Multivalent cations and ligand affinity of the type 1 insulin-like growth factor receptor on P2A2-LISN muscle cells.

Mouse P2A2-LISN myoblasts are transfected cells that overexpress the human type 1 insulin-like growth factor (IGF) receptor. Because the type 1 IGF receptor is the major binding site for both IGF-I and IGF-II, this cell line is an excellent model to determine the effect of multivalent cations on ligand binding specifically to this type of receptor. Competitive binding assays were performed to characterize IGF binding and Scatchard analysis to quantify affinity (Ka). 125I-IGF-I, 125I-IGF-II, and 125I-R3-IGF-I bind only to the type 1 IGF receptor on these cells. Zn2+ increased binding of the three ligands to the type 1 IGF receptor by 17 to 35%. Cd2+ significantly increased binding of 125I-IGF-I, although by only 8%. La3+ and Cr3+ did not effect binding. Au3+ decreased IGF binding by approximately 56%. Scatchard analysis produced nonlinear concave-down plots yielding binding constants for high and low affinity sites. Zn2+ increased the strength of only the high affinity sites. Au3+ decreased the affinity of both high and low affinity sites. Zn2+ increased binding with a half-maximal effect between 40 microM and 60 microM. Half-maximal dose of Au3+ was >130 microM. Zinc, gold, and cadmium bind to similar regions within proteins (a zinc-binding motif) and only these cations were found to affect receptor binding indicating similar mechanisms of action. Thus, multivalent cations may alter IGF binding to cell surface receptors ultimately controlling growth. Physiologically this may be especially important for the growth promoting effects of Zn2+.

Multivalent cations depress ligand affinity of insulin-like growth factor-binding proteins-3 and -5 on human GM-10 fibroblast cell surfaces.

The effect of multivalent cations on [125I]-IGF binding to cell-associated IGFBPs was investigated using human fibroblasts. The major cell-associated binding site for [125I]-IGF-I is IGFBP-3 and for [125I]-IGF-II are IGFBP-3 and IGFBP-5. Lanthanum and chromium did not affect either [125I]-IGF-I or [125I]-IGF-II binding to cell-associated IGFBPs. By contrast, zinc (Zn2+), gold (Au3+), and cadmium (Cd2+) depressed binding of both ligands. Ligand binding resulted in nonlinear Scatchard plots. Assuming a pre-existent asymmetric model with high- (K[aHi]) and low- (K[aLo]) affinity sites, Zn2+ lowered both K(aHi) and K(aLo). Au3+ eliminated K(aHi). Assuming that the nonlinear plots were caused by ligand-induced negative cooperativity, Zn2+ and Cd2+ lowered both Ke and Kf (affinity of unoccupied and saturated IGFBPs, respectively). Au3+ eliminated Ke and reduced Kf. Zn2+ was active at serum levels in lowering IGF binding. Zinc, gold, and cadmium bind to similar regions within proteins (a zinc-binding motif) indicating similar mechanisms of action. A zinc-binding motif is present in the IGFBPs, but not in the IGFs. We demonstrate for the first time that the trace nutrient zinc and related multivalent cations decrease IGF binding to fibroblast-associated IGFBPs by lowering the affinity of the IGF-IGFBP interaction.

Multivalent cations depress ligand binding to cell-associated insulin-like growth factor binding protein-5 on human glioblastoma cells.

