Pattern and Coloration of Periclimenes rathbunae from the Turks and Caicos Islands, with Comments on Host Associations in Other Anemone Shrimps of the West Indies and Bermuda

The commensal shrimp Periclimenes rathbunae Schmitt, 1924, lives in association with the sea anemones Condylactis gigantea Weinland, 1860, and Stichodactyla (= Stoichactis) helianthus Ellis, 1767, in the Turks and Caicos Islands, British West Indies. We describe its pattem and coloration in life. Published reports of distribution and host acceptance by P. rathbunae and three of its congeners (P. anthophilus Holthuis and Eibl-Eibesfeldt, 1964; P. pedersoni Chace, 1958; and P. yucatanicus Ives, 1891) are reviewed. The last two species are recorded for the first time from the Turks and Caicos, and the association of P. yucatanicus with Stichodactyla helianthus on the Caicos Bank is a new host record. Finally, we offer the first direct evidence that P. yucatanicus leaves the host anemone temporarily to clean fishes, discounting a previous suggestion of its role as a noncleaning mimic of P. pedersoni

Pattern and Coloration of Periclimenes rathbunae from the Turks and Caicos Islands, with Comments on Host Associations in Other Anemone Shrimps of the West Indies and Bermuda

The commensal shrimp Periclimenes rathbunae Schmitt, 1924, lives in association with the sea anemones Condylactis gigantea Weinland, 1860, and Stichodactyla (= Stoichactis) helianthus Ellis, 1767, in the Turks and Caicos Islands, British West Indies. We describe its pattem and coloration in life. Published reports of distribution and host acceptance by P. rathbunae and three of its congeners (P. anthophilus Holthuis and Eibl-Eibesfeldt, 1964; P. pedersoni Chace, 1958; and P. yucatanicus Ives, 1891) are reviewed. The last two species are recorded for the first time from the Turks and Caicos, and the association of P. yucatanicus with Stichodactyla helianthus on the Caicos Bank is a new host record. Finally, we offer the first direct evidence that P. yucatanicus leaves the host anemone temporarily to clean fishes, discounting a previous suggestion of its role as a noncleaning mimic of P. pedersoni

Captive seawater fishes : science and technology/ Spotte

xxiii, 942 hal. : ill.; 25 cm

Caridean Shrimps Associated with the Slimy Sea Plume (\u3ci\u3ePseudopterogorigia americana\u3c/i\u3e) in Midsummer at Guana Island, British Virgin Islands, West Indies

Fifty-one slimy sea plumes (Pseudopterogorgia americana Gmelin, 1791) were sampled for caridean shrimps at Guana Island, British Virgin Islands, during one week in July 1992. Sam- pling depth ranged from 3-22 m. Nine species were collected: Hippolyte nicholsoni Chace, 1972; Latreutes sp.; Neopontonides chacei Heard, 1986; Perclimenes cf. patae Heard and Spotte, 1991; Periclimenes cf. pauper Holthuis, 1951; Periclimenes sp.; Pseudocoutierea antillensis Chace, 1972; Tozeuma cf. cornutum Milne Edwards, 1881; and Trachycaris rugosa (Bate, 1888). A total of 1,418 specimens (including fragments) was obtained. The number of shrimp species per gorgonian ranged from 1-5; one gorgonian harbored 156 shrimps. The two predominant species, N. chacei and H. nicholsoni, occupy different mean depths (12.6 and 8.2 m, respectively). Sexual dimorphism assessed with Mann-Whitney U-tests was not apparent in the specimens of N. chacei (P \u3e 0.05), but females of H. nicholsoni were significantly larger than males (P \u3c 0.001). Minimum carapace length (CL, the tip of the rostrum to the posterior dorsal margin of the carapace) at which male N. chacei acquire a single appendix masculina spine is 1.25 mm; male H. nicholsoni can acquire a single spine at 0.9 mm CL. Histological sections of male N. chacei showed that shrimp with 0 or 1 spine are least likely to be mature. Female N. chacei can become ovigerous at 1.9 mm CL and female H. nicholsoni at 1.2 mm CL. The taxonomic status of 5 of the 9 species collected is uncertain

