Influence of organic matter quality in the cleavage of polymers by marine bacterial communities

The influence of the quality of organic matter on the hydrolysisof polymers by marine bacteria was investigated in microcosmscontaining aggregates created in rolling tanks. Two types ofmicrocosms were analysed: microcosms type M1 from unalteredseawater and microcosms type M2 from phytoplankton cultures.Kinetics of aminopeptidase, -glucosidase and ß-glucosidasewere measured in the ambient water and the aggregates in thetwo types of microcosms. Bacteria attached to aggregates expressedenzymes with K_m values higher than those of the bacteria inthe ambient water for the three hydrolytic activities analysedin both types of microcosms. Attached bacteria showed higherrates of polymer hydrolysis than free-living bacteria only inmicrocosms M2 created from freshly produced phytoplanktonicmaterial, while free-living bacteria were more active than attachedbacteria in the microcosms M1 containing unaltered seawater.The ratio V_max/K_m, which describes the ability of enzymes tocompete at low substrate concentration, shows that free-livingbacteria are more efficient at dealing with low substrate concentrationsin microcosms derived from natural seawater, where the liquidphase may be depleted of utilizable dissolved organic matter,than in the microcosms derived from phytoplankton cultures.Our data suggest that the hydrolytic activities of both attachedand free-living bacteria are significantly influenced by thequality of the aggregates and the consequences of this influenceare discussed.     

Microbial community composition and function in permanently cold seawater and sediments from an arctic fjord of svalbard

Heterotrophic microbial communities in seawater and sediments metabolize much of the organic carbon produced in the ocean. Although carbon cycling and preservation depend critically on the capabilities of these microbial communities, their compositions and capabilities have seldom been examined simultaneously at the same site. To compare the abilities of seawater and sedimentary microbial communities to initiate organic matter degradation, we measured the extracellular enzymatic hydrolysis rates of 10 substrates (polysaccharides and algal extracts) in surface seawater and bottom water as well as in surface and anoxic sediments of an Arctic fjord. Patterns of enzyme activities differed between seawater and sediments, not just quantitatively, in accordance with higher cell numbers in sediments, but also in their more diversified enzyme spectrum. Sedimentary microbial communities hydrolyzed all of the fluorescently labeled polysaccharide and algal extracts, in most cases at higher rates in subsurface than surface sediments. In seawater, in contrast, only 5 of the 7 polysaccharides and 2 of the 3 algal extracts were hydrolyzed, and hydrolysis rates in surface and deepwater were virtually identical. To compare bacterial communities, 16S rRNA gene clone libraries were constructed from the same seawater and sediment samples; they diverged strongly in composition. Thus, the broader enzymatic capabilities of the sedimentary microbial communities may result from the compositional differences between seawater and sedimentary microbial communities, rather than from gene expression differences among compositionally similar communities. The greater number of phylum- and subphylum-level lineages and operational taxonomic units in sediments than in seawater samples may reflect the necessity of a wider range of enzymatic capabilities and strategies to access organic matter that has already been degraded during passage through the water column. When transformations of marine organic matter are considered, differences in community composition and their different abilities to access organic matter should be taken into account.     

脑膜炎球菌多糖疫苗培养基的优化研究

目的探索A群、C群脑膜炎球菌多糖疫苗培养基的适宜配方。方法通过筛选改良培养基(配方2)中酸水解酪蛋白替代培养基配方1中原50%盐酸酪蛋白水解液制备相应的培养基,培养A群、C群脑膜炎球菌一定时间后,以收获的细菌浓度和复合多糖量来确定培养基的配比,并比较该培养基在不同温度条件下培养细菌的结果。结果在A群、C群脑膜炎球菌多糖疫苗不同培养基的细菌培养过程中,用酸水解酪蛋白制备的改良培养基(配方2)培养的细菌浓度和多糖收获量均高于其他培养基(配方1和配方3),用酸水解酪蛋白培养基能提高脑膜炎球菌的产量。结论以酸水解酪蛋白为主要原料(配方2)的改良培养基能作为流脑A群、C群细菌的最适培养基,且细菌在(37±0.2)℃培养情况良好。     

