Use of large pieces of printed circuit boards for bioleaching to avoid 'precipitate contamination problem' and to simplify overall metal recovery.

Very recently bioleaching has been used for removing metals from electronic waste. Most of the research has been targeted to using pulverized PCBs for bioleaching where precipitate formed during bioleaching contaminates the pulverized PCB sample and making the overall metal recovery process more complicated. In addition to that, such mixing of pulverized sample with precipitate also creates problems for the final separation of non metallic fraction of PCB sample. In the present investigation we attempted the use of large pieces of printed circuit boards instead of pulverized sample for removal of metals. Use of large pieces of PCBs for bioleaching was restricted due to the chemical coating present on PCBs, the problem has been solved by chemical treatment of PCBs prior to bioleaching. In short,•Large pieces of PCB can be used for bioleaching instead of pulverized PCB sample.•Metallic portion on PCBs can be made accessible to bacteria with prior chemical treatment of PCBs.•Complete metal removal obtained on PCB pieces of size 4 cm × 2.5 cm with the exception of solder traces. The final metal free PCBs (non metallic) can be easily recycled and in this way the overall recycling process (metallic and non metallic part) of PCBs becomes simple.

A 16-amino acid peptide from human alpha2-macroglobulin binds transforming growth factor-beta and platelet-derived growth factor-BB.

Alpha2-macroglobulin (alpha2M) is a major carrier of transforming growth factor-beta (TGF-beta) in vitro and in vivo. By screening glutathione S-transferase (GST) fusion proteins with overlapping sequences, we localized the TGFbeta-binding site to aa 700-738 of the mature human alpha2M subunit. In separate experiments, we screened overlapping synthetic peptides corresponding to aa 696-777 of alpha2M and identified a single 16-mer (718-733) that binds TGF-beta1. Platelet-derived growth factor-BB (PDGF-BB) bound to the same peptide, even though TGF-beta and PDGF-BB share almost no sequence identity. The sequence of the growth factor-binding peptide, WDLVVVNSAGVAEVGV, included a high proportion of hydrophobic amino acids. The analogous peptide from murinoglobulin, a human alpha2M homologue that does not bind growth factors, contained only three nonconservative amino acid substitutions; however, the MUG peptide failed to bind TGF-beta1 and PDGF-BB. These results demonstrate that a distinct and highly-restricted site in alpha2M, positioned near the C-terminal flank of the bait region, mediates growth factor binding. At least part of the growth factor-binding site is encoded by exon 18 of the alpha2M gene, which is notable for a 5' splice site polymorphism that has been implicated in Alzheimer's Disease.

Urokinase-type plasminogen activator stimulates the Ras/Extracellular signal-regulated kinase (ERK) signaling pathway and MCF-7 cell migration by a mechanism that requires focal adhesion kinase, Src, and Shc. Rapid dissociation of GRB2/Sps-Shc complex is associated with the transient phosphorylation of ERK in urokinase-treated cells.

Urokinase-type plasminogen activator (uPA) stimulates MCF-7 cell migration by binding to the UPA receptor and activating the Ras-extracellular signal-regulated kinase (Ras-ERK) signaling pathway. Studies presented here show that soluble uPA receptor and a peptide derived from the linker region between domains 1 and 2 of the uPA receptor also stimulate cellular migration via a mitogen-activated protein kinase/ERK kinase (MEK)-dependent pathway. Signaling proteins that function upstream of Ras in uPA- stimulated cells remain undefined. To address this problem, we transfected MCF-7 cells to express the noncatalytic carboxylterminal domain of focal adhesion kinase (FAK), FAK(Y397F), kinase-defective c-Src, or Shc FFF, all of which express dominant-negative activity. In each case, ERK phosphorylation and cellular migration in response to uPA were blocked. Both activities were rescued by co-transfecting the cells to express constitutively active MEK1, indicating that FAK, c-Src, and Shc are upstream of MEK. Shc was tyrosine-phosphorylated in uPA-treated cells. The level of phosphorylated Shc was increased within 1 min and remained increased for at least 30 min. Sos co-immunoprecipitated with Shc in cells that were treated with uPA for 1-2.5 min, probably reflecting the formation of Shc-Grb2/Sos complex; however, by 10 min, co-immunoprecipitation of Sos with Shc was no longer observed. Rapid dissociation of Sos from Shc represents a possible mechanism for the transient phosphorylation of ERK in uPA-treated MCF-7 cells.