- Email: [email protected]
In vitro selection of nucleic acids and proteins: what are we learning?
521
In vitro selection of nucleic acids and proteins: we learning? Richard W Roberts* and William W Ja For almost used
a decade,
to isolate
according
novel
to their
our perception appear
selection acids,
experiments peptides
function.
Selection
experiments
mimicry
and catalysis,
with
facile
than
desired
rational
properties.
design New
have
the
been
have
structural molecules
Information hlghlights
ratlonal
approaches.
testin::
altered
each
that
,\ dcr~lc
ago.
LYHII~ hc t’o~~nd that
:rnd/or
fllnction
I:ltion
of KiY,\
that
Addresses
in Structural
hind
Callfornta
lnstltute
Science
Ltd
ISSN
1999,
Introduction
and
aptan’crs
;;:encral
.Idrlitic)n
KY\
Kc\,), no
3s lrcll
nkitiiral \,ascul:ir
in3~
‘Ilie
ahilit)-
35 small
\ystcms.
I:ition.
‘l‘hcrc.
IX
ilii;igc,
molcciilca
hind
transcrip anJ
proteins :ictivit, [L~l<(;l:]
factor
tcstcd
allow for
function
all the ;It
the
tinic. 13> coniI)2risoii. sci-ccllinfi cupuriments th:lt t-:lch 1~)ol mcmhcr bc qllericd indi\iidllail\. selection cupcrinients ,~ wncrilll\ ,illou milch Iarxcito I)r sirr\,cvcd than \crccriiiig eYpcrimcnts. On
th;it
:tcici\
of the
it’ the mirror with naturkrl \t:lhlc
binds
to mimic
in
oli,qmu-
the
and
best
the
5triictiirc .i
‘l’hc
natural
rheory
crsir!
strtictiircs
121.
this
the
transition
seen1
of
the
that
i5 doniinatt4 howc\,cr,
an
‘KN/I
by proteins ha\,c
its hounds.
t:,ictol
ril~osonie
cnlr\
m;inv
bv folded in
ha\c the
cii!i;lr\otic
inlportaiit
3 p-cat
esperiniental
in tt‘r-
and
to in
internal
mimicry from
in\.ol\ed
.Siniil:irl~,
!)\ ;kn tlcncc.
pn~\~itlcs
th;it
dot<,
t:,ictors
min~icked of
kno\\ from exists in tr;lns-
1<1~-(~4;‘1’1’)
Kk-.34;‘1’1’)
portion
in sclcction
no\\
examples Ed
he mimicked (IKICS) 11.3,1-l]. di\
wc
protcin
I Il.
initi;ttion. can
proteins
eY:liiiplu~
One of the KKX
general
both
protein KNA strllc-
natur:il
and
support
for
c\orld
to a bio-
is possible. It follo~~s
thut.
if
any small molecrile target, c;italysts COIIIJ IK discovered tq sclccting lihrar): mcmhers that hind transition-statc andogs (‘I’SAsL ‘I’his approach has hccn iiscd to ,great adv3ntage in the immiinc sclcction of catal\,tic antiboclit3 1 IS]: howc~cr. success has been Iiliiitcd llsin:: KN.1 ;~ncl I)NA apt:lnlcr\. ‘l’he first ewmple was .ii)taincrs
euperirnents
sllhstitution
I~iologic:ill~
~onstrii~~tcd
(t~l~-‘li~~~~‘l‘l’~rK~~~ (KIY-1. KIT-2 :lnd
\liinicrk
libraric5
the
th;lt
rc\wsc
or hv the
is cchoetl
chcmistrv
i~lmc rcqllirt: ‘l’hiia.
isolated
HIV
(e.g. 191). .iltcrn:lti\ei~, protciil tar~:ct is iised
of nucleic
n:ltural
the
he
miniic
1101.
non-n:irirr;il
to
[7]) clone
hetcropol~-
to
iliiclci~-acid-t)iii~lili~ cndothelial ,qrowth
:I mirror
or I)k;\.
tal’!$?
of art
yclection
has
one
iiscd
been
(c.g.
of pho~~,horothioarcs
I leotide
tklrc\.
l~)oI
that
iso-
fit’
1.
have
\U~IIC~CC’ nmtifs can bc ftlnction:lli\
;,ifftv
‘I‘hc
proteins
hc
;I pi-ottzin
;Ipt;tniers
1’-01 I t\ith 2’-Ntl, irnak:c of the 0ri:in;rl
ti.;liisl;ition
the
:lt best.
2nd 1 asoprcwin) IX]. ‘l‘hcsc krptamcrs can Lx ackiptcd foi IISC i/l c,izw if thcv ;Irc protcctccl from degrad:ltion b! the
cll4‘4(;
i/l
:tnd
or :I I>NA strll<‘turc
the
c//)TN.F, ‘to
and
notion
protrins
thrombin,
ximc
in
KNA
(from
miiv
I1iX.A) (c.~.
I)N:\
,ind tlli’ t11:1t h:l\,e
clon,qtion min;ltion
nlolccllle
;I
in
cloning
either an mimicked
molcc~~lc~
the or
of :lnc)thcr
c\pcrinwnts
(kncra1ly.
rnelnbers
withollt
W;LS hrretical
I>NX
sm;ill
KN,A
t;isc
9:521-529
0959-440X
and terms
that
of ;1 protein
to advance
I<%\
quantum coherence polymerase chain reactlon single-chain vanable domaln fragment transitlon-state analog vascular endothellal growth factor
SCFV TSA VEGF
individwi
of
Abbreviations EF elongation factor FMN flavln mononucleotide HSQC heteronuclear stngle PCR
propn\:ll
:tncl
both
(e.g.
(c.K. c Elsevler
the
iiir~lci~-acicl-l,indinfi
Biology
of
known
and mimicry
fllnction
Opinion
it\
is not
m()IccIIIc
lnu(.h
Englneenng, USA
:Icti\
RNA and DNA
Aptamers
have
on a number of selected and future challenges for design via
Dlvislon of Chemistry and Chemical Technology. Pasadena, CA 91125, *e-mail: [email protected]
the
inciiviciual.
Functional
at generating methods
iller
Current
hand, experiment
and they
been developed improve the power of functional strategies In ways that nature has already dwovered - by expanding library size and facilitating the recombination of positive mutations. Recent evolved
other
selection
and proteins
of molecular
to be more
biopolymers
in vitro nucleic
what are
:I Irll>o/.wnc
could
th:lt
hind
enhanced
the
isomerization
ofs~~l~rtitutetl
522
Engineering
and
design
biphenyls by M-fold over background [ 161. Subsequently, RNA and DNA aptamers that bind /V-methylmesoporphyrin (NMMP) were found to stimulate porphyrin metalation [I 7,181. ‘I’he scarcity of enzy-mes compared with catalytic antibodies may be a result of the different mechanisms used by nucleic acids to recognize small molecules compared with those used by proteins (see discussion below). On the other hand. the relative paucity of ‘I’SA-binding protein catalysts that have been isolated via phage display may imply that in vitro selection techniques need to be improved in order to match the ability of the immune system. Amide- and peptide-bond-forming catalysts One central tenet of the ‘R&A world’ hypothesis is that the mother of all enzymes, the ribosome, contains RNA in its catalytic heart. In addition to in\,estigations that point to rRNA as being essential for ribosome activity [ 19-21 1. :I number of laboratories ha\,c set out to test whether or not ribozyncs could be found that arc capable of catalyzing amide-bond formation. ‘I’he first C~ICCCSS involved an ac\l transferasc ribozyme that was capable of forming an amide bond between a .i’-NI-I,-R’VA and .Y-biotiny-l methionine attached to the 3’ end of ;I hexanlrcleotidc (k, - 0.6 min-1) [27]. Recently, E;aton and co-norkcrs (2.31 reported the isoIation of amide-bond-forming rihozymcs that do not require an oligonuclcotidc tether ro the substrate. a .j’Ahll’ actixrated ester of biotin. ‘l’hcse riboqmes do rcquirc .j’-imidazole uridine, which ws incorporated uniformI\ in place of uridine in the RNA pool. Although neither of these ribozymcs was reported to contain sec~wzr~cc: homology to natural RNA sequences, me of the peptidyl transferasc riboqmcs isolated by %hang and Tech did [24,25-l. The clone 25 ribozyme contains ml internal loop with regions of’ sequence identity to the centrdl loop of domain c’ of 2% rRNA, a region that is central to the peptidyl transferasc function of the ribosomc. Surprisingly, aptamcrs that bind the pcptidyl transferasc inhibitor (:cdAp-I’urotn)lcin share identity with the peptidy1 transferasc ribozyme and with 23s rRNA 1261. I>cspite the recent retraction of bvork arguing that domain \’ RNA transcripts ha\,e peptidyl transferase activity [27/> the selection data represent proof that RhA has the potcntiul to carry out a \,ariety of amide-bon~l-forming reactions. New ribozyme reactions A number of rihozymes with new activities have been isoIatcd recentI>, including molecules that are capable of catalyzing the s\.nthcsis of ;I IlUc~e~Jtidc [28”]. cnzylcs selected to mim;c reactions in the spliccosome [29’] and riboaynes capable of performing a I)iels-Alder cycloaddition reaction [.iO]. In the first example, I Jnrau and I3artel [28”] uncovered ribozymcs that are capable of joining a tethered I-thio-uridine nucleotide to pRpp (5’ phosphoriI,os)jl-a-l’~rol’hosphatc), the activated ribosc (ised in nucleotide biosvnthesis (I~,..,, = 0.1 .i minmI). ‘I’his reaction is almost identical to the natural reaction carried out I)\ uracil
phosphoribosyltransferase pRpp, making uridine
(IIPK’I’) 5’ phosphate,
to couple
uracil
and
In the second example, a selection was designed to test whether modern spliceosomal RNA ll2/1J6 could be used to resurrect RNA-based spliecosomal activity. Each of the four ribozyme classes found performs some kind of cleavage reaction, followed by a ligation; however, none of the selected molecules produces an activity that is similar to that of the spliceosome [29’]. Interestingly, the templates generated by the ribozymes uncovered a previously unknown activity for reverse transcriptase. nontemplated jumps in sequence. Adding functional group diversity - ‘If I only had a histidine’ A number of laboratories have recently worked to expand the chemical di\.ersity of RtiA and 1)NA. either through covalent modification or through the addition of cofactors and ions to the selection mixture. Examples of the first category include ribo/.ymes that catalyze carbon-carbon bond formation though 3 IXels-Alder reaction (.iO]. a5 well as the previously mentioned smi,ie-bond-forming rihJ~);lll~S [Z.3] that contain 5-pyridy~meth~lclirhox3mid uridinc and ii-imidazole uridine, respcctivcly. Kxamplcs of the second case include the routine addition of low (micromolar to millimolar) concentrations of’ divalcnt cations, including hip:+‘, (:a+‘. %n+?, Rin+L. ( :u*l and eI’en l’b”, or cofactors, \uch as histidinc 1.31‘I. ‘I’hc itnportancc of these prosthetics can bc xc11 in that their omission abrogates ftlnction.