Chemical Decapsulation of Resting Cysts of the Anostracans \u3ci\u3eArtemia Franciscana\u3c/i\u3e and \u3ci\u3eStreptocephalus Seali\u3c/i\u3e as Revealed by Scanning Electron Microscopy

Chemical decapsulation of resting anostracan cysts involves removal of the tertiary envelope with a strong oxidant, typically a hypochlorite solution. Previously desiccated, commercially processed cysts of Artemia franciscana (San Francisco Bay strain) and undesiccated cysts of A. franciscana (Great Salt Lake strain) and Streptocephalus seali were treated with sodium hypochlorite for timed intervals. Oxidation of the tertiary envelope of cysts of Streptocephalus occurred by 240 s, whereas 840 s were required to completely decapsulate previously desiccated San Francisco Bay cysts of Artemia. The tertiary envelopes of undesiccated Great Salt Lake cysts of Artemia appeared undamaged through 480 s. The decapsulation process is documented sequentially with scanning electron photomicrographs. The evidence suggests that commercial processing of San Francisco Bay cysts of Artemia neither damages nor removes the outer membrane of the tertiary envelope. This contradicts the current view

Chemical Decapsulation of \u3ci\u3eArtemia franciscana\u3c/i\u3e Resting Cysts Does Not Necessarily Produce More Nauplii

Decapsulation of Artemia spp. cysts in strong hypochlorite solutions reportedly increases the number of nauplii that hatch. Commercial cysts of Artemia franciscano were subjected to four decapsulation methods prior to hatching them in aerated seawater. Samples were removed from the hatch vessels every 5 h from 15 through 45 h, and fully hatched nauplii were counted. The experiment was performed three times. No significant difference was seen between mean numbers of control nauplii and nauplii obtained using the decapsulation method that yielded the best hatch: oxidation for 15 min in equal parts Clorox® and seawater plus 6 mL of a 40% NaOH solution, followed by reduction with 100 mL of 0.7 M sodium thiosulfate. A third treatment was inferior to either of these, and two others produced very low yields. It was concluded that of the methods evaluated, none is superior to no treatment at all, and some are clearly detrimental to developing Artemia embryos

Plasma Cortisol Changes in Seawater-Adapted Mummichogs (\u3ci\u3eFundulus heteroclitus\u3c/i\u3e) Exposed to Ammonia

Seawater-adapted mummichogs (Fundulus heteroclitus) were exposed to total NH4-N concentrations of 1, 2, 5, 10, 25, 50, 100, 150, and 200 mg/L for periods of 2, 4, 8, 12, 18, 24, 36, and 48 h. Afterward, the fish were captured quickly and anesthetized with MS-222 before blood was collected. The concentration of total NH4-N and duration of exposure accounted for, respectively, ~35 and \u3c4% of the observed increase in plasma cortisol. The effective concentration (the concentration of total NH4-N inducing a mean cortisol response two standard deviations above the mean of the controls) was 47.14 mg/L, corresponding with a mean cortisol level of 13.44 μg/dL. Test concentrations of NH3-N were calculated from total NH4-N, pH, salinity, and temperature (constant at 20 °C), and the effects of both forms of ammonia on plasma cortisol concentration were compared. Significance was not detected at p \u3c 0.05, demonstrating that total NH4-N and NH3-N explained the observed changes in cortisol levels similarly. Mean cortisol concentrations of mummichogs anesthetized and sampled in the field were comparable with published values and did not differ significantly from the mean value of captive control fish sampled after the same length of time in MS-222 (p \u3c 0.05)

Fish and invertebrate culture : water management in closed systems/ Spotte

xiv, 145 hal.: ill.; 25 cm