Enzymes of galactose metabolism in livers of suckling and adult tammar wallabies (Macropus eugenii) and other marsupials

The activities of galactokinase, hexose-1-phosphate uridylyl transferase and UDPglucose 4-epimerase in homogenates of livers of two adult and 20 suckling tammar wallabies aged from 6 to 50 weeks were investigated. The activities of all three enzymes were high until 24-30 weeks post partum, after which they declined to low levels. The activities of the three liver enzymes were high in pouch young of six other species of marsupial. Comparison of the activities of the three liver enzymes in suckling tammar wallabies with those in suckling rats showed no difference between the two species in regard to galactokinase and uridylyl transferase, but the UDPglucose 4-epimerase activity in tammar wallabies was approximately double than found in rats. This may be related to the high galactose content of tammar wallaby milk compared with rat milk. In suckling tammar wallabies, the liver had higher enzyme activities than other tissues studied. It is concluded that, contrary to the suggestion of Stephens et al. (1975), pouch young marsupials are not deficient in their ability to metabolize galactose.     

Enzymes of galactose utilization in the rat tapeworm, Hymenolepis diminuta.

1. Crude enzyme preparations from Hymenolepis diminuta contained galactokinase, galactose 1-phosphate uridyl transferase and UDPgalactose 4-epimerase activity, although their specific activities were low. 2. Galactose 1-phosphate non-competitively inhibited galactose phosphorylation. This inhibition, together with the low specific activities of the enzymes in the pathway of galactose utilization, probably accounts for the inadequacy of galactose as a main nutritive carbohydrate for development of the worm.     

Characteristics of galactokinase and galactose-1-phosphate uridyltransferase in cultivated fibroblasts and amniotic fluid cells

Summary The kinetic characteristics of galactose-1-phosphate uridyltransferase and galactokinase in cultivated fibroblasts and amniotic fluid cells were investigated. The K _m values of galactokinase for galactose at 2.0 mM ATP are 0.34 mM in amniotic fluid cells and 0.48 mM in fibroblasts. The K _m values for ATP at 0.5 mM galactose are 1.25 mM and 2.10 mM.Transferase and galactokinase activities and protein content increase logarithmically during the growth of cultivated cells. The specific activity of both enzymes also increases and reaches a maximum level 10–15 days after subculture. The specific activity of transferase increases faster than that of galactokinase in the case of amniotic fluid cells. In the case of fibroblasts the specific activity of galactokinase increases faster than that of transferase.     

Organization and nucleotide sequence of the Streptococcus mutans galactose operon

The galactose operon encoding a repressor and genes for the Leloir pathway for galactose metabolism (galactokinase, galactose-1-phosphate-uridyl transferase and UDP glucose-4-epimerase) was located adjacent to the multiple sugar metabolism (msm) operon on the chromosome of Streptococcus mutans Ingbritt (serotype c) and the complete nucleotide sequence of this 5-kilobase region was determined. The Leloir pathway was induced by the presence of galactose in the growth medium or following the release of intracellular galactose after uptake and cleavage of -galactosides by the multiple sugar metabolism system. Analysis of the mechanism of galactose transport confirmed the absence of a galactose-specific phosphotransferase system and suggested the presence of an inducible galactose permease. Evidence is presented that galactose transport is independent of the proton motive force and may be ATP-dependent.     

Comparative studies of galactokinase activity on mammal's red blood cells.

1. ATP: D-galactose-1-phosphotransferase activity was measured in human, pig, cow, rabbit, mouse and rat red blood cells. Mean values of galactokinase activity was markedly lower in the human and pig erythrocyte as compared to those of the other species. 2. The permeability to galactose of the red cells studied was always higher than galactose phosphorylation. 3. The affinity constants of galactokinase for galactose ranged from 119 to 291 microM and from 178 to 406 microM for ATPMg2-. 4. The thermostability values of the galactokinase of the species studied were similar. The pH-optimum is pH 7.5 for the human, mouse and rabbit enzyme and pH 8.0 for cow, pig and rat galactokinase.     

