Tài liệu Báo cáo khoa học: The Mycobacterium tuberculosis membrane protein Rv2560 ) biochemical and functional studies pdf

This makes the Keywords high-activity binding peptide; invasion inhibition; Mycobacterium tuberculosis – host cell interaction; Rv2560 membrane protein Correspondence M.. Peptide 11024 1

Rv2560 ) biochemical and functional studies

David F Plaza1, Hernando Curtidor2,4, Manuel A Patarroyo1,4, Julie A Chapeton-Montes1,

Claudia Reyes3, Jose Barreto3and Manuel E Patarroyo1,5

1 Molecular Biology Department, Fundacion Instituto de Inmunologia de Colombia, Bogota, Colombia

2 Receptor–Ligand Department, Fundacion Instituto de Inmunologia de Colombia, Bogota, Colombia

3 Chemical Synthesis Department, Fundacion Instituto de Inmunologia de Colombia, Bogota, Colombia

4 Universidad del Rosario, Bogota, Colombia

5 Universidad Nacional de Colombia, Bogota, Colombia

Tuberculosis (TB) is a major public health problem

throughout the world, affecting almost nine million

people [1] and causing more than three million deaths

per year An increasing incidence of TB, related to the

high risk of developing the disease in immuno-suppressed individuals and the increasing proportion

of Mycobacterium tuberculosis drug-resistant strains, has contributed to this problem [2,3] This makes the

Keywords

high-activity binding peptide; invasion

inhibition; Mycobacterium tuberculosis –

host cell interaction; Rv2560 membrane

protein

Correspondence

M E Patarroyo, Carrera 50 # 26-00,

Bogota, Colombia

Fax: +57 (1) 4815269

Tel: +57 (1) 4815219 or +57 (1) 3244672

Ext 125

E-mail: mepatarr@mail.com

(Received 31 July 2007, revised 11 October

2007, accepted 17 October 2007)

doi:10.1111/j.1742-4658.2007.06153.x

The characterization of membrane proteins having no identified function in Mycobacterium tuberculosis is important for a better understanding of the biology of this pathogen In this work, the biological activity of the Rv2560 protein was characterized and evaluated Primers used in PCR and RT-PCR assays revealed that the gene encoding protein Rv2560 is present

in M tuberculosis complex strains, but transcribed in only some of them Sera obtained from rabbits inoculated with polymer peptides from this pro-tein recognized a 33 kDa band in the M tuberculosis lysate and a mem-brane fraction corresponding to the predicted molecular mass (33.1 kDa)

of this protein Immunoelectron microscopy analysis found this protein on the mycobacterial membrane Sixteen peptides covering its entire length were chemically synthesized and tested for their ability to bind to A549 and U937 cells Peptide 11024 (121VVALSDRATTAYTNTSGVSS140) showed high specific binding to both cell types (dissociation constants of

380 and 800 nm, respectively, and positive receptor–ligand interaction cooperativity), whereas peptide 11033 (284LIGIPVAALIHVYTYRKLS GG304) displayed high binding activity to A549 cells only Cross-linking assays showed the specific binding of peptide 11024 to a 54 kDa membrane protein on U937 Invasion inhibition assays, in the presence of shared high-activity binding peptide identified for U937 and A549 cells, presented maximum inhibition percentages of 50.53% and 58.27%, respectively Our work highlights the relevance of the Rv2560 protein in the M tuberculosis invasion process of monocytes and epithelial cells, and represents a funda-mental step in the rational selection of new antigens to be included as components in a multiepitope, subunit-based, chemically synthesized, anti-tuberculosis vaccine

Abbreviations

GRAVY, grand average of hydropathicity; HABP, high-activity binding peptide; SPf66, synthetic Plasmodium falciparum 66; SSP, simple sequence protein; TB, tuberculosis.

development of new therapies and⁄ or vaccines, or the

improvement of existing ones, necessary to control this

disease

The identification and characterization of the

pro-teins involved in the interaction of M tuberculosis with

its target cells and the mechanisms for evading an

immune response produced against this pathogen are

thus of crucial interest Of special interest are those

proteins found on the cell membrane and in the

secreted fraction, as they represent the ‘face’ shown by

the bacterium to its host, thereby leading to its

identifi-cation and elimination

Although TB is mainly a pulmonary disease, it can

also affect other organs Few microorganisms can

sur-vive within macrophages because of the abundance of

hydrolytic enzymes contained in acid phagocytic

com-partments [4] M tuberculosis has developed

evolution-ary mechanisms that allow it to penetrate, survive and

grow within these compartments [5] Adhesion and

phagocytosis are the initial steps in the entry of the

bacterium into macrophages, processes triggered by

receptor–ligand interactions These interactions are

complex and have an important influence on the

intra-cellular fate of M tuberculosis [6,7], being mediated

mainly by membrane proteins present on the bacillus

and its host [8] The M tuberculosis cell membrane,

and that of other prokaryotes, contains proteins

func-tioning as enzymes, ligands, signal transducers or

viru-lence factors, all of great importance for bacterial

survival [9]

