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Undrstanding ho th prcis intrcon-nctions of nurons account for brainfunctions has bn a proccupation of nuroscintists for or a cntury. Toaccompish this aim, nuroscintists ind arious typs of data. First, i nd a physica map of th nuronsthat compris a circuit and th sits at
hich thy form synapss ith ach othr.Scond, i nd to undrstand hoctrica signas fo through th circuithn a stimuus is prcid, a dcisionis mad or an action is takn. Third, if thcircuitry undrgos modifications, ind information on ho circuits and thirsignas chang or tim. Finay, and argu-aby most dmanding, i nd aysto transform th ra data into usfu formsso that can xtract maning from thphysica maps. Nuroscintists ar hard atork doping th toos that ar nddto accompish ach of ths; hr discuss
sra tchnoogica adancs that mightproid soutions to th first probm:obtaining a compt physica map of thnrous systm.
Circuit-mapping strategies
Or th past cntury, nuroscintistsha usd thr main sts of anatomicaapproachs to study nura connctiity:sing-c imprgnation, opticay basdtract-tracing and ctron microscopy (FIG. 1). In this sction, brify discussths mthods and thir imitations.
Single-cell staining by dye impregnation. This as th first and most infuntiaapproach. Sing-c imprgnation is rootdin th xtraordinary ork of SantiagoRamón y Caa (1852–1934), ho usdGogi’s ‘back raction’ — a sir-stainingtchniqu that abs nurons ith a dark prcipitat. This mthod stains th ntirty
of ust a f indiidua nr cs anda thir procsss (axons and dndrits),thrby making idnt shaps that oudothris b indiscrnib in th dnsmshork of th nuropi1. Using th Gogistain, Caa as ab to not ony idntify many diffrnt nurona typs in th brain,but aso dscrib thir pattrn of intrcon-nctions and discor princips of nuronacircuit organization (FIG. 1a).
Dspit thir por, th Gogi mthodand othr sing-c abing tchniqus— for xamp, intracuar inction of dys— ha significant imitations. First, bcaus
th chmicas ith hich th nurons arimprgnatd must b appid to ratiy sma bocks of tissu, thy cannot b usdto trac ong-distanc connctions. Scond,bcaus of diffraction, nurona procsssthat com cosr to ach othr than approxi-maty 0.25 µm ar not rsoab in th ightmicroscop. It is thrfor difficut to tracsndr axons and dndrits ithout thrbing any ambiguitis. Third, if a or nmany of th mnts in a circuit ar staind,thy bcom impossib to distinguish fromon anothr. Thrfor, circuit dscriptions
ar amost aays basd on a statisticaanaysis of sma amounts of data from mu-tip indiiduas, rathr than on fu anayssof any actua circuit. Indd, ths probmsar so sr that, ith th xcption of Caa, f scintists ha bn ab to dragnra concusions from such matria thatha stood th tst of tim2.
Diffusion or transport of labelling agents
placed at discrete positions. Th probmof isuaizing ong-distanc connctiity can b addrssd, at ast in part, by circuit-
tracing tchniqus, hich ino markingtracts that proct from on brain rgionto anothr. Tracts ar gnray abd by mchanicay introducing a spcific abingagnt — for instanc, through a surgica pro-cdur. Th first tract-tracing mthods to bappid, hor, took adantag of th factthat axons dgnrat fooing inury anda bhind dbris that prsists for days toks bfor it is card. This dbris coudb staind ith sir sats. Thus, fooingoca damag to a nurona popuation ortract, th sir stain markd sits to hich
nurons had proctd3
.By th 1970s, dgnration mthods hadargy bn rpacd by a suit of tchniqusin hich abs r pacd into circum-scribd rgions of th cntra or priphranrous systms and thn diffusd or actiy transportd aong axons to othr sits(FIG. 1b). A id rang of abs prod usfufor this appication: radioacti amino acidsor sugars, protins such as th chora toxin Bsubunit, nzyms such as horsradish proxi-das, and fuorscnt organic mocus suchas DiI, DiO and Fuorogod4. Most rcnty,gnticay ncodd tracrs, incuding
fuorscnt protins (s bo), ha bnxprssd undr th contro of subtyp- orrgion-spcific rguatory mnts or from
ira ctors5–9. Ths mthods ha sraadantags or mthods that us chmicaabs, incuding th possibiity of indibmarking and, for th transgnic approachs,aoidanc of th nd for surgry. An addi-tiona xciting dopmnt is th abiity tointroduc gnticay ncodd trans-synaptictracrs that can cross from a nuron to itssynaptic partnrs8–12, thus raing (ithsom caats; s reF. 9) connctiity.
