Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-28T07:35:44.309Z Has data issue: false hasContentIssue false
  • English
  • Français

Verification of ageing methods for the burrowing shrimp, Neotrypaea californiensis, using extractable lipofuscin and gastric mill cuticular features

Published online by Cambridge University Press:  09 September 2019

Katelyn M. Bosley Open the ORCID record for Katelyn M. Bosley [Opens in a new window] ,
Natalie Coleman  and
Brett R. Dumbauld
Katelyn M. Bosley*
Affiliation:
Department of Fisheries and Wildlife, Oregon State University, Hatfield Marine Science Center, Newport, Oregon, 97365, USA
Natalie Coleman
Affiliation:
Department of Integrative Biology, Oregon State University, Corvallis, OR, 97331, USA
Brett R. Dumbauld
Affiliation:
US Department of Agriculture, ARS, Newport, Oregon, 97365, USA
*
Author for correspondence: Katelyn M. Bosley, E-mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

The burrowing shrimp Neotrypaea californiensis is an important ecosystem engineer that inhabits estuaries along the US Pacific Northwest coast. This species plays an important role in the estuarine ecosystem but negatively impacts oyster aquaculture through its burrowing activities. Development of population models for burrowing shrimp management requires more detailed life history information and accurate estimates of age. Ageing studies have been limited for crustaceans because it is generally believed that they do not retain structures with annual deposits commonly used to age other marine organisms, when they moult their exoskeletons. A mesocosm growth experiment and field surveys were combined to compare the performance of two ageing techniques, quantification of autofluorescent lipofuscin and gastric mill ossicular lamellae, for estimating age in N. californiensis. Animals of known age were grown in outdoor mesocosms and sampled regularly to correlate age metrics with body size and true age. Lipofuscin concentration increased with time across multiple cohorts at the rate of 1.430 ± 0.060 ng µg−1 year−1. Lamellae counts also increased with time (4.922 ± 0.337 lamellae year−1). While age estimates based on lipofuscin concentration and lamellae counts generally agreed, carapace size did not correlate to either age metric. Lamellae counts from field collections suggest they are added sequentially with age but the relationship can vary by location. When used together, the application of both techniques may provide robust estimates of crustacean age especially when size-based measurements are imprecise.

