Tài liệu Báo cáo khoa học: Thermal unfolding of smooth muscle and nonmuscle tropomyosin a-homodimers with alternatively spliced exons docx

On the other hand, both DSC and CD stud-ies show that replacement of muscle exons 1a and 2a by nonmuscle exon 1b not only increases the thermal stability of the N-terminal part of Tm, bu

Thermal unfolding of smooth muscle and nonmuscle

tropomyosin a-homodimers with alternatively spliced

exons

Elena Kremneva1, Olga Nikolaeva2, Robin Maytum3*, Alexander M Arutyunyan2,

Sergei Yu Kleimenov1, Michael A Geeves3and Dmitrii I Levitsky1,2

1 A.N Bach Institute of Biochemistry, Russian Academy of Sciences, Moscow, Russia

2 A.N Belozersky Institute of Physico-Chemical Biology, Moscow State University, Russia

3 Department of Biosciences, University of Kent at Canterbury, UK

Tropomyosins (Tm) are a family of actin-binding,

a-helical coiled-coil proteins found in most eukaryotic

cells [1] They bind to actin cooperatively along the

length of actin filaments and confer cooperativity

upon the interaction of actin with myosin heads [2]

The Tm molecules are parallel homo- or

hetero-dimers (encoded from the same or different genes) of

two a-helical chains of identical length, although the

length can vary according to isoform type In

mam-malian cells, alternative splicing produces a variety

of muscle and nonmuscle isoforms from four differ-ent genes [1] Muscle cells express two major iso-forms of Tm (a and b), each containing 284 residues Smooth and skeletal muscles express differ-ent isoforms resulting from alternative splicing of the

a and b genes

There are two major classes of a-Tm: long (or high relative molecular mass) Tm (284 residues) are expressed in muscle and nonmuscle cells whereas short (or low relative molecular mass) Tm (247 residues) are

Keywords

tropomyosin; actin; thermal unfolding;

differential scanning calorimetry; circular

dichroism

Correspondence

D.I Levitsky, A.N Bach Institute of

Biochemistry, Russian Academy of

Sciences, Leninsky prosp 33,

119071 Moscow, Russia

Fax: +7095 9542732

E-mail: levitsky@inbi.ras.ru

*Present address

School of Biological Sciences, Queen Mary,

University of London, Mile End Road,

London E1 4NS, UK

(Received 14 September 2005, revised

2 December 2005, accepted 6 December

2005)

doi:10.1111/j.1742-4658.2005.05092.x

We used differential scanning calorimetry (DSC) and circular dichroism (CD) to investigate thermal unfolding of recombinant fibroblast isoforms

of a-tropomyosin (Tm) in comparison with that of smooth muscle Tm These two nonmuscle Tm isoforms 5a and 5b differ internally only by exons 6b⁄ 6a, and they both differ from smooth muscle Tm by the N-terminal exon 1b which replaces the muscle-specific exons 1a and 2a We show that the presence of exon 1b dramatically decreases the measurable calorimetric enthalpy of the thermal unfolding of Tm observed with DSC, although it has no influence on the a-helix content of Tm or on the end-to-end interaction between Tm dimers The results suggest that a significant part of the molecule of fibroblast Tm (but not smooth muscle Tm) unfolds noncooperatively, with the enthalpy no longer visible in the cooperative thermal transitions measured On the other hand, both DSC and CD stud-ies show that replacement of muscle exons 1a and 2a by nonmuscle exon 1b not only increases the thermal stability of the N-terminal part of Tm, but also significantly stabilizes Tm by shifting the major thermal transition

of Tm to higher temperature Replacement of exon 6b by exon 6a leads to additional increase in the a-Tm thermal stability Thus, our data show for the first time a significant difference in the thermal unfolding between muscle and nonmuscle a-Tm isoforms, and indicate that replacement of alternatively spliced exons alters the stability of the entire Tm molecule

Abbreviations

CD, circular dichroism; DSC, differential scanning calorimetry; Tm, tropomyosin; smTm, recombinant smooth muscle Tm; Tm5a and Tm5b, recombinant fibroblast Tm isoforms with alternatively spliced exons 6b and 6a, respectively.

found in nonmuscle cells [1,2] In the short a-Tm

iso-forms, a single exon (exon 1b, encoding residues 1–43)

replaces the first two exons (exons 1a and 2 encoding

residues 1–80) in long a-Tm (see Fig 1) The two other

alternatively spliced exons in a-Tm are exons 6 and 9

Possible relationships between the alternatively spliced

exons and the functional properties of the a-Tm

iso-forms have been addressed in previous studies The

actin binding properties are mainly determined by the

two terminal regions, encoded by exons 1 and 9 [3]

Amino acid replacements in the region encoded by

exon 2 of lobster muscle Tm altered end-to-end

inter-action between Tm molecules and actin affinity of Tm

[4] The replacement of muscle-specific exon 6b by

nonmuscle exon 6a in recombinant rat smooth muscle

a-Tm was shown to increase the actin affinity of a-Tm

[5], and the same exon exchange has a similar effect

between fibroblast Tm5a and 5b isoforms [6] This

replacement in rat fibroblast a-Tm has been shown to

increase the calcium sensitivity of the regulation of

acto-myosin interaction in the presence of troponin [7]

