Hyperinduction of enzymes of the phosphorylative pathway of glucose dissimilation inPseudomonas cepacia

Glucose-dehydrogenase-deficient (Gcd^–) strains ofPseudomonas cepacia 249 compensated for loss of operation of the direct oxidative pathway by expanding the phosphorylative pathway. When grown on glucose, they had between two- and fourfold higher than normal levels of glucokinase and NAD-linked glucose-6-phosphate dehydrogenase activity and a comparable increase in capacity to transport glucose. Similar expansion of the phosphorylative pathway was noted when the wild type was grown on cellobiose or trehalose. Gcd^– strains grew normally on cellobiose and trehalose, but not if also deficient in glucokinase; this indicates that the disaccharides were converted to glucose and metabolized via the phosphorylative pathway. The expansion of the phosphorylative pathway during growth of the wild type on disaccharides or of Gcd^– mutants on glucose was a consequence of hyperinduction of pathway enzymes. Other compounds that promoted such hyperinduction included aromatic conjugates of glucose such as arbutin and salicin, and mannose. Under conditions leading to expansion of the phosphorylative pathway, enzymes related to the direct oxidative pathway, such as gluconate dehydrogenase and the 6-phosphogluconate dehydrogenase active with NAD, were not formed. The results indicate that intracellular glucose and extracellular glucose are metabolized to 6-phosphogluconate via different routes.     

Enzymes related to galactose utilization inPseudomonas cepacia

Pseudomonas cepacia produced a characteristic green sheen on EMB-galactose plates owing to production of galactonic acid by the constitutive membrane-associated glucose dehydrogenase of this bacterium. Mutants isolated as glucose dehydrogenase deficient (Gcd^–) also were deficient in membrane-associated galactose dehydrogenase. A strain that formed glucose dehydrogenase at 30°C but not at 40°C was also temperature sensitive with respect to formation of galactose dehydrogenase. The Gcd^– strains still utilized galactose. A second, NAD-specific, galactose dehydrogenase (not membrane associated) along with a transport system for galactose were induced during growth on galactose and constituted an alternative pathway of conversion of galactose to galactonate. Enzymes of the De Ley-Doudoroff pathway of conversion of galactonate to pyruvate and glyceraldehyde-3-phosphate were induced during growth on galactose. Unexpectedly, growth on galactose also elicited formation of enzymes of the Entner-Doudoroff (ED) route. Furthermore, mutants blocked in the ED pathway grew poorly on galactose. One interpretation of these findings is that glyceraldehyde-3-phosphate formed from galactose via the De Ley-Doudoroff route (by cleavage of 2-keto-3-deoxy-6-phosphogalaconate) is reconverted to hexose phosphate and metabolized via the ED pathway.     

Microcosm method to assess survival of recombinant bacteria associated with plants and herbivorous insects

A microcosm method was developed to investigate survial and fate of genetically engineered bacteria associated with plant surfaces and a plant-feeding insect, the variegated cutworm,Peridroma saucia. Larvae on radish plants in microcosms were sprayed with nonrecombinantPseudomonas cepacia and a recombinant strain ofP. cepacia carrying the transmissible plasmid R388::Tn1721. Leaf, whole insect, foregut, and frass samples were periodically assayed over a 48-h period to enumerate total bacteria andP. cepacia strains. Immediately after spraying,P. cepacia comprised about 20%–30% of the total population on leaves, which was 2×10⁷ cfu/g of leaf. Approximately 4×10⁷ total cfu were recovered from each gram of whole insect, when theP. cepacia strains averaged about 3×10⁵ cfu/g. After 2 days, the total epiphytic population had increased approximately fourfold, while theP. cepacia strains had decreased to 2%–30% of their initial numbers. After 24 and 48 h, eachP. cepacia strain numbered between 10⁴ and 10⁵ cfu/g of insect in foregut samples, whereas none was detectable in frass. Plasmid transfer fromP. cepacia R388::Tn1721 to the nonrecombinant recipientP. cepacia strain was not observed.     

