IGF-I and IGF-II are essential regulators of mammalian growth, development and metabolism, whose actions are modified by six high-affinity IGF binding proteins (IGFBPs). New lines of knockout (KO) mice lacking either IGFBP-3, -4, or -5 had no apparent deficiencies in growth or metabolism beyond a modest growth impairment (approximately 85-90% of wild type) when IGFBP-4 was eliminated. To continue to address the roles of these proteins in whole animal physiology, we generated combinational IGFBP KO mice. Mice homozygous for targeted defects in IGFBP-3, -4, and -5 remain viable and at birth were the same size as IGFBP-4 KO mice. Unlike IGFBP-4 KO mice, however, the triple KO mice became significantly smaller by adulthood (78% wild type) and had significant reductions in fat pad accumulation (P < 0.05), circulating levels of total IGF-I (45% of wild type; P < 0.05) and IGF-I bioactivity (37% of wild type; P < 0.05). Metabolically, triple KO mice showed normal insulin tolerance, but a 37% expansion (P < 0.05) of beta-cell number and significantly increased insulin secretion after glucose challenge, which leads to enhanced glucose disposal. Finally, triple KO mice demonstrated a tissue-specific decline in activation of the Erk signaling pathway as well as weight of the quadriceps muscle. Taken together, these data provide direct evidence for combinatorial effects of IGFBP-3, -4, and -5 in both metabolism and at least some soft tissues and strongly suggest overlapping roles for IGFBP-3 and -5 in maintaining IGF-I-mediated postnatal growth in mice.
Therapeutic pegylated interferon-␣s (IFN-␣) are mixtures of positional isomers that have been monopegylated at specific sites on the core IFN-␣ molecule. The pegylation results in lower in vitro specific activity associated with the core IFN-␣ molecule that is related to the site of pegylation and size of polyethylene glycol (PEG) attached. We prepared purified, homogeneous, positional pegylation isomers of IFN-␣2b that were monopegylated using 5-30-kDa linear PEG molecules attached at 7 primary reactive amino acid residues: Chronic hepatitis C is considered one of the major causes of chronic liver disease, cirrhosis, and hepatocellular carcinoma and is the most common reason for liver transplantation in the United States (1). It is estimated that there are 3 million chronically infected individuals in the United States and over 170 million worldwide (1). Treatment of hepatitis C has evolved from the use of interferon-␣ (IFN-␣), 1 either alone or in combination with ribavirin, to the newer pegylated interferons (PEGIFNs), which have provided a dramatic increase in virological response, especially in combination with ribavirin. Standard IFN-␣ therapy has a short (Ͻ12-h) half-life that requires subcutaneous injection three times weekly to maintain effective levels in the blood (2). The short half-life of IFN-␣ has led to the development of longer lasting preparations achieved by the attachment of a large polyethylene glycol (PEG) molecule directly to IFN-␣. Two different commercial preparations of PEG-IFN-␣ have been developed for clinical use, PEG-IFN-␣2b (PEG-INTRON®) and PEG-IFN-␣2a (Pegasys®); both have long half-lives (40 and 80 h, respectively) that permit once weekly administration (3). Both of these preparations have been demonstrated to be effective for the treatment of patients with hepatitis C (4), and clinical trial results have shown further that both of the pegylated molecules produce sustained viral response rates superior to those achieved with their respective standard IFN-␣s (5-7).Whereas pegylation has proven to be highly effective for slowing the clearance of biological molecules, including IFN-␣, and thus increasing serum half-life, it has been shown to also modify in vitro biological activity (8). For instance, we have reported that pegylation of IFN-␣2b with a 12-kDa linear PEG molecule results in a preparation that has a specific activity of 28% relative to IFN-␣2b; the loss in activity was not due to structural perturbation of the core IFN-␣2b core protein (9). Other groups have reported that pegylation of IFN-␣2a with a 40-kDa branched PEG molecule results in a preparation that contains from 1 to 7% relative specific activity compared with IFN-␣2a (10, 11). These two pegylated interferon-␣s (PEG-IFN␣s) differ substantially in their postpegylation constituent properties. PEG-IFN-␣2b has a 12-kDa linear PEG molecule attached using succinimidyl carbonate polyethylene glycol (SC-PEG) chemistry via a covalent urethane-like bond to the IFN␣2b protein (12). The pegylation linkage process results...
Dopamine systems are intimately involved with opioid actions. Pharmacological studies suggest an important modulatory effect of dopamine and its receptors on opioid analgesia. We have now examined these interactions in a knock-out model in which the dopamine(2) (D(2)) receptor has been disrupted. Loss of D(2) receptors enhances, in a dose-dependent manner, the analgesic actions of the mu analgesic morphine, the kappa(1) agonist U50,488H and the kappa(3) analgesic naloxone benzoylhydrazone. The responses to the delta opioid analgesic [d-Pen(2),d-Pen(5)]enkephalin were unaffected in the knock-out animals. Loss of D(2) receptors also potentiated spinal orphanin FQ/nociceptin analgesia. Antisense studies using a probe targeting the D(2) receptor revealed results similar to those observed in the knock-out model. The modulatory actions of D(2) receptors were independent of final sigma receptor systems because the final sigma agonist (+)-pentazocine lowered opioid analgesia in all mice, including the D(2) knock-out group. Thus, dopamine D(2) receptors represent an additional, significant modulatory system that inhibits analgesic responses to mu and kappa opioids.
Newborn rat astroglia cells possess epidermal growth factor (EGF) and insulin-like growth factor (IGF) receptors, which suggests that these growth factors regulate their growth and development. To determine the relative roles and interactions between the two growth factors on astroglial growth, primary cultures of astroglial cells from newborn rats (1 day postnatal) were treated with pure peptides, singly or in combination in various concentrations, and the growth response was determined by DNA synthesis ([3H]thymidine incorporation). EGF, IGF-I, and IGF-II, as single peptides, stimulated DNA synthesis, with half-maximal stimulatory concentrations of 0.25 ng/ml for EGF, 2.0 ng/ml for IGF-I, and 25 ng/ml for IGF-II, respectively. These findings indicate that astroglial cells are responsive to these growth factors in physiological concentrations, with the relative sensitivity of EGF greater than IGF greater than IGF-II. When EGF and IGF-I were added in combination, the growth stimulatory effect was greater than the additive effects of each growth factor added alone, indicating that the two growth factors act in synergism with each other. In particular, addition of increasing concentrations of EGF from 0.25-10 ng/ml to a constant concentration of 50 ng/ml IGF-I resulted in significant potentiation of [3H]thymidine incorporation of astroglial cells. To determine if the synergistic effect was due to a local synthesis of IGF-I by astroglia, a specific monoclonal antibody against IGF-I (Sm 1.2) was added to the peptides. Sm 1.2 decreased not only IGF-I-stimulated DNA synthesis, but also EGF-stimulated DNA synthesis, suggesting that the effects of EGF were contributed to in part by the local synthesis of IGF-I by astroglial cells. Analysis of conditioned medium from cells treated with EGF revealed a significant increase (approximately 2-fold) in IGF-I (from 4.5 to 8.8 ng/ml), but not IGF-II. To determine if the EGF effect on IGF synthesis was at the level of IGF-I mRNA transcription, stable IGF-I mRNA levels were determined in the astroglial cells before and after stimulation with EGF, using Northern analysis and quantification by densitometry. Astroglia expressed four IGF-I mRNA transcripts as in the adult and fetal liver, but only one (3.6 kilobases) IGF-II mRNA.(ABSTRACT TRUNCATED AT 400 WORDS)
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