Báo cáo Y học: The cold-active lipase of Pseudomonas fragi Heterologous expression, biochemical characterization and molecular modeling pdf

The cold-active lipase of Pseudomonas fragiHeterologous expression, biochemical characterization and molecular modeling Claudia Alquati, Luca De Gioia, Gianluca Santarossa, Lilia Albergh

The cold-active lipase of Pseudomonas fragi

Heterologous expression, biochemical characterization and molecular modeling Claudia Alquati, Luca De Gioia, Gianluca Santarossa, Lilia Alberghina, Piercarlo Fantucci and Marina Lotti

Dipartimento di Biotecnologie e Bioscienze, Universita` degli Studi di Milano-Bicocca, Milano, Italy

A recombinant lipase cloned from Pseudomonas fragi strain

IFO 3458 (PFL) was found to retain significant activity at

low temperature In an attempt to elucidate the structural

basis of this behaviour, a model of its three-dimensional

structure was built by homology and compared with

homologous mesophilic lipases, i.e the Pseudomonas

aeruginosalipase (45% sequence identity) and Burkholderia

cepacialipase (38%) In this model, features common to all

known lipases have been identified, such as the catalytic triad

(S83, D238 and H260) and the oxyanion hole (L17, Q84)

Structural modifications recurrent in cold-adaptation, i.e a large amount of charged residues exposed at the protein surface, have been detected Noteworthy is the lack of a disulphide bridge conserved in homologous Pseudomonas lipases that may contribute to increased conformational flexibility of the cold-active enzyme

Keywords: lipase; Pseudomonas; cold-active enzymes; modeling; selectivity

Enzymes from psychrotrophic and psychrophilic

microor-ganisms have recently received increasing attention, due to

their relevance for both basic and applied research This effort

has been stimulated by the recognition that cold-adapted

enzymes might offer novel opportunities for biotechnological

exploitation based on their high catalytic activity at low

temperatures, low thermostability and unusual specificities

These properties are of interest in different fields such as

detergents, textile and food industry, bioremediation and

biocatalysis under low water conditions [1,2] Furthermore,

fundamental issues concerning the molecular basis of cold

activity and the interplay between flexibility and catalytic

efficiency are of importance in the study of structure–function

relationships in proteins Such issues are often approached

through comparison with the mesophilic or thermophilic

counterparts, if available, and/or mutagenesis [3,4]

In this context, the recent cloning of a few lipases

(acylglycerol ester hydrolases, EC 3.1.1.3) active at low

temperature is relevant [5–7] Because of their metabolic and

industrial role, lipases have been thoroughly investigated by

studies encompassing sequence, structure, regulation of

expression, activity and specificity [8] Among bacterial

lipases, a focus has been on enzymes produced by

members of the genus Pseudomonas, some of which

have been recently reclassified as Burkholderia A dozen of

lipase-encoding genes have been cloned from different species, and the corresponding proteins have been classified into families I.1 and I.2 of bacterial lipases according to their molecular properties and to the requirement of helper proteins for correct folding and secretion [9] Crystal structure determinations of Pseudomonas lipases have been reported including B glumae (BGL) [10], P aeruginosa (PAL) [11], and B cepacia (BCL) [12–14]

In this paper, we describe the characterization of a cold-active lipase cloned from P fragi, the main spoiling agent of refrigerated meat and raw milk [15] This enzyme shares high sequence similarity with Pseudomonas lipases of known three-dimensional structure, therefore providing a new tool

to study the molecular bases of cold-adaptation

E X P E R I M E N T A L P R O C E D U R E S

P fragi strain IFO3458 (LMG2191T) was obtained from the BCCMTM/LMG bacteria collection (Universiteit Gent, Belgium) As the cloning host, E coli JM101 (Promega Co, Madison, Wisconsin) was used Heterologous expression was performed in the E coli strain SG13009[pREP4] (Qiagen)

