Disposable screen-printed chemiluminescent biochips for the simultaneous determination of four point-of-care relevant proteins.

A screen-printed (SP) microarray is presented as a platform for the achievement of multiparametric biochips. The SP platform is composed of eight (0.28-mm(2)) working electrodes modified with electroaddressed protein A-aryl diazonium adducts. The electrode surfaces are then used as an affinity immobilisation support for the orientated binding of capture monoclonal antibodies, having specificity against four different point-of-care related proteins (myoglobin, cardiac troponin I, C-reactive protein and brain natriuretic peptide). The immobilised capture antibodies are involved in sandwich assays of the four proteins together with biotinylated detection antibodies and peroxidase-labelled streptavidin in order to permit a chemiluminescent imaging of the SP platform and a sensitive detection of the assayed proteins. The performances of the system in pure buffered solutions, using a 25-min assay duration, were characterised by dynamic ranges of 0.5-50, 0.1-120, 0.2-20 and 0.67-67 microg/L for C-reactive protein, myoglobin, cardiac troponin I and brain natriuretic peptide, respectively. The four different assays were also validated in spiked 40-times-diluted human sera, using LowCross buffer, and were shown to work simultaneously in this complex medium.

Coenzyme Q, Vitamin E and Apo-E alleles in Alzheimer Disease.

Neurodegenerative Diseases represent the most common cause of Dementia, about 5-10% of the population aged above 65 years and about 30% above 80 years. A study about Apo-E alleles, Coenzyme Q and Vitamins E as biological indicators was performed in plasma samples of patients aged from 30 to 85 years, affected by Neurodegenerative Diseases. The results were compared with control subjects of approximately the same ages as the reference group. A frequency of 21.7% of epsilon4 allele in control group was estimated, against 15.8% observed in patients. The frequency of epsilon2 and epsilon3 alleles was 13.0% and 65.2% in the control group against 10.5% and 73.7% in patients. No significant differences were observed between the frequency of epsilon3/epsilon3 genotype and epsilon3/epsilon4 genotype in the control group compared to patients' group. The frequencies observed in epsilon2/epsilon3 genotype groups were 8.7% vs 15.8% and of e2/e4 genotype 17.4% vs 5.3%. The epsilon2/epsilon2 and epsilon4/epsilon4 genotypes were not identified in any groups. Plasma CoQ10 concentrations were similar in patient and control groups and no differences were found even taking into account the distribution of male and female subjects in the two groups. Also, vitamin E did not provide evidence of any differences between groups and the analysis among sexes revealed that again vitamin E concentrations were similar in between subgroups.

Fiberoptic biosensors based on chemiluminescent reactions.

The chemiluminescence of luminol in the presence of H2O2 has been exploited to develop fiberoptic biosensors associated with flow injection analysis systems. A chlorophenol sensor was developed based on the ability of certain halophenols to enhance the peroxidase-catalyzed luminol chemiluminescence. Horseradish peroxidase immobilized on a collagen membrane was used. Ten chlorophenols have been tested with this chemiluminescent-based sensor. The lower detection limit was obtained with 4-chloro-3-methylphenol and was equal to 0.01 microM. Electrochemiluminescent-based fiberoptic biosensors for glucose and lactate were also developed using glucose oxidase or lactate oxidase immobilized on polyamide membranes. In the presence of oxidase-generated H2O2, the light emission was triggered electrochemically by means of a glassy carbon electrode polarized at +425 mV vs a platinum pseudo-reference electrode. The detection limits for glucose and lactate were 150 and 60 pmol, respectively, and the dynamic ranges were linear from 150 pmol to 600 nmol and from 60 pmol to 60 nmol, respectively.

The apolipoprotein E epsilon4 allele causes a faster decline of cognitive performances in Down's syndrome subjects.