A technicolour approachto the connectome
Jeff W. Lichtman, Jean Livet and Joshua R. Sanes
Abtact | A cntal aim f nucinc i t map nual cicuit, in d t lan
hw thy accunt f mntal activiti and bhaviu and hw altatin in thm
lad t nulical and pychiatic did. Hwv, th mthd that a
cuntly availabl f viualizin cicuit hav v limitatin that mak it
xtmly difficult t xtact pci wiin diaam fm hitlical ima.H w viw cnt advanc in thi aa, aln with m f th pptuniti
that th advanc pnt and th btacl that main.
NATURe RevIewS | neuroscience vOlUMe 9 | jUNe 2008 | 417
Progress
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a b c
Dspit th ncouraging progrss thatthr has bn aong ths ins, difficutisrmain. First, tracing from a st of somatato a trmina fid, or ic rsa, i in most
cass a oca intrnurons unabd orimpossib to rso. Scond, bcaus thsmthods typicay ab groups of nuronsrathr than indiidua cs, tract-tracingmthods can sdom b usd to trac thhighy compx branching pattrns of ththousands of intrdigitatd axons anddndrits in ach cubic µm of brain.
Electron microscopy. Sria sction ctronmicroscopy has bn th mthod of choicfor orcoming th imitd rsoutionof ight microscopy and th insufficincis of tract-tracing. In pionring ork, lintha,
loprsti and Macagno usd this mthod tomap connctions in th optic ob of th smacrustacan Daphnia13, and whit et al. usdit to proid a nary compt map of con-nctiity in th roundorm, Caenorhabditis elegans14. Sria ctron microscopy is soaborious, hor, that its appication hasbn infrqunt. Fortunaty, this situation isno changing thanks to rcnt dopmntsin th automation of ctron microscopy 15–17.On promising approach is to imag th thinsurfac ayr (tns of nanomtrs) of a bock of pastic-mbddd and hay-mta-staind
brain tissu by ooking at backscattrd c-trons ith a scanning ctron microscop15.Aftr taking th imag, th top sction of thbock is rmod ith a diamond knif and
th bock fac is rimagd. This procdurcan no b itratd thousands of timsto gi prfcty aignd stacks of digitactron micrographs from hich nuronaprocsss can b tracd (FIG. 1c). Othrapproachs us n microtom dsignsinoing a rotary ath and a tap transportsystm to automat th cutting and coc-tion of sria thin sctions. Aong ith nmthods in computationa sgmntationthat impro tracing and thr-dimnsionarconstruction (s bo), ths innoationsar iky to rstor ctron microscopy toa position of prominnc in circuit anaysis.
Nonthss, arg-sca rconstruction,spciay or ong distancs, rmains a dis-tant hop. For xamp, rconstructing pathsfrom th rtina to th thaamus or fromth thaamus to th cortx oud rquirhundrds of thousands or n miions of sctions to b acquird and anaysd, andn thn thr oud b no obious ay to
rify th accuracy of th tracing.
The multicolour solution
Introducing a markr into th rconstructdnuron aos its idntity to b rifid in
ach sction. Hor, th nd for sparsabing hn using monochromatic absrmaind an intractab imitation untircnty. Th obious soution is to us
mutip, distinct abs so that narby pro-csss can b distinguishd from ach othr.This approach is xmpifid by th us of ‘rainbo’ cabs in ctronic dics: th
arious coours of th irs hp pop kptrack of thm. Sra mthods dsigndaong this princip ha bn appid toth task of nurona circuit isuaization.On, cad Dioistics, inos shootingtissus ith bioistic mta bads that habn coatd ith arious combinationsof diffrnt coourd ipophiic dys, suchas DiI, DiO, and DiD, ith th rsut thatimprgnatd cs ar abd ith diffrnt
coours18. Hor, Dioistic abing is bstdon ex vivo on sics, so it is poory suitdfor ong-rang rconstruction.
