Cold-Adapted β-Galactosidase from the Antarctic Psychrophile
            <i>Pseudoalteromonas haloplanktis</i>

Hoyoux, Anne; Jennes, I.; Dubois, Philippe; Genicot, Sabine; Dubail, F.; François, Jean-Marie; Baise, Etienne; Feller, Georges; Gerday, Charles

doi:10.1128/aem.67.4.1529-1535.2001

Cited by 172 publications

(97 citation statements)

References 30 publications

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“…This provides only a small glimpse into the exceptional adaptation of the microbiota to the Antarctic environment. The Pseudoalteromonas isolates in particular showed great potential for bioprospecting of all screened enzymatic activities, a result that agrees with those from previous studies (Holmströ m & Kjelleberg 1999;Hoyoux et al 2001;Truong et al 2001;Tutino et al 2002;Zeng et al 2006). Beyond the biotechnological potential, the high proportion of isolates belonging to the genus Pseudoalteromonas and the versatile hydrolytic activities detected in this group also suggest that these organisms may play an important role in polymer hydrolysis in cold environments.…”

Section: Discussionsupporting

confidence: 80%

Culturable heterotrophic bacteria from Potter Cove, Antarctica, and their hydrolytic enzymes production

Tropeano¹,

Coria²,

Turjanski³

et al. 2012

Polar Research

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Affiliations of the dominant culturable bacteria isolated from Potter Cove, South Shetland Islands, Antarctica, were investigated together with their production of cold-active hydrolytic enzymes. A total of 189 aerobic heterotrophic bacterial isolates were obtained at 4°C and sorted into 63 phylotypes based on their amplified ribosomal DNA restriction analysis profiles. The sequencing of the 16S rRNA genes of representatives from each phylotype showed that the isolates belong to the phyla Proteobacteria (classes Alpha- and Gamma-proteobacteria), Bacteroidetes (class Flavobacteria), Actinobacteria (class Actinobacteria) and Firmicutes (class Bacilli). The predominant culturable group in the site studied belongs to the class Gammaproteobacteria, with 65 isolates affiliated to the genus Pseudoalteromonas and 58 to Psychrobacter. Among the 189 isolates screened, producers of amylases (9.5%), pectinases (22.8%), cellulases (14.8%), CM-cellulases (25.4%), xylanases (20.1%) and proteases (44.4%) were detected. More than 25% of the isolates produced at least one extracellular enzyme, with some of them producing up to six of the tested extracellular enzymatic activities. These results suggest that a high culturable bacterial diversity is present in Potter Cove and that this place represents a promising source of biomolecules

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Section: Discussionsupporting

confidence: 80%

Culturable heterotrophic bacteria from Potter Cove, Antarctica, and their hydrolytic enzymes production

Tropeano¹,

Coria²,

Turjanski³

et al. 2012

Polar Research

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“…H-BgaS had a catalytic efficiency of 0.27 and 0.53 at 5 and 18°C, respectively. Both of these values are higher than those reported for a LacZ enzyme (0.15) without a His tag at 20°C (13).…”

Section: Comparison Of Bgas and Lacz Propertiescontrasting

confidence: 51%

“…To examine possible metal requirements for H-BgaS, it was treated with various concentrations of EDTA. Unlike the Pseudoalteromonas haloplanktis ␤-galactosidase, which was inhibited by 5 mM EDTA (13), no activity loss was detected until the EDTA concentration reached 100 mM, at which the enzyme was inactivated after a 1.5-h treatment. Activity of H-BgaS was relatively unchanged by the addition of Co 2ϩ , Cu 2ϩ , Ca 2ϩ , or Na ϩ (2, 2, 1.5, or 5% increase, respectively).…”