M tuberculosis invades alveolar epithelial cells,

thereby inducing macropinocytosis, using secreted or

membrane components [10] The identification of the

bacterial peptides involved in this process has been

poorly studied, and represents an objective of this

work

Membrane proteins represent a bank of antigens

available for the design of a subunit-based,

multiepi-tope vaccine, as they may be involved in the

patho-genicity of the bacterium and may also be highly

susceptible to immune recognition The M tuberculosis

membrane proteome has revealed the presence of

mul-tiple immunogenic components with unknown function

[11–13], which could be used for this purpose

Bioinformatics represents a preliminary method for

the evaluation of the presence of a determined gene or

protein sequence in different organisms, and for

pre-dicting (with some degree of confidence) the existence

of membrane anchoring or signal export regions within

them, making it a fundamental tool when screening

and⁄ or selecting for a vaccine candidate [14,15]

Fur-thermore, work carried out on the proteomics of the

bacterium has led to the identification of a large

number of membrane proteins with an as yet undeter-mined function [11–13]

A previous study has shown the importance of the melA gene (encoding an Rv2560 homologous protein)

in Mycobacterium marinum invasion of THP-1 cells, indicating that its homologous gene might be relevant

in M tuberculosis–host cell interaction [16]

This work has led to the identification of the pres-ence of the Rv2560 proline- and glycine-rich trans-membrane protein encoding gene and its transcripts in the M tuberculosis complex and clinical isolate strains,

as well as the characterization of the high-activity binding peptide (HABP) involved in the binding to and invasion of monocytes (U937) and type II alveolar epithelial cells (A549), using synthetic peptides The protein encoded by the Rv2560 gene was synthesized

in 20-mer-long, nonoverlapping peptides, which were analysed by a highly specific and robust methodology (widely used in Plasmodium falciparum research) for the identification of the HABPs interacting with U937 and A549 cells (in this case), their binding dissociation constants, their critical binding residues and their role

in cell invasion inhibition, with the specific purpose of employing them as probable components of a multiepi-tope, subunit-based, synthetic vaccine This has impor-tant biological significance and implications for the development of strategies to control this disease

Results

Bioinformatic analysis Different bioinformatics’ tools were used to predict the cell location of Rv2560 and its transmembrane topol-ogy Although signalp did not predict the existence of

a signal peptide, the high grand average of hydropath-icity (GRAVY) value (0.488) and the existence of four possible transmembrane helices in the complete Rv2560 amino acid sequence suggested its presence on the bacterial surface Membrane topology prediction proposed four transmembrane helices (i103–125o, o145–167i, i197–228o and o271–293I, where i denotes inside and o denotes outside), suggesting that the iden-tified HABPs are located in the protein’s solvent-exposed region (Fig 4, topology diagram, see later)

Genomic PCR assay Two specific primers, flanking an HABP region (encoding amino acids 80–290), were designed and syn-thesized to determine the presence or absence of the gene encoding the Rv2560 protein in M tuberculosis complex strains A single 631 bp amplification band

was observed in the following strains: M tuberculosis

H37Rv, M tuberculosis H37Ra, Mycobacterium bovis,

M bovis BCG, Mycobacterium africanum and

Myco-bacterium microti(Fig 1A, lanes 2–7) tblastn

analy-sis showed similar (although not identical) genes in

M marinumand Mycobacterium ulcerans

DNA sequencing

The amplified fragments in the different clinical

iso-lates studied were purified, and their DNA was

sequenced to determine this region’s polymorphism It

was observed that this region was completely

con-served in all M tuberculosis clinical isolates analysed,

independent of geographical origin This result was confirmed by sequencing each fragment’s complemen-tary chain (data not shown)

RT-PCR assay Two specific primers were designed and synthesized to determine the transcriptional pattern of the Rv2560 gene in M tuberculosis complex strains A single

308 bp amplification band was observed in some

M tuberculosis complex strains (Fig 1B, lanes 2–7) This gene’s transcription was exclusive to M tuberculo-sis H37Rv, M tuberculosis H37Ra, M bovis BCG and

M africanum strains, but not M bovis and M microti, suggesting that it was not transcribed, in spite of this gene being present as assessed by PCR Figure 1C shows a 360 bp conserved fragment from a mycobacte-rial genus constitutive gene (the rpoB gene encoding the RNA polymerase b-subunit) used as transcription control

Western blot Polymerized synthetic peptides corresponding to the Rv2560 protein peptide 11027 (181ADGKPVTIATFF RPRNLGLV200) and 11031 (242SPIDSVKASIETV GSNIGGSVY262) amino acid sequences, located in the extracellular solvent-exposed region (as predicted

by the TMHMM server), were used as immunogens in rabbits, employing a 0, 20 and 40 day inoculation scheme Western blot (Fig 2) was performed with preimmune and post-third inoculation rabbit sera against M tuberculosis sonicate and membrane frac-tion Sera had previously been adsorbed on columns with Escherichia coli and Mycobacterium smegmatis lysates, as well as synthetic Plasmodium falcipa-rum 66 (SPf66), prior to western blotting to eliminate the cross-reactivity against bacterial (E coli), myco-bacterial (M smegmatis) and polymerization (SPf66) neo-antigens