DNA catalysts Although DNA tion storage. it
plays a centrdl role in biological informaa functionail>impoverished bi(Jplylller comparc~ with cithcr proteins or RNA. Despite its limitations, the list of DNA catalysts has grown significantly in the past few years (see ‘Iliblc 1 in [32]; [U]). It is not surprising that many of the DLL4 catalysts isolated require ;I cofactor of some kind. It is surprising that the highest catalytic cfficietq, 10” IL-~*s-’ (although not the highesr k,;,,), is held by the 10-33 RNA-cleaving DKA enzyme [.34,35j. ‘Ii) date, the scope of I>KA-based catalysts has significant di\,ersity. including ligation ( .VI]. RNA phosphoester cleavage [.3-!,.37-391, DNA clea\,age (40j. porphyrin metalation [1X], peroxidase acti\,ity [41’], fl~~orophorc oxidation [3.2] and 5’-IIN, phosphor)ilation [4.3*]. It is interesting to note that C;-quartets seem to play a ccntral role in the folded structure of many DNA catalysts, ;IS \vell as of DNA aptamers. is
Engineering allosteric enzymes and templates One potentially powerful application of nucleic acid aptamers and catalysts is the engineering of allostericall) controlled enzymes and templates. Breaker and co-workcrs [-M.lrS*] have shown that, through combinatorial enainecring, chimaeras between either the A’I’I’ or I:hlN aptamer with the hammcrhcad ribozyme may be allostcricaily regulated to function onI> when they bind their
In vitro
selection
of nucleic
acids
and proteins
Roberts
and Ja
523
Table 1 Peptides Initial
evolved
pool*
MVSKGEEX,,DAQAPKA
Pool:
X&X&X, x,cx,cx, X&X&X, x,cx,cxs x,cx,cx, x,cxgcx,
from
randomized
sequences. Diversity+ 2x10’3
5 x 10s
Target c-myc
(each)
References
Result
mAb
Epitope X(Q/E)XLISEXX(L/M) Mimic
VEGF
3.5 x 1 Og (total)
(a) [69-l
(i) RGWVEICVADDNGMCVTEAQ (ii) GWDECDVARMWEWECFAGV
x4cx,ocx4
X,CX,GPX,CX,
X, ,GGGS
SRX,
,SR
SADGAX,,GAAGA
ADGAXsGAAG
X 10
5x10s
VEGF
1.9 x 109
1 xl09
Paclitaxel
Tropomn
2.5 x 108
C
CTLA4
4x107
CSF
2 x 1 Og (phage)
Mimic GERWCFDGPLTWVCGEES
[69-l
Epitope HTPH
11071 P
Epitope (VIL)(DIE)XLKXXLXXLA
mAb
IgG
Ii peptide
[751
Unknown (i) GFVCSGIFAVGVGRC (ii) APGVRLGCAVLGRYC
11081
Epitope RRPFFX
I1091
Epitope WFSWGFPCIWW
I1101
LEX,TS
2.8 x 10s
(clones)
PAI-
Unknown GCIFWHLTSMSGSYFLEPFDLIST SQQRNIPLEIRDADT
11111
LEX , ,TS
1.4 x 1 O7 (clones)
PAI-
Mimic PVSQFVFLCGHQPCFTSEHAHDVP DPAPPHHPLELITGRCIATPISVGMS
11111
*Flanking sequences shown where reported. ?Where further differ, values given refer to only the initial round of selection. represent diversity, except where Indicated (clones = number transformants; phage = number of input phage). Sequences type represent ammo acids encoded by DNA sequences
respective small molccr~le. Wcrstuck demonstrated that allosteric mRN.4 erated by inserting 3 drug-binding S’-untranslated region (S’-IU‘R) of tion allow both it/ s&u and it/ repressed in the presence of a small
rounds Values of in bold
and (;recn [Ih’] have templates may be genaptamer into the an mRN.4. ‘I‘his inserGsv translation to bc molecule.
The thirst for structural information I,ogic:~lly, structural analysis providch ;I clear path to understanding the mechanisms of recognition jnd catalysis pcrformcd by functional nucleic acids. Indeed. Jacks [-I71 argued that, for protein enqmcs, the most striking generalization WLS that many of the expectations bawd on chemical studies were simple cwnfirmrd once crvstal strllcturns were in hand. In rhis l.cin, the striicnirc of alptamers in S(JlLltiOn solved using NhIR spectroscopy has generally pro\idcd significant insight inro the recognition process, indic:lting the presence of compact binding pockets for slnall inolcclilcs (for rwiws, set [-C--SO]). Analysis of
corresponding RW Roberts, observations. co-stimulatory MHC class
to restrictlon sites. (a) P Burgstaller, S Hale, M Wright, R Liu, JW Szostak, RW Wagner, unpublished CSF, cerebrospinal fluid; CTLA4, anti-T lymphocyte molecule; Ii, Invariant chain peptide from cytosollc tail of II; PAI-1, plasminogen activator Inhibitor 1.
three pockets (present in A’l‘l’, FRIN and @nine aptamers) indicates that binding appears to provide somehvhat less of a tight fit than protein sites and relies heavily on stacking, 3s opposed to hydrogen bonding [SO]. ‘l’he path has been somewhat bumpier when examining nucleic acid catalysts. ‘I’he central difficulty is crystallizing either RNA or DNA enzymes in their active form. In the crystal structure of the 10-23 DNAqme, the molecule has rearranged to form a dimer that is not likely to be the active conformation [Sl’]. ‘I’he sn-ucturc of the lead-dependent rihozyme crystallizes in two forms. one of uhich is ‘precat3tytic’ and rationalizes the cleavage chemistry (S?]. IXfficulties are seen in structural analyses of natural ribozvmcs as well. hluch has been made of the conundrum tlut the hammerhead ribozyme structures do not rationalize the cleavage chcmistr?; [S.i,%]. whereas larger RN.4 catalysts. such as the group I intron catalytic core [SS] and the hepatitis delta virus rihozyne (after cleavage) I.561,
524
Engineering
Table
2
Proteins
and design
displayed
Protein
on phage. Clones*
modlfled
Heregulin (nine mutagenized Knottins
1 .O-6.4
sections separately)
(CBD)
Llpocalln bindlng
(16 residues site)
in
hGH (site 2: four sectlons mutagenlzed separately)
*Values
represent
the
ErbE3
x 1 O*
receptor
References
>50-fold
higher
afflnlty
Cellulose tr-Amylase Alkaline phosphatase [&Glucuronldase
Epitope Unsuccessful K,=lOpM Unsuccessful
3.7 x 10s
FluoresceIn
K, = 35.2
nM
(>102-told
hGH
K, = 0.16
nM
(38.fold
higher
afflnlty)
domaln;
hGH,
human
growth
x 107
of transformants
in the first
round.
receptor
CBD.
C-terminal
cellulose-bIndIng
therein).
[87”]
H>- comparison.
the
hxttisc
the
imcnt that
cm
IX
ribosome Ability
and proteins
Selections ‘i‘hc tnosT
using
prorcitls
and
Tc’iii
dcvelopcd
!n
:ttf‘init!,
toh,
2nd
c;iI
panning
of ~tly~ro~itmttcl~
iising
;I \3ri:iriori
infi-ctive
phtig:c
wlccrioti int’cctt\,it!, libr-;ir)-
of or
‘S11”
iii
\\ ith
:I tot31
Iligh
in
binding I I I f(tsions
libr:tr\
rccovcred
dtthbcd
(rc\ic\+cd
to
\I hcreb\
uliarion.
h:ts also. t)ccn
1,
0.0001 ‘,C IX cl cn selccli\c-
ISX],.
111
i\ rcclttired containinK
constraints
iniposcd
translated
prowins
ril)osontc
iticrcasing ribosomc
one
IIillion
the
lihrar\ prouzina
six
has
to otticr
mainI\ In addirion, ph;tx:c pwt2rftil techniqites.
4s
t-ccoliil)inacioii
in tuctcria.
;ttld
nlolcculcs.
(WC
~tscd
for
been
the
i~/c.it/~~
limircd
frOmi
prescricc \vhich
*I
31ltl
the
or 101.i pcplidc4 rc\
prowin\
ic\vS).
‘4
hid
G;I c’ompruiicn-
IW].
cl
i-cfcrcncc,
In this
itscd cl.oltition
scl~~\~s
cull.
