The force required to dislodge mussels from the substrate is known as attachment strength. This feature has been mostly studied in mytilids inhabiting the intertidal of consolidated rocky substrates, whereas it has been less studied in sedimentary substrates. The aim of this study was to evaluate the attachment strength and the number of byssal threads of Brachidontes rodriguezii in two sites with mobile substrates in San Antonio Bay, Argentina [Punta Verde (PV) and Punta Delgado (PD)]. PV has relatively higher current velocities and coarser grain size than PD. Along coastal line transects at two different levels of the mid-intertidal of each site, the attachment strength was measured. The number of byssal threads in collected mytilids and the weight of the sediment adhered to them were recorded in the lab. The attachment strength, the number of byssal threads and the sediment adhered to the byssus differed significantly between levels and sites. Mytilids from the mid-level of both sites where the density was relatively lower, had a significantly greater number of byssal threads and higher weight of sediment adhered. This study reveals that a high amount of coarse sediment adhered to the byssus affects the attachment strength of B. rodriguezii in ecosystems relative to unstable substrates. We underline the importance of mobile substrates in understanding attachment features (attachment strength and byssal threads) of mytilids in this unstable ecosystem.

The impact of an alien species is correlated with its abundance and potential to colonisenew environments. Consequently, the crucial aspects that give a mytilid species invasivepotential include its strength and capacity for adhesion to a wide variety of substratesand its ecological tolerance to environmental conditions. The alien black pygmy musselXenostrobus securis settles together with the indigenous and raftcultured mussel Mytilus galloprovincialis on hard substrates of the innercoastline of the Ría de Vigo (Atlantic Coast NW Spain). Key parameters for the ecologicalsuccess of these species could include their byssus structure and ecological plasticity.In this study, we assessed their comparative ability to attach to different substratesunder different environmental conditions, using both in situ and laboratory approaches.Byssus threads secreted by X. securis were found to be extremely thin andtheir thickness did not vary with mussel size. This thinness of byssus filaments inX. securis was compensated by the secretion of a huge number (up tothousand of byssus filaments). Although no increase in attachment strength was found withincreasing mussel size in this species, multiple byssus thread secretion might be a keyfactor in the successful invasion of inner areas of the estuary. Furthermore, X.securis exposes a much lower shell area to lift and drag forces in musselconglomerates. By contrast, the indigenous species M. galloprovincialissecretes thicker byssus threads, which provide stronger in situ attachmentdisplaying a linear increase in strength relative to the size of mussels. The exposure ofboth mytilid species to different abiotic factors in the laboratory confirmed the weakerbyssus secretion and limited variation in attachment strength in the alien species. On onehand, X. securis seemed to be better adapted to life on soft bottoms andnot capable of much plasticity when attached to different substrates. However, X.securis might be also well adapted to variable environmental conditions, e.g.,salinity fluctuations, with no need to modify its byssus properties to ensure secureattachment. Attachment strength of M. galloprovincialis was higher thanX. securis in all abiotic conditions tested. Results are discussed inrelation to the ecological tolerance and impact of these mytilid species.

Byssogenesis rate and attachment strength of the mussel Mytilus galloprovincialis were investigated in the laboratory considering different body sizes and feeding conditions. Byssal thread secretion was significantly higher in juveniles as compared to larger mussels of approximately 87 mm shell length. Asymptotic number of threads attached was obtained from approximately 72 hours onwards within a range of 42–46 and 27–31 for juveniles and larger experimental mussels, respectively (P < 0.05 ANOVA). Absorption efficiency values of control fed individuals dropped significantly from 0.78 in juveniles to 0.70 in larger mussels (P < 0.001 ANOVA) which pointed out energetic constraints of mussels with regard to their size and its probable effect on byssus secretion rates. Attachment force was 2.8 times higher in larger mussels than in juveniles (2.21 versus 0.78 N for both sizes, respectively; P < 0.001 ANOVA) which in turn followed the same order of magnitude than differences in the thread's thickness values of both experimental mussel sizes. Tenacity followed a reverse pattern with juveniles presenting two-fold higher values than larger mussels (P < 0.001 ANOVA) based on a lower increment of attachment force (x2.8) as compared to shell area (x6) for the comparison larger versus juvenile mussel size, which in turn might suggest that larger specimens secreted weaker threads. When animals were maintained unfed for a week, a significant drop in both byssus secretion and attachment force were observed in juveniles but was not the case for larger mussels most likely as a consequence of a relatively short period of maintenance under food availability stress for the latter individuals that showed significantly higher initial condition and/or energetic store values. Accordingly, the use of energetic reserves in juveniles kept unfed for a week together with a significant drop in byssus secretion and attachment force might suggest a link, i.e. transfer of energy between soft tissues and byssus under stress. Quantitative values of byssal threads, based on the significance of the byssus versus attachment force relationship, together with its morphometric value, i.e. thread's thickness, represented a primary mechanism to explain variability in attachment strength of M. galloprovincialis of the different body sizes studied here.