Integrative omics analysis reveals differentially distributed proteins in dimorphic euspermatozoa of the squid, Loligo bleekeri.

In the coastal squid Loligo bleekeri, each male produces one of two types of fertilization-competent spermatozoa (eusperm) that exhibit morphological and behavioral differences. Large "consort" males produce short-tailed spermatozoa that display free-swimming behavior when ejaculated into seawater. Small "sneaker" males, on the other hand, produce long-tailed spermatozoa that exhibit a self-swarming trait after ejaculation. To understand the molecular basis for adaptive traits employed by alternative male mating tactics, we performed the transcriptome deep sequencing (RNA-seq) and proteome analyses to search for differences in testicular mRNAs and sperm proteins, respectively. From mature male testes we identified a total of 236,455 contigs (FPKM ≧1) where 3789 and 2789 were preferentially (≧10-fold) expressed in consort and sneaker testes, respectively. A proteomic analysis detected 4302 proteins in the mature sperm as post-translational products. A strongly biased (≧10-fold) distribution occurred in 55 consort proteins and 61 sneaker proteins. There was no clear mRNA-protein correlation, making a ballpark estimate impossible for not only overall protein abundance but also the degree of biased sperm type expressed in the spermatozoa. A family encoding dynein heavy chain gene, however, was found to be biased towards sneakers, whereas many enzymes involving energy metabolism were heavily biased towards consort spermatozoa. The difference in flagellar length matched exactly the different amount of tubulins. From these results we hypothesize that discrete differential traits in dimorphic eusperm arose from a series of innovative alterations in the intracellular components of spermatozoa.

Immunostaining of peripheral nerves and other tissues in whole mount preparations from hatchling cephalopods.

Newly hatched paralarvae ("hatchlings") or late-stage embryos of Loligo opalescens were dissected and pieces of tissue removed for immunostaining as flat whole mounts. The general layout of the peripheral nervous system in the mantle and gills was investigated using antisera for tubulin and FMRFamide. Primary sensory neurons are densely distributed in the outer mantle epidermis and show strong FMRFamide immunoreactivity. Their axons form a plexus in the underlying dermis, but do not appear to innervate the chromatophore muscles, which are well visualized with anti-tubulin. Some cross the muscle layer and enter the stellate ganglia via the stellar nerves. The stellate ganglion neuropil contains a rich FMRFamide-immunoreactive mass of axons. It is suggested that these axons originate in large part from sensory neurons in the skin and that the known modulatory effects of FMRFamide-related peptides on motor output of the stellate ganglion may be a reflection of this sensory input in normal life. FMRFamide-immunoreactive primary sensory neurons are also abundant in the gills, but unlike those in the mantle, these cells lack cilia or other external projections. Anti-tubulin staining reveals a network of interstitial cells in the mantle dermis. Such networks may have been mistaken for nerve nets in older accounts. Additional results with Octopus vulgaris hatchlings and immunostaining for serotonin (5HT), small cardioactive peptide (SCP), and gonadotropin releasing hormone (GnRH) are briefly reported.

Malleable skin coloration in cephalopods: selective reflectance, transmission and absorbance of light by chromatophores and iridophores.

Nature's best-known example of colorful, changeable, and diverse skin patterning is found in cephalopods. Color and pattern changes in squid skin are mediated by the action of thousands of pigmented chromatophore organs in combination with subjacent light-reflecting iridophore cells. Chromatophores (brown, red, yellow pigment) are innervated directly by the brain and can quickly expand and retract over underlying iridophore cells (red, orange, yellow, green, blue iridescence). Here, we present the first spectral account of the colors that are produced by the interaction between chromatophores and iridophores in squid (Loligo pealeii). Using a spectrometer, we have acquired highly focused reflectance measurements of chromatophores, iridophores, and the quality and quantity of light reflected when both interact. Results indicate that the light reflected from iridophores can be filtered by the chromatophores, enhancing their appearance. We have also measured polarization aspects of iridophores and chromatophores and show that, whereas structurally reflecting iridophores polarize light at certain angles, pigmentary chromatophores do not. We have further measured the reflectance change that iridophores undergo during physiological activity, from "off" to various degrees of "on", revealing specifically the way that colors shift from the longer end (infra-red and red) to the shorter (blue) end of the spectrum. By demonstrating that three color classes of pigments, combined with a single type of reflective cell, produce colors that envelop the whole of the visible spectrum, this study provides an insight into the optical mechanisms employed by the elaborate skin of cephalopods to give the extreme diversity that enables their dynamic camouflage and signaling.