55 Ice age kelp forests: climate-driven changes in kelp forest distribution since the last glacial maximum

The University of Connecticut presents the "Benthic Marine Algal Herbarium of Long Island Sound Digital Collection." The collection is available on the web for teaching and identification purposes. Phase One of this project will be finished later by early next year. Currently, the collection has approximately 60% of all Long Island Sound macroalgae species. The taxonomy is part of a collaboration between the University of Connecticut and the Northeast Algal Society (NEAS). Thus far, the specimens have come from Dr. Charles Yarish's herbarium and from the Environmental Laboratory at Millstone Power Station on Long Island Sound. The botanical illustrations are from "Illustrated Key to the Seaweeds of New England" by Martine Villalard-Bohnsack. Database features include the ability to create searches and generate sets based on subjects, division, class, order, family, genus, habitat, species, keyword, and location. Data retrieved includes JPG image, cataloged data, map regions, synonyms, and illustrated microscopic, cross section and surface view for some species. The web site is available for use at: http://www.algae.uconn.edu     

REPORT OF A NEW INVASIVE ALGA IN THE ATLANTIC UNITED STATES: “HETEROSIPHONIA” JAPONICA IN RHODE ISLAND1

Recent collections of tetrasporangiate “Heterosiphonia” japonica Yendo from Watch Hill to Point Judith, Rhode Island, represent the first report of this nonnative alga in the western Atlantic. Native to the Pacific Ocean, this species was unintentionally introduced into European waters by 1984 and has subsequently invaded the eastern Atlantic Ocean widely from France to Norway and south into the Mediterranean Sea. Thus far, all western Atlantic collections of this species are confined to the outer coast of Rhode Island, and at present are not found in Narragansett Bay or in Long Island Sound along the Connecticut coast. Molecular and morphological studies confirm the identity of this newly introduced invasive species.     

Book reviews

Book reviewed in this article: Dreyer, Glenn D. & Niering, William A. 1995. Tidal marshes of Long Island Sound: Ecology, history and restoration. 72 pp. Connecticut College Arboretum Bulletin No. 34. Published by the Connecticut College Arboretum, Box 5201 Connecticut College, 270 Michigan Avenue, New London, CT 06320–4196, USA. ISBN 1–878899–05–8 (paper). Price USD 5.-. Jerry M. Baskin ^{1 1} School of Biological Sciences, University of Kentucky, Lexington, KY, 40506-0225, USA.     

Distribution of Methanogenic and Sulfate-Reducing Bacteria in Near-Shore Marine Sediments

The distribution of methanogenic and sulfate-reducing bacteria was examined in sediments from three sites off the coast of eastern Connecticut and five sites in Long Island Sound. Both bacterial groups were detected at all sites. Three distributional patterns were observed: (i) four sites exhibited methanogenic and sulfate-reducing populations which were restricted to the upper 10 to 20 cm, with a predominance of sulfate reducers; (ii) three sites in western Long Island Sound exhibited a methanogenic population most abundant in sediments deeper than those occupied by sulfate reducers; (iii) at one site that was influenced by fresh groundwater, methanogens and sulfate reducers were numerous within the same depths; however, the number of sulfate reducers varied vertically and temporally with sulfate concentrations. It was concluded that the distributions of abundant methanogenic and sulfate-reducing bacteria were mutually exclusive. Methanogenic enrichments yielded all genera of methanogens except Methanosarcina, with the methanobacteria predominating.     

Allocation of blade surface to reproduction in Laminaria longicruris of Long Island Sound (USA)

Sorus formation in the kelp Laminaria longicruris de la Pylaie (Phaeophyta) was quantified for a biennial population in Long Island Sound (Connecticut, USA), at the southern limit of its biogeographical range in the Western Atlantic Ocean. The allocation of blade surface to reproduction was measured monthly during two years, with additional samples taken at times of peak growth and reproduction. Sporophytes produced sori year-round, with the highest percentages of fertile plants (75 to 95 percent) occurring from October to December. The mean percentage of sorus area to blade ranged from 1 to 37 percent, remaining low and fairly constant during the spring and summer, but reaching much higher levels in the fall (when growth is minimal) and early winter. The comparatively low mean annual allocation of blade surface to reproduction (5 percent), was postulated to be due to temperature stress on these plants at the southern limit of distribution, but may instead be typical of the species. Such a small allocation of resources to reproduction nevertheless results in billions of spores per m² of substrate, making a major contribution of material potentially available to grazing food webs.     