Cloning and expression DNA manipulations were according to Sambrook et al [16] and according to manufacturer’s instructions for the enzymes and materials employed

Chromosomal DNA was extracted as described previ-ously [17] with minor modifications from a P fragi culture grown to the late exponential phase at 25
C in 1% bacto tryptone, 0.5% bacto yeast extract and 0.5% NaCl The lipase-encoding gene was amplified from chromoso-mal DNA by PCR with oligonucleotide primers designed based on the sequence of the homologous lipase from strain IFO 12049 (AC X14033) Forward primer: 5¢-CACCCTG CGAGATTGAACATG-3¢ (nucleotides)18to+3);reverse primer: 5¢-AAGCTTGATTACAGGCTACAAG-3¢ (+938

Correspondence to M Lotti, Dipartimento di Biotecnologie

e Bioscienze, Universita` degli Studi di Milano-Bicocca,

Piazza della Scienza 2, 20126 Milano, Italy.

Fax: + 39 02 64483565, Tel.: + 39 02 64483527,

E-mail: marina.lotti@unimib.it

Abbreviations: BCL, Burkholderia cepacia lipase; BGL, Burkholderia

glumae lipase; MM, molecular mechanics; PAL, Pseudomonas

aeruginosa lipase; PFL, Pseudomonas fragi lipase; PCR, polymerase

chain reaction; SRC, structural conserved regions.

Enzyme: lipase (EC 3.1.1.3).

(Received 18 February 2002, revised 17 May 2002,

accepted 23 May 2002)

to +924), where a restriction site for HindIII was inserted.

Reaction was carried out in a total volume of 100 lL and was

catalyzed by 2.5 U of Pfu TurboTM polymerase (Stratagene,

CA, USA) The amplification program was as follows:

3 min 94
C followed by 25 cycles of 30 s 94
C, 45 s 55
C,

1 min 72
C, the final elongation step was 5 min 72
C

and 15 min 10
C The amplified fragment, purified from a

0.8% agarose gel, was automatically sequenced by

M-Medical (Firenze, Italy)

The lipase-encoding gene was inserted in the BamHI and

HindIII cloning sites of pQE30(Qiagen), a plasmid designed

for the regulated expression in E coli of foreign genes

Recombinant proteins are produced as fusion with a His6

tag at the N-terminus The gene was amplified as before and

modified by: (a) introducing a BamHI site and deleting the

starting ATG codon and (b) introducing a HindIII cleavage

site at the 3¢ end Primers were as follows: forward primer:

5¢-GGATCCGACGATTCGGTAAAT-3¢; reverse primer:

5¢-AAGCTTGATTACAGGCTACAAG-3¢

E coliSG13009 transformed with the expression plasmid

was grown overnight at 27
C in Luria–Bertani medium

supplemented with 100 lgÆmL)1ampicillin and 25 lgÆmL)1

kanamycin Isopropyl thio-b-D-galactoside was added to a

concentration of 0.4 mMand cultivation was continued for

an additional 4 h Cells were collected by centrifugation

(30 min, 8000 g, 4
C) and resuspended in 50 mM

NaH2PO4 pH 8.0, 300 mM NaCl and 10 mM imidazole

After the addition of 1 mgÆmL)1lysozyme, the suspension

was incubated on ice for 30 min and then sonicated six times

for 10 s The cell lysate was centrifuged for 20 min at 4
C,

25 000 g The His6-tagged lipase was purified at 4
C on

50% Ni-nitrilotriacetic acid resin (Qiagen) Two mililiters of

clear lysate were added to 1 mL resin, mixed by gentle

shaking at 4
C for 60 min and loaded on a column After

washing with 4 mL of 50 mMNaH2PO4pH 8.0, 300 mM

NaCl and 20 mM imidazole, the recombinant lipase was

eluted at pH 7.5 with 2 mL of 50 mMNaH2PO4, 300 mM

NaCl and 250 mMimidazole Purification of the

recombin-ant protein was monitored spectrophotometrically

follow-ing the increase in absorbance at 410 nm due to hydrolysis

of p-nitro-phenylpalmitate The reaction mixture (1 mL)

