Post on 18-Oct-2020
Antigenic variation as adaptive process: the case of
Trypanosoma brucei
African trypanosomes infect a wide spectrumof mammalianhosts, including humans
Mechanisms of adaptation:I. Antigenic variation
A dense coat of Variant Surface Glycoprotein(VSG) covers the entiresurface of T. bruceibloodstreamforms
Bloodstreamform
Procyclic form
N-terminal VSG domains
VSG coat: protection
VSG dimers
phospholipids
- Tightly packed array of 107 molecules organized in dimers- Impenetrable to macromolecules of the host, including antibodies- Only surface loops recognizable by the host
antibody
1 2 3
Anti-1 Anti-2 Anti-3
Parasitenumber
Time
VSG coat: antigenic variation
The coat changesevery 103 to 105 cell divisions
Significance:participation in the control of the parasite burdenby attracting the lytic immune response and subsequently allowingnew antigenic variants to prolong the infection.
Genetic mechanisms of antigenicvariation in Trypanosoma brucei
7 6 5 4 8 8 3 2 1 VSG
7 6 5 4 8 8 3 2 1 VSG
VSG
VSG VSGDNA recombination(either gene conversion
or reciprocal recombination)
In situ (in)activation
~1,500 genes
~15 telomericVSG expression sites
VSG VS V G
Mechanisms of adaptation:II. Generation of adaptive proteins
Parasites must escape the defenses of their hosts, but they also need to communicate with host cells and
internalize vital host components
transferrin
antibodies
The flagellar pocket:the unique accessible
site
Surface receptors:- invariant- accessible- vitalVaccination targets??
Endocytosis in T. brucei
- only limited to 0.5% of the cell surface - highly efficient, probably due to special features (pNAL lectin?)
out
in
digestivevacuole
lysosome
Most ESAGs encode surface proteins, including a heterodimeric receptor for transferrin
and a homodimeric receptor-like adenylyl cyclase
Flagellar pocket Flagellum
plasma membrane
ATP cAMP
44444444 4444
AC
77776666 2222TF
44444444 4444
AC
?
ACAC????
plasma membrane
= VSG N-terminal domains!!!
1111
The use of different ESs, thus, the expression of different sets of ESAGs, allows a better
adaptation to a variety of different hosts:
• efficient uptake of transferrin from variousmammalian species, hence, colonization of a wide spectrumof mammals
• resistance to lysis by human serum, hence, colonization of man
10 4 8 8 3 2 1117 6 5( 9( )) VSG
10 4 8 8 3 2 1117 6 5( 9( )) VSG
The use of different BES allows a better adaptation to different hosts : efficient uptake of transferrin
The use of different BES allows a better adaptation to different hosts: resistance to lysis by human serum
T.b.rhodesiense
T.b.brucei
??
Lysis by human serumrequires endocytosis of the trypanosome lytic factor (TLF)
out
in
endocytosis
lysosome
TLF(HDL -linked)
In T. b. rhodesiense, resistance to human serumis linkedto activation of a specific VSG expression site (R-ES)
VSG
in non-human serum
VSG
R-ES
result:trypanosomessensitiveto
human serum(S clones)
VSG
in human serum
VSG
R-ES
result:trypanosomesresistant to
human serum(R clones)
Xong et al (1998) Cell 95, 839-846
The R-ES site is severely truncated and contains the Serum Resistance-Associated gene (SRA)
VSG
Expression of SRA in the R-ES appears to be a generalfeature of T. b. rhodesiense strains ;
SRA is the best available diagnostic tool of this subspecies
( )10 4 8 8 3 2 1117 6 5 9( ) VSG
B-ES
6 7 5 SRAR-ES
SRA is necessary and sufficient to confer full resistance to human serum
Xong et al (1998) Cell 95, 839-846
Trypanosoma b. b. w.t.
