scholarly journals Hoki (Macruronus novaezelandiae) Diet Variability and  Associated Middle-Depth Demersal Fish Species Depth  Distribution in the Ecosystem on the Chatham Rise, New Zealand.

2021 ◽  
Author(s):  
◽  
Amelia MacLeod Connell
Keyword(s):  
Body Size ◽  
New Zealand ◽  
Fisheries Management ◽  
Species Distribution ◽  
Depth Distribution ◽  
Prey Species ◽  
Demersal Fish ◽  
Species Level ◽  
Geometric Constraints ◽  
Diet Variability

<p>Fisheries management in New Zealand is mostly on a single species basis. Globally there is a shift towards multispecies or ecosystem based fisheries management. For this to happen an understanding of how the ecosystem is organised and functions is needed. Trophic food web and diet studies have been used effectively to begin to understand the functioning of marine ecosystems. Who eats whom, however, is not the full extent of ecosystem function. Understanding of species distribution patterns, of both predators and prey species are also needed to begin to understand the full function of the marine ecosystem. The first part of this study investigated the diet of hoki (Macruronus novaezelandiae) over the Chatham Rise, New Zealand, between 200-800m. It characterised the diet of hoki as well as investigated potential sources of diet variability. Hoki diet was found to consist largely of mesopelagic teleosts, mainly of the family Myctophidae, natant decapods and euphausids, suggesting a pelagic feeding strategy, as other studies have also found. Differences were found in diet composition between this study and other studies on hoki diet, potentially suggesting differences in prey distribution between study areas. Differences in diet were found between fish from different depths and different sized fish from the same depth. No consistent pattern of diet differences was found between the different areas studied, suggesting that the patterns found may be aliasing depth and size patterns as well as reflecting differences in hoki size class distribution. The distribution of hoki was not homogeneous over the study area, with small fish found mainly in the western part of the study area in shallower water, while large fish were predominately found at greater depths over the whole study area. The second part of this study looked at the overall species distribution of 30 demersal fish species over the Chatham Rise, specifically examining for evidence of the mid-domain effect. The study also investigated body-size depth trends between these species, and split by class Osteichthyes and Chondrichthyes. The mid-domain effect predicts species richness, and thus distribution, is due to geometric constraints with the greatest species richness to be found at the centre of a geographically constrained domain. The overall species distribution was found to be explained by the mid-domain effect. The distribution pattern of larger individuals being found in deeper water, with smaller individuals found in shallower water has often been seen in marine systems. We found no interspecific pattern for body-size depth distribution with the entire species assemblage, nor when the assemblage was split by class into Osteichthyes and Chondrichthyes, which supports our findings of the mid-domain effect. At a species level patterns of positive, negative and no trend were found with body-size depth relationships. At a community level species distribution over the studied depth range was largely explained by the geometric constraints of the mid-domain effect, while at a species level distribution over depth was often a reflection of body size. Some species had large individuals deep while other species had small. Overall this supports the hypothesis that competition or adaptation works more strongly at a population or species level, than on the overall community who's species distribution can more often be attributed to random chance. This study begins to explain predator species distribution over the Chatham Rise and looks at the diet of one dominant species in the Chatham Rise ecosystem. This provides some of the basic knowledge needed for fisheries management to move towards a more ecosystem based approach. Further research should include investigation into prey species distribution and abundance to clarify some of the questions raised in the diet part of this study about the cause of diet variability and whether it was related to either prey abundance or patchy prey distribution. Research into the diet of other fish would be useful to ascertain which species compete with hoki for food and would provide fisheries managers with a list of species that may be affected indirectly through changes in hoki quota of abundance.</p>

scholarly journals Hoki (Macruronus novaezelandiae) Diet Variability and  Associated Middle-Depth Demersal Fish Species Depth  Distribution in the Ecosystem on the Chatham Rise, New Zealand.

