John W. Forsythe

Effect of temperature on laboratory growth, reproduction and life span of Octopus bimaculoides

Laboratory culture of 40 Octopus bimaculoides from April 1982 to August 1983 through the full life cycle at 18°C vs 23°C provided information on the growth, reproductive biology and life span of this California littoral octopus. At 18°C, the cephalopods grew from a hatchling size of 0.07 g to a mean of 619 g in 404 d; the largest individual was 872 g. Octopuses cultured at 23°C reached their highest mean weight of 597 g in 370 d; the largest individual grown at this temperature was 848 g after 404 d. Growth data revealed a two-phase growth pattern: a 5 mo exponential phase followed by a slower logarithmic (power function) phase until spawning. At 5 mo octopuses grown at 23°C were over three times larger than their 18°C siblings. However, beyond 6.5 mo, growth rates were no higher at 23°C than at 18°C. At 13.5 mo, the mean weight of the 18°C group surpassed that of the 23°C group. The slope of the length/weight (L/W) relationship was significantly different for the two temperature regimes, with the 23°C octopuses weighing 18% less than their 18°C siblings at a mantle length of 100 mm. Females weighed more than males at any given mantle length. Males grew slightly larger and matured before females. The L/W relationship indicated isometric body growth throughout the life cycle. Higher temperature accelerated all aspects of reproductive biology and shortened life span by as much as 20% (from approximately 16 to 13 mo). O. bimaculoides has one of the longest life cycles among species with large eggs and benthic hatchlings. Extrapolations to field growth are made, and the possible effects of temperature anomalies such as El Niño are discussed.

Foraging and associated behavior by Octopus cyanea Gray, 1849 on a coral atoll, French Polynesia

Individual Octopus cyanea Gray, 1849 were observed continuously while foraging over a 6 day period during daylight hours. Foraging usually occurred once early in the morning and once late in the afternoon, and successive forages did not duplicate the same routes. On average, single forages (n = 16) covered 81 m (max. 129 m), lasted 118 min (max. 6 h), and often included up to five types of substrata. Octopuses spent about 28% of daylight hours foraging, usually in a saltatory (stop and go) search strategy. Small fishes (five species) often followed foraging octopuses. Foraging was tactile and speculative: octopuses either pounced on a likely object with the web spread, or groped deeply into crevices with the long arms, according to substratum. No octopus was observed to make direct, visually guided attacks on prey. These field observations suggest that their keen eyesight is used for determining the foraging path, scanning for predators, matching the substrata for crypsis, and finding their way back to their dens.

The effects of crowding on growth of the European cuttlefish, Sepia officinalis Linnaeus, 1758 reared at two temperatures.

The objective of this study was to examine the impact of crowding (stocking density) on food consumption and growth of juvenile Sepia officinalis reared at 17 and 25 °C. Two groups of 75 cuttlefish each were reared in closed seawater systems with water temperatures of 17 and 25 °C. Each group was subdivided into two treatments (three replicates per treatment): low-density (equivalent to 100 Sepia m−2) and high-density (equivalent to 400 Sepia m−2). Food consumption was measured daily and live wet body weight (g) was measured weekly over a 5-week study. The 25 °C treatment resulted in significantly higher growth rates and food consumption compared to the 17 °C treatment. Stocking density had no statistically significant effect on food consumption, gross growth efficiency (GGE), or weight at either temperature. However, the high-density treatments had slightly lower GGE values overall and growth in weight at 25 °C was slightly but consistently lower in the high-density treatment suggesting that stocking densities of 400 Sepia m−2 may be approaching levels that impact feeding and growth.

Fatal penetrating skin ulcers in laboratory-reared octopuses

Young Octopus joubini and O. briareus (35 to 60 days old) that were being reared in high-density groups for biomedical studies developed skin ulcers, whereas octopuses reared in individual containers in the same culture system were disease-free. The ulcers first affected the epidermis of the mantle, and then penetrated downward through the dermis and underlying muscle tissue. Four stages of ulceration were observed. Untreated octopuses with ulcers always died, usually within 4 days. Five species of bacteria were isolated from ulcers: Vibrio alginolyticus, V. damsela, Pseudomonas stutzeri, and Aeromonas caviae from O. joubini; and V. parahaemolyticus, V. damsela, and P. stutzeri from O. briareus. Bacteria were found during all stages of the ulceration. Healthy O. joubini were infected experimentally with four species of bacteria, and V. alginolyticus produced skin ulcers within 2 days. The ulceration was treated with nifurpirinol, and complete healing of the skin occurred within 2 months. The ulcers were probably species-specific because O. maya and O. bimaculoides that were reared in the same culture systems were not affected. The cause of the ulceration was probably an increase in contact among crowded octopuses that produced skin abrasions which were invaded by opportunistic bacteria.

A closed marine culture system for rearing Octopus joubini and other large-egged benthic octopods

The system consists of 2 adjoining 150 litre aquaria, one functioning as the water-conditioning tank and the other as the principal rearing tank. Water quality remained high with biological and mechanical filtration, physical adsorption and ultraviolet-light disinfection taking place exclusively in the conditioning tank. The pH ranged from 7·58 to 8·00 and ammonia and nitrite levels never exceeded 0·004 mg/l and 0·198 mg/l, respectively. Nitrate levels were maintained at 40 mg/l or less with no adverse affects. Adult octopuses readily mated and females produced 50-150 eggs, with 95% hatching success. When fed small live crabs, the octopus hatchlings were reared to sexual maturity either in groups or individually in about 120-150 days. Growth rates (4% bodyweight/day) and food conversion efficiences (30-40%) were as high as those obtained in open systems by previous workers.

Adaptable Night Camouflage by Cuttlefish

Cephalopods are well known for their diverse, quick‐changing camouflage in a wide range of shallow habitats worldwide. However, there is no documentation that cephalopods use their diverse camouflage repertoire at night. We used a remotely operated vehicle equipped with a video camera and a red light to conduct 16 transects on the communal spawning grounds of the giant Australian cuttlefish Sepia apama situated on a temperate rock reef in southern Australia. Cuttlefish ceased sexual signaling and reproductive behavior at dusk and then settled to the bottom and quickly adapted their body patterns to produce camouflage that was tailored to different backgrounds. During the day, only 3% of cuttlefish were camouflaged on the spawning ground, but at night 86% (71 of 83 cuttlefish) were camouflaged in variations of three body pattern types: uniform ( \documentclass{aastex} \usepackage{amsbsy} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{bm} \usepackage{mathrsfs} \usepackage{pifont} \usepackage{stmaryrd} \usepackage{textcomp} \usepackage{portland,xspace} \usepackage{amsmath,amsxtra} \usepackage[OT2,OT1]{fontenc} \newcommand\cyr{ \renewcommand\rmdefault{wncyr} \renewcommand\sfdefault{wncyss} \renewcommand\encodingdefault{OT2} \normalfont \selectfont} \DeclareTextFontCommand{\textcyr}{\cyr} \pagestyle{empty} \DeclareMathSizes{10}{9}{7}{6} \begin{document} \landscape

First multi-generation culture of the tropical cuttlefish Sepia pharaonis Ehrenberg, 1831

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Sexual cannibalism by Octopus cyanea on a Pacific coral reef

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