Keywords

Growthlamellaemesocardiac ossiclemesocosmmixed-effects model
Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 99 , Issue 7 , November 2019 , pp. 1627 - 1638
Copyright
Copyright © Marine Biological Association of the United Kingdom 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bird, EM (1982) Population Dynamics of Thalassinidean Shrimps and Community Effects through Sediment Modification (PhD Dissertation). University of Maryland, College Park, MD.Google Scholar
Bates, DM (2010) lme4: Mixed-effects modeling with R. Available at http://lme4.r-forge.r-project.org/book.Google Scholar
Bates, D, Maechler, M, Bolker, B and Walker, S (2015) Fitting linear mixed effects models using lme4. Journal of Statistical Software 67, 148.Google Scholar
Becker, C, Dick, JTA, Cunningham, EM, Schmitt, C and Sigwart, JD (2018) The crustacean cuticle does not record chronological age: new evidence from the gastric mill ossicles. Arthropod Structure & Development 47, 498512.Google Scholar
Booth, S (2003) A Comprehensive Plan Towards an Integrated Pest Management Program for Burrowing Shrimp on Commercial Oysterbeds. Olympia, WA: Washington State Department of Ecology, p. 14.Google Scholar
Bosley, KM (2016) An Integrated Approach to Age, Growth and Population Dynamics of Thalassinidean Burrowing Shrimps in a US West Coast Estuary (PhD Dissertation). Oregon State University, Corvallis, OR.Google Scholar
Bosley, KM and Dumbauld, B (2011) Use of extractable lipofuscin to estimate age structure of ghost shrimp populations in west coast estuaries of the USA. Marine Ecology Progress Series 428, 161176.Google Scholar
Bosley, KM, Copeman, LA, Dumbauld, BR and Bosley, KL (2017) Identification of burrowing shrimp food sources along an estuarine gradient using fatty acid analysis and stable isotope ratios. Estuaries and Coasts 40, 11131130.Google Scholar
Brösing, A (2014) Foregut structures of freshly moulted exuviae from Maja crispata, Cancer pagurus and Pseudosesarma moeschi (Decapoda: Brachyura). Journal of Natural History 48, 543555.Google Scholar
Campana, SE (2001) Accuracy, precision and quality control in age determination, including a review of the use and abuse of age validation methods. Journal of Fish Biology 59, 197242.Google Scholar
Chew, KK (2002) Burrowing shrimp vs. Pacific Northwest Oysters. Aquaculture Magazine 28, 7175.Google Scholar
Claiborne, BJ and Ayers, J (1987) Functional anatomy and behavior. In Selverston, AI and Moulins, M (eds), The Crustacean Stomatogastric System. Berlin: Springer, pp. 929.Google Scholar
Crook, DA, Adair, BJ, Grubert, MA, Saunders, TM, Morrongiello, JR, Douglas, MM and King, AJ (2018) Muddy waters: an assessment of the suitability of zygocardiac ossicles for direct age estimation in the Giant mud crab Scylla serrata. Limonology and Oceanography Methods 16, 895905. https://doi.org/10.1002/lom3.1029.Google Scholar
Du, J (2002) Combined Algorithms for Fitting Finite Mixture Distributions (MSc). McMaster University, Toronto, Ontario.Google Scholar
Dumbauld, B and Bosley, KM (2018) Recruitment ecology of burrowing shrimps in US Pacific coast estuaries. Estuaries and Coasts 41, 18481867.Google Scholar
Dumbauld, BR, Armstrong, D and Feldman, K (1996) Life history characteristics of two sympatric thalassinidean shrimps, Neotrypaea californiensis and Upogebia pugettensis, with implications for oyster culture. Journal of Crustacean Biology 16, 689708.Google Scholar
Dumbauld, BR, Booth, S, Cheney, D, Suhrbier, A and Beltran, H (2006) An integrated pest management program for burrowing shrimp control in oyster aquaculture. Aquaculture 261, 976992.Google Scholar
Factor, JR (1995). The digestive system. In Factor, JR (ed.), Biology of the lobster Homarus americanus. New York, NY: Academic Press, pp. 395440.Google Scholar
Feldman, KL, Armstrong, DA, Dumbauld, BR, DeWitt, TH and Doty, DC (2000) Oysters, crabs, and burrowing shrimp: review of an environmental conflict over aquatic resources and pesticide use in Washington state's (USA) coastal estuaries. Estuaries 23, 141176.Google Scholar
Fonseca, DB, Brancato, CL, Prior, AE, Shelton, PMJ and Sheehy, MRJ (2005) Death rates reflect accumulating brain damage in arthropods. Proceedings of the Royal Society B – Biological Sciences 272, 19411947.Google Scholar
Griffis, RB and Suchanek, TH (1991) A model of burrow architecture and trophic modes in thalassinidean shrimp (Decapoda: Thalassinidea). Marine Ecology Progress Series 79, 171183.Google Scholar
Hartnoll, RG (2001) Growth in Crustacea – twenty years on. Hydrobiologia 448, 111122.Google Scholar
Harvey, HR, Ju, S-J, Son, S-K, Feinburg, LR, Shaw, CT and Peterson, WT (2010) The biochemical estimation of age in euphausiids: laboratory calibration and field comparisons. Deep-Sea Research Part II 57, 663671.Google Scholar
Hirose, GL, Fransozo, V, Tropea, C, López-greco, LS and Negreiros-Fransozo, ML (2013) Comparison of body size, relative growth and size at onset sexual maturity of Uca uruguayensis (Crustacea: Decapoda: Ocypodidae) from different latitudes in the south-western Atlantic. Journal of the Marine Biological Association of the United Kingdom 93, 781788.Google Scholar
