To investigate the role of Asp 26 and Lys 57, two conserved, buried residues, in the redox mechanism of Escherichia coli thioredoxin (Trx), three mutant proteins, Asp 26 --> Ala (D26A), Lys 57 --> Met (K57M), and the double mutant D26A/K57M, were prepared, replacing the charged amino acids with hydrophobic residues with similar sizes. Both the oxidized (Trx-S2) and reduced [Trx-(SH)2] forms of the mutant thioredoxins are fully folded and similar in overall structure to the wild-type protein (wt). The structure of the active site hydrophobic surface is unchanged by the mutation of Asp 26 and Lys 57, since DNA polymerase activity in the 1:1 complex of the T7 gene 5 protein and mutant Trx-(SH)2 shows similar Kd values (approximately 5 nM) for both mutants and wt. In contrast, redox reactions involving thioredoxin as a catalyst of the reduction of disulfides or oxidation of dithiols are strongly affected by the mutations. In the reaction of Trx-S2 with thioredoxin reductase at pH 8.0, the kcat/Km value for the D26A mutant is decreased by a factor of 10 from that of wt, while the value for the D26A/K57M mutant is reduced 40-fold. The activity of Trx-(SH)2 as a protein disulfide reductase was measured with insulin, using fluorescence to detect oxidation of thioredoxin. At 15 degrees C and pH 8.0, both the D26A and K57M mutants showed 5--10-fold decreases in rates of reaction compared to those of the wild type, and the pH-rate profiles for the mutants were shifted 1 (K57M) and 2 (D26A) units to higher pH compared with the wt curve. NMR measurements for the three mutant proteins indicate that the proteins have the same global fold as that of the wild type, although changes in the chemical shifts of a number of resonances indicate local structural changes in the active site region. The resonances of oxidized D26A and D26A/K57M are pH-independent between pH 6.0 and 10.0, confirming the identification of the active site group titrating with a pKa of 7.5 in wt Trx-S2 as Asp 26. A profound change in the pKa of Asp 26, from 7.5 in the wild type to 9.4 in the mutant, is observed for K57M Trx-S2. The pH-dependent behavior of the resonances is affected in all mutant Trx-(SH)2 proteins. A single pKa shifted to higher values is observed on both the Cys 32 and Cys 35 Cbeta resonances. Ultraviolet absorbance measurements (A240) as a function of pH for wt Trx-(SH)2 demonstrate that the cysteine thiols titrate with apparent pK(a)s of about 7.1 and 9.9. The mutant proteins each show a single transition in the A240 measurements, with a midpoint at pH 7.8-8.0, consistent with the NMR results. The change in absorbance at 240 nm with increasing pH indicates that the number of thiols titrating in each mutant is greater than one but less than two. It is clear that both thiol pK(a)s have been significantly shifted by the mutations. The Cys 32 pKa is moved from 7.1 in wt to 7.8-8.0 in the mutants. The value of the Cys 35 pKa either is indistinguishable from that of Cys 32, thus accounting for more than one thiol titrating in the UV absorbance m...
CD. {:em)· R. liwiii!WrSiriim L, Slal11 • /. Sc'qumlialnpret\1011 oj an amelin gene in ;lle\·cnch) 'lllal and epithelial cells during odmrtogel/c. \i\ in rtlls. Eur J Oral Sci /99H; f(}fJ (suppl /): 324 330. < ur J Oral ci, 1998 'ovcl mR 1 oforms cncodmg the enamel matrix proteins amclin-1. amclm-2 and ameloblastm have been recently des(;nbed . We ha\e applied <.!<.:tailed immunohistochemical as well as non-radioactive in .1itu hybriditatwn anal)~s to I oliO\\ am lin-I expression m developing rat incisors and molar ... \\ e constructed an expression vector overproduced recombinant amchn in Ellhcrtrhia coli and prcp;tred ttn ant1bod>. In addition to the pre\iou ly reported <~mel in mR NA cxpre~~10n patterns 111 umelobla-.b. the amclin mess,tgc \HIS also detected in pulpal mesenchymal cells mcludmg preodontoblasts and young odontohla.ts. 1 he signal il1 these cells r ·rsisted until deposition or mantle dentin bccam~: evidenl. rhe immunolocalmttion of amt:lin-1 in pr l>dontobla~ts und mn~:lnblasts cssent1,tll> followed the path:rn of mR. cxpre am. 1 he most intense sta1n1n • was f'ound 111 the enamel matrix atiJ&H:cnt to crctor> amcloblasts. Focal accumtdalion~ of 1mmu1wrcact1ve material \\ere found ill the dcnt•no~:namcl JUI1Ctlon durinv th~: muturatwn tag~:. I o, usin • 5'-R I~ (Rapid Amplification of d)NA ntis) w~: could confirm only amclin-1 and amcloblu~tin mc~sage~ 1t1 the total R pool from r
Observations that amelogenins, in the form of enamel matrix derivative (EMD), have a stimulatory effect on mesenchymal cells and tissues, and on the regeneration of alveolar bone, justified investigations into the effect of EMD on bone-forming cells. The binding and uptake of EMD in primary osteoblastic cells was characterized, and the effect of EMD on osteoblast gene expression, protein secretion, and mineralization was compared with the effect of parathyroid hormone (PTH). Although no specific receptor(s) has yet been identified, EMD appeared to be taken up by osteoblasts through clathrin-coated pits via the interaction with clathrin adaptor protein complex AP-2, the major mechanism of cargo sorting into coated pits in mammalian cells. EMD had a positive effect on factors involved in mineralization in vitro, causing an increased alkaline phosphatase (ALP) activity in the medium as well an as increased expression of osteocalcin and collagen type 1. Several hundred genes are regulated by EMD in primary human osteoblasts. There appear to be similarities between the effects of EMD and PTH on human osteoblasts. The expression pattern of several mRNAs and proteins upon EMD stimulation also indicates a secondary osteoclast stimulatory effect, suggesting that the osteogenic effect of EMD in vivo, at least partly, involves stimulation of bone remodelling.
Background: Ameloblastin plays a key role in the complex biomineralization process that forms tooth enamel, the hardest tissue of the body. Results: Ameloblastin self-associates into ribbon-like supramolecular structures via a short segment encoded by exon 5. Conclusion: Ameloblastin self-association may be essential for correct structural organization and mineralization of the enamel in vivo. Significance: The results provide molecular insight into biology of tooth enamel formation.
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