Diffusion in immobilized-cell agar layers: influence of microbial burden and cell morphology on the diffusion coefficients ofl-malic acid and glucose

Summary The diffusivities ofl-malic acid and glucose in an agar membrane entrapping small amounts ofEscherichia coli orRhodospirillum rubrum whole cells were measured using time lag (TL) and steady state (SS) methods. Diffusivities were overestimated by the SS method. For concentrations of immobilizedR. rubrum cells ranging between 10⁴ and 10⁹ organisms cm^–3 agar (20 ng-2 mg dry weight cm^–3 agar), the diffusion coefficient ofl-malic acid, determined by both methods, was related to the logarithm of the membrane cell content by a decreasing linear relationship. The diffusion coefficient of glucose obtained by TL analysis was not significantly affected by the presence in the membrane of 3 ng-0.3 mg dry wt.E. coli cm^–3 agar. However, values arising from the SS method decreased linearly as a function of the amount of immobilized organisms. Membranes containingR. rubrum cells offered higher diffusional resistance tol-malic acid and glucose than those loaded with the same amount ofE. coli cells.     

The effect of<Emphasis Type="Italic"> pfl</Emphasis> gene knockout on the metabolism for optically pure <Emphasis Type="SmallCaps">d</Emphasis>-lactate production by<Emphasis Type="Italic"> Escherichia coli</Emphasis>

The effect of gene knockout on metabolism in the pflA^–, pflB^–, pflC^–, and pflD^– mutants of Escherichia coli was investigated. Batch cultivations of the pfl ^– mutants and their parent strain were conducted using glucose as a carbon source. It was found that pflA^– and pflB^– mutants, but not pflC^– and pflD^– mutants, produced large amounts of d-lactate from glucose under the microaerobic condition, and the maximum yield was 73%. In order to investigate the metabolic regulation mechanism, we measured enzyme activities for the following eight enzymes: glucose 6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, glyceraldehyde 3-phosphate dehydrogenase (GAPDH), pyruvate kinase, lactate dehydrogenase (LDH), phosphoenolpyruvate carboxylase, acetate kinase, and alcohol dehydrogenase. Intracellular metabolite concentrations of glucose 6-phosphate, fructose 1,6-bisphosphate, phosphoenolpyruvate, pyruvate, acetyl coenzyme A as well as ATP, ADP, AMP, NADH, and NAD⁺ were also measured. It was shown that the GAPDH and LDH activities were considerably higher in pflA^– and pflB^– mutants, which implies coupling between NADH production and consumption between the two corresponding reactions. The urgent energy requirement was shown by the lower ATP/AMP level due to both oxygen limitation and pfl gene knockout, which promoted significant stepping-up of glycolysis when using glucose as a carbon source. It was shown that the demand for energy is more important than intracellular redox balance, thus excess NADH produced through GAPDH resulted in a significantly higher intracellular NADH/NAD⁺ ratio in pfl ^– mutants. Consequently, the homolactate production was achieved to meet the requirements of the redox balance and the energy production through glycolysis. The effect of using different carbon sources such as gluconate, pyruvate, fructose, and glycerol was investigated.     

ATP Production after ultraviolet irradiation inEscherichia coli

Doses of ultraviolet (UV) irradiation up to 40 Jm^–2 produce a continuous increase of both the level and the rate of ATP production in a RecA⁺ strain ofEscherichia coli growing in AB minimal medium with glucose as carbon source. At fluences higher than 40 Jm^–2, these two parameters increase at a constant rate independent of the dose. Furthermore, in the UV-irradiatedrecA13 mutant, the concentration of ATP is higher and its rate of production is faster than in the RecA⁺ strain. The same behavior as cited above was shown by both RecA⁺ and RecA^– cells when incubated in AB minimal medium without any carbon source both 60 min before and after UV irradiation.     

Electrophoretic analysis of newly synthesized and stored maternal RNA during oogenesis ofCalliphora erythrocephala (Dipt.)

