Aldred N, Clare A. 2008. The adhesive strategies of cyprids and development of barnacle-resistant marine coatings. Biofouling 24: 351-363.
Arnow LE. 1937. Colorimetric determination of components of 3, 4-dihydroxyphenyl-L-alanine/tyrosine mixtures. J Biol Chem 118: 531-537.
Baker JR. 1956. The histochemical recognition of pehnols, especially tyrosine. Q J Microsc Sci 97: 161-164.
Barlow DE, Dickinson GH, Orihuela B, Kulp JL, Rittschof D, Wahl KJ. 2010. Characterization of the adhesive plaque of the barnacle Balanus amphitrite: amyloid-like nanofibrils are a major component. Langmuir 26: 6549-6556.
Barnes H, Blackstock J. 1974. The biochemical composition of the cement of a pedunclulate cirripede. J Exp Mar Biol Ecol 16: 87-91.
Barnes H, Blackstock J. 1976. Further observations on the biochemical composition of the cement of Lepas fascicularis Ellis & Solander; electrophoretic examination of the protein moieties under various conditions. J Exp Mar Biol Ecol 25: 263-271.
Barnett RJ, Seligman AM. 1958. Histochemical demonstration of protein bound alpha-acylamido carboxyl groups. J Biophys Biochem Cytol 4: 196-176.
Burns J, Pennock CA, Stoward PJ. 1967. The specificity of the staining of amyloid deposits with thiofavin T. J Pathol Bacteriol 94: 337-334.
Cheung PJ, Ruggieri GD, Nigrelli RF. 1977. A new method for obtaining barnacle cement in the liquid state for polymerization studies. Mar Biol 43: 157-163.
DeMoor S, Waite HJ, Jangoux MJ, Flammang PJ. 2003. Characterization of the adhesive from cuvierian tubules of the sea cucumber Holothuria forskali (Echinodermata, Holothuroidea). Mar Biotechnol 5: 45-57.
Dickinson GH, Vega IE, Wahl KJ, Orihuela B, Beyley V, Rodriguez EN, Everett RK, Bonaventura J, Rittschof D. 2009. Barnacle cement: A polymerization model based on evolutionary concepts. J Exp Biol 212: 3499-3510.
Dougherty WJ. 1996. Zinc metalloprotease activity in the cement precursor secretion of the barnacle, Chthamalus fragilis Darwin. Tissue Cell 28: 439-447.
Endrizzi BJ, Stewart RJ. 2009. Glueomics: An expression survey of the adhesive gland of the sandcastle worm. J Adhes 85: 546-559.
Flammang P, Lambert A, Bailly P, Hennebert E. 2009. Polyphosphoprotein-containing marine adhesives. J Adhes 85: 447-464.
Fyhn UEH, Costlow JD. 1976. A histochemical study of cement secretion during the intermolt cycle in barnacles. Biol Bull 150: 47-56.
Hennebert E. 2010. Adhesion mechanisms developed by sea stars: A review of the ultrastructure and composition of tube feet and their secretion. In: von Byern J, Grunwald I, editors. Biological Adhesive Systems. Vienna: Springer-Verlag. pp 99-109.
Hennebert E, Wattiez R, Flammang P. 2011. Characterisation of the carbohydrate fraction of the temporary adhesive secreted by the tube feet of the sea star Asterias rubens. Mar Biotechnol 13: 484-495.
Highman B. 1946. Improved methods for demonstrating amyloid in paraffin sections. Arch Pathol 41: 559-562.
Jensen RA, Morse DE. 1988. The bioadhesive of Phragmatopoma californica tubes: A silk-like cement containing L-DOPA. J Comp Physiol B: Biochem System Environ Physiol 158: 317-324.
Kamino K. 2006. Barnacle underwater attachment. In: Smith AM, Callow JA, editors. Biological Adhesives. Berlin, Germany: Springer-Verlag. pp 145-166.
Kamino K. 2010a. Molecular design of barnacle cement in comparison with those of mussel and tubeworm. J Adhes 86: 96-110.
Kamino K. 2010b. Absence of cross-linking via trans-glutaminase in barnacle cement and redefinition of the cement. Biofouling 26: 755-760.
Kamino K, Shizuri Y. 1998. Structure and function of barnacle cement proteins. In: Le Gal Y, Halvorson H, editors. New Developments in Marine Biotechnology. New York: Plenum Press. pp 77-80.
Kamino K, Odo S, Maruyama T. 1996. Cement proteins of the acorn-barnacle, Megabalanus rosa. Biol Bull 190: 403-409.