Selection of Galactose-Fermenting Streptococcus thermophilus in Lactose-Limited Chemostat Cultures

Stock cultures of Streptococcus thermophilus are essentially galactose negative (Gal). Although both galactose 1-phosphate uridyl transferase and uridine-5-diphospho-glucose 4-epimerase are present, suggesting that the genes for the Leloir pathway exist, cells cannot induce high levels of galactokinase. Therefore, galactose is largely excreted when cultures are grown on lactose, and most strains cannot be readily adapted to grow on free galactose. Gal cultures were grown in a chemostat under lactose limitation in which high concentrations of residual galactose were present. Under this selection pressure, Gal organisms eventually took over the culture with all four strains examined. Gal cells had induced galactokinase, and three of the four strains grew on free galactose with doubling times of 40 to 50 min. When Gal organisms were grown on lactose in batch culture, the galactose moiety was only partially utilized while lactose was still present. As lactose was exhausted, and catabolite repression was lifted, the Leloir pathway enzymes (especially galactokinase) were induced and the residual galactose fermented. Neither phospho-beta-galactosidase activity nor the enzymes of the d-tagatose 6-phosphate pathway were detected in S. thermophilus. In contrast to Streptococcus cremoris and Streptococcus lactis, fermentation was homolactic with galactose in batch cultures and with lactose limitation in the chemostat. When mixed Gal-Gal cultures were repeatedly transferred in milk, the Gal cells became the dominant cell type. The Gal phenotype of stock cultures probably reflects their prolonged maintenance in milk.     

DNA-dependent in vitro synthesis of enzymes of the galactose operon of Escherichia coli

Summary Two active enzymes of the galactose operon of Escherichia coli, uridyl transferase and galactokinase have been synthesized with high yields in a DNA dependent system for protein synthesis. The unspecific blank values amount to less than two percent of the rate obtained under optimal conditions and permit the accurate determination of even a small fraction of the maximum synthesis rate. Therefore this system provides a sensitive assay for the biological activity of DNA that contains the intact galactose operon of Escherichia coli.The synthesis of these galactose enzymes is to a high extent dependent on the presence of cyclic adenosine-3:5-monophosphate.D-fucose, known as an inducer of the galactose operon in vivo, stimulates the synthesis of galactokinase, indicating that the repressor of the galactose operon in active under these conditions. This stimulation is not observed, if the bacterial extract is prepared from a strain defective for the galactose repressor or if the DNA carries an operator constitutive mutation in the galactose operon. Therefore the stimulation by D-fucose is true derepression.     

Cloning and expression of Clostridium pasteurianum galactokinase gene in Escherichia coli K-12 and nucleotide sequence analysis of a region affecting the amount of the enzyme

The Clostridium pasteurianum galactokinase gene was cloned by complementation, of the galK locus, into Escherichia coli. Restriction enzyme analysis subcloning and Tn5 mutagenesis indicated that the gene was located on a 1.8 X 10(3) base-pair ClaI-Sau3A fragment that encoded a polypeptide of approximately 40 Mr. Although the C. pasteurianum and the E. coli galactokinases have similar subunit molecular weights, Southern hybridization analysis indicated no strong homology between their genes. Even though this clone showed a low level of galactokinase expression, the Gal+ phenotype, provided by the clostridial galactokinase, was unstable in E. coli, and the gene was frequently inactivated by the spontaneous acquisition of insertion sequences. A second clone containing this gene on a large restriction fragment was isolated by hybridization. This clone was unable to grow on galactose-containing media due to the overproduction of galactokinase. Comparison of the plasmids from these two clones revealed that the second contained an additional 300 base-pairs located at one end of the galactokinase gene. Appropriate operon fusions with a promoter-less E. coli galactokinase gene indicated that these additional 300 base-pairs had promoter activity in E. coli. The DNA sequence of this region which lies upstream of the C. pasteurianum galactokinase gene was determined and compared with that from several clones producing high, low or undetectable amounts of galactokinase. The reasons for the high and low level expression and for the instability of the C. pasteurianum galactokinase in E. coli are discussed. The presence of the galactokinase suggests that galactose is used in C. pasteurianum through the Leloir pathway via galactose 1-phosphate.     