In ribosotn~
remain
of Ioueritig
display.
complexed
the
with
tcnipwttttre
and
[O.i]. Selections dctnonstratcd the
(single-chain
is Ihat
approach. .Afwt-
pcptid)l u ith the
lnatel\
host
mKN4
trrtn\lation or other
\ 3riat)lc
libr;iricS
fb~‘].
libraries
mitsr
ttsing aKinit\’
dotnain (hlc
frq-
Of
~illlir~i~iOi~
he screened
in rhe
rhc entireI~i~JiJSOtllc iindcicondition:, in tcr-itar\ mKN~i-ril,osolne-pepri~i~l-tliN ~1 is stahlc ;liigh hlgJ+ arid 1014~ remperatttre). A nicthod for producing co~.alcntl\ linked fitsion~ ha hccn rcccntl\ introdrtc.cd
.i’-puromycin.
abottr
cell-free in I itro :t11\ wnsfortn;lCon
of
(4,5”].
cliie C(J the trarisfcction liinit disl>la\, is nc,r easily poj-tzl>lc includln~ i/l E+//.o rnttt3gcI1C. I.SY.f~O”*.f,l
nietfiods,
pro\.idc
the
coii~l~lcx IlO\
by chc and
iilliiiilnized
displa);
fortltc
selection
to onl!
01‘
tiieil~s)
\.arietv
and
expcr-
transl:ttcd fOr
is littkccl
the hl$’ concetitracion displa), rcccntl! ha\,c
rlii\
target.
rccentl~~.
pcpridcs
10”
[~?,h]
reporred
34 3 resttlt
in;itiir:lfioti
linkage I ltitil
infortn;triott
:\II of these stratcgics ttTili/c \) siccms. therch\, a\ aiding
tilKNA-protcitl
New methods of
than
the
of tiiolccttle:,
fusions.
(XX
sclccin
is impotunt
dc\~ulolxx1
kcepin::
IJ!
inKk/j
approach.
ril~osornc
niulriplict-
01‘ pliage
displ:t!.
rcccp-
In ;i typlihr;tr\ is
the
i ii
O\vIl
acid sreps
combinatorial
rccentl)
of more’
rcspccti\,cly.
hormone.
tlutnlwr
niK\/\-prowin
lil)rarics
11121
nttclcic
ofa
to the
‘I’\~-0
and
ICI dlcir
the
bacteria
hctuccti 0.01 % :ind ‘I‘his pcrcctltag:’ can
proccdttre. ligaticlLtar,p3 itsing hipartatc g:enc ~iid
uittt
mcml)crs.
ph;ig:c
or
selccrcd 01
IrottnJ~.
fr:tctiott
lo\\ (rvl~ic:tll~ popiilation).
\‘cI-\
31~
mixctl
(>lOOO).
tltc
(- l-7700 1’111
substraws
ticrlcc
IO-10”
Ixxaiisc
iripttt
lower
scq
\)s-
in the K tcrniiiitis hactcriophagc
\trh\ccl”cnr
phagc
inany
i\ csscntial,
~cncr;ill\ of the
f‘or
prorcins.
with
b38’1
;irc
gciic
hlolcc~tles arc
phagc
t5CIl
I,\
I0
imnrot~ili~cd
pliaqc
cXpcrinierir.
\i7c
I>
rcsitltirifi
pro~ctl)
represented r\
on
display
formar
fiirtons
[7..57’]).
of
Scqitencrs
tntilticopv
sw
selection
phqc
(O-S col~ies/pha,gc) sitrf2cc of filametitotts
rebic\v.
tlic
prmliicc
it/ Ct/u
Snlich.
Y-terminal
‘single’ copy fortii;rt 01‘ ;gctic II I on the 3 rccwlt
the rhc
(;corgc
in
cithct 3s
ccJl~ics/phafic)
for
screened.
ro scrccii
linked
is currently IJ!
cxprcsscd
(for
display
techniclttc
common
pcptides
or
phage
proportional
display
affinity)
bccausc all the ‘l’his diftbrencc
pwvcr
~Otll~ltl~~~~Oll~i~
is dirccrly
higher
litnit
tions is 1 ()t5-1()t(~ seqttrnccs, process arc pcrformcd ;?I s.itm.
Peptides
[ 104”]
5.5 r 108
1.3-7.3
number
Result
Target(s)
transfuasr protein allous
that
a mKNA
Cr3ns13tion.
2
selccrions
ttr bc Kccenrl!.
arid
scrccii
x 1 ()I.“ diffcrcnr to the anti-c-tn\ic,
mcnT tltcror5 (1’ Hurgstallcr. .I\L’ S/.oartik,
is tagged
puromycirl
site and bccotnes it encwdcs. ‘l’his
of conditions. to generate
librq rlic
of more S Hale, 1<\2~ \Vagrtcr,
co\~alently chctnically
pcrformcd rhic
3 lihrar\ peptidcs antihod!-
rh:rn 700 hl \Vright. ttnl>ttt)lishcd
lvith
enters
linked rohttsr
i~t~clct-
techniqrtc conraininx for YElO.
:t the
;I
has
wide
IXCII
approxiIjinding and wirh enriclt-
per rotlticl (‘li~hle 1) RM’ Roberts. K I,itt, ot,aer\,ations).
In vitro
Se~cral other technical ad\,ances arc also expected to techniques, cnhancc the power of ill r:ifro selection including improved in tvtro recombination and mutagrnsis. and interaction mapping by XMK spectroscopy. New methods for in vitrn recombination may bc technically simpler and/or more eff*ecti\,e than the original IINA shuffling technique devised by Stemmer [hS]. Among these is family shuffling [60”], whereby di\,crsity is created b> recombining two or more homologous gents. ‘I’his has the ad\,antage of creating di\.ersity that ha\ alrcady been prescrecned 1,~ nature to weed out mutatil)nb thar are deleterious to :I particular fold. generating libraric\ that are much richer in functional proteins. Alternatives to the original I)Yase-I-based shuffling pietow1 ha\,e also been dc\,tzlopcJ. including random priminK recombination (KI’K) [M] and the staggered extension process (61’1. Kandom clon,gation rnirtagcnesis (Kk:kl). the addition of a partially randomized sequence to the (: terminus of’ the protein. i\ rrnlikel\~ to change catal) tic propcrtics. hiit 111;1\ bc ;I siinplc apl)roac‘h for enhancing enzyme \tabitit! (073. III an increasing nurnbcr 01‘ casts, thcb conforn~ation~ 01 sclcctcd n~01cc11Ies (peptidc\ and pmtcins) bound to thcirtarget4 h;I\.c’ been sol\Tcd 1~) crystallographic (see discussion below). NhlK spcctrowlp~ has pro\ed to bc increasingly uaefui ti)r char-actchri/.ing l)oth dynamical sy+ tcnis and those that arc rccalcirrant to cr\srallization. ‘li\o rqJrcscntati\ c examples arc given. ‘I’hc Schultz and \Ycmmcr laboratories [6X’] ha\c rcccntl\ iised transt‘crrcti NOI< (nuclear O\whauscr cnhancsmcnt) cxpct-inicrits t(~ dctcr-niirrc the qzonrctr\~ of‘ t\I 0 \rrbstratca in tlic ;rcri\c site ofarr a(,\.1 tr-snsferasc antiljod!. I~;rirlJrothcr- /I/ N/. [OO**/ irscd t\\.o-~iiiiiciisioii;iI I I I-l’K I I.S(>C 1 (hctcronrrcIc3r billfilC (1uantirm cohcr-crrc,e) cxlwr-inicnt5 to dcl‘inc the interactiori bct\vccn bclectcd 1Jcptidc.s 2nd tlic rl l,ri%labclcd target VE(;IC I’cptidc intct-action5 with \~l
selection
of nucleic
acids
and proteins
Roberts
and Ja
525
.An increasing number of laboratories have reported peptides or small protein tigands that can functionally mimic the three-dimensional surface that is normally bound by a full-sized protein. ‘I’hese examples are particularly interesting because they emphasize both the plasticity of protein surf&es and the range of structures (both in size and topology) that can functionally substitute for one another. ‘I’he functional substitution of small peptides for much larger proteins runs counter to the notion that protein interactions arc driven in proportion to the burial of h!rdrophobic surf&e (see [7h] and references therein). One of the most compellink cr e.uamples of this mimicry arc the erythropoetin mimetic peptides (ti;2ll’). short (-13-20 residues) p hairpins that functionally mimic erythropoetin, a .M kl)a glycoprotein. but bear no sequence homology 177.7X.79’]. Similarly, prptides or minimized proteins have bc*en found that mimic the function of thrornbopoetin IXO], an antagonk VkL(;I; lhY”.70’], or bind to constant tcgions in antibody structures (XI 1. ‘l‘lrc peptides isolated by both types of selection generatI! bind to the same regions utilized by the natural counterparts they arc meant to mimic. I’or linear epitopes, this is perhap” not surprising. I’Or’ the peptide mimics. it borders on scandalous, as, often. most of the target protein surface i\ available for interaction during the aelcction. ‘l’trc clear implication is that sonic regions of protcin srrri’ac~~ arc more ‘stickv’ than others and, thus. act as hot spots for interaction iX.!I. Antibody selection: the importance of large libraries Although complete co~eragc ofpha~c antibody selection is tjcvond the scope of this war-h. a recent re\.ic\r highlights the importance of high-colnlllc~it~ starting librdrics [.57’]. \z’lrci~ lo\\~-con~~~lcsit~ libraric~ containing 3 x 10’ clones \\crc rised. single-chain antibodies with affinitic\ ranging from 10 to 0.1 X 10~” pZl IX.%.XAJ \\cre isolated. With lrbi-arics containing 10”’ clonc~, affinities of 10 to O..‘, nhl \+‘cr’c tijund (X.51. ‘I’hc commensurate increase in binding constant with increased library \i/c is in line with thcorctical pi-edictions dc\,clopcd to cstirnatc the binding ~onst;~nts from IitJrar~~ complcxit~~ (XOI. Alternative scaffolds II‘ Iqtidcs can bc found that mimic proteins. one might ekpcct that snia11. strrrctured pcptidcs could be used as scaffold\ to display function. Kather than choose ;I single motif’. I~‘airbrothcr otcr/. [W”] used 3 variety of small, disulfi~lc-coiitaininC pcptide\ to isolate binders to \‘K(;f; c’I~IIJIc I). Similarly, knottiw. small, disulfide-rich proteins h.r\,c been irsctl to generatr librark that recognize alkalint phosphatasc, a ~H’Oteill Lrith no wild-type knoctin binding 1X7”]. j’r.otcin scaffolds that cordd IX imbued with antibody di\.crsit\: h:r\,e also been sought. particularly beca~~se ofrhe rcfractorq natrtrc of some scl*‘\~. Skcrrd and co-workers (HX’I ha\ c rcccntlv reported that lipocalin HI3I’ variants
526
Engineering
and design
(a 174 amino acid p barrel) could be isolated that bound fluorescein with a dissociation constant (K,) of 35 nlvl. Direct selections
for catalysis
There is great interest in using selection both to refine known catalysts and to isolate new ones. TSAs have been used to isolate a great diversity of antibody catalysts via ill v&o immune selection (151. In a few cases,irt vitro selection has been used for affinity maturation of the catalysts using ‘1‘SAs [89,90’,91,923 or via a mechanism-based approach (discussed below). The potential limitations of the ‘TSA approach are highlighted by work from the Wells’ laboratory. Baca rt ul. [89] used affinity panning of an esterolytic antibody library derived from immune selection to isolate variants with two- to eightfold improvements in their binding affinity for a phosphonate ‘EGA. Notably, a correlation between binding afftnity and catalytic ability was not observed. A weaker binding variant was identified with twofold greater catalytic activity than the parent antibody, emphasizing the need for an approach that selectsfor catalytic activity [WY]. In the direct strategy. enzymatic activity is required to either covalently attach or releasethe library membersduring selection. This approach hasbeen successfully applied to isolate RNA and DNA catalysts that are capable of performing chemistry with rates ranging from 0.1 to more than 100 min-1. significantly faster than many catalytic antihodies [33]. Lerner and co-workers [93,94] ha1.eapplied this strategv to immune selection with great success.In one interesting combination of reacti\,e and ‘I‘SA approaches, phage display was used to improve catalytic antibodics designed to cleave a glycosidic bond by 700-fold (k,,,/k,,,,,, = 7 x l(P versus 102 from immune selection) [OSj. Substrate-bond cleavage generated a quinone methide that reacted with rhe phage to afford immobilization and selection. Reactive approaches can also be incorporated in phage selections to afford specific release. The Schultz laboratory [96’] has recently demonstrated that phage harboring active staphylococcal nuclease can be enriched IOO-fold in a single round, based on cleavage of an oligonucleotide tether in C/S.A similar strategy involving immobilization demonstrated enrichments of more than SO-fold for two model proteins using phage-displayed enzymes and the calciunl-depelident binding of substrate to calmodulin [97]. Structural proteins
studies
of selected
and evolved
peptides
and
‘I’here are now a significant number of selected prptides and proteins whose structures arc known. \Ve include catalytic antibodies and i/f d/a screened proteins in this discussionbecausethe structural conclusions seem gcnerally applicable to all functional approaches. One \‘crv striking feature is the way in which protein structure can be modulated by seemingly subtle changes in sequence.
