Characterization of recombinant E. coli ATCC 11303 (pLOI 297) in the conversion of cellulose and xylose to ethanol

This work describes the characterization of recombinant Escherichia coli ATCC 11303 (pLOI 297) in the production of ethanol from cellulose and xylose. We have examined the fermentation of glucose and xylose, both individually and in mixtures, and the selectivity of ethanol production under various conditions of operation. Xylose metabolism was strongly inhibited by the presence of glucose. Ethanol was a strong inhibitor of both glucose and xylose fermentations; the maximum ethanol levels achieved at 37 degrees C and 42 degrees C were about 50 g/l and 25 g/l respectively. Simultaneous saccharification and fermentation of cellulose with recombinant E. coli and exogenous cellulose showed a high ethanol yield (84% of theoretical) in the hydrolysis regime of pH 5.0 and 37 degrees C. The selectivity of organic acid formation relative to that of ethanol increased at extreme levels of initial glucose concentration; production of succinic and acetic acids increased at low levels of glucose (< 1 g/l), and lactic acid production increased when initial glucose was higher than 100 g/l.     

Cellulolytic activity of aerobic soil actinomycetes

The cellulolytic activity of several aerobic soil actinomycetes against insoluble cellulose and soluble cellulose derivatives (CMC-carboxymethylcellulose) was studied. From the soil, 8 actinomycete strains were isolated after enrichment growth and purification on the same synthetic medium. The actinomycete strains were able to degrade insoluble cellulose, with the production of cellobiose and various oligosaccharide intermediates as degradation products, indicating the random attack of the cellulose chain. The actinomycete strains showed also a great activity against soluble cellulose (CMC). The viscosity of CMC solutions decreased rapidly and was followed by an increase in reducing compounds. The degree of substitution of CMC solutions had an effect on the degradation by the actinomycetes. The degree of polymerization did not affect the rate of hydrolysis, however.     

Two proteins of the Dictyostelium spore coat bind to cellulose in vitro

The spore coat of Dictyostelium contains nine different proteins and cellulose. Interactions between protein and cellulose were investigated using an in vitro binding assay. Proteins extracted from coats with urea and 2-mercaptoethanol could, after removal of urea by gel filtration, efficiently bind to particles of cellulose (Avicel), but not Sephadex or Sepharose. Two proteins, SP85 and SP35, were enriched in the reconstitution, and they retained their cellulose binding activities after purification by ion exchange chromatography under denaturing conditions to suppress protein--protein interactions. Neither protein exhibited cellulase activity, though under certain conditions SP85 copurified with a cellulase activity which appeared after germination. Amino acid sequencing indicated that SP85 and SP35 are encoded by the previously described pspB and psvA genes. This was confirmed for SP85 by showing that natural M(r) polymorphisms correlated with changes in the number of tetrapeptide-encoding sequence repeats in pspB. Using PCR to reconstruct missing elements from the recombinogenic middle region of pspB, SP85 was shown to consist of three sequence domains separated by two groups of the tetrapeptide repeats. Expression of partial pspB cDNAs in Escherichia coli showed that cellulose-binding activity resided in the Cys-rich COOH-terminal domain of SP85. This cellulose-binding activity can explain SP85's ultrastructural colocalization with cellulose in vivo. Amino acid composition and antibody binding data showed that SP35 is derived from the Cys-rich N-terminal region of the previously described psvA protein. SP85 and SP35 may link other proteins to cellulose during coat assembly and germination.     

Cellulase activity of Leishmania major in the sandfly vector and in culture

The secretion of cellulose-degrading enzymes by Leishmania promastigotes in culture and in the sandfly vector was demonstrated. Two types of activity of cellulase enzyme-complexes were measured: endoglucanases, which randomly cleave cellulose chains and cellobioydrolases, which remove cellobiose from the nonreducing end of the molecule. The assays demonstrated that enzymes with these activities were secreted into the culture medium by Leishmania major, L. donovani, and L. braziliensis. These activities were also found in cultures of Sauroleishmania agamae, Leptomonas seymouri, Herpetomonas muscarum, Crithidia fasciculata and Trypanosoma brucei brucei that had a relatively low endoglucanase activity. Both endoglucanase and cellobiohydrolase activities were found in the gut of L. major-infected Phlebotomus papatasi, while gut preparations of uninfected sandflies had only cellobiohydrolase activity. The similar growth of L. major parasites in medium supplemented with either cellulose or glucose suggests these parasites can utilize cellulose.     