contained 0.8 mM p-nitro-phenylpalmitate in 50 mM

Na2HPO4Æ2H2O, KH2PO4with 2% arabic gum

Protein characterization

SDS PAGE [18] was performed using 12% acrylamide gels

with GELCODE staining (Pierce) The protein

concentra-tion was determined according to Bradford [19] with BSA as

the standard

Lipase activity was determined in a pH-stat assay by

titrating fatty acids released from triacylglycerols with

0.01M sodium hydroxide using a 718 STAT TITRINO

(Metrhom) Emulsions of 20 mMtriacylglycerols with 2%

arabic gum were used as the substrate Tricaprylin was the

substrate for activity determination, if not otherwise stated

The pH and temperature optima were investigated in the

range of 4–9 and 25–40
C, respectively Substrate

speci-ficity was determined at 29
C, pH 8.0 on triacylglycerol

substrates with chain lengths ranging from C4to C18 The

effect of temperature on stability was determined by

preincubating samples of purified rPFL at 10
, 27
and

50
C before determining residual activity

The effect of calcium ions on activity was investigated under standard assay conditions by measuring enzymatic activity in the presence of 5 mM EDTA at free calcium concentrations varying between 0 and 50 mM

Molecular modeling Multiple sequence alignments were carried out with the program CLUSTALX [20] using the following lipase sequences: P aeruginosa (PAL, Swissprot code: P26876),

B glumae (BGL, Swissprot code: O05489), B cepacia (BCL, Swissprot code: P22088), P fragi (PFL, this work) The alignment featuring the highest score was obtained using the Blosum matrix [21] and standard CLUSTALX

parameters The atomic coordinates of PAL and BCL in their open conformation [11,13] were obtained from the Brookhaven Protein Data Bank

The PFL three-dimensional model was built according

to the following procedure: (a) protein regions charac-terized by high similarity, as identified by sequence alignment and featuring very similar secondary structure,

as derived from experimental data or as predicted by the PHD algorithm [22], were chosen as structurally con-served regions (SCR); (b) the atomic coordinates of the backbone atoms inside the SCR regions were transferred from the reference X-ray structure to the model; (c) fragments connecting the scaffold elements (usually loops) were modeled scanning the Brookhaven Protein Databank for protein structures of a predefined length that would fit properly into the model protein between two SCRs The search was carried out by comparing the a-carbon distance matrix of the flanking SCR peptides with a precalculated matrix for all known proteins that have the same number of flanking residues and an intervening peptide segment of the given length The following strategy has been adopted to optimize the structure of the model: (a) all atoms, except those corresponding to the fragments connecting SCRs, were kept fixed during the first Molecular Mechanics (MM) energy minimization This allowed the nonSCR elements

to re-arrange their conformation without affecting the global folding of the more conserved regions (b) In a second MM optimization step, only the backbone atoms

of the SCRs were kept fixed (c) Only the a-carbons of the SCR regions were constrained to their initial position and (d) as the final step, the whole model was subjected

to MM optimization without constraints The optimized structure was subjected to the program PROCHECK [23], which allowed confirming its structural reliability

R E S U L T S A N D D I S C U S S I O N

Sequence analysis Lipases have been cloned from a few P fragi strains [24–26] Out of them, the short lipase sequence (135 residues) from strain IFO3458 present in the database ([24]; AC: M14604)

is probably truncated at its 3¢ half as it lacks functional sites The coding sequence was therefore amplified from chro-mosomal DNA with oligonucleotide primers designed based on the sequences immediately upstream and down-stream the coding sequence of the lipase from the related strain IFO12049 (S02005) [25]