Salt Marsh Restoration in Connecticut: 20 Years of Science and Management

In 1980 the State of Connecticut began a tidal marsh restoration program targeting systems degraded by tidal restrictions and impoundments. Such marshes become dominated by common reed grass (Phragmites australis) and cattail (Typha angustifolia and T. latifolia), with little ecological connection to Long Island Sound. The management and scientific hypothesis was that returning tidal action, reconnecting marshes to Long Island Sound, would set these systems on a recovery trajectory. Specific restoration targets (i.e., pre‐disturbance conditions or particular reference marshes) were considered unrealistic. However, it was expected that with time restored tides would return ecological functions and attributes characteristic of fully functioning tidal salt marshes. Here we report results of this program at nine separate sites within six marsh systems along 110 km of Long Island Sound shoreline, with restoration times of 5 to 21 years. Biotic parameters assessed include vegetation, macroinvertebrates, and use by fish and birds. Abiotic factors studied were soil salinity, elevation and tidal flooding, and soil water table depth. Sites fell into two categories of vegetation recovery: slow, ca. 0.5%, or fast, more than 5% of total area per year. Although total cover and frequency of salt marsh angiosperms was positively related to soil salinity, and reed grass stand parameters negatively so, fast versus slow recovery rates could not be attributed to salinity. Instead, rates appear to reflect differences in tidal flooding. Rapid recovery was characterized by lower elevations, greater hydroperiods, and higher soil water tables. Recovery of other biotic attributes and functions does not necessarily parallel those for vegetation. At the longest studied system (rapid vegetation recovery) the high marsh snail Melampus bidentatus took two decades to reach densities comparable with a nearby reference marsh, whereas the amphipod Orchestia grillus was well established on a slow‐recovery marsh, reed grass dominated after 9 years. Typical fish species assemblages were found in restoration site creeks and ditches within 5 years. Gut contents of fish in ditches and on the high marsh suggest that use of restored marsh as foraging areas may require up to 15 years to reach equivalence with reference sites. Bird species that specialize in salt marshes require appropriate vegetation; on the oldest restoration site, breeding populations comparable with reference marshland had become established after 15 years. Use of restoration sites by birds considered marsh generalists was initially high and was still nearly twice that of reference areas even after 20 years. Herons, egrets, and migratory shorebirds used restoration areas extensively. These results support our prediction that returning tides will set degraded marshes on trajectories that can bring essentially full restoration of ecological functions. This can occur within two decades, although reduced tidal action can delay restoration of some functions. With this success, Connecticut's Department of Environmental Protection established a dedicated Wetland Restoration Unit. As of 1999 tides have been restored at 57 separate sites along the Connecticut coast.     

Seasonal aspects of sarcomatous neoplasia in Mya arenaria (soft-shell clam) from Long Island Sound

Mya arenaria were collected monthly for 2.5 years from three populations in Long Island Sound. Histopathological examination revealed that 6.1% of the clams from Stonington, Connecticut, 12.9% of the clams from the Saugatuck River, Westport, Connecticut, and 12.7% of those from Old Mill Beach, Westport, also in Connecticut, had sarcomatous neoplasms. This is the first documented account of the occurrence of clam neoplasm in populations from this geographic area. Peak prevalences of 45, 59, and 60%, respectively, were found in clams from the three study sites. The prevalence of neoplasms in clams collected from three epizootic areas showed a pronounced seasonal pattern, with the highest incidences occurring in the late fall-winter of each year studied. The regular, seasonal occurrence of neoplasia in field populations does not support the hypothesis that pollution alone is the cause of the disorder.     