Our aim in the present study was to determine how

the alternatively spliced exons 1, 2, and 6 affect the

structural properties of the a-Tm molecule For this

purpose, we have used the smooth muscle a-Tm

(smTm) and the two a-Tm fibroblast isoforms Tm5a

and Tm5b, as shown in Fig 1 All of these a-Tm

iso-forms have a smooth muscle-like exon 9d Both of the

fibroblast isoforms are shorter than smTm because

they lack exon 2 due to replacement of muscle exons

1a and 2a by nonmuscle exon 1b The short fibroblast

isoforms Tm5a and Tm5b differ internally only by

exon 6 Confusingly, Tm5a has exon 6b, whereas

Tm5b possesses exon 6a (Fig 1) Thus, comparison of

Tm5a with smTm allows study of the effects of

replacement of muscle exons 1a and 2a by nonmuscle

exon 1b, and comparison of Tm5a with Tm5b allows

the effects of exchange of exon 6 to be studied

Studies of thermal unfolding of Tm may provide

valuable information on the structure of Tm both free

in solution and bound to actin Thermal unfolding of the Tm coiled-coil can be successfully studied by differ-ent methods such as CD, fluorescence, and DSC Many authors have used DSC for detailed investiga-tion of the thermal unfolding of Tm from skeletal and smooth muscles [8–14] Other authors successfully used

CD to study the thermal unfolding of homo- and het-erodimers of skeletal [15,16] and smooth [17–19] muscle Tm, their mutants [20–23], and numerous coiled-coil model peptides corresponding to the N- and C-terminal parts of the Tm molecule [24–29] CD measures whole the process of the unfolding of a-helical coiled-coil of Tm, whereas DSC generally gives reliable information only on the thermal unfolding of those parts of Tm which melt cooperatively with significant changes in enthalpy On the other hand, DSC is capable

of monitoring the thermal unfolding of Tm when bound to actin [13,14,30], whereas CD is of limited use

in the presence of actin as the signal from the six- or sevenfold molar excess of actin dominates the signal Fluorescent labels can also be used in the presence of actin but may report only the local unfolding of regions close to the label Thus, each method has strong and weak sides, but combination of both the DSC and CD provides a powerful approach for structural characteri-zation of Tm and its interaction with actin

In this work we have used DSC and CD to character-ize the thermal unfolding of smTm, Tm5a, and Tm 5b

We have shown that exon replacements alter the stabil-ity of the entire Tm molecule The replacement of mus-cle exons 1a and 2a in smTm by nonmusmus-cle exon 1b

in Tm5a (and Tm5b) dramatically decreases the total measurable calorimetric enthalpy of the thermal unfold-ing of Tm, although it has no influence on the a-helix content of Tm and on end-to-end interaction between

Tm dimers On the other hand, this replacement signifi-cantly stabilizes Tm, increasing the temperature of the cooperative thermal transitions of Tm Replacement of exon 6b in Tm5a by exon 6a in Tm5b leads to addi-tional increase in the thermal stability of Tm

Results

Thermal unfolding of recombinant Tm: DSC studies

The excess heat capacity curves obtained for recombin-ant smTm, Tm5a, and Tm5b are presented in Fig 2 Judging by the complete reproducibility of the calori-metric traces after cooling the sample within the DSC cell, the heat-induced unfolding of Tm was fully reversible For both fibroblast Tms the major trans-ition takes place at a higher temperature than for

Fig 1 Exon structure of smooth muscle a-Tm and the two

fibro-blast isoforms Tm5a and Tm5b with constitutive exons are shown

in white, smooth muscle exons in light grey, and nonmuscle exons

in dark grey.

smTm (Tm¼ 34.6
C), by
5
C for Tm5a (Tm¼

39.3
C) and by
8
C for Tm5b (Tm¼ 42.7
C)

Surprisingly, the calorimetric enthalpy, DHcal, of the

thermal unfolding of both Tm5a and Tm5b was much

less than that for smTm, and it represented only

60% of the DHcalvalue for smTm (Table 1)

Another difference between Tm5a, Tm5b and smTm

is that both fibroblast Tm isoforms possess, in addition

to the major sharp thermal transition and the shoulder

at 25–35
C, a broad low-cooperative transition at 55–

65
C (Fig 2) It is important to note that it was

diffi-cult to reveal this broad high-temperature transition in

our apparatus as it was small and difficult to

distin-guish from the instrumental baseline Therefore we

used a specially developed method to avoid artefacts

caused by subtraction of the instrumental baseline (see

Experimental procedures) The heat capacity curves

obtained in this way were subjected to deconvolution

analysis (Fig 3), which shows that the profiles can be

decomposed into three separate thermal transitions (calorimetric domains)

The first, the low-temperature transition at
33
C (Fig 3) represents 15–20% of the total calorimetric enthalpy (Table 1) The second transition, which repre-sents more than 60% of the total enthalpy, is similar

in enthalpy but more stable in Tm5b (Tm¼ 42.7
C) than in Tm5a (Tm¼ 39.3
C) The third transition again represents
20% of the total enthalpy, and it is very similar for Tm5a and Tm5b (Tm
57.5
C) (Fig 3, Table 1) Since the only major difference between the two Tms is in transition 2 this is likely to represent the unfolding of the region of Tm containing the alternately spliced exon 6