Summary Ovaries ofC. erythrocephala synthesize large amounts of poly(A)⁺ and poly(A)^– RNA during early and middle stages of oogenesis as shown by labelling with³H-uridine in vivo. After incubation for 1 h, a striking difference in the electrophoretic pattern of newly synthesized labelled poly(A)⁺ RNA and the poly(A)⁺ RNA present in sufficient amounts for optical density measurements (steady state poly(A)⁺ RNA) was observed. During early and mid-oogenesis, in the poly(A)^– RNA fraction, 4S predominantly mature rRNA, 5S RNA and tRNA were labelled. These fractions were no longer synthesized during late oogenesis, whereas poly(A)⁺ RNA was labelled continously During oogenesis stage specific differences in the size distribution of newly synthesized and steady state poly(A)⁺ RNA were not obvious. However, different sizes of labelled poly(A)⁺ RNA species were detected in 0–2h old preblastoderm embryos, after injection of³H-uridine into females either 3–4 days (stage 3–4 of oogenesis) or 24 h before oviposition (stage 5–6 of oogenesis). This difference in RNA synthesis was related to the presence of active nurse cell nuclei. The poly(A)⁺ RNA fraction represents about 2–3% of the total RNA in both ovaries and freshly laid eggs as judged by measurements of optical density and radioactivity bound to oligo(dT). The length of poly(A)-segments in ovarian poly(A)⁺ RNA varied from about 30 to 200 nucleotides.     

Biosynthesis of Novel Exopolymers by Aureobasidium pullulans

Aureobasidium pullulans ATCC 42023 was cultured under aerobic conditions with glucose, mannose, and glucose analogs as energy sources. The exopolymer extracts produced under these conditions were composed of glucose and mannose. The molar ratio of glucose to mannose in the exopolymer extract and the molecular weight of the exopolymer varied depending on the energy source and culture time. The glucose content of exopolymer extracts formed with glucose and mannose as the carbon sources was between 91 and 87%. The molecular weight decreased from 3.5 × 10⁶ to 2.12 × 10⁶ to 0.85 × 10⁶ to 0.77 × 10⁶ with culture time. As the culture time increased, the glucose content of the exopolymer extract formed with glucosamine decreased from 55 ± 3 to 29 ± 2 mol%, and the molecular weight increased from 2.73 × 10⁶ to 4.86 × 10⁶. There was no evidence that glucosamine was directly incorporated into exopolymers. The molar ratios of glucose to mannose in exopolymer extracts ranged from 87 ± 3:13 ± 3 to 28 ± 2:72 ± 2 and were affected by the energy source added. On the basis of the results of an enzyme hydrolysis analysis of the exopolymer extracts and the compositional changes observed, mannose (a repeating unit) was substituted for glucose, which gave rise to a new family of exopolymer analogs.     

Untersuchungen zum Glukose-Effekt bei der Synthese der Galaktose-Enzyme vonEscherichia coli

Summary Two mutants, L1 and L2, showing a three to eight-fold decreased sensitivity to glucose for the synthesis of galactose-enzymes have been isolated fromE. coli K 12 strainsW 8 (=W 3110) andHfrH 3000 respectively. Their growth rate on glucose is the same as that of wild type and the synthesis of two unrelated enzymes, d-serin-deaminase and tryptophanase, shows the usual sensitivity to glucose.The mutations are located in thelac-i gene (the strains arei ^–) as shown by transduction mapping with phagesPlkc and dg, by examination of otheri ^–-strains and by isolation ofi ⁺-revertants. Comparable resistance to glucose can be obtained inlac i ⁺ o ⁺-orlac i ⁺ o ^c-strains by preinduction oflac-enzymes with IPTG. The essential factor for the increased resistance to glucose is the presence of a fully induced, active TMG-permease I, which is determined by they-gene in thelac-operon. TMG-permease I takes up — when present in large amounts — galactose and overcomes the effect of glucose of lowering the intracellular galactose concentration.On the basis of these results and the findings of other authors, a model is proposed according to which the glucose effect is composed of two parts based on separate mechanisms. The major part can be explained by the effect of glucose on the concentration of inducer in the cells, the other part may involve special catabolite repressors as proposed byMagasanik (1961).     

Poly-3-hydroxybutyrate (P3HB) production by bacteria from xylose,glucose and sugarcane bagasse hydrolysate

Fifty-five bacterial strains isolated from soil were screened for efficient poly-3-hydroxybutyrate (P3HB) biosynthesis from xylose. Three strains were also evaluated for the utilization of bagasse hydrolysate after different detoxification steps. The results showed that activated charcoal treatment is pivotal to the production of a hydrolysate easy to assimilate. Burkholderia cepacia IPT 048 and B. sacchari IPT 101 were selected for bioreactor studies, in which higher polymer contents and yields from the carbon source were observed with bagasse hydrolysate, compared with the use of analytical grade carbon sources. Polymer contents and yields, respectively, reached 62% and 0.39 g g^–1 with strain IPT 101 and 53% and 0.29 g g^–1 with strain IPT 048. A higher polymer content and yield from the carbon source was observed under P limitation, compared with N limitation, for strain IPT 101. IPT 048 showed similar performances in the presence of either growth-limiting nutrient. In high-cell-density cultures using xylose plus glucose under P limitation, both strains reached about 60 g l^–1 dry biomass, containing 60% P3HB. Polymer productivity and yield from this carbon source reached 0.47 g l^–1 h^–1 and 0.22 g g^–1, respectively.     

