Stephen et al.: Comparison of life history parameters for landed and discarded fish off the southeastern United States 
303 
context of sustainable fisheries. Bull. Mar. Sci. 70: 
639-656. 
Heppell, S. S., S. A. Heppell, F. C. Coleman, and C. C. Koenig. 
2006. Models to compare management options for a pro- 
togynous fish. Ecol. Appl. 16:238-249. 
Hood, P. B., and A. K. Johnson. 
1999. Age, growth, mortality, and reproduction of vermil- 
ion snapper, Rhomboplites aurorubens, from the eastern 
Gulf of Mexico. Fish. Bull. 97:828-841. 
Hood, P. B., and A. K. Johnson. 
2000. Age, growth, mortality, and reproduction of 
red porgy, Pagrus pagrus, from the eastern Gulf of 
Mexico. Fish. Bull. 98:723-735. 
Hutchings, J. A. 
2005. Life history consequences of overexploitation to 
population recovery in Northwest Atlantic cod (Gadus 
morhua). Can. J. Fish. Aquat. Sci. 62:824-832. 
Hutchings, J. A., and R. A. Meyers. 
1993. Effect of age on the seasonality of maturation and 
spawning of Atlantic cod, Gadus morhua, in the North- 
west Atlantic. Can. J. Fish. Aquat. Sci. 50:2468-2474. 
Kjesbu, O. S., P. Solemdal, P. Bratland, and M. Fonn. 
1996. Variation in annual egg production in individual 
captive Atlantic cod ( Gadus morhua). Can. J. Fish. 
Aquat. Sci. 53:610-620. 
Kuparinen, A., and J. Merila. 
2007. Detecting and managing fisheries-induced evolu- 
tion. Trends Ecol. Evol. 22:652-659. 
Law, R. 
2000. Fishing, selection, and phenotypic evolution. ICES 
J. Mar. Sci. 57:659-668. 
Liu, M., and Y. Sadovy. 
2004. The influence of social factors on adult sex change 
and juvenile sexual differentiation in a diandric, pro- 
togynous epinepheline, Cephalopholis boenak (Pisces, 
Serranidae). J. Zool. 264:239-248. 
Manooch, C. S., Ill, and G. R. Huntsman. 
1977. Age, growth, and mortality of the red porgy, Pagrus 
pagrus. Trans. Am. Fish. Soc. 106:26-33. 
Manooch, C. S„ III, J- C. Potts, M. L. Burton, and P. J. Harris. 
1998. Population assessment of the scamp, Mycteroperca 
phenax, from the southeastern United States. NOAA 
Tech. Memo. NMFS-SEFSC-410, 57 p. 
Matheson, R. H., Ill, G. R. Huntsman, and C. S. I. Manooch. 
1986. Age, growth, mortality, food and reproduction of the 
scamp, Mycteroperca phenax, collected off North Caro- 
lina and South Carolina. Bull. Mar. Sci. 38:300-312. 
Mollet, F. M., S. B. M. Kraak, and A. D. Rijnsdorp. 
2007. Fisheries-induced evolutionary changes in matura- 
tion reaction norms in North Sea sole Solea solea. Mar. 
Ecol. Prog. Ser. 351:189-199. 
Munday, P. L., P. M. Buston, and R. R. Warner. 
2006a. Diversity and flexibility of sex-change strategies 
in animals. Trends Ecol. Evol. 21:89-95. 
Munday, P. L., J. W. White, and R. R. Warner. 
2006b. A social basis for the development of primary 
males in a sex-changing fish. Proc. R. Soc. Lond., Ser. 
B: Biol. Sci. 273:2845-2851. 
NMFS (National Marine Fisheries Service). 
2010. 2009 status of U.S. fisheries, 28 p. U.S. Dept. 
Comm., NOAA, National Marine Fisheries Service, Silver 
Spring, MD. [Available at http://www.nmfs.noaa.gov/sfa/ 
statusoffisheries/SOSmain.htm (accessed April 2011).] 
Olsen, E. M., G. R. Lilly, M. Heino, M. J. Morgan, J. Brattey, and 
U. Dieckmann. 
2005. Assessing changes in age and size at matura- 
tion in collapsing populations of Atlantic cod ( Gadus 
morhua). Can. J. Fish. Aquat. Sci. 62:811-823. 
Pitcher, T. J., and P. J. B. Hart. 
1982. Fisheries ecology, 414 p. Groom Helm, London. 
Potts, J. C., and C. S. Manooch, III. 
2002. Estimated ages of red porgy (Pagrus pagrus) 
from fishery-dependent and fishery-independent data 
and a comparison of growth parameters. Fish. Bull. 
100:81-89. 
Ratner, S., and R. Lande. 
2001. Demographic and evolutionary responses to selec- 
tive harvesting in populations with discrete genera- 
tions. Ecology 82:3093-3104. 
Reznick, D. A., H. Bryga, and J. A. Endler. 
1990. Experimentally induced life-history evolution in 
a natural population. Nature 346:357-359. 
Reznick, D. N., and C. K. Ghalambor. 
2005. Can commercial fishing cause evolution? Answers 
from guppies ( Poecilia reticulata). Can. J. Fish. Aquat. 
Sci. 62:791-801. 
Ricker, W. E. 
1945. A method of estimating minimum size limits for 
obtaining maximum yield. Copeia 1945:84-94. 
Rothschild, B. J. 
1986. Dynamics of marine fish populations, 277 p. Har- 
vard Univ. Press, Cambridge, MA. 
SAFMC (South Atlantic Fishery Management Council). 
1983. Fishery management plan, regulatory impact 
review, and final environmental impact statement for 
the snapper-grouper fishery of the south atlantic region, 
303 p. SAFMC, Charleston, SC. 
Schmidt, D. J., M. R. Collins, and D. M. Wyanski. 
1993. Age, growth, maturity, and spawning of Spanish 
mackerel, Scomberomorus maculatus (Mitchili), from the 
Atlantic coast of the southeastern United States. Fish. 
Bull. 91:526-533. 
SEDAR (SouthEast Data, Assessment, and Review). 
2006. SEDAR-01 Update: Stock assessment of red porgy 
off the southeastern United States, SEDAR update 
assessment, 152 p. South Atlantic Fishery Manage- 
ment Council, Beaufort, NC. [Available at http://www. 
sefsc.noaa.gov/sedar (accessed April 2011).] 
SEDAR (SouthEast Data, Assessment, and Review). 
2008. SEDAR-17: Stock assessment report: South Atlan- 
tic vermilion snapper, 450 p. South Atlantic Fishery 
Management Council, Charleston, SC. [Available at 
http://www.sefsc.noaa.gov/sedar (accessed April 2011).] 
Sharpe, D. M. T., and A. P. Hendry. 
2009. Life history change in commercially exploited fish 
stocks: an analysis of trends across studies. Evol. Appl. 
2:260-275. 
Stephen, J. A., and P. J. Harris. 
2010. Commercial catch composition with discard 
and immediate release mortality proportions off the 
southeastern coast of the United States. Fish. Res. 
103:18-24. 
Stokes, K., and R. Law. 
2000. Fishing as an evolutionary force. Mar. Ecol. Prog. 
Ser. 208:307-309. 
Swain, D. P, A. F. Sinclair, and J. M. Hanson. 
2007. Evolutionary response to size-selective mortality 
in an exploited fish population. Proc. R. Soc. Lond., 
Ser. B: Biol. Sci. 274:1015-1022. 
Trippel, E. A., O. S. Kjesbu, and P. Solemdal 
1997. Effects of adult age and size structure on repro- 
ductive output in marine fishes. In Early life history 
