- Email: [email protected]
Muscle differentiation: more complexity to the network of myogenic regulators
539
Muscle differentiation: myogenic regulators Hans-Henning Recent
genetic
and biochemical
our understanding myogenesis
of control
in vertebrate
combinations revealed
Arnold*
unique
and
overlapping
that establishes
Moreover,
which
within
muscle
In addition,
novel genes
myogenesis
loop-helix
(bHLH)
molecular
mechanisms
are being elucidated, factors
upstream
of myogenic or negative
interactions
most notably
between
and MEFP transcription
of that
i/l &CO that
of
basic helix-
University
the myogenic
factors.
Biology, Institute of Biochemistry of Braunschweig, Spielmannstrasse
7,
38106 Braunschweig, Germany *e-mail: [email protected] Current
Opinion
in Genetics
& Development
1998,
myoblasts
8:539-544
http://biomednet.com/elecref/0959437X00800539 Biology
Ltd ISSN
The
basic helix-loop-helix
MEFP MLP
myogenic enhancer muscle LIM protein
YACs
yeast artificial
muscle
determination
seen
when
myogenin-null
for functional
redundancy
[8-101.
0959-437X
Abbreviations bHLH MDFs
not
in vitru [h,7].
The temporal sequence of LIDF gene activations during embryogenesis and the mutant phenotypes have led to the simple view of a two-step model for skeletal myogenesis in which hlyf-5 and MyoD act early to establish myoblasts and myogenin mediates their terminal differentiation. hlRF4 was also assumed to exert late functions in the myogenic pathway, possibly similar to myogenin. This assumption is primarily based on its late activation in the embryo and in cultured muscle cells but this has not been supported by direct evidence. ‘Igrgeted inactivation of the hIRF4 gent causes only a very mild muscle phenotype bvhich argues
0 Current
is, however,
are cultured
ways. The
and cooperativity
Addresses Department of Cell and Molecular and Biotechnology,
overlap of both gents despite their markedly different onset of expression. ‘I’he functional overlap of A[\& and JQf.5 in the regulatory network of myogenesis has been confirmed by simultaneous disruption of both genes which causes a complete absence of myoblasts and differentiated skeletal muscle. The null-mutation of the myogenin gene exhibits a severe muscle phenotype with substantial but not complete reduction of skeletal muscle tissue, resulting from a differentiation defect of myoblasts
cell lineages.
have been discovered
in positive
of these
of the
the regulatory
as a key regulator
and the activity
proteins
have
of members
seems to act genetically
modulate
bHLH
factors
systematic
in mice
functions
skeletal
have advanced
underlying
In particular,
Pax3 has been identified
myogenesis MyoD.
approaches
gene disruptions
MyoD family of transcription network
and Barbara Winter
mechanisms
organisms.
of targeted
more complexity to the network of
factors factor
2
chromosomes
Introduction Specification and differentiation of skeletal muscle cells in birds and mammals is critically dependent on four muscle-specific basic helix-loop-helix (bHLH) transcription factors, frequently referred to as the family of muscle determination factors (MDFs). Targeted gene disruptions of each family member - hlyoD, blyf-5, myogenin, and hlRF4 - in mice have shown that they play central roles in vertebrate myogenesis [l-3]. Inactivation of the hlyf-5 gene - the first member of the family to be induced in muscle precursors in somites through signals from the adjacent neural tube and notochord [4] results in a delay of myotome formation and aberrant migration of the presumptive muscle precursors into the adjacent tissues, dermis and sclerotome, where they acquire non-muscle fates [S]. This early defect in myogenesis, however, is compensated by the later expression of hIyoD leading to essentially normal muscle at birth. Vice versa, disruption of the MyoD gene that is normally first expressed two days after hlyf-5 also does not perturb muscle differentiation at a gross level, suggesting substantial functional
precise
assessment
of the roles of individual
MFDs
has been complicated by the apparent overlap of functions observed between the \-arious myogenic bHI,H genes. A unicluc role of myogenin in skeletal muscle differentiation it1 .u& \\ith no functional redundancy to either hlyol) or hlyf-S has been demonstrated by formal genetics with crosses of myogenin and hlyoD null mutants, and myogenin and hlyf-5 mutants [ll]. Recent investigations which further address the individual roles of myogenic bHLH genes in the complex network of skeletal myogenesis are rcvicwed. \Ve also refer to the recent discovery that the transcription factor Pax3 may be a key player in myogenesis. Despite the fundamental importance of hlDFs, they are by no means the only factors affecting muscle cell differentiation. A number of other transcription factors that either positively or negatively modulate MDF activity and muscle-specific gene expression are also discussed.
How unique are the intrinsic properties of the individual myogenic bHLH genes? Overexpression of individual hlI)Fs in a variety of nonmuscle cells results in comparable activation of the program of skeletal muscle differentiation. Nevertheless, inactivation of these genes in mice leads to different myogenie phenotypes, raising the important issue of whether the different myogcnic bHLH factors have unique
540
Differentiation
intrinsic
and gene regulation
or whether
propcrtics
pttcrns
their
distinct
expression
mutant
i71 .~Ycocawc the difference.
mice
direct
lacking
cI.idcncc
eGzw. as they \Vang d d. scclucnw the
[ 121 replaced
of myogcnin
transcriptional
carrying
this
control
myogcnin
lack the rib defect mutation.
‘I‘his
of
normally
result
leads
to
mice
hlyf-5.
t)), the
associated
under
Ilomozygous
mice
are 1 iable
establishment
of
and
m)ogcnic
mice Il6’). fib-s
mrisclc mice
ahsolritcly
rcqliircd
to activate
cells
in
the
stems
indicating
iI/ fvzv and
conditions.
not very
muscle
the
myogenin
knock-in
mutant
background,
hlyoI>-null homozygotcs skclctal
die shod)
to fully
the
myogcnin
knock-in
knock-in
iirc
with
also
allclc.
;1s they
simihr
allclc
lack
;I
double
of
I13’].
\ic\l,
hIiIJIi
skeletal
the
.1!,;{-,5
promoter
ib
cmbryogcncsis.
the results
cxprcssion
the myogenin
fic,icnt
from
to either
establish
downrcp~lated
mu)
Ix
during
cxpl:iincd
knod-in
Iq
allele
the frrll complcmcnt
c.cIIs or to support
diffcrcntiation
of inyol)lnsts.
addition,
transacti\ ation
propcrtics
ilniquc
that arc distinct contribiltc
from
that 1lyolI
of target genes
niyogenii~
is
10-fold
Rlyol>‘s abilit> to rcmodcl rcK:ions
of tlic
protein
traiisac.ti\,;(tion constwd
for
prcc’iously.
eqdain
\rhy
hlyol)
early step
is tlir less cfficicnt more
Ii\ idcncc for the abilit) fcrcntiation ol,taincti
similar
nio~isc.
to
suggesting
tcmporc,sl~~itial
nl)ogcnin
--
the
c’:in lxirtiall)
tions.
(~on\~cr~cl~, in
L ial)lc
and
gcriin
is rrprc,gulatcd
abscncc
I1a1.c
of
silent
with
t\vo
implicated regions
in arc
\\hich
Interestingly,
of
ma)
hmvcvcr.
for
h4lil~l
~c~riltl 1~ factors i5
If this Icvcl
of sc\-a-al
t\vo
riilc.
of
bIII,ll
gents.
comI~in~itions
in mice.
tIicn.
Ix
dctrinicnt3l.
IIS in:icti\ation
cxamplc.
i\
niy)gcnic
results
ot
in fairly
IX].
clifhccn
of the
[IS]. In rcscticd
in
\\.hcn
pattcrii
of
for- m);ogenin
fklnc-
mic.c
\\,hich
mtlsclcs.
compcnsatc4 ho\\ wcr.
:irc ha\,e
iirc
e\ idcncc
functions
probably
\llIl;s
of
associated
tllat in \cr-
v ith
thcil
I)tit it i5 al\0 clear that thew
distinct
potential
intrinsic
~bhich
most
propcrtios
likely
anti
contrit>iltcs
to
~lSl’“C’S of nl)o~:cncsls.
