Ronald M. Shymko

The Insulin-Like Growth Factor-I Receptor

The nonclassical binding kinetics of IGF-I and insulin to their respective receptors, suggestive of negative cooperativity, can be readily explained by our recently proposed novel binding mechanism wh

Mitogenic and antiadipogenic properties of human growth hormone in differentiating human adipocyte precursor cells in primary culture

Children with GH deficiency have enlarged fat cells but a reduced number of fat cells compared with healthy children. After treatment with human GH (hGH) both fat cell volume and number are shifted toward normal. To clarify the role of hGH in fat cell formation in human adipose tissue, we investigated the effect of hGH on the proliferation and the differentiation of cultured human adipocyte precursor cells obtained from five children and 10 adults. In a chemically defined serum-free medium treatment of adipocyte precursor cells with hGH led to an increase in IGF-I production and a stimulation of cell proliferation, which could be blocked by a MAb raised against human IGF-I. hGH dose-dependently reduced the number of differentiating cells and suppressed the expression of glycerol-3-phosphate dehydrogenase (GPDH), a marker of adipose differentiation. No significant differences in the hGH effects on proliferation and differentiation capacities were seen between cultures obtained from children and adults. In newly differentiated adipocytes, hGH inhibited glucose uptake and lipogenesis, and stimulated lipolysis. Scatchard analysis of hGH competition experiments using 125I-labeled hGH yielded a linear plot with an apparent Kd of 1.08 nM and an estimated number of 7000 hGH receptors per cell. These data suggest that hGH is able to enlarge the human adipocyte precursor pool via induction of IGF-I synthesis but exhibits a direct antiadipogenic activity. hGH is also able to reduce fat cell volume by reducing lipogenesis and increasing lipolysis.

Role of the time factor in signaling specificity : application to mitogenic and metabolic signaling by the insulin and insulin-like growth factor-I receptor tyrosine kinases

The signal transduction pathways activated by hormones, growth factors, and cytokines show an extraordinary degree of cross-talk and redundancy. This review addresses the question of how the specificity conferred at the binding step is maintained through the signaling network despite the convergence of multiple signals on common efferent pathways such as mitogen-activated protein (MAP) kinase. The mechanism of receptor activation by ligand-induced dimerization provides a signaling device with both a switch and a timer. The role of the time factor, ie, of signaling kinetics, as a determinant of selectivity is discussed with emphasis on the receptor tyrosine kinases and cytokine receptors, and especially mitogenic versus metabolic signaling by insulin and insulin-like growth factor-I (IGF-I).

TIMING-DEPENDENCE OF INSULIN-RECEPTOR MITOGENIC VERSUS METABOLIC SIGNALLING : A PLAUSIBLE MODEL BASED ON COINCIDENCE OF HORMONE AND EFFECTOR BINDING

Mitogenic signalling through the insulin receptor is enhanced compared with metabolic signalling for insulin analogues having slower dissociation kinetics than insulin itself. A plausible explanation in molecular terms of this timing-dependent specificity is lacking. We show here that if signalling is transmitted through a single effector, binding coincidentally with hormone to the insulin receptor and whose association and dissociation kinetics are slow relative to the hormone dissociation rate, the resulting biological effect is predicted to be dependent on hormone-binding kinetics. However, known primary effector molecules associating with the insulin receptor bind and interact rapidly with the receptor, contrary to the assumptions of the single-effector model. A model with two effectors which must bind coincidentally with hormone for signalling to occur also gives the required dependence of signalling on hormone-binding kinetics, provided that at least one of the effectors has slow binding kinetics relative to hormone binding. In this case, the other effector can have rapid kinetics, which is consistent with the properties of the major known substrates of the insulin receptor, such as the insulin receptor substrate (IRS) molecules.

Swine basal cell proliferation during a course of daily irradiation, five days a week for six weeks (6000 RAD)☆

In swine skin irradiated with 200 rad per day, 5 days per week for 6 weeks, basal cell density remained at control levels for the first 2 weeks and then decreased to a nadir of 50% at 38 days. Thereafter it began increasing and returned to near control levels within 1 day after the end of irradiation on day forty-three. The mitotic index increased progressively to a maximum value three times the controls at day forty-two and then decreased as the cell density returned to control levels. The pattern strongly suggests that cell proliferation occurred during the period of irradiation. The cell density changes are simulated by a model in which doubling time switches from 12 days to 2.5 days at the 50% cell density level.

FIELD SIZE DEPENDENCE OF RADIATION SENSITIVITY AND DOSE FRACTIONATION RESPONSE IN SKIN

Four sets of data from the literature were analyzed to assess the effects of field size on dose tolerance and dose fraction size dependence in irradiated skin. The data consisted of combinations of total dose and dose per exposure (or number of fractions) required to yield a given degree of visible damage to the skin, for fields of different sizes. Putative cell survival curves were constructed, under the assumptions that the isoeffect represents a fixed cell survival, and that each exposure during a course of fractionated irradiation has equal effect on cell survival. The analysis showed that overall sensitivity to radiation, and dependence on dose per exposure, both increase with field size. To account for these results we describe a model that can be qualitatively related to the geometric properties of the dermal vascular network. First, vascular function after irradiation should depend on the length of the vessels exposed to the radiation. This directly predicts an increasing sensitivity in large irradiated fields. Furthermore, if vascular function determines radiation response, the shape of the shoulder (low-dose) region of the effective survival curve will depend on the average number of vessels nourishing each cell, with a more pronounced shoulder for a high multiplicity of vessels. The model predicts a greater fractionation sensitivity in large than in small fields, in agreement with our analysis of the isoeffect data. It is therefore possible that the advantages of hyperfractionation in reducing late effects in normal tissues may be related to vascular architecture, and not to inherent differences between late and acutely responding cell populations.

Lack of correlation between basal cell survival and gross response in irradiated swine skin

The relationship between basal cell survival and gross response in irradiated swine skin was tested by comparing dose survival curves derived from time-dose isoeffect data with curves obtained directly from basal cell counts in histological sections. Assuming equal effect per exposure and constant cell survival at isoeffect, best-fitting single-hit multi-target and linear-quadratic response curves were determined for time-dose schedules resulting in non-healing of 50% of irradiated fields. Basal cell survivals for single doses of 970, 1649, 2231, and 2619 rad were estimated 1) by counting regenerating islands and 2) by monitoring total basal cell counts through time. The dose survival curve derived from the isoeffect data was steeper than the curve obtained from direct basal cell counts. Furthermore, the direct basal cell survival curve extrapolates to less than 100% at zero dose, indicating the presence of a resistant basal cell subpopulation. The data show that the isoeffect in this case is not strongly coupled to basal cell survival. Rather, the probability of healing of an irradiated field is more sensitive to the dose per fraction than is basal cell survival, implying a contribution to non-healing from damage to stromal elements such as the capillary endothelium.