Correlation between localized anodic areas and Oceanospirillum biofilms on copper

The marine bacterium Oceanospirillum produces copious amounts of exopolymer when grown on copper surfaces and binds Cu⁺² from the substratum. The organism and associated exopolymers result in local anodic regions that can be detected by scanning vibrating electrode microscopy. Oceanospirillum was grown in small laminar flow cells with two carbon sources on copper and 316 stainless steel as substrata. The chemical composition of the exopolymer varied with growth medium, but not with substratum. Exopolymers from cells grown in glutamic acid medium on both substrata contained glucose with no other sugar monomers or uronic acids. The quantity of exopolymer did vary with substratum and copper promoted greater polymer production that stainless steel.     

Application of percoll density gradients in studies of the adhesion ofStreptococcus pyogenes to human epithelial cells

A new assay was used to study the adhesion ofStreptococcus pyogenes strains to epithelial cells. [³H]thymidine-labeled bacteria were incubated with standardized preparations of epithelial cells collected from oral-pharyngeal surfaces of human volunteers. The mixtures were then centrifuged in 50% Percoll to form a density gradient. Epithelial cells with attached bacteria formed a band near the top of the tube, whereas unattached bacteria were located near the bottom. The epithelial cells were collected on membrane filters, and the number of adherent bacteria was then determined by scintillation counting.The abilities of M-protein-positive (M⁺) and M-protein-negative (M^–) strains ofS. pyogenes to attach to human pharyngeal, buccal, and tongue epithelial cells were compared. The results obtained confirmed the significant difference previously shown to exist between the attachment of M⁺ and M^– strains to human epithelial cells. M⁺ strains ofS. pyogenes exhibited a much greater ability to bind to pharyngeal epithelial cells than did M^– variants. Also, M⁺ strains were bound in higher numbers to pharyngeal epithelial cells than to buccal or tongue epithelial cells. The adhesion ofS. pyogenes strains to epithelial cells was time dependent, and a significant increase in the adhesion of M⁺ strains occurred after 3–4 h of exposure of the bacteria to epithelial cells.The adsorption ofS. pyogenes strains to epithelial cells was described by a Langmuir isotherm. With this model, the number of binding sites and the affinities of the streptococci for epithelial cells were estimated. Significantly higher numbers of binding sites were calculated to be present on pharyngeal epithelial cells for M⁺ strains ofS. pyogenes than on buccal cells. However, the affinity of the organisms was similar for both types of cells.Adsorption of M⁺ strains to human pharyngeal epithelial cells was inhibited by certain galactosides and fucose, but not by glucose or xylose. This suggests that saccharide moities play a role in the binding of M⁺ strains ofS. pyogenes to human pharyngeal epithelial cells.     

Ethanol production by immobilized whole cells ofZymomonas mobilis in a continuous flow expanded bed bioreactor and a continuous flow stirred tank bioreactor

Continuous ethanol fermentation by immobilized whole cells ofZymomonas mobilis was investigated in an expanded bed bioreactor and in a continuous stirred tank reactor at glucose concentrations of 100, 150 and 200 g L^–1. The effect of different dilution rates on ethanol production by immobilized whole cells ofZymomonas mobilis was studied in both reactors. The maximum ethanol productivity attained was 21 g L^–1 h^–1 at a dilution rate of 0.36 h^–1 with 150 g glucose L^–1 in the continuous expanded bed bioreactor. The conversion of glucose to ethanol was independent of the glucose concentration in both reactors.     

