Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Drug
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Target Concepts:
Gene/Protein
Disease
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Query: EC:3.2.1.23 (
beta-galactosidase
)
14,648
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The technique of affinity chromatography has been used in the partial purification of complementable fractions and complemented enzyme of
beta-galactosidase
from Escherichia coli mutant M15. The crude extract of mutant M15 was incubated with fragment CM-B. The complemented enzyme and complementable fractions were passed through a small column of p-aminophenyl-beta-D-thiogalactoside to which inhibitors had been covalently attached. A high percentage of the nonspecific protein passed directly through the affinity column while the specific enzymatic protein remained bound to the gel.
Phosphate
buffer with NaCl was used to elute the complementable fractions from the column. Sodium borate buffer was used to elute the bound complemented enzyme from the affinity support. The results of this study show that 100% of the complemented enzyme was bound to the column. The partially purified enzyme had the same position in disc gel electrophoresis as
beta-galactosidase
from E. coli.
...
PMID:Complementable fraction and complemented enzyme of mutant M15 from Escherichia coli: partial purification by affinity chromatography. 32 18
The conditions and the intestinal processes responsible for the action of lactose as a potential dietary fibre are described. The
beta-galactosidase
activity in the rat caecum and colon is influenced by dietary factors: It declines with increasing lactose concentration and it rises with increasing protein and phosphate concentration in the diet. The enzyme activity correlates negatively with the content of lactose, and positively with the content of protein and phosphate in the chymus. The products of lactose hydrolysis are degraded by microbial glycolysis in caecum and colon. The glycolytic products are mainly absorbed and energetically utilized by the macroorganism.
Phosphate
stimulates the microbial metabolism and, therefore, accelerates the consumption of the energy substrate lactose. Mathematical optimization gives the necessary composition of the diet which causes an intended microecological effect. To minimize the chymus pH (5.1 in the colon ascendens; 4.6 in the colon descendens; 4.3 in the faeces) the lactose content of the diet has to be greater than or equal to 160 mumol/g, the protein content less than or equal to 10 mg/g, and the phosphate content less than or equal to 5.5 mumol/g. The minimal pH value depends to a greater extent on variations in the supply of protein and phosphorus with the diet whereas the response to changes in lactose concentration is less noticeable.
...
PMID:[Lactose--a potential dietary fiber. The regulation of its microecologic effect in the intestinal tract. 4. Dietary fiber action of lactose: evaluation with multivariate statistical analysis]. 166 43
The lethal effects of inorganic acid on phoE+ Escherichia coli strains, grown at neutral pHo, were enhanced by chloramphenicol, apparently because some organisms acquire acid tolerance (habituate) during challenge and chloramphenicol stops this.
Phosphate
(and/or polyphosphate) present during challenge prevented killing and damage by acid to outer membranes, DNA and cellular enzymes but did not prevent acid pHo enhancing novobiocin activity. To reverse acid effects, phosphate must interact with or cross the outer membrane but need not enter the cytoplasm; it is probable that it competes with H+ (or protonated anions) for passage through the PhoE pore.
Phosphate
also prevented induction of
beta-galactosidase
in a strain with the cadA promoter fused to lacZ. Four unc mutants showed essentially normal acid sensitivity and habituation; the same was true for strains with lesions in fur, oxyR, katF, phoP, cadA and hycB. In contrast, deletion of rpoH led to slightly increased acid sensitivity for cells grown at pHo 7.0, although habituation was relatively normal.
...
