Cell confluence-dependent remodeling of endothelial membranes mediated by cholesterol.

The plasma membranes of endothelial cells reaching confluence undergo profound structural and functional modifications, including the formation of adherens junctions, crucial for the regulation of vascular permeability and angiogenesis. Adherens junction formation is accompanied by the tyrosine dephosphorylation of adherens junctions proteins, which has been correlated with the strength and stability of adherens junctions. Here we show that cholesterol is a critical determinant of plasma membrane remodeling in cultures of growing cow pulmonary aortic endothelial cells. Membrane cholesterol increased dramatically at an early stage in the formation of confluent cow pulmonary aortic endothelial cell monolayers, prior to formation of intercellular junctions. This increase was accompanied by the redistribution of caveolin from a high density to a low density membrane compartment, previously shown to require cholesterol, and increased binding of the annexin II-p11 complex to membranes, consistent with other studies indicating cholesterol-dependent binding of annexin II to membranes. Furthermore, partial depletion of cholesterol from confluent cells with methyl-beta-cyclodextrin both induced tyrosine phosphorylation of multiple membrane proteins, including adherens junctions proteins, and disrupted adherens junctions. Both effects were dramatically reduced by prior complexing of methyl-beta-cyclodextrin with cholesterol. Our results reveal a novel physiological role for cholesterol regulating the formation of adherens junctions and other plasma membrane remodeling events as endothelial cells reach confluence.

Identification of an early endosomal protein regulated by phosphatidylinositol 3-kinase.

Phosphatidylinositol 3-kinases (PI 3-kinases) have been implicated in membrane trafficking in the secretory and endocytic pathways of yeast and mammalian cells, but the molecular mechanisms by which these lipid kinases operate are not known. Here we identify a protein of 170 kDa that is rapidly released from cell membranes in response to wortmannin, a potent inhibitor of mammalian PI 3-kinases. The amino acid sequence of peptides from p170 reveal its identity to early endosomal antigen (EEA) 1, an endosomal antigen with homology to several yeast proteins genetically implicated in membrane trafficking. Immunofluorescence analysis of 3T3-L1 adipocytes with antisera against p170/EEA1 reveal a punctate peripheral pattern that becomes diffuse in response to wortmannin. In vitro, p170/EEA1 binds specifically to liposomes containing PIns(3)P, suggesting that the effect of wortmannin on cells is due to inhibition of PIns(3)P production. Thus, p170/EEA1 may define a family of proteins that mediate the regulatory effects of 3'-phosphoinositides on membrane trafficking in yeast and mammalian cells.

A binding site for SH3 domains targets dynamin to coated pits.

Dynamin is a GTPase that plays a critical role in the very early stages of endocytosis, regulating the scission of clathrin-coated and non-clathrin-coated pits from the plasma membrane. While the ligands through which dynamin exerts its in vivo effects are unknown, dynamin exhibits in vitro binding to several proteins containing Src homology 3 (SH3) domains, as well as to microtubules and anionic phospholipids, via a basic, proline-rich C-terminal domain. To begin to identify the in vivo binding partners of dynamin, we have examined by immunofluorescence the association of mutant and wild-type forms of dynamin with plasma membranes prepared by sonication of transiently transfected cells. Wild-type dynamin was found almost exclusively in association with clathrin-containing domains. Binding to these regions was abolished by removal of a nine-amino acid sequence within the C-terminal domain encoding a candidate SH3 domain binding site. Binding did not require clathrin and resisted extraction at both high and low ionic strength, consistent with an interaction with an SH3 domain. Surprisingly, we also find that dynamin contains multiple regions involved in binding to nonclathrin-containing domains, including a 13-amino acid sequence directly upstream of the C-terminal domain. These observations suggest that a protein containing an SH3 domain is involved in recruiting dynamin to coated pits and provide the first evidence for a biological role for SH3 domains in dynamin function.

Microtubules and Src homology 3 domains stimulate the dynamin GTPase via its C-terminal domain.

Dynamin is a 100-kDa GTPase that plays a critical role in the initial stages of endocytosis. Dynamin binds to microtubules, which potently stimulate its GTPase activity. Binding to Src homology 3 (SH3) domains of proteins involved in signal transduction has also recently been reported. In the present study, the protein was digested with a variety of proteases to define its functional domains. Limited digestion with papain split the protein into an approximately 7- to 9-kDa microtubule-binding fragment and a 90-kDa nonbinding fragment. Immunoblotting with an antibody to the C-terminal 20 amino acids of rat dynamin showed the small fragment to derive from the C-terminal end of the polypeptide. Microtubule-activated GTPase activity, but not basal GTPase activity, was abolished by papain digestion, identifying the basic, proline-rich C-terminal region of dynamin as an important regulatory site. Bacterially expressed growth factor receptor-bound protein 2 (GRB2) and the SH3 domain of c-Src were also found to stimulate GTPase activity, although to a lesser extent than microtubules. Stimulation of GTPase activity by the recombinant proteins was similarly abolished by papain digestion. These results identify the basic, proline-rich C-terminal region of dynamin as the binding site for both microtubules and SH3 domains and demonstrate an allosteric interaction between this region of the molecule and the N-terminal GTPase domain.