Lanes 1 and 3 in Fig 2 show the lack of preimmune rabbit sera protein recognition in the M tuberculosis sonicate and membrane fraction, respectively Rabbits immunized with 11031 polymerized peptide developed polyclonal antibodies specifically recognizing a 33 kDa molecular mass band in the M tuberculosis sonicate, close to the protein’s molecular mass (33.1 kDa) in lane 2 Preimmune serum (lane 3) did not recognize bands in the membrane fraction; however, postimmune serum from 11027 immunized rabbits strongly recog-nized a band close to 33 kDa in this fraction (lane 4), suggesting that this protein becomes enriched in the cell membrane

Fig 1 Genomic PCR and RT-PCR assays (A) A 631 bp PCR

prod-uct from the gene encoding M tuberculosis H37Rv Rv2560 protein

was only amplified on DNA from M tuberculosis complex strains

(lanes 2–7) Lane 1, 1 kb molecular weight marker (Gibco); lane 2,

M tuberculosis H37Rv; lane 3, M tuberculosis H37Ra; lane 4,

M bovis; lane 5, M bovis BCG; lane 6, M africanum; lane 7,

M microti; lane 8, PCR negative control (B) M tuberculosis

Rv2560 protein H37Rv 308 bp RT-PCR product obtained from

M tuberculosis complex strain cDNA Lane 1, 1 kb molecular

weight marker (Gibco); lane 2, M tuberculosis H37Rv; lane 3,

M tuberculosis H37Ra; lane 4, M bovis; lane 5, M bovis BCG;

lane 6, M africanum; lane 7, M microti; lane 8, negative control

[M tuberculosis H37Rv DNA treated with DNAse Q (Promega)];

lane 9, PCR positive control (M tuberculosis H37Rv DNA); lane 10,

PCR negative control A single 308 bp amplification band was

observed in some M tuberculosis complex strains (C) PCR 360 bp

product from the same strains as (B) but with amplification of the

Mycobacterium rpoB gene as positive control for mRNA expression

and cDNA synthesis.

Immunoelectron microscopy

Rabbit serum raised against peptide 11027 was used

for immunolabelling Immunoelectron microscopy

showed that colloidal gold particles (5 nm) were

mainly located on the surface of M tuberculosis

H37Rv (Fig 3), supporting the concept that this

expressed gene is located on the surface and is

recog-nized by serum directed against one of its forming

pep-tides No labelling was observed in negative controls

with preimmune serum (data not shown)

High specific binding peptides

A highly specific, sensitive and robust receptor–ligand

binding assay was developed, based on previous

stud-ies with erythrocytes and hepatocytes [17–19] This

methodology was adapted to other cell types, such as

monoblastic U937 and epithelial A549 cells, as they

are useful models for M tuberculosis invasion studies

[20] The binding assay was performed at four 125

I-radiolabelled peptide concentrations (10–200 nm) in

the presence or absence of at least a 400 times excess

of unlabelled peptide, as described previously [21–23]

The binding activity was defined as the slope of the

specific binding curve in the added peptide range

Pep-tides showing binding activity greater than or equal to

1% were considered to be U937 or A549 cell HABPs

A previously reported U937 and A549 cell HABP,

11095 (from the Rv1510c protein), was used as binding assay control [23]

Figure 4 shows the Rv2560 synthetic peptide sequences and the corresponding U937 or A549 cell binding activities The black bars represent the binding activity Those peptides having a binding activity ‡ 1.0 slope (dotted line) were considered to be cell line HABPs Peptide 11024 (121VVALSDRATTAYT NTSGVSS140) was found to be the only U937 and A549 cell HABP identified for the Rv2560 protein This peptide is predicted to be in the extracellular sol-vent-exposed region, as determined by tmhmm and tmpred online software Peptide 11033 (284LIGI PVAALIHVYTYRKLSGG304) showed high binding activity to the epithelial A549 cell line only

Affinity constants Saturation assays and Hill analysis [24,25] were carried out for shared 11024 HABPs based on initial screening results, using a greater 125I-radiolabelled peptide

Fig 2 Immunoblotting assay Western blotting was performed

with rabbit preimmune and post-third inoculation sera against a

M tuberculosis sonicate (lanes 1, 2 and 5) and a membrane

frac-tion (lanes 3 and 4) Lanes 1 and 3, absence of recognifrac-tion of

M tuberculosis proteins by rabbit preimmune sera; lane 2, serum

from rabbit inoculated with polymerized peptide 11031; lane 4,

serum from rabbit inoculated with polymerized peptide 11027;

lane 5, serum from rabbit inoculated with M tuberculosis total

son-icate Molecular weight markers are shown on the left-hand side.