Reduction in the number of young during pouch-life in a small marsupial

The honey possum Tarsipes rostratus , a shrew-sized marsupial endemic to south-western Australia, feeds exclusively upon nectar and pollen. Tarsipes has fewer pouch-young, which remain in the pouch longer, than the young of sympatric insect-feeding marsupials of comparable size. Tarsipes pouch-young were recorded in every month of the year. Of all adult females caught, 68% had pouch-young and 36% of the remainder had recently carried young. This continual reproduction is offset by an average lifespan of only about one year.
Although Tarsipes have four teats, only very few of the largest females reared four young to independence. The number of pouch-young was inversely related to their size, changing, on average, from 3.6 young immediately after birth to 2.4 young at pouch-exit. Larger females gave birth to larger litters than smaller females and appeared more successful in rearing them. Variation in the initial litter size, and any subsequent reduction in litter size, might allow females to optimize offspring production during their short lifetime in relation to an unpredictable and specialized food supply.     

Galactose and glucose metabolism in galactokinase deficient, galactose-1-P-uridyl transferase deficient and normal human fibroblasts.

Despite the genetic interruption of the Leloir pathway both galactosemic patients and galactosemic fibroblasts can convert galactose to CO2 and TCA precipitable products, although at less than the normal rate. These observations stimulated investigations into the identity of the alternative metabolic routes which allows for galactose metabolism in the absence of in vitro galactose-1-P-uridyl transferase. Four lines of galactosemic cells, each without detectable gal-transferase, produced 14CO2 from [1-14C]-galactose (0.094 mumoles in 20 cc of medium) at approximately 39% +/- 16% the rate of transferase positive cells over a 48-hour period. However, galactokinase deficient fibroblasts produced 14CO2 and TCA precipitable products from [1-14C]-galactose or [U-14C]-galactose at only 3% to 9% the rate of normal fibroblasts. Therefore it seems likely that gal-transferase deficient fibroblasts must first synthesize galactose-1-P for further metabolism of galactose.     

The occurrence of the Leloir pathway in non-pathogenic mycobacteria

It has been found that saprophytic strains of mycobacteria can utilize D-galactose via the Leloir pathway which involves galactokinase, galactose-1-phosphate uridyl transferase and UDP-galactose-4-epimerase. The resulted glucose-1-phosphate is further converted by phosphoglucomutase to glucose-6-phosphate and the latter catabolized in glycolitic cycle to pyruvate. The particular enzymes of the galactose pathway have been fully separated by chromatography on a DEAE-cellulose column and some of them partially characterized.     

Studies on the regulation of the three enzymes of the leloir pathway in cultured mammalian cells. I. Effect of substitution of galactose for glucose as the sole hexose in the medium in human diploid cell strains and in a rat hepatoma line

In human diploid cell strains, the substitution of galactose for glucose as the sole hexose in the medium had no measurable effect on the specific activity of the cell protein for any of the three enzymes of the Leloir pathway. These enzymes are galactokinase, α-D-galactose-1-phosphate:UDP glucose uridylyl transferase and UDP galactose 4-epimerase. A cell strain from a patient with galactosemia had no detectable activity for the transferase. The substitution of galactose for glucose in the medium of these cells (which has been shown to cause the cells to accumulate galactose-1-phosphate) also failed to affect cellular activity for the three enzymes. Similarly, the three activities failed to respond to the substitution of galactose for glucose in cultures of a rat hepatoma line. Cells of this line have been shown by others to perform a number of the tissue-specific functions of liver. The failure of galactose to stimulate increased cellular activity for the three enzymes represents a striking difference between the behavior of these enzymes in human diploid cell strains and their behavior in E. coli.     

