Professor
Education:
NIH Postdoctoral Fellow- University of Pennsylvania-1986-1988
Ph.D.-University of Connecituct-1986
B.A.-Boston University-1981
Discipline(s):
Growth and Development
Websites of interest:
The Laboratory of Dr. Sandra Gayle Velleman
Courses Taught:
Molecular Events in Tissue Growth (AS 618)
Grants & Awards:
Awards:
National Turkey Federation Research Award, 2006.
Gamma Sigma Delta, The Ohio State University Chapter 1999
Poultry Science Association Inc., Research Award 1998
Outstanding Young Woman of America 1997
Phi Kappa Phi 1994
Sigma Xi, University of Connecticut Chapter 1989
Grants:
Velleman, S.G. (Co-PI), USDA-NRI, "Identification, Differential Expression, and Mapping of Muscle Genes in Genetically Selected Turkey," 5/1/05-4/30/09.
Velleman, S.G., Midwest Poultry Research Program, "Growth and Development of the Commercial Pheasant Reared Under Different Environmental Conditions," 6/1/05-5/31/06.
Velleman, S.G. (Co-PI), Midwest Poultry Research Program, "Regulation of the Growth of Turkey Skeletal Muscle, 6/1/05-5/31/05.
Velleman, S.G., OARDC Research Enhancement Competitive Grants, "Regulation of the Growth of Turkey Skeletal Muscle," 4/05-3/06.
Velleman, S.G., Ohio Poultry Association, "Studies on Turkey Muscle Fiber Analysis," 1/05-12/05.
Velleman, S.G. Aviagen, "Maternal Inheritance of Breast Muscle Morphology in Broilers, 1/05-12/31/06.
Velleman, S.G. Cobb-Vantress. “Effect of Selection on Breast Muscle Morphological Characteristics and Creatine Kinase,” 7/1/04-6/30/05.
Velleman, S.G. Ohio Poultry Association. “Studies on Turkey Muscle Fiber Analysis,” 1/04-12/31/04.
Velleman, S.G., USDA-NRI, “Role of Proteoglycans in Skeletal Muscle Growth and Development,” 9/1/2003-8/31/2006.
Publications:
Publications (last 5 years):
Nestor, K.E., Bacon, W.L., Velleman, S.G., Anderson, J.W., and Patterson, R.A. 2002. Effect of selection for increased body weight and increased plasma yolk precursor on developmental stability in Japanese quail. Poult. Sci. 81: 160-168.
Medeiros, D.M., Velleman, S.G., Jarrold, B.B., Shiry, L.J., Radin, J., and McCune, S.A. 2002. Ontogeny of enhanced decorin levels and distribution within myocardium of failing hearts. Connect. Tissue Res. 43:1-12.
Emmerson, D.A., Velleman, S.G., and Nestor, K.E. 2002. Genetics of growth and reproduction in the turkey. 15. Effect of long-term selection for increased egg production on the genetics of growth and egg production traits. Poult. Sci. 81:316-320.
Velleman, S.G. 2002. Role of the extracellular matrix in muscle growth and development. J. Animal Sci. 80: (E. Suppl. 2): E8-E13.
Velleman, S.G., Coy, C.S., Anderson, J.W., Patterson, R.A., and Nestor, K.E. 2002. Effect of selection for growth rate on embryonic breast muscle development in turkeys. Poult. Sci. 81:1113-1121.
Liu, X., Nestor, K.E., McFarland, D.C., and Velleman, S.G. 2002. Developmental expression of skeletal muscle heparan sulfate proteoglycans in turkeys with different growth rates. Poult. Sci. 81:1621-1628.
Ding, S.T., Li, Y.C., Nestor, K.E., Velleman, S.G., and Mersmann, H.J. 2003. Expression of turkey transcription factors and acyl CoA oxidase in different tissues and genetic populations. Poult. Sci. 82:17-24.
Velleman, S.G., Coy, C.S., and Bacon, W.L. 2003. Temporal and spatial localization of the proteoglycan decorin transcripts during the progression of cholesterol induced atherosclerosis in Japanese quail. Connect. Tissue Res. 44:69-80.
McFarland, D.C., Liu, X., Velleman, S.G., Caiyun, Z., Coy, C.S., and Pesall, J.E. 2003. Variation in fibroblast growth factor response and heparan sulfate proteoglycan production in satellite cell populations. Comp. Biochem. Physiol. Part C 134:341-351.
Velleman, S.G. Anderson, J.W., Coy, C.S., and Nestor, K.E. 2003. Effect of selection for growth rate on muscle damage during turkey breast muscle development. Poult. Sci. 82:1069-1074.
Liu, X., McFarland, D.C., Nestor, K.E., and Velleman, S.G. 2003. Expression of fibroblast growth factor 2 and its receptor during skeletal muscle development from turkeys with different growth rates. Dom. Anim. Endocrinol. 25:215-229.
Velleman, S.G., and Nestor, K.E. 2003. Effect of selection for growth rate on myosin heavy chain temporal and spatial localization during turkey breast muscle development. Poult. Sci. 82:1373-1377.