Anothr approach is basd on th grnfuorscnt protin (GFP) roution19,hich has d to a tchnica rnaissanc inimaging. Or th past sra yars, doznsof spctra and photophysica fuorscntprotin ariants (XFPs) ha bn disco-rd or nginrd20, and many of ths habn introducd as intrinsic nurona absin transgnic mic. In som of th micthat produc ths XFPs, th xprssion is
Fiu 1 | ct-mappgtatg. exampl f th th mainappach that hav bn ud t tudy th cnnctivity f nun.
a | sinl-cll tainin by dy impnatin. Th bt-knwn f th tch-
niqu i th gli tainin mthd, which wa ud by ramón y Cajal t
dcib th pincipl f nunal cicuit anizatin39.b | Th intductin
f diffuibl tanptabl labllin ant t dict aa. In m ca
th labl c a ynap t ach a cnd-d tat. A claical xam-
pl i th idntificatin f cula dminanc clumn in th viual ctx
fllwin th injctin f adiactiv plin int n y40. | sial lctnmiccpy can b ud t cntuct nun and thi pc with th
bt attainabl lutin. shwn h i a cntuctin fm th adult at
bal ctx that wa mntd fm a th-dimninal ima tack
btaind by ial blck-fac imain16. Pata pducd, with pmiin,
fm reF. 39 (1914) Hd d santia ramón y Cajal. Pat b p-
ducd, with pmiin, fm reF. 40 (1977) ryal scity f Lndn.
Pat pducd, with pmiin, fm reF. 16 (2006) elvi scinc.
Progress
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d
ca
b
Yes No Yes
loxP loxP lox2272 lox2272
Construct Construct
Promoter Promoter
OutcomesOutcomes
Cre recombinaseTransientCre recombinaseactivity
RFP RFPOFP YFP GFP YFP
GFP YFP
YFP GFP
CFP CFP
RFP CFP
CFP
RFP YFP CFP
YFP CFP
CFP
OFP GFP
RFP
GFP
CFP
YFP
RFP
YFP
CFP
or
or
1
1 2 3
2
3
loxN loxPlox2272i
i
ii iii
iii
RFP
iv v
loxP loxP loxP loxP
confind to sma, quasi-random substs of cs, crating th quiant of a ita Gogistain21. By crossing to such ins of micxprssing spctray distinct XFPs, on canobtain ‘bicoour’ or n ‘tricoour’ animasin hich th intractions btn to nu-rons can b isuaizd21–24. Anothr mthod
for xprssing to XFPs in a mosaic man-nr is th ingnious mosaic anaysis ithdoub markrs (MADM) stratgy 25. In thismthod, th XFP gns ar artificiay spitby a synthtic intron that contains a loxP sit(Box 1). Rciprocay chimric gns madby pairing th xons that ncod th to
XFPs ar insrtd at idntica positions ina pair of homoogous chromosoms. Thsmnts rmain non-functiona unti Cre rcombinas (Box 1) triggrs intrchromo-soma rcombination to rconstitut actiXFP-ncoding gns. Subsqunt mitosssgrgat th as such that diffrnt cs
inhrit diffrnt products of rcombinationand thus xprss distinct coours.Dspit thir utiity, bi- and tricoour
mic ha far too f abs to disambiguaton nura procss from th thousandsof axons and dndrits that it i cosy approach as it courss through th nroussystm. Rcnty, dopd a combi-natoria coour mthod, cad Brainbo26,that addrsss this probm by markingindiidua nurons in on of >100 cooursrathr than on of 2–3 coours. Th mthodis basd on combinatoria and stochasticxprssion of mutip XFPs from a sing
transgn. In princip, combinatoriaxprssion of thr diffrnt XFPs coudcoour nurons in on of tn hus (FIG. 2).Hor, thr XFPs can produc a muchargr numbr of hus if thy ar xprssdin diffrnt amounts in diffrnt nurons.A good anaogy is a Tv monitor, hichcombins diffrnt intnsitis of thr chan-ns (rd, grn and bu) to gnrat amostth ntir coour spctrum that th human
isua systm can prci (FIG. 2b). Ourthought as to us such coour combina-tions to distinguish nurons in a circuit by
gnrating a random mixtur of thr fuo-rscnt protins in ach nuron. This sto-chastic coour xprssion as accompishdin to stps. First, dsignd gnticconstructs that coud b rcombind insra mutuay xcusi ays to gi any on of thr or four coours (s Box 1 for adtaid dscription of th mthod). Scond, insrtd mutip copis of th transgninto th gnom. Indpndnt xprssionfrom ach copy aos a rang of coours torsut from combinatoria xprssion of thXFPs (FIG. 2c). As a rsut, indiidua nuronsxprss on of many distinguishab hus
(~100), nabing th spctra diffrntiationof indiidua nurons and thir procsss(FIG. 3).