Evaluation of the cellulolytic capacity of Ascobolus furfuraceus (Fungi, Ascomycotina)

Growth kinetic variables (dry weight, mycelial protein, extracellular protein and pH evolution) were measured in Ascobolus furfuraceus cultures either with soluble cellulose (CMC) or crystalline cellulose as only carbon sources. When growing on CMC the mycelial protein production reached a maximum at 14 days, while the extracellular protein was maximal at 17 days. On crystalline cellulose more delay was observed (4 and 14 days, respectively). Straight lineal correspondence (r = 0.9883) was observed between the extracellular protein production and enzymatic activity kinetics, showing parallel behavior of these variables. When the biomass and extracellular protein production rates were analysed, the maxima were observed at diverse growth stages. For CMC, the dry weight production rythm precedes the cellulolytic system liberation rythm (maxima at 9 and 14 days, respectively). When crystalline cellulose was the substrate, the maximal rates were inverse, 16th day for biomass production rythm and 12th day for enzyme release rythm. On the basis of such tests and analyses, a model to explain cellulose degration by A. furfuraceus, is proposed.     

Evidence for trehalose-6-phosphate-dependent and -independent mechanisms in the control of sugar influx into yeast glycolysis

In the yeast Saccharomyces cerevisiae, trehalose-6-phosphate (tre-6-P) synthase encoded by GGS1/TPS1, is not only involved in the production of trehalose but also in restriction of sugar influx into glycolysis in an unknown fashion; it is therefore essential for growth on glucose or fructose. In this work, we have deleted the TPS2 gene encoding tre-6-P phosphatase in a strain which displays very low levels of Ggs1/TPS1, as a result of the presence of the byp 1-3 allele of GGS1/TPS1. The byp 1-3 tps2 delta double mutant showed elevated tre-6-P levels along with improved growth and ethanol production, although the estimated concentrations of glycolytic metabolites indicated excessive sugar influx. In the wild-type strain, the addition of glucose caused a rapid transient increase of tre-6-P. In tps 2 delta mutant cells, which showed a high tre-6-P level before glucose addition, sugar influx into glycolysis appeared to be diminished. Furthermore, we have confirmed that tre-6-P inhibits the hexokinases in vitro. These data are consistent with restriction of sugar influx into glycolysis through inhibition of the hexokinases by tre-6-P during the switch to fermentative metabolism. During logarithmic growth on glucose the tre-6-P level in wild-type cells was lower than that of the byp 1-3 tps2 delta mutant. However, the latter strain arrested growth and ethanol production on glucose after about four generations. Hence, other mechanisms, which also depend on Ggs1/Tps1, appear to control sugar influx during growth on glucose. In addition, we provide evidence that the requirement for Ggs1/Tps1 for sporulation may be unrelated to its involvement in trehalose metabolism or in the system controlling glycolysis.     

What is the appropriate workup and treatment for an infant with an umbilical artery catheter-related thrombosis?

We investigated the effect of inhibition of a polyol pathway on the glucose-induced increase in transforming growth factor-beta (TGF-beta) production and activity of protein kinase C (PKC) in cultured human mesangial cells (MCs). The exposure of MCs to 33 mmol/l glucose resulted in an increase in TGFbeta production, measured by ELISA, compared with 5 mmol/l glucose. The glucose-induced increase in TGF-beta was prevented by concomitant incubation with epalrestat, an aldose reductase inhibitor (ARI), in a dose-dependent manner at a concentration of more than 10(-6) mol/l. Moreover, the glucose-induced enhancement of PKC activity in the membrane fraction of MCs was also abolished by epalrestat. The addition of epalrestat to MCs cultured with 5 mmol/l glucose showed no demonstrable effects on TGF-beta production and PKC activity. These results provide direct evidence for linkages between derangements in polyol pathway and glucose-induced overproduction of TGF-beta and enhancement of PKC activity in MCs. Accordingly, the effect of an ARI on these metabolic abnormalities in MCs may justify its clinical application for treatment of diabetic nephropathy.     