Fig 3 Immunoelectron microscopy Immunogold location of Rv2560 protein on M tuberculosis H37Rv membrane, as assessed

by 5 nm gold-labelled anti-rabbit IgG particles Intact cells were incubated with a 1 : 10 dilution (1 and 2) or pure (3) rabbit sera directed against peptide 11027, and prepared for immunoelectron microscopy by negative contrast, as described No labelling of the surface was obtained in control experiments from which these anti-bodies had been omitted, or with preimmune serum (data not shown) The arrows indicate the location of the Rv2560 protein on the mycobacterial surface.

concentration range (500–2000 nm) (Fig 5A)

Scat-chard and Hill analyses were then performed and

dis-sociation constants (Kd) were calculated for Rv2560

HABP 11024 for U937 and A549 cell lines (Kd of 380

and 800 nm, respectively) The Hill coefficient (nh) was

1.5 for U937 and 1.2 for A549 cells, suggesting positive

ligand–receptor cooperativity The numbers of binding

sites per cell calculated for peptide 11024 were 200 000

and 3 000 000 for U937 and A549 cells, respectively

Critical residues for cell binding in U937 cells

Glycine scanning analogue peptides were synthesized,

and competition cell binding assays were performed

between original radiolabelled peptides and their

ana-logue peptides to identify HABP critical amino acids

for U937 cell binding Critical residues were those

which, on replacement with glycine, rendered an

invariable decrease of at least 50% in the ability to

compete with original radiolabelled peptide in a

bind-ing assay at two concentrations (16 and 400 nm) This

assumed dramatic changes in peptide binding activity

Figure 5B shows that critical residues in peptide 11024

binding were VVALSDRATTAYTNTSGVSS (shown

in bold italic in the sequence)

Cross-linking assays HABP 11024 bound to a protein located on the U937 cell membrane, specifically recognizing a 54 kDa hypo-thetical receptor Radiolabelled peptide binding to this receptor protein was inhibited in the presence of non-radiolabelled peptide; this was clearly shown by the band intensities (Fig 6) Peptide 11024 binding was target cell specific, as it did not show any binding to HepG2 cells or erythrocytes (data not shown)

Invasion inhibition assay using HABPs A549 and U937 cell lines were preincubated in the presence of HABP 11024 in two independent experi-ments to evaluate the effect of HABP on bacterial invasion of target lung cells It was found that invasion was inhibited in both cell types The inhibitory power

of HABP 11024 was greater in assays carried out using the A549 cell line, where it reached close to 60% inhi-bition when such cells were preincubated in the pres-ence of 1 lm peptide Monocyte invasion assays revealed around 50% maximum inhibition only when higher peptide concentrations were used than those employed for A549 cell assays (Fig 7) It was also

Fig 4 Cell binding activity of Rv2560 peptides Amino acid sequence and specific U937 and A549 cell binding activity for 20-mer long chem-ically synthesized Rv2560 peptides from the M tuberculosis H37Rv strain The peptides are given on the left-hand side, with numbers indi-cating their position within the native protein; in peptides that did not contain tyrosine, it was added to the carboxy-terminal end To the right, the black bar represents each peptide binding activity, determined as the specific binding ⁄ total added peptide ratio The dotted line separates peptides having ‡ 1% binding activity HABP 11095 was used as a binding activity control Rv2560 transmembrane topology is presented on the left-hand side Grey shows the transmembrane helices present in the sequence according to the TMHMM prediction server.

nd, not done because of solubilization problems.

observed that the inhibitory activity of HABP 11024

decreased at concentrations equal to or greater than

100 lm The secondary structure of HABP 11024 in

solution at different concentrations (including those in which activity was seen to decrease) was verified by

CD, and it was shown that this HABP underwent conformational changes critical for its function at the concentrations already established in functional assays (data not shown)

Discussion

Although the elucidation of the M tuberculosis gen-ome sequence has revealed the presence of many gene families which can be classified according to their homology to genes having a known function in other microorganisms, no functional counterparts have been found for many of these mycobacterial genes Pro-teome studies have led to the determination of some of the proteins present on the membrane for which no role in M tuberculosis invasion of the host cell has yet been determined [12,13]

The infection of epithelial cells in the alveoli requires the interaction of the bacterium with several surface receptors, which have been poorly studied to date [26] Studies of nonpolarized pulmonary epithelial cells (HEp-2) have revealed the existence of at least five

M tuberculosis proteins that bind to biotinylated cell fractions, including the already characterized adhesion heparin-binding haemagglutinin [27]

Fig 5 Saturation curves and critical residues of cell binding (A) Saturation binding curve for HABP 11024 binding to U937 and A549 cells The saturation curves resulted from plotting the specifically bound125I-HABP concentration versus free125I-HABP The affinity constants and maximum number of sites per cell were obtained from these curves Inset: the abscissa is log F in the Hill plot and the ordinate is log [B ⁄ B m ) B], where B m is the maximum bound peptide, B is the bound peptide and F is free peptide (B) Competition binding assay with analogous peptides Specific original radiolabelled peptide binding inhibited by analogous peptide (at 16 and 400 n M ) is shown Amino acids underlined in bold represent the critical binding residues, as their binding activity decreased by 50% or more when modified and assayed at the two concentrations used.

