Polarization Vision in Cephalopods: Neuroanatomical and Behavioral Features that Illustrate Aspects of Form and Function

Polarization sensitivity (PS), which arises from the orthogonal arrangement of microvilli in the retina, has long been known in shallow-water cephalopods. Micrographs presented herein signify that some deep-water cephalopods may also possess PS. Precise measurements of the angles of microvilli in the retinas of shallow-water octopus, squid and cuttlefish revealed neuroanatomical differences that may explain variation in the limits of polarization angular discrimination in different species and habitats. A question yet unanswered is whether cephalopods can discriminate between polarization and intensity. Recent behavioral experimentation has illustrated that one clear function of PS is enhanced predation: it enables better detection of transparent, opaque, or silvery-reflecting prey. The use of PS for navigation in cephalopods is still controversial, and our recent experiment on squids failed to support this notion. It is possible that cephalopods show polarization patterning produced in their skin as a mode of communication that cannot be detected by polarization-insensitive predators such as many fishes and marine mammals.     

Groundnut (Arachis hypogaea L.) cultivars for cultivation on calcareous soils

Summary Studies of incubation experiments showed that the phosphorus turnover under aerobic decomposition in soil starts with a non-biological process, which is rapid and probably due to chemical fixation. The present study allowed a distinction to be made between chemical fixation and biological immobilisation of added phosphorus with special reference to the effects of addition of energy material in the process of biological turnover. Invariably, both glucose and cellulose additions resulted in an increase in phosphorus immobilisation. Comparatively, cellulose acted slowly on phosphorus turnover, with the prospect of more immobilisation in long term experiments. re]19730416     

Bipedal locomotion in Octopus vulgaris: A complementary observation and some preliminary considerations

Lacking an external shell and a rigid endoskeleton, octopuses exhibit a remarkable flexibility in their movements. Bipedal locomotion is perhaps the most iconic example in this regard. Until recently, this peculiar mode of locomotion had been observed only in two species of tropical octopuses: Amphioctopus marginatus and Abdopus aculeatus. Yet, recent evidence indicates that bipedal walking is also part of the behavioral repertoire of the common octopus, Octopus vulgaris. Here we report a further observation of a defense behavior that encompasses both postural and locomotory elements of bipedal locomotion in this cephalopod. By highlighting differences and similarities with the other recently published report, we provide preliminary considerations with regard to bipedal locomotion in the common octopus.