Cloning of the galactokinase gene (galK) from Streptomyces coelicolor A3(2)

Streptomyces coelicolor A3(2) and Streptomyces lividans 66 strains were shown to be sensitive to the galactose analogue 2-deoxy-D-galactose. Spontaneous resistant mutants were isolated that were Gal- and lacked the enzyme galactokinase. The galK gene (structural gene for galactokinase) from S. coelicolor was cloned into S. lividans using the low copy number vector pIJ922. The resulting plasmid (pMT650), which contained a 14 kb insert, complemented gal mutations in both species. The presence of the galK gene on a 2.8 kb EcoRI fragment was confirmed by expressing it in Escherichia coli where it complemented a well characterized galK mutation.     

Hexose metabolism in pancreatic islets. — Galactose transport,phosphorylation and oxidation

Summary In rat pancreatic islets, the apparent space of distribution of galactose is not different from that of other hexoses. In homogenates of islets or tumoral insulin-producing cells, galactose is phosphorylated at a very low rate relative to either glucose phosphorylation in the same tissues or galactose phosphorylation by liver homogenates. In intact islets, galactose increases modestly the glucose 6-phosphate content and is oxidized at a much lower rate than glucose. Galactose slightly increases insulin output in the presence of a stimulatory concentration of glucose but fails to provoke insulin release in the absence of glucose, whether in islets removed from rats fed a normal or galactose-rich diet. The low rate of galactose oxidation and its poor insulinotropic capacity appear attributable to the weak activity of galactokinase in pancreatic islets.     

Mutant of Escherichia coli exhibiting a cold-sensitive phenotype for growth on lactose

As part of a study on the effect of low temperature on cellular regulatory processes, a class of lactose-negative mutants of Escherichia coli K-12 was isolated which could use lactose as a sole carbon and energy source at 37 C, but which could not use this sugar at 20 C. The lactose operon of the mutants functioned normally at 20 C. Galactose exhibited a strong inhibitory effect on growth, especially at 20 C. Growth of the mutants on glycerol was stopped at 20 C and slowed considerably at 37 C if galactose was added to the medium. Making the mutants galactose-positive eliminated the cold sensitivity of lactose utilization. One mutant was shown to be galactose-1-phosphate uridyl transferase-negative, galactose-kinase heat-sensitive, and uridine diphosphate-galactose-4-epimerase-positive. It is postulated that the mutant is able to phosphorylate galactose at 20 C (if only at a very low rate), but lacking transferase it is poisoned by the accumulation of galactose-1-phosphate. At 37 C, galactokinase is nonfunctional and the mutant grows on the glucose moiety of lactose.     

A galactokinase of Mycobacterium sp. 279 galactose mutant

A galactokinase and the other enzymes of a galactose catabolic pathway were found in Mycobacterium sp. 279 galactose mutant. The galactokinase was partially purified in a procedure involving ammonium sulfate precipitation, Sephadex G-100 filtration and DEAE-cellulose chromatography. The enzyme was 170-fold purified with 25% of recovery. It was most active at pH 7.8-8.0 in the presence of Mg2+, CO2+, Mn2+ or Fe2+ ions. The molecular weight of the enzyme as determined by Sephadex G-100 filtration amounted to 41,700. The apparent Michaelis constants for galactose and ATP in spectrophotometric test were 1.0 mM and 0.29 mM, respectively. Mercuric compounds at concentration of 0.4 mM completely blocked the enzyme. The galactokinase was quite stable during storage at moderatory temperatures and neutral pH but underwent rapid inactivation on heating above 50 degrees C.     