2021 ◽  
Author(s):  
◽  
Amelia MacLeod Connell
Keyword(s):  
Body Size ◽  
New Zealand ◽  
Fisheries Management ◽  
Species Distribution ◽  
Depth Distribution ◽  
Prey Species ◽  
Demersal Fish ◽  
Species Level ◽  
Geometric Constraints ◽  
Diet Variability

<p>Fisheries management in New Zealand is mostly on a single species basis. Globally there is a shift towards multispecies or ecosystem based fisheries management. For this to happen an understanding of how the ecosystem is organised and functions is needed. Trophic food web and diet studies have been used effectively to begin to understand the functioning of marine ecosystems. Who eats whom, however, is not the full extent of ecosystem function. Understanding of species distribution patterns, of both predators and prey species are also needed to begin to understand the full function of the marine ecosystem. The first part of this study investigated the diet of hoki (Macruronus novaezelandiae) over the Chatham Rise, New Zealand, between 200-800m. It characterised the diet of hoki as well as investigated potential sources of diet variability. Hoki diet was found to consist largely of mesopelagic teleosts, mainly of the family Myctophidae, natant decapods and euphausids, suggesting a pelagic feeding strategy, as other studies have also found. Differences were found in diet composition between this study and other studies on hoki diet, potentially suggesting differences in prey distribution between study areas. Differences in diet were found between fish from different depths and different sized fish from the same depth. No consistent pattern of diet differences was found between the different areas studied, suggesting that the patterns found may be aliasing depth and size patterns as well as reflecting differences in hoki size class distribution. The distribution of hoki was not homogeneous over the study area, with small fish found mainly in the western part of the study area in shallower water, while large fish were predominately found at greater depths over the whole study area. The second part of this study looked at the overall species distribution of 30 demersal fish species over the Chatham Rise, specifically examining for evidence of the mid-domain effect. The study also investigated body-size depth trends between these species, and split by class Osteichthyes and Chondrichthyes. The mid-domain effect predicts species richness, and thus distribution, is due to geometric constraints with the greatest species richness to be found at the centre of a geographically constrained domain. The overall species distribution was found to be explained by the mid-domain effect. The distribution pattern of larger individuals being found in deeper water, with smaller individuals found in shallower water has often been seen in marine systems. We found no interspecific pattern for body-size depth distribution with the entire species assemblage, nor when the assemblage was split by class into Osteichthyes and Chondrichthyes, which supports our findings of the mid-domain effect. At a species level patterns of positive, negative and no trend were found with body-size depth relationships. At a community level species distribution over the studied depth range was largely explained by the geometric constraints of the mid-domain effect, while at a species level distribution over depth was often a reflection of body size. Some species had large individuals deep while other species had small. Overall this supports the hypothesis that competition or adaptation works more strongly at a population or species level, than on the overall community who's species distribution can more often be attributed to random chance. This study begins to explain predator species distribution over the Chatham Rise and looks at the diet of one dominant species in the Chatham Rise ecosystem. This provides some of the basic knowledge needed for fisheries management to move towards a more ecosystem based approach. Further research should include investigation into prey species distribution and abundance to clarify some of the questions raised in the diet part of this study about the cause of diet variability and whether it was related to either prey abundance or patchy prey distribution. Research into the diet of other fish would be useful to ascertain which species compete with hoki for food and would provide fisheries managers with a list of species that may be affected indirectly through changes in hoki quota of abundance.</p>

ERRORS ASSOCIATED WITH HERBAGE DISSECTION ANALYSES 2. Problems of species identification

1976 ◽  
pp. 213-225
Author(s):  
I.M. Ritchie ◽  
C.C. Boswell ◽  
A.M. Badland
Keyword(s):  
New Zealand ◽  
Dry Weight ◽  
Analytical Tool ◽  
Species Level ◽  
Weight Basis ◽  
Plant Identification ◽  
Leaf Fragment ◽  
Research Division ◽  
Or Groups ◽  
Botanical Analysis

HERBACE DISSECTION is the process in which samples of herbage cut from trials are separated by hand into component species. Heavy reliance is placed on herbage dissection as an analytical tool ,in New Zealand, and in the four botanical analysis laboratories in the Research Division of the Ministry of Agriculture and Fisheries about 20 000 samples are analysed each year. In the laboratory a representative subsample is taken by a rigorous quartering procedure until approximately 400 pieces of herbage remain. Each leaf fragment is then identified to species level or groups of these as appropriate. The fractions are then dried and the composition calculated on a percentage dry weight basis. The accuracy of the analyses of these laboratories has been monitored by a system of interchanging herbage dissection samples between them. From this, the need to separate subsampling errors from problems of plant identification was, appreciated and some of this work is described here.

scholarly journals The isotopic niche of Atlantic, biting marine mammals and its relationship to skull morphology and body size