The heat capacity curve for smTm also reveals three transitions However, the first and third transitions are broader and are not as clearly resolved from the second, main transition SmTm and Tm5a are identical in struc-ture except for the alternative exons 1 and 2 therefore differences in the unfolding thermogram should reflect the role of these exons in thermal stability As seen from Table 1 all three transitions for smTm are at a lower temperature than for Tm5a (by 2, 4.7, and 18.4
C, respectively) while the total enthalpy of smTm unfolding

is 1.6 times that of Tm5a Note however, that the parti-tion of the total enthalpy between the three transiparti-tions remains at approximately 20, 60, and 20%, respectively The major difference between the thermal unfolding

of smTm and Tm5a is on the Tm of the third trans-ition which is destabilized by almost 20
C It is there-fore most likely to reflect the N-terminal part of the molecule dominated by the exchange of exon 1b for exons 1a and 2a However all three calorimetric domains are destabilized by the exon change and the total enthalpy is increased This suggests that the N-terminal part of the molecule is affecting the stabil-ity of the entire molecule

End-to-end interaction One possible reason for the differences in the thermal stability between smTm and Tm5a is that it is related

Fig 2 Temperature dependence of the excess heat capacity (Cp)

of smTm, Tm5a, and Tm5b The protein concentration was

1.2 mgÆmL)1 Other conditions: 30 m M Hepes pH 7.3, 100 m M KCl,

and 1 m M MgCl2 The heating rate was 1 KÆmin)1.

Table 1 Calorimetric parameters obtained from the DSC data for individual thermal transitions (calorimetric domains) of smTm, Tm5a, and Tm5b The parameters were extracted from Fig 3 The error of the given values of transition temperature (T m ) did not exceed ± 0.2
C The relative error of the given values of calorimetric enthalpy, DHcal, did not exceed ± 8%.

Sample

Transition 1 Transition 2 Transition 3

Total DH (kJÆmol)1)

DH (kJÆmol)1) T m (
C) DH (kJÆmol)1) T m (
C) DH (kJÆmol)1) T m (
C)

smTm 150 30.9 515 34.6 125 39.0 790 Tm5a 100 32.9 310 39.3 85 57.4 495 Tm5b 75 33.5 300 42.7 110 57.9 485

to different end-to-end interactions of the Tm species.

Indeed, Tm5a not only differs from smTm by the

sequence encoded by the N-terminal exon 1 (Fig 1),

but also because the recombinant smTm was expressed

with an N-terminal Ala-Ser extension to substitute for

the N-terminal acetylation of the native Tm [31] The

fibroblast Tm5a (and Tm5b) has a natural five-amino

acid extension in exon 1b (Ala-Gly-Ser-Ser-Ser) in

comparison to exon 1a [6,7,32] These differences in

the sequence might affect end-to-end interaction

between Tm dimers and could influence the observed

enthalpy of the thermal unfolding

The strength of the end-to-end interaction between

Tm dimers can be estimated by viscometry, and the

interaction is known to be highly sensitive to ionic

strength [17,33] We measured the viscosity and

calori-metric enthalpy (total DHcal) of smTm and Tm5a at dif-ferent ionic strengths as shown in Fig 4 The relative viscosity of Tm5a was very similar to that of smTm at all ionic strengths (Fig 4A) At 500 mm KCl the visco-sity was similar to that of water consistent with the absence of any significant polymerization of Tm Over the range of ionic strengths studied, the DHcalvalue for Tm5a was consistently smaller by 40–50% than that of smTm (Fig 4B) This means that end-to-end inter-actions of Tm play little role in the difference in the calorimetric enthalpy between smTm and fibroblast Tm5a

Thermal unfolding of recombinant Tm: CD studies

The CD spectra of smTm, Tm5a, and Tm5b, which are shown in Fig 5, possessed the double minima at

208 and 222 nm characteristic of the correctly folded, fully a-helical structure of Tm The CD spectra of Tm5a and Tm5b were virtually identical to each other and to the spectrum of smTm

Fig 3 Deconvolution analysis of the heat sorption curves of smTm

(A), Tm5a (B), and Tm5b (C) Conditions were the same as in

Fig 2 Solid lines represent the experimental curves after

subtrac-tion of instrumental and chemical baselines, and dotted lines

repre-sent the individual thermal transitions (calorimetric domains)

obtained from fitting the data to the nontwo-state model.

Fig 4 Effects of ionic strength on the relative viscosity (A) and calorimetric enthalpy DHcal (B) of smTm and Tm5a The concen-tration of Tm was 0.5 mgÆmL)1 in viscosity experiments and 1.2 mgÆmL)1in DSC experiments.

