Phylogenetic conservation of the cell-type-specific Lan3-2 glycoepitope in Caenorhabditis elegans.

The biological function of a cell-type-specific glycosylation of an adhesion molecule belonging to the L1CAM immunoglobulin superfamily was previously determined in the nervous system of the embryonic leech, Hirudo medicinalis. The Lan3-2 glycoepitope is a surface marker of sensory afferent neurons and is required for their appropriate developmental collateral branching and synaptogenesis in the CNS. The chemical structure of the Lan3-2 glycoepitope consists of beta-(1,4)-linked mannopyranose. Here, we show the conservation of the cell-type-specific expression of this mannose polymer in Caenorhabditis elegans. The Lan3-2 glycoepitope is expressed on the cell surface of a subset of dissociated embryonic neurons and, in the adult worm, by the pharyngeal motor neuron, M5, and the chemosensory afferents, the amphids. Additionally, the vulval epithelium expresses the Lan3-2 glycoepitope in late L4 larvae and in adult hermaphrodites. To investigate proteins carrying this restrictively expressed glycoepitope, worm extract was immunoaffinity purified with Lan3-2 monoclonal antibody and Western blotted. A polyclonal antibody reactive with the cytoplasmic tail of LAD-1/SAX-7, a C. elegans member of the L1CAM family, recognizes a 270 kDa protein band while Lan3-2 antibody also recognizes a 190 kDa glycoform, its putative Lan3-2 ectodomain. Thus, in C. elegans, as in leech, the Lan3-2 epitope is located on a L1CAM homologue. The cell-type-specific expression of the Lan3-2 glycoepitope shared by leech and C. elegans will be useful for understanding how cell-type-specific glycoepitopes mediate cell-cell interactions during development.

The Lan3-2 glycoepitope of Hirudo medicinalis consists of beta-(1,4)-linked mannopyranose: cell type-specific glycans of H. medicinalis.

While glycosyltransferases are restrictively expressed in invertebrate model organisms, little is known of their glycan end products. One such restrictively expressed glycoepitope was localized to sensory and epithelial cells of leech and Caenorhabditis elegans using the Lan3-2 monoclonal antibody. A biological function for the neural Lan3-2 epitope was previously determined in the leech. Here we report on the chemical structure of this mannosidic epitope harvested from whole Hirudo medicinalis. Crude glycans were liberated from glycoproteins by hydrazinolysis. Re-N-acetylated glycans were subjected to immunoaffinity purification. The affinity-purified glycans were fractioned by size chromatography into oligosaccharides and polysaccharides. Lan3-2 oligosaccharide structure was characterized by gas chromatography of alditol acetates, methylation analysis, 500 MHz 1H NMR spectroscopy, matrix-assisted laser desorption/ionization mass spectrometry, and electrospray ionization tandem MS-MS of permethylated derivatives. The predominant components of the Lan3-2 oligosaccharide fraction were a series of linear beta-(1,4)-linked mannose polymers. The homologous expression of the Lan3-2 epitope in C. elegans will facilitate the exploration of its glycosylation pathway. Other invertebrates expressing the Lan3-2 epitope are Planaria dugesia, Capitella sp. I and Lumbriculus variegatus. The glycoepitope was not detected in the diploblastic animals Hydra littoralis and Aptaisia sp. or in deuterostomes.

Leech filamin and Tractin: markers for muscle development and nerve formation.

The Lan3-14 and Laz10-1 monoclonal antibodies recognize a 400 kDa antigen that is specifically expressed by all muscle cells in leech. We show that the antigen recognized by both antibodies is a member of the filamin family of actin binding proteins. Leech filamin has two calponin homology domains and 35 filamin/ABP-repeat domains. In addition, we used the Laz10-1 antibody to characterize the development of the segmentally iterated dorsoventral flattener muscles. We demonstrate that the dorsoventral flattener muscle develops as three discrete bundles of myofibers and that CNS axons pioneering the DP nerve extend only along the middle bundle. Interestingly, the middle dorsoventral muscle anlage is associated with only non-neuronal expression of the L1-family cell adhesion molecule Tractin. This expression is transient and occurs at the precise developmental stages when DP nerve formation takes place. Based on these findings we propose that the middle dorsoventral muscle anlagen provides a substrate for early axonal outgrowth and nerve formation and that this function may be associated with differential expression of distinct cell adhesion molecules.

Accumulation of high-molecular-weight amylose in Alzheimer's disease brains.

Although most of the glucose metabolized in the brain is taken up from the blood, glucose derived from glycogen stores is increasingly implicated in both normal brain function and injury repair. An impaired glucose metabolism is one of the features of Alzheimer's disease (AD) entailing a reduction in glucose transporters and the uptake of glucose as well as alterations in the specific activity of glycolytic enzymes. Here we report that AD brains accumulate amylose, the unbranched alpha(1,4)-linked glucose polymer that is resistant to degradation by glycolytic enzymes. Neutral polysaccharides harvested from postmortem brains were purified with hydrazinolysis, ion exchange, and sizing chromatography and subjected to NMR spectroscopy, GC, GC-MS, and methylation analysis. Five percent of the polysaccharides (50 micro g [0.3 micro mol]/g wet weight brain tissue) consisted of amylose with molecular weights exceeding 600,000 Da. There is no evidence for 1,6-branching, indicating that the polymer is not a form of high-molecular-weight glycogen. By GC analysis, the glucose content of the AD brains was almost three times greater than that of the age-matched control brains. A synthesis of amylose in AD brains at the expense of glycogen would compromise glucose metabolism and enhance neural degeneration.