The role of Brainbow in connectomics
Brainbo transgns ha gnratd strikingimags and xcitd considrab intrst, butho can thy actuay b xpctd to con-tribut to th mapping of nurona circuits? Thir potntia is iustratd by our rcntxprinc ith prhaps th simpst con-nctom: th innration of skta muscsby motor axons. A f yars ago, bfor
Bx 1 | Brainbow strategies
Brainbow transgenes drive the combinatorial expression of several fluorescent proteins (XFPs) in
neurons, resulting in the colour-tagging of individual cells. Here we outline the methodology that
we used to generate these constructs.
The strategy makes use of the Cre/lox recombination system.Crerecombinase specifically
recognizes and catalyses recombination between a pair of 34-nucleotide sequences called loxP.
This reaction leads to the excision of a DNA segment that is flanked by two loxP sites of the
same orientation, and to the inversion of a DNA segment that is flanked by loxP sites of opposite
orientation (see figure, part ).
One strategy, Brainbow-1, makes use of mutant lox sites that can recombine among themselves
but which bear mutations that render them incompatible with the canonical loxP site7; see figure,
part a). Alternating canonical (wild-type) loxP sites with variant sites creates mutually exclusive
excision possibilities (see figure, part b). Implementation of this strategy with three loxvariants
creates four possible outcomes following excision by Crerecombinase: three different products ofrecombination plus the unrecombined initial state. In all cases, only the XFP directly following the
promoter is expressed. A second strategy, Brainbow-2, usesCre-recombinase-mediated DNA
inversion. The DNA segment can invert repeatedly while Crerecombinase is present but will
stabilize in a random orientation when Crerecombinase stops acting, offering two possibilities of
expression. Moreover, when two such invertible segments are arranged in tandem, the number
of possibilities is increased: additional inversion and excision possibilities create a total of four
expression possibilities (see figure, part d).
Both of these strategies are in essence stochastic: the Crerecombinase enzyme is given a choice
and the outcome is unpredictable. This rolling of the ‘molecular dice’ allows each cell to
independently make a random choice from several XFPs. In the transgenes, a choice is initially given
between several recombination possibilities, each leading to a distinct final configuration (that is,
the different sides of the molecular dice) corresponding to the expression of a particular gene.
For the generation of the first-generation Brainbow mice26, transgenes were placed under the
control of Thy1 genomic elements to obtain strong neuronal expression; these animals were
mated to other transgenic mice that expressed Cre recombinanse or a ligand-activated variant,
CreER. CFP, cyan flucnt ptin; gFP, n flucnt ptin; oFP, an flucnt
ptin; rFP, d flucnt ptin; YFP, yllw flucnt ptin. Figure modified, with
permission, from reF. 26 (2007) Macmillan Publishers Ltd.