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Massimiliano Drago ◽  
Marco Signaroli ◽  
Meica Valdivia ◽  
Enrique M. González ◽  
Asunción Borrell ◽  
...  
Keyword(s):  
Body Size ◽  
Atlantic Ocean ◽  
Fisheries Management ◽  
Marine Mammals ◽  
Trophic Position ◽  
Sympatric Species ◽  
Isotopic Niche ◽  
Apex Predators ◽  
Skull Morphology ◽  
Ecosystem Based Fisheries Management

AbstractUnderstanding the trophic niches of marine apex predators is necessary to understand interactions between species and to achieve sustainable, ecosystem-based fisheries management. Here, we review the stable carbon and nitrogen isotope ratios for biting marine mammals inhabiting the Atlantic Ocean to test the hypothesis that the relative position of each species within the isospace is rather invariant and that common and predictable patterns of resource partitioning exists because of constrains imposed by body size and skull morphology. Furthermore, we analyze in detail two species-rich communities to test the hypotheses that marine mammals are gape limited and that trophic position increases with gape size. The isotopic niches of species were highly consistent across regions and the topology of the community within the isospace was well conserved across the Atlantic Ocean. Furthermore, pinnipeds exhibited a much lower diversity of isotopic niches than odontocetes. Results also revealed body size as a poor predictor of the isotopic niche, a modest role of skull morphology in determining it, no evidence of gape limitation and little overlap in the isotopic niche of sympatric species. The overall evidence suggests limited trophic flexibility for most species and low ecological redundancy, which should be considered for ecosystem-based fisheries management.

scholarly journals Temperature and Prey Species Richness Drive the Broad-Scale Distribution of a Generalist Predator

Diversity ◽  
2021 ◽  
Vol 13 (4) ◽  
pp. 169
Author(s):  
Danai-Eleni Michailidou ◽  
Maria Lazarina ◽  
Stefanos P. Sgardelis
Keyword(s):  
Species Richness ◽  
Species Distribution ◽  
Prey Species ◽  
Abiotic Factors ◽  
Biodiversity Loss ◽  
Generalist Predator ◽  
Distributional Patterns ◽  
The Future ◽  
Grass Snake ◽  
Broad Scale

The ongoing climate change and the unprecedented rate of biodiversity loss render the need to accurately project future species distributional patterns more critical than ever. Mounting evidence suggests that not only abiotic factors, but also biotic interactions drive broad-scale distributional patterns. Here, we explored the effect of predator-prey interaction on the predator distribution, using as target species the widespread and generalist grass snake (Natrix natrix). We used ensemble Species Distribution Modeling (SDM) to build a model only with abiotic variables (abiotic model) and a biotic one including prey species richness. Then we projected the future grass snake distribution using a modest emission scenario assuming an unhindered and no dispersal scenario. The two models performed equally well, with temperature and prey species richness emerging as the top drivers of species distribution in the abiotic and biotic models, respectively. In the future, a severe range contraction is anticipated in the case of no dispersal, a likely possibility as reptiles are poor dispersers. If the species can disperse freely, an improbable scenario due to habitat loss and fragmentation, it will lose part of its contemporary distribution, but it will expand northwards.

Horizontal and vertical movements of telemetered rainbow trout (Oncorhynchus mykiss) in Lake Washington

1995 ◽  
Vol 73 (1) ◽  
pp. 146-153 ◽  
Author(s):  
Eric J. Warner ◽  
Thomas P. Quinn
Keyword(s):  
Rainbow Trout ◽  
Oncorhynchus Mykiss ◽  
Average Velocity ◽  
Sockeye Salmon ◽  
Depth Distribution ◽  
Prey Species ◽  
Nearshore Zone ◽  
Vertical Movements ◽  
Rainbow Trout Oncorhynchus Mykiss ◽  
Lake Washington

In summer and fall 1989, six rainbow trout (Oncorhynchus mykiss) were tracked in Lake Washington with ultrasonic transmitters for a total of 349 h to determine their movements in relation to the distribution of possible prey species. The trout moved primarily in the nearshore area at an average velocity of 12.4 cm/s (~ 0.25–0.3 body lengths/s). Five of the six fish made one more rapid (>1 body lengths/s) excursion across the lake, then continued moving in the nearshore zone. The trout were generally inactive, staying close (<50 m) to shore at night, and became more active near dawn; however, the highest average velocities were at dusk. They spent over 90% of their time in the top 3 m of the water column and 10% in brief (2 min), shallow (mean 6.6 m) dives. Dives occurred most frequently at dawn and during the day (0.8/h), less often near dusk (0.5/h), and seldom at night (0.1/h). The depth distribution and movement patterns suggest that the trout were feeding on Daphnia pulicaria during the day, in both nearshore and offshore areas, supplementing this diet with nearshore fishes such as prickly sculpins (Cottus asper). Predation on pelagic planktivores (longfin smelt, Spirinchus thaleichthyes, and juvenile sockeye salmon, Oncorhynchus nerka) was unlikely because the trout were primarily found nearshore and near the surface, whereas the planktivores are primarily offshore and closer to the bottom.