The thermal unfolding of the a-helix in smTm,

Tm5a, and Tm5b was measured by the temperature

dependence of the CD elipticity at 222 nm (Fig 6)

These CD studies were performed under similar

condi-tions and at the same heating rate (1
CÆmin)1) as the

DSC measurements except that lower protein

concen-tration (0.1 mgÆmL)1) and sodium phosphate buffer

was used instead of Hepes However, the buffer

replacement had no significant influence on the

ther-mal unfolding of any Tm measured by DSC (data not

shown) Melting was fully reversible with a repeated

melting curve being identical to the initial ones The

helix unfolding profile of recombinant smTm (Fig 6A)

agrees with previous CD studies of the native

aa-homo-dimers of smooth muscle Tm [18,19] The transition

midpoint for smTm (
34
C) is similar to the

max-imum temperature (Tm¼ 34.6
C) of the heat capacity

curve measured by DSC under similar conditions

(Fig 2)

The CD melting curve of Tm5a and 5b are similar

and differ significantly from that for smTm, having

broader (lower cooperativity) changes in ellipticity

(Fig 6A) The first derivative of the data, dh⁄ dt, shows

three well distinguished peaks on the profile of Tm5a

(Fig 6B), with the major peak at 39.6
C and two

small peaks at
30
C and
50
C similar to those

observed in DSC The CD melting profile of Tm5b

also shows, like Tm5a, significant changes in ellipticity

long before and well after the major peak at 41.2
C

(Fig 6B) In general, these CD data are in very good

agreement with DSC results presented above (Figs 2

and 3) Both DSC and CD show that the magnitude

of the main thermal transition is much higher for smTm than for Tm5a and Tm5b Thus, both methods show a marked difference in the thermal unfolding between smooth and nonmuscle Tms

DSC studies of the thermal unfolding of Tm

in the presence of F-actin Previous studies have shown that DSC can be success-fully used for studies of the actin-induced changes in the thermal unfolding of Tm [13,14,30] Interaction of smooth muscle Tm with F-actin caused a 2–6
C shift

in the Tm thermal transition to higher temperature, depending on the Tm : actin molar ratio [13] In the present work, we apply this approach to characterize the thermal unfolding of smTm, Tm5a, and Tm5b complexed with F-actin

DSC experiments with Tm–F-actin complexes were performed in the presence of excess of Tm, i.e under conditions where actin filaments should be fully satur-ated with Tm molecules The character of the thermal

Fig 5 CD spectra in the far-UV region of smTm, Tm5a, and Tm5b.

The spectra were measured at 20
C Protein concentration was

0.1 mgÆmL)1in all cases Other conditions: 50 m M sodium

phos-phate buffer pH 7.3 containing 100 m M NaCl and 1 m M MgCl2.

Fig 6 The thermal unfolding profiles of smTm, Tm5a, and Tm5b

as measured by CD (A) The temperature dependence of a-helix content measured as the ellipticity at 222 nm The heating rate was 1 KÆmin)1 The protein concentration was 0.1 mgÆmL)1in all cases The heating rate was 1 KÆmin)1 Other conditions: 50 m M

sodium phosphate buffer pH 7.3 containing 100 m M NaCl, 1 m M

MgCl 2 and 1 m M b-mercaptoethanol (B) First derivative profiles for the data shown in (A).

denaturation of Tm was noticeably changed when

bound to F-actin This is reflected in the appearance

of a new highly cooperative thermal transition at

higher temperature (Fig 7) The interaction of Tm

with actin had no effect on the thermal denaturation

of F-actin stabilized by phalloidin, which denatures

irreversibly at much higher temperature (80
C), as

was previously shown for smooth and skeletal muscle

Tms [13,14] Thus, after heating of the Tm–F-actin

complex to 90
C (i.e after complete irreversible

dena-turation of actin) and subsequent cooling, only the

peaks corresponding to the thermal denaturation of

free Tm were observed during a second heating

(dashed line curves on Fig 7) Thus, we conclude that

the appearance, in the presence of F-actin, of new

peak at higher temperature reflects the actin-induced changes in the thermal unfolding of Tm This peak on Fig 7 is named as peak 2, whereas the peak named as peak 1 corresponds to the thermal unfolding of non-actin-bound Tm in the presence of F-actin, and peak 3 corresponds to the thermal unfolding of free Tm dur-ing re-heatdur-ing after complete irreversible denaturation

of actin It should be noted that in this case we did not analyse the small thermal transitions of Tm5a and Tm5b at
57.5
C (Figs 2 and 3), because irreversible thermal denaturation of F-actin began in this temper-ature range

In the case of smTm, the actin-induced shift in the thermal transition (i.e the difference in Tm between peak 2 and peak 3) was equal to 3.8
C, while this effect was less pronounced for Tm5a (T2) T3¼ 3
C) and Tm5b (T2) T3¼ 1.4
C) (Table 2) However, it is clearly seen on Fig 7 that the actin-induced increase in the enthalpy of thermal unfolding of Tm5a and Tm5b

is more pronounced than for smTm Indeed the enthalpy of the actin-induced peak 2 (DH2) for Tm5a

is now almost exactly six-sevenths of the value for smTm consistent with similar enthalpy of unfolding per unit length To calculate the actin-induced increase

in enthalpy we measured the enthalpy of the actin-induced peak 2 (DH2) and determined the difference between DH2 and the enthalpy of free Tm (DH3) with the enthalpy of peak 1 subtracted (DH3) DH1) (Table 2) (It is noteworthy that in the absence of actin the enthalpy of reversible unfolding of Tm did not sig-nificantly change even after heating to 90
C) As a result, interaction with F-actin increased the enthalpy

of the thermal unfolding by 220–240 kJÆmol)1 for

Fig 7 Thermal denaturation of smTm (A), Tm5a (B), and Tm5b (C)

complexed with phalloidin-stabilized F-actin A temperature region

above 55
C corresponding to irreversible thermal denaturation of

F-actin stabilized by phalloidin is not shown Accordingly, small

ther-mal transitions of Tm5a and Tm5b at
57.5
C were not analysed

in this case Curves shown by dashed lines (peak 3) were obtained

by reheating the same samples after the first heating to 90
C and

following cooling to 5
C The heating rate was 1 KÆmin)1 The

peaks 1, 2, and 3 are described in the text In C peak 1 is

highligh-ted as a dothighligh-ted line showing the curve fit Concentration of Tm

was 10 l M for smTm and 15 l M for Tm5a and Tm5b Other

condi-tions: 46 l M F-actin, 70 l M phalloidin, 30 m M Hepes, pH 7.3,

100 m M KCl, 1 m M MgCl 2 , and 1 m M b-mercaptoethanol.