Properties ofPseudomonas aeruginosa exhibiting self-lysis

Spontaneous lysis leading to the production of turbid, iridescent auto-plaques (AP⁺) was noted in 46 out of 50 strains ofPseudomonas aeruginosa. Strain Pa-1 which is mucoid and is a non-auto-plaque former (M⁺AP^–) on rare occasions lyses; the surviving cells are non-mucoid and always exhibited plaques on itself (M^–AP⁺) as well as on the M⁺AP^– culture. In addition, the non-mucoid culture gave rise to a mucoid, auto-plaque producing variant (M⁺AP⁺). Biochemical characterization of the cultures indicated no other qualitative differences, although AP⁺ cultures were more proteolytic, but less hemolytic than the M⁺AP^– strain. All three cultures synthesized the bacteriocin pyocin, but were immune to both their own and each other's agents. In addition, they exhibited the same lysogenic host range when streaked against 18 other cultures ofP. aeruginosa. Treatment of the auto-plaque forming strains with non-inhibitory levels of penicillin, streptomycin, chloromycetin, or polymyxin, stimulated cultures to produce increased numbers of auto-plaques in proportion to antibiotic concentrations, while no lysis was noted with the non-autolytic strain (M⁺AP^–). However, treatment of the three cultures with varying doses of ultra-violet did not stimulate the production of auto-plaques beyond the normal level of non-irradiated cultures, and in some cases suppressed their appearance. Filtrates obtained from the non-mucoid, auto-plaque producing culture (M^–AP⁺) formed iridescent, turbid plaques on M⁺AP^–, M⁺AP⁺, and M^–AP⁺. Similar results were obtained with the M⁺AP⁺ filtrates.     

Glucose oxidase and catalase activities ofPenicillium variabile P16 immobilized in polyurethane sponge

Conidia ofPenicillium variabile P16 were immobilized in polyurethane sponge and used in repeated-batch processes in a fluidized-bed reactor. Optimal conditions for production of glucose oxidase and catalase were: inoculum size, 10%; glucose concentration, 80 g L^–1; Ca-carbonate concentration, 15 g L^–1; temperature, 28°C and aeration rate, 4 VV^–1 min^–1. In an extended repeated-batch process, glucose oxidase activity was highest after the fourth batch and catalase activity was highest after the fifth batch. Scanning electron microscopy showed that the fungus grew only in the interior of carrier particles.     

A direct comparison of approaches for increasing carbon flow to aromatic biosynthesis inEscherichia coli

Different approaches to increasing carbon commitment to aromatic amino acid biosynthesis were compared in isogenic strains ofEscherichia coli. In a strain having a wild-type PEP: glucose phosphotransferase (PTS) system, inactivation of the genes encoding pyruvate kinase (pykA andpykF) resulted in a 3.4-fold increase in carbon flow to aromatic biosynthesis. In a strain already having increased carbon flow to aromatics by virtue of overexpression of thetktA gene (encoding transketolase), thepykA and/orpykF mutations had no effect. A PTS glucose⁺ mutant showed a 1.6-fold increase in carbon flow to aromatics compared to the PTS⁺ control strain. In the PTS^– glucose⁺ host background, overexpression oftktA caused a further 3.7-fold increase in carbon flow, while inactivation ofpykA andpykF caused a 5.8-fold increase. When all of the variables tested (PTS^– glucose⁺,pykA, pykF, and overexpressedtktA) were combined in a single strain, a 19.9-fold increase in carbon commitment to aromatic biosynthesis was achieved.     

Proton conductance through phospholipid bilayers: Water wires or weak acids?

The proton/hydroxide (H⁺/OH^–) permeability of phospholipid bilayer membranes at neutral pH is at least five orders of magnitude higher than the alkali or halide ion permeability, but the mechanism(s) of H⁺/OH^– transport are unknown. This review describes the characteristics of H⁺/OH^– permeability and conductance through several types of planar phospholipid bilayer membranes. At pH7, the H⁺/OH^– conductances (G _H/OH) range from 2–6 nS cm^–2, corresponding to net H⁺/OH^– permeabilities of (0.4–1.7)×10^–5 cm sec^–1. Inhibitors ofG _H/OH include serum albumin, phloretin, glycerol, and low pH. Enhancers ofG _H/OH include chlorodecane, fatty acids, gramicidin, and voltages >80 mV. Water permeability andG _H/OH are not correlated. The characteristics ofG _H/OH in fatty acid (weak acid) containing membranes are qualitatively similar to the controls in at least eight different respects. The characteristics ofG _H/OH in gramicidin (water wire) containing membranes are qualitatively different from the controls in at least four different respects. Thus, the simplest explanation for the data is thatG _H/OH in unmodified bilayers is due primarily to weakly acidic contaminants which act as proton carriers at physiological pH. However, at low pH or in the presence of inhibitors, a residualG _H/OH remains which may be due to water wires, hydrated defects, or other mechanisms.     