Bifurcation of gill filaments in winter flounder (Pleuronectes americanus Walbaum) from Long Island Sound

Morphological and histological examinations of gills excised from adult winter flounder, Pleuronectes americanus Walbaum, collected at clean and contaminated areas of Long Island Sound were undertaken to assess possible biological consequences of contamination. On the basis of previous studies, three collection sites were chosen: Shoreham, New York, a relatively clean, unindustrialized area, and New Haven Harbor, Connecticut and Hempstead Harbor, New York, both industrialized and heavily populated.
Gill samples were taken monthly at all three sites for light and scanning electron microscopy (SEM) examination. Results from both techniques suggest a relationship between contamination of the sediments and the prevalence of bifurcated gill filaments, the condition being most severe at New Haven Harbor. The bifurcations were not consistently associated with any parasitological or pathological conditions when examined by light microscopy.
Gill samples were subsequently taken from juvenile winter flounder caught in New Haven Harbor to determine how early in the life cycle gill bifurcations develop. The data show that the majority of these anomalies begin in juvenile flounder rather than in embryos, larvae, or adults. Gill bifurcations were found in 27% of the 2-year-old flounder, compared to 12% of the 1-year-old fish and 15% of the adults from the same area.     

Life history and population dynamics of the chaetognath Sagitta elegans in central Long Island Sound

One chaetognath species is found in Long Island Sound. Sagittaelegans. Individuals ranging in length from 1.5 to 22 mm werefound from March through August. Length at maturity ranged from13 to 22 mm. Maximum abundances. 67 ind m^–3 in 1982 and106 md m in 1983. occurred in early summer Two cohorts wereseen during both years, beginning as eggs produced in April-May.and in late June. The population is not endemic to Long IslandSound because temperatures during summer exceed 19C, whichseems to be lethal. The appearance of the first cohort in springis due to advection of animals from shelf waters. The secondcohort, however, is produced locally. The S. elegans populationin Long Island Sound is unique in two ways. First, the adultsare considerably longer than predicted by McLaren's (1963) Belhrdekfunction, and second, the total abundance of eggs, juvenilesand adults is at least two times higher than anywhere else.     

EXPLORING PORPHYRA SPECIES FOR USE AS NITROGEN SCRUBBERS IN INTEGRATED AQUACULTURE

Carmona, R.¹, Kraemer G. P.², Zertuche, J. A.³, Chanes, L.⁴, Chopin, T.⁵, Neefus C.^4,6 & Yarish, C.^{1 1}Dept. of Ecol. and Evol. Biol., University of Connecticut, One University Place, Stamford, CT 06901, USA; ²Department of Environmental Sciences, State University of New York, Purchase, NY 10577 USA; ³IIO, Universidad Autonoma de Baja California. Ensenada,B.C., Mexico; ⁴DGETI-CBTis41, Mexico; ⁵CCSA, Dept. of Biol., University of New Brunswick, Saint John, N.B., E2L 4L5, Canada; ⁶Department of Plant Biology, University of New Hampshire, Durham, NH 03824, USA Finfish mariculture along the Northeast US coast continues to develop into a strong industry. At a regional level, mariculture can be a significant contributor to nutrient loading in coastal waters. Since macroalgae are able to concentrate nutrients and grow at high rates, they can be an useful tool for alleviating this problem. In addition, seaweed mariculture is by itself a multi-billion dollar industry, with the red alga Porphyra (nori) valued at over $US 1.8 billion. Local species and strains of Porphyra from the Northeast U.S.A. are being studied to determine their capacity as nutrient scrubbers under different nutrient and temperature conditions. P. purpurea was grown under two N sources (NO3- vs. NH4+). The fastest growth (up to 13% d-1) and greatest N content (ca. 7% DW) were measured in plants grown at 300 µM NH4+. Short-term NH4+ uptake by P. purpurea (strains from Maine and Long Island Sound) and by P. amplissima was not saturated at 150 µM, the highest concentration tested. The P. purpurea isolate from Maine took up NH4+ faster than did the Long Island Sound isolate. NH⁴⁺ uptake by P. amplissima was faster than uptake by either P. purpurea strain. The high growth rates obtained and the ability for N uptake and tissue accumulation make these species suitable for using as a biological nutrient removal system.     

Bush medicine in the Exumas and long island,bahamas a field study

Reports from native informants backed with voucher plant specimens were obtained in a 1969–1970 field study on the Bahama islands of Great Exuma, Little Exuma and Long Island. Over 130 plant species of some 60 families are used within this culture for a wide variety of medicinal purposes. Pertinent background material and personal observations during field work indicated that knowledge of “bush medicine” is fading. The information recorded includes common names of each medicinal plant, uses, and preparations. A systematic list cross-referenced with common names is provided.     