0
5
10
15
20
25
30
35
40
45
1 2 3 4 5 6 7
days
par
asit
emia
FCS
NHSSRA transformants
0
5
10
15
20
25
30
35
40
45
1 2 3 4 5 6 7
days
par
asit
emia
FCS
NHS
SRA is a VSG-like glycoprotein devoid of surface loops
Models of the N-terminal domain of SRA and VSGs
SRA VSG WaTat 1.2VSG MiTat 1.2
αααα-helixA
αααα-helixB
N-term surface loops
The study of the SRA moiety necessary to confer resistance to human serumhas uncovered:• the essential role of the N-terminal αααα-helix A, which is
interactive in VSGs;• the ability of this helix to interact with apolipoprotein L-I
(antiparallel to C-terminal αααα-helix)
(serumalbumin)
Coomassie blue
control
apoL1
SRA
• ApoL1 is the trypanosome lytic factor of humanserum.
• Interactions between the N-terminal αααα-helix of SRA and the C-terminal αααα-helix of apoL1, which occurwithin the lysosome, prevent trypanolysis by humanserum.
SRA
apoL1
Vanhammeet al (2003) Nature 422, 83-87
Activity of apoL1
•The colicin-like anion-selective pore-forming domain isresponsible for lytic activity.
•The membrane-addressing domain is responsible for bothbinding to HDL and addressing to a membrane.
•The C-terminal region is not required for either activity, but isthe target for neutralisation by the trypanosome immunity proteinSRA of T. b. rhodesiense.
Pérez-Morgaet al (2005) Science 309, 469-472
endosome
flagellarPocket
lysosome
pH 5.3
apoL-I
HDL
Trafficking of apoL1 to the lysosome of T. brucei: a model
NHS/apoL1 triggers swelling of the lysosome
0 h 1 h 2 h
3 h 4 h 5 h(1 µg/ml apoL1; 33°C)
Cl-
apoL1Cl-
DIDSApoL1-driven effect
on the lysosome:a model
Pérez-Morgaet al (2005) Science 309, 469-472
Hpr
apoA-I
apoL1
Lipids
91% identity to haptoglobin(hemoglobin scavenger)
ApoL1 is associated with Haptoglobin-related protein(Hpr) on the same subset of HDL particles (HDL3);
Hpr is involved in the binding of the particlesto the trypanosome surface.
Vanhollebekeet al (2007) PNAS 104, 4118-4123
kk
Haptoglobin(r)Alexa 488
+ hemoglobin
hemoglobinAlexa 488
+ haptoglobin(r)
The haptoglobin(r)-hemoglobin complex is a ligand for T.brucei
The trypanosome receptor for Hp(r)-Hb was recently identified.
In mouse serum, this receptor appears to be responsible for the uptake of heme, which is incorporated in
hemoproteins that confer resistance of the parasite to the oxidative response of host macrophages.
In human serum, this receptor also triggers the uptake of the trypanolytic HDL particles through recognition of
the Hpr-Hb complex.
Vanhollebekeet al (2008) Science 320, 677-681
Mutual adaptations between T. bruceiand man
Mφ
ROS RNS Hp-Hb
TbHpHbRTbHpHbR
Intravascular hemolysis
CD163
Hpr
Lipids
humans
SRASRA
Human infection
apoL1Hb-
Trypanolysis
T.b.rhodesiense
HDL3
Conclusions (I)
* The telomeric VSG ESs are powerful geneticworkshops for the adaptation of the parasite:
- their high homologous recombination rate, due to both highlevel of sequence identity with other loci and high level of DNA accessibility to recombinases, allows the continuouscreation of new antigens to cope with the immune system
- their diversity allows the variation of surface receptors
- their high recombination rate leads to the generation of new adaptive proteins
Conclusions (II)
* The VSG gene seems to have been used as a major tool to construct various adaptive components (transferrin receptors, SRA, otherVSG-like proteins..??)
* Allelic exclusion is the key to adaptive variation of T. brucei
ESAG7/6 as VSG-like transferrin receptor: Didier Salmon
SRA as inhibitor of trypanolysis: Huang Van Xong, Luc Vanhamme
ApoL1 as trypanolytic factor: Luc Vanhamme, Françoise Paturiaux-Hanocq, Philippe Poelvoorde
Mechanism of trypanolytic activity of apoL1: David Pérez-Morga, Benoit Vanhollebeke
Hpr as ligand of trypanolytic HDLs : Benoit Vanhollebeke
Identification of the trypanosome Hp-Hb receptor: Benoit Vanhollebeke
Annette Pays, Patricia Tebabi, Géraldine De Muylder, Laurence Lecordier, Derek Nolan