What lies upstream of the myogenic bHLH genes? ‘I‘hc a\ailablc and .l!yo/1 cells
c\idcncc
constitlltcs
to the
m)-ojicnic
must
these
gene acti\.itics
of
cmh\o.
the
signals and
t,f dcm
from
surfilcc
lincagc muscle
the
and location
all ciiscs,
howocr,
(neural
tube
[20],
iii
arc also in\ol\d
it i5 tinclcar bH1,l
I Ictlgcho,~ notochcdi
of ni>cqznic I)ar;ixial
it was shcnvn
of nlyogcncsis 1 gcnc
mcso-
that
IShll’\
in the control
u ithin
hoa thee
01‘
control rcKions
and
csprc5sicJn
myogcncsia
noggin
to control
which
m~is~lc-ti)rming
can indttcc
acti\ ;I-
c 1 iv\\
of \\:nt and Sonic
rcccntly
:intagonist
csprcwion \\+th
mechanisms
various
somitic
of timin!:
of .l!r/~.;
;\ comprchcnsi\
the
btriicturc4
cctodcrm
3nd their
intcgratcd
gcncs. in
activation
c step that commits
anal sut)scqucnt
:I umil)in;ltic)n
;i*ial
that
cell ciiffcrcntiatic~n
inclLlde
11,11 factors and I17-191. Jlorc
ally
suggests
the determinati\
of miisclc-specific
m)og:enc5is
recentl)
-
some
is accirmulating
unique
c~t‘cuprc‘;sion
factors
tranucti\.:ition
tion
cell linugc
mtisclc
thcrc
01 the apparcntl~
o~‘N~~I!,“(‘NIII triggcrs
the control
skeletal
and probtibl\[IO].
in
and mygcnin
diffcrcnti~ltion.
knock-oilt
normal
sunimar~.
transcription
chromatin.
that hlKI:4
sulxtitlltc
.MR/.‘4
cwentially
hlKIC-l
chroniatin. in activating
is partially
the abhcncc of m)og;enin,
In
some
niygcncsis
tr;illscril)-
hckgrcbiind
diffcrcntiation
cxprcsscd
in
ma) 31~0
patterns
has
tin&r
of myogcnic
mtisculaturc
spccitic
to promote
myogcnin
transgcnc
hI\;f-.5
roles pathwa!
strtictur;iI
;I gcncral
tehratc
m!oficnic
in 3 ~/~//‘~~,,/i//-iiiiII
muscle
skclctal
thcsc
terminal
of \lK124
from a .lIKb’J
I~J~~I~BN;Npr0motcr
norrn:il
and Jl~d-.? arc niol-c cfficicnt
in triggci-ing
cffccti\c
compensator! differentiation
elimination
mcdi:ltcs
of ~kclctal myogencsis tlic
factors,
is
one can
mutants,
normal
Ic\.cI
by
can not Ix
of myogcnic
t,tlt not in myogcnin
31 cstablishin~
blHI,l-l ‘l’his
and
of m\cqcnin
Iu3i
Significantly,
protein
achiacti
douhlc
muta-
As myogcnin
[ lh’l.
cxcpluna-
to actir,atc muscle
X1KF-l
i\ associatccl not
threshold
a
ii/ E~iev. ‘l’he simplest
in the miiscle
that is insuf-
in rcprcssi\c
II~I~C
latc
display
alone is rrnablc to support
the unanticipated
a critical
mutants
to that seen in ni~o,q3iin
or both. In
Ics5 efficient
chromatin
that
in the \l).f-5
mediating
tlii\
able
although
both the .I//?/+‘4 and .1!,~0/1 single
that myopiin
In frict. Gerber O/N/.
thcsc gcncs in regions of transcription~~ll\i
hiit
Ilnder
program.
effect on myq3v2sis
cell differentiation
and Xlyol) that
low -ICI cl
2nd RIy111
phrnot>I)cs.
ticmonstratcri
acti\stion
whcrcas
those of hlyf-5
to the ol~ser\d
recently
ma!’
diffcrcntiation.
double
similar
in these ,lfR~‘4/~ll~oD
csscntial
1l.i’j.
phenotype
muscle tion
mygcnin-null
diffcrcntiatcd
mutant
expressed conclude
pro-
hy the ‘Il,~f-.i/t~/~l?rrr’I/iN
most
deficiency
whereas
mutants,
normally
tional
.WR/*‘4
t~~~~o,gn/irn is
hl~-f-.5 are apparently
diffcrcntiation
,lIRb‘4/,lf~wl1
miisclc
se\zre
tions have little
reduced
is not sufficient
:i second
this
to the m);ogcnin
on
the diaphragm)
rcscucd
not
the
Ixcausc
for J~y~-.j uhcii
(hsistcnt
mice
are bred
hmvevcr.
birth
(including
is lackinK.
muscle.
after
formation
compcns2tc
miitant
mutants
muscle
Apprcnt1y
[l-I*]
nor
efficiently.
11nexpectedly,
As
niyogcnin-null
additional
,I/RF4
myoblast and/or
as
of the emlqw.
U’hcn
tcin
for
i/j
phcnotypc
in
1)~ the
ncithcr
no
gcncs
the amount of rcsid-
present
unaffcctrd that
of both
the same
In particular,
hlyol)
the
overlap
normally
mutation, thcsc
and rnnwg~~ir/ provide
‘L/RF4
essentially
ual
in place of
function
exhibit
my~,Xenin-null mutant
the blyf-.5-null
with
that myogenin
for early hlyf-5
coding
myqenin
mutation
suggests
can compensate the
in
to express
‘knock-in’
hlyf-5
mytomc
.wlrflS
in order
both
foi- functional
the romitc. $ign;ils
In
arc actll-
cxprcs5ion.
mvofor
the
dout3lc
(Zorrect
sl’;itiotcmpor”l
cxprcssion
animals
and acti\,ation
in diffcrcntiating
ot’~~~wy~i~~ in transgcnic m>-ot>last5 i/l r,;tu/
Muscle differentiation Arnold and Winter
dej)ends
on li-box
proxinlal scription h,IKF4
fztorh
region
clement
factors
hovcvcr, promoter
myogcnin
culture
promoter
mouse
fragment
only
timcs.
directs
probat,ly
requires
(K Zwcigcrdt,
:idditional,
II-II
more
limited
that
an X.5 kh j32utcrn [%].
control
is known this
mollsc.
about the control
gene is located
and most of the intcrgcnic in
transgcnic
branchial [‘sing
mice
arches
and.
mouse
,b($.5
uncxpcctcdly
lows.
it
distant
elements,
the .l!$.!i of the
control
results
itidiutc
regions
regulate
the \ arious bl?
Llorco\w.
e\ en lateral
nu er express .jQ&
clcmcnts
somites
the
rcccntly
that
been
regions
to different
almost certainly
or locus
the
control
.11$.? cxprcssion of the embryo.
signals.
As thcsc
lie closer to .llRP4
underlying
to
composition
investigated.
cnhanccrs
the control
uith
in
prolu-
regulator)
than to ;jl~f-.T.
of both g:rnes will
be interesting.
these
evidcncc
that
obscure. transcription
tranccrij,tion
is cxj>rcsscd paraxial migrate
and
Pos.~ constitutes
of skeletal
in the dorsal
in
somites
to the dermom)otomc
neural
where
including
one
muscle.
of
Pax3
tube,
it
in
functions
a Pus.i
of impaired
3 ~0nscq1Icn~~
mutation migration
the lateral d~rmom);otome.
ation potential
is not impaired
lack limb
u ill
II~~ISCICS as
of muscle jwogenitors
although
their
lllllscles
exist
and
In any
(33].
express
genetic fail
myogenic
diffcrenti-
[39,X)].
studies
to cxj>rcsT
function
of.s~/0t~/I/,j!1;/15 double iLlvo1)
in the mvotome
ni~~sclcs but not the muscles cells ;Iction
in the absence of .jfyliD.
t!-j>c :irgues for RlyoI)
that
in heiid muscles
can
only
in precursors
which
form
and lack all hod) arise
double
Pax.3 i\ ~iii essential
I>>
niicc which
in the head [.il”].
the .sp/i&/.M,$.j
cxprcsbion
way. ‘1%~ analysis
of LjQfl.T
revcalcd
mut;lnt
As m~iscle through
mutnnt
upstream
of body
the
phcnoregulator
muscle
but not
in a /‘/lo.?-independent
p:ith-
of sp/~f&/,j{yf.T
mutants
gene that
is
are also de\ oid of I)od) coregulators
in neural
tissiics
must
th:it
ne\er
.jf.y~I).
Cooperation of MDFs with other transcription factors for muscle-specific gene activation Other
thali
scription
the
IzlyoD
Lictors.
family
imjwrt;rnt generate
proteins
Rll:I‘1 +2 domains.
present
scqllcnc‘c
cell linoagcs in
the
myogenesis
tltc
XII’lT1
cell diffcr-
genes
conser\ul
JlIS:! control
csscntial
[X-.37]
hind
regions
of
most
gcnc
for differentiation
cardiac
3s
consen-
I)-I\IE:f7
in
of all
of the h1EFX:
niirtation
and
impairs
which
LlAIX
jwotcins
sing:lc
‘I’hc
mouse
3150 play 3n
muscle
to an A-‘1’ rich I)NA
in
gcncs.
tran-
cnh;inccr
fwtors
during
the highly
homo- or hcterodimers
hHI,H
ni!ogcnic
ha\e foilr
containing
3djaccnt
the
ntusclc
the
of transcrij)tion
1.341. \‘crtclwtcs
gene
of
role in gcnc acti\2tion
cnti:ition
anJ
of myogcnic
nienibcrs
factor 2 (\11<1:2) family
morphogenrsis
and
[3X].
It is beliebed vatc
&it
also argiics
for
\1111:2 transcription
target genes
b>. bindinK
to their
site Ijut also by protcin-protein t~HI,II/El7
heterodiniers
co~~sensl~s
jm)l,al,l!
j>roteins
miisclc-specific
gene
xti\
of
their motifs.
1.191. ‘l’he
:ihility
j3rotcins
on two conser\ ed amino acitj rcsidiics
Rll)Fs
-
the
Ixxausc
corresponding
domain ders
thrconinc
xubstitution two
of nonmyogcnic
the
mutated
in
myogcnic
the
bHI,Ii
h;lsic
of these
asjwragincs
bH1,F-I
in this \~a)- still
and j>roniotc
factors
bind DNA,
myogencsis -
ala-
domains
of
t\\o rcsiducs
\vith
jwvznt
factors.
for
of m!-o-
i\ dependent and
and
In this comcofwtors
gcnic I>I~L,H nine
to initiate
E-box
rcspccti\c
:ict as csscntial
ation
niyogcnic
to the
hll
through
and Ilcterodimerization
plcx. hlI
with
3rc bolind
interaction
occurs
hetcrodimers
factors not onI>- actiown l)i’XA recognition
intcractiotis
u.hich
‘I’his
secjllencc.
l~l~I,li
of Pr/;ci ~2s
are not
to note that mouse
additional
case.
is no
directl)
mesodcrm
3 I)HI,I1
ptu.c”si.s.
jwttcrning.
