Báo cáo Y học: Arginine 121 is a crucial residue for the specific cytotoxic activity of the ribotoxin a-sarcin potx

Arginine 121 is a crucial residue for the specific cytotoxic activity of the ribotoxin a-sarcin Manuel Masip, Javier Lacadena*, Jose´ Miguel Manchen˜o, Mercedes On˜aderra, Antonio Martı´

Arginine 121 is a crucial residue for the specific cytotoxic activity of the ribotoxin a-sarcin

Manuel Masip, Javier Lacadena*, Jose´ Miguel Manchen˜o, Mercedes On˜aderra, Antonio Martı´nez-Ruiz†, A´lvaro Martı´nez del Pozo and Jose´ G Gavilanes

Departamento de Bioquı´mica y Biologı´a Molecular, Facultad de Quı´mica, Universidad Complutense, Madrid, Spain.

a-Sarcin, a cyclizing ribonuclease secreted by the mould

Aspergillus giganteus, is one of the best characterized

members of a family of fungal ribotoxins This protein

induces apoptosis in tumour cells due to its highly specific

activity on ribosomes Fungal ribotoxins display a

three-dimensional protein fold similar to those of a larger group of

microbial noncytotoxic RNases, represented by RNases T1

and U2 This similarity involves the three catalytic residues

and also the Arg121 residue, whose counterpart in RNase

T1, Arg77, is located in the vicinity of the substrate

phos-phate moiety although its potential functional role is not

known In this work, Arg121 of a-sarcin has been replaced

by Gln or Lys These two mutations do not modify the conformation of the protein but abolish the ribosome-inactivating activity of a-sarcin In addition, the loss of the positive charge at that position produces dramatic changes

on the interaction of a-sarcin with phospholipid membranes

It is concluded that Arg121 is a crucial residue for the characteristic cytotoxicity of a-sarcin and presumably of the other fungal ribotoxins

Keywords: Aspergillus protein; cytotoxin; protein – lipid interaction; ribotoxin; a-sarcin

a-Sarcin is the best characterized member of a family of

fungal cytotoxic ribosome-inactivating proteins (ribotoxins)

that cleave one single phosphodiester bond at an

evolu-tionarily conserved sequence of the larger rRNA [1],

impair-ing the bindimpair-ing of elongation factors EF-1 and EF-2 [2]

This well known exquisite ribonucleolytic action in cell-free

systems has been also recently observed in intact cells,

namely human rhabdomyosarcoma cells, where the toxic

effect produces cell death via apoptosis [3] a-Sarcin is

internalized by the target cells via endocytosis involving

acidic endosomes and the Golgi [3,4] This traffic might be

related to the known ability of a-sarcin to interact with

model membranes In fact, besides its specific ribonuclease activity, this highly polar protein binds to acidic lipid vesicles promoting their aggregation and fusion [5,6] and resulting in translocation of the protein across the model membranes [7,8] Ribotoxins of the a-sarcin family display a high degree of sequence similarity although they are secreted by a variety

of different moulds [9 – 11], i.e restrictocin and mitogillin, two other members of this family, display 85% sequence identity to a-sarcin, which is only one residue longer [12–14] These ribotoxins belong to a larger group of micro-bial extracellular RNases, represented by the noncytotoxic RNases T1 and U2 [10,11,15], based on their sequence and three-dimensional structure similarities Thus, a-sarcin [15], restrictocin [16] and RNase T1 [17] display an identical architecture and connectivity of the secondary structure elements in the three proteins The catalytic mechanisms of a-sarcin and RNase T1 are similar [18 – 20] and related to that of bovine pancreatic RNase A [21] They behave as cyclizing RNases, the overall reaction being composed of two steps, cyclization followed by cleavage of the 20,30 -cyclic product formed [18,21 – 23] In RNase T1, His92 acts