The apolipoprotein E gene (APOE), located on human chromosome 19, has three common alleles (epsilon2, epsilon3, epsilon4) which encode for the three main isoforms indicated as E2, E3 and E4 respectively. Several findings indicate epsilon4 allele as an important risk factor in both sporadic and familial late-onset Alzheimer's disease (AD). Pathological changes similar to AD are seen in almost all patients with Down's syndrome (DS) aged over 35 (senile plaques, neurofibrillary tangles and neuronal loss); a proportion of these may subsequently develop dementia. Aim of this study is to evaluate the possible pathological role of epsilon4 allele as risk factor for developing AD in a DS population. ApoE epsilon4 allele frequency is not significantly different in DS cases and controls. We found a statistically significant inverse correlation between full scale IQ values and age of patients in the subgroup of DS subjects selected for the presence of at least one epsilon4 allele, while no correlation was observed in DS subjects with other ApoE genotypes. A longitudinal analysis of cognitive performances (available in 38 patients) showed a faster rate of decline in intellectual ability in those subjects carrying at least one epsilon4 allele. Our data support the hypothesis that ApoE epsilon4 allele has a contributory role in accelerating the mental deterioration of AD-type in DS patients.

Brown's syndrome associated with Smith-Magenis syndrome: Case report.

Brown's syndrome is generally an isolated clinical condition. The authors observed a girl with a right Brown's syndrome and a rare condition due to an interstitial deletion of chromosome 17, known as Smith-Magenis syndrome. A wide spectrum of congenital disorders have been reported in Smith-Magenis syndrome, but never Brown's syndrome.

In vitro transfer of N-acetylglucosamine to endogenous glycoprotein acceptors catalyzed by the nucleus and the cytoplasmic membranes prepared from L1210 cells.

The non-nuclear membranes and the nuclei prepared from L1210 cells catalyze the in vitro transfer of N-acetyl(14C)glucosamine from UDP-N-acetyl(14C)glucosamine to endogenous glycoprotein acceptors. Adequate analysis of these acceptors have demonstrated that the nucleus has its own N-acetylglucosaminyltransferase system that leads to the formation of N-N'-diacetylchitobiosylated proteins.

In vitro transfer of N,N'-diacetylchitobiose to glycoproteins in rat liver nuclei.

This work demonstrates that (N-acetyl[14C]glucosamine)2 is transferred from dolichyl pyrophosphate-(N-acetyl[14C]glucosamine)2 to endogenous nuclear glycoproteins. The (N-acetyl[14C]glucosamine)2 moiety is N-linked, since it can be released from the tryptic glycopeptides by N-glycosidase F and by hydrazinolysis, but not by beta-elimination. The biological significance of this direct transfer of N,N'-diacetylchitobiose to nuclear proteins remains to be elucidated.

Effect of vitamin A deficiency on the in vitro transfer of mannose and N-acetylglucosamine in rat liver nuclei.

Liver nuclei, prepared from normal and vitamin A-deficient rats, were incubated in the presence of GDP-(14C)mannose or UDP-N-acetyl(14C)glucosamine and the labelled glycoproteins analysed by SDS PAGE. Fluorographic analysis has shown that (14C) mannose labelling is enhanced by vitamin A deficiency whereas N-acetyl(14C)glucosamine transfer remains approximately at the same level regardless of the vitamin A status; we did not notice any modification when the proteins were monitored by Coomassie blue or by silver nitrate.

Influence of vitamin A status and DDT on vitamin A-dependent protein mannosylation in rat liver.

Male Wistar rats of different vitamin A status (total depletion to moderate deficiency) were administered DDT (5 mg/kg/day) or vehicule (corn oil) i.p. daily for 14 days. Vitamin A-dependent protein mannosylation was measured either by in vivo incorporation of [3H]mannose into liver glycoprotein or by in vitro assay of incorporation of [14C]mannose into mannosylretinyl phosphate. Vitamin A deficiency resulted in a significantly impaired in vivo incorporation of mannose in liver glycoprotein but had no effect on the in vitro transport of mannose via retinyl phosphate. Although DDT induced an increase synthesis of liver proteins in smooth endoplasmic reticulum and caused a diminution of the hepatic vitamin A content, it did not affect vitamin A-dependent protein mannosylation.