Table 2 Parameters of the thermal transitions observed by DSC for smTm, Tm5a, and Tm5b in the presence of F-actin and of heat-induced dissociation of the Tm–F-actin complexes The calorimetric parameters, T m and DH cal , were extracted from Fig 7 The parame-ters T 1 , T 2 , T 3 , DH 1 , DH 2 , and DH 3 correspond to peaks 1, 2, and 3 described in the text Concentration of Tm was 10 l M for smTm and 15 l M for Tm5a and Tm5b; concentration of phalloidin-stabil-ized F-actin was 46 l M The error of the T m values did not exceed ± 0.2
C The relative error of the DH cal values did not exceed ± 10% The values of Tdisswere calculated from light-scat-tering data presented in Fig 8 The error of the T diss values did not exceed ± 0.2
C.

Sample

Tdiss (
C)

Tm(
C) DHcal(kJÆmol)1)

T 1 T 2 T 3 DH 1 DH 2 DH 3 DH 2 –(DH 3 –DH 1 ) smTm 38.5 33.8 38.3 34.5 120 685 680 125

Tm5a 43.2 38.7 43 40 65 575 400 240 Tm5b 43.9 40.3 44.4 43 60 530 370 220

Tm5a and Tm5b, and by only 125 kJÆmol)1 for smTm

(Table 2)

Thermally induced dissociation of Tm–F-actin

complexes

Previous studies have shown that Tm dissociates

from F-actin on heating, and this process can be

studied by light scattering measurements [13,14,34]

To examine the thermal dissociation of the Tm–

F-actin complexes, we measured the temperature

dependence of light scattering for the complexes of

phalloidin-stabilized F-actin with smTm, Tm5a, and

Tm5b These measurements were performed under

conditions identical to those of the DSC experiments

presented in Fig 7 When heated below the

denatur-ation temperature of actin under these conditions,

dissociation of the Tm–F-actin complexes was

revers-ible, as the light scattering intensity increased during

cooling after the first heating and decreased again

during the second heating The fitted curves to the

normalized light scattering changes of dissociation of

the Tm–F-actin complexes are shown in Fig 8 The

temperature of midpoint of dissociation (Tdiss), i.e

the temperature at which a 50% decrease in light

scattering occurs, are presented in Table 2 and com-pared with the maximum temperature of the actin-induced transition 2 (T2) for the same samples studied by DSC This comparison shows a very good correlation between the Tdiss and T2 (Table 2) We therefore conclude that actin-induced changes in the thermal denaturation of Tm (i.e the appearance of the actin-induced peak 2) are associated with dissoci-ation of Tm from F-actin This confirms the DSC data showing that both fibroblast Tms, Tm5a and Tm5b, dissociate from F-actin at higher temperature (Tdiss
43.5
C) than smTm (Tdiss¼ 38.5
C)

Discussion

In the present work we applied DSC combined with

CD to characterize the thermal unfolding of recombin-ant fibroblast Tms, Tm5a and Tm5b, in comparison with that for smooth muscle Tm The thermal unfold-ing of smooth muscle Tm isoforms has been investi-gated in detail by DSC [11–13] and by CD [17–19] and the results presented here agree with these earlier works Thus, smTm expressed with the addition of Ala-Ser to the N-terminus is a good mimic of native acetylated Tm

The thermal unfolding of nonmuscle fibroblast Tms has not been studied by DSC before The two a-Tm fibroblast isoforms Tm5a and 5b are identical in seven

of their eight exons and differ internally only by exon

6 (Fig 1) The short 25-residue sequences encoded by exons 6b and 6a do not differ in stabilizing or destabil-izing clusters defined by Hodges and coworkers in the hydrophobic core [35–37], both containing only one stabilizing cluster of five residues However, sequence analysis of exon 6 using coiled-coil prediction software [38] suggests that the coiled-coil propensity of exon 6b (Tm5a) is lower than that of exon 6a (Tm5b) [7] The DSC data presented are consistent with this prediction, showing that the replacement of exon 6b in Tm5a by exon 6a in Tm5b increases the thermal stability of the major thermal transition by 3.4
C In contrast the exon swap has no appreciable influences on the a-helix content at 20
C (Fig 5) and on the total calorimetric enthalpy of the thermal unfolding (Table 1) Previous

CD studies also showed an increased thermal stability

of a recombinant smooth muscle a-Tm with exon 6b replaced by exon 6a [5,39]

Previous studies of thermal unfolding of skeletal Tm have allowed assignment of the thermal transitions to specific regions of Tm for skeletal a-Tm [8,9,14] Ther-mal unfolding of smTm (Fig 3A) is quite different from that of skeletal Tm measured by DSC under the same conditions, skeletal Tm has for example two

