Cheuk Ki Fung

Tunicamycin, an antibiotic that inhibits protein glycosylation, elicited a rapid depletion of insulin binding activity at the surface of 3T3-L1 adipocytes. Disappearance of insulin receptors occurred more rapidly in the presence of tunicamycin than when protein synthesis was inhibited by cycloheximide and was accompanied by a diminution in sensitivity of the adipocytes to the acute effects of insulin and anti-insulin receptor antibody on hexose uptake and metabolism.

Exposure of insulin-responsive, differentiated 3T3-L1 cells (adipocytes) to 0.1 to 1.0 microgram/ml of insulin for 3 to 48 h resulted in a persistent state of enhanced 2-deoxy-D-glucose and 3-O-methyl-D-glucose uptake. Elevated basal transport activity was retained under conditions where 125I-insulin binding activity remained unchanged and exchangeable insulin was dissociated from cell surface receptors. The appearance of enhanced hexose transport activity was prevented by cycloheximide and could be distinguished from the activation of the glucose transport system observed in these and other cells during glucose deprivation. Rigorously washed adipocytes, exhibiting insulin-induced elevations in basal transport activity, were refractory to further stimulation by insulin during hexose uptake assays. Insulin-unresponsive 3T3-L1 preadipocytes failed to increase hexose uptake activity when treated under conditions that elicited an optimal response in adipocytes.

As determined by EPR, malic enzyme from pigeon liver binds Mn2+ with a half-site stoichiometry of two tight binding sites (KD=6 to 10 mum) per enzyme tetramer and at two to four weak binding sites (KD=0.43 to 1.34 mM). The activation of malic enzyme by Mn2+ at high levels of L-malate shows biphasic kinetics yielding two activator constants for Mn2+. The dissociation constants of Mn2+ for both classes of sites are of the same order as the kinetically determined activator constants of Mn2+, indicating active site binding at both classes of binding sites. The binding of Mn2+ to the tight sites enhances the paramagnetic effect of Mn2+ on 1/T1 of water protons by a factor (epsilon) of 17, while binding at the weak sites yields a smaller epsilon of 11. The coenzymes TPN and TPNH have no effects on epsilon, while the carboxylic acid substrates L-malate and pyruvate and the inhibitors D-malate and oxalate significantly decrease epsilon. TPNH causes a 38-fold tightening of binding of the substrate L-malate to the enzyme-Mn2+ complex, consistent with the previously described highly ordered kinetic scheme, but only a 2-fold tightening of binding of the competitive inhibitor D-malate. The dissociation constant of L-malate from the quaternary E-Mn2+-TPNH-L-malate complex (32 muM) agrees with the Km of L-malate (25 muM), indicating active site binding. The dissociation constants of pyruvate from the ternary E-Mn2+-pyruvate complex (12 mM) and from the quaternary E-Mn2+-TPN-pyruvate complex (20 mM) are similar to the Km of pyruvate (5 mM), also indicating active site binding and a less highly ordered kinetic scheme for the reactions of pyruvate than for those of L-malate. Analysis of the frequency dependence of 1/T1 of water protons indicates that two fast exchanging water ligands remain coordinated to Mn2+ in the binary E-Mn2+ complex. The binding of the substrates L-malate and pyruvate and of the transition state analog oxalate to the E-Mn2+ complex decrease the number of fast exchanging water ligands on Mn2+ by approximately 1, but the binding of D-malate has no significant effect on this parameter, indicating the occlusion or replacement of a water ligand of the enzyme-bound Mn2+ by a properly oriented substituent on C-2 of the substrate. Occlusion rather than replacement of a water ligand by pyruvate is established by studies of 1/T1 of 13COO- and 13CO-enriched pyruvate which indicate second sphere Mn2+ to pyruvate distances of 4.6 A (COO-) and 4.8 A (CO) in the ternary enzyme-Mn2+-pyruvate complex. Formation of the quaternary complex with TPN increases these distances by 0.8 A, indicating the participation of a second sphere enzyme-Mn2+-(H2O)-pyruvate complex in catalysis. Thus, malic enzyme, like five other enzymes which utilize metals to polarize carbonyl groups, forms a second sphere complex with its substrate.

OBJECTIVE: Social networks play a vital role in facilitating late-life health and well-being. The current research sought to examine the psychometric properties of the abbreviated Lubben Social Network Scale (LSNS-6) among community-dwelling Hong Kong Chinese older adults and to explore the association between social network and well-being indicators such as life satisfaction, functional social support, loneliness and anxiety. METHODS: We administered the LSNS-6 scale to 324 older adults (mean = 71.70, SD = 8.58, range: 58-95). We performed confirmatory factor analysis (CFA) to confirm the construct validity. Cronbach's alpha was chosen for internal consistency estimation. Correlational analysis was performed between LSNS-6 scale and other measures to ascertain the convergent validity. RESULTS: /df = 2.61, CFI = 0.98, RSMEA = 0.07, SRMR = 0.05. The internal consistency of the scale was α = 0.75. It also demonstrated good construct validity in measuring the social network and acceptable convergent validity to other measures. CONCLUSIONS: The LSNS-6, according to current findings, can be a valid reference to the social network of Hong Kong older adults, enabling researchers and clinicians to investigate and develop further corresponding remedies for those in need.