In general, proteins that have been evolved either in viva or in vitro contain positive mutations that are distal to the active site ([98-l 001;B Spiller, A Gershenson, FH Arnold, RC Stevens, personal communication). These mutations often have the effect of remodeling the shapeof the active site and may act by biasing the conformation towards lockand-key-type recognition [99,101]. In addition, the selected mutations often make significant changes to the local structure (B Spiller, A Gershenson, FH Arnold, RC Stevens, personal communication) and can even alter topology [1OZ”]. As interesting as where mutations are is where they are not-the active site or critical residueson the interface of the proteins. For example, residues conserved in phage selections of heregulin variants (binding to the ErbB3 receptor) correlate strongly with positions that were found to be important using alanine-scanning mutagenesis [103’,104”]. Selection and evolution thus seem to avoid changing residuesthat are in direct contact with the target. Rather, beneficial mutations enhance affinity by reconfiguring essential binding residues or by forming new contacts. Indeed, these complicating secondary effects prohibit the delineation of a recognition code, even for highly modular protein contacts, such aszinc-finger-DNA interactions [lOS**]. The importance of long-range interactions and plastic local structure are likely reasons why rational design has yet to produce the results seen with functional approaches, such as in vitlz, selection [lob]. Computational approachesmay significantly enhance pool design. however, allowing us to ‘stack the deck’ of initial libraries, making selections more fruitful or reducing the number of cycles required.
Conclusions IN eli~o selection has proved itself to be a powerful technique. For the foreseeable future, functional approaches provide the most facile path for engineering nucleic acids and proteins alike. The new methods developed will allow larger, better libraries to bc generated and more powerful \vays to screen them to be elaborated - further expanding our ability to generate interesting molecules for studv. A fundamental question is how the information from selection experiments can be used to further insight into biopolymer folding and function. l;or the present, the results of selection and screening cxperimcnts provide existence proofs and hard data on some very interesting questions, including the number of nucleotides needed to specify a catalyst, the number of amino acid changesneeded to improve protein thermostability and the free energy consequences(or lack thereof!) of introducing or removing a small functional group (e.g. a methyl group) from either the macromolecule or its target. Future experiments are likely to addressissuessuch asthe generation of new function. the minimum size of protein needed to perform catalysis and the likelihood that such a protein could be found in random sequence libraries.
In vitro
Acknowledgements 1%‘~ thank Frances H Arnold and rhcir manu&pt prior IO publication.
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of the thrombopoietin receptor Soence 1997, 276:1696-l 699.
81.
Starovasnlk MA, Bratsted AC, Wells JA: Structural native protein by a minimized binding domain. USA 1997, 94:i 0080-i 0085.
82
Clackson receptor
T, Wells interface.
JA: A hot spot of binding energy Soence 1995, 267:383-386.
as the
mimicry of a Proc Nat/ Acad SC{
selection
of nucleic
protein model
of phage. enrichment
acids
and
Intramolecular catalysis using staphylococcal
proteins
provides nuclease
Roberts
and
Ja
529
the basis for selection. is demonstrated.
97.
Demartls S, Huber A, Vitt F, Loui L, Glovannoni Neri D: A strategy for the isolation of catalytic repertoires of enzymes displayed on phage. 286:617-633.
L, Neri P, Winter activities from J MO/ Biol 1999,
98
Patten PA, Gray NS, Yang PL, Marks CB, Wedemayer Bonlface JJ, Stevens RC, Schultz PG: The immunological of catalysis. Soence 1996, 271 :I 086-l 091.
A G,
in a hormoneevolution
Marks JD, Hoogenboorn Wmter G: By-passing gene libraries displayed
99
84
Gnfftths AD, Malmqvist M, Marks JD, Bye JM, Embleton MJ. McCafferty J, Maler M. Holliger KP. Gonck BD, Hughs-Jones NC ef al.: Human anti-self antibodies with high specificity from phage display libraries. EMBO J 1993, 12:725-734.
Wedemayer GJ, Patten PA, Wang LH. Schultz PG, Steven RC: Structural insights into the evolution of an antibody combining site. Science 1997. 276:i 665-l 669.
100.
Vaughan TJ. Willlams AJ, Pritchard K, Osbourn JK, Pope AR Earnshaw JC, McCafferty J, Hodlts RA, Wllton J, Johnson KS: Human antibodies with sub-nanomolar affinities isolated from a large non-immunized phage display library. Nat B;ofechno: 1996, 14:309-314.
Oue S, Okamoto A, Yano T, Kagamiyama H: Redesigning the substrate specificity of an enzyme by cumulative effects of the mutations of non-active site residues. J B/o/ Chem 1999, 274:2344-2349.
101.
Romesberg FE, Spiller B, Schultz origins of binding and catalysis Science 1998, 279:1929-l 933.
86.
87. .*
Lancet D. Sadovskv molecular recog&ion significance to the 1993, 90:3715-3719
Smith GP, Pate1 SIJ, Gnfflths AD: Small repertoire of knottins 277.317-332. Tht: knotttns represent sequences maintain their fide bonds (typically 2-3 folds to display chemical knottln library and derived
TP, McCafferty J, Gnffiths AD, human antibodies from VI MO/ 8101 1991, 222:581-597.
GJ,
83.
85.
HR, Bonnert immunization: on phages.
as potent
In vitro
E. Seidemann E: Probabilitv model for in biological receptor repertoires: olfactory system. Proc Nat/ Acad So USA Wlndass JD. Thornton JM, Winter G. binding proteins selected from a combinatorial displayed on phage. I iflo/ B/o/ 1998,
103. .
some of the smallest proteins known. These folded conformations due to the presence of dlsulout of 30 amino ar:lds! and have potentcal as scat diversity The authors screened a cellulose~blndlng binders for alkaline phosphatase (see Table 2).
Beste G, Schmidt FS, Stlbora T, Skerra A: Small antibody-like proteins with prescribed ligand specificities derived from the lipocalin fold. Proc Nafi Acad So USA 1999, 96:1898-l 903. The authors demonstrated that I~pocal~ns may represent an alternate franxwork to antIbodIes for developing general bIndIng proteins vfa ,,I vitro selcctlon Baca M, Scanlan TS, Stephenson RC, Wells JA, Phage display of a catalytic antibody to optimize affinity for transition-state analog binding. Proc Nat/ Acad So USA 1997, 94.10063-l 0068
90. .
ArkIn MR, Wells JA: Probing the importance of second sphere residues in an esterolytic antibody by phage display. I MO/ B/o/ 1998, 284:1083-l 094. Phage display was used to improve and probe estrrolytlc antbody functton The report provides another example in which residues remote from the active site are Important for blnding and catalysis A correlation IS seen between transitton state analog bindlng and catalytic function for single mutations. 91.
92.
FUJII I, Fukuyama S, lwabuchi antibodies in a phage-displayed Rmfechnol 1998, 16:463-467.
Y. Tanlmura R. Evolving catalytic combinatorial library. Nat
Gao C, Lavey BJ, Lo C-HL, Datta for catalysis from combinatorial acid probe: primary amide bond 120:2211-2217.