Fig 8 Normalized temperature dependence of dissociation of the

F-actin complexes with smTm, Tm5a, and Tm5b 100%

corres-ponds to the difference between light scattering of the Tm–F-actin

complexes measured at 25
C and that of pure F-actin stabilized by

phalloidin which was temperature independent within the

temper-ature range used A decrease in the light-scattering intensity

reflects dissociation of the Tm–F-actin complexes Conditions were

the same as for DSC experiments presented in Fig 7 The heating

rate was 1 KÆmin)1.

thermal unfolding transitions of similar enthalpy

compared to one major and two minor transitions

observed for smTm [14] The less stable of the two

thermal transitions for skeletal Tm has been assigned

to the C-terminal part of the molecule but the

C-ter-minal region of the two Tms differ at exon 9 (and at

the N-terminal exons 1 and 2) Thus comparison

between skeletal and smTm isoforms does not allow

the assignment of the transitions of smTm

Comparison between the three Tm molecules studied

here can allow assignment of the three thermal

trans-itions observed to specific regions of the Tm The

observation that only the main thermal transition is

affected by exon 6 in Tm5a and 5b suggests that

trans-ition 2 represents the central part of the Tm including

exon 6 Note however, that the enthalpy of transition

2 is almost identical for Tm 5a and 5b Transition 3 is

stabilized by almost 20
C when the N terminal exons

1a and 2a of smTm are replaced by exon 1b in the

fibroblast Tm suggesting that transition 3 represents

unfolding of the N-terminal part of the Tm In support

of this are the CD data on model peptides showing

that the peptide mimicking exon 1b is much more

ther-mostable than the peptide corresponding to exon 1a

[26,27,29] Transition 1 is the least stable of the

ther-mal transitions and is similar in all three Tms

There-fore this transition cannot be unambiguously assigned

It might correspond to the C-terminal part of Tm In

favour of this assumption are the CD data showing

that model peptides corresponding to the C-terminal

exon 9d are much less thermostable than the

N-ter-minal peptides [29] In contrast, however, the data of

Paulucci et al [40] show that the C terminus of Tm (in

particular the last 24 residues) is crucial for the

stabil-ity of Tm The increased thermal stabilstabil-ity of transition

3 in Tm5a and Tm5b in comparison with smTm can

be explained in part by recently proposed theory of

Hodges and coworkers [35–37] that the thermal

stabil-ity of a-helical coiled-coil depends on the presence of

stabilizing and destabilizing clusters in its hydrophobic

core They defined these clusters as three or more

con-secutive core-forming a and d residues in a heptad

repeat motif (abcdefg)n of either stabilizing (Leu, Ile,

Val, Met, Phe, and Tyr) or destabilizing (the remaining

13 amino acids) residues, and postulated the presence

of very long destabilizing cluster (seven residues) in the

hydrophobic core of N-terminal part of muscle Tm

encoded by exons 1a and 2a [37] The sequence of

fibroblast Tm5a [41], being analysed in the same way,

contained only a short destabilizing cluster (just three

residues) in the hydrophobic core of the N-terminal

region encoded by exon 1b The shortening of the

destabilizing cluster from seven to three residues might

stabilize the transition 3 assigned to the N-terminal part of the Tm

SmTm is
15% larger than the fibroblast Tm (due

to inclusion of exon 2) and according to the CD spec-tra the helical content of the two proteins appears sim-ilar at 20
C Therefore the simple prediction is that the two proteins should have a similar enthalpy of unfolding (differing by 15% at most), yet the data in Table 1 shows that the total energy of unfolding of SmTm is 1.6-fold larger than that of Tm5a The pro-portion of the total enthalpy in the three domains of each is very similar at 20 : 60 : 20, so this increase in enthalpy is not simply due to the change in the stabil-ity of the N-terminal part of the molecule, but a change in the observed enthalpy of the whole mole-cule

There are two possible explanations for the increased enthalpy in smTm compared to Tm5a, either the addition of exon 2 influences enthalpy of the whole molecule or there is some ‘unseen’ enthalpy in the Tm5a

Evidence that specific regions of Tm can have long-range effects on the stability of the whole molecule have been reported previously [40,42,43] A recent study by Singh and Hitchcock-DeGregori [22] has shown that mutations in a region at the C-terminal end of exon 2b in a-Tm2 (identical to smTm except exon 2b vs 2a) can cause a change in the melting pro-file of several unfolding transitions The mutations which caused either an increase or decrease in mid-point of the melting transition could both result in

an apparent major decrease in total enthalpy of un-folding

‘Unseen’ enthalpy may be the consequence of broad noncooperative unfolding of parts of the molecule, giv-ing a very slight slope to the heat capacity curve This proceeds over a broad temperature range and can be difficult to precisely measure by DSC Noncooperative melting was earlier observed by DSC for some muscle proteins (e.g troponin T, troponin I [30], and calponin [44]), which did not exhibit any detectable thermal transitions upon heating up to 100
C

