This study investigates the evolution of snake spermatozoa within a phylogenetic context, with the addition of a new ultrastructural description from the spermatozoa of the Black Swamp Snake, Seminatrix pygaea. Overall the spermatozoon of S. pygaea is similar to that described for other squamates, whereas some characters such as the electron lucent space separating the cortex and medulla of the acrosome complex may be a unique feature of S. pygaea spermatozoa. This preliminary analysis of sperm evolution within Serpentes leads to the hypothesis that some sperm characters are more plastic than others. Incongruencies are found between the molecular and the morphological topologies utilized, and the phylogeny derived from a morphological data set recovers more unequivocal ancestral states of snake sperm structure. Characters such as the beginning of the fibrous sheath at mitochondrial tier one unite the Colubroidea, whereas characters such as the presence of an acrosome vesicle subdivision, absent vacuity subdivision, and round ⁄ oval mitochondria in transverse section unite all squamates. However, from this analysis it is evident that more taxa need to be studied and taxa with current data need to be more thoroughly investigated to make more conclusive remarks regarding the evolution of sperm structure within snakes.
Ticks are protected against ants by release of an allomonal defense secretion from the large wax glands (or type 2 glands) that line their bodies. To explore how the large wax glands operate, before and after microscopic observations of these glands (nonsecreted versus secreted test groups), mass determinations were made for Rhipicephalus sanguineus that had been exhausted of secretion by repeated leg pinching to simulate attack by a predator. Prior to secretion, the glandular organ is fully intact histologically and matches the sensillum sagittiforme, a key taxonomic structure described in the 1940s. The large wax gland is innervated and responds to pressure stimulation as a proprioceptor that stimulates the secretory response. Histological observations after secretion has occurred show that the entire glandular contents and associated cells are jettisoned out of the gland like a syringe. The glandular cellular components are subsequently rebuilt by underlying hypodermal cells within a few days so that secretion can take place again. Presumably, the active allomonal ingredients (hydrocarbons) are released when these derived epidermal cells reach and burst onto the cuticular surface. Our conclusion is that the large wax glands are holocrine and feature intermittent regeneration.
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