A, Wentworth PJ: Direct selection antibody libraries using a boronic hydrolysis. / Am Chem Sot 1998,
93.
Wirsching P, Ashley JA, Lo C-HL. Janda immunization. Sc/ence 1995, 270.1775-l
94.
Barbas CFI, Helne A, Zhong G, Hoffmann T, Gramatlkova S, Blornestedt R, List B, Anderson J, Stura EA. Wilson IA, Lerner RA Immune versus natural selection: antibody aldolases with enzymatic rates but broader scope. Science 1997, 278:2085-2092.
95.
96. .
KD, Lerner 782
Jones JT, Balllnger MD, Plsacane PI, Lofgren JA, Fitzpatrick VD. Fairbrother WJ, Wells JA, Sllwkowski MX: Binding interaction of the heregulinR egf domain with ErbB3 and ErbB4 receptors assessed by alanine scanning mutagenesis. J Biol Chem 1998, 273:l 1667-l 1674. A thorough study of protein speclficlty through exhaustive alanlne scanning mutagenesis.
Balllnger MD, Jones JT, Lofgren JA. Fairbrother WJ, Akita RW. Sliwkowskt MX, Wells JA: Selection of heregulin variants having higher affinity for the ErbB3 receptor by monovalent phage display. J BKI/ Chem 1998, 273:i 1675-l 1684. Variants of a growth factor domaln with higher affinities for Its receptor revealed that beneflclal mutations generally avotded critlcal blndtng residues, Evolved proteins had enhanced affinity either by reconfjgunng essential blnalng reslduos or by formlng new contarts
l
104. *
105 ..
Elrod-Erlkson M, Benson TE. Pabo CO: High-resolution structures of variant Zif268-DNA complexes: implications for understanding zinc finger-DNA recognition. Struc~re 1998, 6:451-464. A thorough structural analysis of zinc-finger-DNA variants revealed the dlfflcultles in determInIng an exhaustive recognition code defimng zlnc-finger DNA-bindIng spectftclty. The results cast serious doubt on developing a code for sequence~spectflc protein-DNA recognltlon. 106
Street 1999,
107.
Rod) DJ. Janes RW, Sanganee HJ, Holton Screening of a library of phage-displayed human Bcl-2 as a taxol-binding protein. 285:197-203.
108.
Fukumoto T, Tongoe N. Kawabata S, Murakaml M. Uede T, Nlshl T, Ito Y, Sugimura K: Peptide mimics of the CTLA4-binding domain stimulate T-cell proliferation. Nat Bmtechnol 1998. 16:267-270.
109.
Rand KH, Houck H. Denslow to find target(s) for oligoclonal / Neural Neurosurg Psychiatry
110
Bremnes displayed peptide
RA: Reactive
Janda KD, Lo L-C. Lo C-HL, Sm M-M, Wang R. Wong C-H. Chemical selection for catalysis in combinatorial antibody libraries. Science 1997. 275:945-948
Lerner
Immunological antibody.
102. Cordes MHJ, Walsh NP, McKnight CJ, Sauer RT: Evolution of a .. protein fold in vitro. Science 1999, 284:325-327. The substltutlon oi two residues Into the Arc repressor changes the local secondary structure from a b sheet to a short u helix, with the preservation of core packing. The results Imply that modest changes in amino acid sequence may allow signlflcant changes in local secondary structure
88 .
89
PG, Stevens RC: in a Diels-Alderase
RA:
Pedersen H. HBlder S. Sutherlln DP. Schwltter U. Klna DS. Schultz PG: A method for directed evolution and f&ctional cloning of enzymes. Proc Nat/ Acad SC/ USA 1998, 95:i 0523-l 0528. A novel strategy tar the direct selection of catalysts by phage display IS demonstrated by attaching both the enzyme and substrate to the coat
AG, Mayo 7:R105-R109.
SL: Computational
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RA, Wallace peptides J MO/ B/o/
Sfructure BA, Makowskl identifies 1999,
ND,
Hellman KM: Molecular approach bands in multiple sclerosis. 1998. 65:48-55.
T, Lauvrak V. Llndqvlst B. Bakke 0: Selection peptides from a random IO-mer library target. lmmunotechnoi 1998. 4:21-28.
of phage recognising
11 1, GBrdsvoll H, van Zonneveld A-J, Helm A, Eldering E, van Meijer M, Dano K, Pannekoek H: Selection of peptides that bind to plasminogen activator inhibitor 1 (PAI-1) using random peptide phage-display libraries. FEBS Letl 1998. 431 :I 70-l 74. 112.
Pearce KHJ. Cunmnaham hormone binding aifinity requirements for cellular
L:
BC. Fuh G. Teerl T. Wells JA: Growth for its receptor surpasses the activity. &ochemfstry 1999, 38:81-89.
a
In vitro selection of nucleic acids and proteins: we learning? Richard W Roberts* and William W Ja For almost used
a decade,
to isolate
according
novel
to their
our perception appear
selection acids,
experiments peptides
function.
Selection
experiments
mimicry
and catalysis,
with
facile
than
desired
rational
properties.
design New
have
the
been
have
structural molecules
Information hlghlights
ratlonal
approaches.
testin::
altered
each
that
,\ dcr~lc
ago.
LYHII~ hc t’o~~nd that
:rnd/or
fllnction
I:ltion
of KiY,\
that
Addresses
in Structural
hind
Callfornta
lnstltute
Science
Ltd
ISSN
1999,
Introduction
and
aptan’crs
;;:encral
.Idrlitic)n
KY\
Kc\,), no
3s lrcll
nkitiiral \,ascul:ir
in3~
‘Ilie
ahilit)-
35 small
\ystcms.
I:ition.
‘l‘hcrc.
IX
ilii;igc,
molcciilca
hind
transcrip anJ
proteins :ictivit, [L~l<(;l:]
factor
tcstcd
allow for
function
all the ;It
the
tinic. 13> coniI)2risoii. sci-ccllinfi cupuriments th:lt t-:lch 1~)ol mcmhcr bc qllericd indi\iidllail\. selection cupcrinients ,~ wncrilll\ ,illou milch Iarxcito I)r sirr\,cvcd than \crccriiiig eYpcrimcnts. On
th;it
:tcici\
of the
it’ the mirror with naturkrl \t:lhlc
binds
to mimic
in
oli,qmu-
the
and
best
the
5triictiirc .i
‘l’hc
natural
rheory
crsir!
strtictiircs
121.
this
the
transition
seen1
of
the
that
i5 doniinatt4 howc\,cr,
an
‘KN/I
by proteins ha\,c
its hounds.
t:,ictol
ril~osonie
cnlr\
m;inv
bv folded in
ha\c the
cii!i;lr\otic
inlportaiit
3 p-cat
esperiniental
in tt‘r-
and
to in
internal
mimicry from
in\.ol\ed
.Siniil:irl~,
!)\ ;kn tlcncc.
pn~\~itlcs
th;it
dot<,
t:,ictors
min~icked of
kno\\ from exists in tr;lns-
1<1~-(~4;‘1’1’)
Kk-.34;‘1’1’)
portion
in sclcction
no\\
examples Ed
he mimicked (IKICS) 11.3,1-l]. di\
wc
protcin
I Il.
initi;ttion. can
proteins
eY:liiiplu~
One of the KKX
general
both
protein KNA strllc-
natur:il
and
support
for
c\orld
to a bio-
is possible. It follo~~s
thut.
if
any small molecrile target, c;italysts COIIIJ IK discovered tq sclccting lihrar): mcmhers that hind transition-statc andogs (‘I’SAsL ‘I’his approach has hccn iiscd to ,great adv3ntage in the immiinc sclcction of catal\,tic antiboclit3 1 IS]: howc~cr. success has been Iiliiitcd llsin:: KN.1 ;~ncl I)NA apt:lnlcr\. ‘l’he first ewmple was .ii)taincrs
euperirnents
sllhstitution
I~iologic:ill~
~onstrii~~tcd
(t~l~-‘li~~~~‘l‘l’~rK~~~ (KIY-1. KIT-2 :lnd
\liinicrk
libraric5
the
th;lt
rc\wsc
or hv the
is cchoetl
chcmistrv
i~lmc rcqllirt: ‘l’hiia.
isolated
HIV
(e.g. 191). .iltcrn:lti\ei~, protciil tar~:ct is iised
of nucleic
n:ltural
the
he
miniic
1101.
non-n:irirr;il
to
[7]) clone
hetcropol~-
to
iliiclci~-acid-t)iii~lili~ cndothelial ,qrowth
:I mirror
or I)k;\.
tal’!$?
of art
yclection
has
one
iiscd
been
(c.g.
of pho~~,horothioarcs
I leotide
tklrc\.
l~)oI
that
iso-
fit’
1.
have
\U~IIC~CC’ nmtifs can bc ftlnction:lli\
;,ifftv
‘I‘hc
proteins
hc
;I pi-ottzin
;Ipt;tniers
1’-01 I t\ith 2’-Ntl, irnak:c of the 0ri:in;rl
ti.;liisl;ition
the
:lt best.
2nd 1 asoprcwin) IX]. ‘l‘hcsc krptamcrs can Lx ackiptcd foi IISC i/l c,izw if thcv ;Irc protcctccl from degrad:ltion b! the
cll4‘4(;
i/l
:tnd
or :I I>NA strll<‘turc
the
c//)TN.F, ‘to
and
notion
protrins
thrombin,
ximc
in
KNA
(from
miiv
I1iX.A) (c.~.
I)N:\
,ind tlli’ t11:1t h:l\,e
clon,qtion min;ltion
nlolccllle
;I
in
cloning
either an mimicked
molcc~~lc~
the or
of :lnc)thcr
c\pcrinwnts
(kncra1ly.
rnelnbers
withollt
W;LS hrretical
I>NX
sm;ill
KN,A
t;isc
9:521-529
0959-440X
and terms
that
of ;1 protein
to advance
I<%\
quantum coherence polymerase chain reactlon single-chain vanable domaln fragment transitlon-state analog vascular endothellal growth factor
SCFV TSA VEGF
individwi
of
Abbreviations EF elongation factor FMN flavln mononucleotide HSQC heteronuclear stngle PCR
propn\:ll
:tncl
both
(e.g.
