Diversity of conotoxin types from Conus californicus reflects a diversity of prey types and a novel evolutionary history.

Most species within the genus Conus are considered to be specialists in their consumption of prey, typically feeding on molluscs, vermiform invertebrates or fish, and employ peptide toxins to immobilize prey. Conus californicus Hinds 1844 atypically utilizes a wide range of food sources from all three groups. Using DNA- and protein-based methods, we analyzed the molecular diversity of C. californicus toxins and detected a correspondingly large number of conotoxin types. We identified cDNAs corresponding to seven known cysteine-frameworks containing over 40 individual inferred peptides. Additionally, we found a new framework (22) with six predicted peptide examples, along with two forms of a new peptide type of unusual length. Analysis of leader sequences allowed assignment to known superfamilies in only half of the cases, and several of these showed a framework that was not in congruence with the identified superfamily. Mass spectrometric examination of chromatographic fractions from whole venom served to identify peptides corresponding to a number of cDNAs, in several cases differing in their degree of posttranslational modification. This suggests differential or incomplete biochemical processing of these peptides. In general, it is difficult to fit conotoxins from C. californicus into established toxin classification schemes. We hypothesize that the novel structural modifications of individual peptides and their encoding genes reflect evolutionary adaptation to prey species of an unusually wide range as well as the large phylogenetic distance between C. californicus and Indo-Pacific species.

Temperature-dependent expression of a squid Kv1 channel in Sf9 cells and functional comparison with the native delayed rectifier.

SqKv1A is a cDNA that encodes a Kv1 (Shaker-type) alpha-subunit expressed only in the giant axon and the parental giant fiber lobe (GFL) neurons of the squid stellate ganglion. We incorporated SqKv1A into a recombinant baculovirus for expression in the insect Sf9 cell line. Whole-cell patch-clamp recordings reveal that very few cells display functional potassium current (IK) if cultured at the standard postinfection temperature of 27 degrees C. At 18 degrees C, less SqKv1A protein is produced than at 27 degrees C, but cells with IK currents are much more numerous and can survive for at least 20 days postinfection (vs. approximately 5 days at 27 degrees C). Activation and deactivation kinetics of SqKv1A in Sf9 cells are slower (approximately 3- and 10-fold, respectively) than those of native channels in GFL neurons, but have similar voltage dependencies. The two cell types show only subtle differences in steady-state voltage-dependence of conductance and inactivation. Rates of IK inactivation in 20 mM external K are identical in the two cell types, but the sensitivity of inactivation to external tetraethylammonium (TEA) and K ions differ: inactivation of SqKv1A in Sf9 cells is slowed by external TEA and K ions, whereas inactivation of GFL IK is largely insensitive. Functional differences are discussed in terms of factors that may be specific to cell-type, including the presence of presently unidentified Kv1 subunits in GFL neurons that might form heteromultimers with SqKv1A.

Natural substitutions at highly conserved T1-domain residues perturb processing and functional expression of squid Kv1 channels.

Shaker-type K-channel alpha-subunits (SqKv1A, B, D) expressed in neurons of the squid stellate ganglion differ in the length of their N-termini and in the species of amino acid present at several points in the T1 domain, an intracellular region involved in the tetramerization process during channel assembly. Heterologous expression of wild-type SqKv1A, B, and D in Xenopus oocytes reveals large differences in the level of both functional channels (assayed by whole-oocyte voltage clamp) and total channel protein (assayed by immunoblotting). Functional expression is poorest with SqKv1A and by far the best with SqKv1D. Biophysical properties of the three SqKv1 channels are essentially identical (assayed by cell-attached patch clamp). Site-directed mutagenesis was used to determine whether the observed differences in expression level are impacted by two residues in the T1 domain at which SqKv1A and B (but not D) differ from the consensus sequences found in many other taxa. In SqKv1A, glycine is substituted for arginine in an otherwise universally conserved sequence (FFDR in the T1(B) subdomain). In SqKv1B, glycine replaces serine in a sequence that is conserved within the Kv1 subfamily (SGLR in the T1(A) subdomain). Restoration of the consensus amino acid at these positions largely accounts for the observed differences in expression level. Analysis of the glycosylation state of aberrant versus restored alpha-subunits suggests that the anomalous amino acids in SqKv1A and B exert their influence during early steps in channel processing and assembly which take place in the endoplasmic reticulum (ER).

Post-hatching development of circular mantle muscles in the squid Loligo opalescens.

Post-hatching development of the circular muscles in the mantle of squid was studied morphometrically to identify structural changes and to quantify hyperplasia and hypertrophy of the muscle fibers. Superficial, mitochondria-rich (SMR) fibers and central, mitochondria-poor (CMP) fibers are present at hatching. Although both fiber types increase in size and, even more so, in number during post-hatching development, CMP fibers increase at a much higher rate than do SMR fibers. As a result, the relative proportion of SMR to CMP fibers shifts from about 1:1 in a hatchling to about 1:6 in an 8-week-old animal; it then apparently remains constant to adulthood. These structural changes are consistent with developmental changes in muscular activity. During slow, jet-propelled swimming, 1-week-old animals show mantle contractions that have twice the relative amplitude and frequency of those in adults. The presence of Na-channel protein in mantle muscle was detected bio-chemically by using site-directed antibodies; the protein was found to be preferentially expressed in CMP fibers. These results suggest that SMR fibers are an important source of locomotory power at hatching, but become progressively less important during the first 8 weeks of development as CMP fibers assume the dominant role in jet locomotion.