Fig 6 Cross-linking assay for peptide 11024 Autoradiographs for

U937 proteins specifically cross-linked with radiolabelled peptide

11024 Lanes 1 and 2, U937 cells; lanes 3 and 4, HepG2 cells;

lanes 1 and 3, total radiolabelled peptide binding; lanes 2 and 4,

inhibited binding The cross-linking assays show that peptide 11024

specifically binds to a 54 kDa membrane protein on U937 cells.

Moreover, it has been observed that M tuberculosis

can promote monocyte differentiation into dendritic

cells that lack CD1, have low CD80 and produce

inter-leukin-10; this altered phenotype is unable to prime

effector T cells, thus becoming an escape mechanism

[28] The identification of proteins specifically binding

to receptors on monocytes or other M tuberculosis

infection-susceptible cells has thus become of interest

in order to determine precisely the regions in such

pro-teins that are directly involved in mycobacterial

inva-sion or immune response modulation

Our group has characterized three mycobacterial

membrane proteins (Rv2004c [21], Rv2536 [22] and

Rv1510c [23]) in recent studies, and has determined

their target cell binding profiles These studies

repre-sent an initial step in the rational selection of

com-ponents for a subunit-based, multiepitope, anti-TB

vaccine candidate

Rv2560 is a proline- and glycine-rich transmembrane

protein, and may thus be classified as a simple

sequence protein (SSP) This type of sequence is

fre-quent in organisms having G + C-rich genomes, such

as M tuberculosis, where several SSPs are organized

into large-sized families having a role in host–pathogen

interaction and are membrane-associated [29] tblastn

analysis of the Rv2560 amino acid sequence revealed

the existence of homologous genes in M marinum and

M ulcerans The homologous gene in M marinum

(melA) was shown to be important in the adhesion,

invasion and intracellular survival of this bacterium in

THP-1 cells after insertion into the noninvasive

M smegmatisspecies [16]

This work shows that the Rv2560 encoded protein,

classified as a putative membrane protein [9] in the

M tuberculosis genome, is present in M tuberculosis complex strain bacilli, is transcribed, expressed and present in greater concentration on the membrane-enriched fraction and the mycobacterial surface, and is involved in the mycobacterial invasion of host cells

On PCR amplification of a 631 bp fragment, includ-ing the sequence of nucleotides encodinclud-ing a high specific binding Rv2560 protein region (amino acids 80–290) (Fig 1), it was found that this fragment was amplified

in M tuberculosis complex strains The presence of this gene was also determined in clinical M tuberculosis isolates obtained from patients having different types

of TB (pulmonary, pleural, osseous, meningeal, abdominal, genitourinary and renal), with the 631 bp fragment being amplified in all clinical isolates All of the foregoing suggests that the Rv2560 gene is present

in different M tuberculosis complex strains, including clinical isolates, and has no genetic variability, as shown by DNA sequencing (data not shown)

The transcription of this gene was also confirmed after the presence of the highly conserved gene had been established in different M tuberculosis complex strains cDNA was therefore obtained from M tuber-culosis complex strains and amplified by PCR, using specific primers for the 308 bp fragment (using more internal primers to amplify smaller fragments in order

to improve RT-PCR efficiency) The results (Fig 1B) led to the conclusion that the Rv2560 gene was transcribed in M tuberculosis H37Rv, M tuberculosis H37Ra, M bovis BCG and M africanum strains, but not in M bovis or M microti

The two polymerized peptides used in rabbit immu-nization produced an antibody response (differing in intensity) evident in western blot results (Fig 2); a

Fig 7 Invasion inhibition assays with HABP 11024 Inhibition percentages with different HABP 11024 concentrations using U937 and A549 cells A peptide having low specific binding ability to A549 cells was used as negative control for this cell line (11021) Colchicine (a vesicular traffic inhibitor) was used as positive invasion inhibition control The results correspond to the average inhibition percentage calculated for each treatment ± standard deviation *P £ 0.05, **P £ 0.01, ***P £ 0.001.

33 kDa band corresponding to the theoretical

molecu-lar mass of the Rv2560 protein (33.1 kDa) was

recog-nized by these sera, suggesting that this protein is

transcribed and expressed in M tuberculosis sonicate,

and at much higher concentration in the membrane

fraction, as inferred from the band intensity

When using serum from rabbits immunized with

poly-merized peptide 11027, immunoelectron microscopy

confirmed the presence of this protein on the

mycobac-terial surface (which has not been reported to date)

