Assembly and regulation of acetylcholinesterase at the vertebrate neuromuscular junction.

The collagen-tailed form of acetylcholinesterase (ColQ-AChE) is the major if not unique form of the enzyme associated with the neuromuscular junction (NMJ). This enzyme form consists of catalytic and non-catalytic subunits encoded by separate genes, assembled as three enzymatic tetramers attached to the three-stranded collagen-like tail (ColQ). This synaptic form of the enzyme is tightly attached to the basal lamina associated with the glycosaminoglycan perlecan. Fasciculin-2 is a snake toxin that binds tightly to AChE. Localization of junctional AChE on frozen sections of muscle with fluorescent Fasciculin-2 shows that the labeled toxin dissociates with a half-life of about 36 h. The fluorescent toxin can subsequently be taken up by the muscle fibers by endocytosis giving the appearance of enzyme recycling. Newly synthesized AChE molecules undergo a lengthy series of processing events before final transport to the cell surface and association with the synaptic basal lamina. Following co-translational glycosylation the catalytic subunit polypeptide chain interacts with several molecular chaperones, glycosidases and glycosyltransferases to produce a catalytically active enzyme that can subsequently bind to one of two non-catalytic subunits. These molecular chaperones can be rate limiting steps in the assembly process. Treatment of muscle cells with a synthetic peptide containing the PRAD attachment sequence and a KDEL retention signal results in a large increase in assembled and exportable AChE, providing an additional level of post-translational control. Finally, we have found that Pumilio2, a member of the PUF family of RNA-binding proteins, is highly concentrated at the vertebrate neuromuscular junction where it plays an important role in regulating AChE translation through binding to a highly conserved NANOS response element in the 3'-UTR. Together, these studies define several new levels of AChE regulation in electrically excitable cells.

Molecular analysis of the 18S rRNA gene of Cryptosporidium serpentis in a wild-caught corn snake (Elaphe guttata guttata) and a five-species restriction fragment length polymorphism- based assay that can additionally discern C. parvum from C. wrairi.

An adult wild-caught corn snake (Elaphe guttata guttata) was presented for humane euthanasia and necropsy because of severe cryptosporidiosis. The animal was lethargic and >5% dehydrated but in good flesh. Gastric lavage was performed prior to euthanasia. Histopathologic findings included gastric mucosal hypertrophy and a hemorrhagic erosive gastritis. Numerous 5- to 7-microm-diameter round extracellular organisms were associated with the mucosal hypertrophy. A PCR, acid-fast stains, Giemsa stains, and an enzyme immunoassay were all positive for Cryptosporidium spp. PCR and restriction fragment length polymorphism (RFLP) analysis on gastric lavage and gastric mucosal specimens, and subsequent sequencing of the 18S rRNA gene, enabled a distinct molecular characterization of the infecting organism as Cryptosporidium serpentis. Until recently, studies on snake Cryptosporidium have relied on host specificity and gross and histopathologic observations to identify the infecting species. A multiple alignment of our sequence against recently published sequences of the 18S rRNA gene of C. serpentis (GenBank accession no. AF093499, AF093500, and AF093501 [L. Xiao et al., unpublished data, 1998]) revealed 100% homology with the C. serpentis (Snake) sequence (AF093499) previously described by Xiao et al. An RFLP method to differentiate the five presently sequenced strains of Cryptosporidium at this locus was developed. This assay, which uses SpeI and SspI, complements a previously reported assay by additionally distinguishing the bovine strain of Cryptosporidium from Cryptosporidium wrairi.