Simultaneous determination of maltose and glucose using a screen-printed electrode system

A screen-printed sensor system consisting of a glucose oxidase (GOD) electrode and an amyloglucosidase/glucose oxidase (A/G) electrode was constructed to determine maltose and glucose simultaneously in a mixture. Sensor construction was optimised so that it contained 20 units of GOD/40 units of amyloglucosidase and 0.2 mM 1,1'-ferrocenedimethanol. These components were deposited onto a screen-printed carbon electrode and an outer membrane was printed from 3.5% hydroxyethyl cellulose (HEC) solution. The optimum pH was 4.8. The linear range of the system was up to 40 mM glucose or 20 mmol/L maltose with coefficients of variation (CVs) ranging from 3.5% to 5.29%. The results obtained by using the enzyme electrode system agreed well with those obtained by the Fehling titration method. When stored dry, especially at 4 degrees C, the enzyme electrodes showed good stability over four months.     

Purification, characterization, and molecular analysis of thermostable cellulases CelA and CelB from Thermotoga neapolitana

Two thermostable endocellulases, CelA and CelB, were purified from Thermotoga neapolitana. CelA (molecular mass, 29 kDa; pI 4.6) is optimally active at pH 6.0 at 95 degreesC, while CelB (molecular mass, 30 kDa; pI 4.1) has a broader optimal pH range (pH 6.0 to 6.6) at 106 degreesC. Both enzymes are characterized by a high level of activity (high Vmax value and low apparent Km value) with carboxymethyl cellulose; the specific activities of CelA and CelB are 1,219 and 1,536 U/mg, respectively. With p-nitrophenyl cellobioside the Vmax values of CelA and CelB are 69.2 and 18.4 U/mg, respectively, while the Km values are 0.97 and 0.3 mM, respectively. The major end products of cellulose hydrolysis, glucose and cellobiose, competitively inhibit CelA, and CelB. The Ki values for CelA are 0.44 M for glucose and 2.5 mM for cellobiose; the Ki values for CelB are 0.2 M for glucose and 1.16 mM for cellobiose. CelB preferentially cleaves larger cellooligomers, producing cellobiose as the end product; it also exhibits significant transglycosylation activity. This enzyme is highly thermostable and has half-lives of 130 min at 106 degreesC and 26 min at 110 degreesC. A single clone encoding the celA and celB genes was identified by screening a T. neapolitana genomic library in Escherichia coli. The celA gene encodes a 257-amino-acid protein, while celB encodes a 274-amino-acid protein. Both proteins belong to family 12 of the glycosyl hydrolases, and the two proteins are 60% similar to each other. Northern blots of T. neapolitana mRNA revealed that celA and celB are monocistronic messages, and both genes are inducible by cellobiose and are repressed by glucose.     

Characterization and phylogeny of the pfp gene of Amycolatopsis methanolica encoding PPi-dependent phosphofructokinase

The actinomycete Amycolatopsis methanolica employs a PPi-dependent phosphofructokinase (PPi-PFK) (EC 2.7.1.90) with biochemical characteristics similar to those of both ATP- and PPi-dependent enzymes during growth on glucose. A 2.3-kb PvuII fragment hybridizing to two oligonucleotides based on the amino-terminal amino acid sequence of PPi-PFK was isolated from a genomic library of A. methanolica. Nucleotide sequence analysis of this fragment revealed the presence of an open reading frame encoding a protein of 340 amino acids with a high degree of similarity to PFK proteins. Heterologous expression of this open reading frame in Escherichia coli gave rise to a unique 45-kDa protein displaying a high level of PPi-PFK activity. The open reading frame was therefore designated pfp, encoding the PPi-PFK of A. methanolica. Upstream and transcribed divergently from pfp, a partial open reading frame (aroA) similar to 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase-encoding genes was identified. The partial open reading frame (chiA) downstream from pfp was similar to chitinase genes from Streptomyces species. A phylogenetic analysis of the ATP- and PPi-dependent proteins showed that PPi-PFK enzymes are monophyletic, suggesting that the two types of PFK evolved from a common ancestor.     