3s Z’U.L? is also expressed
l)NA-binding :\ rcmarkablc
in somitic
lacking
.I!$.5
date, there of ,j!yoD
mutants
in\.ol\,ed in mcsoderm
gene.
becomes
cells that
to form limb rn~~sclcs. Among other severe defects.
.sp/~t& mice carrving from
bctor
in the embryo
mcsodcrm,
rcstrictcd
has been that the paired-box
dwclopment
to
the
regulatory
‘Ii)
In this context, it is intcrcsring
/h.w/~hi/~~ i\ absolutely
in the
tube
underscore
myogcnic
remains
An exciting
gcncs
pre-
be induced
can
ohscr\,ations
Pax3 controls
muscle-sj)ccific
key
of
cxprcssion.
and neural
naturally
unlikely.
sus
homcodomain
explants
,j/yf’.S
the I-‘c/.\;i-cxj>ressing rctrovirus.
striking
Pax3 is an upstream regulator of MyoD
the
in
mcsoderm
of 1’/1.\:~as 3 dominant
its mode of action
cithcr
recent discovery
using a
cxpres-
Lvith 50 kb proximal
has not
distinct
[Z7].
cur)-ing
the prwisc
correct spatiotcmpor3l
the mechanisms
in
jjlatc
ectopic
tissues
In this stud?; it is shown
maintains
cells which
it by infection
by
chick embryo
expression
and
and more general
in
to activate the gene in
be achicwd
Inusclc-formin:
in response
expression
\zhcrcar correct somitic
clcmcnts
the
located >.50 kb upstream
17X]_ Although
that
In
prcrursors
(l’A(:s)
arc ncccssq
can
promoter
cxtcnt,
,j!y~D
mcsoderni
Although
of ,llRZ*‘4
hlyf-ii
muscle
\vzu, demonstrated
cells of the limbs.
sion in myotomes
dri\w
facial
chromosomes
of the ,M,lf1.5 promotcr, muscle
in
to some
yeaat artifical
of.lfyj1.5.
-8 kb downstrum
region
only
complemented
clcments
observations).
regions
nicely
vector 1.3Z”].
f’/I.~.i induces
somitic
j3otcntial Littlc
;lrc
of /‘c/s.i in cultured csj3rcssion
express
in the mytome
distal
,\rnold, unjwblishcd
findings
expression retrovirus
expression
of ,bfRF4
‘l’hese
revcal,
lines
drives the correct fetal expression
early esprcssion
[%I.
transcrip-
whereas
and part of the early mytomal
‘1%~ comj+tc
tran-
by a proximal
and hlEF2
‘liansgenic
at all decelopmcntal fragment
of .jfRb‘4
to which
this
located in the
in .WRfq’4 regulation
in tissue
[25].
sites
iV~lscle-specific
properly
bind
that
expression
binding [21-23].
3rc also inwlvcd
i\ activated
promoter tion
and hlEF2
j3romotcr
541
in
the
IlaG
such as El 1, rcn-
inactibc. ii model
.tLs hlI>Fs suggchts
thnt
542
Differentiation and gene regulation
alaninc and thrconinc arc rcquircd for the myogenic bHLH factors to recruit an essential myogenic cofactor probably through adoption of a compatible conformation.
A recent study [40’] now provides evidence that the myogenie residues alanine and threonine in the basic domain of R;lyoD are required for synergistic activation of musclespecific transcription by MyoD and hlEF2 hut not for the interaction ,OU se. Obviously the hlyoD/MEF2 complex must acquire transcriptional competence through a mechanism that is dependent on the basic domain of hIpoD and complex formation is not sufficient. ‘I’he requirement to transmit the transcriptional activation signal within the complex can he bypassed through suhstitution of the MyoD or MEFZ activation domain with the constitutive activation domain of the herpes virus protein VP16. As the actual nature of signal transmission is not known, an intriguing possibility would he that yet another cofactor must be recruited into the complex. Indeed, it has been shown that the transcriptional adaptors p300 and CBP coactivatc the myogcnic hHLH proteins by physical interaction [41]. Stimulation of hlyoD’s transact&Con potential by p300 requires two domains of p300 and the transactivation domain of MyoD. Interestingly, p300 also interacts with the MADS domain of MEFZ proteins and potcntiates its transcriptional activation capability. hluscle LIkl protein (RILP) IS another potential coregulator of skeletal myogenesis which promotes myogenic differentiation [42]. A recent study shows that hlLP enhances the activity of MyoD and interacts with MDFs through the bHLH domain and the first I,IILl motif of MLP 1431. This interaction is specific for myogenic bHI,H transcription factors and does not occur with nonmuscle hHLH proteins, such as El2 or E47. Although the precise mechanism by which MLP enhances terminal differentiation is unknown, it may act by increasing the binding of myogenic hHLH proteins to specific DNA regulatory elements, as hlLP on its own lacks a transcription activation domain.
Negative regulators of muscle gene transcription Given the dominant myogenic functions of MDFs, it seems important to regulate their activity in order to prevent premature differentiation of myohlasts and ectopic development of muscles. Peptide growth factors, such as ‘I’GF-p, BhlPs, and FGFs, arc known to inhibit myogenesis by blocking the expression and transcriptional activity of myogenic factors. Stern total. [44] have shown that TGFpl and FGF may also collaborate to induce myogenesis in somites. Myostatin, a TGF-P-related factor which acts in an autocrinc fashion, was recently identified as a potential inhibitor of skeletal myogenesis [45]. A number of nuclear factors have also been implicated in the inhibitory role, most notably the Id (inhibitor of DNA
binding) HI,H proteins which lack the basic DNA-binding domain and act to sequester hHLH proteins into nonbinding complexes. Differential interactions of the four known Id proteins with hHLH transcription factors may contribute to their specific biological functions [40]. ‘I’he mouse hHLH protein twist was also found to inhibit hlDF activity by blocking DNA binding, by titrating E-proteins, and by interference with the transactivation of the hlyoD cofactor ILIEFZ [47,48].
Mistl,
a novel
hHLH
protein
that
accumulates
genie stem cells and decreases as myohlasts to myotuhes, also functions as a negative
in myo-
differentiate regulator of
RlyoD activity [49]. hlistl-induced inhibition of diffcrcntiation involves formation of inactive hlyoD-hlistl heterodimers and occupancy of E-box target sites b); Mist1 homodimers. Mist1 possesses no transcription activation domain hut a repressor region capable of inhibiting heterologous acti\,ators. I-mfa protein may he another factor which prevents inappropriate myogenesis. This protein is highly cxprcsscd in the sclerotome and in oitro inhibits transactikation b) hlyoD family members [SO]. I-mfa associates with hlyoD and retains it in the cytoplasm but it can also interfere with DNA binding of hlDFs. ZEB (zinc-finger/E-box binding), a vertebrate homolog of the Dm.sophil~ zinc finger/homeodomain protein zfh-1, constitutes a completely different type of negative regulator of muscle differentiation [Sl]. ZEB hinds to a subset of E-boxes in muscle genes and actively represses transcription until it becomes replaced by high concentrations of myogenic hHLH factors. This may provide a mechanism to regulate temporal order of muscle gene expression depending on the relative concentrations of ZEB and m);ogcnic hHLH proteins as well as on their affinities to various E-box target sites.
Conclusions During the past decade, myogencsis has become a paradigm for cell lineage determination and differentiation most importantly through the discolzry of the four myogenie hHLH transcription factors. ‘I’hc genetic approach of targeted gene disruptions for each mcmbcr of the farnil) and even more powerful double mutations in diffcrcnt pairs of the myogcnic hHLH genes ha\,e revealed unique and overlapping functions of these genes and placed them in a network of regulators in the myogcnic pathway. ‘l‘he important issue of whether the different phcnotypcs that result from inactivations of these genes reflect their disexpression patterns or specialized functions tinct associated with the different myogenic hHLH proteins has now been approached. The collective evidence from many experiments suggests that both the le\cls and possibly timing of expression and unique functional properties are important to properly execute muscle lineage determination and differentiation in the embryo. As an open topic for
Muscle
the future,
it remains
unclear
how precisely
these
factors
discriminate between the distinct sets of target genes that they must activate to promote cells through the different stages
important
topic
in the field has been
genie lineage commitment, a parallel pathway with hlyf-5 upstream of MyoD must also exist. A third myogenic pathway
independent
of both
hIyf-5
and
Pax3
appears
to
opcratc for head muscle formation. It will be interesting to see which factors trigger myogenic commitment and My011 gcnc activation there. It is also important to kno\f how precisely Pm? muscles and whcthcr
activates JZyoD expression in body Pa.? plays a role in 22!,if1.5regulation.
543
Patapoutian A, Yoon K, Miner H, Wang S, Stark K, Wold B: Disruption of the MRF4 gene identifies multiple waves of myogenesis in the myotome. Development 1995, 12:3347-3358.
