at the dendrite, which is the postsynaptic site of synaptic transmission. Recent advances in identifying the function of dendritic components of the mechanisms of protein and RNA transport, non-nuclear RNA splicing and localized translation underscore their importance as targets of neuropharmacology.

cAMP-induced Auditory Supporting Cell Proliferation is Mediated by ERK MAPK Signaling Pathway

Sensorineural hearing deficiencies result from the loss of auditory hair cells. This hearing loss is permanent in humans and mammals because hair cells are not spontaneously replaced. In other animals such as birds, this is not the case. Damage to the avian cochlea evokes proliferation of supporting cells and the generation of functionally competent replacement hair cells. Signal transduction pathways are clinically useful as potential therapeutic targets, so there is significant interest in identifying the key signal transduction pathways that regulate the formation of replacement hair cells. In a previous study from our lab, we showed that forskolin (FSK) treatment induces auditory supporting cell proliferation and formation of replacement hair cells in the absence of sound or aminoglycoside treatment. Here, we show that FSK-induced supporting cell proliferation is mediated by cell-specific accumulation of cyclic adenosine monophosphate (cAMP) in avian supporting cells and the extracellular signal-regulated kinase (ERK) mitogen-activated protein kinase (MAPK) pathway. By a combination of immunostaining and pharmacological analyses, we show that FSK treatment increases cAMP levels in avian auditory supporting cells and that several ERK MAP inhibitors effectively block FSK-induced supporting cell proliferation. Next, we demonstrate by Western blotting and immunostaining analyses the expression of several ERK MAPK signaling molecules in the avian auditory epithelium and the cell-specific expression of B-Raf in avian auditory supporting cells. Collectively, these data suggest that FSK-induced supporting cell proliferation in the avian auditory epithelium is mediated by increases of cAMP levels in supporting cells and the cell-specific expression of the ERK MAPK family member B-Raf in supporting cells.

Single-Neuron Isolation for RNA Analysis Using Pipette Capture and Laser Capture Microdissection

The field of single-cell analysis has greatly benefitted from recent technological advances allowing scientists to study genomes, transcriptomes, proteomes, and metabolomes at the single-cell level. Transcriptomics allows a unique window into cell function and is especially useful for studying global variability among single cells of seemingly the same type. Generating transcriptome data from RNA samples has become increasingly easy and can be done using either microarray or RNA-Seq techniques. RNA isolation is the first step of transcriptomics. Numerous RNA isolation procedures exist and differ with respect to the type and number of cells from which they are capable of isolating RNA. Although it is trivial to isolate RNA from bulk tissue or culture plates, sophisticated methods are required to capture RNA from single cells in a pool of cells or in intact tissue. We describe here the protocols used for isolating the soma of single neurons in cultures and in tissue slices using the pipette capture and the PALM or laser capture microdissection (LCM) approaches, respectively. LCM was developed to isolate cells from tissue sections primarily for pathological tissue analysis. LCM can be used to isolate individual cells or groups of cells from ethanol or paraffin-embedded formalin-fixed tissue sections and dissociated tissue cultures. The soma isolates from either technique can subsequently be used for RNA amplification procedures and transcriptome analysis. These procedures can also be adapted to other cell types in cultures and tissue sections and can be used on neuronal subcellular structures, such as dendrites.

PAIR Technology: Exon-Specific RNA-Binding Protein Isolation in Live Cells

RNA-binding proteins (RBPs) are fundamental regulatory proteins for all forms of transcriptional and posttranscriptional control of gene expression. However, isolating RBPs is technically challenging for investigators. Currently, the most widely used techniques to isolate RBPs are in vitro biochemical approaches. Although these approaches have been useful, they have several limitations. One key limitation to using in vitro biochemical approaches is that RBP-RNA interactions are isolated under nonbiological conditions. Here we review a novel experimental approach to identify RBPs called peptide nucleic acid (PNA)-assisted identification of RBPs (PAIR) technology (Zielinski et al., Proc Natl Acad Sci USA 103:1557-1562, 2006). This technology has two significant advantages over traditional approaches. (1) It overcomes the in vitro limitation of biochemical approaches by allowing investigators to isolate RBP-RNA interactions under in vivo conditions. (2) This technology is highly mRNA specific; it isolates RBPs in an exon-specific manner. By selectively targeting alternatively spliced exons with PAIR technology, investigators can isolate splice variant-specific and mRNA region-specific (5-UTR and 3-UTR) RBP complexes for any mRNA of interest.

Antisense RNA Amplification for Target Assessment of Total mRNA from a Single Cell

This protocol describes how to amplify mRNA isolated from a single cell and then analyze its gene expression profile using polymerase chain reaction (PCR). Single-cell analysis is advantageous over studies of cell populations because it allows identification of a range of normal physiological states expressed by different cells of the same cell type without the confounding effects of averaging that result from measuring physiological states of cell populations. This is especially important when addressing questions of physiology in tissues, which comprises many different cell types. However, a single cell does not contain enough mRNA for all of the expressed transcripts to be detected or measured by any current molecular biology techniques. The antisense RNA (aRNA) amplification method was developed to amplify the picogram amounts of mRNA found within a single cell to microgram amounts of aRNA after three rounds of amplification. This aRNA can then easily be analyzed by microarray or next-generation sequencing. These methods allow identification of all expressed mRNA species within a single cell, including previously unknown mRNAs or those mRNAs specifically affected by a certain treatment. mRNA species of interest identified by these techniques can be further analyzed by designing primers targeting these species and performing PCR. cDNA synthesized from RNA at any stage in the aRNA amplification procedure, including material directly from collected unamplified cells, can be analyzed using PCR. Regardless of downstream applications, single-cell aRNA amplification is a powerful tool for studying single-cell physiological dynamics.

Live Cell Genomics: Cell-Specific Transcriptome Capture in Live Tissues and Cells

The sensitivity of new transcriptomic techniques is rapidly improving to the point that single-cell molecular analysis is now becoming commonplace. However to obtain accurate transcriptome data, the initial experimental steps must strive to maintain the natural environment of cell and always get set in motion under in vivo conditions. Achieving these critical experimental parameters is technically challenging for investigators and currently the most frequently used molecular techniques experimentally commence with tissues or cells in artificial environments or under in vitro conditions. Here we review an innovative experimental approach that is called transcriptome in vivo analysis (TIVA) that was designed to overcome theses well-known limitations. The TIVA methods permit cell-specific transcriptome capture from viable intact heterogeneous tissues. Cell-penetrating peptides (CPPs) are used to deliver multifunctional transcriptome-capture tags (TIVA tags) to the cytoplasm of the cell under in vivo conditions. The TIVA capture tag enables investigators to target and isolate cell-specific transcriptomes in their natural microenvironments. The combination of maintaining in vivo conditions and selective cell-specific transcriptome capture provides investigators with the opportunity to yield the most biologically accurate and informative transcriptome data hitherto.