Microbial activities and dissolved organic matter dynamics in oil-contaminated surface seawater from the Deepwater Horizon oil spill site

The Deepwater Horizon oil spill triggered a complex cascade of microbial responses that reshaped the dynamics of heterotrophic carbon degradation and the turnover of dissolved organic carbon (DOC) in oil contaminated waters. Our results from 21-day laboratory incubations in rotating glass bottles (roller bottles) demonstrate that microbial dynamics and carbon flux in oil-contaminated surface water sampled near the spill site two weeks after the onset of the blowout were greatly affected by activities of microbes associated with macroscopic oil aggregates. Roller bottles with oil-amended water showed rapid formation of oil aggregates that were similar in size and appearance compared to oil aggregates observed in surface waters near the spill site. Oil aggregates that formed in roller bottles were densely colonized by heterotrophic bacteria, exhibiting high rates of enzymatic activity (lipase hydrolysis) indicative of oil degradation. Ambient waters surrounding aggregates also showed enhanced microbial activities not directly associated with primary oil-degradation (β-glucosidase; peptidase), as well as a twofold increase in DOC. Concurrent changes in fluorescence properties of colored dissolved organic matter (CDOM) suggest an increase in oil-derived, aromatic hydrocarbons in the DOC pool. Thus our data indicate that oil aggregates mediate, by two distinct mechanisms, the transfer of hydrocarbons to the deep sea: a microbially-derived flux of oil-derived DOC from sinking oil aggregates into the ambient water column, and rapid sedimentation of the oil aggregates themselves, serving as vehicles for oily particulate matter as well as oil aggregate-associated microbial communities.     

The potential of bacteria isolated from ruminal contents of seaweed‐eating North Ronaldsay sheep to hydrolyse seaweed components and produce methane by anaerobic digestion in vitro

The production of methane biofuel from seaweeds is limited by the hydrolysis of polysaccharides. The rumen microbiota of seaweed‐eating North Ronaldsay sheep was studied for polysaccharidic bacterial isolates degrading brown‐seaweed polysaccharides. Only nine isolates out of 65 utilized > 90% of the polysaccharide they were isolated on. The nine isolates (eight Prevotella spp. and one Clostridium butyricum) utilized whole Laminaria hyperborea extract and a range of seaweed polysaccharides, including alginate (seven out of nine isolates), laminarin and carboxymethylcellulose (eight out of nine isolates); while two out of nine isolates additionally hydrolysed fucoidan to some extent. Crude enzyme extracts from three of the isolates studied further had diverse glycosidases and polysaccharidase activities; particularly against laminarin and alginate (two isolates were shown to have alginate lyase activity) and notably fucoidan and carageenan (one isolate). In serial culture rumen microbiota hydrolysed a range of seaweed polysaccharides (fucoidan to a notably lesser degree) and homogenates of L. hyperborea, mixed Fucus spp. and Ascophyllum nodosum to produce methane and acetate. The rumen microbiota and isolates represent potential adjunct organisms or enzymes which may improve hydrolysis of seaweed components and thus improve the efficiency of seaweed anaerobic digestion for methane biofuel production.     