as the general acid and Glu58 as the general base during the first step of the reaction The hydrolysis of the cyclic derivative is performed by the same groups, but their roles are reversed [23] In a-sarcin the same roles are fulfilled by His137 and Glu96, although differences between the two enzymes regarding the individual pKa values of these catalytic residues and optimum pH have been observed [19,20] Analysis of the three dimensional structure of RNase T1 complexed with different inhibitors or substrate analogues has revealed the presence of some other side chains in the vicinity of the substrate phosphate moiety [22,24] This is the case for His40 and Arg77, their counter-parts in a-sarcin being His50 and Arg121 [10,11] occupying geometrically conserved positions [15,25] (Fig 1) Site-directed mutagenesis experiments have revealed that His40

Correspondence A Martı´nez del Pozo or J G Gavilanes,

Departamento de Bioquı´mica y Biologı´a Molecular I, Facultad de

Quı´mica, Universidad Complutense, 28040 Madrid, Spain.

Fax: 1 34 91 3944159, Tel.: 1 34 91 3944158,

E-mail: alvaro@bbm1.ucm.es or ppgf@bbm1.ucm.es

Enzymes: mitogillin and restrictocin (RNMG_ASPRE, P04389,

EC 3.1.27.-); ribonuclease A (RNP_BOVIN, P00656, EC 3.1.27.5);

ribonuclease T1 (RNT1_ASPOR, P00651, EC 3.1.27.3); ribonuclease

U2 (RNU2_ASTSP, P00654, EC 3.1.27.4); a-sarcin (RNAS_ASPGI,

P00655, EC 3.1.27.10) All accession codes are for the SWISS-PROT

data base.

*Present address: Facultad de Biologı´a, Universidad SEK, 40003

Segovia, Spain.

†Present address: Centro de Investigaciones Biolo´gicas, CSIC,

Vela´zquez 144, 28006 Madrid, Spain.

Note: a web page is available at http://www.bbm1.ucm.es

(Received 2 July 2001, revised 4 September 2001, accepted 1 October

2001)

Abbreviations: ApA, adenylyl(30!5 0 )adenosine; Myr 2 GroPGro,

dimyristoylglycerophosphoglycerol; Nbd-Myr 2 GroP Etn,

[N-(7-nitro-2-1,3-benzoxadiazol-4-yl)-dimyristoylglycerophosphoethanolamine;

rhodamine-GroP Etn, N-(lissamine rhodamine B

sulfonyl)-diacylglycerophosphoethanolamine; RNase, ribonuclease.

of RNase T1 [23,26,27] and His50 of a-sarcin [20] are

involved in catalysis rather than in substrate binding The

role of Arg77 has not yet been established as all attempts to

isolate any RNase T1 Arg77 mutant have been unsuccessful

[23] Hydroxylamine treatment has been used to produce

point mutations in recombinant mitogillin produced by yeast

[28] Only a few transformants survived upon induction,

suggesting that the affected residues, one of them Arg120

(the counterpart of Arg121 in a-sarcin), has a crucial role in

the ribonucleolytic catalysis [28]

