Characterization of the parallel rod floor apparatus to test motor incoordination in mice.

Impairment of motor coordination, or ataxia, is a prominent effect of alcohol ingestion in humans. To date, many models have been created to examine this phenomenon in animals. Evidence suggests that the tasks thought to measure this behavior in mice actually measure different components of this complex trait. We have characterized the parallel rod floor apparatus to quantify ethanol-induced motor incoordination. Using genetically heterogeneous mice, we evaluated the influence of rod diameter and inter-rod distance on dose-related ethanol-induced motor incoordination to select parameters that optimized testing procedures. We then used the DBA/2J and C57BL/6J inbred strains of mice to examine the effect of 2 g/kg of ethanol, by serially testing mice on two floor types, separated by 1 week. Finally, we tested eight inbred strains of mice on four floor types to examine patterns of strain sensitivity to 2 g/kg of intraperitoneal ethanol and determined the test parameters that maximized strain effect size. Motor incoordination varied depending on the floor type and strain. When data from strain 129S1/SvlmJ were removed from the analyses because of their extreme behavior, the greatest strain effect size was observed on one floor type during the first 10 min of testing after 2 g/kg of intraperitoneal ethanol. These findings suggest that the parallel rod floor apparatus provides a useful means for examining ethanol-induced motor incoordination in mice but that specific testing procedures are important for optimizing detection of motor incoordination and genetic influences.

The molecular characterization of transport vesicles.

Secretion, endocytosis and transport to the lytic compartment are fundamental, highly coordinated features of the eukaryotic cell. These intracellular transport processes are facilitated by vesicles, many of which are small (100 nm or less in diameter) and 'coated' on their cytoplasmic surface. Research into the structure of the coat proteins and how they interact with the components of the vesicle membrane to ensure the selective packaging of the cargo molecules and their correct targeting, has been quite extensive in mammalian and yeast cell biology. By contrast, our knowledge of the corresponding types of transport vesicles in plant cells is limited. Nevertheless, the available data indicate that a considerable homology between plant and non-plant coat polypeptides exists, and it is also suggestive of a certain similarity in the mechanisms underlying targeting in all eukaryotes. In this article we shall concentrate on three major types of transport vesicles: clathrin-coated vesicles, COP-coated vesicles, and 'dense' vesicles, the latter of which are responsible for the transport of vacuolar storage proteins in maturing legume cotyledons. For each we will summarize the current literature on animal and yeast cells, and then present the relevant data derived from work on plant cells. In addition, we briefly review the evidence in support of the 'SNARE' hypothesis, which explains how vesicles find and fuse with their target membrane.

Functional interaction of the auxilin J domain with the nucleotide- and substrate-binding modules of Hsc70.

The uncoating of clathrin-coated vesicles requires the DnaJ homologue auxilin for targeting Hsc70 to clathrin coats. This function involves a transient interaction of the auxilin J domain with Hsc70. We have now identified the structural elements of Hsc70 that are responsible for the uncoating activity, and we show that the hitherto accepted view, which implicates the 10-kDa carboxyl-terminal variable domain of Hsc70, is incorrect. A 60-kDa chymotryptic or analogous recombinant fragment of Hsc70, which contains the ATPase- and substrate-binding domains, is sufficient to liberate clathrin from coated vesicles. Consistent with this was the observation that Hsp70 uncoats coated vesicles with the same efficacy as Hsc70 and that DnaK possesses vestigial uncoating activity. Direct binding studies demonstrated that the auxilin J domain undergoes an ATP-dependent reaction only with fragments of Hsc70 that contain both the ATPase- and substrate-binding domains. The individual domains by themselves did not bind to the J domain nor did a recombinant protein that contained the substrate-binding domain attached to the 10-kDa variable domain.

Mechanism of clathrin basket dissociation: separate functions of protein domains of the DnaJ homologue auxilin.