Sequencing revealed an ORF of 879 bp encoding a

polypeptide of 293 residues Comparison with M14604

evidences a sequencing error at bp 354 where a missing

nucleotide causes a reading frameshift followed by an early

stop codon after few amino acids The revised sequence has

been assigned accession number AJ250176 Total GC

content (59.3%) and the predicted codon usage, with

72.2% of the codons ending with G or C, are characteristic

of Pseudomonas genes Analysis of the deduced amino-acid

sequence is consistent with a protein of Mr32.086 and an

isoelectric point of 9.33 A single cysteine residue is present

at position 39, thus ruling out the presence of a disulphide

bridge, characteristic of most Pseudomonas lipases A leader

sequence for secretion could not be unambiguously

identi-fied at the N-terminal end

The amino-acid sequence shares 97% identity with IFO

12049 lipase from which it only diverges in its C-terminal 22

residues (highlighted in Fig 1) Scanning of protein

sequence databases by FASTA[27] revealed a high degree

of similarity with the P fluorescens strain C9 (O68310,

48.1% identity over 297 amino acids), Proteus vulgaris

(Q52614, 47.9% over 286 amino acids), Pseudomonas sp

(Q9X512, 47.2% over 290 amino acids), P aeruginosa

(Q9L6C7, 45.1% over 288 amino acids) and Vibrio cholerae

(P15493, 48,2% over 288 amino acids) lipases High identity

is also shared with other Pseudomonas lipases of known

three-dimensional structure, i.e B cepacia (37.7% over 318

amino acids), and B glumae (37.9% over 322 amino acids)

The similarity with P fluorescens lipases is restricted to a

30-kDa enzyme recently isolated from milk [15] and does

not extend to the 50-kDa P fluorescens lipases described so

far Surprisingly, the remarkable similarity to the lipase

from Proteus vulgaris K80 [28], that in addition shares with PFL the absence of cysteine residues possibly involved in intramolecular disulphide bond formation

On the other hand, the lipase sequence does not display obvious sequence similarity with either a lipase cloned from

an alaskan psychrotrophic Pseudomonas [5] or with other cold-adapted lipases from different microorganisms [6,7] Expression and purification

Expression of rPFL carrying a His6tag at its N-terminus was obtained as described above Culture growth and induction was performed at 27
C to cope with both enzyme thermolability and the optimal growth temperature for the

E coli expression system Under these conditions, rPFL was partly obtained in a soluble, active form suitable for further characterization About 2 mg of pure recombinant rPFL per g wet weight cells were recovered by a one-step purification method involving metal-chelating chromatog-raphy (Fig 2) In order to exclude any influence of the His6 tag on the recombinant lipase activity, a control plasmid was constructed where the tag was followed by a recognition site for Tevprotease Enzyme obtained by protease digestion did not show any difference in activity (not shown)

Several Pseudomonas lipases have been reported to require a chaperone (or helper) protein for efficient secretion and folding of the active lipase [9] Therefore, coexpression

of the lipase- and helper-encoding genes has been success-fully exploited as a tool to obtain high levels of recombinant active lipase in heterologous bacterial hosts [29] However, coexpression of rPFL with the foldase of P aeruginosa did

Fig 1 Alignment of the PFL sequence with Pseudomonas lipases of known three-dimensional structure The sequence is identical to that of the lipase from strain IFO12049 except for the C-terminal 22 amino acids which are shown in bold ˆ ¼ amino acid forming the catalytic triad,
¼ amino acid forming the LID, § ¼ amino acid involved in calcium binding PAL ¼ P aeruginosa lipase, PFL ¼ P fragi lipase, BCL ¼ B cepacia lipase and BGL ¼ B glumae lipase.