10
Zhang W, Behringer RR, Olson EN: Inactivation of the myogenic bHLH gene MRF4 results in up-regulation of myogenin and rib anomalies. Genes Dev 1995, 9:1388-l 399.
11
Rawls A, Morris JH, Rudmcki M, Braun T, Arnold HH, Klein WH, Olson EN: Myogenin’s functions do not overlap with those of MyoD or My+5 during mouse embryogenesis. Dev Bioll995, 172:37-50.
12
Wang Y, Schnegelsberg P, Dausman J, Jaenisch R: Functional redundancy of muscle-specific transcription factors Myf5 and myogenin. Nature 1996, 379:823-825.
understand-
ing what regulates the myogenic bHLH genes to initiate Compelling genetic evidence argues that myogcnesis. Pm.? is an csscntial upstream regulator for ,t[sflD expression in body muscle precursors. Although Pax3 is the first example of 3 non-cell type-specific factor involved in myo-
Arnold and Winter
9.
of myogenesis.
Another
differentiation
Wang Y, Jaenisch R: Myogenin can substitute for Myf5 in promoting myogenesis but less efficiently. Development 1997, 124:2510-2513. The first knock-In expenment replacing one myogenic bHLH factor gene by another addresses the issue of unique intrinsic properties of Myf-5 and myogenin versus functlonal differences as a result of their distinct expression patterns. The results reveal that myogenin expressed under the control of the Myf-5 gene can partially substitute for Myf-5 but is unable to compensate for loss of a second myogenic bHLH gene in double mutants also lacking either MyoD or myogenin. This suggests that myogemn only inefficiently compensates for Myf-5, probably owing to altered levels of gene expression and/or different transactivation properties. 13 .
14. .
The detailed genie bHLH insights into
analysis of important interactions of myofactors and MEFZ proteins has provided mechanisms of cell-type-specific transcrip-
tion. Kesearch over continue to identify
the next few years will undoubtedly novel factors lvhich will either syner-
gize with or repress thcsc principal and thus refine our view of muscle
players in myogencsis cell differentiation.
Acknowledgements
Gerber AN, Kleseri TR, Bergstrom DA, Tapscott SJ: Two domains of MyoD mediate transcriptional activation of genes in repressive chromatin: a mechanism for lineage determination in myogenesis. Genes Dev 1997,11:436-450. This study provides evidence that MyoD and Myf-5 can remodel chromatin at binding sites In muscle gene enhancers and activate transcription at previously silent loci, whereas myogenin IS markedly less efficient at activating genes in transcriptionally silent chromatln. The ability of MyoD to activate endogenous genes IS associated with two regions in the protein that are distinct from its transactivation domaln and are conserved in the Myf-5 protein. TGF-P, basic FGF, and sodium butyrate - known inhibitors of myogenesls - block MyoD-mediated chromatin reorganization. These results may provide a molecular basts for the fact that MyoD and My+5 establish the myogenic lineage, whereas myogenin mediates terminal differentiation. 15.
References
and recommended
l
of special interest * of outstandlng Interest
1.
Arnold HH, Braun T: Targeted inactivation of myogenic factor genes reveals their roles during myogenesis: a review. Int Dev Biol 1996, 40:345-363.
2.
Molkentin JD, Olson EN: Defining the regulatory networks for muscle development. Curr Op;n Genet Dev 1996, 6:445-453.
3.
Yun KS, Wold BJ: Skeletal muscle determination and differentiation: story of a core regulatory network and its context. Curr Opin Cell Biol 1996, 8:877-889.
4.
5.
6.
7.
8.
during
early
16. .
reading
Papers of particular interest, published within the annual period of review, have been hIghlIghted as:
l
Zhu Z, Miller JB: MRF4 can substitute for myogenin stages of myogenesis. Dev Dyn 1997, 209:233-241.
Rawls A, Valdez MR, Zhang W, Richardson J, Klein WH, Olson EN: Overlapping functions of the myogenic bHLH genes MRF4 and MyoD revealed in double mutant mice. Development 1998, 125:2349-2358. Circumstantial evidence had suggested that MRF4 may fulfil late functions in muscle differentiation, similar to and possibly overlapping with myogenin. Double mutant mice for MRF4 and myogenin now show that neither gene IS absolutely essential for myoblast differentiation; instead, any of the four myogenic bHLH factors appears capable of activating the muscle differentiation program under the appropriate conditions. Unexpectedly, MRF4/MyoD double mutants reveal overlapping roles of both genes in the control of myoblast differentiation, as the mutants lack dtfferentiated myotubes. As Myf-5 and myogenin are expressed in these mutants, the observations suggest that critical threshold concentrations of myogenic bHLH factors may be needed for myoblast differentiation to occur. 1 7.
MOnsterberg AE, Kitajewski J, Bumcrot DA, McMahon AP, Lassar AB: Combinatorial signaling by sonic hedgehog and Wnt family members induces myogenic bHLH gene expression in somites. Genes Dev 1995, 9:291 l-2922.
18
Tajbakhsh S, Rocancourt D, Buckingham M: Muscle progenitor cells failing to respond to positional cues adopt non-myogenic fates in myf-5 null mice. Nature 1996, 384:266-270.
Stern HM, Brown AMC, Hauschka SD: Myogenesis in paraxial mesoderm: Preferential induction by dorsal neural tube and by cells expressing Wnt-1. Development 1995, 121:3675-3686.
19.
Hasty P, Bradley A, Morris JH, Edmondson DE, Venuti JM, Olson EN, Klein WH: Muscle deficiency and neonatal death in mice with targeted mutation in the myogenin gene. Nature 1993, 364:501-506.
Spence MS, Yip J, Erickson CA: The dorsal neural tube organizes the dermamyotome and induces axial myocytes in the avian embryo. Development 1996, 122:231-241.
20.
Reshef R, Maroto M, Lassar AB: Regulation of dorsal somitic cell fates: BMPs and Noggin control the timing and pattern of myogenic regulator expression. Genes Dev 1998, 12:290-303.
21.
Cheng TC, Wallace MC, Merlie JP, Olson EN: Separable elements governing myogenin transcription in mouse embryogenesis. Science 1993, 261:215-218.
22.
Yee SP, Rigby PW: The regulation of myogenin gene expression during the embryonic development of the mouse. Genes Dev 1993, 7:i 277-l 289.
Cossu G, Kelly R, Tajbakhsh S, DiDonna, S, Vivarelli E, Buckingham M: Activation of different myogenic pathways: Myf-5 is induced by the neural tube and MyoD by the dorsal ectoderm in mouse paraxial mesoderm. Development 1996, 122:429-437.
Nabeshima YK, Hanaoka K, Hayasaka M, Esumi S, Lis, Nonaka J: Myogenin gene disruption results in perinatal lethality because severe muscle defect. Nature 1993, 364:532-535.
of
Braun T, Arnold HH: Inactivation of Myf-6 and Myf-5 genes in mice leads to alterations in skeletal muscle development. EMBO J 1995, 14:1176-l 186
regulatory
544
23.
24.
25.
Differentiation
and gene regulation
Buchberger A, Ragge K, Arnold HH: The myogenin gene is activated during myocyte differentiation by pre-existing, not newly synthesized transcription factor MEFP. J Biol Chem 1994, 286:17289-l 7296.
38.
Naidu PS, Ludolph DC, To RR, Hinterberger TJ, Konieczny SF: Myogenin and MEF2 function synergistically to activate the MRF4 promoter during myogenesis. MO/ Cell Biol 1995, 15:2707-2718.
Lln Cl, Schwarz JJ, Bucana C, Olson EN: Control of mouse cardiac morphogenesis and myogenesis by the myogenic transcription factor MEF2C. Science 1997, 278:1404-l 407.
39.
Molkenttn JD, Black BL, Martin JF, Olson EN: Cooperative activation of muscle gene expression by MEFP and myogenic bHLH proteins. Cell 1995, 83:i 125-l 136.
Black BL, Martln JF, Olson EN: The mouse MRF4 promoter is transactivated directly and indirectly by muscle-specific transcription factors. J Viol Chem 1995, 270:2889-2892.
26.
Pin CL, Ludolph DC, Cooper ST, Klocke BJ, Merlie JP, Konieczny SF: Distal regulatory elements control MRF4 gene expression in early and late myogenic cell populations. Dev Dyn 1997, 208:299-312.
27.
Patapoutian A, Miner H, Lyons GE, Wold B: Isolated sequences from the linked Myf-5 and MRF4 genes drive distinct patterns of muscle-specific expression in transgenic mice. Development 1993, 118:61-69.
28.
Zwelgerdt R, Braun T, Arnold HH: Faithful expression of the Myf-5 gene during mouse myogenesis requires distant control regions: a transgene approach using yeast artificial chromosomes. Dev Biol 1997, 191 :I 72-l 80.
29.
Daston G, Lamar E, Olivler M, Goulding M: Pax 3 is necessary for migration but not differentiation of limb muscle precursors in the mouse. Development 1996, 122:1017-l 027.
30.
Bober E, Franz T, Arnold HH, Gruss P, Trambley P: Pax 3 is required for the development of limb muscles: a possible role for the migration of dermomyotomal muscle progenitor cells. Development 1994, 120:603-612.