Bacterial Colonization and Ectoenzymatic Activity in Phytoplankton-Derived Model Particles: Cleavage of Peptides and Uptake of Amino Acids

Abstract Phytoplankton-derived model particles were created in laboratory from a mixture of autoclaved diatom cultures. These particles were colonized by a marine bacterial community and incubated in rolling tanks in order to examine the relationship between aminopeptidase activity and leucine uptake. Bacteria inhabiting particles and ambient water were characterized for abundance, biovolume, aminopeptidase activity, leucine uptake, and growth rate. Particles were a less favorable habitat than ambient water for bacterial growth since growth rates of particle-attached bacteria were similar or even lower than those of free-living bacteria. During the first ∼100 h of the particle decomposition process, there were not statistically significant differences in the aminopeptidase activity:leucine uptake ratio between attached and free-living bacteria. From ∼100 h to ∼200 h, this ratio was higher for attached bacteria than for free-living bacteria. This indicates an uncoupling of aminopeptidase activity and leucine uptake. During this period, attached and free-living bacteria showed similar hydrolytic activities on a cell-specific basis. In the free-living bacterial community, variations in aminopeptidase activity per cell were associated with variations in leucine uptake per cell and growth rates. However, in the attached bacterial community, when leucine uptake and growth rates decreased, aminopeptidase activity remained constant. Thus, after ∼100 h, particle-attached bacteria were not taking advantage of their high aminopeptidase activity; consequently the hydrolysed amino acids were released into the ambient water, supporting the growth of free-living bacteria. These results demonstrate that over the particle decomposition process, the relationship between hydrolysis and uptake of the protein fraction shows different patterns of variation for attached and free-living bacterial communities. However, in our experiments, this uncoupling was not based on a hyperproduction of enzymes by attached bacteria, but on lower uptake rates when compared to the free-living bacteria. Received: 4 February 1997; Accepted: 9 May 1997     

Composition and enzymatic function of particle-associated and free-living bacteria: a coastal/offshore comparison

We compared the function and composition of free-living and particle-associated microbial communities at an inshore site in coastal North Carolina and across a depth profile on the Blake Ridge (offshore). Hydrolysis rates of six different polysaccharide substrates were compared for particle-associated (>3 μm) and free-living (<3 to 0.2 μm) microbial communities. The 16S rRNA- and rDNA-based clone libraries were produced from the same filters used to measure hydrolysis rates. Particle-associated and free-living communities resembled one another; they also showed similar enzymatic hydrolysis rates and substrate preferences. All six polysaccharides were hydrolyzed inshore. Offshore, only a subset was hydrolyzed in surface water and at depths of 146 and 505 m; just three polysaccharides were hydrolyzed at 505 m. The spectrum of bacterial taxa changed more subtly between inshore and offshore surface waters, but changed greatly with depth offshore. None of the OTUs occurred at all sites: 27 out of the 28 major OTUs defined in this study were found either exclusively in a surface or in a mid-depth/bottom water sample. This distinction was evident with both 16S rRNA and rDNA analyses. At the offshore site, despite the low community overlap, bacterial communities maintained a degree of functional redundancy on the whole bacterial community level with respect to hydrolysis of high-molecular-weight substrates.     

Rhizobial polysaccharide-degrading enzymes from roots of legumes

The surface structure and chemistry of symbiotic bacteria from the genus Rhizobium are probably important for the outcome of the infection of legume hosts. Exopolysaccharide, capsular polysaccharide, lipopolysaccharide and a low-molecular-weight polysaccharide were isolated from R. trifolii UTC 110-1 and R. leguminosarum UTC 114-5 and partially characterized. No or only minor differences in sugar composition could be found for the corresponding fractions from the two organisms. A general method to measure low activities of polymer-degrading enzymes was developed, and used to determine enzyme activities in root extracts of Trifolium repens L. cv. Lena and Pisum xativiini L. cv. Little Marvel against the isolated rhizobial polysaccharides. An enzyme preparation from T. repens partially degraded all polysaccharides isolated from its symbiont R. trifolii while polysaccharides from R. leguminosarum , symbiont of P. sativum , were degraded to a much lesser extent. Correspondingly, an enzyme preparation from P. sativum degraded all polysaccharides isolated from both its symbiont R. leguminosarum and its non-symbiont R. trifolii. The amount of symbiont polysaccharides degraded was larger than the amount of polysaccharides degraded from the non-symbiont R. trifolii.     