The work herein presented deals with the production,

purification and characterization of two a-sarcin mutants

where Arg121 has been substituted by Lys (R121K) or Gln

(R121Q) The results obtained show that this residue is

involved in the specific ribonucleolytic activity of ribotoxins

against ribosomes and also in the interaction with

membranes

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

DNA manipulations

All materials and reagents were of molecular biology grade

Cloning procedures and bacteria manipulations were carried

out according to standard methods [29] as described

pre-viously [20,30,31] Oligonucleotide site-directed

mutagen-esis was used to replace Arg121 with Lys (R121K) or Gln

(R121Q) as described previously [20,30 – 32] The

muta-genic primers used were 50-CCTGGCCCGGCGAAGGTCA

CAGGTCATCTACACC-30for R121Q (the site of mutation

is underlined) The E coli strains used were BW313

{(HfrKL16 pol45 [LysA (61 – 62)] dut1 ung1 thi1 relA1] to

obtain the uridine-rich ssDNA, DH5aF0({[F0] endA1 hsdR17

(rK– mK–) supE44 thi-1 recA1 gyrA (NaIR) relA1

D(lac-ZYA-argF ) U169 deoR [B80 dLac D(lacZ ) M15]}) to

obtain the expression constructs, and BL21(DE3)(F0

ompT[lon] hsdB (rB– mB–)) to produce the proteins The

thioredoxin producing plasmid (pT-Trx) [33] was a generous

gift of S Ishii, from the Riken Tsukuba Life Science Center

(Riken, Japan)

Proteins production and purification

BL21(DE3) cells cotransformed with pT-Trx and the

corre-sponding a-sarcin mutant plasmid were used to produce the

mutant proteins, which were purified as described for the

wild-type protein [30,34] Fungal wild-type a-sarcin was

produced and purified as previously reported [30,35,36]

Polyacrylamide electrophoresis, tryptic digestions, acid

hydrolysis of proteins, peptide maps, and amino-acid

analysis were also performed according to standard

pro-cedures described previously [20,30,35,37]

Spectroscopic characterization

Proteins were dissolved in either 50 mMsodium phosphate,

pH 7.0, or 50 mM sodium acetate, pH 5.0, both containing

0.1M NaCl, as required and centrifuged at 14 000 g for

5 min Absorbance measurements were carried out on a

Uvikon 930 spectrophotometer at 100 nm:min21scanning

speed, at room temperature, and in 1-cm optical-path cells

CD spectra were obtained on a Jasco 715 spectropolarimeter

Fig 1 Diagrams corresponding to the three-dimensional structure

of a-sarcin constructed from the atomic coordinates deposited in the PDB (accession code [1DE3], http://www.rcsb.org/pdb) Images were generated by the MOLMOL program [52] (A), Ribbon diagram of the whole protein molecule where selected residues (His50, Glu96, His137, Arg121, in black; Tyr48, Trp51, Tyr106, in grey) are shown (B), Detail of the residues not labelled in part A (C), Active site residues of a-sarcin (black)/RNase T1 (grey), after fitting of the backbone atoms of the residues involved in the five-strands central b sheet of both proteins The protein view is maintained through the three diagrams.

at 0.2 nm:s21scanning speed; 0.1- and 1.0-cm optical-path

cells were used in the far- and near-UV wavelength range,

respectively Mean residue weight ellipticities were

expressed in units of degrees:cm2:dmol21 Extinction

coef-ficients E0.1%(280 nm, 1-cm optical path) were calculated

from the corresponding absorbance spectra and amino-acid

analyses Thermal denaturation profiles were obtained by

measuring the temperature dependence of the ellipticity at

220 nm in the range of 25 – 85 8C; the temperature was

continuously changed at a rate of 0.5 8C:min21 The

tem-perature values at the midpoint of the thermal transition (Tm)

were calculated assuming a two-state unfolding mechanism

[38 – 40] Fluorescence emission spectra were obtained on a

SLM Aminco 8000 spectrofluorimeter at 25 8C in 0.2-cm

optical-path cells, as described previously [20]

Ribonucleolytic activity

The specific ribonucleolytic activity of a-sarcin against intact

ribosomes was followed by detecting the release of the 400

nucleotide a-fragment [1,41,42] from a cell-free

reticulo-cyte lysate (Promega) as described previously [20,30,31]

The production of the 400 nucleotide a-fragment was

visualized by ethidium bromide staining after

electrophor-esis on 2.4% agarose The activity of the purified proteins

against polyadenylic acid was assayed after subjecting the

samples to an electrophoretic procedure in 15%

polyacryl-amide gels containing 0.1% SDS and 0.3 mg:mL21poly(A)