Velleman, S.G., Coy, C.S., Anderson, J.W., Patterson, R.A., and Nestor, K.E. 2003. Effect of selection for growth rate and inheritance on post hatch muscle development in turkeys. Poult. Sci. 82:1365-1372.
Wick, M., Velleman, S.G., Coy, C.S., McFarland, D.C., and Pretzman, C.I. 2003. Myosin heavy chain isoform expression is altered during in vitro myogenesis in low score normal chickens. Comp. Biochem. Physiol. Part A 136:401-408.
Velleman, S.G., Anderson, J.W., and Nestor, K.E. 2003. Possible maternal inheritance of breast muscle morphology in turkeys at sixteen weeks of age. Poult. Sci. 82:1479-1484.
Velleman, S.G., and McFarland, D.C. 2004. Beta 1 integrin mediation of myogenic differentiation: Implications for satellite cell differentiation. Poult. Sci. 83:245-253.
Liu, X., McFarland, D.C., Nestor, K.E., and Velleman, S.G. 2004. Developmentally regulated expression of syndecan-1 and glypican in pectoralis major muscle in turkeys with different growth rates. Dev. Growth Diff. 46:37-51.
Velleman, S.G., Liu, X., Coy, C.S., and McFarland, D.C. 2004. Effects of syndecan-1 and glypican on muscle cell proliferation and differentiation: Implications for possible functions during myogenesis. Poult. Sci. 83: 1020-1027.
Liu, X., Nestor, K.E., and Velleman, S.G. 2004. The influence for increased body weight and sex on pectoralis major muscle weight during the embryonic and post-hatch periods. Poult. Sci. 83: 1089-1092.
Nestor, K.E., Anderson, J.W., Patterson, R.A., and Velleman, S.G. 2004. Genetic variation in body weight and egg production in an experimental line selected long term for increased egg production, a commercial dam line, and reciprocal crosses between lines. Poult. Sci. 83:1055-1059.
Velleman, S.G. and Nestor, K.E. 2004. Inheritance of breast muscle morphology in turkeys at sixteen weeks of age. Poult. Sci. 83:1060-1066.
Liu, C., McFarland, D.C., and Velleman, S.G. 2005. Effect of selection on MyoD and myogenin expression in turkeys with different growth rates. Poult. Sci. 84:376-384.
Velleman, S.G., and Mozdziak, P.E. 2005. Effects of posthatch feed deprivation on heparan sulfate proteoglycan, syndecan-1, and glypican expression: Implications for muscle growth potential in chickens. Poult. Sci. 84:601-606.
Velleman, S.G., and Nestor, K.E. 2005. Effect of genetic increases in egg production, age, and sex on muscle development in turkeys. Poult Sci. 84:1347-1349.
Nestor, K.E., Anderson, J.W., and Velleman, S.G. 2005. Genetic variation in pure lines and crosses of large-bodied turkey lines. 3. Growth-related measurements on live birds. Poult Sci. 84:1341-1346.
Nestor, K. E., Anderson, J. W., Hartzler, D., and Velleman, S.G. 2005. Genetic variation in pure lines and crosses of large-bodied turkeys. 4. Body shape and carcass traits. Poult. Sci. 84:1825-1834.
Li, X., McFarland, D.C., and Velleman, S.G. 2006. Effect of transforming growth factor beta on decorin and beta 1 integrin expression during muscle development in chickens. Poult. Sci 85:326-332.
Liu, C., McFarland, D.C., and Velleman, S.G. 2006. Membrane-associated heparan sulfate proteoglycans are differentially expressed in the skeletal muscle of turkeys with different growth rates. Poult. Sci. 85:422-428.
Velleman, S.G., Liu, C., Coy, C.S., and McFarland, D.C. 2006. Effects of glypican-1 on turkey skeletal muscle cell proliferation, differentiation, and fibroblast growth factor 2 responsiveness. Dev. Growth Diff. 48:271-276.
McFarland, D.C., Velleman, S.G., Pesall, J.E., and Liu, C. 2006. Effect of myostatin on turkey myogenic satellite cells and embryonic myoblasts. Comp. Biochem. Physiol. Pt A 144:501-508.
Nestor, K.E., Anderson, J.W., Patterson, R.A., and Velleman, S.G. 2006. Genetics of growth and reproduction in the turkey. 16. Effect of repeated backcrossing of an egg line to a commercial sire line. Poult. Sci. 85:1550-1554.
Velleman, S.G., and Nestor, K.E. 2006. Inheritance of breast muscle morphology in a line of turkeys selected long term for increased egg production, its randombred control line, and reciprocal crosses among them. Poult. Sci. 85:2130-2134.
Velleman, S.G. 2007. Muscle development in the embryo and hatchling. Poult. Sci. 86:1050-1054.
Velleman, S.G., Coy, C.S., and McFarland, D.C. 2007. Effect of syndecan-1, syndecan-4, and glypican-1 on turkey muscle satellite cell proliferation, differentiation, and responsiveness to fibroblast growth factor 2. Poult. Sci. 86:1406-1413.