Nitrate and nitrite reductase negative mutants of N2-fixingAzospirillum spp.

Chlorate resistant spontaneous mutants ofAzospirillum spp. (syn.Spirillum lipoferum) were selected in oxygen limited, deep agar tubes with chlorate. Among 20 mutants fromA. brasilense and 13 fromA. lipoferum all retained their functional nitrogenase and 11 from each species were nitrate reductase negative (nr^–). Most of the mutants were also nitrite reductase negative (nir^–), only 3 remaining nir⁺. Two mutants from nr⁺ nir⁺ parent strains lost only nir and became like the nr⁺ nir^– parent strain ofA. brasilense. No parent strain or nr⁺ mutant showed any nitrogenase activity with 10 mM NO ₃ ^– . In all nr^– mutants, nitrogenase was unaffected by 10 mM NO ₃ ^– . Nitrite inhibited nitrogenase activity of all parent strains and mutants including those which were nir^–. It seems therefore, that inhibition of nitrogenase by nitrate is dependent on nitrate reduction. Under aerobic conditions, where nitrogenase activity is inhibited by oxygen, nitrate could be used as sole nitrogen source for growth of the parent strains and one mutant (nr^– nir^–) and nitritite of the parent strains and 10 mutants (all types). This indicates the loss of both assimilatory and dissimilatory nitrate reduction but only dissimilatory nitrite reduction in the mutants selected with chlorate.     

Kinetic mechanism of Na+, K+, Cl−-cotransport as studied by Rb+ influx into HeLa cells: Effects of extracellular monovalent ions

Summary Ouabain-insensitive, furosemide-sensitive Rb⁺ influx (J _Rb) into HeLa cells was examined as functions of the extracellular Rb⁺, Na⁺ and Cl^– concentrations. Rate equations and kinetic parameters, including the apparent maximumJ _Rb, the apparent values ofK _m for the three ions and the apparentK _i for K⁺, were derived. Results suggested that one unit molecule of this transport system has one Na⁺, one K⁺ and two Cl^– sites with different affinities, one of the Cl^– sites related with binding of Na⁺, and the other with binding of K⁺(Rb⁺). A 11 stoichiometry was demonstrated between ouabain-insensitive, furosemidesensitive influxes of²²Na⁺ and Rb⁺, and a 12 stoichiometry between those of Rb⁺ and³⁶Cl^–. The influx of either one of these ions was inhibited in the absence of any one of the other two ions. Monovalent anions such as nitrate, acetate, thiocyanate and lactate as substitutes for Cl^– inhibited ouabain-insensitive Rb⁺ influx, whereas sulfamate and probably also gluconate did not inhibitJ _Rb. From the present results, a general model and a specialized cotransport model were proposed: 1) In HeLa cells, one Na⁺ and one Cl^– bind concurrently to their sites and then one K⁺ (Rb⁺) and another Cl^– bind concurrently. 2) After completion of ion bindings Na⁺, K⁺(Rb^–) and Cl^– in a ratio of 112 show synchronous transmembrane movements.     

Differential response to gene dosage experiments involving the two loci which control xanthine dehydrogenase ofDrosophila melanogaster

Summary Assays of xanthine dehydrogenase in flies heterozygous forry indicate that these heterozygotes have about 50–70% of the activity of normal. Thus, thery mutants appear to be similar to other genes in which the heterozygote has lower enzyme activity than the homozygous wild-type. On the other hand, the data obtained fromma-l ⁺ /ma-l heterozygotes indicate no dosage response toma-l. This is substantiated by the insertion ofma-l ⁺-bearing chromosomal fragments into various diploid combinations ofma-l ⁺ andma-l. The results demonstrate that one dose ofma-l ⁺ produces normal amounts of xanthine dehydrogenase activity, even in the presence ofma-l.With 1 Figure in the TextThis work was supported by a grant (RG-8202) from the National Institutes of Health.