This method, designated as a zymogram, was based on one

previously described [31,43] Proteins exhibiting ribonuclease

activity appear as colourless bands after proper destaining

treatment Hydrolysis of adenylyl(30!50)adenosine (ApA)

by a-sarcin and the mutant variants was performed as

described elsewhere [18] at pH 5.0 The reaction products

were resolved by HPLC with a phosphate-methanol gradient

as described [18,44] All of these assays were performed

with the corresponding controls to test potential nonspecific

degradation of the substrates, which did not occur under the

conditions used

Protein– lipid interactions

Dimyristoylglycerophosphoglycerol (Myr2GroPGro) was

purchased from Avanti Polar Lipids Inc Vesicles were

formed by hydrating a dry lipid film with Tris buffer (15 mM

Tris, pH 7.5, containing 0.1M NaCl and 1 mMEDTA) for

60 min at 37 8C The lipid suspension was subjected to five

cycles of extrusion through two stacked 0.1 mm (pore

diameter) polycarbonate membranes [45] The average

diameter of the vesicle population was 100 nm (85% of the

vesicles in the range 75 – 125 nm), as determined by electron

microscopy studies [45] Phospholipid concentration was

determined as described [46] Aggregation of phospholipid

vesicles was monitored by measuring the increase in the

absorbance at 360 nm of a suspension of Myr2GroPGro

vesicles in Tris buffer (30 mM final lipid concentration)

after addition of a small aliquot of a freshly prepared

solution of protein [5] Intermixing of membrane lipids was

measured by fluorescence energy transfer assays [47] as

described [45,48] A decrease in the donor-to-acceptor,

[N-(7-nitro-2-1,3-benzoxadiazol-4-yl)-dimyristoylglycero-phosphoethanolamine (Nbd-Myr2GroP Etn) and N-(lissamine

rhodamine B sulfonyl)-diacylglycerophosphoethanolamine

(rhodamine-GroP Etn), respectively, fluorescence energy transfer indicates lipid-mixing between membranes Bind-ing of the proteins to the lipid vesicles was analysed by measuring the free protein concentration in the supernatant obtained by centrifugation (160 000 g for 20 min, Beckman Airfuge) of protein – vesicle mixtures at different protein/ lipid ratios In this particular case, the buffer used was

15 mM Mops, pH 7.0, containing 0.1M NaCl and 1 mM

EDTA The protein concentration was calculated by densitometering the Coomasie-stained SDS-gels resulting from subjecting supernatant aliquots to SDS/PAGE A calibration plot, volumogram obtained (density or quantity

of a spot calculated from its volume made of the sum of all pixel intensities composing the spot obtained with a photo documentation system UVI-Tec using the software facility

UVISOFT UVI BAND) vs protein concentration (determined

by amino-acid analysis of acid-hydrolysed protein samples) was used for these calculations Other experimental details were as reported previously [45,48,49] Control assays without protein were always performed

R E S U L T S Purification and structural characterization Both mutant variants of a-sarcin, R121K and R121Q, were purified to homogeneity according to their behaviour on SDS/PAGE, and displayed a single immunoreactive band when stained with anti-(a-sarcin) Ig in Western-blots ana-lysis Yields were about 5.0 mg per litre of E coli culture for the R121K variant but much lower for R121Q (less than 0.3 mg per L) Amino-acid analysis as well as tryptic map of the purified mutants were consistent with the residue substitutions planned The calculated E0.1%(280 nm, 1-cm optical path) were 1.30 and 1.12 for R121K and R121Q, respectively, in reasonable agreement with the value of 1.34 reported for the wild-type protein [37] The far-UV CD spectra of both mutant variants were indistinguishable from that already reported for the natural fungal a-sarcin [20,30,36,37] (Fig 2A) Small differences were observed

in the near-UV wavelength range (Fig 2B) Only minor differences were also observed in terms of protein

Fig 2 Circular dichroism spectra of fungal wild-type a-sarcin (X) and its R121K (W) and R121Q (K) mutant variants (A) Far- and (B) near-UV Mean residue weight ellipticities (u MRW ) are expressed in units of degrees:cm2:dmol 21