Diversity in destinations, routes and timing of small adult and sub-adult striped bass Morone saxatilis on their southward autumn migration

Almost three-quarters of the 46 young adult and sub-adult striped bass Morone saxatilis that were acoustically tagged in Plum Island Estuary, Massachusetts, U.S.A., in the summer of 2006 were detected in one or more southern coastal arrays during their autumn migration. On the basis of the trajectories along which these M. saxatilis moved from feeding to overwintering areas, three migratory groups emerged. After leaving Plum Island Estuary, about half of the fish were detected only in a mid-latitude array, Long Island Sound. The other half of the tagged fish were detected during autumn and winter in a more southern array, the Delaware Estuary. This latter group of fish may have used two routes. Some travelled to the Delaware Estuary through Long Island Sound while other fish may have taken a second, more direct, coastal route that did not include Long Island Sound. Consequently, a seemingly homogeneous group of fish tagged at the same time in the same non-natal feeding location exhibited a diversity of southward movement patterns that could affect population-level processes. These three groups that differed in overwintering location and migration route could be movement contingents with migratory connectivity.     

Ciliate diversity and distribution across an environmental and depth gradient in Long Island Sound,USA

The nature and extent of microbial biodiversity remain controversial with persistent debates over patterns of distributions (i.e. cosmopolitanism versus endemism) and the processes that structure these patterns (neutrality versus selection). We used culture‐independent approaches to address these issues focusing on two groups of ciliates, the Oligotrichia (Spirotrichea) and Choreotrichia (Spirotrichea) across an environmental gradient. We assessed SSU rDNA diversity in ciliate communities at six stations in Long Island Sound spanning the frontal region that separates the fresher Connecticut River outflow plume from the open Sound. As in previous studies, we find one abundant cosmopolitan species (Strombidium biarmatum), a few moderately abundant sequences, and a long list of rare sequences. Furthermore, neither ciliate diversity nor species composition showed any clear relationship to measured environmental parameters (temperature, salinity, accessory pigment composition and chorophyll). Overall, we observed that diversity decreased moving from nearshore to offshore. We also conducted analyses to detect clustering among the sampled communities using the software Unifrac. This approach revealed three significant clusters grouping samples from nearshore, surface and deep/well mixed stations. We find no strong fit of our communities to log series, geometric or log normal distributions, though one of the 3 clusters is most consistent with a log series distribution. However, when we remove the abundant cosmopolitan species S. biarmatum, all three clusters fit to a log series distribution. These analyses suggest that, with the exception of one cosmopolitan species, the oligotrich and choreotrich communities at these stations may be distributed in a neutral manner.     

Quantitative and qualitative studies of gut flora in striped bass from estuarine and coastal marine environments

Examination of the intestinal contents of 130 striped bass (Morone saxatilis) collected from the Hudson River and Long Island Sound during May to October 1981 showed that opportunistic fish pathogens--especially Aeromonas hydrophila--predominated in samples from both locations. Other isolates from both groups of striped bass included Vibrio, pseudomonads, flavo-bacteria, Alcaligenes, and enterics. Small numbers of Micrococcus, Bacillus, Corynebacterium, and Acinetobacter were also isolated. Total numbers of bacteria in the intestines were 100 to 1,000 times higher in striped bass from the Hudson River than in those from Long Island Sound.     

UNDERUTILIZED TOOLS: SEAWEEDS AS BIOREMEDIATION AND DIVERSIFICATION TOOLS AND BIOINDICATORS FOR INTE-GRATED AQUACULTURE AND COASTAL MANAGEMENT