Progress
NATURe RevIewS | neuroscience vOlUMe 9 | jUNe 2008 | 419
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Red Green Blue
RFP YFP CFP
2 3
RFP YFP CFPP RFP YFP CFPP RFP YFP CFPP
CFP
CFP Light blue
Cyan
Green
Yellow-green
Orange
Red
Magenta
Purple
Grey
CFP
YFP
YFP
YFP
RFP
RFP
RFP
RFP
CFP
CFP
YFP
YFP
YFP
RFP
RFP
RFP
CFP
CFP
CFP
YFP
YFP
YFP
RFP
RFP
RFP
CFP
CFP
YFP
Blue
Resulting colour
a
c
b
1
Brainbo ins r aaiab, bgan by
using a mous in in hich a motor axonsar abd th sam coour21 to ra thntir connctiona map in a sing musc.w orkd on a sing sma musc that asinnratd by ony 15 or so motor axons(j. lu, prsona communication). A com-pt map rquirs that a axons b abd,and this is on of th imitations of th no-xisting ‘first gnration’ Brainbo mic (fora dtaid discussion of ths imitations sbo). Our thought as that, ith ony 15axons innrating ~200 musc fibrs, sucha mapping oud not b difficut. w r
rong. In ordr to gt sufficint rsoution
to track a of th axons and at th sam timimag th ho innration fid, hadto assmb tns of thousands of high mag-nification confoca imags into hundrds of stacks and thn stitch th stacks togthr tognrat a montag of th ho musc. Usof a motorizd computr-automatd stagmad it possib to coct th imags, hichtogthr comprisd hundrds of gigabytsof data. Thn, using computr-assistd trac-ing, trackd th ntir branching tr of ach motor axon and its synaptic contacts(a motor unit) to rconstruct th ntir
‘connctom’ of th musc. This ntrprisrquird sra months of ork for achindiidua musc, highighting th sca of th tchnica hurds that oud ha to bsurmountd to accompish th sam task forany rgion of th CNS. By contrast, as ha bgun to rconstruct nuromuscuar
connctoms ith Brainbo ins, ha found that th ho procss can baccompishd in an ordr of magnitud sstim. Indd, in som cass it is possib toidntify th dstination of an axon ithouthaing to trac its path, as its uniqu coourrmains rcognizab aong its ngth.
Basd on ths initia ncouragingrsuts, ar hopfu that Brainbotchnoogy can aso b appid to modnrous systms ith imitd numbrs of axons in ordr to furthr dduc principsof nrous systm connctiity. Brainbotransgns ar arady bing usd for mu-
ticoour abing of th zbrafish snsory nrous systm (Y.A. Pan and A. Schir,prsona communication), and attmpts arundray to gnrat Brainbo Drosophila.
A much mor ambitious goa is to usBrainbo mthods in th mammaian CNS.Hr th changs incud th shr dnsity of th iring, th ry fin caibr of much ofth nuropi, th normous dirsity of nurona typs and th intrsting fact thatmany axons tra ry ong distancs toinnrat nurons throughout th brain.Ths obstacs mak it uniky that com-
pt connctoms of arg brain rgions ib obtainab in th nxt f yars. workingtoards that nd sms a auab goa, ho-r, and n partia connctoms — forxamp, of th rtina innr pxiform ayror of a cortica coumn — oud proidconsidrab insight into th dsignprincips of th brain.
Moror, such partia connctomsmight b usfu in studying mous mods of psychiatric disordrs. Thr is a groing sus-picion that dfcts in th pattrn, numbr orproportions of connctions might undribhaioura disordrs ith a dopmnta
componnt, such as schizophrnia andautism. Th primary causs of such disor-drs might incud arious gntic ariantsor nironmnta insuts that might affct
arious mocuar cascads or dopmn-ta nts, but th fina common pathay coud b a quantitati or quaitati dfctin circuitry. That is, som disordrs of thissort might b ‘connctopathis’. BcausBrainbo abing faciitats th suryingof quantitati and quaitati aspcts of circuitry in dirs brain rgions, it mightnab this hypothsis to b tstd.
