The study shows that two natural peptides, thymosin beta‑4 and beta‑10, bind to actin building blocks inside cells and, when present in large amounts, cause many of the cell’s internal scaffolding fibers to disappear, especially in the middle of the cell. This also reduces the spots where cells stick to their surroundings, though the cells mostly keep their shape.

The beta-thymosins are a family of small proteins originally isolated from the thymus. Recently, two of the major mammalian isoforms, thymosin beta 4 (T beta 4) and thymosin beta 10 (T beta 10), are identified as significant actin monomer sequestering proteins which may be involved in regulating actin filament assembly. To study the cellular function of beta-thymosins, we have used isoform-specific antibodies to determine their concentration and intracellular distribution, and examined the effects of inducing overexpression of T beta 4 and T beta 10 on actin filament structures. Immunofluorescence labeling of peritoneal macrophages showed that both beta-thymosins are uniformly distributed within the cytoplasm. cDNA-mediated overexpression of beta-thymosins in CV1 fibroblasts induced extensive loss of phalloidin-stained actin stress fibers. Stress fibers in the cell center were more susceptible than those at the periphery. There was a decrease in the number of focal adhesions, as evidenced by a decrease in discrete vinculin staining and an increase in diffuse vinculin fluorescence. The majority of the transfected cells had normal shape in spite of extensive loss of actin filaments. Occasionally, cells overexpressing beta-thymosin were observed to divide. In these cells, beta-thymosin was excluded from the midbody which contains an actin filament-rich contractile ring. Our results indicate that T beta 4 and T beta 10 are functionally very similar and both are effective regulators of a large subset of actin filaments in living cells.