In vivo dynamics of CNS sensory arbor formation: a time-lapse study in the embryonic leech.

In the embryo of the leech Hirudo medicinalis, afferent projections of peripheral sensory neurons travel along common nerve tracts to the CNS, where they defasciculate, branch, and arborize into separate, modality-specific synaptic laminae. Previous studies have shown that this process requires, at least in part, the constitutive and then modality-specific glycosylations of tractin, a leech L1 homologue. We report here on the dynamics of growth of these projections as obtained by examining the morphology of single growing dye-filled sensory afferents as a function of time. Using 2-photon laser-scanning microscopy of the intact developing embryo, we obtained images of individual sensory projections at 3 to 30 min intervals, over several hours of growth, and at different stages of development. The time-lapse series of images revealed a highly dynamic and maturation-state-dependent pattern of growth. Upon entering the CNS, the growth cone-tipped primary axon sprouted numerous long filopodial processes, many of which appeared to undergo repeated cycles of extension and retraction. The growth cone was transformed into a sensory arbor through the formation of secondary branches that extended within the ganglionic neuropil along the anterior-posterior axis of the CNS. Numerous tertiary and quaternary processes grew from these branches and also displayed cycles of extension and retraction. The motility of these higher-order branches changed with age, with younger afferents displaying higher densities and greater motility than older, more mature sensory arbors. Finally, coincident with a reduction in higher order projections was the appearance of concavolar structures on the secondary processes. Rows of these indentations suggest the formation of presynaptic en-passant specializations accompanying the developmental onset of synapse formation.

Extracellularly applied horseradish peroxidase increases the number of dense core vesicles in leech sensory neurons.

The uptake of horseradish peroxidase (HRP), applied as an extracellular tracer, is a classical method for studying endo/exocytosis of synaptic vesicles at the ultrastructural level. It is generally not considered that HRP may affect neuronal function. Reported here is the finding that extracellularly applied HRP (0.1%) perturbs dense core vesicles in the synaptic processes of leech neurons. The strength of the effect varies with neuronal class. In sensory afferents, the number of dense core vesicles increases 5-fold, while there is only a 2-fold increase in central neurons.

Proteolytic cleavage of the ectodomain of the L1 CAM family member Tractin.

Tractin is a member of the L1 family of cell adhesion molecules in leech. Immunoblot analysis suggests that Tractin is constitutively cleaved in vivo at a proteolytic site with the sequence RKRRSR. This sequence conforms to the consensus sequence for cleavage by members of the furin family of convertases, and this proteolytic site is shared by a majority of other L1 family members. We provide evidence with furin-specific inhibitor experiments, by site-specific mutagenesis of Tractin constructs expressed in S2 cells, as well as by Tractin expression in furin-deficient LoVo cells that a furin convertase is the likely protease mediating this processing. Cross-immunoprecipitations with Tractin domain-specific antibodies suggest that the resulting NH(2)- and COOH-terminal cleavage fragments interact with each other and that this interaction provides a means for the NH(2)-terminal fragment to be tethered to the membrane. Furthermore, in S2 cell aggregation assays we show that the NH(2)-terminal fragment is necessary for homophilic adhesion and that cells expressing only the transmembrane COOH-terminal fragment are non-adhesive. However, tethering of exogeneously provided Tractin NH(2)-terminal fragment to S2 cells expressing only the COOH-terminal fragment can functionally restore the adhesive properties of Tractin.

Sequential steps of carbohydrate signaling mediate sensory afferent differentiation.

Differences in carbohydrate signaling control sequential steps in synaptic growth of sensory afferents in the leech. The relevant glycans are constitutive and developmentally regulated modifications of leechCAM and Tractin (family members of NCAM and L1) that are specific to the surface of sensory afferents. A mannosidic glycosylation mediates the dynamic growth of early afferents as they explore their target region through sprouting sensory arbors rich with synaptic vesicles. Later emerging galactosidic glycosylations serve as markers for subsets of the same sensory afferents that correlate with different sensory modalities. These developmentally regulated galactose markers now oppose the function of the constitutive mannose marker. Sensory afferents gain cell-cell contact with central neurons and self-similar afferents, but lose filopodia and synaptic vesicles. Extant vesicles are confined to sites of en passant synapse formation. The transformation of sensory afferent growth, progressing from mannose- to galactose-specific recognition, is consistent with a change from cell-matrix to cell-cell contact. While the constitutive mannosidic glycosylation promotes dynamic growth, developmentally regulated galactosidic glycosylations of the same cell adhesion molecules promote tissue stability. The persistence of both types of neutral glycans beyond embryonic age allows their function in synaptic plasticity during habituation and learning.