Conformatonal analyss of bovine erythrocuprein from circular dichroism and infra-red spectra

Int.

3.

Biochem., 1973, 4, 365-371.

CONFORMATIONAL FROM

ANALYSIS

CIRCULAR W.

H.

Department

[Scientechnica

(Publishers)

OF BOVINE

DICHROISM

BANNISTER, of Physiology

J.

V.

Ltd.]

365

ERYTHROCUPREIN

AND INFRA-RED

BANNISTER*,

and Biochemistry,

Royal

P. University

SPECTRA

CAMILLERIt, of Malta,

Msida,

Malta

AND A. Department

LEONE

of Mathematics,

Royal

GANADO University

of Malta,

Msida,

Malta

ABSTRACT I. The analysis of protein conformation from circular dichroism (C.D.) spectra by curve-fitting and matrix-rank determination is examined with reference to spectra of bovine erythrocuprein. 2. Poly-a-amino-acid reference spectra are not applicable to bovine erythrocuprein C.D. spectra in so far as they give least-square fits with negative percentages of secondary structure, in contrast to reference spectra derived from the C.D. spectra of the proteins The latter indicate the presence of a small ribonuclease, lysozvme, and myoglobin. percentage of a-helix and preponderance of unordered structure over 8-structure in the protein. 3. The presence of these structural modes and the preponderance of unordered structure is supported by the i&a-red spectrum of the holoprotein in the amide I region. 4. Matrix-rank analysis of a set of five independent C.D. spectra of bovine erythrocuprein in the far ultra-violet supports the three-component fit of the spectra by least squares. is

ERYTHROCUPREW (Carrico

and

a

Deutsch,

cupro-zinc 1970;

protein Bannister,

and Wood, x97x) with superoxide dismutase activity (McCord and Fridovich, I 969). The profile of the far ultra-violet circular dichroism (C.D.) spectrum of bovine erythrocuprein suggests that the protein contains little or no a-helix and a mixture of antiparallel p-pleated sheet and unordered structure (Wood, Dalgleish, and Bannister, 197 I; Weser, Bunnenberg, Cammack, Djerassi, FlohC, Thomas, and Voelter, x971). This view has been examined and put on a quantitative basis by a combined approach of curve-fitting and matrix-rank analysis of C.D. spectra of the protein. This kind of approach to the conformational analysis of Bannister,

* Present address: Clinical Biochemistry, OX2 6HE.

Nuffield Denartment of Radcliffe Infirmary, Oxford

t Present address: Department of Chemistry, University College of Swansea, Swansea SA2 8PP.

proteins from C.D. spectra has not been exploited so far. The results for bovine erythrocuprein are described in the present paper to indicate the potential of the method of analysis as well as its assumptions and limitations. The results are also compared with the qualitative picture of conformation given by the infra-red (I.R.) absorption spectrum of the protein in the amide I region. THEORETIC& The analysis of C.D. spectra for the number of contributing components by curve-fitting and matrix-rank methods depends on the vectorial representation of the spectra as the mean residue ellipticity at a series of wavelengths in the far ultraviolet. As a working hypothesis, the C.D. spectrum is assumed to be given by a linear combination of properly chosen spectra of the a-hehcal, 8structural, and unordered conformations (Greenfield and Fasman, 1968). In functional notation:

A(h)c = do.), (1) where A(i) is a vector function whose components are the spectra of the three conformations; c is

y36

BANNISTER

ht. 3. Biochem.