Receptor–ligand assays led to the identification of

two high specific binding peptides, one (11024) being

shared by both U937 monoblast and A549 epithelial

cells Peptide 11024 binding to both cell types was

sat-urable, presenting strong positive cooperativity, as

shown by the dissociation constant and Hill coefficient

The corresponding analyses for the determination of

the receptor for 11024 HABPs and the identification of

the critical binding residues, and the invasion

inhibi-tion assays, were thus performed exclusively with this

peptide

This peptide is located in the solvent-exposed central

region of the protein between residues 121 and 140,

sequence (where the amino acids shown in bold italic

correspond to those identified as being critical in 11024

binding to U937 cells) These residues may be involved

directly in target cell binding or may be important for

the structural characteristics of the peptide, thereby

allowing specific binding BLAST analysis of this small

region led to the identification of 78% homology with

Burkholderia cenocepacia-dependent AMP synthase,

which causes respiratory tract infection and is

cyto-toxic for alveolar epithelial cells [30]

A 54 kDa protein was found to be a receptor on

U937 cells; its binding by peptide 11024 was inhibited

by an excess of nonradiolabelled peptide This receptor

was specific for the U937 cell line, but was not seen in

hepatocytes or erythrocytes A receptor having a

simi-lar molecusimi-lar mass (51 kDa) has been described for

the Rv1510c protein HABP 11095; however, further

studies are required to determine whether the same

membrane protein is involved

Peptide 11024 (for which high monocyte and

alveo-lar epithelial cell binding has already been determined)

induced a 36.96–50.53% decrease in M tuberculosis

invasion of U937 cells and a 30.98–58.27% decrease in

M tuberculosis invasion of A549 cells (Fig 7) This

indicates that this HABP is important in the

recogni-tion and invasion of monocytes and type II alveolar

epithelial cells by the mycobacterium

It was observed in preliminary assays that HABP

concentrations of less than 100 lm had a greater

inhibitory effect than larger concentrations Therefore, additional CD secondary structural studies were per-formed to verify possible conformational changes at concentrations greater than 100 lm which were critical

in the inhibitory activity of this peptide It was found that the structure of the peptide changed at concentra-tions equal to or greater than 100 lm (not shown), thereby explaining the loss of inhibitory potential in the assay carried out for alveolar epithelial cells The above results indicate that the Rv2560 protein

is conserved within the M tuberculosis complex It is also transcribed and expressed in low abundance on the mycobacterial surface The protein contains a spe-cific high binding peptide for U937 and A549 cells, which plays an important role in mycobacterial inva-sion Therefore, it is concluded that the Rv2560 pro-tein is highly relevant in pathogen–host interaction, and that the identification of the region directly involved in such interaction makes it an important candidate for inclusion in the development of a subunit-based, multiepitope, chemically synthesized vaccine

Experimental procedures

Bioinformatics’ analysis

M tuberculosis Rv2560 protein sequences were obtained from the Tuberculist Webserver (http://genolist.pasteur.fr/ TubercuList/) Proteins were aligned by BLAST (http:// www.ncbi.nlm.nih.gov/BLAST/) and clustalw (http:// npsa-pbil.ibcp.fr/cgi-bin/npsa_automat.pl?page=npsa_clu stalw.html) multiple alignments Protein features and GRAVY scores for the Rv2560 amino acid sequence were calculated using the protparam tool (http://us.expasy org⁄ tools ⁄ protparam.html), for which a score of greater than ) 0.4 (mean score for the cytosolic proteins) suggests membrane association probability; the higher the score, the greater the probability [13] Transmembrane regions were predicted by tmhmm (http://www.cbs.dtu.dk/services/ TMHMM) and tmpred (http://www.ch.embnet.org/ software/TMPRED_form.html) Cell localization, lipid attachment sites and signal sequences were predicted using psort(http://psort.nibb.ac.jp)

Mycobacterial species and strains The following M tuberculosis complex species and strains were used: M tuberculosis H37Rv (ATCC27294), M tuber-culosis H37Ra (ATCC25177), M bovis (ATCC19210),

M bovisBCG (ATCC27291, Pasteur sub strain), M africa-num (ATCC25420) and M microti (kindly donated by

F Portaels, Prince Leopold Institute of Tropical Medicine)

Ten M tuberculosis clinical strains were isolated from

speci-mens obtained from different patients attending the TB

pro-gramme at either the San Juan de Dios Hospital or Santa

Clara Hospital, both in Bogota, Colombia Patients came

from several geographical areas of Colombia All

mycobacte-rial strains were grown for 5–15 days in 7H9 Middlebrook

broth (Difco Laboratory, Detroit, MI, USA) with 0.04%

Tween 80 and in Middlebrook agar 7H10 (Difco), both

sup-plemented with oleic acid, albumin, dextrose and catalase

(BBL, Becton Dickinson, Mountain View, CA, USA)

Genomic DNA extraction

Cells were harvested in Tris–EDTA buffer (TE, pH 8.0)

and suspended in 25% sucrose in 10· TE Lysozyme

(100 lgÆmL)1) was added and the preparation was incubated

at 37C for 2 h with subsequent addition of 100 lgÆmL)1

proteinase K and N-lauroylsarcosine (Sigma, St Louis, MO,

USA) at 1% final concentration Following 18 h incubation

at 65C, the mixture was extracted with

chloroform–iso-amyl alcohol (24 : 1, v⁄ v), once with phenol–chloroform

(1 : 1, v⁄ v) and twice more with chloroform–isoamyl

alco-hol DNA was precipitated with 2-propanol, washed with

70% (v⁄ v) ethanol and suspended in 1 · TE [31,32]