Fiu 2 |cmbatalxpfthdttfltptagatalag
ptmfl.a | sval pctally ditinct flucnt ptin (XFP) a nw availabl,
includin n that mit in d (rFP), n (YFP) and blu (CFP) fqunci. b | Th cmbinatial
xpin f d, n and blu XFP at vaiu lvl i ufficint t ncd a clu pac anal-
u t th n that i natd by an rgB vid mnit. | An xampl hwin hw tn ditinct
clu can b natd by xpin a timic cmbinatin f th diffnt XFP.In Bainbw
mic, thi utcm wuld ult if th cpi f a tichmatic tann (illutatd at th tp f
th panl; Box 1 f dtail) ach cmbind indpndntly (Box 1). Tianl pnt loxit
( Box 1 f dtail). CFP, cyan flucnt ptin; P, pmt; rFP, d flucnt ptin; YFP,
yllw flucnt ptin.
Progress
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a b c
It i aso b auab to us Brainbotransgns to arn ho connctionapattrns chang or th ifspan of ananima. For xamp, th nurobioogicaundrpinnings of hathy aging rmain amystry. Soing this mystry is not ony important in its on right, but might asob rquird if ar to undrstand thpathoogica atrations to hich th agingnrous systm is spciay unrab.likis, circuit modifications that undr-i th critica priod in ary postnata
if ar incompty undrstood, as arth compnsatory changs that mak thyoung nrous systm so rsiintfooing inury.
In studying ths issus, th microscopicanaysis that ha usd so far i b us-fu. Gratr insights might ntuay comfrom tim-aps imaging of circuit atra-tions as thy occur. XFPs mak ida absfor this purpos, and tim-aps mthodsha no bn appid to many parts of thpriphra and cntra nrous systms of on- and to-coour XFP mic27–30. Furthrimpromnts in spctra sparation, acqui-
sition rat and dtctor snsitiity shoudmak it possib to xpand th mthod toBrainbo mic.
So far, ha ony discussd con-nctions among th minority cuarpopuation of th brain: nurons. Brainbomthods can aso b usd to map connc-tions among th maority popuation, gia,or btn nurons and gia. Indd, somBrainbo ins arady ab som gia sub-sts, incuding astrocyts, Schann cs andBrgman gia; it shoud b straightforard tognrat othrs.
Finay, Brainbo can b usd to highightconnctions of anothr sort: th inag ra-tions among c popuations. If rcombina-tion is inducd in nura prognitors ith aigand-actiatd Cre rcombinas (for xam-p, Tamoxifn-dpndnt CreR) (Box 1), aoffspring of a particuar bast c shoud babd ith th sam coour. This approachmight ao th anaysis of th intractions of many cona sts of cs (ach ith thir oncoour) in th sam pic of tissu.
Technological challengesFor mor compx circuits, th diffraction-imitd rsoution of th ight microscopis a srious imitation. Fortunaty, srasoutions to this probm ar arady mrg-ing. On is to cut xtrmy thin sctions of abd tissu31,32. By cutting sctions thatar sra-fod thinnr than th opticasction thicknss, th suprimposition of mutip nurits in th sam foca thicknssis aoidd. In addition, th thin sampsscattr ight much ss, and this impros thcontrast and carity of th abd matria.
To mak such thin sctions, th nura
tissu must b mbddd in a hard rsin.This, in turn, rquirs th XFPs to rtainthir fuorscnc fooing th dhydra-tion and mbdding stps. To som xtntthis might b possib; hor, Brainbotransgns coud atrnatiy b rdsigndto incud pitop tags that oud b rc-ognizd by antibodis33. This oud aotraditiona staining mthods to b usd aftrth tissu has bn cut and oud thrforao th abing by th ndognous fuor-scnt protin to b augmntd or rpacd.Th smingy simp soution of using
antibodis to dtct th XFPs thmssis unfortunaty not yt fasib, bcaussra of th XFPs (for xamp, GFP, cyanfuorscnt protin and yo fuorscntprotin) diffr by ony a f amino acidsand ar, in ffct, antignicay idntica. If immunohistochmica dtction is usd, oncan aso ocaiz sits of synaptic contacts onor btn markd cs, using antibodis topr- or postsynaptic componnts. Mthodssuch as array tomography, in hich thinsctions of brain matria ar assayd ith
an assmbag of antibody probs, proid angant protoco for dtcting many antigns(or pitop tags) in sing thin sctions31.