AND OTHERS

the vector representing the contributions of the smoothed by a quadratic five-point least-squares conformations: and d(i.) is the vector function approximation (Savitzkv and Golay. 1961,. representing the protein spectrum. .4ssuming A(i.), Iterated interpolation {Neville, tg34! was used to c may be obtained by a continuous least-squares construct spectra digitized at intervals of I nm. approximation ( LIagar, I 968). Alternatively, a Curve-fitting was performed on these spectra. collocation method at equal intervals can be used Matrix-rank analysis was performed on the basic on equation (I) to obtain the discrete approximaexperimental spectra digitized at intervals of tion : 2’j nm. C.D. spectra of poly-L-lysine in a-helical, 8c = (AA)-‘A’d, (2) structural, and unordered conformations were where A and d are obtained by sampling A()<) and constructed from the data reported by Greenfield d(i), and A’ is the transpose of A (Searle, x966). and Fasman (1969). Reference spectra of the aGood results are obtained when the spectra helix, ,%tructure, and unordered structure, chosen for the matrix A truly form a basis for the obtainable from the C.D. spectra of ribonuclease, protein spectrum. The spectra of poly-~-aminolysozyme, and myoglobin as proposed by Saxena acids in the a-helical, p-structural, and unordered and Wetlaufer (x971), were calculated from the conformations give good approximations in certain data reported by these authors. The spectra of the cases (Greenfield and Fasman, rg6g; Rosenkranz reference conformations proposed by Rosenkranx and Scholtan, 1971). The difficulties in the use and Scholtan ( I g7 I )-the standard a-helical of these homopolymer spectra have been pointed conformation of poly-r&sine, the 8-structural out by Greenfield and Fasman (1969). As an conformation of poly-r-lysme in the presence of alternative, Saxena and Wetlaufer (1971) have I per cent SDS at neutral pH, and the unordered proposed the use of a matrix A obtained from the conformation of poly-L-serine in the presence of relationship : 8 ilf LiCl-were kmdly supplied by Dr. W. AC = D, Scholtan. (3) The infra-red absorption of a deposited protein where C is the matrix composed of the vectors film prepared according to the procedure of representing the a-helical, ~-structural, and unTimasheff and Susi (1966) was measured with a ordered structural content of three reference UnicamSP~oo gratingspectrophotometeroperated proteins as revealed by X-ray crystallography, at a mean speed of approximately 4 cm.-1 per and D is the matrix of the C.D. spectra of the second. The wavenumber scale of the instrument This assumes that the spectra of the proteins. was calibrated by means of a polystyrene film. reference proteins have the same basis set and The resolution in the amide I region was apthat the matrix A which is obtained is a proximateh 1.; cm.-i and the wavenumber reasonable approximation to the basis set of the ;eproducibility approximately 0.5 cm.-‘. .4 despectra of the proteins on which curve-fitting is mountable cell with CaF, windows was used. The carried out. spectra of Nujol mull, -fluorocarbon film, and For a set of protein C.D. spectra having the same KBr disk preparations of the protein were also basis the rank of the matrix of the spectra gives the measured. number of vectors forming the basis. When the The I.R. spectrum between 16oo and matrix is composed of the spectra of a number of I 700 cm.-i was read at intervals of 0.5 cm.-’ by different proteins it may be difficult to attach a means of a mechanical co-ordinate digitizer. The general meaning to the rank of the matrix. ,4 data were smoothed by a quadratic five-point rank of four (or higher) in these cases (Dalgleish, least-sauares annroximation and the centre of x972) does not necessarily disprove the threeabsorption bands was confirmed by numerical component representation of protein C.D. spectra differentiation (Savitzky and Golay, 1964). in the far ultra-violet. Although a rank greater All computations were performed on a Hewlettthan three is conceivable in view of the expectation Packard giooB Calculator fitted with a g1or.4 of contributions from chromophores other than Extended Memory. amides in certain cases (Greenfield and Fasman,

1969; Magar, 197x), it is desirable to demonstrate this for a matrix of spectra of a single protein under conditions which alter the proportions of the structural modes, since it would then be safer to assume that the spectra have the same basis set. METHODS

The C.D. spectra analysed here have been reported previously (Wood and others, I 971I. For the purposes of the present work the spectra were read at intervals of 2.5 nm. ?\lolar C.D. was converted to mean residue ellipticity assuming a mean residue weight of I IO, and the data were