PCR assay

PCR amplifications were performed in a thermal cycler

GeneAmp PCR System 9600 (Perkin-Elmer Life Sciences

Inc., Boston, MA, USA), using 100 ng mycobacterial

geno-mic DNA for amplifications The mixture contained 50 mm

KCl, 10 mm Tris⁄ HCl (pH 8.3), 1.5 mm MgCl2, 0.1 mm of

each dNTP, 0.4 mm of both direct 5¢-CAATCGTCG

GGTTTTAGCG-3¢ and reverse 5¢-GTGTAGACGTG

GATGAGCG-3¢ oligonucleotide primers and 1.5 U Taq

DNA polymerase (Invitrogen, Carlsbad, CA, USA)

Twenty-five cycles of the following thermal profile were

car-ried out after DNA had been denatured for 5 min at 94C:

56C for 30 s, 72 C for 40 s and 95 C for 40 s A final

5 min extension cycle was then performed at 72C The

amplification products were loaded onto 1% agarose gel,

electrophoresed at 70 V in 1· Tris/acetate/EDTA, stained

with ethidium bromide and photographed

DNA sequencing

The dideoxy chain termination method was used for

sequencing reactions with a Taq FS DyeDeoxy Terminator

cycle sequencing kit (Applied Biosystems, Foster City, CA,

USA) on a GeneAmp PCR System 9600 (Perkin-Elmer Life

Sciences Inc.), and run on a 373 DNA sequencer model

(Applied Biosystems) The sequencing strategy involved

for-ward and reverse specific primers for the 631 bp fragment

of the Rv2560 gene

RNA isolation The bacilli were harvested by spinning at 12 000 g for

15 min at 4C Sodium azide (10 mm) was added to the culture just before harvesting The cell pellet was suspended

in 2 mL of cold lysis buffer for each 200 mg wet weight of cells [33], and sonicated twice for 15 min Two volumes of Trizol (Gibco BRL, Gaithersburg, MD, USA) were then added and extracted according to the manufacturer’s instructions The pellet was suspended in 100 lL of distilled water and stored in aliquots at) 80 C

RT-PCR Total RNA was quantified by a GeneQuant spectropho-tometer (Pharmacia Biotech, Piscataway, NJ, USA), treated with RNAse-free DNAse RQ1 at 37C for 3 h, precipi-tated with isopropanol, washed with 70% ethanol and sus-pended in distilled water M tuberculosis H37Rv DNA was included as DNAse Q activity control (1 UÆlg)1 DNA) Target RNA (500 lg) was reverse transcribed in a tube containing distilled water and 10 lgÆmL)1 random primers (Gibco BRL) This mixture was incubated for 10 min at

70C; 1 · RT buffer, 10 mm dithiothreitol, 0.5 mm dNTPs and 40 U human placenta ribonuclease inhibitor (Promega, Madison, WI, USA) were then added on ice; 200 U M-MLV reverse transcriptase (Gibco-Life Technologies, Grand Island, NY, USA) was then added at a final volume

of 30 lL This mixture was kept at 37C for 1 h The enzyme was finally denatured for 5 min at 95C PCR was carried out as described above

The rpoB gene was used as positive transcription control This gene, encoding the RNA polymerase b-subunit, is present in all mycobacterial species [33] DNAse-Q-treated

M tuberculosis H37Rv was used as cDNA synthesis nega-tive control Distilled water and M tuberculosis H37Rv DNA were used as negative and positive PCR controls, respectively

Rabbit immunization Two New Zealand strain rabbits per peptide (previously determined to be nonreactive to M tuberculosis sonicate, as assessed by western blot) were injected with 500 lg of peptide 11027 (181ADGKPVTIATFFRPRNLGLV200) or

500 lg of peptide 11031 (242SPIDSVKASIETVGSNIG GSVY262) [polymerized via the addition of cysteine at the amino and carboxy termini and mixed with Freund’s Incomplete Adjuvant (Sigma)] on days 0, 20 and 40 Final bleeding was carried out on day 60 and sera were collected

in accordance with the Fundacion Instituto de Inmunolo-gia’s Bioethics Committee recommendations The Rv2560 protein peptide sequences chosen for the immunization of rabbits were obtained using T-epitope prediction software

syfpeithi (15-mer T-epitope for major histocompatibility

complex class II only) downloaded from http://www

syfpeithi.de/Scripts/MHCServer.dLl/EpitopePrediction.htm

SDS-PAGE and immunoblotting

M tuberculosis sonicate or membrane fraction (1 mg) was

loaded in a discontinuous SDS-PAGE system, using a 10–

20% (w⁄ v) acrylamide gradient, and then transferred to

nitrocellulose paper using the semidry blotting technique

[34] The filters were incubated with a 1 : 100 (v⁄ v) dilution

of the sera obtained from rabbits immunized with

polymer-ized 11027 or 11031 peptides Sera were diluted in NaCl⁄

Tris⁄ Tween 20 (0.02 m Tris-HCl, pH 7.5, 0.05 m NaCl, 1%

Tween 20) and 5% skimmed milk Incubation for 1 h with

1 : 3000 (v⁄ v) alkaline phosphatase-conjugated anti-rabbit

IgG (ICN Biomedicals, Costa Mesa, CA, USA) followed

five NaCl⁄ Tris ⁄ Tween 20 washes The reaction was

devel-oped with Nitro Blue tetrazolium⁄

5-bromo-4-chloroindol-2-yl phosphate (KPL, Gaithersburg, MD, USA)