not produce significant improvements in the fraction of

soluble lipase The apparent ineffectiveness of foldase

together with the lack of a signal peptide at the N-terminal

suggests the hypothesis that PFL might be secreted by a

signal peptide-independent pathway and calls for further

investigation on this subject

Enzyme activity and specificity

In the standard tricaprylin hydrolysis assay, rPFL displayed

highest activity at 29
C and pH 8.0, in good agreement

with results reported for the wild type enzyme [30]

Interestingly, the enzyme lost most of its activity at 50
C

but retained about 60% of its specific activity at 10
C

(Table 1) Under the same conditions, the activity of the

homologous lipase from Burkholderia cepacia was reduced

to 10% (not shown) The stability of rPFL was further

investigated Incubation of the enzyme at different

temper-atures showed that at 10
C rPFL retains for several hours

most of its activity, whereas its half-life at 27
C is about

5 h Activity dramatically drops after a few minutes at

50
C (Fig 3) This is an important characteristic for PFL

identification as a cold-active enzyme and well fits with the

structural features evidenced by the three-dimensional

model, as reported below

Specificity towards triglycerides was tested in a pH-stat

assay using six triacylglycerol substrates of different chain

length (C4 to C18) As shown in Fig 4, rPFL activity

decreases going from short- to long-chain substrates and

triolein is a poor substrate Therefore, PFL differs in chain

length selectivity from both PAL, with broad substrate

specificity on triglycerides [31] and BCL which shows a high

preference for the hydrolysis of triglycerides with a chain

length‡ 8 [32] No activity was detected in a phospholipase assay using phosphatidylcholine as the substrate

Finally, experiments have been carried out to elucidate the influence of Ca2+ions on the catalytic activity rPFL activity measured in the presence of 5 mMEDTA was by 55% lower than the control Variation of the calcium concentration resulted in a saturation curve with a plateau between 10 mMand 20 mMcalcium (Fig 5)

Fig 3 Effect of temperature on the enzyme stability as measured at

10 °C (d), 27 °C (r) and 50 °C (m).

Fig 4 Activity of rPFL on triacylglycerols with different chain length C4, C8, C12, C16, C18 and C18* are tributyrin, tricaprylin, trilaurin, tripalmitin, tristearin and triolein, respectively.

Fig 5 Enzymatic activity of rPFL as a function of calcium concentra-tion.

Fig 2 Electrophoretic analysis showing the purification of recombinant

PFL (1) Molecular mass standards; (2) 2 lg rPFL after purification by

metal-chelating chromatograpy; (3) total soluble extract of E coli

expressing the recombinant protein.

Table 1 Rate of hydrolysis of tricaprylin by rPFL at different

temper-atures.

Temperature of hydrolysis (
C)

Relative hydrolysis (%) 59 100 15

Model building

In order to derive a three-dimensional model of the PFL

structure, its sequence was aligned with those of

Pseudo-monaslipases of known three-dimensional structure, namely

B cepacia (BCL), B glumae (BGL) and P aeruginosa

(PAL) As can be observed in Fig 1, sequence similarity

extends along all the protein sequence with the exception of

the 177–213 region (PFL numbering) where the BCL and

BGL sequences are characterized by peptide insertions Use

of secondary structure data allowed to better define SCR in

regions where sequence similarity alone provided

ambigu-ous results Using this approach, 11 SCRs were defined that

constitute the structural scaffold upon which the PFL

three-dimensional model was built These SCRs span the peptide

segments 5–23, 31–49, 54–68, 76–120, 129–148, 155–181,

191–201, 214–218, 237–242, 245–267 and 277–293 of PFL

It is interesting to note that most nonSCRs are peptide

fragments forming loop regions in the experimentally

derived three-dimensional structures, supporting our choice

of SCRs On the other hand, regions forming important

structural and/or functional portions in the selected lipases,

such as the catalytic triad, the oxyanion hole and the

calcium binding site are all located in SCRs

In this work, PAL was chosen as structural reference as

this enzyme shows the highest degree of similarity to PFL

Furthermore, the computed structure was validated against

the BCL structure We observed that our PFL model might

overlap to a high degree with both structures, as expected

from the overall structural similarity relating PAL and BCL

[11] On these bases, the structural features of the PFL were

analysed in deeper detail (Figs 6–8)

Fig 6 Overall three-dimensional structure of PFL, as obtained by

homology modeling For clarity, only arginine side chains are explicitly

shown.

