MAP2 Splicing is Altered in Huntington's Disease : MAP2 Spicing is Altered in HD

Numerous disease-associated point mutations exert their effects by disrupting the activity of exonic splicing enhancers (ESEs). We previously derived position weight matrices to predict putative ESEs specific for four human SR proteins. The score matrices are part of ESEfinder, an online resource to identify ESEs in query sequences. We have now carried out a refined functional SELEX screen for motifs that can act as ESEs in response to the human SR protein SF2/ASF. The test BRCA1 exon under selection was internal, rather than the 3'-terminal IGHM exon used in our earlier studies. A naturally occurring heptameric ESE in BRCA1 exon 18 was replaced with two libraries of random sequences, one seven nucleotides in length, the other 14. Following three rounds of selection for in vitro splicing via internal exon inclusion, new consensus motifs and score matrices were derived. Many winner sequences were demonstrated to be functional ESEs in S100-extract-complementation assays with recombinant SF2/ASF. Motif-score threshold values were derived from both experimental and statistical analyses. Motif scores were shown to correlate with levels of exon inclusion, both in vitro and in vivo. Our results confirm and extend our earlier data, as many of the same motifs are recognized as ESEs by both the original and our new score matrix, despite the different context used for selection. Finally, we have derived an increased specificity score matrix that incorporates information from both of our SF2/ASF-specific matrices and that accurately predicts the exon-skipping phenotypes of deleterious point mutations.

We have analyzed the polarity orientation of microtubules in the axons and dendrites of cultured rat hippocampal neurons. As previously reported of axons from other neurons, microtubules in these axons are uniform with respect to polarity; (+)-ends are directed away from the cell body toward the growth cone. In sharp contrast, microtubules in the mid-region of the dendrite, approximately 75 microns from the cell body, are not of uniform polarity orientation. Roughly equal proportions of these microtubules are oriented with (+)-ends directed toward the growth cone and (+)-ends directed toward the cell body. At distances within 15 micron of the growth cone, however, microtubule polarity orientation in dendrites is similar to that in axons; (+)-ends are uniformly directed toward the growth cone. These findings indicate a clear difference between axons and dendrites with respect to microtubule organization, a difference that may underlie the differential distribution of organelles within the neuron.

Neurons, the basic information processing units of the nervous system, are characterized by a complex polar morphology which is essential for their function. To attain their precise morphology, neurons extend cytoplasmatic processes (axons and dendrites) and establish synaptic connections in a highly regulated way. Additionally, neurons are also subjected to small plastic changes at the adult stage which serve to regulate synaptic transmission. Every step of neuronal development is genetically controlled by endogenous determinants, as well as by environmental signals including intercellular contacts, extracellular matrix and diffusible signals. Cytoskeletal components are among the main protein targets modified in response to most of those extracellular signals which ultimately determine neuronal morphology. One of the major mechanisms controlling the neuronal cytoskeleton is the modification of the phosphorylation state of cytoskeletal proteins via changes in the relative activities of protein kinases and phosphatases within neurons. In particular, the microtubule-associated protein 2 (MAP2) family of proteins is an abundant group of cytoskeletal components which are predominantly expressed in neurons and serve as substrates for most of protein kinases and phosphatases present in neurons. MAP2 phosphorylation seems to control its association with the cytoskeleton and it is developmentally regulated. Moreover, MAP2 may perform many functions including the nucleation and stabilization of microtubules (and maybe microfilaments), the regulation of organelle transport within axons and dendrites, as well as the anchorage of regulatory proteins such as protein kinases which may be important for signal transduction. These putative functions of MAP2 have also been proposed to play important roles in the outgrowth of neuronal processes, synaptic plasticity and neuronal cell death. Thus, MAP2 constitutes an interesting case to understand the regulation of neuronal function by the alteration of the phosphorylation state of cytoskeletal proteins in response to different extracellular signals. Here we will review the current knowledge about the regulation of MAP2 function through phosphorylation/dephosphorylation and its relevance in the broader context of neuronal functions.