Auxilin was recently identified as cofactor for hsc70 in the uncoating of clathrin-coated vesicles (Ungewickell, E., H. Ungewickell, S.E. Holstein, R. Lindner, K. Prasad, W. Barouch, B. Martin, L.E. Greene, and E. Eisenberg. 1995. Nature (Lond.). 378: 632-635). By constructing different glutathione-S-transferase (GST)-auxilin fragments, we show here that cooperation of auxilin's J domain (segment 813-910) with an adjoining clathrin binding domain (segment 547-814) suffices to dissociate clathrin baskets in the presence of hsc70 and ATP. When the two domains are expressed as separate GST fusion proteins, the cofactor activity is lost, even though both retain their respective functions. The clathrin binding domain binds to triskelia like intact auxilin with a maximum stoichiometry of 3 and concomitantly promotes their assembly into regular baskets. A fragment containing auxilin's J domain associates in an ATP-dependent reaction with hsc70 to form a complex with a half-life of 8 min at 25 degrees C. When the clathrin binding domain and the J domain are recombined via dimerization of their GST moieties, cofactor activity is partially recovered. The interaction between auxilin's J domain and hsc70 causes rapid hydrolysis of bound ATP. Release of inorganic phosphate appears to be correlated with the disintegration of the complex between auxilin's J domain and hsc70. We infer that the metastable complex composed of auxilin, hsc70, ADP, and P(i) contains an activated form of hsc70, primed to engage clathrin that is brought into apposition with it by the DnaJ homologue auxilin.

Role of auxilin in uncoating clathrin-coated vesicles.

Clathrin-coated vesicles transport selected integral membrane proteins from the cell surface and the trans-Golgi network to the endosomal system. Before fusing with their target the vesicles must be stripped of their coats. This process is effected by the chaperone protein hsp70c together with a 100K cofactor which we here identify as the coat protein auxilin. Auxilin binds with high affinity to assembled clathrin lattices and, in the presence of ATP, recruits hsp70c. Dissociation of the lattice does not depend as previously supposed on clathrin light chains or on the amino-terminal domain of the heavy chain. The presence of a J-domain at its carboxy terminus now defines auxilin as a member of the DnaJ protein family. In conjunction with hsp70, DnaJ proteins catalyse protein folding, protein transport across membranes and the selective disruption of protein-protein interactions. We show that deletion of the J-domain of auxilin results in the loss of cofactor activity.

Identification of a beta-type adaptin in plant clathrin-coated vesicles.

Plant clathrin-coated vesicles (CCV), suitably protected against proteolysis, were isolated from zucchini hypocotyls, and screened for the presence of adaptin-like polypeptides using monoclonal antibodies prepared against alpha, beta(beta') and gamma-adaptins of bovine brain. An immunoreactive polypeptide in plant CCV was only detected in the case of the beta(beta')-adaptin antibody. This polypeptide has a molecular mass of 108 kDa in SDS-PAGE, and gives rise to a major cleavage product of 70 kDa after proteolysis with trypsin. Gel filtration of 0.75 M MgCl2-dissociated coat proteins showed that the plant beta(beta')-type adaptin eluted with other polypeptides in a manner similar to the adaptor complexes of brain CCV. Upon subsequent hydroxyapatite chromatography the immunoreactive polypeptide eluted in fractions corresponding to Golgi (HA-I) rather than plasma membrane (HA-II) brain adaptor complexes. In addition, this polypeptide did not shift to a higher molecular mass when subjected to urea-SDS-PAGE. Confirmation of the presence of a beta-type adaptin in plants was provided by dot and Southern blotting experiments using genomic DNA from zucchini hypocotyls and a beta-adaptin cDNA clone from human fibroblasts.

Membranes markers in highly purified clathrin-coated vesicles from Cucurbita hypocotyls.

The two plasma-membrane (PM) markers: 1,3-ß-glucan synthase and naphthylphthalamic-acid-binding capacity are localized in two peaks of activity on isopycnic Ficoll/D2O gradients prepared from a zucchini (Cucurbita pepo L.) hypocotyl post-microsomal fraction. The denser peak overlaps with the major distribution of clathrin and represents a region of the gradient enriched in coated vesicles (cv). Further purification of the pooled cv-fractions has shown that these PM marker activities are not borne by the cv, but are instead carried by smooth membrane fragments also present in these fractions. As judged from the results of Western blotting with polyclonal antibodies prepared against the 100-kilodalton (kDa) subunit of a PM H(+)-ATPase and the 70-kDa subunit of a tonoplastic H(+)-ATPase, these contaminants are of both PM and endomembrane origin. The PM contaminants however, differ from phase-partitioning- and free-flow-electrophoresis-purified PM prepared from microsomal fractions of zucchini hypocotyls in terms of their bouyant density in Ficoll/D2O gradients. Moreover, they do not appear to be present as sealed, outside-out, vesicles. Highly purified cv fractions from zucchini hypocotyls cross-react with subunit antibodies from both vacuolar and PM H (+)-ATPases. These results are discussed in terms of recent findings on cv ATPases from bovine brain.