Harry N. Antoniades scite author profile

The transforming protein of a primate sarcoma virus and a platelet-derived growth factor are derived from the same or closely related cellular genes. This conclusion is based on the demonstration of extensive sequence similarity between the transforming protein derived from the simian sarcoma virus onc gene, v-sis, and a human platelet-derived growth factor. The mechanism by which v-sis transforms cells could involve the constitutive expression of a protein with functions similar or identical to those of a factor active transiently during normal cell growth.

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Induction of DNA synthesis in BALB/c 3T3 cells by serum components: Reevaluation of the commitment process

Pledger

Stiles

Antoniades

et al. 1977

Proc. Natl. Acad. Sci. U.S.A.

616

413

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Serum contains a growth factor derived from platelets and also growth factors derived from platelet-poor plasma. Extracts of heated (1000) human platelets function synergistically with platelet-poor plasma to induce DNA synthesis in quiescent, density-inhibited BALB/c 3T3 cells. Platelet-poor plasma alone did not induce DNA synthesis. Cells exposed to platelet extracts became competent to enter the cell cycle, but the rate of entry into the S phase depended upon the concentration of platelet-poor plasma. The time required for the induction of this competent state was a function of the concentration of the platelet extract. A 2-hr exposure to 100',g of the platelet extract at 370 caused the entire cell population to become competent to enter the S phase. At 40 or 250 the cells did not become competent to synthesize DNA. The platelet extract-induced competent state was stable for at least 13 hr after removal of the platelet extract; however, in the absence of platelet-poor plasma, these competent cells did not progress through the cell cycle. The addition of an optimal concentration of platelet-poor plasma (5%) to these competent cells initiated cell cycle traverse with a ra id, first-order entry of cells into the S phase beginning 12 hr after addition of the plasma. The addition of a suboptimal concentration of the plasma (0.25%) did not increase the rate of cell entry into the S phase. Thus, the induction of DNA synthesis in quiescent BALB/c 3T3 cells can be resolved into at least two phases, controlled by different serum components: (i) competence, induced by the plateletderived growth factor; and (ii) progression of competent cells into the cell cycle, mediated by factors in platelet-poor plasma.The growth of 3T3 cells (1), diploid fibroblasts (2), and smooth muscle cells (3) in vitro is controlled by the concentration of serum in the medium. Serum can be separated into two sets of components which control different cell functions. One set maintains cell viability (4), while the other stimulates replication (5). A heat-stable (1000) cationic growth factor (6) derived from. platelets (7) is released into serum during the clotting process (8, 9). Human serum contains about 770 pg of this polypeptide growth factor per mg of protein, as demonstrated by radioimmunoassay (7). Defibrinogenated platelet-poor plasma, a fraction prepared from unclotted blood, contains only low levels of the growth factor and does not stimulate the replication of diploid fibroblasts or BALB/c 3T3 cells (3, 7-9). Platelet-poor plasma does, however, contain the factors that maintain cell viability (3).The process by which resting cells become committed to enter the growth cycle remains unclear. Smith and Martin (10) have proposed that the commitment of quiescent cells to synthesize DNA is a random event characterized by a first-order rate constant, the transition probability. According to thisThe costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked ...

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Dual control of cell growth by somatomedins and platelet-derived growth factor.

Stiles¹,

Capone²,

Scher³

et al. 1979

Proc. Natl. Acad. Sci. U.S.A.

835

396

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Quiescent BALB/c 3T3 cells exposed briefly to a platelet-derived growth factor (PDGF) become "competent" to replicate their DNA but do not "progress" into S phase unless incubated with growth factors contained in platelet-poor plasma. Plasma from hypophysectomized rats is deficient in progression activity; it does not stimulate PDGF-treated competent cells to synthesize DNA. Addition of somatomedin C to hypophysectomized rat plasma stimulates competent cells to synthesize DNA, demonstrating that somatomedin C is required for progression. Various growth factors were tested for progression activity and competence activity by using BALB/c 3T3 tissue culture assays. Multiplication stimulating activity and other members of the somatomedin family of growth factors are (like somatomedin C) potent mediators of progression. Other mitogenic agents, such as fibroblast growth factor, are (like PDGF) potent inducers of competence. Growth factors with potent progression activity have little or no competence activity and vice versa. In contrast, simian virus 40 provides both competence and progession activity. Coordinate control of BALB/c 3T3 cell growth in vitro by competence factors and somatomedins may be a specific example of a common pattern for growth regulation in animal tissues.

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The Effects of Short‐Term Application of a Combination of Platelet‐Derived and Insulin‐Like Growth Factors on Periodontal Wound Healing

Lynch

Castilla

Williams

et al. 1991

Journal of Periodontology

414

246

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Polypeptide growth factors are a class of potent natural biologic mediators which regulate many of the activities of wound healing including cell proliferation, migration, and metabolism. Platelet-derived growth factor (PDGF) and insulin-like growth factor-I (IGF-I) have been shown to regulate DNA and protein synthesis in bone cells in vitro and to interact synergistically to enhance soft tissue wound healing in vivo. We have hypothesized that the combination of PDGF and IGF-I may, therefore, enhance regeneration of both the soft and hard tissue components of the periodontium. To test this hypothesis we performed conventional periodontal surgery on all 4 quadrants of the mouth of 13 beagle dogs with naturally occurring periodontal disease. Following flap reflection, degranulation, and root planing, all premolar teeth in 2 quadrants of each dog received a combination of 3 micrograms of recombinant PDGF-B and IGF-I in a methylcellulose gel, while the premolar teeth in the contralateral quadrants received the gel alone. Teeth in 4 additional animals also received 125I-PDGF or 125I-IGF-I in the treated sites. The clearance rate of the 125I-labeled protein, changes in local bone metabolism, and amount of new bone and cementum with inserting collagen fibers were measured. The clearance studies revealed that the half-life of the factors at the site of application was 3.0 hours for IGF-I and to 4.2 hours for PDGF-B. Greater than 96% of the radio-labeled proteins was cleared by 96 hours and no radioactivity was detected 2 weeks after application. There was a significant (P less than 0.01) 2-fold increase in uptake of the bone-seeking radiopharmaceutical Technetium 99-MDP at 2 and 4 weeks in growth factor treated sites compared to controls, indicating that there was increased metabolic activity within the bone at these sites. Computer-aided histologic analyses of biopsies obtained at 2 and 5 weeks post-operatively revealed a significant (P less than 0.01), 5 to 10 fold increase in new bone and cementum in PDGF-B/IGF-I treated sites at both time points compared to controls receiving the placebo gel. The height and total area of new bone continued to increase from 2 to 5 weeks. The new bone underwent a normal maturation process as judged by histologic appearance. A physiologic periodontal ligament space was also formed between the new bone and new cementum. There was no increase in ankylosis in the treated sites.(ABSTRACT TRUNCATED AT 400 WORDS)

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