Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0271276 (Hudson)
 1,066 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The noncollagenous (NC1) domain hexamer of glomerular basement membrane (GBM) collagen is composed of a multiplicity of monomeric and dimeric subunits, and specific subunits are the targets for anti-GBM autoantibodies of patients with Goodpasture (GP) syndrome. The identity of GBM monomers has been established and the alpha 3(IV)NC1 monomer identified as the one that binds GP antibodies (Gunwar, S., Saus, J., Noelken, M. E., and Hudson, B. G. (1990) J. Biol. Chem. 265, 5466-5469). In the present study, the chain origin of 25 dimeric components and the identity of those that bound the anti-GBM antibodies from two GP patients were determined. This was accomplished by NH2-terminal sequence analysis and immunoblotting analysis of dimeric components that were resolved by two-dimensional electrophoresis in combination with high pressure liquid chromatography. The results revealed that (a) the components are mainly homodimers of the NC1 domains of alpha 1, alpha 2, alpha 3, alpha 4, and probably alpha 5 chains of collagen IV, reflecting a specificity of promoter-promoter association and (b) each homodimer had several size and charge isoforms. The GP antibodies bound exclusively to both alpha 3(IV)NC1 monomers and dimers and not to other basement membrane constituents. These findings provided new insights about the structure of GBM collagen and together with our previous findings firmly established the alpha 3(IV) chain as the target for the anti-GBM antibodies that mediate glomerulonephritis and pulmonary hemorrhage in patients with Goodpasture syndrome.
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PMID:Glomerular basement membrane. Identification of dimeric subunits of the noncollagenous domain (hexamer) of collagen IV and the Goodpasture antigen. 186 55

In the present study, the utilization of dilute CaCl2 extraction and free metal ion activity was tested for its ability to predict urease activity in soils that was measured by a simple and rapid urease assay. Two soil series (an Arkport sandy loam and a Hudson silty clay loam) were spiked with Cu and Zn, both singly and in combination, and then field aged for over a year prior to use. For both the metal-spiked Arkport and Hudson soils, much of the inhibition in measured urease activity was explained by increased CaCl2-extractable Cu, with a lesser effect from increased Zn extractability. A positive but weak interaction between Cu and Zn suggested by regression analysis indicates the toxicity of Cu-Zn mixtures to soil urease is slightly less than additive (antagonistic). Copper extractability using CaCl2 was able to predict urease activity in only one of the tested soils. By contrast, measurements of Cu2+ activity were predictive of reduced urease activity in both soils (R2adj = 0.726, p < 0.0001), indicating that Cu2+ activity is a more useful predictor of urease inhibition in soils than CaCl2-extractable Cu. The present study also highlighted the importance that clay mineral content had on controlling the availability of added metals in soils over time since a greater aging effect on Cu toxicity was found for the fine-textured Hudson than the coarse-textured Arkport soil.
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PMID:Urease activity in aged copper and zinc-spiked soils: relationship to CaCl2-extractable metals and Cu2+ activity. 1869 75

A field pot experiment was conducted to investigate the interactive phytotoxicity of soil Cu and Zn on soybean plants [Glycine max (L.) Merr.]. Two soils (Arkport sandy loam [coarse-loamy, mixed, active, mesic Lamellic Hapludalf] and Hudson silty clay loam [fine, illitic, mesic Glossaquic Hapludalf]) spiked with Cu, Zn, and combinations of both to reach the final soil metal range of 0 to 400 mg kg(-1) were tested in a 2-yr bioassay after 1 yr of soil-metal equilibration in the field. The soluble and easily-extractable fraction of soil Zn (or Cu), estimated by dilute CaCl2, increased linearly in response to the total Zn (or Cu) added. This linearity was, however, strongly affected where soils were treated with both metals in combination, most notably for Zn, as approximately 50% more of soil Zn was extracted into solution when the Cu level was high. Consequently, added Zn is less likely to be stabilized by aging than added Cu when both metals are present in field soils. The predictive model relating soil metal extractability to plant Zn concentration also revealed a significant Cu-Zn interaction. By contrast, the interaction between the two metals contributed little to explain plant Cu uptake. The additive action of soil Cu and Zn was of considerable importance in explaining plant biomass reduction. This work clearly demonstrates the critical roles of the properties of the soil, the nature of the metal, and the level of other toxic metals present on the development of differential phytotoxicity due to soil Cu and Zn.
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PMID:Phytotoxic effects of Cu and Zn on soybeans grown in field-aged soils: their additive and interactive actions. 1987 81