Carbohydrate-binding domains: multiplicity of biological roles

Insoluble polysaccharides can be degraded by a set of hydrolytic enzymes formed by catalytic modules appended to one or more non-catalytic carbohydrate-binding modules (CBM). The most recognized function of these auxiliary domains is to bind polysaccharides, bringing the biocatalyst into close and prolonged vicinity with its substrate, allowing carbohydrate hydrolysis. Examples of insoluble polysaccharides recognized by these enzymes include cellulose, chitin, β-glucans, starch, glycogen, inulin, pullulan, and xylan. Based on their amino acid similarity, CBMs are grouped into 55 families that show notable variation in substrate specificity; as a result, their biological functions are miscellaneous. Carbohydrate or polysaccharide recognition by CBMs is an important event for processes related to metabolism, pathogen defense, polysaccharide biosynthesis, virulence, plant development, etc. Understanding of the CBMs properties and mechanisms in ligand binding is of vital significance for the development of new carbohydrate-recognition technologies and provide the basis for fine manipulation of the carbohydrate–CBM interactions.     

Studies of molecular-weight distribution for hydrolysis products from some Klebsiella capsular polysaccharides

Gel-permeation chromatography has been used to determine the molecular-weight distribution of the products at various stages of acid hydrolysis of some capsular polysaccharides from klebsiella bacteria. Structurally significant oligosaccharides, which are believed to correspond closely to the chemical repeating units in the polysaccharide molecules, were detected together with products having higher molecular weights, which are clearly aggregates of these oligosaccharides. This constitutes good supporting evidence for the view that relatively simple sequences of sugars are repeated throughout the entire molecular structure of these polysaccharides, and quantitative information for the polysaccharides from three different Klebsiella strains (serotyped as k54, K4, and K64, respectively) has been obtained by this procedure. The study of the polysaccharide from Klebsiella K-type 54 has afforded both independent corroboration and some extension of available data.     

Isolation of Moderately Halophilic <Emphasis Type="Italic">Pseudoalteromonas</Emphasis> Producing Extracellular Hydrolytic Enzymes from Persian Gulf

Extracellular hydrolytic enzymes such as amylases, proteases, lipases and DNases have quite diverse potential usages in different areas such as food industry, biomedical sciences and chemical industries, also it would be of great importance to have available enzymes showing optimal activities at different values of salt concentrations and temperature. Halophiles are the most likely source of such enzymes, because not only their enzymes are salt-tolerant, but many are also thermotolerant. The purpose of this study was isolation of hydrolytic extracellular enzyme producing halophilic bacteria from water and sediment of the Persian Gulf. Isolated bacteria from water and sediment were inoculated in media with concentration of 0–20% NaCl to determine the optimum salt concentration for growth, isolates were also inoculated in 4 types of solid medium containing substrates of 3 extracellular hydrolytic enzymes including amylase, Protease and Lipase, to determine the quantitative detection of enzyme production, selected strains after more accurate physiological and biochemical studies were identified regarding phylogeny and molecular characteristics using 16S rRNA technique. Isolated enzyme producing bacteria belong to Pseudoalteromonas genera.     

Autohydrolysis of plant polysaccharides using transgenic hyperthermophilic enzymes

Commercial bioprocessing of plant carbohydrates, such as starch or cellulose, necessitates the use of commodity enzyme additives to accelerate polysaccharide hydrolysis. To simplify this procedure, transgenic plant tissues constitutively producing commodity enzymes were examined as a strategy for accelerating carbohydrate bioprocessing. Hyperthermophilic glycosyl hydrolases were selected to circumvent enzyme toxicity, because such enzymes are inactive at plant growth temperatures and are therefore physiologically benign. Transgenic tobacco lines were established that produced either a hyperthermophilic alpha-glucosidase or a beta-glycosidase using genes derived from the archaeon Sulfolobus solfataricus. Western blot and immunoprecipitation analyses were used to demonstrate the presence of recombinant enzymes in plant tissues. Transgenic enzyme levels exhibited an unusual delayed pattern of accumulation while their activities survived plant tissue preservation. Transgenic plant protein extracts released glucose from purified polysaccharide substrates at appreciable rates during incubation in high-temperature reactions. Glucose was also produced following enzymatic treatment of plant extracts enriched for endogenous polysaccharides. Direct conversion of plant tissue into free sugar was evident using whole plant extracts of either transgenic line, and could be significantly accelerated in a synergistic manner by combining transgenic line extracts.     

