Microtubule-associated protein-2 in the hypothalamo-neurohypophysial system: low-molecular-weight microtubule-associated protein-2 in pituitary astrocytes
Wataru MatsunagaSeiji MiyataYosuke HashimotoShan LinToshihiro NakashimaToshikazu KiyoharaT. Matsumoto
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Supraoptic nucleus
Tau protein
Posterior pituitary
Microtubule-associated protein
Microtubule-associated protein 1 (MAP 1; Mr = 350,000) was analyzed by column chromatography of microtubule protein obtained from calf brain gray and white matter. Two low molecular weight proteins (LMW MAPs; Mr 28,000 and 30,000) were found to cochromatograph with MAP 1 under all conditions examined. MAP 1 and the LMW MAPs were purified from calf brain white matter as a complex containing approximately equimolar amounts of the three species. Urea (6 M) was used to remove the LMW MAPs from MAP 1. Binding of MAP 1 to microtubules was unaffected by urea and occurred with or without the LMW species. Electron microscopy of microtubules composed of purified tubulin and either MAP 1 preparation revealed that, like MAP 2, MAP 1 has the appearance of a filamentous arm on the microtubule surface.
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The microtubule‐binding domains of microtubule‐associated protein (MAP) 2, MAP4, and tau are structurally similar [Aizawa, H., Emori, Y., Murofushi, H., Kawasaki, H., Sakai., H., and Suzuki, K. (1990) J. Biol. Chem. 265 , 13849–13855]. To compare the microtubule‐binding mechanisms of the three MAPs, we performed a quantitative competition analysis using the three MAPs and the microtubule‐binding domain fragment of MAP4 (PA 4 T fragment). The two‐cycled microtubule protein fraction from bovine brain contains MAP1, MAP2, MAP4, and tau. When an excess of the PA 4 T fragment was added to the microtubule protein fraction, MAP4 and tau were completely released from the microtubules, while MAP1 remained bound. MAP2 was only partially released from the microtubules. The competition between MAP2 and MAP4 was further analyzed using purified MAP2, the PA 4 T fragment, and tubulin. About half of the MAP2 was still bound to the microtubules, even in the presence of an excess amount of the PA 4 T fragment. The microtubule‐binding mechanisms of MAP2 and MAP4 seem to be different, in spite of their similar primary structures.
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Tau protein
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Abstract The physical properties of cytoskeletal microtubules have a multifaceted effect on the expression of their cellular functions. A superfamily of microtubule-associated proteins, MAP2, MAP4, and tau, promote the polymerization of microtubules, stabilize the formed microtubules, and affect the physical properties of microtubules. Here, we show differences in the effects of these three MAPs on the physical properties of microtubules. When microtubule-binding domain fragments of MAP2, tau, and three MAP4 isoforms were added to microtubules in vitro and observed by fluorescence microscopy, tau-bound microtubules showed a straighter morphology than the microtubules bound by MAP2 and the three MAP4 isoforms. Flexural rigidity was evaluated by the shape of the teardrop pattern formed when microtubules were placed in a hydrodynamic flow, revealing that tau-bound microtubules were the least flexible. When full-length MAPs fused with EGFP were expressed in human neuroblastoma (SH-SY5Y) cells, the microtubules in apical regions of protrusions expressing tau were straighter than in cells expressing MAP2 and MAP4. On the other hand, the protrusions of tau-expressing cells had the fewest branches. These results suggest that the properties of microtubules, which are regulated by MAPs, contribute to the morphogenesis of neurites.
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We have purified and characterized a 31-kDa protein named mapmodulin that binds to the microtubule-associated proteins (MAPs) MAP2, MAP4, and tau. Mapmodulin binds free MAPs in strong preference to microtubule-associated MAPs, and appears to do so via the MAP's tubulin-binding domain. Mapmodulin inhibits the initial rate of MAP2 binding to microtubules, a property that may allow mapmodulin to displace MAPs from the path of organelles translocating along microtubules. In support of this possibility, mapmodulin stimulates the microtubule- and dynein-dependent localization of Golgi complexes in semi-intact CHO cells. To our knowledge, mapmodulin represents the first example of a protein that can bind and potentially regulate multiple MAP proteins.