.

fluorescence emission Thus, the fluorescence emission of

R121K coincided with that of the wild-type protein while

R121Q showed identical Trp emission but an increased

(1.5-fold) tyrosine contribution (Fig 3)

R121K and R121Q displayed a decreased stability in

comparison to the wild-type protein Denaturation of these

proteins was studied by analysing the thermal variation

of their far-UV circular dichroism properties (Fig 4) The

Tm value for the wild-type protein was 62 8C at pH 5.0,

the optimum pH for both enzyme activity and stability

[19,20,50] The Tm of the R121K and R121Q mutant

variants was 56 8C and 53 8C, respectively, which

corre-sponded to a decreased stability of 8.36 and 12.54 kJ:mol21,

respectively, according to the calculated DDG values

Enzymatic characterization

Neither of the two mutants produced the a-fragment

result-ing from the specific ribonucleolytic activity of these fungal

ribotoxins against ribosomes Forty nanograms of the wild-type protein was enough to completely release the a-fragment from the larger rRNA under the standard assay conditions [20,30,31], but no cleavage was observed even when 100 ng

of the mutant variants were assayed In addition, although wild-type a-sarcin degrades polyadenylic acid on a zymo-gram assay, R121K and R121Q did not cleave the homo-polynucleotide even when 500 ng of protein were assayed, the lowest detection limit of this assay being 50 ng of wild-type protein [20] A quantitative analysis of the ribonuclease activity of a-sarcin has been developed by using the dinucleotide ApA as substrate [18] Both mutant variants hydrolysed ApA They displayed a Km value similar to that of the wild-type protein although they exhibited a lower catalytic efficiency (Table 1), thus suggesting that the mutated residue is involved in catalysis rather than in substrate binding

Interaction with phospholipid vesicles The interaction of a-sarcin with model phospholipid vesicles through electrostatic and hydrophobic interactions

is well documented The ribotoxin promotes aggregation of vesicles and mixing of phospholipids from different bilayers [5,6] The mutant variant R121K promoted the same effects than the wild-type protein and these became saturated at the same protein/phospholipid molar ratio, although R121K displayed a slightly higher affinity for the target vesicles (1.3-fold that of the wild-type protein) (Fig 5) However,

Fig 3 Fluorescence emission spectra of wild-type a-sarcin (WT) and its R121K and R121Q mutant variants (1), Fluorescence emission spectra for excitation at 275 nm; (2), fluorescence emission spectra for excitation at 295 nm (tryptophan contribution) normalized at wavelengths above 380 nm where the tyrosine emission is negligible; (3) calculated difference spectra of (1) minus (2) (tyrosine contribution) Fluorescence emission is expressed in arbitrary units considering the intensity at the wavelength of the emission maximum of the wild-type protein for excitation at

275 nm as 1.0.

Fig 4 Thermal denaturation profiles of fungal wild-type a-sarcin

(X) and its R121K (W) and R121Q (K) mutant variants.

Measurements were performed by continuously recording the mean

residue weight ellipticity at 220 nm, expressed in units of

degrees:cm2:dmol 21

.

Table 1 Activity of a-sarcin and its mutant variants against ApA at

pH 5.0 Kinetic parameters (^ SD) determined from the transesterifi-cation of ApA by linear regression analysis of double reciprocal plots from three different determinations [18].