Revision of Zorion Pascoe (Coleoptera: Cerambycidae), an endemic genus of New Zealand

Zootaxa ◽  
2005 ◽  
Vol 1066 (1) ◽  
pp. 1 ◽  
Author(s):  
FRANZ-RUDOLF SCHNITZLER ◽  
QIAO WANG
Keyword(s):  
New Species ◽  
New Zealand ◽  
Species Distribution ◽  
Taxonomic Revision ◽  
Original Description ◽  
Biological Information ◽  
Distribution Map ◽  
Endemic Genus ◽  
Longhorn Beetle

The genus Zorion Pascoe (Cerambycidae: Cerambycinae), commonly known as flower longhorn beetle, is endemic to New Zealand where it is widely distributed on the main and some offshore islands. A taxonomic revision of Zorion adults is given, including a description and illustrations of the genus. The previously known species Z. batesi Sharp, Z. guttigerum (Westwood), Z. minutum (Fabricius), and Z. opacum Sharp are redescribed; Z. castum Broun is synonymised with Z.guttigerum. Lectotypes are designated here for Z. guttigerum and Z. opacum. Six new species are described, Z. angustifasciatum sp. nov. from Three Kings Islands, Z. australe sp. nov. from South Island, Z. dugdalei sp. nov. from Poor Knights Island, Z. kaikouraiensis sp. nov. from the Kaikoura region, Z. nonmaculatum sp. nov. from D’Urville Islands, and Z. taranakiensis sp. nov. from the Taranaki region. The species Z. exiguum Gmelin has been excluded from the study because neither the original description nor the holotype could be located. A key to all ten species is included and diagnostic elytral spot patterns are illustrated. Biological information presented is based on publications, collecting records and our observations. A distribution map for all species is included and species distribution is discussed in relation to New Zealand’s biogeographical history.

scholarly journals Demersal Assemblages on the Soft Bottoms off the Catalan-Levante Coast of the Spanish Mediterranean

2011 ◽  
Vol 2011 ◽  
pp. 1-16 ◽  
Author(s):  
Mariano García-Rodríguez ◽  
Pere Abelló ◽  
Angel Fernández ◽  
Antonio Esteban
Keyword(s):  
Fisheries Management ◽  
Depth Distribution ◽  
Ecosystem Approach ◽  
Western Mediterranean ◽  
Multispecies Fisheries ◽  
Middle Slope ◽  
Soft Bottoms ◽  
High Species Richness ◽  
Total Species ◽  
Upper Slope

The analysis of 255 bottom trawl samples obtained in annual experimental surveys (2007–2010) along the western Mediterranean shows the existence of five well-defined demersal assemblages that follow a depth distribution: (a) upper shelf assemblages, including two assemblages differentiated by the type of substrate (sand-muddy and terrigenous muddy bottoms); (b) a middle shelf assemblage; (c) an upper slope assemblage; (d) a middle slope assemblage. Faunally, they are dominated by fish (37% of 452 total species), followed by crustaceans (22%), molluscs (17%), echinoderms (9%), and other invertebrates (15%). The assemblages identified showed major alterations on the shelf and shelf edge and less pronounced ones on the upper and middle slope. The average diversity values were more or less high, evidencing the high species richness in the western Mediterranean. The identified assemblages may facilitate future multispecies fisheries management based on an ecosystem approach.

scholarly journals Deprivation matters: understanding associations between neighbourhood deprivation, unhealthy food outlets, unhealthy dietary behaviours and child body size using structural equation modelling

2020 ◽  
Vol 74 (5) ◽  
pp. 460-466 ◽  
Author(s):  
Victoria Egli ◽  
Matthew Hobbs ◽  
Jordan Carlson ◽  
Niamh Donnellan ◽  
Lisa Mackay ◽  
...  
Keyword(s):  
Body Size ◽  
New Zealand ◽  
Structural Equation Modelling ◽  
Structural Equation ◽  
Unhealthy Food ◽  
Neighbourhood Deprivation ◽  
Food Outlets ◽  
Dietary Behaviours ◽  
Equation Modelling ◽  
Home And School