RESULTS The C.D. spectra of bovine erythrocuprein analysed in the present work are given

in

Table I.

of

The

rcsuhb

of fitting

the

spectra

the reference conformations proposed by Rosenkranz and Schoitan ( I 97 I j, Saxena and 1Vetlaufer ( I 97 I 1: and Greenfield and Fasman

i 1969; to the spectra apoprotein, apoprotein

and between

the

of the

holoprotein,

the

S-carboxymerhylated 200 nm.

and

240 nm.

CONFORMATIONAL

‘9735 4

ANALYSIS

given in Table II. It is seen that continuous least-squares approximation gave I.-CIRCULAR

WAVELENGTH (nm.j

_

DICHROISM SPECTRA OF BOVINE ER~THROCUPREIX PREPARATIONS MEAN RESIDUE ELLIPTICIN* (degree cm* per dmole)

-

S-Carboxymethylated Xpoprotein

Holoprotein

- 2904 -4432 -54’3 -j856 -j8Io

202’j 205 207'j

210 212’j 21j 217.j 220 222’j 22j 227’j 230 232’j

-5492 -4931 -4120 -3180 -2364 - I 800 - 1426 -1138 861

235 237’5 240

-

* Experiment

--

__

__

.a1 values

604 410 300

367

virtually the same percentages of r-helix, and unordered structure as $-structure,

are

Table

OF ERYTHROCUPREIN

-

- ‘994

-3822 -5192 -5962 -6154 -5980 - j486 -4771 -3951 -3187 -2523 -2013 - 1627 -1301 z

:F$

-

459

-

1402

- ‘235 -1051 868

smooth ed by quadratic

15,

-

703 573 475 399 3j* 312 286

-

2j9 231 181 132

-

89 59

Apoprotein in 8M Urea

Holoprotein in 8M Urea

-4603 -3695

-4385 -4888 -4938 -4661

-2922

-2296 - 1820 -1438 - 1167 - 989 - 889 - 841 - 796 - 6go - 540 - 407 - 301

-4’05 -333’ -2516 - 1878 1480 -1220 - 1001 766

-

t-point least-squares

568 403 302

approxima

n.

Table II.-STRUCTURAL CONTENT OF BOVINE ERYTHROCUP~UEINPREPARATIONS AS ESTIMATEDBY FITT~G THE REFERENCE SPECTRA PROPOSEDBY ROSENKRANZ AND SCHOLTAI ( I g7 I ) (d) t SAXENA ANY LVETLAUFER (1971) ;B>, AND GREENFIELD AND FANAN (1969, (CJ TO THE C.D. SPECTRUM BETWEEN 200 nm. AND

240 nm.

/ REFERENCE SPECTRA

I

%-HELIX

S-STRUCTURE

(per centj

(per cent)

/ UNORDERED STRKXXURE (per cent)

RMSt

Holoprotein ;: C

.4poprotein

A CB

o-2 (o-3) IO (10.6) 17.3 (12.8)

22’1

(22.2)

31.8 28.7

(31.5) (32.3)

1’7 (1.2) 12.j (12.4) 18.8 (14.6)

24’3 (24.3) 31’9 (32.2) 3 * ‘: (34.6)

74’1 (74.j) jj’j (jj.4) 49’5 (jo.7)

j94 670 IOIj

SCarboxymethylated apoprotein ;: c

2.5 (2.6’1 Ij.9 (16’1 17.3 (16)

3.7* (4-o*) (18.5)

18.2 ‘3

( ‘4.3)

* Segative with respect to least squares. t Root mean square of residuals for fitted spectrum. The results of discrete and continuous least-squares approximation

93.8 (93.4) 65.9 (65.5) 69.7

(69.6)

30

281 86

are given, the latter in parentheses.