Dynamin, a GTPase involved in the initial stages of endocytosis.

Dynamin is a high molecular mass (100 kDa) GTPase which binds to and co-purifies with microtubules. Molecular cloning of rat brain dynamin has revealed the three well-established consensus sequence elements for GTP binding within the N-terminal third of the protein, as well as sequence similarity within this region to the interferon-inducible antiviral Mx proteins, the product of the yeast membrane sorting gene VPS1, and the product of the yeast mitochondrial replication gene MGM1. More extensive sequence similarity between rat dynamin and the product of the Drosophila gene shibire, which is involved in endocytosis, has also been found. In in vitro assays microtubules strongly stimulate the dynamin GTPase. This effect can be reversed by removal of the dynamin C-terminus using papain, which abolishes microtubule binding. Overexpression of mutant forms of dynamin in vivo using Cos-7 cells inhibits transferrin uptake and alters the distribution of clathrin and of alpha-adaptin, but not gamma-adaptin. Deletion of the C-terminus of mutant forms of dynamin abolishes these effects. Together these results suggest a critical role for dynamin in the early stages of endocytosis. It is uncertain whether microtubules interact with dynamin in vivo or whether the in vitro effects of microtubules mimic the effects of other regulatory elements in vivo.

Dynamin is a GTPase stimulated to high levels of activity by microtubules.

Dynamin was initially identified in calf brain tissue as a protein of relative molecular mass 100,000 which induced nucleotide-sensitive bundling of microtubules. Purified dynamin showed only trace ATPase activity. But in combination with an activating factor removed during the purification, it exhibited microtubule-activated ATPase activity and dynamin-induced bundles showed evidence of ATP-dependent force production. Dynamin is the product of the Drosophila gene shibire, which has been implicated in synaptic vesicle recycling and, more generally, in the budding of endocytic vesicles from the plasma membrane. Dynamin also shows extensive homology with proteins that participate in vacuolar protein sorting and spindle pole-body separation in yeast, and in interferon-induced viral resistance in mammals. All members of this family contain consensus sequence elements consistent with GTP binding near their amino termini, although none has been shown to have GTPase activity. We report here that dynamin is a specific GTPase which can be stimulated to very high levels of activity by microtubules.

Dynamin: a microtubule-associated GTP-binding protein.

We recently identified dynamin as a third nucleotide-sensitive microtubule-associated protein in brain tissue, in addition to kinesin and cytoplasmic dynein. Molecular cloning analysis has revealed that dynamin contains the three consensus elements characteristic of GTP-binding proteins, and biochemical results support a role for GTP in dynamin function. Dynamin is also homologous to the Mx proteins, involved in interferon-induced viral resistance, and the product of the yeast VPS1 gene, involved in vacuolar protein sorting. These results identify a novel class of GTP-utilizing proteins, with apparently diverse functions.

Molecular cloning of the microtubule-associated mechanochemical enzyme dynamin reveals homology with a new family of GTP-binding proteins.

A complementary DNA encoding the D100 polypeptide of rat brain dynamin--a force-producing, microtubule-activated nucleotide triphosphatase--has been cloned and sequenced. The predicted amino acid sequence includes a guanine nucleotide-binding domain that is homologous with those of a family of antiviral factors, inducible by interferon and known as Mx proteins, and with the product of the essential yeast vacuolar protein sorting gene VPS1. These relationships imply the existence of a new family of GTPases with physiological roles that may include microtubule-based motility and protein sorting.

Identification of dynamin, a novel mechanochemical enzyme that mediates interactions between microtubules.

We report that calf brain microtubules prepared without nucleotide contain, in addition to kinesin and dynein, a polypeptide of 100 kd that could be dissociated by nucleotide. The protein was selectively extracted from microtubules using a combination of GTP and AMP-PNP. The extract contained microtubule-stimulated (6-fold) MgATPase activity that partitioned into two components upon further purification: the 100 kd polypeptide and a soluble activating fraction. The 100 kd protein induced microtubules to form hexagonally packed bundles containing periodic cross bridges spaced 13 nm apart. In the presence of ATP and the activating fraction, bundles fragmented, elongated, and exhibited other behavior indicative of sliding between microtubules. These findings indicate that the 100 kd protein is part of a novel mechanochemical enzyme, which we term "dynamin", that may mediate microtubule sliding in vivo.