The assumption that noncooperative unfolding takes place for some parts of nonmuscle Tm is corroborated

by our DSC studies on the complexes of Tm with F-actin Interaction with F-actin significantly increases the thermal stability and unfolding enthalpy of Tm, and reduces the difference in total enthalpy seen between smTm and nonmuscle Tm isoforms 5a and 5b (Fig 7, Table 2) In particular the enthalpy of peak 2 for Tm 5a, corresponding to the actin-bound Tm, is almost exactly six-sevenths of that of smTm as predic-ted on a simple size comparison This suggests that the

stabilizing of Tm on actin results in almost all of the

unfolding occurring as a single cooperative process

simultaneous with dissociation from actin It was

con-cluded from our previous studies that F-actin prevents

the actin-bound Tm from thermal denaturation, which

only occurs upon dissociation of Tm from F-actin

[14,45] As a result, Tm unfolds at higher temperature

and with much higher cooperativity This allows the

‘lost’ enthalpy of parts which unfold noncooperatively

at temperatures below Tdiss in the absence of actin, to

be ‘recovered’ in the highly cooperative dissociation

transition It is possible that smTm also has some ‘lost’

enthalpy, but it is likely to be much less than in

non-muscle Tm isoforms, which demonstrate in the

pres-ence of F-actin much more pronounced ‘recovery’ of

enthalpy (by 70%) than smTm (by only 20%)

(Table 2)

The recent CD and DSC data of Dragan and

Priv-alov on the thermal unfolding of a leucine zipper

which, like Tm, is an a-helical, double-stranded

coiled-coil [46] support noncooperative transitions in

the unfolding pathway These authors showed that

the initial almost linear change of leucine zipper

ellip-ticity prior to the sigmoidal change (that is very

sim-ilar to those of Tms in Fig 6A) cannot be regarded

as a trivial optical effect but is associated with some

temperature-induced conformational changes of the

dimeric molecule from the very beginning of its

heat-ing They concluded, that the enthalpy of cooperative

unfolding that is associated with dissociation of the

two strands and is observed as a cooperative thermal

transition by DSC, does not represent the full

enthalpy of unfolding of the molecule The full

enthalpy also includes the enthalpy of all

predissocia-tion changes, which comprises almost 40% of the

total enthalpy These temperature-induced changes in

protein structure, that occur before the cooperative

separation of strands, are believed to be associated

with some rearrangements in the coiled-coil, and they

are highly sensitive to modifications of the N

termi-nus [46] It seems possible that somewhat similar

structural changes may also occur in nonmuscle Tm

isoforms due to replacement of the N-terminal muscle

exon 1a by nonmuscle exon 1b

The noncooperative unfolding of a significant part of

the nonmuscle Tm molecule may suggest that this part

(or these parts) of the molecule becomes more flexible

due to replacement of the N-terminal muscle exons 1a

and 2a by nonmuscle exon 1b Higher flexibility may

affect actin-binding (since Tm must match the actin

periodicity to bind effectively and flexibility may be

important in the ability of Tm to change position on the

actin surface [22,47,48]) This could explain in part why

the replacement of exon 1a by exon 1b strongly increases the affinity of Tm for actin [3] despite having little effect

on Tm end-to-end interactions as shown by the Tm polymerization measured by viscosity (Fig 4A)

In conclusion, the data presented here comparing the three tropomyosins is compatible with previous reports that suggest there is no simple correlation between specific ‘domains’ of Tm and the overall stability of the molecule but there are long-range cooperative effects

on structure Furthermore, in some cases local confor-mation changes and unfolding occur as low enthalpy noncooperative transitions that are not easily detected

by DSC This missing enthalpy becomes apparent when the Tm dissociates from actin and unfolds as a single highly cooperative process Understanding the nature and location of the noncooperative unfolding regions will be important to understand the way in which the exons changes affect the stability of remote unfolding domains In the future, definitive identification of specific regions of Tm with particular unfolding transi-tions could be facilitated by the use of labels to report local unfolding events

Experimental procedures

DNA constructs

Clones of rat fibroblast tropomyosins 5a and 5b were amplified from PET8c (gift from M Gimona and D Helf-man) using PCR primers designed to introduce NdeI and BamHI restriction sites for cloning into pJC20 The sequences for the primers used were 5¢-GGAATTCCA

primer) and 5¢-CGCGGATCCTCACATGTTGTTTAGCT CCAGTAAAG-3¢ (3¢-reverse primer) Identical primers were used for TPM5a and TPM5b as they differ only by an internal alternatively spliced exon 6 (see Fig 1) The smooth muscle clone was amplified from a full-length clone which also contained the 5¢ UTR in pGem4 (gift from

C Smith, Cambridge), using PCR primers again designed to produce NdeI and BamHI restriction sites The 5¢ forward primer also introduced bases coding for a three amino acid Met-Ala-Ser N-terminal extension to substitute for the lack

of N-terminal acetylation The sequence for the N-terminal 5¢ forward primer was 5¢-GGAATTCCATATGGCGAGC ATGGACGCCATCAAGAAGAAGATGC-3¢ As smTm uses the same C-terminal exon 9d as Tm5a and Tm5b, the same 3¢ reverse primer was used The ligated plasmids were transformed into Escherichia coli XL-1 Blue for plasmid replication The entire coding regions of the constructs were verified by automatic DNA sequencing on Applied Biosystems 373A sequencer (Applied Biosystems, Foster City, CA, USA) using a dye-based PCR sequencing reaction