Hufnagl, M, Temming, A, Siegel, V, Tulp, I and Bolle, L (2010) Estimating total mortality and asymptotic length of Crangon crangon between 1955 and 2006. ICES Journal of Marine Science 67, 875884.Google Scholar
Ju, S-J, Secor, DH and Harvey, HR (1999) Use of extractable lipofuscin for age determination of blue crab Callinectes sapidus. Marine Ecology Progress Series 185, 171179.Google Scholar
Kilada, R and Acuña, E (2015) Direct age determination by growth band counts of three commercially important crustacean species in Chile. Fisheries Research 170, 134143.Google Scholar
Kilada, R and Driscoll, JG (2017) Age determination in crustaceans: a review. Hydrobiologia 799, 2136.Google Scholar
Kilada, R, Sainte-Marie, B, Rochette, R, Davis, N, Vanier, C, Campana, S and Gillanders, B (2012) Direct determination of age in shrimps, crabs, and lobsters. Canadian Journal of Fisheries and Aquatic Sciences 69, 17281733.Google Scholar
Kilada, R, Agnalt, A-L, Arboe, NH, Bjarnason, S, Burmeister, A, Farestveit, E, Gíslason, ÓS, Guðlaugsdóttir, A, Guðmundsdóttir, D, Jónasson, JP, Jónsdóttir, IG, Kvalsund, M, Sheridan, M, Stansbury, D and Søvik, G (2015) Feasibility of using growth band counts in age determination of four crustacean species in the Northern Atlantic. Journal of Crustacean Biology 35, 499503.Google Scholar
Kilada, R, Reiss, CS, Kawaghchi, S, King, RA, Matsuda, T and Ichii, T (2017) Validation of band counts in eyestalks for the determination of age of Antarctic krill Euphausia superba. PLoS ONE 12, e0171773.Google Scholar
Leland, J and Bucher, D (2017) Direct Age Determination with Validation for Commercially Important Australian Lobster and Crab Species: Western, Eastern, Southern and Ornate Rock Lobsters and Crystal, Giant and Mud Crabs. Canberra, NSW: Fisheries Research and Development Corporation and Lismore, NSW: Southern Cross University. ISBN: 9780646957845.Google Scholar
Leland, JC, Bucher, DJ and Coughran, J (2015) Direct age determination of a subtropical freshwater crayfish (Redclaw, Cherax quadricarinatus) using ossicular growth marks. PLoS ONE 10, e0134966.Google Scholar
Macdonald, P and Du, J (2015). Mixdist: finite mixture distribution models. R package version 0.5-4. Available at https://CRAN.R-project.org/package=mixdist.Google Scholar
MacGinitie, G (1934) The natural history of Callianassa californiensis Dana. American Midlands Naturalist 15, 166177.Google Scholar
Marinovic, B and Mangel, M (1999) Krill can shrink as an ecological adaptation to temporarily unfavorable environments. Ecological Letters 2, 338343.Google Scholar
Neville, AC (1965) Chitin lamellogenesis in locust cuticle. Quarterly Journal of Microscopical Science 106, 269286.Google Scholar
Newton, JA and Horner, RA (2003) Use of phytoplankton species indicators to track the origin of phytoplankton blooms in Willapa Bay, Washington. Estuaries 26, 10711078.Google Scholar
O'Donovan, V and Tully, O (1996) Lipofuscin (age pigment) as an index of crustacean age: correlation with age, temperature and body size in cultured juvenile Homarus gammarus L. Journal of Experimental Marine Biology and Ecology 207, 114.Google Scholar
Pinchuk, AI, Harvey, HR and Eckert, GL (2016) Development of biochemical measures of age in Alaskan red king crab Paralithodes camtchaticus (Anomura): validation, refinement and initial assessment. Fisheries Research 183, 9298.Google Scholar
R Core Team (2016) R: A Language and Environment for Statistical Computing. Vienna: R Foundation for Statistical Computing,. Available at http://www.R-project.org/.Google Scholar
Sheehy, MRJ (2002) Role of environmental temperature in aging and longevity: insights from neurolipofuscin. Archives of Gerontology and Geriatrics 34, 287310.Google Scholar
Sheehy, MRJ (2008) Questioning the use of biochemical extraction to measure lipofuscin for age determination of crabs: Comment on Ju et al. (1999, 2001). Marine Ecology Progress Series 353, 303306.Google Scholar
Sheehy, MRJ and Prior, AE (2008) Progress on an old question for stock assessment of the edible crab Cancer pagurus. Marine Ecology Progress Series 353, 191202.Google Scholar
Sheehy, MRJ, Greenwood, JG and Fielder, DR (1995) Lipofuscin as a record of “rate of living” in an aquatic poikilotherm. Journal of Gerontology 50, 327336.Google Scholar
Sheridan, M, O'Connor, I and Henderson, AH (2016) Investigating the effect of molting on gastric mill structure in Norway lobster (Nephrops norvegicus) and its potential as a direct ageing tool. Journal of Experimental Marine Biology and Ecology 484, 1622.Google Scholar
Terman, A and Brunk, U (2002) Lipofuscin: mechanisms of age-related accumulation and influence on cell function. Free Radical Biology and Medicine 33, 611619.Google Scholar
Tully, O and Fletcher, D (2000) Metabolic rate and lipofuscin accumulation in juvenile European lobster (Homarus gammarus) in relation to simulated seasonal changes in temperature. Marine Biology 137, 10311040.Google Scholar
Vatcher, H, Roer, R and Dillaman, RM (2015) Structure, molting, and mineralization of the dorsal ossicle complex in the gastric mill of the blue crab, Callinectes sapidus. Journal of Morphology 276, 13581367.Google Scholar
Supplementary material: File

Bosley et al. supplementary material

Figures S1-S2 and Tables S1-S3

Download Bosley et al. supplementary material(File)
File 43.2 KB