The role of dynein in retrograde axonal transport.

Fast axonal transport is manifested at the sub-cellular level as the anterograde or retrograde movement of membrane-bounded organelles along microtubules. Earlier work implicated the protein kinesin as the motor for anterograde axonal transport. More recent work indicates that a brain microtubule-associated protein, MAP 1C, is responsible for retrograde transport. Of additional interest, MAP 1C has been found to be a cytoplasmic form of the ciliary and flagellar ATPase dynein, indicating a much more general functional role for this enzyme in cells than had been suspected.

Characterization of the microtubule-activated ATPase of brain cytoplasmic dynein (MAP 1C).

We recently found that the brain cytosolic microtubule-associated protein 1C (MAP 1C) is a microtubule-activated ATPase, capable of translocating microtubules in vitro in the direction corresponding to retrograde transport. (Paschal, B. M., H. S. Shpetner, and R. B. Vallee. 1987b. J. Cell Biol. 105:1273-1282; Paschal, B. M., and R. B. Vallee. 1987. Nature [Lond.]. 330:181-183.). Biochemical analysis of this protein (op. cit.) as well as scanning transmission electron microscopy revealed that MAP 1C is a brain cytoplasmic form of the ciliary and flagellar ATPase dynein (Vallee, R. B., J. S. Wall, B. M. Paschal, and H. S. Shpetner. 1988. Nature [Lond.]. 332:561-563). We have now characterized the ATPase activity of the brain enzyme in detail. We found that microtubule activation required polymeric tubulin and saturated with increasing tubulin concentration. The maximum activity at saturating tubulin (Vmax) varied from 186 to 239 nmol/min per mg. At low ionic strength, the Km for microtubules was 0.16 mg/ml tubulin, substantially lower than that previously reported for axonemal dynein. The microtubule-stimulated activity was extremely sensitive to changes in ionic strength and sulfhydryl oxidation state, both of which primarily affected the microtubule concentrations required for half-maximal activation. In a number of respects the brain dynein was enzymatically similar to both axonemal and egg dyneins. Thus, the ATPase required divalent cations, calcium stimulating activity less effectively than magnesium. The MgATPase was inhibited by metavandate (Ki = 5-10 microM for the microtubule-stimulated activity), 1 mM NEM, and 1 mM EHNA. In contrast to other dyneins, the brain enzyme hydrolyzed CTP, TTP, and GTP at higher rates than ATP. Thus, the enzymological properties of the brain cytoplasmic dynein are clearly related to those of other dyneins, though the brain enzyme is unique in its substrate specificity and in its high sensitivity to stimulation by microtubules.

Microtubule-associated protein 1C from brain is a two-headed cytosolic dynein.

Dynein, an ATPase, is the force-generating protein in cilia and flagella. It has long been speculated that cytoplasmic microtubules contain a related enzyme involved in cell division or in intracellular organelle transport. A 'cytoplasmic dynein' has been described in sea urchin eggs, but because the egg stockpiles precursors for both cytoplasmic and ciliary microtubules, the role of this enzyme in the cell has remained unresolved. We recently found that the microtubule-associated protein (MAP) 1C (ref. 6) from brain is a microtubule-activated ATPase that produces force in the direction corresponding to retrograde organelle transport in the cell. MAP 1C has several similar properties to ciliary and flagellar dynein. Here we show directly, using scanning transmission electron microscopy, that MAP 1C is structurally equivalent to the ciliary and flagellar enzyme and is the long-sought cytoplasmic analogue of this enzyme.

MAP 1C is a microtubule-activated ATPase which translocates microtubules in vitro and has dynein-like properties.

We observe that one of the high molecular mass microtubule-associated proteins (MAPs) from brain exhibits nucleotide-dependent binding to microtubules. We identify the protein as MAP IC, which was previously described in this laboratory as a minor component of standard microtubule preparations (Bloom, G.S., T. Schoenfeld, and R.B. Vallee, 1984, J. Cell Biol., 98:320-330). We find that MAP 1C is enriched in microtubules prepared in the absence of nucleotide. Kinesin is also found in these preparations, but can be specifically extracted with GTP. A fraction highly enriched in MAP 1C can be prepared by subsequent extraction of the microtubules with ATP. Two activities cofractionate with MAP 1C upon further purification, a microtubule-activated ATPase activity and a microtubule-translocating activity. These activities indicate a role for the protein in cytoplasmic motility. MAP 1C coelectrophoreses with the beta heavy chain of Chlamydomonas flagellar dynein, and has a sedimentation coefficient of 20S. Exposure to ultraviolet light in the presence of vanadate and ATP results in the production of two large fragments of MAP 1C. These characteristics suggest that MAP 1C may be a cytoplasmic analogue of axonemal dynein.