Talbakhsh S, Rocancourt D, Cossu G, Buckingham M: Redefining the genetic hierarchies controlling skeletal myogeneis: pax 3 and myf5 act upstream of myoD. Cell 1997, 89: 127-I 38. This paper establishes Pax3 as a key regulator in skeletal muscle development. By a genetlc approach, the authors demonstrate that MyoD gene activation In body muscle precursors is dependent on either Pax3 or My+5. In Pax3/Myf-5 double homozygous mutant mice, MyoD IS not expressed and body muscles are completely absent. Thus, Pax3 and Myf-5 define two distinct myogenic pathways and both genes act genetlcally upstream of MyoD. This hierarchy, however, does not apply to head muscle formation.
factor reveals multiple functions in larval and adult myogenesis Drosophila. Dev i3iol 1995, 171:169-181.
40. .
Black BL, Molkentin JD, Olson EN: Multiple roles for the MyoD basic region in transmission of transcriptional activation signals and interaction with MEFP. MO/ Cell i3;ol 1998, 18:69-77. Synergistic activation of muscle-speclflc transcription by myogenlc bHLH and MEFP transcription factors occurs through interaction between these proteins and binding of the complex to either bHLH or MEFP DNA target sttes. The ability of these proteins to synerglstically lnltlate myogenesis IS dependent on two conserved amino acid residues: alanlne and threonlne In the basic domain of the myogenic bHLH factors. The paper now demonstrates that these two ‘myogenic’ amino acids are not required to form complexes between bHLH proteins and MEF2 factors but to acquire the transactivatlon competence provided either from the MyoD or MEFP transactivation domain. Thus, MEFP may be the putative myogenlc cofactor which allows transmission of transcnptlonal activation signals, possibly by inducing a compatible conformation for Interaction with the basal transcriptlon machinery or other cofactors. The dependence on the basic domain of MyoD (alanine and threonine) can be bypassed by substltutlon of the MyoD or the MEFP activation domaln with the activation domain of VP16. As myogenlc bHLH-MEF2 Interactions can be uncoupled from transcriptional activation, the results support the Idea that the myogenlc amino acids In myogenic bHLH proteins are essential for generating the transactivation capacity. 41.
Sartorelli V, Huang J, Hamamori Y, Kedes L: Molecular mechanisms of myogenic coactivation by ~300: direct interaction with the activation domain of MyoD and with the MADS box of MEF2C. MO/ Cell Bfol 1997, 17:1010-1026.
42.
Arber S, Halder G, Caroni P: Muscle LIM protein, a novel essential regulator of myogenesis, promotes myogenic differentiation. Cell 1994, 79:221-231.
43.
Kong Y, Flick MJ, Kudla AJ, Komeczny SF: Muscle LIM protein promotes myogenesis by enhancing the activity of MyoD. MO/ Ceil B/o/ 1997, 17:4750-4760.
31. ..
32. ..
in
Maroto M, Reshef R, MOnsterberg AE, Koester S, Goulding M, Lassar AB: Ectopic pax3 activates myoD and myf5 expression in embryonic mesoderm and neural tissue. Cell 1997, 89:139-l 48. The study demonstrates that signals from ectoderm or Wnt and Sonic hedgehog can induce dermomyotomal and myotomal markers In presegmented mesoderm. Pax3 and Pax7 are induced concomitantly with Myf-5 and prior to MyoD. Moreover, retrovlral expressIon of Pax3 in embryonic tissues. such as paraxial and lateral plate mesoderm as well as neural tube explants induces MyoD expression and myogenesis in the absence of inducing signals, These results imply that Pax3 mediates actlvatlon of My+5 and MyoD expression in response to muscle-Inducing signals.
44.
Stern HM, Lin-Jones J, Hauschka SD: Synergistic interactions between bFGF and a TGF-beta family member may mediate myogenic signals from the neural tube. Development 1997, 124:351 l-3523.
45.
McPherron AC, Lawler AM, Lee SJ: Regulation of skeletal muscle mass in mice by a new TGF-P superfamily member. Nafure 1997, 387:83-90.
46.
Rawls JA, Parsons S, Wilson-Rawls NJ: Mice lacking paraxis and Myf-5 display severe defects in skeletal muscle and axial skeleton. Dev B/o/ 1998, 198:217.
Langlands K, Yin X, Anand G, Prochownlk EV: Differential interactions of Id proteins with basic-helix-loop-helix transcription factors. J B/o/ Chem 1997, 272: 19785-19793.
47.
Olson EN, Perry M, Schulz RA: Regulation of muscle differentiation by the MEF2 family of MADS box transcription factors. Dev Biol 1995, 172:2-14.
Spacer DB, Rhee SJ, Cheung WL, Lassar AB: Inhibition of myogenic bHLH and MEF2 transcription factors by the bHLH protein Twist. Science 1996, 272:1476-i 480.
48.
Hamamorl Y, Wu HY, Sartorelll V, Kedes L: The basic domain of myogenic bHLH proteins is the novel target for direct inhibition by another bHLH protein, Twist. MO/ Cell B/o/ 1997, 17:6563-6573.
49.
Lemercler C, To RCI, Carrasco RA, Komeczny SF: The basic helixloop-helix transcription factor Mist1 functions as a transcriptional repressor of MyoD. EM60 J 1998, 17: 1412-l 422.
50.
Chen CM, Kraut N, Groudine M, Welntraub H: I-mf, a novel myogenic repressor interacts with members of the MyoD family. Cell 1996, 86:731-741.
51.
Postigo AA, Dean DC: ZEB, a vertebrate homolog of Drosophila Zfh-I, is a negative regulator of muscle differentiation. EMBO J 1997, 16:3935-3943.
33.
34.
35.
Bour BA, O’Brien MA, Lockwood WL, GoldsteIn ES, Bodmer R, Taghert PH, Abmayr SM, Nguyen HT: Drosophila MEFP, a transcription factor that is essential for myogenesis. Genes Dev 1995, 9:730-741.
36.
Lilly B, Zhao B, Ranganayakulu G, Paterson BM, Schulz RA, Olson EN: Requirement of MADS domain transcription factor DMEF2 for muscle formation in Drosophila. Science 1995, 267:688-693.
37.
Ranganayakulu G, Zhao B, Dokodis A, Molkentln JD, Olson EN, Schulz RA: A series of mutations in the D-MEF2 transcription
Muscle differentiation: myogenic regulators Hans-Henning Recent
genetic
and biochemical
our understanding myogenesis
of control
in vertebrate
combinations revealed
Arnold*
unique
and
overlapping
that establishes
Moreover,
which
within
muscle
In addition,
novel genes
myogenesis
loop-helix
(bHLH)
molecular
mechanisms
are being elucidated, factors
upstream
of myogenic or negative
interactions
most notably
between
and MEFP transcription
of that
i/l &CO that
of
basic helix-
University
the myogenic
factors.
Biology, Institute of Biochemistry of Braunschweig, Spielmannstrasse
7,
38106 Braunschweig, Germany *e-mail: [email protected] Current
Opinion
in Genetics
& Development
1998,
myoblasts
8:539-544
http://biomednet.com/elecref/0959437X00800539 Biology
Ltd ISSN
The
basic helix-loop-helix
MEFP MLP
myogenic enhancer muscle LIM protein
YACs
yeast artificial
muscle
determination
seen
when
myogenin-null
for functional
redundancy
[8-101.
0959-437X
Abbreviations bHLH MDFs
not
in vitru [h,7].
The temporal sequence of LIDF gene activations during embryogenesis and the mutant phenotypes have led to the simple view of a two-step model for skeletal myogenesis in which hlyf-5 and MyoD act early to establish myoblasts and myogenin mediates their terminal differentiation. hlRF4 was also assumed to exert late functions in the myogenic pathway, possibly similar to myogenin. This assumption is primarily based on its late activation in the embryo and in cultured muscle cells but this has not been supported by direct evidence. ‘Igrgeted inactivation of the hIRF4 gent causes only a very mild muscle phenotype bvhich argues
0 Current
is, however,
are cultured
ways. The
and cooperativity
Addresses Department of Cell and Molecular and Biotechnology,
overlap of both gents despite their markedly different onset of expression. ‘I’he functional overlap of A[\& and JQf.5 in the regulatory network of myogenesis has been confirmed by simultaneous disruption of both genes which causes a complete absence of myoblasts and differentiated skeletal muscle. The null-mutation of the myogenin gene exhibits a severe muscle phenotype with substantial but not complete reduction of skeletal muscle tissue, resulting from a differentiation defect of myoblasts
cell lineages.
have been discovered
in positive
of these
of the
the regulatory
as a key regulator
and the activity
proteins
have
of members
seems to act genetically
modulate
bHLH
factors
systematic
in mice
functions
skeletal
have advanced
underlying
In particular,
Pax3 has been identified
myogenesis MyoD.
approaches
gene disruptions
MyoD family of transcription network
and Barbara Winter
mechanisms
organisms.
of targeted
more complexity to the network of
factors factor
2
chromosomes
Introduction Specification and differentiation of skeletal muscle cells in birds and mammals is critically dependent on four muscle-specific basic helix-loop-helix (bHLH) transcription factors, frequently referred to as the family of muscle determination factors (MDFs). Targeted gene disruptions of each family member - hlyoD, blyf-5, myogenin, and hlRF4 - in mice have shown that they play central roles in vertebrate myogenesis [l-3]. Inactivation of the hlyf-5 gene - the first member of the family to be induced in muscle precursors in somites through signals from the adjacent neural tube and notochord [4] results in a delay of myotome formation and aberrant migration of the presumptive muscle precursors into the adjacent tissues, dermis and sclerotome, where they acquire non-muscle fates [S]. This early defect in myogenesis, however, is compensated by the later expression of hIyoD leading to essentially normal muscle at birth. Vice versa, disruption of the MyoD gene that is normally first expressed two days after hlyf-5 also does not perturb muscle differentiation at a gross level, suggesting substantial functional
precise
assessment
of the roles of individual
MFDs
has been complicated by the apparent overlap of functions observed between the \-arious myogenic bHI,H genes. A unicluc role of myogenin in skeletal muscle differentiation it1 .u& \\ith no functional redundancy to either hlyol) or hlyf-S has been demonstrated by formal genetics with crosses of myogenin and hlyoD null mutants, and myogenin and hlyf-5 mutants [ll]. Recent investigations which further address the individual roles of myogenic bHLH genes in the complex network of skeletal myogenesis are rcvicwed. \Ve also refer to the recent discovery that the transcription factor Pax3 may be a key player in myogenesis. Despite the fundamental importance of hlDFs, they are by no means the only factors affecting muscle cell differentiation. A number of other transcription factors that either positively or negatively modulate MDF activity and muscle-specific gene expression are also discussed.