Protein K m (m M ) k cat (s21) k cat /K m ( M21:s 21

) Wild-type 40 ^ 4 (27.0 ^ 1.0)  10 25 6.7 ^ 0.7 R121K 36 ^ 4 (1.2 ^ 0.2)  1025 0.3 ^ 0.1 R121Q 27 ^ 4 (7.9 ^ 0.3)  1025 2.3 ^ 0.4

R121Q exhibited a low affinity, 0.2-fold that of the

wild-type a-sarcin, which corresponded to a very low affinity to

aggregate vesicles and promote lipid-mixing between

bilayers (Fig 5)

D I S C U S S I O N

Both purified mutant forms of a-sarcin display the same

global fold as the wild-type protein according to the

spec-troscopic and structural characterization performed Thus,

the modified activities of these mutants to cleave RNA

substrates or to interact with phospholipid vesicles cannot be

considered as a consequence of an altered native

confor-mation In fact, no secondary structure variations have been

detected and only slight differences were observed in terms

of extinction coefficient and environment of aromatic amino

acids (near-UV circular dichroism and fluorescence

emission spectra) Tyr48, Trp51 and Tyr106 are located in the vicinity of the mutated 121st position (their a-carbons are about 11 A˚ distant in the same side of the central b sheet

of the protein) (Fig 1) [15] Thus, such differences might be attributed to changes in the local environment of these residues In fact, the side-chain of Trp51 has been proven to

be responsible for most of the ellipticity signal of a-sarcin observed in the near-UV wavelength region but it does not show fluorescence emission [51] Therefore, the near-UV ellipticity variations observed for both mutant variants arise from local changes affecting Trp51, while the change on the fluorescence of R121Q, 1.5-fold increased Tyr emission, is related to Tyr48 and/or Tyr106

Both mutant variants were isolated in a very different yield (< 5 mg:L21 and < 0.3 mg:L21 for R121K and R121Q, respectively), but this cannot be related to a differ-ent protein stability Although mutation results in a less stable protein form, the stability change DDG is similar in both cases, 28.36 and 212.54 kJ:mol21 for R121K and R121Q, respectively

The cytotoxic action of a-sarcin can be dissected into two different steps First, the protein must enter the cells, crossing the phospholipid bilayer barrier This inter-nalization occurs in the target cells by endocytosis [3], which would require a membrane interaction Further, the toxin cleaves ribosomes, impairing protein biosynthesis and producing cellular death via apoptosis [3] Conse-quently, both abilities have been studied for R121Q and R121K

Substitution of Arg121 by Lys or Gln abolishes the activity of a-sarcin to release the a-fragment from ribosomes This lack of ribonuclease activity against the specific substrate is also observed against the homopoly-nucleotide poly(A) These results indicate that this residue plays an important role in the rRNA catalytic cleavage by a-sarcin, which would not be simply related to the bearing positive charge Both mutant variants of a-sarcin cleave ApA, with slight variation in the Km value but kcatbeing reduced by about one order of magnitude (Table 1) A very similar result has been obtained before for the H50Q variant, while mutation of either Glu96 or His137, residues acting as the general acid and base on the catalysis by a-sarcin [19,20], rendered proteins with no detectable activity against ApA [20] Cleavage of ApA by a-sarcin is a low-specificity reaction requiring high amounts of protein and long incu-bation times [18] Thus, using this dinucleotide substrate only allows us to obtain information about the minimal requirements needed for a-sarcin to cleave a phosphodiester bond but it appears to be a more sensitive assay than those using rRNA or poly(A) From this point of view, this Arg residue although not essential for catalysis would contribute

to position the substrate in the optimum conformation for cleavage In fact, in the crystal structure of restrictocin the active site residues His49, Glu95, Arg120 and His136 (equivalent to His50, Glu96, Arg121 and His137 in a-sarcin) cluster together and point towards a tetrahedral-shaped electron density which was interpreted as an inorganic phosphate group derived from the crystallization buffer [16]

A very similar situation occurs with Arg77 in the active site

of RNase T1, where the phosphate group can accept hydrogen bonds from Arg77(N1H/NhH) [22 – 24], although its role in catalysis has not been elucidated because no mutant forms at this position have been obtained [23] Thus,

Fig 5 Effect of fungal wild-type a-sarcin (X) and its R121K (W)

and R121Q (K) mutant variants on phosphatidylglycerol vesicles.