BackgroundChildren residing in neighbourhoods of high deprivation are more likely to have poorer health, including excess body size. While the availability of unhealthy food outlets are increasingly considered important for excess child body size, less is known about how neighbourhood deprivation, unhealthy food outlets and unhealthy dietary behaviours are interlinked.MethodsThis study involves children aged 8–13 years (n=1029) and resided in Auckland, New Zealand. Unhealthy dietary behaviours (frequency of consumption of unhealthy snacks and drinks) and food purchasing behaviour on the route to and from school were self-reported. Height and waist circumference were measured to calculate waist-to-height ratio (WtHR). Geographic Information Systems mapped neighbourhood deprivation and unhealthy food outlets within individual, child-specific neighbourhood buffer boundaries (800 m around the home and school). Associations between neighbourhood deprivation (calculated using the New Zealand Index of Deprivation 2013), unhealthy food outlets, unhealthy dietary behaviours and WtHR were investigated using structural equation modelling in Mplus V.8.0. Age, sex and ethnicity were included as covariates, and clustering was accounted for at the school level.ResultsStructural equation models showed that unhealthy food outlets were unrelated to unhealthy dietary behaviours (estimate 0.029, p=0.416) and excess body size (estimate −0.038, p=0.400). However, greater neighbourhood deprivation and poorer dietary behaviours (estimate −0.134, p=0.001) were associated with greater WtHR (estimate 0.169, p<0.001).ConclusionExcess child body size is associated with neighbourhood deprivation and unhealthy dietary behaviours but not unhealthy outlet density or location of these outlets near home and school.

Phylogeny, systematics and rarity assessment of New Zealand endemic Saphydrus beetles and related enigmatic larvae (Coleoptera : Hydrophilidae : Cylominae)

2020 ◽  
Author(s):  
Matthias Seidel ◽  
Yûsuke N. Minoshima ◽  
Richard A. B. Leschen ◽  
Martin Fikácek
Keyword(s):  
New Zealand ◽  
Adult Stage ◽  
Single Species ◽  
Species Level ◽  
Phylogenetic Position ◽  
Primary Reason ◽  
Altitudinal Distribution ◽  
Population Number ◽  
Threatened Status ◽  
Over Time

The New Zealand endemic beetle genus Saphydrus Sharp, 1884 (Coleoptera:Hydrophilidae:Cylominae) is studied in order to understand its phylogenetic position, species-level systematics, biology and distribution, and to reveal reasons for its rarity. The first complete genus-level phylogeny of Cylominae based on two mitochondrial (cox1, 16S) and two nuclear genes (18S, 28S) covering 18 of 19 genera of the subfamily reveals Saphydrus as an isolated lineage situated in a clade with Cylorygmus (South America), Relictorygmus (South Africa) and Eurygmus (Australia). DNA is used to associate two larval morphotypes with Saphydrus: one of them represents the larvae of S. suffusus Sharp, 1884; the other, characterised by unique characters of the head and prothorax morphology, is revealed as sister but not closely related to Saphydrus. It is described here as Enigmahydrus, gen. nov. with a single species, E. larvalis, sp. nov., whose adult stage remains unknown. Saphydrus includes five species, two of which (S. moeldnerae, sp. nov. and S. tanemahuta, sp. nov.) are described as new. Larvae of Enigmahydrus larvalis and Saphydrus suffusus are described and illustrated in detail based on DNA-identified specimens. Candidate larvae for Saphydrus obesus Sharp, 1884 and S. tanemahuta are illustrated and diagnosed. Specimen data are used to evaluate the range, altitudinal distribution, seasonality and population dynamics over time for all species. Strongly seasonal occurrence of adults combined with other factors (winter occurrence in S. obesus, occurrence at high altitudes in S. tanemahuta) is hypothesised as the primary reason of the rarity for Saphydrus species. By contrast, Enigmahydrus larvalis underwent a strong decline in population number and size since the 1970s and is currently known from a single, locally limited population; we propose the ‘nationally threatened’ status for this species. http://zoobank.org/urn:lsid:zoobank.org:pub:28D87163-29E8-418C-9380-262D3038023A

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