How unique are the intrinsic properties of the individual myogenic bHLH genes? Overexpression of individual hlI)Fs in a variety of nonmuscle cells results in comparable activation of the program of skeletal muscle differentiation. Nevertheless, inactivation of these genes in mice leads to different myogenie phenotypes, raising the important issue of whether the different myogcnic bHLH factors have unique
540
Differentiation
intrinsic
and gene regulation
or whether
propcrtics
pttcrns
their
distinct
expression
mutant
i71 .~Ycocawc the difference.
mice
direct
lacking
cI.idcncc
eGzw. as they \Vang d d. scclucnw the
[ 121 replaced
of myogcnin
transcriptional
carrying
this
control
myogcnin
lack the rib defect mutation.
‘I‘his
of
normally
result
leads
to
mice
hlyf-5.
t)), the
associated
under
Ilomozygous
mice
are 1 iable
establishment
of
and
m)ogcnic
mice Il6’). fib-s
mrisclc mice
ahsolritcly
rcqliircd
to activate
cells
in
the
stems
indicating
iI/ fvzv and
conditions.
not very
muscle
the
myogenin
knock-in
mutant
background,
hlyoI>-null homozygotcs skclctal
die shod)
to fully
the
myogcnin
knock-in
knock-in
iirc
with
also
allclc.
;1s they
simihr
allclc
lack
;I
double
of
I13’].
\ic\l,
hIiIJIi
skeletal
the
.1!,;{-,5
promoter
ib
cmbryogcncsis.
the results
cxprcssion
the myogenin
fic,icnt
from
to either
establish
downrcp~lated
mu)
Ix
during
cxpl:iincd
knod-in
Iq
allele
the frrll complcmcnt
c.cIIs or to support
diffcrcntiation
of inyol)lnsts.
addition,
transacti\ ation
propcrtics
ilniquc
that arc distinct contribiltc
from
that 1lyolI
of target genes
niyogenii~
is
10-fold
Rlyol>‘s abilit> to rcmodcl rcK:ions
of tlic
protein
traiisac.ti\,;(tion constwd
for
prcc’iously.
eqdain
\rhy
hlyol)
early step
is tlir less cfficicnt more
Ii\ idcncc for the abilit) fcrcntiation ol,taincti
similar
nio~isc.
to
suggesting
tcmporc,sl~~itial
nl)ogcnin
--
the
c’:in lxirtiall)
tions.
(~on\~cr~cl~, in
L ial)lc
and
gcriin
is rrprc,gulatcd
abscncc
I1a1.c
of
silent
with
t\vo
implicated regions
in arc
\\hich
Interestingly,
of
ma)
hmvcvcr.
for
h4lil~l
~c~riltl 1~ factors i5
If this Icvcl
of sc\-a-al
t\vo
riilc.
of
bIII,ll
gents.
comI~in~itions
in mice.
tIicn.
Ix
dctrinicnt3l.
IIS in:icti\ation
cxamplc.
i\
niy)gcnic
results
ot
in fairly
IX].
clifhccn
of the
[IS]. In rcscticd
in
\\.hcn
pattcrii
of
for- m);ogenin
fklnc-
mic.c
\\,hich
mtlsclcs.
compcnsatc4 ho\\ wcr.
:irc ha\,e
iirc
e\ idcncc
functions
probably
\llIl;s
of
associated
tllat in \cr-
v ith
thcil
I)tit it i5 al\0 clear that thew
distinct
potential
intrinsic
~bhich
most
propcrtios
likely
anti
contrit>iltcs
to
~lSl’“C’S of nl)o~:cncsls.
What lies upstream of the myogenic bHLH genes? ‘I‘hc a\ailablc and .l!yo/1 cells
c\idcncc
constitlltcs
to the
m)-ojicnic
must
these
gene acti\.itics
of
cmh\o.
the
signals and
t,f dcm
from
surfilcc
lincagc muscle
the
and location
all ciiscs,
howocr,
(neural
tube
[20],
iii
arc also in\ol\d
it i5 tinclcar bH1,l
I Ictlgcho,~ notochcdi
of ni>cqznic I)ar;ixial
it was shcnvn
of nlyogcncsis 1 gcnc
mcso-
that
IShll’\
in the control
u ithin
hoa thee
01‘
control rcKions
and
csprc5sicJn
myogcncsia
noggin
to control
which
m~is~lc-ti)rming
can indttcc
acti\ ;I-
c 1 iv\\
of \\:nt and Sonic
rcccntly
:intagonist
csprcwion \\+th
mechanisms
various
somitic
of timin!:
of .l!r/~.;
;\ comprchcnsi\
the
btriicturc4
cctodcrm
3nd their
intcgratcd
gcncs. in
activation
c step that commits
anal sut)scqucnt
:I umil)in;ltic)n
;i*ial
that
cell ciiffcrcntiatic~n
inclLlde
11,11 factors and I17-191. Jlorc
ally
suggests
the determinati\
of miisclc-specific
m)og:enc5is
recentl)
-
some
is accirmulating
unique
c~t‘cuprc‘;sion
factors
tranucti\.:ition
tion
cell linugc
mtisclc
thcrc
01 the apparcntl~
o~‘N~~I!,“(‘NIII triggcrs
the control
skeletal
and probtibl\[IO].
in
and mygcnin
diffcrcnti~ltion.
knock-oilt
normal
sunimar~.
transcription
chromatin.
that hlKI:4
sulxtitlltc
.MR/.‘4
cwentially
hlKIC-l
chroniatin. in activating
is partially
the abhcncc of m)og;enin,
In
some
niygcncsis
tr;illscril)-
hckgrcbiind
diffcrcntiation
cxprcsscd
in
ma) 31~0
patterns
has
tin&r
of myogcnic
mtisculaturc
spccitic
to promote
myogcnin
transgcnc
hI\;f-.5
roles pathwa!
strtictur;iI
;I gcncral
tehratc
m!oficnic
in 3 ~/~//‘~~,,/i//-iiiiII
muscle
skclctal
thcsc
terminal
of \lK124
from a .lIKb’J
I~J~~I~BN;Npr0motcr
norrn:il
and Jl~d-.? arc niol-c cfficicnt
in triggci-ing
cffccti\c
compensator! differentiation
elimination
mcdi:ltcs
of ~kclctal myogencsis tlic
factors,
is
one can
mutants,
normal
Ic\.cI
by
can not Ix
of myogcnic
t,tlt not in myogcnin
31 cstablishin~
blHI,l-l ‘l’his
and
of m\cqcnin
Iu3i
Significantly,
protein
achiacti
douhlc
muta-
As myogcnin
[ lh’l.
cxcpluna-
to actir,atc muscle
X1KF-l
i\ associatccl not
threshold
a
ii/ E~iev. ‘l’he simplest
in the miiscle
that is insuf-
in rcprcssi\c
II~I~C
latc
display
alone is rrnablc to support
the unanticipated
a critical
mutants
to that seen in ni~o,q3iin
or both. In
Ics5 efficient
chromatin
that
in the \l).f-5
mediating
tlii\
able
although
both the .I//?/+‘4 and .1!,~0/1 single
that myopiin
In frict. Gerber O/N/.
thcsc gcncs in regions of transcription~~ll\i
hiit
Ilnder
program.
effect on myq3v2sis
cell differentiation
and Xlyol) that
low -ICI cl
2nd RIy111
phrnot>I)cs.
ticmonstratcri
acti\stion
whcrcas
those of hlyf-5
to the ol~ser\d
recently
ma!’
diffcrcntiation.
double
similar
in these ,lfR~‘4/~ll~oD
csscntial
1l.i’j.
phenotype
muscle tion
mygcnin-null
diffcrcntiatcd
mutant
expressed conclude
pro-
hy the ‘Il,~f-.i/t~/~l?rrr’I/iN
most
deficiency
whereas
mutants,
normally
tional
.WR/*‘4
t~~~~o,gn/irn is
hl~-f-.5 are apparently
diffcrcntiation
,lIRb‘4/,lf~wl1
miisclc
se\zre
tions have little
reduced
is not sufficient
:i second
this
to the m);ogcnin
on
the diaphragm)
rcscucd
not
the
Ixcausc
for J~y~-.j uhcii
(hsistcnt
mice
are bred
hmvevcr.
birth
(including
is lackinK.
muscle.
after
formation
compcns2tc
miitant
mutants
muscle
Apprcnt1y
[l-I*]
nor
efficiently.