Bacterioplankton nutrient metabolism in the Eastern Tropical North Pacific

Bacterioplankton nutrient metabolism in the Eastern Tropical North Pacific (ETNP) was assessed using specific activities of intracellular nitrogen (N) assimilation enzymes and hydrolytic ectoenzymes during amendment experiments, mesocosms, and diel studies of in situ rates. Glutamine synthetase (GS) and assimilatory nitrate reductase (ANR) were used to investigate N bioavailability, alkaline phosphatase (AP) to assess phosphorous (P) bioavailability and β-glucosidase (β-Glu) to detect shifts in the use of labile dissolved organic carbon (DOC). Conditions regulating activity of each enzyme were tested using incubations of < 0.6 mm size-fractionated seawater amended with different combinations of N, P, and DOC as glucose. Overall, N-deficiency was indicated by pronounced growth stimulation and repression of GS and ANR activity in incubations amended with dissolved free amino acid and ammonium. Phosphate and glucose amendments produced little or no growth stimulation, but did influence activity of all enzymes measured. Enzyme activities of bacterioplankton in mesocosms of whole plankton indicated enhanced N-deficiency and glucoside hydrolysis when the plankton community was released from any P-deficiency. Spatially, enzyme activity of bacterioplankton during two diel studies (at one slope and one open-ocean station) suggested greater N-deficiency at surface depths than within the chlorophyll maximum where activity of AP and b-Glu was often greatest. There was also greater GS and ANR activity at the open-ocean station, which had lower concentrations of dissolved inorganic N (DIN) relative to soluble reactive P (SRP), than along the continental slope of Mexico. These data suggest that bacterioplankton in surface waters of the ETNP require a large flux of DOC to drive N-deficiency; whereas, bacterioplankton deeper in the chlorophyll maximum depend on hydrolysis of complex DOC and DOP to meet their carbon demand in the presence of elevated nutrients with a low DIN:SRP ratio.     

Comparison of Cell Wall Polysaccharide Hydrolysis by a Dilute Acid/Enzymatic Saccharification Process and Rumen Microorganisms

Evaluation of biomass crops for breeding or pricing purposes requires an assay that predicts performance in the bioenergy conversion process. Cell wall polysaccharide hydrolysis was compared for a dilute sulfuric acid pretreatment at 121°C followed with cellulase hydrolysis for 72?h conversion assay (CONV) with in vitro rumen microflora incubation for 72?h (RUMEN) for a set of maize (Zea mays L.) stover samples with a wide range in cell wall composition. Residual polysaccharides from the assays were analyzed for sugar components and extent of hydrolysis calculated. Cell wall polysaccharide hydrolysis was different for all sugar components between the CONV and RUMEN assays. The CONV assay hydrolyzed xylose-, arabinose-, galactose-, and uronic acid-containing polysaccharides to a greater degree than did the RUMEN assay, whereas the RUMEN assay was more effective at hydrolyzing glucose- and mannose-containing polysaccharides. Greater hydrolysis of hemicelluloses and pectins by CONV can be attributed to the acid hydrolysis mechanism of the CONV assay for noncellulosic polysaccharides, whereas the RUMEN assay was dependent on enzymatic hydrolysis. While CONV and RUMEN hydrolysis were correlated for most polysaccharide components, the greatest correlation was only r?=?0.70 for glucose-containing polysaccharides. Linear correlations and multiple regressions indicated that polysaccharide hydrolysis by the RUMEN assay was negatively associated with lignin concentration and ferulate ether cross linking as expected. Corresponding correlations and regressions for CONV were less consistent and occasionally positive. Use of rumen microbial hydrolysis to characterize biomass performance in a conversion process may have some limited usefulness for genetic evaluations, but such assays would be unreliable for biomass pricing.     