(c.K. c Elsevler
the
iiir~lci~-acicl-l,indinfi
Biology
of
known
and mimicry
fllnction
Opinion
it\
is not
m()IccIIIc
lnu(.h
Englneenng, USA
:Icti\
RNA and DNA
Aptamers
have
on a number of selected and future challenges for design via
Dlvislon of Chemistry and Chemical Technology. Pasadena, CA 91125, *e-mail: [email protected]
the
inciiviciual.
Functional
at generating methods
iller
Current
hand, experiment
and they
been developed improve the power of functional strategies In ways that nature has already dwovered - by expanding library size and facilitating the recombination of positive mutations. Recent evolved
other
selection
and proteins
of molecular
to be more
biopolymers
in vitro nucleic
what are
:I Irll>o/.wnc
could
th:lt
hind
enhanced
the
isomerization
ofs~~l~rtitutetl
522
Engineering
and
design
biphenyls by M-fold over background [ 161. Subsequently, RNA and DNA aptamers that bind /V-methylmesoporphyrin (NMMP) were found to stimulate porphyrin metalation [I 7,181. ‘I’he scarcity of enzy-mes compared with catalytic antibodies may be a result of the different mechanisms used by nucleic acids to recognize small molecules compared with those used by proteins (see discussion below). On the other hand. the relative paucity of ‘I’SA-binding protein catalysts that have been isolated via phage display may imply that in vitro selection techniques need to be improved in order to match the ability of the immune system. Amide- and peptide-bond-forming catalysts One central tenet of the ‘R&A world’ hypothesis is that the mother of all enzymes, the ribosome, contains RNA in its catalytic heart. In addition to in\,estigations that point to rRNA as being essential for ribosome activity [ 19-21 1. :I number of laboratories ha\,c set out to test whether or not ribozyncs could be found that arc capable of catalyzing amide-bond formation. ‘I’he first C~ICCCSS involved an ac\l transferasc ribozyme that was capable of forming an amide bond between a .i’-NI-I,-R’VA and .Y-biotiny-l methionine attached to the 3’ end of ;I hexanlrcleotidc (k, - 0.6 min-1) [27]. Recently, E;aton and co-norkcrs (2.31 reported the isoIation of amide-bond-forming rihozymcs that do not require an oligonuclcotidc tether ro the substrate. a .j’Ahll’ actixrated ester of biotin. ‘l’hcse riboqmes do rcquirc .j’-imidazole uridine, which ws incorporated uniformI\ in place of uridine in the RNA pool. Although neither of these ribozymcs was reported to contain sec~wzr~cc: homology to natural RNA sequences, me of the peptidyl transferasc riboqmcs isolated by %hang and Tech did [24,25-l. The clone 25 ribozyme contains ml internal loop with regions of’ sequence identity to the centrdl loop of domain c’ of 2% rRNA, a region that is central to the peptidyl transferasc function of the ribosomc. Surprisingly, aptamcrs that bind the pcptidyl transferasc inhibitor (:cdAp-I’urotn)lcin share identity with the peptidy1 transferasc ribozyme and with 23s rRNA 1261. I>cspite the recent retraction of bvork arguing that domain \’ RNA transcripts ha\,e peptidyl transferase activity [27/> the selection data represent proof that RhA has the potcntiul to carry out a \,ariety of amide-bon~l-forming reactions. New ribozyme reactions A number of rihozymes with new activities have been isoIatcd recentI>, including molecules that are capable of catalyzing the s\.nthcsis of ;I IlUc~e~Jtidc [28”]. cnzylcs selected to mim;c reactions in the spliccosome [29’] and riboaynes capable of performing a I)iels-Alder cycloaddition reaction [.iO]. In the first example, I Jnrau and I3artel [28”] uncovered ribozymcs that are capable of joining a tethered I-thio-uridine nucleotide to pRpp (5’ phosphoriI,os)jl-a-l’~rol’hosphatc), the activated ribosc (ised in nucleotide biosvnthesis (I~,..,, = 0.1 .i minmI). ‘I’his reaction is almost identical to the natural reaction carried out I)\ uracil
phosphoribosyltransferase pRpp, making uridine
(IIPK’I’) 5’ phosphate,
to couple
uracil
and
In the second example, a selection was designed to test whether modern spliceosomal RNA ll2/1J6 could be used to resurrect RNA-based spliecosomal activity. Each of the four ribozyme classes found performs some kind of cleavage reaction, followed by a ligation; however, none of the selected molecules produces an activity that is similar to that of the spliceosome [29’]. Interestingly, the templates generated by the ribozymes uncovered a previously unknown activity for reverse transcriptase. nontemplated jumps in sequence. Adding functional group diversity - ‘If I only had a histidine’ A number of laboratories have recently worked to expand the chemical di\.ersity of RtiA and 1)NA. either through covalent modification or through the addition of cofactors and ions to the selection mixture. Examples of the first category include ribo/.ymes that catalyze carbon-carbon bond formation though 3 IXels-Alder reaction (.iO]. a5 well as the previously mentioned smi,ie-bond-forming rihJ~);lll~S [Z.3] that contain 5-pyridy~meth~lclirhox3mid uridinc and ii-imidazole uridine, respcctivcly. Kxamplcs of the second case include the routine addition of low (micromolar to millimolar) concentrations of’ divalcnt cations, including hip:+‘, (:a+‘. %n+?, Rin+L. ( :u*l and eI’en l’b”, or cofactors, \uch as histidinc 1.31‘I. ‘I’hc itnportancc of these prosthetics can bc xc11 in that their omission abrogates ftlnction.
DNA catalysts Although DNA tion storage. it
plays a centrdl role in biological informaa functionail>impoverished bi(Jplylller comparc~ with cithcr proteins or RNA. Despite its limitations, the list of DNA catalysts has grown significantly in the past few years (see ‘Iliblc 1 in [32]; [U]). It is not surprising that many of the DLL4 catalysts isolated require ;I cofactor of some kind. It is surprising that the highest catalytic cfficietq, 10” IL-~*s-’ (although not the highesr k,;,,), is held by the 10-33 RNA-cleaving DKA enzyme [.34,35j. ‘Ii) date, the scope of I>KA-based catalysts has significant di\,ersity. including ligation ( .VI]. RNA phosphoester cleavage [.3-!,.37-391, DNA clea\,age (40j. porphyrin metalation [1X], peroxidase acti\,ity [41’], fl~~orophorc oxidation [3.2] and 5’-IIN, phosphor)ilation [4.3*]. It is interesting to note that C;-quartets seem to play a ccntral role in the folded structure of many DNA catalysts, ;IS \vell as of DNA aptamers. is
Engineering allosteric enzymes and templates One potentially powerful application of nucleic acid aptamers and catalysts is the engineering of allostericall) controlled enzymes and templates. Breaker and co-workcrs [-M.lrS*] have shown that, through combinatorial enainecring, chimaeras between either the A’I’I’ or I:hlN aptamer with the hammcrhcad ribozyme may be allostcricaily regulated to function onI> when they bind their
In vitro
selection
of nucleic
acids
and proteins
Roberts
and Ja
523
Table 1 Peptides Initial
evolved
pool*
MVSKGEEX,,DAQAPKA
Pool:
X&X&X, x,cx,cx, X&X&X, x,cx,cxs x,cx,cx, x,cxgcx,
from
randomized
sequences. Diversity+ 2x10’3
5 x 10s
Target c-myc
(each)
References
Result
mAb
Epitope X(Q/E)XLISEXX(L/M) Mimic
VEGF
3.5 x 1 Og (total)
(a) [69-l
(i) RGWVEICVADDNGMCVTEAQ (ii) GWDECDVARMWEWECFAGV
x4cx,ocx4
X,CX,GPX,CX,
X, ,GGGS
SRX,
,SR
SADGAX,,GAAGA
ADGAXsGAAG
X 10
5x10s
VEGF
1.9 x 109
1 xl09
Paclitaxel
Tropomn
2.5 x 108
C
CTLA4
4x107
CSF
2 x 1 Og (phage)
Mimic GERWCFDGPLTWVCGEES
[69-l
Epitope HTPH
11071 P
Epitope (VIL)(DIE)XLKXXLXXLA
mAb
IgG
Ii peptide
[751
Unknown (i) GFVCSGIFAVGVGRC (ii) APGVRLGCAVLGRYC
11081
Epitope RRPFFX
I1091
Epitope WFSWGFPCIWW
I1101
LEX,TS
2.8 x 10s
(clones)
PAI-
Unknown GCIFWHLTSMSGSYFLEPFDLIST SQQRNIPLEIRDADT
11111
LEX , ,TS
1.4 x 1 O7 (clones)
PAI-
Mimic PVSQFVFLCGHQPCFTSEHAHDVP DPAPPHHPLELITGRCIATPISVGMS
11111
*Flanking sequences shown where reported. ?Where further differ, values given refer to only the initial round of selection. represent diversity, except where Indicated (clones = number transformants; phage = number of input phage). Sequences type represent ammo acids encoded by DNA sequences
respective small molccr~le. Wcrstuck demonstrated that allosteric mRN.4 erated by inserting 3 drug-binding S’-untranslated region (S’-IU‘R) of tion allow both it/ s&u and it/ repressed in the presence of a small
rounds Values of in bold
and (;recn [Ih’] have templates may be genaptamer into the an mRN.4. ‘I‘his inserGsv translation to bc molecule.