Kamino K, Nakano M, Kanai S. 2012. Significance of the conformation of building blocks in curing of barnacle underwater adhesive. FEBS J 279: 1750-1760.
Karande A, Gaonkar S. 1977. Histology and histochemistry of cement glands of Balanus kondakovi. Proc: Plant Sci 86: 409-416.
Kelienyi G. 1967. On the histochemistry of azo group-free thiazole dyes. J Histochem Cytochem 15: 172-180.
Khurana R, Coleman C, Ionescu-Zanetti C, Carter SA, Krishna V, Grover RK, Roy R, Singh S. 2005. Mechanism of Thioflavin T binding to amyloid fibrils. J Struct Biol 151: 229-238.
Kiernan JA. 2008. Histological and histochemical methods, theory and practice. Oxfordshire: Scion Publishing Ltd.
Koehler R. 1889. Recherches sur l'organisation des Cirrhipedes. Arch Biol 9: 311-402.
Lacombe D. 1970. A comparative study of the cement glands in some balanid barnacles (Cirripedia, Balanidae). Biol Bull 139: 164-179.
Lacombe D, Liguori VR. 1969. Comparative histological studies of the cement apparatus of Lepas anatifera and Balanus tintinnabulum. Biol Bull 137: 170-180.
Lindner E, Dooley C. 1972. Chemical bonding in cirripede adhesive. In: Acker RF, Brown BF, DePalma JR, Iverson WP, editors. Proceedings of the 3rd International Congress of Marine Corrosion and Fouling. Gaithersburg, Maryland: National Bureau of Standards. pp 653-673.
Liu Y-C, Li F-H, Wang B, Dong B, Zhang Q-L, Luan W, Zhang X-J, Xiang J-H. 2007. A transglutaminase from Chinese shrimp (Fenneropenaeus chinensis), full-length cDNA cloning, tissue localization and expression profile after challenge. Fish Shellfish Immunol 22: 576-588.
Maiza D, Brewer PA, Alfeat M. 1953. The cytochemical staining and measurement of protein with mercuric Bromopehnol blue. Biol Bull 104: 57-67.
McEvilly P. 2011. A look at some components of the adhesive of the pedunculate barnacles Dosima fasicularis, Lepas anatifera, Conchoderma auritum, Lepas pectinata and Pollicipes pollicipes. Galway: National University of Ireland. 166 p.
Mori Y, Urushida Y, Nakano M, Uchiyama S, Kamino K. 2007. Calcite-specific coupling protein in barnacle underwater cement. FEBS J 274: 6436-6446.
Nagasawa H. 2011. Structure and function of matrix proteins and peptides in the biomineral formation in Crustaceans. In: Müller WEG, editor. Molecular Biomineralization. Berlin/Heidelberg: Springer. pp 315-329.
Naldrett MJ, Kaplan DL. 1997. Characterization of barnacle (Balanus eburneus and B. crenatus?) adhesive proteins. Marine Biology 127: 629-635.
Naldrett MJ. 1993. The importance of sulphur cross-links and hydrophobic interactions in the polymerization of barnacle cement. J Mar Biol Assoc UK 73: 689-702.
Nozawa H, Mamegoshi S-I, Seki N. 1997. Partial purification and characterization of six transglutaminases from ordinary muscles of various fishes and marine invertebrates. Comp Biochem Physiol Part B: Biochem Mol Biol 118: 313-317.
Okano K, Shimizu K, Satuito CG, Fusetani N. 1998. Enzymatic isolation and culture of cement secreting cells from cypris larvae of the barnacle Megabalanus rosa. Biofouling 12: 149-159.
Pearse AGE. 1960. Histochemistry, Theoretical and Applied. London: Churchill Ltd.
Power AM, Klepal W, Zheden V, Jonker JL, McEvilly P, von Byern J. 2010. Mechanisms of adhesion in adult barnacles. In: Grunwald I, vonByern J, editors. Biological Adhesive Systems. Vienna: Springer-Verlag. pp 153-166.
Shimony T, Nigrelli RF. 1971. Phenoloxidase activity in the cement apparatus of the adult barnacle, Balanus eburneus Gould, and its possible function in the hardening process of the adhesive substances. Am Zool 11: 662-663.
Smith AM. 2010. Gastropod secretory glands and adhesive gels. In: Grunwald I, vonByern J, editors. Biological Adhesive Systems. Vienna: Springer-Verlag. pp 41-52.
Spicer SS, Lillie RD. 1961. Histochemical identification of basic proteins with Biebrich scarlet at alkaline pH. Stain Technol 36: 365-370.