Zhang, X., Liu, C., Nestor, K.E., McFarland, D.C., and Velleman, S.G. 2007. The effect of glypican-1 glycosaminoglycan chains on turkey myogenic satellite cell proliferation, differentiation, and fibroblast growth factor 2 responsiveness. Poult. Sci. 86:2020-2028.
Christensen, V.L., Ort, D.T., Nestor, K.E., Velleman, S.G., and Havenstein, G.B. 2007. Genetic control of neonatal growth and intestinal maturation in turkeys. Poult. Sci. 86:476-487.
McFarland, D.C., Velleman, S.G., Pesall, J.E., and Liu, C. 2007. The role of myostatin in chicken (Gallus domesticus) myogenic satellite cell proliferation and differentiation. Gen. And Comp. Endocrinol. 151:351-357.
Hoekstra, K.A., and Velleman, S.G. 2007. Brain microvascular and intracranial artery resistance to atherosclerosis is associated with heme oxygenease ferritin. Molecular and Cellular Biochem. (In press).
Chester-Jones, H., and Velleman, S.G. 2007. Growth and development symposium: Transcriptional factors and cell mechanisms for regulation of growth and development with application to animal agriculture. J. Anim. Sci. (In press).
Book Chapters
Velleman, S.G. 2003. “Extracellular Matrix and Growth,” in Biology of Growth of Domestic Animals ed. Colin Scanes, Iowa State University Press.
Velleman, S.G. and Liu, C. 2006. "Structure and Function of Cell Associated and Pericellular Heparan Sulfate Proteoglycans," in Chemistry and Biology of Heparin and Heparan Sulfate. eds. H. G. Garg, R.J. Linhardt, and C.A. Hales, Elsevier Publishing, 29-54.
Species:
Poultry
Extracellular Matrix Regulation of Skeletal Muscle Growth and Development:
Skeletal muscle myogenesis is a highly organized process regulated by complex interactions between muscle cells and their environment. Muscle develops from myoblasts that proliferate, align, and fuse to form multinucleated myotubes that differentiate into mature muscle fibers. Muscle fibers are surrounded and supported by three layers of connective tissue: endomysium, perimysium, and epimysium. Connective tissue is composed of cells and an extracellular matrix. The extracellular matrix is composed of fibrous and nonfibrous proteins including collagens and proteoglycans. In the past decade, research has shown the extracellular matrix to be a dynamic action zone that functions to instruct cellular phenotype. The extracellular matrix modulates the activation of signal transduction pathways critical to differentiation. Important to this role of the extracellular matrix is the dynamic nature of the extracellular environment in that the composition of the matrix changes with maturation and is cell type specific. These developmentally regulated changes in the extracellular matrix have profound affects on the function of the extracellular matrix as well as cellular responses to the extracellular matrix. How the expression of the extracellular matrix macromolecules affects muscle growth is currently not well understood. It is the long-term goal of my research to further understand the signaling mechanisms by which specific extracellular matrix macromolecules influence the process of skeletal muscle growth and development.
The Role of the Extracellular Matrix in the Loss of Muscle with Age:
Skeletal muscle and its associated connective tissue comprises approximately 40% of the total human body. The appropriate structure and function of skeletal muscle is required for muscle contraction and relaxation, and the maintenance of body posture. The average human loses 25-30% of their skeletal muscle mass by the age of 70. Skeletal muscle satellite cells are responsible for the regeneration and repair of muscle fibers. The percentage of satellite cells in relation to the total number of nuclei present in a muscle fiber progressively declines with age, and the ability of satellite cells to reenter the cell cycle to proliferate and differentiate also decreases with age. Muscle fibers including the satellite cells are surrounded by an extracellular matrix that contains proteoglycans which are required for the activity of certain growth factors that function as potent stimulators or inhibitors of satellite cell proliferation and differentiation. How the extracellular matrix proteoglycans involved with growth factor signaling of satellite cells changes with age is largely unknown. The objective of this research is to learn more about how the expression of proteoglycans integral to growth factor signaling changes with muscle age and how these changes are associated with satellite cell proliferation and differentiation.
The Affect of Genetic Selection of Poultry for Growth Rate on Muscle Formation:
The trend of the poultry industry has been to select birds with increased growth rate and muscling. Although growth rate, feed conversion, and muscling have improved in meat-type chickens and turkeys, meat quality has been altered. The turkey processing industry in recent years is experiencing a meat quality problem which is similar to the pale, soft, exudative (PSE) condition in swine. Turkey PSE meat after cooking has a soft texture, poor meat binding, poor juiciness due to reduced water-holding capacity, and increased yield losses. How genetic selection for growth rate has affected muscle fiber bundle architecture and extracellular matrix spacing between the muscle fibers is not well understood. The extracellular space around the muscle fibers contains molecules essential in maintaining water-holding capacity. If the concentration or distribution of these extracellular molecules is modified, it is likely that water-holding capacity will be affected. The goals of this research are to determine if genetic selection for increased growth rate and breast muscling has changed pectoral muscle fiber characteristics, the degree of extracellular matrix spacing between muscle fibers, and the expression of extracellular matrix proteins pivotal to muscle development.