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MAP2 and tau exhibit microtubule-stabilizing activities that are implicated in the development and maintenance of neuronal axons and dendrites. The proteins share a homologous COOH-terminal domain, composed of three or four microtubule binding repeats separated by inter-repeats (IRs). To investigate how MAP2 and tau stabilize microtubules, we calculated 3D maps of microtubules fully decorated with MAP2c or tau using cryo-EM and helical image analysis. Comparing these maps with an undecorated microtubule map revealed additional densities along protofilament ridges on the microtubule exterior, indicating that MAP2c and tau form an ordered structure when they bind microtubules. Localization of undecagold attached to the second IR of MAP2c showed that IRs also lie along the ridges, not between protofilaments. The densities attributable to the microtubule-associated proteins lie in close proximity to helices 11 and 12 and the COOH terminus of tubulin. Our data further suggest that the evolutionarily maintained differences observed in the repeat domain may be important for the specific targeting of different repeats to either α or β tubulin. These results provide strong evidence suggesting that MAP2c and tau stabilize microtubules by binding along individual protofilaments, possibly by bridging the tubulin interfaces.
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The role of microtubule associated proteins (MAPs) on the dynamic instability of microtubules was examined under a dark-field microscope using bovine brain tubulin purified by DEAE-Sepharose column chromatography. In the absence of MAPs, the transition from the shortening phase to the growing phase (the rescue) occurred rarely both in self-assembled microtubules and seeded ones, especially at the plus end. Even under the conditions unfavorable to stabilize microtubule, the addition of a small amount of crude MAPs or purified microtubule associated protein 2 (MAPs) to the microtubules allowed them to undergo the rescue. At increased concentrations of MAPs or MAP2, both the length change required for a rescue during shortening phase ("shortening length") and for a catastrophe (transition from the growing to the shortening phase) ("growth length") decreased. Under these conditions, the rescue often occurred at the same site where previous rescues occurred. Distribution of immunofluorescent MAP2 antibodies along individual microtubules showed that MAP2 molecules bound onto microtubules by forming discrete clusters. The number of MAP2 molecules per cluster was estimated to be between 25 and 60. Because both the "shortening length" and the distance between MAP2 clusters in a microtubule decreased with increased MAPs concentration, we suggest that the MAP2 clusters may form the specific site at which the shortening of the microtubule readily stops. MAP2 possibly regulates the dynamic instability by stopping the shortening, which is a prerequisite for the rescue.
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ABSTRACT Microtubules induced with taxol to assemble in cell-free extracts of the brine shrimp, Artemia, are cross-linked by microtubule-associated proteins (MAPs). When the MAPs, extracted from taxol-stabilized microtubules with lM-NaCl are co-assembled with purified Artemia or mammalian neural tubulin, reconstitution of cross-linking between microtubules occurs. The most prominent non-tubulin protein associated with reconstituted cross-linked microtubules has a molecular weight of 49000 but we cannot yet exclude the possibility that other proteins may be responsible for the crosslinking. Cross-linkers are separated by varying distances while cross-linked microtubules, pre pared under different conditions, are 6·9-7·7nm apart. Cross-linking of microtubules by MAPs occurs whether MAPs are added to assembling tubulin or to microtubules, and it is not disrupted by ATP. The MAPs are heat-sensitive and do not stabilize microtubules to cold. Immunological characterization of Artemia MAPs on Western blots indicates that Artemia lack MAP 1, MAP 2 and tau. Our results clearly demonstrate that Artemia contain novel MAPs with the ability to cross-link microtubules from phylogenetically disparate organisms in an ATP-independent manner.
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The posterior pituitary gland secretes oxytocin and vasopressin (the antidiuretic hormone) into the blood system. Oxytocin is required for normal delivery of the young and for delivery of milk to the young during lactation. Vasopressin increases water reabsorption in the kidney to maintain body fluid balance and causes vasoconstriction to increase blood pressure. Oxytocin and vasopressin secretion occurs from the axon terminals of magnocellular neurons whose cell bodies are principally found in the hypothalamic supraoptic nucleus and paraventricular nucleus. The physiological functions of oxytocin and vasopressin depend on their secretion, which is principally determined by the pattern of action potentials initiated at the cell bodies. Appropriate secretion of oxytocin and vasopressin to meet the challenges of changing physiological conditions relies mainly on integration of afferent information on reproductive, osmotic, and cardiovascular status with local regulation of magnocellular neurons by glia as well as intrinsic regulation by the magnocellular neurons themselves. This review focuses on the control of magnocellular neuron activity with a particular emphasis on their regulation by reproductive function, body fluid balance, and cardiovascular status. © 2016 American Physiological Society. Compr Physiol 6:1701-1741, 2016.
Posterior pituitary
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Supraoptic nucleus
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