BANNISTER AND OTHERS

368

approximation. The reference discrete spectra of Rosenkranz and Scholtan ( I 97 I j indicated virtually no z-helix, those of Saxena and Wetlaufer (1971) and Greenfield and Fasman (1969) indicated a small percentage Table

of r-helix. All reference spectra indicated a preponderance of unordered structure over $-structure and further increase in unordered structure in the A’-carboxyrnethylated apoprotein.

ANALYSIS OF CD. SPECTRA OF Table Z BETWEEN 205 PROCEDURE OF WALLACE AND KATZ (1964)

ZZZ.--MATRIX-RANK

-6rj4

Reduced data matrix*

0 0 0 0

Reduced 5 per cent error

308 0 0 0 0

matrix*

*

Int. J. Biochem.

Original

data transposed:

-jg62 -2138

o 0

0 0 0

0 0 submatrix

AND

240 nm.

BY THE

- j486 785

0

217 -119 28

299 271 4% 643

274 243 461 681

0

8j

-156

260 307 262

298

314

leading

-jg8o j43 82

-j792 -864 626

0 0 0

nm.

after four reduction

steps.

Table IV.-STRUCTURAL CONTENT OF BOVINE ERYTHROCUPREIN PREPARATIONSAs ESTIMATED BY FITTING THE REFERENCE SPECTRA PROPOSEDBY ROSENKRANZ AND SCHOLTAN ( Ig7 Ij (A), SAXENA AND WETLAUFER (1g7I), (B), AND GREENPIELD AND FA~MAN (1969) (C) TO THE C.D. SPECTRUM BETWEEN 205 nm. AND 240 nm.

REFERENCE

SPECTRA

8-STRUCTURI (per cent)

I-HELIX (per cent)

__

UNORDERED sTxucrURz (per cent)

RMSt

Holoprotein d

I’9 9’4 3.2*

CB

__

18.3 32’9 38.4

80 j7’7 j8.3

328 506 822

20’7 32’4 40.2

78.6 jj’b j8.1

3jg jj 736

Apoprotein .4

0.6* 12’1 1’7*

: SCarboxymethylated

__

apoprotein

A

j.8*

3-o Ij'I

CB Holoprotein

3’7

27

62.2 68.4

42 66

18.0

80.2 j8.I j8.4

334 4jI 698

92’4

155

in 8 M urea I.8* IO

: c .4poprotein

__

91'1

22.6 27’9

in 8

M A CB

3.3*

_.

$3

urea I.6 ‘3’9 I .6

6* 22.3 28.5

* Negative with respect to least squares. f Root mean square of residuals for fitted spectrum. The results of discrete least-squares approximation are given.

63.8 69.7

‘94 325

‘973>4

CONFORMATIONAL

ANALYSIS

Rank analysis of the matrix given by the spectra of Table I between 205 nm. and 240 nm. indicated a three-component fit of the spectra. The procedure of Wallace and Katz (I 964) was followed, a 5 per cent error matrix being first set up as a reasonable

OF ERYTHROCUPREIN

369

by matrix-rank analysis was best corroborated by the fit given by the reference spectra of Saxena and Wetlaufer ( 197 I). These were the only reference spectra which did not give negative percentages of secondary structure in the best fit of the experimental

-6000 200

220 nm

240

FIG. I.-Far ultra-violet C.D. spectrum of bovine erythrocuprein (-) and least-square fits (. . .) given by the reference spectra of Saxena and Wetlaufer (1971) in the wavelength regions 200-240 nm. and 205-240 nm.

estimate. The results of the four reduction steps possible with the original matrix and the corresponding propagated errors are given in Table III. The elements of the principal diagonals of the reduced and the error matrices indicate three non-zero rows in the reduced matrix. A similar finding was made with a IO per cent error matrix. The results of fitting the five spectra of Table I between 205 nm. and 240 nm. by the reference spectra of Rosenkranz and Scholtan (1971), Saxena and LVetlaufer (1971), and Greenfield and Fasman (I 969) are shown in Table IV. It is seen that the three-component

fit of the

spectra

indicated

1600

1650 cm-l

1700

FIG. I.-I.R. spectrum of a deposited film of bovine erytbrocuprein in the amide I frequency region.