Chopin, T.¹, Yarish, C.², Neefus, C.³, Kraemer, G. P.⁴, Belyea, E.¹, Carmona, R.², Saunders, G. W.⁵, Bates, C.⁵, Page, F.⁶ & Dowd, M.^{6 1}University of New Brunswick, Centre for Coastal Studies and Aquaculture and Centre for Environmental and Molecular Algal Research, P.O. Box 5050, Saint John, New Brunswick, E2L 4L5, Canada; ²University of Connecticut, Department of Ecology and Evolutionary Biology, 1 University Place, Stamford, Connecticut, 06901-2315, USA; ³University of New Hampshire, Department of Plant Biology, Office of Biometrics, G32 Spaulding Life Science Center, Durham, New Hampshire, 03824, USA; ⁴State University of New York, Purchase College, Division of Natural Sciences, Purchase, New York, 10577, USA; ⁵University of New Brunswick, Centre for Environmental and Molecular Algal Research, P.O. Box 4400, Fredericton, New Brunswick, E3B 5A3, Canada; ⁶Department of Fisheries and Oceans, Biological Station, 531 Brandy Cove Road, St. Andrews, New Brunswick, E5B 2L9, Canada On a regional scale, finfish aquaculture can be one of the significant contributors to coastal nutrification. Contrary to common belief, even in regions of exceptional tidal and apparent “flushing” regimes like the Bay of Fundy, water mixing and transport may be limited and water residency time can be locally prolonged. Hence, nutrient bio-availability remains significant for a relatively long period of time in some areas. Understanding the assimilative capacity of coastal ecosystems under cumulative pressure, then, becomes critical. To avoid pronounced shifts in coastal processes, conversion, not dilution, is the solution by integrating fed aquaculture (finfish) with organic and inorganic extractive aquaculture (shellfish and seaweed) so that the “ wastes” of one resource user become a resource for the others. Such a bioremediative approach provides mutual benefits to co-cultured organisms, and economic diversification and increased profitability per cultivation unit for the aquaculture industry. These concepts will be discussed and illustrated by the results of our on-going projects and we will demonstrate that seaweeds can also be excellent bio-indicators of nutrification/eutrophication revealing symptoms of environmental stress and measuring the zone of influence of an aquaculture site. The aquaculture industry is here to stay in our “coastal scape”: it has its place in the global seafood supply and demand, and in the economy of coastal communities. To help ensure its sustainability, it needs, however, to responsibly change its too often monotrophic practices by adopting polytrophic ones to become better integrated into a broader coastal management framework.     

Epifaunal and algal assemblages associated with the native Chondrus crispus (Stackhouse) and the non-native Grateloupia turuturu (Yamada) in eastern Long Island Sound

Although the spread of non-native algae is rapidly escalating, relatively few ecological studies have been done to gauge the impacts incurred to native flora and fauna. A reduction in the dominance of a native habitat-forming macroalga due to the replacement by an introduced species can have adverse effects on the community. The non-native red alga Grateloupia turuturu, first reported in Rhode Island, USA in 1994, has since extended its southern range into eastern Long Island Sound. This large alga has the potential to impact coastal communities by altering the floristic composition important to associated flora and fauna. A comparison of algal and epifaunal assemblages was made during 2006 and 2007 between native and non-native algal communities dominated by either G. turuturu or the native, Chondrus crispus at two sites in Long Island Sound. We found that within Grateloupia-dominated habitat, there was a large decrease in overall macrophyte biomass as compared to native habitat. We also found that habitat dominated by the non-native alga reduced species richness and total abundance of invertebrates relative to nearby habitats dominated by C. crispus. In addition, we found that the dominant mesofaunal species, important to higher trophic level consumers, had greatly reduced densities in communities dominated by the non-native alga.     

SEAWEED ANATOMY AND PHOTOSYNTHETIC PERFORMANCE: THE ECOLOGICAL SIGNIFICANCE OF LIGHT GUIGES,HETEROGENEOUS ABSORPTION AND MULTIPLE SCATTER12

Light absorption by two green seaweeds with similar photophysiology but different anatomies are compared: i) Ulva lactuca var. rigida (C. Ag.) Le Jolis, an optically translucent species of two cell layers both bearing chloroplasts; and, ii) Codium fragile subsp. tomentosoides (van Goor) Silva, an optically opaque species with a colorlelss medulla surrounded by a cortex of choloroplast-bearing utriclels. Thallus absorptance (fraction of incident light absorbed) was measured for various pigment contents. Absorptance by U. lactuca was dependent on pigment concentration in an exponential manner and never exceeded 0.6, whereas absorptance by C. fragile was independent of pigment concentration and always approached a balue of 1.0. Water in the medullary tissue of C. fragile is often of the utricles. The utricles appear to be “integrating spheres” enhancing the capture of incident light, aided by the wave-guide function of the thin peripheral layer of cytoplasm and a reflector function at their base. Photosynthitic performance for U. lactuca saturates at high light intensities and attenuates rapidly with decreasing intensities. In contrast, photosynthetic performance for C. fragile saturates at low light intensities and attenuates slowly with diminishing radiation. Extrapolated diel variation in photosynthesis shows that U. lactuca's anatomy is adaptive for high light intensity environments, whereas C. fragile's anatomy is adaptive for low light intensity environments. Both seaweeds fit into the ecological category of “fugitive” species, and compete in the Long Island Sound (Atlantic Ocean) rocky intertidal for free-space. Predictions are presented for relative species abundances along a monotonic gradient of light intensity.     