Family variables in substance-misusing male adolescents: the importance of maternal disorder

Production of hydrogen by anaerobes, facultative anaerobes, aerobes, methylotrophs, and photosynthetic bacteria is possible. Anaerobic Clostridia are potential producers and immobilized C. butyricum produces 2 mol H2/mol glucose at 50% efficiency. Spontaneous production of H2 from formate and glucose by immobilized Escherichia coli showed 100% and 60% efficiencies, respectively. Enterobactericiae produces H2 at similar efficiency from different monosaccharides during growth. Among methylotrophs, methanogenes, rumen bacteria, and thermophilic archae, Ruminococcus albus, is promising (2.37 mol/mol glucose). Immobilized aerobic Bacillus licheniformis optimally produces 0.7 mol H2/mol glucose. Photosynthetic Rhodospirillum rubrum produces 4, 7, and 6 mol of H2 from acetate, succinate, and malate, respectively. Excellent productivity (6.2 mol H2/mol glucose) by co-cultures of Cellulomonas with a hydrogenase uptake (Hup) mutant of R. capsulata on cellulose was found. Cyanobacteria, viz., Anabaena, Synechococcus, and Oscillatoria sp., have been studied for photoproduction of H2. Immobilized A. cylindrica produces H2 (20 ml/g dry wt/h) continually for 1 year. Increased H2 productivity was found for Hup mutant of A. variabilis. Synechococcus sp. has a high potential for H2 production in fermentors and outdoor cultures. Simultaneous productions of oxychemicals and H2 by Klebseilla sp. and by enzymatic methods were also attempted. The fate of H2 biotechnology is presumed to be dictated by the stock of fossil fuel and state of pollution in future.     

Modifications to the ADH1 promoter of Saccharomyces cerevisiae for efficient production of heterologous proteins

The promoter of alcohol dehydrogenase I of the yeast Saccharomyces cerevisiae was studied using Bacillus amyloliquefaciens alpha-amylase as a marker protein. On glucose, activity of the original ADH1 promoter decreases during late exponential, ethanol production growth phase. When 1100 bp (from -414 bp to -1500 bp) of the upstream sequence are deleted, activity increases into the late ethanol consumption phase but the promoter becomes active only after ethanol production growth phase (Ruohonen et al. (1991) Yeast 7, 337-346). We have now restored 300 bp (from -414 bp to -700 bp) upstream of the deletion site and obtained expression from the ADH1 promoter throughout the yeast growth cycle. The restored sequence allowed alpha-amylase expression to start during early exponential growth phase indicating that it is required for activation of the ADH1 promoter during ethanol production growth phase, possibly through glucose induction. On ethanol, all the promoters were active, but the short promoter was temporally activated first, suggesting that the restored sequence is not required for promoter activity during early oxidative growth.     

Profiles of published social work practitioners: who wrote and why

Pasteurella multocida was examined for glucose and mannose transport. P. multocida was shown to possess a phosphoenolpyruvate (PEP):mannose phosphotransferase system (PTS) that transports glucose as well as mannose and was functionally similar to the Escherichia coli mannose PTS. Phosphorylated proteins with molecular masses similar to those of E. coli mannose PTS proteins were visualized when incubated with 32P-PEP. The presence of an enzyme IIAGlc which could play an important role in regulation, as described in other Gram-negative bacteria, was detected. The enzymes of the pentose-phosphate pathway were present in P. multocida growth on glucose. The activity of 6-phosphofructokinase (the key enzyme of the Embden-Meyerhof pathway (EMP)), was very low in cell extracts, suggesting that EMP is not the major pathway for glucose catabolism.     

Improvement of the production of foreign proteins using a heterologous secretion vector system in Bacillus subtilis: effects of resistance to glucose-mediated catabolite repression

To improve protein production, a heterologous secretion vector system was constructed with the aid of the amyR2 region. The operator sequence (amyO) of the amyR2 region on the secretion vector was changed through site-directed mutagenesis to eliminate carbon-source-mediated catabolite repression. Three substitutional (AG, G5, G10), one deletional (delta HH), and one insertional (AGHF) mutant promoters were obtained. The expression level and the degree of catabolite repression of amyR2 and the mutant promoters were examined with a single copy system using an integrational promoter probe vector, pDH32. Under glucose-free culture conditions, expression levels from all mutant promoters except HH were 1.4 to 1.5 fold higher than that from amyR2. While the expression of the amyR2 promoter was repressed by 90% in the presence of 2% glucose, expression levels of the mutant promoters were repressed by only 1% to 50%. To evaluate the advantage of the mutant promoters in production of foreign proteins by the heterologous secretion system, beta-lactamase and human pancreatic secretory trypsin inhibitor (hPSTI) were expressed by the mutant promoters. When B. subtilis LKS87 was used as a host strain, the production of the target proteins using the respective mutant promoter was increased by about 1.5 fold under glucose-free culture conditions. Under the high glucose culture conditions, secretion of target proteins produced from the mutant promoters increased 1.5 to 2 fold, whereas those by the amyR2 promoter were reduced to between 50% and 60%. The additive effect of degUh mutation on protein production was not observed under high glucose culture conditions. In addition, such culture conditions inhibited proteolytic degradation of secreted target proteins after the stationary growth phase even in B. subtilis LKS88 (degUh mutant). Thus, our results indicated that the mutant promoters, which are resistant to glucose-mediated catabolite repression, are very useful for over-production of foreign proteins under the high glucose culture conditions using the heterologous expression-secretion system in B. subtilis.     