The thirst for structural information I,ogic:~lly, structural analysis providch ;I clear path to understanding the mechanisms of recognition jnd catalysis pcrformcd by functional nucleic acids. Indeed. Jacks [-I71 argued that, for protein enqmcs, the most striking generalization WLS that many of the expectations bawd on chemical studies were simple cwnfirmrd once crvstal strllcturns were in hand. In rhis l.cin, the striicnirc of alptamers in S(JlLltiOn solved using NhIR spectroscopy has generally pro\idcd significant insight inro the recognition process, indic:lting the presence of compact binding pockets for slnall inolcclilcs (for rwiws, set [-C--SO]). Analysis of
corresponding RW Roberts, observations. co-stimulatory MHC class
to restrictlon sites. (a) P Burgstaller, S Hale, M Wright, R Liu, JW Szostak, RW Wagner, unpublished CSF, cerebrospinal fluid; CTLA4, anti-T lymphocyte molecule; Ii, Invariant chain peptide from cytosollc tail of II; PAI-1, plasminogen activator Inhibitor 1.
three pockets (present in A’l‘l’, FRIN and @nine aptamers) indicates that binding appears to provide somehvhat less of a tight fit than protein sites and relies heavily on stacking, 3s opposed to hydrogen bonding [SO]. ‘l’he path has been somewhat bumpier when examining nucleic acid catalysts. ‘I’he central difficulty is crystallizing either RNA or DNA enzymes in their active form. In the crystal structure of the 10-23 DNAqme, the molecule has rearranged to form a dimer that is not likely to be the active conformation [Sl’]. ‘I’he sn-ucturc of the lead-dependent rihozyme crystallizes in two forms. one of uhich is ‘precat3tytic’ and rationalizes the cleavage chemistry (S?]. IXfficulties are seen in structural analyses of natural ribozvmcs as well. hluch has been made of the conundrum tlut the hammerhead ribozyme structures do not rationalize the cleavage chcmistr?; [S.i,%]. whereas larger RN.4 catalysts. such as the group I intron catalytic core [SS] and the hepatitis delta virus rihozyne (after cleavage) I.561,
524
Engineering
Table
2
Proteins
and design
displayed
Protein
on phage. Clones*
modlfled
Heregulin (nine mutagenized Knottins
1 .O-6.4
sections separately)
(CBD)
Llpocalln bindlng
(16 residues site)
in
hGH (site 2: four sectlons mutagenlzed separately)
*Values
represent
the
ErbE3
x 1 O*
receptor
References
>50-fold
higher
afflnlty
Cellulose tr-Amylase Alkaline phosphatase [&Glucuronldase
Epitope Unsuccessful K,=lOpM Unsuccessful
3.7 x 10s
FluoresceIn
K, = 35.2
nM
(>102-told
hGH
K, = 0.16
nM
(38.fold
higher
afflnlty)
domaln;
hGH,
human
growth
x 107
of transformants
in the first
round.
receptor
CBD.
C-terminal
cellulose-bIndIng
therein).
[87”]
H>- comparison.
the
hxttisc
the
imcnt that
cm
IX
ribosome Ability
and proteins
Selections ‘i‘hc tnosT
using
prorcitls
and
Tc’iii
dcvelopcd
!n
:ttf‘init!,
toh,
2nd
c;iI
panning
of ~tly~ro~itmttcl~
iising
;I \3ri:iriori
infi-ctive
phtig:c
wlccrioti int’cctt\,it!, libr-;ir)-
of or
‘S11”
iii
\\ ith
:I tot31
Iligh
in
binding I I I f(tsions
libr:tr\
rccovcred
dtthbcd
(rc\ic\+cd
to
\I hcreb\
uliarion.
h:ts also. t)ccn
1,
0.0001 ‘,C IX cl cn selccli\c-
ISX],.
111
i\ rcclttired containinK
constraints
iniposcd
translated
prowins
ril)osontc
iticrcasing ribosomc
one
IIillion
the
lihrar\ prouzina
six
has
to otticr
mainI\ In addirion, ph;tx:c pwt2rftil techniqites.
4s
t-ccoliil)inacioii
in tuctcria.
;ttld
nlolcculcs.
(WC
~tscd
for
been
the
i~/c.it/~~
limircd
frOmi
prescricc \vhich
*I
31ltl
the
or 101.i pcplidc4 rc\
prowin\
ic\vS).
‘4
hid
G;I c’ompruiicn-
IW].
cl
i-cfcrcncc,
In this
itscd cl.oltition
scl~~\~s
cull.
In ribosotn~
remain
of Ioueritig
display.
complexed
the
with
tcnipwttttre
and
[O.i]. Selections dctnonstratcd the
(single-chain
is Ihat
approach. .Afwt-
pcptid)l u ith the
lnatel\
host
mKN4
trrtn\lation or other
\ 3riat)lc
libr;iricS
fb~‘].
libraries
mitsr
ttsing aKinit\’
dotnain (hlc
frq-
Of
~illlir~i~iOi~
he screened
in rhe
rhc entireI~i~JiJSOtllc iindcicondition:, in tcr-itar\ mKN~i-ril,osolne-pepri~i~l-tliN ~1 is stahlc ;liigh hlgJ+ arid 1014~ remperatttre). A nicthod for producing co~.alcntl\ linked fitsion~ ha hccn rcccntl\ introdrtc.cd
.i’-puromycin.
abottr
cell-free in I itro :t11\ wnsfortn;lCon
of
(4,5”].
cliie C(J the trarisfcction liinit disl>la\, is nc,r easily poj-tzl>lc includln~ i/l E+//.o rnttt3gcI1C. I.SY.f~O”*.f,l
nietfiods,
pro\.idc
the
coii~l~lcx IlO\
by chc and
iilliiiilnized
displa);
fortltc
selection
to onl!
01‘
tiieil~s)
\.arietv
and
expcr-
transl:ttcd fOr
is littkccl
the hl$’ concetitracion displa), rcccntl! ha\,c
rlii\
target.
rccentl~~.
pcpridcs
10”
[~?,h]
reporred
34 3 resttlt
in;itiir:lfioti
linkage I ltitil
infortn;triott
:\II of these stratcgics ttTili/c \) siccms. therch\, a\ aiding
tilKNA-protcitl
New methods of
than
the
of tiiolccttle:,
fusions.
(XX
sclccin
is impotunt
dc\~ulolxx1
kcepin::
IJ!
inKk/j
approach.
ril~osornc
niulriplict-
01‘ pliage
displ:t!.
rcccp-
In ;i typlihr;tr\ is
the
i ii
O\vIl
acid sreps
combinatorial
rccentl)
of more’
rcspccti\,cly.
hormone.
tlutnlwr
niK\/\-prowin
lil)rarics
11121
nttclcic
ofa
to the
‘I’\~-0
and
ICI dlcir
the
bacteria
hctuccti 0.01 % :ind ‘I‘his pcrcctltag:’ can
proccdttre. ligaticlLtar,p3 itsing hipartatc g:enc ~iid
uittt
mcml)crs.
ph;ig:c
or
selccrcd 01
IrottnJ~.
fr:tctiott
lo\\ (rvl~ic:tll~ popiilation).
\‘cI-\
31~
mixctl
(>lOOO).
tltc
(- l-7700 1’111
substraws
ticrlcc
IO-10”
Ixxaiisc
iripttt
lower
scq
\)s-
in the K tcrniiiitis hactcriophagc
\trh\ccl”cnr
phagc
inany
i\ csscntial,
~cncr;ill\ of the
f‘or
prorcins.
with
b38’1
;irc
gciic
hlolcc~tles arc
phagc
t5CIl
I,\
I0
imnrot~ili~cd
pliaqc
cXpcrinierir.
\i7c
I>
rcsitltirifi
pro~ctl)
represented r\
on
display
formar
fiirtons
[7..57’]).
of
Scqitencrs
tntilticopv
sw
selection
phqc
(O-S col~ies/pha,gc) sitrf2cc of filametitotts
rebic\v.
tlic
prmliicc
it/ Ct/u
Snlich.
Y-terminal
‘single’ copy fortii;rt 01‘ ;gctic II I on the 3 rccwlt
the rhc
(;corgc
in
cithct 3s
ccJl~ics/phafic)
for
screened.
ro scrccii
linked
is currently IJ!
cxprcsscd
(for
display
techniclttc
common
pcptides
or
phage
proportional
display
affinity)
bccausc all the ‘l’his diftbrencc
pwvcr
~Otll~ltl~~~~Oll~i~
is dirccrly
higher
litnit
tions is 1 ()t5-1()t(~ seqttrnccs, process arc pcrformcd ;?I s.itm.
Peptides
[ 104”]
5.5 r 108
1.3-7.3
number
Result
Target(s)
transfuasr protein allous
that
a mKNA
Cr3ns13tion.
2
selccrions
ttr bc Kccenrl!.
arid
scrccii
x 1 ()I.“ diffcrcnr to the anti-c-tn\ic,
mcnT tltcror5 (1’ Hurgstallcr. .I\L’ S/.oartik,
is tagged
puromycirl
site and bccotnes it encwdcs. ‘l’his
of conditions. to generate
librq rlic
of more S Hale, 1<\2~ \Vagrtcr,
co\~alently chctnically
pcrformcd rhic
3 lihrar\ peptidcs antihod!-
rh:rn 700 hl \Vright. ttnl>ttt)lishcd
lvith
enters
linked rohttsr
i~t~clct-
techniqrtc conraininx for YElO.
:t the
;I
has
wide
IXCII
approxiIjinding and wirh enriclt-
per rotlticl (‘li~hle 1) RM’ Roberts. K I,itt, ot,aer\,ations).