Functional differences between Arctic seawater and sedimentary microbial communities: contrasts in microbial hydrolysis of complex substrates

The activities and structural specificities of extracellular enzymes that initiate microbial remineralization of high-molecular-weight (MW) organic matter were investigated in surface waters and sediments of an Arctic fjord of Svalbard. Hydrolysis rates of a suite of fluorescently labeled macromolecular substrates, including seven commercially available polysaccharides and three high-carbohydrate-content plankton extracts ranged from rapid to not detectable, and differed markedly between seawater and sediments. Order (fastest to slowest) of hydrolysis in surface water was laminarin, Spirulina extract, xylan>chondroitin, alginic acid, Wakame extract>arabinogalactan, fucoidan>Isochrysis extract>pullulan, while in sediments the order was pullulan, laminarin, alginic acid, Wakame extract>chondroitin, xylan>arabinogalactan, Isochrysis extract>Spirulina extract>fucoidan. These differences cannot be explained by simple scaling factors such as differences in microbial cell numbers between seawater and sediments. Other investigations have shown that microbial community composition of Svalbard sediments and of polar bacterioplankton samples differ markedly. These results demonstrate that sedimentary and seawater microbial communities also differ fundamentally in their abilities to access specific high-MW substrates. Substrate bioavailability depends on the capabilities of a microbial community, as well as the chemical and structural features of the substrate itself.     

Accessory enzymes influence cellulase hydrolysis of the model substrate and the realistic lignocellulosic biomass

The potential of cellulase enzymes in the developing and ongoing “biorefinery” industry has provided a great motivation to develop an efficient cellulase mixture. Recent work has shown how important the role that the so-called accessory enzymes can play in an effective enzymatic hydrolysis. In this study, three newest Novozymes Cellic CTec cellulase preparations (CTec 1/2/3) were compared to hydrolyze steam pretreated lignocellulosic substrates and model substances at an identical FPA loading. These cellulase preparations were found to display significantly different hydrolytic performances irrelevant with the FPA. And this difference was even observed on the filter paper itself when the FPA based assay was revisited. The analysis of specific enzyme activity in cellulase preparations demonstrated that different accessory enzymes were mainly responsible for the discrepancy of enzymatic hydrolysis between diversified substrates and various cellulases. Such the active role of accessory enzymes present in cellulase preparations was finally verified by supplementation with β-glucosidase, xylanase and lytic polysaccharide monooxygenases AA9. This paper provides new insights into the role of accessory enzymes, which can further provide a useful reference for the rational customization of cellulase cocktails in order to realize an efficient conversion of natural lignocellulosic substrates.     

Systemic changes in hydrolytic enzyme activities in mice affected with murine leprosy

In order to investigate the behavior of hydrolytic enzymes in chronic infections, the activities of 17 hydrolytic enzymes were tested in limb muscles, heart muscle, spleen, liver, and kidney of lepromatous mice infected with Mycobacterium lepraemurium (M. lepraemurium) and their controls. Typical increases in those enzymatic activities were seen in spleen and liver, where pathological changes were the most pronounced, especially at the 11th week after the inoculation of the bacilli. At the 16th week, the enzymatic changes became less remarkable probably because of the decreased viability of tissues in these organs. The enzymatic changes observed could not be explained as due to bacterial enzymes. These findings are compatible with the notion that the increases in hydrolytic enzyme activities are related to tissue damage caused by murine leprosy.     