Interactions between Fibrobacter succinogenes, Prevotella ruminicola, and Ruminococcus flavefaciens in the digestion of cellulose from forages

The synergistic and inhibitory interactions observed between Fibrobacter succinogenes A3c, Prevotella ruminicola H2b, and Ruminococcus flavefaciens B34b in the digestion of forage cellulose were studied in detail. Orchardgrass and alfalfa hays, both at two maturity stages, were used as substrates. Sequential inoculation procedures were developed whereby a second inoculation was made after the initial fermentation was killed. Total cellulose digestion from sequential addition of the organisms was then compared to values obtained in simultaneous co-culture. When the noncellulolytic P. ruminicola was co-cultured with either of the two cellulolytic species (F. succinogenes or R. flavefaciens) forage cellulose digestion numerically increased over that of the cellulolytic species alone. In contrast, decreases from co-culture values were noted with sequential addition of the organisms. When F. succinogenes and R. flavefaciens were co-cultured, cellulose digestion was reduced compared to F. succinogenes alone. However, no such reduction was observed when the organisms were added sequentially. Further experiments indicated that this inhibitory activity is only produced when the organisms are co-cultured and is stable to autoclaving at 121 degrees C for 20 min. Inhibition of this type could be the result of bacterocin production by one of the organisms; however, most bacterocins are destroyed by autoclaving.     

Immunoglobulin heavy chain junctional diversity in young and aged humans

The important role of hyperglycemia in the genesis of diabetic renal disease has been strengthened by tissue culture studies, experimental animal models, and clinical trials. A mechanistic understanding of the cellular and biochemical processes that link hyperglycemia with the development of diabetic nephropathy is indispensable for directing the most optimal therapeutic interventions. Likely mediators of the effects of high ambient glucose include activation of the polyol pathway, increased protein kinase C activity, nonenzymatic glycation of circulating or matrix proteins, and/or aberrant synthesis or actions of cytokines and vasomodulatory agents. The latter include angiotensin II, thromboxane, platelet-derived growth factor, endothelins, insulin-like growth factor-1, and transforming growth factor-beta. The studies we review here argue strongly in support of the hypothesis that elevated production and/or activity of transforming growth factor-beta in the kidney is a final common mediator of diabetic renal hypertrophy and mesangial matrix expansion.     

Composition and functional analysis of the Saccharomyces cerevisiae trehalose synthase complex

In the yeast Saccharomyces cerevisiae, trehalose-6-phosphate synthase (TPS) and trehalose-6-phosphate phosphatase (TPP), which convert glucose 6-phosphate plus UDP-glucose to trehalose, are part of the trehalose synthase complex. In addition to the TPS1 (previously also called GGS1, CIF1, BYP1, FDP1, GLC6, and TSS1) and TPS2 (also described as HOG2 and PFK3) gene products, this complex also contains a regulatory subunit encoded by TSL1. We have constructed a set of isogenic strains carrying all possible combinations of deletions of these three genes and of TPS3, a homologue of TSL1 identified by systematic sequencing. Deletion of TPS1 totally abolished TPS activity and measurable trehalose, whereas deletion of any of the other genes in most cases reduced both. Similarly, deletion of TPS2 completely abolished TPP activity, and deletion of any of the other genes resulted in a reduction of this activity. Therefore, it appears that all subunits are required for optimal enzymatic activity. Since we observed measurable trehalose in strains lacking all but the TPS1 gene, some phosphatase activity in addition to Tps2 can hydrolyze trehalose 6-phosphate. Deletion of TPS3, in particular in a tsl1Delta background, reduced both TPS and TPP activities and trehalose content. Deletion of TPS2, TSL1, or TPS3 and, in particular, of TSL1 plus TPS3 destabilized the trehalose synthase complex. We conclude that Tps3 is a fourth subunit of the complex with functions partially redundant to those of Tsl1. Among the four genes studied, TPS1 is necessary and sufficient for growth on glucose and fructose. Even when overproduced, none of the other subunits could take over this function of Tps1 despite the homology shared by all four proteins. A portion of Tps1 appears to occur in a form not bound by the complex. Whereas TPS activity in the complex is inhibited by Pi, Pi stimulates the monomeric form of Tps1. We discuss the possible role of differentially regulated Tps1 in a complex-bound or monomeric form in light of the requirement of Tps1 for trehalose production and for growth on glucose and fructose.     