Immunoelectron microscopy

Immunoelectron microscopy studies were carried out on a

Philips CM 10 transmission electron microscope (Philips,

Suresne, Hauts-de-Seine, France) Briefly, a wet pellet

(50 lL) of M tuberculosis H37Rv was fixed with a 4%

paraformaldehyde)0.5% glutaraldehyde solution for 2 h at

4C After fixation, the pellet was dehydrated in graded

ethanol and then embedded in LR-white hard-grade acrylic

resin (Sigma) for 4 days at 4C Thin slices (400 nm) were

cut and mounted on 300 mesh nickel grids The slices were

incubated in a saturated sodium metaperiodate solution for

1 h at 20–22C for antigen retrieval [35] The grids were

then floated, section down, in a beaker containing 0.01 m

sodium citrate buffer for 15 min at 80C After 1 h of

blocking in Tris-buffered saline (NaCl⁄ Tris) (0.05 m Tris in

isotonic saline, pH 7.6) containing 0.05% BSA, the grids

were incubated in either 1 : 10 (v⁄ v) or pure rabbit

polyclonal serum for 1 h at 37C Following an NaCl ⁄

Tris⁄ 0.025% Tween 20 wash, the grids were immersed in a

1 : 50 (v⁄ v) dilution of 5 nm gold-labelled anti-rabbit IgG

(Sigma) for 1 h at 20–22C The grids were then washed

with NaCl⁄ Tris ⁄ Tween 20 and fixed in 2.5%

glutaralde-hyde, followed by 15 min of incubation in 1% uranyl

ace-tate The grids were washed with distilled water and dried

at 20–22C before observation

Cell culture

A549 human lung epithelial (ATCC CCL-185) and U937

monocyte-like (ATCC CRL-1593.2) cells were grown at

37C and 5% CO2 in RPMI 1640 medium (Gibco-BRL)

supplemented with 10% fetal bovine serum (Hyclone,

Logon, UT, USA) A549 cells were dislodged with 0.1% EDTA–NaCl⁄ Pi Cell lines were collected in 50 mL tubes, centrifuged at 1000 g for 5 min and washed with RPMI 1640

Peptide synthesis Sixteen sequential 20-mer peptides, corresponding to the Rv2560 amino acid sequence [9], were synthesized in this study by a solid-phase multiple peptide system [36,37] 4-Methylbenzhydrylamine resin (0.7 meqÆg)1), t-Boc amino acids and low–high cleavage techniques were used [38] Pep-tide identity and purity were analysed by MALDI-TOF MS and analytical reverse phase HPLC An extra tyrosine resi-due was added to any peptide C-terminus that did not contain it to enable radiolabelling

Peptide radiolabelling Radiolabelling with125I was performed according to previ-ously described techniques [24,25,39,40], in which chlor-amine-T (2.25 mgÆmL)1) and 3.2 lL Na125I (100 mCiÆmL)1) were added to 5 lL peptide solution (1 lgÆlL)1); 15 lL sodium bisulfite (2.75 mgÆmL)1) and 50 lL NaI (0.16 m) were added after 5 min of reaction at 18C The radiola-belled peptide was then separated from reaction by-prod-ucts on a Sephadex G-10 column (Pharmacia Biotech,

St Albans, UK) (80· 5.0 mm)

Binding assay A549 and U937 cells (1· 106) were incubated with increas-ing quantities of each Rv2560 m tuberculosis putative mem-brane protein 125I-radiolabelled peptide (100–2000 nm) at

100 lL total volume for 90 min at 4C, in the presence or absence of 40 lm unlabelled peptide, to determine the bind-ing specificity After incubation, unbound peptide was removed from the cells by sedimentation through a dioctyl-phthalate–dibutylphthalate cushion (d¼ 1.015 gÆmL)1) and centrifuged at 9000 g for 2 min [18,19] The assay was car-ried out in triplicate in identical conditions; bound and free peptides were determined by measuring the cell-associated radioactivity on a gamma counter (Gamma Counter Cobra II, Packard Instrument Co., Meriden, CT, USA); the average results of the assays performed in triplicate are reported and shown graphically in Fig 4

Saturation assay A549 and U937 cells (1· 106

) were incubated with increas-ing concentrations (100–2000 nm) of radiolabelled peptide

at 120 lL total volume for 90 min at 4C, in the presence

or absence of 40 lm unlabelled peptide, to determine the binding specificity After incubation, unbound peptide was