11nexpectedly,
As
niyogcnin-null
additional
,I/RF4
myoblast and/or
as
of the emlqw.
U’hcn
tcin
for
i/j
phcnotypc
in
1)~ the
ncithcr
no
gcncs
the amount of rcsid-
present
unaffcctrd that
of both
the same
In particular,
hlyol)
the
overlap
normally
mutation, thcsc
and rnnwg~~ir/ provide
‘L/RF4
essentially
ual
in place of
function
exhibit
my~,Xenin-null mutant
the blyf-.5-null
with
that myogenin
for early hlyf-5
coding
myqenin
mutation
suggests
can compensate the
in
to express
‘knock-in’
hlyf-5
mytomc
.wlrflS
in order
both
foi- functional
the romitc. $ign;ils
In
arc actll-
cxprcs5ion.
mvofor
the
dout3lc
(Zorrect
sl’;itiotcmpor”l
cxprcssion
animals
and acti\,ation
in diffcrcntiating
ot’~~~wy~i~~ in transgcnic m>-ot>last5 i/l r,;tu/
Muscle differentiation Arnold and Winter
dej)ends
on li-box
proxinlal scription h,IKF4
fztorh
region
clement
factors
hovcvcr, promoter
myogcnin
culture
promoter
mouse
fragment
only
timcs.
directs
probat,ly
requires
(K Zwcigcrdt,
:idditional,
II-II
more
limited
that
an X.5 kh j32utcrn [%].
control
is known this
mollsc.
about the control
gene is located
and most of the intcrgcnic in
transgcnic
branchial [‘sing
mice
arches
and.
mouse
,b($.5
uncxpcctcdly
lows.
it
distant
elements,
the .l!$.!i of the
control
results
itidiutc
regions
regulate
the \ arious bl?
Llorco\w.
e\ en lateral
nu er express .jQ&
clcmcnts
somites
the
rcccntly
that
been
regions
to different
almost certainly
or locus
the
control
.11$.? cxprcssion of the embryo.
signals.
As thcsc
lie closer to .llRP4
underlying
to
composition
investigated.
cnhanccrs
the control
uith
in
prolu-
regulator)
than to ;jl~f-.T.
of both g:rnes will
be interesting.
these
evidcncc
that
obscure. transcription
tranccrij,tion
is cxj>rcsscd paraxial migrate
and
Pos.~ constitutes
of skeletal
in the dorsal
in
somites
to the dermom)otomc
neural
where
including
one
muscle.
of
Pax3
tube,
it
in
functions
a Pus.i
of impaired
3 ~0nscq1Icn~~
mutation migration
the lateral d~rmom);otome.
ation potential
is not impaired
lack limb
u ill
II~~ISCICS as
of muscle jwogenitors
although
their
lllllscles
exist
and
In any
(33].
express
genetic fail
myogenic
diffcrenti-
[39,X)].
studies
to cxj>rcsT
function
of.s~/0t~/I/,j!1;/15 double iLlvo1)
in the mvotome
ni~~sclcs but not the muscles cells ;Iction
in the absence of .jfyliD.
t!-j>c :irgues for RlyoI)
that
in heiid muscles
can
only
in precursors
which
form
and lack all hod) arise
double
Pax.3 i\ ~iii essential
I>>
niicc which
in the head [.il”].
the .sp/i&/.M,$.j
cxprcsbion
way. ‘1%~ analysis
of LjQfl.T
revcalcd
mut;lnt
As m~iscle through
mutnnt
upstream
of body
the
phcnoregulator
muscle
but not
in a /‘/lo.?-independent
p:ith-
of sp/~f&/,j{yf.T
mutants
gene that
is
are also de\ oid of I)od) coregulators
in neural
tissiics
must
th:it
ne\er
.jf.y~I).
Cooperation of MDFs with other transcription factors for muscle-specific gene activation Other
thali
scription
the
IzlyoD
Lictors.
family
imjwrt;rnt generate
proteins
Rll:I‘1 +2 domains.
present
scqllcnc‘c
cell linoagcs in
the
myogenesis
tltc
XII’lT1
cell diffcr-
genes
conser\ul
JlIS:! control
csscntial
[X-.37]
hind
regions
of
most
gcnc
for differentiation
cardiac
3s
consen-
I)-I\IE:f7
in
of all
of the h1EFX:
niirtation
and
impairs
which
LlAIX
jwotcins
sing:lc
‘I’hc
mouse
3150 play 3n
muscle
to an A-‘1’ rich I)NA
in
gcncs.
tran-
cnh;inccr
fwtors
during
the highly
homo- or hcterodimers
hHI,H
ni!ogcnic
ha\e foilr
containing
3djaccnt
the
ntusclc
the
of transcrij)tion
1.341. \‘crtclwtcs
gene
of
role in gcnc acti\2tion
cnti:ition
anJ
of myogcnic
nienibcrs
factor 2 (\11<1:2) family
morphogenrsis
and
[3X].
It is beliebed vatc
&it
also argiics
for
\1111:2 transcription
target genes
b>. bindinK
to their
site Ijut also by protcin-protein t~HI,II/El7
heterodiniers
co~~sensl~s
jm)l,al,l!
j>roteins
miisclc-specific
gene
xti\
of
their motifs.
1.191. ‘l’he
:ihility
j3rotcins
on two conser\ ed amino acitj rcsidiics
Rll)Fs
-
the
Ixxausc
corresponding
domain ders
thrconinc
xubstitution two
of nonmyogcnic
the
mutated
in
myogcnic
the
bHI,Ii
h;lsic
of these
asjwragincs
bH1,F-I
in this \~a)- still
and j>roniotc
factors
bind DNA,
myogencsis -
ala-
domains
of
t\\o rcsiducs
\vith
jwvznt
factors.
for
of m!-o-
i\ dependent and
and
In this comcofwtors
gcnic I>I~L,H nine
to initiate
E-box
rcspccti\c
:ict as csscntial
ation
niyogcnic
to the
hll
through
and Ilcterodimerization
plcx. hlI
with
3rc bolind
interaction
occurs
hetcrodimers
factors not onI>- actiown l)i’XA recognition
intcractiotis
u.hich
‘I’his
secjllencc.
l~l~I,li
of Pr/;ci ~2s
are not
to note that mouse
additional
case.
is no
directl)
mesodcrm
3 I)HI,I1
ptu.c”si.s.
jwttcrning.
3s Z’U.L? is also expressed
l)NA-binding :\ rcmarkablc
in somitic
lacking
.I!$.5
date, there of ,j!yoD
mutants
in\.ol\,ed in mcsoderm
gene.
becomes
cells that
to form limb rn~~sclcs. Among other severe defects.
.sp/~t& mice carrving from
bctor
in the embryo
mcsodcrm,
rcstrictcd
has been that the paired-box
dwclopment
to
the
regulatory
‘Ii)
In this context, it is intcrcsring
/h.w/~hi/~~ i\ absolutely
in the
tube
underscore
myogcnic
remains
An exciting
gcncs
pre-
be induced
can
ohscr\,ations
Pax3 controls
muscle-sj)ccific
key
of
cxprcssion.
and neural
naturally
unlikely.
sus
homcodomain
explants
,j/yf’.S
the I-‘c/.\;i-cxj>ressing rctrovirus.
striking
Pax3 is an upstream regulator of MyoD
the
in
mcsoderm
of 1’/1.\:~as 3 dominant
its mode of action
cithcr
recent discovery
using a
cxpres-
Lvith 50 kb proximal
has not
distinct
[Z7].
cur)-ing
the prwisc
correct spatiotcmpor3l
the mechanisms
in
jjlatc
ectopic
tissues
In this stud?; it is shown
maintains
cells which
it by infection
by
chick embryo
expression
and
and more general
in
to activate the gene in
be achicwd
Inusclc-formin:
in response
expression
\zhcrcar correct somitic
clcmcnts
the
located >.50 kb upstream
17X]_ Although
that
In
prcrursors
(l’A(:s)
arc ncccssq
can
promoter
cxtcnt,
,j!y~D
mcsoderni
Although
of ,llRZ*‘4
hlyf-ii
muscle
\vzu, demonstrated
cells of the limbs.
sion in myotomes
dri\w
facial
chromosomes
of the ,M,lf1.5 promotcr, muscle
in
to some
yeaat artifical
of.lfyj1.5.
-8 kb downstrum
region
only
complemented
clcments
observations).
regions
nicely
vector 1.3Z”].
f’/I.~.i induces
somitic
j3otcntial Littlc
;lrc
of /‘c/s.i in cultured csj3rcssion
express
in the mytome
distal
,\rnold, unjwblishcd
findings
expression retrovirus
expression
of ,bfRF4
‘l’hese
revcal,
lines
drives the correct fetal expression
early esprcssion
[%I.
transcrip-
whereas
and part of the early mytomal
‘1%~ comj+tc
tran-
by a proximal
and hlEF2
‘liansgenic
at all decelopmcntal fragment
of .jfRb‘4
to which
this
located in the
in .WRfq’4 regulation
in tissue
[25].
sites
iV~lscle-specific
properly
bind
that
expression
binding [21-23].
3rc also inwlvcd
i\ activated
promoter tion
and hlEF2
j3romotcr
541
in
the
IlaG
such as El 1, rcn-
inactibc. ii model
.tLs hlI>Fs suggchts
thnt
542
Differentiation and gene regulation
alaninc and thrconinc arc rcquircd for the myogenic bHLH factors to recruit an essential myogenic cofactor probably through adoption of a compatible conformation.