by least squares. The fit of the holoprotein spectrum by the reference spectra of Saxena and Wetlaufer ( 197 I) is shown in Fig. I. The presence of r-helix was supported by the I.R. spectrum of the holoprotein, whether a deposited film, a Nujol mull, a fluorocarbon film, or a KBr disk preparation was examined. The deposited film spectrum in the 1600r 700 cm.-’ region is shown in Fig. 2. The spectra

BANNISTER AND OTHERS

370 observed cm.-I

amide and

Relevant

I band has a peak at 1641

considerable

to the analysis

fine

structure.

of protein

conforma-

at 1632, 1654, and 1685 cm.-‘. The peak at 1641 cm.-’ indicates a predominance of unordered structure; the band at 1632 cm.-1 indicates the presence of p-structure; and the smaller band at 1685 cm.-l suggests that it is the antiparallel P-structure which is present. The maximum at I 654 cm.-l is in the region of the amide I frequency thought to be characteristic of the a-helix (Susi, Timasheff, and Stevens, I 967). tion

are

the partially

resolved

bands

make a significant difference to the computations given here. For example, discrete least-squares fitting of the erythrocuprein spectrum in the stringent 200-240 nm. region, using basis spectra calculated from the revised C.D. spectra ofribonuclease, lysozyme, and myoglobin given by Chen, Yang, and Martinez (I 972) and the values for the X-ray structural composition of these proteins given by Saxena and Wetlaufer ( 197 I ,,. indicates 10.4 per cent a-helix, 31.2 per cent P-structure, and 58.4 per cent unordered structure and gives a value of 350 for the root mean square of the residuals. ACKNOWLEDGEMENT

DISCUSSION The present analysis indicates three structural modes for bovine erythrocuprein: a-helix, $-structure, and unordered structure. This conclusion was reached by curvefitting and matrix-rank analysis of far ultraviolet C.D. spectra of the protein and examination of the I.R. spectrum in the amide I region. It is of interest that the reference spectra of Saxena and Wetlaufer (I 97 I) derived from three reference proteins did not give negative percentages of secondary structure in least-squares fitting of the experimental CD. spectra in contrast to the poly-aamino-acid reference spectra of Rosenkranz and Scholtan ( 1971) and Greenfield and Fasman ( 1969). In principle, negative percentages of secondary structure should not be found if the reference spectra truly form a basis for the protein spectrum and equation !I) is satisfied. Magar (1971 j has suggested hnear programming instead of least-squares curve-fitting where negative percentages occur. However, it would be better in these cases first to inquire into the &ability of the reference spectra. Probably bovine erythrocuprein and the reference proteins of Saxena and Wetlaufer (197x ), i.e., ribonuclease, lysozyme, and myoglobin, have the same or a closely similar three-component basis for their far ultra-violet C.D. spectra. NOTE ADDED AT PROOF STAGE: Chen, and Martinez (1972) inadvertent error in

have

Saxena and Wetlaufer

(197 I).

the

ht. J. Biochem.

Yang,

pointed out an C.D. spectra of This does not

One of us (W. H. EL) thanks the Nufficld Foundation and the Wellcome Trust for research grants.

REFEREXCES BANNISTER,J., BANNISTER,\V., and WOOD, E. (ICJ~I), ‘ Bovine erythrocyte cupro-zinc protein. I. Isolation and general characterization ‘, Eur. j. Biochem., 18, 178-186. CARRICO. R. J., and DEUTSCH,H. F. ( Ig7o), ‘ The presence of zinc in human ytocuprein and some properties of the apoprotem ‘, 3. biol. Chem., y159 723-727. CHEN, Y-H., YANG*J. T., and LMARTINEZ, H. &I.