Section: Comparison Of Bgas and Lacz Propertiesmentioning

confidence: 99%

Biochemical Characterization of a β-Galactosidase with a Low Temperature Optimum Obtained from an Antarctic Arthrobacter Isolate

et al. 2003

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A psychrophilic gram-positive isolate was obtained from Antarctic Dry Valley soil. It utilized lactose, had a rod-coccus cycle, and contained lysine as the diamino acid in its cell wall. Consistent with these physiological traits, the 16S ribosomal DNA sequence showed that it was phylogenetically related to other Arthrobacter species. A gene (bgaS) encoding a family 2 ␤-galactosidase was cloned from this organism into an Escherichia coli host. Preliminary results showed that the enzyme was cold active (optimal activity at 18°C and 50% activity remaining at 0°C) and heat labile (inactivated within 10 min at 37°C). To enable rapid purification, vectors were constructed adding histidine residues to the BgaS enzyme and its E. coli LacZ counterpart, which was purified for comparison. The His tag additions reduced the specific activities of both ␤-galactosidases but did not alter the other characteristics of the enzymes. Kinetic studies using o-nitrophenyl-␤-D-galactopyranoside showed that BgaS with and without a His tag had greater catalytic activity at and below 20°C than the comparable LacZ ␤-galactosidases. The BgaS heat lability was investigated by ultracentrifugation, where the active enzyme was a homotetramer at 4°C but dissociated into inactive monomers at 25°C. Comparisons of family 2 ␤-galactosidase amino acid compositions and modeling studies with the LacZ structure did not mimic suggested trends for conferring enzyme flexibility at low temperatures, consistent with the changes affecting thermal adaptation being localized and subtle. Mutation studies of the BgaS enzyme should aid our understanding of such specific, localized changes affecting enzyme thermal properties.Glycosyl hydrolases (EC 3.2.1 to 3.2.3) cleave the glycosidic bond between two or more carbohydrates or between a carbohydrate and another moiety. Traditionally, glycosyl hydrolases were classified based on functional similarity. More recently, however, Henrissat and his coworkers have organized these enzymes into 90 glycosyl hydrolase families characterized by hydrophobicity plots, amino acid sequence similarities, and reaction mechanisms (10-12). This system also identifies possible common structural domains, thereby defining evolutionary connections and suggesting reaction mechanisms for the glycosyl hydrolases. Based on these criteria, the once-unified group of enzymes that exhibit ␤-galactosidase activity (EC 3.2.1.23) are now subdivided into four different families: 1, 2, 35, and 42.Of these, the best studied is family 2, which includes the well-characterized ␤-galactosidase from Escherichia coli that is encoded by the lacZ gene. Although there is considerable information about the regulation (1), biochemistry (18,23,35,47), reaction mechanism (17, 45), and structure (16) of this LacZ ␤-galactosidase, few other ␤-galactosidases within this family have been characterized biochemically (4, 7, 13-15, 26, 27, 43), while most examples exist only as a published sequence. Because of the emphasis on the E. coli LacZ enzyme, opportunities to lea...

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“…Even when some of the proteases from psychrotolerants had their maximal activity at similar temperatures than their corresponding mesophile, the majority of them showed curves of activity as a function of temperature shifted towards low temperatures, with apparent optimum values between 10 and 15 °C lower than Carlsberg Subtilisin. Other authors found similar results for proteases (Helmke & Weyland 1991;Turkiewicz et al 1999) and other enzymes Hoyoux et al 2001) produced by marine bacteria from permanently cold environments. This observation reveals a clear adaptation of the enzyme-producing strains to their habitats.…”

Section: Discussionsupporting

confidence: 70%

Effect of isolation temperature on the characteristics of extracellular proteases produced by Antarctic bacteria

Vázquez

Cormack

2002

Polar Research

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Cold-Adapted β-Galactosidase from the Antarctic Psychrophile Pseudoalteromonas haloplanktis

Cited by 172 publications

References 30 publications

Culturable heterotrophic bacteria from Potter Cove, Antarctica, and their hydrolytic enzymes production

Culturable heterotrophic bacteria from Potter Cove, Antarctica, and their hydrolytic enzymes production

Biochemical Characterization of a β-Galactosidase with a Low Temperature Optimum Obtained from an Antarctic Arthrobacter Isolate

Effect of isolation temperature on the characteristics of extracellular proteases produced by Antarctic bacteria

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