A recent study [40’] now provides evidence that the myogenie residues alanine and threonine in the basic domain of R;lyoD are required for synergistic activation of musclespecific transcription by MyoD and hlEF2 hut not for the interaction ,OU se. Obviously the hlyoD/MEF2 complex must acquire transcriptional competence through a mechanism that is dependent on the basic domain of hIpoD and complex formation is not sufficient. ‘I’he requirement to transmit the transcriptional activation signal within the complex can he bypassed through suhstitution of the MyoD or MEFZ activation domain with the constitutive activation domain of the herpes virus protein VP16. As the actual nature of signal transmission is not known, an intriguing possibility would he that yet another cofactor must be recruited into the complex. Indeed, it has been shown that the transcriptional adaptors p300 and CBP coactivatc the myogcnic hHLH proteins by physical interaction [41]. Stimulation of hlyoD’s transact&Con potential by p300 requires two domains of p300 and the transactivation domain of MyoD. Interestingly, p300 also interacts with the MADS domain of MEFZ proteins and potcntiates its transcriptional activation capability. hluscle LIkl protein (RILP) IS another potential coregulator of skeletal myogenesis which promotes myogenic differentiation [42]. A recent study shows that hlLP enhances the activity of MyoD and interacts with MDFs through the bHLH domain and the first I,IILl motif of MLP 1431. This interaction is specific for myogenic bHI,H transcription factors and does not occur with nonmuscle hHLH proteins, such as El2 or E47. Although the precise mechanism by which MLP enhances terminal differentiation is unknown, it may act by increasing the binding of myogenic hHLH proteins to specific DNA regulatory elements, as hlLP on its own lacks a transcription activation domain.
Negative regulators of muscle gene transcription Given the dominant myogenic functions of MDFs, it seems important to regulate their activity in order to prevent premature differentiation of myohlasts and ectopic development of muscles. Peptide growth factors, such as ‘I’GF-p, BhlPs, and FGFs, arc known to inhibit myogenesis by blocking the expression and transcriptional activity of myogenic factors. Stern total. [44] have shown that TGFpl and FGF may also collaborate to induce myogenesis in somites. Myostatin, a TGF-P-related factor which acts in an autocrinc fashion, was recently identified as a potential inhibitor of skeletal myogenesis [45]. A number of nuclear factors have also been implicated in the inhibitory role, most notably the Id (inhibitor of DNA
binding) HI,H proteins which lack the basic DNA-binding domain and act to sequester hHLH proteins into nonbinding complexes. Differential interactions of the four known Id proteins with hHLH transcription factors may contribute to their specific biological functions [40]. ‘I’he mouse hHLH protein twist was also found to inhibit hlDF activity by blocking DNA binding, by titrating E-proteins, and by interference with the transactivation of the hlyoD cofactor ILIEFZ [47,48].
Mistl,
a novel
hHLH
protein
that
accumulates
genie stem cells and decreases as myohlasts to myotuhes, also functions as a negative
in myo-
differentiate regulator of
RlyoD activity [49]. hlistl-induced inhibition of diffcrcntiation involves formation of inactive hlyoD-hlistl heterodimers and occupancy of E-box target sites b); Mist1 homodimers. Mist1 possesses no transcription activation domain hut a repressor region capable of inhibiting heterologous acti\,ators. I-mfa protein may he another factor which prevents inappropriate myogenesis. This protein is highly cxprcsscd in the sclerotome and in oitro inhibits transactikation b) hlyoD family members [SO]. I-mfa associates with hlyoD and retains it in the cytoplasm but it can also interfere with DNA binding of hlDFs. ZEB (zinc-finger/E-box binding), a vertebrate homolog of the Dm.sophil~ zinc finger/homeodomain protein zfh-1, constitutes a completely different type of negative regulator of muscle differentiation [Sl]. ZEB hinds to a subset of E-boxes in muscle genes and actively represses transcription until it becomes replaced by high concentrations of myogenic hHLH factors. This may provide a mechanism to regulate temporal order of muscle gene expression depending on the relative concentrations of ZEB and m);ogcnic hHLH proteins as well as on their affinities to various E-box target sites.
Conclusions During the past decade, myogencsis has become a paradigm for cell lineage determination and differentiation most importantly through the discolzry of the four myogenie hHLH transcription factors. ‘I’hc genetic approach of targeted gene disruptions for each mcmbcr of the farnil) and even more powerful double mutations in diffcrcnt pairs of the myogcnic hHLH genes ha\,e revealed unique and overlapping functions of these genes and placed them in a network of regulators in the myogcnic pathway. ‘l‘he important issue of whether the different phcnotypcs that result from inactivations of these genes reflect their disexpression patterns or specialized functions tinct associated with the different myogenic hHLH proteins has now been approached. The collective evidence from many experiments suggests that both the le\cls and possibly timing of expression and unique functional properties are important to properly execute muscle lineage determination and differentiation in the embryo. As an open topic for
Muscle
the future,
it remains
unclear
how precisely
these
factors
discriminate between the distinct sets of target genes that they must activate to promote cells through the different stages
important
topic
in the field has been
genie lineage commitment, a parallel pathway with hlyf-5 upstream of MyoD must also exist. A third myogenic pathway
independent
of both
hIyf-5
and
Pax3
appears
to
opcratc for head muscle formation. It will be interesting to see which factors trigger myogenic commitment and My011 gcnc activation there. It is also important to kno\f how precisely Pm? muscles and whcthcr
activates JZyoD expression in body Pa.? plays a role in 22!,if1.5regulation.
543
Patapoutian A, Yoon K, Miner H, Wang S, Stark K, Wold B: Disruption of the MRF4 gene identifies multiple waves of myogenesis in the myotome. Development 1995, 12:3347-3358.
10
Zhang W, Behringer RR, Olson EN: Inactivation of the myogenic bHLH gene MRF4 results in up-regulation of myogenin and rib anomalies. Genes Dev 1995, 9:1388-l 399.
11
Rawls A, Morris JH, Rudmcki M, Braun T, Arnold HH, Klein WH, Olson EN: Myogenin’s functions do not overlap with those of MyoD or My+5 during mouse embryogenesis. Dev Bioll995, 172:37-50.
12
Wang Y, Schnegelsberg P, Dausman J, Jaenisch R: Functional redundancy of muscle-specific transcription factors Myf5 and myogenin. Nature 1996, 379:823-825.
understand-
ing what regulates the myogenic bHLH genes to initiate Compelling genetic evidence argues that myogcnesis. Pm.? is an csscntial upstream regulator for ,t[sflD expression in body muscle precursors. Although Pax3 is the first example of 3 non-cell type-specific factor involved in myo-
Arnold and Winter
9.
of myogenesis.
Another
differentiation
Wang Y, Jaenisch R: Myogenin can substitute for Myf5 in promoting myogenesis but less efficiently. Development 1997, 124:2510-2513. The first knock-In expenment replacing one myogenic bHLH factor gene by another addresses the issue of unique intrinsic properties of Myf-5 and myogenin versus functlonal differences as a result of their distinct expression patterns. The results reveal that myogenin expressed under the control of the Myf-5 gene can partially substitute for Myf-5 but is unable to compensate for loss of a second myogenic bHLH gene in double mutants also lacking either MyoD or myogenin. This suggests that myogemn only inefficiently compensates for Myf-5, probably owing to altered levels of gene expression and/or different transactivation properties. 13 .
14. .
The detailed genie bHLH insights into
analysis of important interactions of myofactors and MEFZ proteins has provided mechanisms of cell-type-specific transcrip-
tion. Kesearch over continue to identify
the next few years will undoubtedly novel factors lvhich will either syner-
gize with or repress thcsc principal and thus refine our view of muscle
players in myogencsis cell differentiation.
Acknowledgements
Gerber AN, Kleseri TR, Bergstrom DA, Tapscott SJ: Two domains of MyoD mediate transcriptional activation of genes in repressive chromatin: a mechanism for lineage determination in myogenesis. Genes Dev 1997,11:436-450. This study provides evidence that MyoD and Myf-5 can remodel chromatin at binding sites In muscle gene enhancers and activate transcription at previously silent loci, whereas myogenin IS markedly less efficient at activating genes in transcriptionally silent chromatln. The ability of MyoD to activate endogenous genes IS associated with two regions in the protein that are distinct from its transactivation domaln and are conserved in the Myf-5 protein. TGF-P, basic FGF, and sodium butyrate - known inhibitors of myogenesls - block MyoD-mediated chromatin reorganization. These results may provide a molecular basts for the fact that MyoD and My+5 establish the myogenic lineage, whereas myogenin mediates terminal differentiation. 15.
References
and recommended
l
of special interest * of outstandlng Interest
1.
Arnold HH, Braun T: Targeted inactivation of myogenic factor genes reveals their roles during myogenesis: a review. Int Dev Biol 1996, 40:345-363.
2.
Molkentin JD, Olson EN: Defining the regulatory networks for muscle development. Curr Op;n Genet Dev 1996, 6:445-453.
3.
Yun KS, Wold BJ: Skeletal muscle determination and differentiation: story of a core regulatory network and its context. Curr Opin Cell Biol 1996, 8:877-889.
4.
5.
6.
7.
8.
during
early
16. .
reading
Papers of particular interest, published within the annual period of review, have been hIghlIghted as:
l
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