In vitro
Se~cral other technical ad\,ances arc also expected to techniques, cnhancc the power of ill r:ifro selection including improved in tvtro recombination and mutagrnsis. and interaction mapping by XMK spectroscopy. New methods for in vitrn recombination may bc technically simpler and/or more eff*ecti\,e than the original IINA shuffling technique devised by Stemmer [hS]. Among these is family shuffling [60”], whereby di\,crsity is created b> recombining two or more homologous gents. ‘I’his has the ad\,antage of creating di\.ersity that ha\ alrcady been prescrecned 1,~ nature to weed out mutatil)nb thar are deleterious to :I particular fold. generating libraric\ that are much richer in functional proteins. Alternatives to the original I)Yase-I-based shuffling pietow1 ha\,e also been dc\,tzlopcJ. including random priminK recombination (KI’K) [M] and the staggered extension process (61’1. Kandom clon,gation rnirtagcnesis (Kk:kl). the addition of a partially randomized sequence to the (: terminus of’ the protein. i\ rrnlikel\~ to change catal) tic propcrtics. hiit 111;1\ bc ;I siinplc apl)roac‘h for enhancing enzyme \tabitit! (073. III an increasing nurnbcr 01‘ casts, thcb conforn~ation~ 01 sclcctcd n~01cc11Ies (peptidc\ and pmtcins) bound to thcirtarget4 h;I\.c’ been sol\Tcd 1~) crystallographic (see discussion below). NhlK spcctrowlp~ has pro\ed to bc increasingly uaefui ti)r char-actchri/.ing l)oth dynamical sy+ tcnis and those that arc rccalcirrant to cr\srallization. ‘li\o rqJrcscntati\ c examples arc given. ‘I’hc Schultz and \Ycmmcr laboratories [6X’] ha\c rcccntl\ iised transt‘crrcti NOI< (nuclear O\whauscr cnhancsmcnt) cxpct-inicrits t(~ dctcr-niirrc the qzonrctr\~ of‘ t\I 0 \rrbstratca in tlic ;rcri\c site ofarr a(,\.1 tr-snsferasc antiljod!. I~;rirlJrothcr- /I/ N/. [OO**/ irscd t\\.o-~iiiiiciisioii;iI I I I-l’K I I.S(>C 1 (hctcronrrcIc3r billfilC (1uantirm cohcr-crrc,e) cxlwr-inicnt5 to dcl‘inc the interactiori bct\vccn bclectcd 1Jcptidc.s 2nd tlic rl l,ri%labclcd target VE(;IC I’cptidc intct-action5 with \~l
selection
of nucleic
acids
and proteins
Roberts
and Ja
525
.An increasing number of laboratories have reported peptides or small protein tigands that can functionally mimic the three-dimensional surface that is normally bound by a full-sized protein. ‘I’hese examples are particularly interesting because they emphasize both the plasticity of protein surf&es and the range of structures (both in size and topology) that can functionally substitute for one another. ‘I’he functional substitution of small peptides for much larger proteins runs counter to the notion that protein interactions arc driven in proportion to the burial of h!rdrophobic surf&e (see [7h] and references therein). One of the most compellink cr e.uamples of this mimicry arc the erythropoetin mimetic peptides (ti;2ll’). short (-13-20 residues) p hairpins that functionally mimic erythropoetin, a .M kl)a glycoprotein. but bear no sequence homology 177.7X.79’]. Similarly, prptides or minimized proteins have bc*en found that mimic the function of thrornbopoetin IXO], an antagonk VkL(;I; lhY”.70’], or bind to constant tcgions in antibody structures (XI 1. ‘l‘lrc peptides isolated by both types of selection generatI! bind to the same regions utilized by the natural counterparts they arc meant to mimic. I’or linear epitopes, this is perhap” not surprising. I’Or’ the peptide mimics. it borders on scandalous, as, often. most of the target protein surface i\ available for interaction during the aelcction. ‘l’trc clear implication is that sonic regions of protcin srrri’ac~~ arc more ‘stickv’ than others and, thus. act as hot spots for interaction iX.!I. Antibody selection: the importance of large libraries Although complete co~eragc ofpha~c antibody selection is tjcvond the scope of this war-h. a recent re\.ic\r highlights the importance of high-colnlllc~it~ starting librdrics [.57’]. \z’lrci~ lo\\~-con~~~lcsit~ libraric~ containing 3 x 10’ clones \\crc rised. single-chain antibodies with affinitic\ ranging from 10 to 0.1 X 10~” pZl IX.%.XAJ \\cre isolated. With lrbi-arics containing 10”’ clonc~, affinities of 10 to O..‘, nhl \+‘cr’c tijund (X.51. ‘I’hc commensurate increase in binding constant with increased library \i/c is in line with thcorctical pi-edictions dc\,clopcd to cstirnatc the binding ~onst;~nts from IitJrar~~ complcxit~~ (XOI. Alternative scaffolds II‘ Iqtidcs can bc found that mimic proteins. one might ekpcct that snia11. strrrctured pcptidcs could be used as scaffold\ to display function. Kather than choose ;I single motif’. I~‘airbrothcr otcr/. [W”] used 3 variety of small, disulfi~lc-coiitaininC pcptide\ to isolate binders to \‘K(;f; c’I~IIJIc I). Similarly, knottiw. small, disulfide-rich proteins h.r\,c been irsctl to generatr librark that recognize alkalint phosphatasc, a ~H’Oteill Lrith no wild-type knoctin binding 1X7”]. j’r.otcin scaffolds that cordd IX imbued with antibody di\.crsit\: h:r\,e also been sought. particularly beca~~se ofrhe rcfractorq natrtrc of some scl*‘\~. Skcrrd and co-workers (HX’I ha\ c rcccntlv reported that lipocalin HI3I’ variants
526
Engineering
and design
(a 174 amino acid p barrel) could be isolated that bound fluorescein with a dissociation constant (K,) of 35 nlvl. Direct selections
for catalysis
There is great interest in using selection both to refine known catalysts and to isolate new ones. TSAs have been used to isolate a great diversity of antibody catalysts via ill v&o immune selection (151. In a few cases,irt vitro selection has been used for affinity maturation of the catalysts using ‘1‘SAs [89,90’,91,923 or via a mechanism-based approach (discussed below). The potential limitations of the ‘TSA approach are highlighted by work from the Wells’ laboratory. Baca rt ul. [89] used affinity panning of an esterolytic antibody library derived from immune selection to isolate variants with two- to eightfold improvements in their binding affinity for a phosphonate ‘EGA. Notably, a correlation between binding afftnity and catalytic ability was not observed. A weaker binding variant was identified with twofold greater catalytic activity than the parent antibody, emphasizing the need for an approach that selectsfor catalytic activity [WY]. In the direct strategy. enzymatic activity is required to either covalently attach or releasethe library membersduring selection. This approach hasbeen successfully applied to isolate RNA and DNA catalysts that are capable of performing chemistry with rates ranging from 0.1 to more than 100 min-1. significantly faster than many catalytic antihodies [33]. Lerner and co-workers [93,94] ha1.eapplied this strategv to immune selection with great success.In one interesting combination of reacti\,e and ‘I‘SA approaches, phage display was used to improve catalytic antibodics designed to cleave a glycosidic bond by 700-fold (k,,,/k,,,,,, = 7 x l(P versus 102 from immune selection) [OSj. Substrate-bond cleavage generated a quinone methide that reacted with rhe phage to afford immobilization and selection. Reactive approaches can also be incorporated in phage selections to afford specific release. The Schultz laboratory [96’] has recently demonstrated that phage harboring active staphylococcal nuclease can be enriched IOO-fold in a single round, based on cleavage of an oligonucleotide tether in C/S.A similar strategy involving immobilization demonstrated enrichments of more than SO-fold for two model proteins using phage-displayed enzymes and the calciunl-depelident binding of substrate to calmodulin [97]. Structural proteins
studies
of selected
and evolved
peptides
and
‘I’here are now a significant number of selected prptides and proteins whose structures arc known. \Ve include catalytic antibodies and i/f d/a screened proteins in this discussionbecausethe structural conclusions seem gcnerally applicable to all functional approaches. One \‘crv striking feature is the way in which protein structure can be modulated by seemingly subtle changes in sequence.
In general, proteins that have been evolved either in viva or in vitro contain positive mutations that are distal to the active site ([98-l 001;B Spiller, A Gershenson, FH Arnold, RC Stevens, personal communication). These mutations often have the effect of remodeling the shapeof the active site and may act by biasing the conformation towards lockand-key-type recognition [99,101]. In addition, the selected mutations often make significant changes to the local structure (B Spiller, A Gershenson, FH Arnold, RC Stevens, personal communication) and can even alter topology [1OZ”]. As interesting as where mutations are is where they are not-the active site or critical residueson the interface of the proteins. For example, residues conserved in phage selections of heregulin variants (binding to the ErbB3 receptor) correlate strongly with positions that were found to be important using alanine-scanning mutagenesis [103’,104”]. Selection and evolution thus seem to avoid changing residuesthat are in direct contact with the target. Rather, beneficial mutations enhance affinity by reconfiguring essential binding residues or by forming new contacts. Indeed, these complicating secondary effects prohibit the delineation of a recognition code, even for highly modular protein contacts, such aszinc-finger-DNA interactions [lOS**]. The importance of long-range interactions and plastic local structure are likely reasons why rational design has yet to produce the results seen with functional approaches, such as in vitlz, selection [lob]. Computational approachesmay significantly enhance pool design. however, allowing us to ‘stack the deck’ of initial libraries, making selections more fruitful or reducing the number of cycles required.
Conclusions IN eli~o selection has proved itself to be a powerful technique. For the foreseeable future, functional approaches provide the most facile path for engineering nucleic acids and proteins alike. The new methods developed will allow larger, better libraries to bc generated and more powerful \vays to screen them to be elaborated - further expanding our ability to generate interesting molecules for studv. A fundamental question is how the information from selection experiments can be used to further insight into biopolymer folding and function. l;or the present, the results of selection and screening cxperimcnts provide existence proofs and hard data on some very interesting questions, including the number of nucleotides needed to specify a catalyst, the number of amino acid changesneeded to improve protein thermostability and the free energy consequences(or lack thereof!) of introducing or removing a small functional group (e.g. a methyl group) from either the macromolecule or its target. Future experiments are likely to addressissuessuch asthe generation of new function. the minimum size of protein needed to perform catalysis and the likelihood that such a protein could be found in random sequence libraries.
In vitro
Acknowledgements 1%‘~ thank Frances H Arnold and rhcir manu&pt prior IO publication.
References
Kdymond
Stcvcns
and recommended
Papers of particular have been highlighted
interest, as:
published
for providing
a copy
the annual
period
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23.
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