(A), Protein binding to the vesicles Protein bound is expressed as

percentage of the total protein present in the assay vs phospholipid/

protein molar ratio (B), Aggregation of lipid vesicles Aggregated

vesicles scatter more light than the un-aggregated vesicles and the

process can be measured from the resulting apparent DA 360 promoted

by the proteins in a vesicle suspension Results are expressed as relative

DA 360 values, considering the maximum increase produced by the

wild-type protein as unit, vs protein/phospholipid molar ratio (C),

Lipid-mixing from different bilayers This assay is performed with a mixture

of fluorescence-labelled and unlabelled vesicles (1 : 9 ratio, labelled to

unlabelled, respectively) The lipid mixing results in dilution of the two

fluorescence probes and consequently in decrease of the relative

fluorescence energy transfer (RET) Results are expressed as relative

RET values, considering the maximum decrease produced by the

wild-type protein as unit, vs protein/phospholipid molar ratio In all cases,

the results shown are the average of three independent experiments.

in the absence of the Arg guanidinium group, the protein

would not be able to accommodate polymeric RNA, such

as rRNA or poly(A), in the proper conformation within the

active site ApA, a much smaller substrate, would fit more

easily into the cleavage pocket although not under optimal

structural constraints This would explain the observed

reduction in kcat In fact, it has been already proposed

that the mechanism of action of a-sarcin against

ribo-somes might differ in some details from that against

dinuc-leotides [18,19] The behaviour of a-sarcin against ApA as a

function of pH, altogether with the characterization of the

individual pKa values of the active site residues, were

consistent with the existence of two mechanisms for the

hydrolysis of ApA with different optimum pH and

different orientations for the dinucleotide within the active

site [19]

The ability of R121K and R121Q variants to interact with

phospholipid model membranes was studied by analysing

their ability in aggregating vesicles and mixing

phospho-lipids from different vesicles The results obtained indicate

that the loss of a positive charge in the position

corre-sponding to Arg121 side-chain has a dramatic effect on the

a-sarcin– membrane interaction Regarding to this, the region

around Trp51, located at around 11 A˚ from position 121,

is involved in the interaction with the lipid bilayer, as

this Trp residue is located in the hydrophobic core of the

bilayer following protein – vesicle interaction [51] The

membrane affinity of R121Q is largely diminished, while

that of R121K is not modified (Fig 5A) The decreased

binding affinity of the R121Q mutant is correlated with a

reduced ability to aggregate lipid vesicles that requires the

formation of vesicle–protein–vesicle complexes [45]

Conse-quently, the lipid-mixing from different bilayers within the

vesicle aggregates also occurs in a very reduced extent

(Fig 5C)

From the results obtained, it can be concluded that

Arg121 of a-sarcin, a conserved residue in its fungal

ribo-toxins family, plays a crucial role in the cytoxicity shown by

this protein Firstly, because this residue is required for the

specific ribonuclease activity of the protein against

ribo-somes and secondly, because this residue is essential for the

binding of the protein to the membranes which would be a

required step in crossing the cell membrane barrier via

endocytosis This essential character of Arg121 for

mem-brane binding may be a consequence of its essential role in

the ribonucleolytic mechanism The dramatic membrane

affinity decrease due to the loss of only one positive charge

in a protein with 24 basic residues and 17 acid residues [12]

and its location at the ribonucleolytic active site may suggest

some kind of relationship It would not be unreasonable to

assume that proteins evolved to interact with nucleic acids,

such as RNases, would have developed structural

deter-minants to recognize polyphosphate lattices, i.e RNA, and

this ability, in some cases, may allow a recognition of

phospholipid surfaces, considered as two-dimensional

phosphate networks

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

This work has been supported by grant BMC2000-0551 from Direccio´n

General de Investigacio´n (Ministerio de Ciencia y Tecnologı´a), Spain.

M M is recipient of a fellowship from Ministerio de Educacio´n,

Cultura y Deporte, Spain.

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