PMID:PhoE porin of Escherichia coli and phosphate reversal of acid damage and killing and of acid induction of the CadA gene product. 839 10
1. By digitonin lysis of penicillin spheroplasts of Escherichia coli a particulate fraction P(1) was previously obtained that supported the sustained synthesis of alkaline phosphatase when supplied with amino acids, nucleotide triphosphates and other cofactors. This P(1) fraction, when subjected to mild ultrasonic treatment in the presence of sucrose and Mg(2+), yielded the P(1)(S) fraction, consisting of integrated particulate subcellular particles containing DNA and RNA. 2. The P(1)(S) fraction from E. coli K10 wild type (R(+) (1)R(+) (2)P(+)) grown under repressed conditions supported the immediate synthesis of alkaline phosphatase in vitro. The synthesis occurred in phases. The first was followed by a lag, and then there was a linear rapid phase that continued for at least 3hr. Actinomycin D inhibited the appearance of the second phase. It was concluded that the particles are programmed to synthesize enzyme even when prepared from repressed cells, and therefore that synthesis of the specific messenger RNA for alkaline phosphatase in vivo was not inhibited when the bacteria were grown in an excess of inorganic phosphate. 3.
Phosphate
inhibited synthesis of enzyme to the same extent with the P(1)(S) fractions of two constitutive strains as with the P(1)(S) fraction of the wild-type strain. 4. Inorganic phosphate inhibited amino acid incorporation with the P(1)(S) fraction and also inhibited enzyme synthesis in vitro. The effect on amino acid incorporation could be partially overcome by adding Mn(2+) to the incubation mixtures. However, Mn(2+) inhibited the synthesis of alkaline phosphatase. Also, inhibition of the incorporation of [(32)P]CTP into RNA was overcome by Mn(2+). The effect of phosphate on amino acid uptake was most probably due to a phosphorolysis of RNA by polynucleotide phosphorylase, also present in the P(1)(S) fraction. This phosphorolysis may be responsible for the instability of messenger RNA in vitro and in vivo. 5.
Phosphate
also specifically inhibited the formation of alkaline phosphatase, since it did not affect markedly the induced formation of
beta-galactosidase
by the same P(1)(S) fraction. The specific effect is attributed to the prevention of formation of the enzymically active dimer from precursors, a Zn(2+)-dependent reaction. It is suggested that the repression of the synthesis of alkaline phosphatase in vivo in the wild-type strain was the sum of these two effects.
...
PMID:THE BIOSYNTHESIS OF ALKALINE PHOSPHATASE WITH A PARTICULATE FRACTION OF ESCHERICHIA COLI. 1433 60
A stable and soapless latex of diethylaminoethyl-dextran-methyl methacrylate (DEAE-dextran-MMA) graft copolymer (DDMC) has been developed for nonviral gene delivery vectors that are possible to autoclave. DDMC relatively easily formed a polyion complex between DNA and DDMC by the hydrophobic force of graft poly(MMA) depending on its large positive entropy change (DeltaS). DDMC has been confirmed as having a high protection facility for DNase by DNase degradation test.Transfection activity was determined using the
beta-galactosidase
assay, and a higher value of 16 times or more was confirmed for the DDMC samples in comparison with one of the starting DEAE-dextran hydrochloride samples. The resulting DDMC, having an amphiphilic domain so as to form a polymer micelle, should become a stable latex with a hydrophilic-hydrophobic microseparated domain. The complex of DDMC and plasmid DNA may be formed on the spherical structure of the amphiphilic microseparated domain of DDMC and have a good affinity to the cell membrane. The infrared absorption spectrum shift to a high-energy direction at around 3450 cm(-1), because of the complexes between DNA and DDMC, may cause the formation of more compact structures, not only by a coulomb force between the
phosphoric acid
of DNA and the DEAE group of DEAE-dextran copolymer but also by a force from the multi-intermolecule hydrogen bond in the backbone polymer DEAE-dextran and a hydrophobic force from the graft poly(MMA) in DDMC. It is thus concluded that DNA condensation may possibly have a high transfection efficiency via DDMC. The high efficiency of this graft copolymer, which is sterilized by an autoclave, may thus make it a valuable tool for safe gene delivery.
...
PMID:Characteristics of DEAE-dextran-MMA graft copolymer as a nonviral gene carrier. 1776 39