A mor radica soution to th rsoutionprobm might b proidd by th n andrapidy groing fid of nanoscopy, hichorcoms th rsoution imitations of ight diffraction34–38. Ths n imagingmodaitis proid rsoutions of tns of nmhich, aon or ith th addition of spctrainformation, might b sufficint to trac thfinst nuropi.
In para, it i b important to dsignn Brainbo transgns to incras th
rang of nurona typs and dopmntastags to hich th mthod can b appid.Thr ar sra maor imitations of th first-gnration Brainbo ins. Thrguatory mnts that ar usd (fromth Thy1 gn) dirct high s of xprs-sion in many proction nurons, but mostintrnurons ar poory markd21. Aso,in most ins, transgn xprssion is o inmbryos and during th first postnata k,so ths ins ar unsuitab for dop-mnta studis. Furthrmor, som cooursar dim (spciay rd shads), primariy
Fiu 3 |MltlallabllgBabwtagm.
a | A mt nv innvatin a mucl.b | An axn tact in th baintm.
| Th hippcampal dntat yu. In th Bainbw mic fm which th
ima w takn, up t ~160 clu w bvd a a ult f th
c-intatin f val tandm cpi f th tann int th mu
nm and th indpndnt cmbinatin f ach by Crecmbina
( FIG. 2c). Th ima w btaind by th uppitin f paat d,
n and blu channl. Th ima in pat a i cuty f ryan Daft.
Progress
NATURe RevIewS | neuroscience vOlUMe 9 | jUNe 2008 | 421
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bcaus th protins ar insufficinty photo-stab. Additionay, sra bright XFPsar difficut to distinguish from ach othr(for xamp, yo rsus grn or orang
rsus rd) bcaus thir spctra ar insuf-ficinty distinct. Moror, athough thnumbr of coours is prsnty arg (~100),
it is nonthss insufficint for som pur-poss. Thr ar f concptua difficutisin dsigning ‘scond-gnration’ Brainbotransgns that circumnt ths imitationsbut, as ith th first gnration, arg num-brs of atrnatis might nd to b assaydbfor succss is achid.
It aso rmains to b sn hthrmuticoour abing can gnrat compxconnctoms onc ths tchnica probmsha bn sod. If it cannot, or n if itcan, th rapid adancs in high-throughputctron microscopy might man thistchniqu mrgs as a iab atrnati16.
Finay, gin that a of ths mthods aroing in para, it might b that thoptima soution to connctomics i b ahybrid of tchniqus that incuds not ony Brainbo but aso ctron microscopy,array tomography and adancd pathay-tracing mthods.
Conclusion
w ca iring diagrams connctoms tohighight th anaogy to gnoms. Obtainingth squnc of th human gnom asdifficut and xpnsi. Th qust for con-
nctomic information i probaby b nmor difficut. lik gnomics, connctomicsrquirs th dopmnt of n tchniqus,th comparison of atrnatis and aysto mak mundan and automatic hatis initiay difficut and abour-intnsi.Unik gnomics, hor, connctomicsmight rquir th para appication of mutip approachs for abing, imaging,rconstructing and anaysing nurons.Fortunaty, th fid is no moing at anastonishing pac, and th approachs ha outind hr rprsnt ony a substof thos that ar bing dopd indpnd-
nty and nrgticay to orcom thchangs that i ahad.
Jeff W. Lichtman and Joshua R. Sanes are at the
Department of Molecular and Cellular Biology and
Center for Brain Science, Harvard University,
Cambridge, Massachusetts 02138, USA.
Jean Livet is at INSERM, UMR S592, Institut de la
Vision, F-75012, Paris, France and at UPMC University
of Paris 06, UMR S592, F-75005, Paris, France.
Correspondence to J.W.L.
e-mail: [email protected]
di:10.1038/nn2391
Publishd nlin 30 Apil 2008
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