Short-term changes in polysaccharide utilization mechanisms of marine bacterioplankton during a spring phytoplankton bloom

Spring phytoplankton blooms in temperate environments contribute disproportionately to global marine productivity. Bloom-derived organic matter, much of it occurring as polysaccharides, fuels biogeochemical cycles driven by interacting autotrophic and heterotrophic communities. We tracked changes in the mode of polysaccharide utilization by heterotrophic bacteria during the course of a diatom-dominated bloom in the German Bight, North Sea. Polysaccharides can be taken up in a ‘selfish’ mode, where initial hydrolysis is coupled to transport into the periplasm, such that little to no low-molecular weight (LMW) products are externally released to the environment. Alternatively, polysaccharides hydrolyzed by cell-surface attached or free extracellular enzymes (external hydrolysis) yield LMW products available to the wider bacterioplankton community. In the early bloom phase, selfish activity was accompanied by low extracellular hydrolysis rates of a few polysaccharides. As the bloom progressed, selfish uptake increased markedly, and external hydrolysis rates increased, but only for a limited range of substrates. The late bloom phase was characterized by high external hydrolysis rates of a broad range of polysaccharides and reduced selfish uptake of polysaccharides, except for laminarin. Substrate utilization mode is related both to substrate structural complexity and to the bloom-stage dependent composition of the heterotrophic bacterial community.     

Differences in the substrate spectrum of extracellular enzymes in shallow lakes of differing trophic status

Organic matter fluxes and food web interactions in lakes depend on the abilities of heterotrophic microbial communities to access and degrade organic matter, a process that begins with extracellular hydrolysis of high molecular weight substrates. In order to determine whether patterns of enzymatic hydrolysis vary among shallow lakes of different trophic status, we investigated the hydrolysis of six specific organic macromolecules (polysaccharides) in the spring and late summer in four adjacent shallow lakes of eutrophic, oligotrophic, and dystrophic status in coastal North Carolina, USA. The spectrum of enzyme activities detected differed strongly between lakes, with all six polysaccharides hydrolyzed in West Mattamuskeet in May, while only two substrates were hydrolyzed in Lake Phelps in August/September. Differences in the spectrum of enzyme activities, and therefore the capabilities of heterotrophic microbial communities, were likely driven by variations among lakes in primary productivity patterns, sediment–water interactions, and/or water chemistry. Our data represent a first step towards a better understanding of carbon substrate availability and differences in carbon cycling pathways in shallow lakes of different trophic status.     

Ecophysiological variabilities in ectohydrolytic enzyme activities of some Pseudoalteromonas species,P. citrea,P. issachenkonii,and P. nigrifaciens

The ecophysiological variabilities in the ectohydrolytic enzyme profiles of the three species of Pseudoalteromonas, P. citrea, P. issachenkonii, and P. nigrifaciens, have been investigated. Forty-one bacteria isolated from several invertebrates, macroalgae, sea grass, and the surrounding water exhibited different patterns of hydrolytic enzyme activities measured as the hydrolysis of either native biopolymers or fluorogenic substrates. The activities of the following enzymes were assayed: proteinase, tyrosinase, lipase, amylase, chitinase, agarase, fucoidan hydrolase, laminaranase, alginase, pustulanase, cellulase, beta-glucosidase, alpha- and beta-galactosidases, beta-N-acetylglucosaminidase, beta-glucosaminidase, beta-xylosidase, and alpha-mannosidase. The occurrence and cell-specific activities of all enzymes varied over a broad range (from 0 to 44 micromol EU per hour) and depended not only on taxonomic affiliation of the strain, but also on the source/place of its isolation. This suggests 'specialization' of different species for different types of polymeric substrates as, for example, all strains of P. citrea and P. issachenkonii hydrolyzed alginate and laminaran, while strains of P. nigrifaciens were lacking the ability to hydrolyze most of the algal polysaccharides. The incidence of certain enzymes such as fucoidan hydrolases, alginate lyases, agarases, and alpha-galactosidases might be strain specific and reflect its particular ecological habitat.