(x972), ‘ Determination of the secondary structures of proteins by circular dichroism and optical rotatory dispersion ‘, Biochemistry, II, 4’2~4131. DALGLEISH. D. G. i I 072,. .,, ,. ‘ The analvsis of the farultraviokt circular dichroism ’ spectra of proteins ‘, FEBS Letters, q, I 34-13 j. GREENFIELD, R’. J., and FASMAN, G. D. i 1969,. ‘Computed circular dichroism spectra for the evaluation of protein conformation ‘, BioChckStTy,8, 4108-4116. MCCORD, J. M., and FRIDOVICH, I. (Ig6g,;, ‘ Superoxide dismutase. An enzymic function for erythrocuprcin (hemocuprem) ‘, 3. biol.

Gem., *

6049-605j.

MACAR, M. E. (rg6f), ‘ On the analvsis of the optical rotatory dispersion of proteins ‘, Biochemish-/, 7, 6 17-620. MAGAR, M. E. ( 197 I ), ‘ On the possibility of determining the secondary structure of proteins in solution ‘, 3. theor. Biol., 33, 1oj-11g. SEVILLE, E. H. (Ig34), ‘ Iterative interpolation ‘, 3. Indian math. SOL., no, 87-120. ROSENKRANZ. H., and SCHOLTAN, W. (Ig7I,, ‘ Eine Verbesserte Methode zur Konformationsbestimmung van Helicalen Proteinen aus Messungen des Circulardichroismus ‘, Hoppe-

St$er’s <. physiol. Gem., 352, 896-904.

‘9731

4

CONFORMATIONAL ANALYSIS OF ERYTHROCUPREIN

SAVITZKY, A., and GOLAY, M. J. E. i ig64), ’ Smoothing and differentiation of data by simohfied least scmares nrocedures ‘. .&oivf. 4 C/r&., 36, x627-1639. * SAXENA. V. P.. and WETLAUFER. D. B. f 107I ). ‘ .q new basis for interpreting the c~ir&&r dichroism snectra of oroteins ‘. Proc. natn. Acad. Sci. C:S.A.,*68, g6g&. ’ SEARLE. S. R. (1466). ‘ Matrix Alecbra for the Biolo&al &ien&~e9, ‘pp. 23x-233. “New”York: Wiley. !%.I, H., TIMASHEFF, S. N., and STEVENS, L. ( I 967)) ’ Infrared spectra and protein conformations in aqueous solutions. I. The amide I band in He0 and DsO solutions ‘, J. biol. Gem., ZZ~Z,j46wj466. TIMASHEFF, S. N., and Susr, H. (rg66), ‘ Infrared investigation of the secondary structure of 3lactoglobuhns ‘, 3. biol. Chem., ~41, 24g-250.

371

WALLACE, R. M., and KATZ, S. M. (x964). ‘ A method for the determination of rank in the anaivsis of absorntion soectra of muiticomnonent syste’ms ‘, 3. phy;. Chcm:, 68, 3890-3892. ’ BUNNENBERG. E.. CAIHMACK. R.. WESER. U.. DJE~I,’ C., FLOHI?, i., THOMAS, G.; and VOELTER, W. (t971), ‘ A study on purified bovine erythrocuprein ‘, Biochim. biophys. Acta, zrq3, 203-2 13. WOOD, E., DALGLEISH, D., and BANNISTER, W. (197 I ), ‘ Bovine erythrocyte cupro-zinc protein. 2. Physicochemical properties and circular dichroism ‘, Eur. 3. Biochcm., 18, 287-193.

Kq Word Index: Protein conformation, circular dichroism spectra, basis spectra, curve fitting, matrix rank analysis, infra-red spectra, amide I band, bovine erythrocuprein.