Galactokinase Mutants of Chinese Hamster Somatic Cells Resistant to 2-Deoxygalactose

The growth of Chinese hamster somatic cells was inhibited by 0.2 mg/cc of 2-deoxygalactose. Mutants partially or fully resistant to 2-deoxygalactose were isolated in a single-step or two-step selection. Some of them did not grow as well as the wild type; one of them which lacked galactokinase(EC.2.7.1.6) activity did not grow at all in galactose medium. The galactokinase kinetic properties (Vmax & kmax of the other mutants and of the wild type were different. Therefore resistance resulted either from the possible absence of galactokinase synthesis or from a structural mutation, possible a missence mutation, in the galactokinase gene.- A simple diagnostic test for juvenile cataract is proposed.     

Cloning and expression of the yeast galactokinase gene in an Escherichia coli plasmid.

This report describes the construction and isolation of a plasmid, derived from pBR322, which carries a BglII restriction fragment of DNA containing the galactokinase gene from Saccharomyces cerevisiae. This was accomplished by the following procedure: (1) Purified galactokinase mRNA, labelled with 125I, was hybridized to BglII digests of yeast DNA employing Southern's filter transfer technique to identify a restriction fragment containing the galactokinase gene. (2) This fragment was partially purified by agarose gel electrophoresis, ligated into the BamHI site of pBR322 and transformed into Escherichia coli to generate a clone bank containing the galactokinase gene. (3) This bank was screened by in situ colony hybridization with galactokinase mRNA resulting in the identification of a plasmid carrying this gene. This plasmid DNA hybridized with the galactokinase mRNA to the same extent in the presence of absence of a large excess of unlabelled mRNA from cells that were not induced for galactokinase synthesis, while the same amount of unlabelled galactose-induced mRNA reduced the hybridization by 95%. When this plasmid was introduced into an E. coli strain deleted for the galactose operon it caused the synthesis of low levels of yeast galactokinase activity.     

Selection and analysis of galactose metabolic pathway variants of a mouse liver cell line.

To study the genetic expression and regulation of galactose-metabolizing enzymes, we mutagenized the mouse liver H2.35 cell line and selected for cell clones resistant to the toxic galactose analog, 2-deoxy-D-galactose (2-DOG). One cloned line, designated H12.10, was stably resistant to high levels of 2-DOG and was completely deficient in galactokinase activity. Galactokinase activity and growth sensitivity to 2-DOG could be restored by transfecting H12.10 cells with a plasmid containing the Escherichia coli galactokinase (galK) gene fused to a eucaryotic promoter; thus, the 2-DOG selection could be directed against transfected recombinant constructs in a liver cell line. We also found that H2.35 cells could not utilize galactose as a primary carbon source because of a deficiency in galactose-1-phosphate uridyltransferase; a variant line of H2.35 cells selected in galactose medium expressed higher levels of uridyltransferase activity. Finally, we found that in all mammalian cell lines tested, galactokinase expression was the same whether the medium contained glucose, galactose, or both sugars. These studies demonstrate differences between mammalian cells and yeast cells in the regulation of gal enzymes, and they define different schemes for obtaining altered expression of genes in the galactose metabolic pathway. The isogenic liver cell lines described here can also serve as model systems for studying galactosemias, which are inherited disorders of galactose metabolism in humans.     

Purification and properties of galactokinase from pig liver

1. Galactokinase has been purified from the liver of young pigs by high-speed centrifugation, chromatography on Sephadex G-100 and DEAE-cellulose, and ammonium sulphate fractionation. 2. The enzyme preparation has a specific activity of 10-18mumoles of galactose phosphorylated/mg. of protein/min. at 37 degrees and has been purified 400-fold from the liver supernatant. 3. Purified liver galactokinase has Michaelis constants of 1x10(-4)-3x10(-4)m for galactose and 2x10(-4)m for ATP-Mg(2+), and the enzyme reaction produces equimolar amounts of galactose 1-phosphate and ADP. 4. Galactokinase phosphorylates 2-deoxygalactose and galactosamine in addition to galactose, has a pH optimum of 7.8, a Q(10) of 2, and is stimulated by cysteine and other thiols. 5. With the exception of substrate specificity, the properties of liver galactokinase are similar to galactokinase purified from yeast and Escherichia coli.