Origin of endocrine-metabolic changes in the weanling rat ventromedial syndrome

Destruction of the ventromedial hypothalamic nuclei (VMN) in the weanling rat without injury to the median eminence results in a series of somatic, endocrine, and metabolic changes that are characterized by normal food and water intake but decreased linear growth, normal body weight but increased carcass fat and reduced carcass protein, lean body mass, and water. The endocrine alterations comprise hyperinsulinemia in the face of normoglycemia, hypertriglyceridemia and hypercholesterolemia and reduced growth hormone levels. The metabolic changes include greater oxidation of glucose and incorporation into lipid and reduced palmitate oxidation but increased incorporation into lipid. Weanling rats with VMN lesions are normophagic in absolute terms, relative to body weight and per metabolic unit, but their nocturnal feeding and weight gain cycles are disrupted and their locomotor activity is reduced. The VMN are involved in the long-term control of feeding - as in the mature rat - as shown by intragastric preloading studies and dietary density manipulation, glucose preference tests and intraperitoneal injections with glucose. Hyperinsulinemia and hypertriglyceridemia are present four days after the VMN operation in the presence of subnormal food intake and plasma glucose levels. Manipulations of the fat content of the diet revealed that the hyperlipidemia is of both endogenous and exogenous origin and that lipoprotein lipase is increased; a 48-hour fast reduced the hyperlipidemia to control levels, however. This suggests that weanling VMN rat tissue may have an impaired ability to take up circulating lipid. An increased incorporation of glycerol into lipid may be due to induction of glycerokinase by hyperinsulinemia. Adipose tissue of weanling VMN rats showed glycerokinase by hyperinsulinemia. Adipose tissue of weanling VMN rats showed neither depressed lipolysis nor diminished lipolytic activity per milligram of tissue protein. Glucose oxidation and incorporation into adipose tissue is increased in several tissues in vitro and there is enhanced glucose disappearance from plasma and incorporation into tissue lipids in vivo. These changes develop within a short time after lesion production and persist at least partially up to six months: glucose utilization in liver increases already four hours after the operation whereas it takes 72 hours to commence in adipose tissue. Insulin resistance is not apparent either in vivo or in vitro. The decreased growth hormone levels are not critical to the metabolic changes, nor is the hyperinsulinemia totally necessary. The metabolic changes also appear on several different types of diet and persist with fasting. The latter does not reduce insulin sensitivity of VMN rat tissues, wheras it does so in normal rats. Mature rats developed the same metabolic changes even in the absence of hyperphagia. The metabolic alterations can be blocked by pharmacologic doses of glucocorticoids, but are enhanced by the administration of estrogen...     

Internal quality assurance activities of a surgical pathology department in an Australian teaching hospital

Parotid and mandibular saliva was obtained from red kangaroos by concurrent acetylcholine isoprenaline stimulation. Salivary proteins were separated by horizontal electrophoresis on either cellulose acetate or starch gels and assessed by specific staining techniques for 23 enzymes commonly found in mammalian tissues and body fluids. Parotid saliva was positive for acid phosphatase, alpha-amylase, carbonic anhydrase, glucose-6-phosphate dehydrogenase, sorbitol dehydrogenase and superoxide dismutase activities. Mandibular saliva was positive for alcohol dehydrogenase in addition to the above six enzymes. The kangaroo salivas lacked activity for alkaline phosphatase, beta-galactosidase and non-specific esterase which occur in saliva from some mammalian species.