Fig 7 Schematic representation of the Ca-coordination environment in PFL The conserved residues D217 and D262 are coordinated to the metal ion by one carboxylic oxygen atom belonging to the side chain The Ca ion is coordinated also by the backbone carbonyl groups of H266 and R269 Bond distances and angles involving the metal atom and the coordinating amino acids are very similar to the corresponding values observed in PAL (data not shown).

Fig 8 Schematic representation of the two aromatic residues of PFL (W184 and F244) that structurally correspond to the disulphide bridge in PAL, shown in grey.

Amino acids forming the catalytic center in PAL and

BCL are conserved in PFL and correspond to S83, D238

and H260 However, some subtle structural differences

between the active sites are worth noting PFL is

charac-terized by a hydrogen bond between D259 and H260, which

is not present either in PAL nor BCL; the proximal

carboxylic acid suggested to function as an alternative

proton acceptor in other Pseudomonas lipases (E289, BCL

numbering) [33] is not conserved in PFL nor does the

analysis of its model reveal other glutamate or aspartate

residues in that region

Another feature characterizing lipases is the so-called

oxyanion hole, an arrangement of amino acids which plays

an important role in the stabilization of the tetrahedral

intermediate transiently formed in the hydrolysis reaction

through hydrogen bonding to main chain donors [34] Even

in this case, two residues that might contribute to the

formation of the stabilizing configuration (L17 and Q84,

PFL numbering) are conserved and located in SCRs

In most lipases, the catalytic site is occluded by a surface

amphiphilic structure, named the lid, that makes the active

site inaccessible to the substrate, unless it is displaced by the

interaction with aggregated substrates The region forming

the lid is located in a SCR and appears to be well conserved

in PFL (128–148)

A further target for investigation was the presence of a

binding site for Ca2+ions, which are reported to enhance

the activity of several bacterial lipases Accordingly, a

calcium binding pocket is present both in PAL and BCL,

where its function seems to be rather related to structure

stabilization [11,13] The crucial features of the calcium

binding site are well conserved in PFL, where D217 and

D262 are favourably located to interact with the metal by

their side chain carboxylic groups (Fig 7) Moreover, two

other amino acids (H266 and R269, PFL numbering), even

if different from the corresponding residues of BCL and

PAL, have a proper structural orientation of the backbone

carbonyl groups to bind the metal ion However, some

subtle differences in the Ca2+coordination environment are

observed in the three considered lipases In PAL (and BCL),

one of the water molecules coordinated to the Ca2+ion is

also involved in hydrogen bonds with the side-chains of

S211 and D212 (S244 and T245 in BCL) In PFL, these

residues are substituted by L219 and H220 Due to the

hydrophobic nature of leucine, the binding energy of the

water molecule is expected to be smaller in PFL than in

PAL and BCL Moreover, in BCL a water molecule

interacts with a large loop (A213–N239) and is coordinated

to the Ca2+ion In PAL the corresponding loop (S202–

F207) is shorter and the water molecule in the coordination

sphere of the metal is substituted by the OH group of T205

In PFL, the loop (A210–L215) has geometry features

similar to PAL but T205 is substituted by the hydrophobic

residue L213, suggesting a weaker coordination to the metal

ion

The enzyme–substrate interaction has been studied in

detail for PAL and BCL crystallized in complex with the

same tryglyceride-like inhibitor [11,14] For both enzymes,

the substrate binding pocket has been shown to consist of a

cleft mostly lined by hydrophobic amino-acid side chains

and residues relevant for substrate recognition have been

identified In this context, a comparison between PFL and

BCL shows important differences in their preference

towards short and long chain acyl substrates A structural comparison suggests features that are responsible for these differences Interesting substitutions are located at the entrance of the substrate binding funnel (V123 with L119 and F249 with R224) and within the binding pocket where T18, F119, A247 and T251 in BCL are substituted in PFL

by F, L, N and V residues, respectively Site-directed mutagenesis is required to elucidate the relevance of the observed aminoacid substitutions