Stewart RJ, Wang CS. 2010. Adaptation of caddisfly larval silks to aquatic habitats by phosphorylation of H-fibroin serines. Biomacromolecules 11: 969-974.
Stewart RJ, Weaver JC, Morse DE, Waite JH. 2004. The tube cement of Phragmatopoma californica: A solid foam. J Exp Biol 207: 4727-4734.
Sullan RMA, Gunari N, Tanur AE, Chan Y, Dickinson GH, Orihuela B, Rittschof D, Walker GC. 2009. Nanoscale structures and mechanics of barnacle cement. Biofouling: J Bioadhes Biofilm Res 25: 263-275.
Tamarin A. 1975. An ultrastructural study of byssus stem formation in Mytilus californianus. J Morphol 145: 151-177.
Tamarin A, Keller PJ. 1972. An ultrastructural study of the byssal thread forming system in Mytilus. J Ultrastruct Res 40: 401-416.
Urushida Y, Nakano M, Matsuda S, Inoue N, Kanai S, Kitamura N, Nishino T, Kamino K. 2007. Identification and functional characterization of a novel barnacle cement protein. FEBS J 274: 4336-4346.
von Byern J, Klepal W. 2006. Adhesive mechanisms in cephalopods: A review. Biofouling 22: 329-338.
Waite JH. 1992. The formation of mussel byssus: Anatomy of a natural manufacturing process. Results Problems Cell Differ 19: 27-54.
Waite JH. 2002. Adhesion a la Moule. Integr Comp Biol 42: 1172-1180.
Waite ME, Walker G. 1988. The haemocytes of balanomorph barnacles. J Mar Biol Assoc UK 68: 391-397.
Walker G. 1970. The histology, histochemistry and ultrastructure of the cement apparatus of three adult sessile barnacles, Elminius modestus, Balanus balanoides and Balanus hameri. Mar Biol 7: 239-248.
Walker G. 1971. A study of the cement apparatus of the cypris larva of the barnacle Balanus balanoides. Mar Biol 9: 205-212.
Walker G. 1972. The biochemical composition of the cement of two barnacle species, Balanus hameri and Balanus crenatus. J Mar Biol Assoc UK 52: 429-435.
Walker G. 1978. A cytological study of the cement apparatus of the barnacle, Chelonibia testudinaria Linnaeus, an epizoite on turtles. Bull Mar Sci 28: 205-209.
Walker G. 1987. Marine organisms and their adhesion. In: Wake WC, editor. Synthetic Adhesives and Sealants. Chichester: Wiley. pp 112-135.
Walker G, Youngson A. 1975. The biochemical composition of Lepas anatifera (L.) cement (Crustacea: Cirripedia). J Mar Biol Assoc UK 55: 703-707.
Wang CS, Stewart RJ. 2012. Localization of the bioadhesive precursors of the sandcastle worm, Phragmatopoma californica (Fewkes). J Exp Biol 215: 351-361.
Wang CS, Svendsen KK, Stewart RJ. 2010. Morphology of the adhesive system in the sandcastle worm, Phragmatopoma californica. In: Grunwald I, vonByern J, editors. Biological Adhesive Systems. Vienna: Springer-Verlag. pp 169-179.
Wiegemann M, Kowalik T, Hartwig A. 2006. Noncovalent bonds are key mechanisms for the cohesion of barnacle (Balanus crenatus) adhesive proteins. Marine Biology 149: 241-246.
Wiegemann M. 2005. Structure formation in barnacle adhesive. In: Possart W, editor. Adhesion: Current Research and Applications. Weinheim: Wiley-VCH. pp 143-156.
Wilker JJ. 2011. Biomaterials: Redox and adhesion on the rocks. Nat Chem Biol 7: 579-580.
Zhao H, Waite JH. 2006. Linking adhesive and structural proteins in the attachment plaque of Mytilus californianus. J Biol Chem 281: 26150-26158.
Zhao H, Sun C, Stewart RJ, Waite JH. 2005. Cement proteins of the tube building polychaete Phragmatopoma californica. J Biol Chem 280: 42938-42944.
Zheden V, Byern Jv, Kerbl A, Leisch N, Staedler Y, Grunwald I, Power AM, Klepal W. 0000 Cement float of a barnacle: morphology of the cement apparatus and the cement of the buoy barnacle Dosima fascicularis (Ellis & Solander, 1786) (Crustacea, Cirripedia Thoracica, Lepadidae). Biol Bull (in press).