The current studies quantified the effect of the multivalent cations zinc, cadmium, lanthanum, chromium, and gold (Zn2+, Cd2+, La3+, Cr3+, and Au3+) on [125I]-insulin-like growth factor ([125I]-IGF) binding to T98G human glioblastoma cells. The major binding site for the IGFs on T98G cells is IGF binding protein-5 (IGFBP-5), as determined by affinity labeling. Competitive binding studies, using either [125I]-IGF-I or [125I]-IGF-II, indicated that La3+ and Cr3+ did not affect [125I]-IGF-I or [125I]-IGF-II binding to cell-associated IGFBP-5. Zn2+, Au3+, and Cd2+ depressed binding of both [125I]-IGF-I and [125I]-IGF-II. [125I]-IGF-I and [125I]-IGF-II binding resulted in nonlinear concave-down Scatchard plots, indicating the presence of high- and low-affinity equilibrium constant of association (Ka) sites. Assuming a preexisting asymmetric model with independent high (KaHi) and low (KaLo) sites; Zn2+, Cd2+, and Au3+ eliminated KaHi and Zn2+, and Au3+ lowered KaLo, compared with control values. The same results were found, independent of whether [125I]-IGF-I or [125I]-IGF-II was used. Similarly, assuming a ligand-induced model of negative cooperativity, all three cations eliminated the initial affinity for the high affinity sites (Ka), whereas Zn2+ and Au2+ reduced the final affinity for the low affinity sites (Kf). Dose-response studies indicated that Zn2+, Au3+, and Cd2+ depressed binding with half-maximal activities of approximately 20 microM, 14-60 microM, and 50-65 microM, respectively. Zn2+, Au3+, and Cd2+ bind to similar sites on proteins (a zinc-binding motif), indicating similar mechanisms of action. A zinc-binding motif is present within the IGFBPs but not the IGFs. We demonstrate, for the first time, that multivalent cations have the potential to modulate IGF activity by decreasing the amount of IGF bound to cell-associated IGFBP-5.

Octopine-type Ti plasmids code for a mannopine-inducible dominant-negative allele of traR, the quorum-sensing activator that regulates Ti plasmid conjugal transfer.

Conjugal transfer of Agrobacterium tumefaciens Ti plasmids is regulated by two hierarchical signalling systems. Transfer is dependent on a subset of opines produced by the plant tumours induced by the bacterium. Induction also requires an acyl-homoserine lactone signal, called AAI, that is produced by the bacteria themselves. AAI is the co-inducer for TraR, the transcriptional activator required for expression of the tra regulon. Octopine induces conjugation of the octopine-mannityl opine-type Ti plasmids by regulating the expression of traR via OccR, the octopine-dependent activator of the opine regulon. We have discovered a second traR-like gene, trlR, on the octopine-mannityl opine-type Ti plasmids pTi15955 and pTiR10. This gene is located in an operon coding for a mannopine transport system and is expressed as part of the mannityl opine regulon. Sequence analysis indicated that trlR is a frameshift allele of traR, and the resulting protein lacks the carboxy-terminal domain thought to constitute the DNA-binding region of TraR. Expression of trlR inhibited octopine-induced conjugation of pTi15955 and pTiR10 by suppressing the TraR-mediated transcription of the tra and trb operons. Although TrlR had no effect on the expression of traR, TraR activated the expression of trlR. Southern hybridizations indicated that several other Ti and opine-catabolic plasmids contain more than one copy of genes homologous to traR. We propose that trlR is a dominant negative allele of traR and that TrlR inhibits conjugation by forming inactive heteromultimers with TraR.

Evaluation of an enzyme immunoassay for detection of Neisseria gonorrhoeae in an adolescent population.

We compared a modified procedure of Gonozyme , an enzyme immunoassay for detection of gonococcal antigen in urogenital specimens, with bacterial culture for Neisseria gonorrhoeae in a hospital-based adolescent clinic. In 839 patients studied, prevalence of urogenital gonorrhea by culture was 14.3%. The sensitivity of the immunoassay was 90.0%, and the specificity was 98.1%; predictive values for a positive and a negative test result were 88.5% and 98.3%, respectively. Gonozyme was highly accurate in 57 males studied; sensitivity, specificity, and predictive values were 100%. In 782 females, sensitivity was 87.5%, specificity was 98.0%, positive predictive value was 85.7%, and negative predictive value was 98.2%. Patients with false-negative immunoassay results had lower colony counts on culture. Gonozyme is an acceptable substitute for culture in males and in females with intermediate or high prevalence of gonorrhea. Results can be available within three hours.