PFL structure was then analysed with the aim of explaining PFL activity at low temperature observed in this study The path followed during evolution to design cold adapted enzymes is still not completely understood However, the number of disulphide bridges, the location of proline and arginine residues, and hydrophobic core interactions are generally recognized as key factors in determining the flexibility of the enzyme molecule and, as a consequence, its catalytic activity at different temperatures [2] One of the most striking differences between PAL, BCL and PFL concerns the number of arginine residues, 11, 9 and 24, respectively In PFL, 20 out of 24 arginine residues are almost evenly distributed on the surface of the protein (Fig 6) and only two of them are involved in intramolecular salt bridges Therefore, PFL is characterized by the abundance of charged residues on the surface which enhances flexibility and ability of interaction with the solvent [3] Both factors are of importance for cold activity

On the other hand, the presence of disulphide bridges may increase the rigidity of the protein backbone and therefore its thermostability [35] Interestingly, the only disulphide bridge present in BCL and PAL is missing in the PFL, where only one cysteine residue is present Recently, it has been shown that CysfiSer mutants of PAL are more sensitive to heat denaturation, confirming a stabilizing role for the PAL disulphide bond [36] Moreover, the analysis of the three-dimensional structure of PFL allow to observe that two aromatic residues (W184 and F244), that struc-turally correspond to the disulphide bridge in BCL, are involved in a stacking interaction (Fig 8), with a moderate stabilizing effect on this portion of the protein Finally, distribution of proline residues was considered, as it has been suggested that conformationally rigid proline residues

in loops and turns might increase the rigidity of a protein and decrease its catalytic efficiency at low temperature [35] PAL, BCL and PFL all contain 13 proline residues, eight of which are located in conserved regions Other prolines are mainly located in loop regions of PAL and BCL, whereas only one is in a loop in PFL Again, this suggests an increased conformational flexibility for the latter enzyme

C O N C L U S I O N S

The P fragi lipase characterized in this study is a new example of cold-active lipase and provides a model for studying the molecular basis of cold adaptation In fact, comparison of proteins from organisms belonging to divergent evolutionary lineages might confuse the analysis

of structural differences of relevance which are masked by substitutions arose from evolutionary divergence [37] Other examples of psychrophilic lipases are reported in the literature, one of which has been cloned from Pseudomon-ads However, such lipases are related in sequence to each other but not to any mesophilic lipase In contrast, PFL can

be classified in a group of bacterial lipases well

character-ized from the biochemical and structural point of view

Comparison of the three-dimensional model with the

structures of mesophilic homologous lipases accounts for

PFL activity at low temperature, in the frame of the largely

accepted assumption that relates cold adaptation to changes

in the protein conformational flexibility This study

high-lights relevant features in the PFL structure, such as a

reduced number of disulphide bridges and of prolines in

loop structures Arginine residues are distributed differently

than in mesophilic enzymes, with only a few residues

involved in stabilizing intramolecular salt bridges and a

large proportion of them exposed at the protein surface and

therefore able to interact with the solvent enhancing

flexibility

A C K N O W L E D G E M E N T S

This work was supported by a grant of the Progetto Finalizzato

Biotecnologie of the Italian National Research Council to L A We

also acknowledge contribution from the Vigoni Program The authors

wish to thank K.-E Jaeger for helpful discussion and for providing the

P aeruginosa foldase-encoding gene.

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