Transfer of N-acetylglucosamine to endogenous glycoproteins in the nucleus and in non-nuclear membranes of rat hepatocytes: electrophoretic analysis of the endogenous acceptors.

The transfer of N-acetyl(14C)glucosamine from UDP-N-acetyl(14C)glucosamine to endogenous glycoproteins acceptors were studied comparatively in the nuclei and in the non-nuclear membranes of rat hepatocytes. Electrophoretic and autoradiographic analysis show that most of the glycoprotein acceptors of the nuclei differ from those of the non-nuclear membranes in terms of molecular weight. In addition, it may interesting to mention that in the nuclear fraction a 30% inhibition by tunicamycin is obtained for concentrations as low as 0.03 microM, whereas at this concentration no effect is detected in the non-nuclear membranes. In the presence of 0.2 microM tunicamycin, the inhibition does not go beyond 25% in the latter fraction but goes up to 80% in the former. The previous results demonstrate clearly that a particular glycosylation reaction occurs in the nucleus.

Presence of a cellular retinylphosphate binding protein in rat liver.

A retinylphosphate binding activity, resolved during purification, has been discovered in rat liver cytosol. The partial purification includes ammonium sulfate precipitation and DEAE-cellulose chromatography. The macromolecular component responsible for the binding has a sedimentation coefficient of about 2 S and is sensitive to pronase. This binding is reversible and specific for retinylphosphate, since retinol, retinoic acid and retinoylphosphate do not compete with [3H]retinylphosphate.

Glycoprotein mannosylation in rat liver nuclei.

Nuclei and non-nuclear membranes were tested for their ability to transfer in vitro (14C)mannose from GDP-(14C)mannose to endogenous glycoprotein acceptors in the presence and in the absence of exogenous retinyl-phosphate. Electrophoretic analysis shows that retinylphosphate is responsible for the labeling of a few endogenous acceptors only in the non-nuclear membranes; in the nuclei the mannosylation reaction is not retinylphosphate dependent and the electrophoretic profile of the labeled protein acceptors is different from that of the non-nuclear membranes.

Spatial aspects of mannosyl phosphoryl retinol formation.

Rat liver microsomes catalyze the transfer of mannose from GDPmannose to both retinyl phosphate and dolichyl phosphate to form mannosylphosphorylretinol, mannosylphosphoryldolichol and GDP. The two reactions differ in term of reversibility. In fact, a 200-fold isotopic dilution of GDP[14C]mannose by unlabeled GDPmannose causes mannosylphosphoryldolichol labeling to disappear almost completely, while mannosylphosphorylretinol labeling remains at the same level. The same observation can be made if the mannose donor is removed by centrifugation and replaced by excess GDP; again mannosylphosphorylretinol is stable, but mannosylphosphoryldolichol drops down to one-third of its initial level, as expected for, respectively, a non-reversible and a reversible reaction. Placed in an aqueous medium, mannosylphosphorylretinol releases mannose 1-phosphate (beta configuration) whereas it is quite stable when kept in a membranous environment. These results strongly suggest that mannosylphosphorylretinol as soon as it is formed is segregated in such a way that it is no longer available to the back-reaction; the functional consequence of this segregation would be the possibility for mannosylphosphorylretinol to mannosylate some non-polar regions of certain protein chains.

Purification of a UTP:D-glucose-1-phosphate uridylyltransferase from Golgi apparatus of cat liver by affinity chromatography on UTP-agarose.

UDP-glucose pyrophosphorylase from Golgi apparatus solubilized by detergent has been purified 100-fold from microsomes by affinity chromatography on UTP-agarose. The purified enzyme has apparent Mr 270,000 and isoelectric pH 3.9 against 360,000 and 4.2 for soluble enzyme. According to these characteristics, UDP-glucose pyrophosphorylase from Golgi apparatus is different from cytosolic enzyme.