Expression and purification of recombinant

tropomyosins

For expression, all the clones were transformed in the

BL-21 DE3 (pLys) cells and expressed and purified as

pre-viously described [7,49] with some modifications In brief,

1-L cultures were grown to late-exponential phase and

induced overnight with 0.4 mm

isopropyl-1-thio-b-d-gal-actopyranoside Cells were harvested, resuspended in

60 mL lysis buffer (20 mm Tris pH 7.0, 150 mm NaCl,

5 mm EDTA, 5 mm MgCl2), and lysed by sonication (two

2-min pulses separated by 1-min rest phase) The majority

of E coli proteins were precipitated by heating to 80
C for

10 min, and the precipitated protein and cell debris were

removed by centrifugation Then solution was incubated

with 5 mgÆL)1DNase and 10 mgÆL)1RNase for 1.5 h The

soluble Tm was then isoelectrically precipitated at pH 4.5

using 0.3 m HCl The precipitate was pelleted and

resus-pended in 10 mL running buffer (5 mm potassium

phos-phate pH 7.0, 100 mm NaCl) This was then further

purified using a 5 mL Hi-trap Q column (Amersham) and

eluted with a 200–500 mm NaCl gradient, with the Tm

elut-ing at 250–450 mm salt Fractions were analysed by

SDS⁄ PAGE [50], pooled, and concentrated by isoelectric

precipitation Extinction coefficients for recombinant

pro-teins were calculated from the sequences using the software

antheprot (G Deleage, IBCP-CNRS) Protein

concen-trations were estimated using extinction coefficients E1%at

280 nm of 1.41 cm)1for smTm and 1.61 cm)1for fibroblast

Tm 5a⁄ 5b, and molecular masses of 32834.8, 28557.9, and

28697.2 Da for smTm, Tm5a, and Tm5b, respectively

Protein molecular masses were determined by

electro-spray mass spectrometry to confirm that the expressed Tms

had the correct size Small (50 lL) stock samples were

dia-lysed overnight against 30 mm Hepes pH 7.3 containing

100 mm KCl and 1 mm MgCl2, and applied to a Finnegan

Mat LCQ ion-trap mass spectrometer fitted with a

nano-spray device Predicted molecular masses for proteins were

calculated using the AnTheProt with Delta Mass (ABRF)

used to determine mass differences among the Tm species

Relative molecular masses determined by MS for smTm,

Tm5a, and Tm5b were in good correspondence with the

predicted masses

Before experiments, all Tm samples were incubated with

20 mm b-mercaptoethanol at 60
C for 60 min Such

treat-ment results in Tm species in completely reduced state [14]

To maintain the reduced Tm species, 1 mm

b-mercapto-ethanol was added to the samples

Preparation of actin

Rabbit actin was prepared by the method of Spudich and

Watt [51] Its molar concentration was determined by its

absorbance at 290 nm using an E1% of 6.3 cm)1 and a

molecular mass of 42 kDa F-actin polymerized by the

addition of 4 mm MgCl2and 100 mm KCl was further sta-bilized by the addition of a 1.5-fold molar excess of phalloi-din (Sigma)

Viscosity measurements

Measurements were carried out at 18.5
C using an Ostow-ald type capillary viscosimeter (Institute for Biological Instrumentation, Puschino, Russia), with a buffer outflow time of 27.6 s Before measurements, proteins (0.5 mgÆmL)1) were dialysed against 30 mm Hepes pH 7.3 containing

100 mm KCl and 1 mm MgCl2

Differential scanning calorimetry

DSC experiments were performed on a DASM-4 m differ-ential scanning microcalorimeter (Institute for Biological Instrumentation, Pushchino, Russia) as described earlier [12–14,30] All measurements were carried out at a scanning rate of 1 KÆmin)1in either 30 mm Hepes, pH 7.3, or 50 mm sodium phosphate, pH 7.3, both containing 100 mm KCl and 1 mm MgCl2 The solution also contained 1 mm b-mercaptoethanol to prevent disulfide cross-linking between the chains in the Tm homodimers In the case of Tm– F-actin complexes, the final concentration of F-actin was

46 lm F-actin was stabilized by the addition of a 1.5-fold molar excess of phalloidin (Sigma) to obtain a better separ-ation of the thermal transitions of actin-bound Tm and F-actin [13,14] The reversibility of the thermal transitions was assessed by reheating of the sample immediately after cooling from the previous scan The calorimetric traces were corrected for the instrumental background by sub-tracting a scan with buffer in both cells In some cases, to reveal small and low-cooperative thermal transitions in Tm5a and Tm5b, a special DSC approach was applied as follows DSC measurements were performed not only by usual way, when the protein was placed into the sample cell and the buffer was placed into the reference cell, but also vice versa, with the same protein in the reference cell and the buffer in the sample cell As a result, in last case the protein peak on the DSC curve turned over This curve with inverted protein peak was then subtracted from the curve obtained by usual way This procedure completely eliminated the instrumental baseline and doubled the ampli-tude of the protein signal The resulting curve was then divided by two The point is that the instrumental baseline

is the own property of each calorimeter, which is independ-ent of the procedures described above The above DSC approach allows us to subtract the instrumental baseline without its direct measurement, and to avoid all possible artefacts caused by the measurement of instrumental base-line and by its following subtraction from the DSC profile

of the protein This new approach makes it possible to per-form DSC experiments with high precision and to reveal rather small and low-cooperative thermal transitions, which