GENETIC RELATIONSHIPS BETWEEN ONE BRITISH AND SEVERAL NORTH AMERICAN POPULATIONS OF CREPIDULA FORNICATA BASED ON ALLOZYME STUDIES (GASTROPODA: CALYPTRAEIDAE)

Crepidula fornicata(Linné) was introduced into Britainand Europe with oysters early in this century. The source populationswere probably from Long Island Sound of the Northwestern Atlantic,U.S.A. In order to determine the genetic similarity of the introducedand native populations, starch-gel electrophoresis was performedon 6 native populations from Maine to Long Island Sound. Theseresults were compared with those for one population from Portsmouth,England. The degree of similarity among New England sites was not relatedto the geographical distance between sites. There were no clinesin gene frequencies. The year-to-year variation at one sitewas often larger than variation between sites. Ail Nei's D valueswere very small, compared with those between species, rangingfrom 0.003 to 0.016 for New England samples. The English populationhad Nei's D values of 0.002 to 0.012 from the New England samples,and hence was not divergent. At no locus was the Portsmouthpopulation significantly different in gene frequencies fromall the new England samples. Genetic distances between speciesof Crepidula are usually in the range of 1.0–2.0. Thedifferences between New England sites can be attributed to samplingerror or to local variation in gene frequency caused by variationin source of recruitment. The species is unified by its planktoniclarvae and a fairly uniform habitat within New England. Heterozygosity and other measures of genetic variation werelower for the Portsmouth population than for any of the NewEngland samples. The absence of some alleles in the Portsmouthpopulation could be due in part to sampling error associatedwith small sample size or the loss of some rare alleles fromthe population. (Received 8 March 1984;     

THE DISTRIBUTION, ABUNDANCE AND SELECTED PREY OF THE HARBOR SEAL, PHOCA VITULINA CONCOLOR, IN SOUTHERN NEW ENGLAND

The seasonal distribution and abundance of harbor seals occurring south of Maine were documented by counting the number of seals at traditional haulout locations. The average number of seals counted during each survey in Massachusetts and New Hampshire was 3,560 ± 255 (95% CI), 1983–1987. The maximum number of seals counted on any individual survey was 4,736 individuals. Fifty percent of all the surveys since January 1985 have resulted in counts greater than 4,000 seals reflecting a 27% increase in the abundance of seals in our study area since that date. Seventy-five percent of the seals in southern New England are located at haulout sites on Cape Cod and Nantucket Island. The largest aggregation of seals in the eastern United States occurs mid-winter at Monomoy Island and adjacent shoals. A single high count of 1,672 seals occurred at this site during the study period. An additional 271–374 seals were also counted in Rhode Island, Connecticut and eastern Long Island Sound during surveys conducted in March 1986 and 1987. The American sandlance Ammodytes americanus was the single dominant prey item of harbor seals in waters adjacent to Cape Cod based on the modified frequency of occurrence of each prey species in scat samples collected from three haulout sites on Cape Cod between 1984–1987. During January and February sandlance was the near exclusive prey item at Monomoy (99%, n= 80). During March and April, the frequency of Atlantic herring Clupea harengus increased in the scat samples at this site. Regional differences in the diet of seals reflect distinct prey communities throughout the study area. Since 1986, the percent occurrence and importance of sandlance in the diet of seals has decreased, reflecting an overall decrease in abundance of this prey species in waters adjacent to Cape Cod. In spite of fluctuations in abundance, and regional differences in the diet of seals throughout the study area, sandlance still comprised a minimum 55% of the total prey species of harbor seals throughout the study area.