Preparation and Properties of Serum and Plasma Proteins. XXII. A

Frank Davidoff , Stephen Carr , Michael Lanner , and Joel Leffler. Biochemistry 1973 12 (16), ... Leon Wofsy and S. J. Singer. Biochemistry 1963 2 (1)...
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w.L. HUGHES,JR., [COSTRIBUTION FROM THE

H. A.

DEPARTMEXT OF

SAROFF AND

A. L.

PHYSICAL CHEMISTRY,

Vol. 71

CARNEY

HARVARD MEDICAL

SCHOOL]

Preparation and Properties of Serum and Plasma Proteins. XXII. A Crystallizable Guanidinated Derivative of Human Serum Albuminlatb BY

m-.L. HUGHES,JR.,

H. -1.S.4ROFF''

While various physical chemical techniques have i i i a d e possible thr approximate description of the shapes of protein molecules as geometrical solids, the polypeptide arrangement responsible not only for the geometry but also for the chemical properties of proteins remains obscure. One approach which may shed some light on this "fine structure" of the protein molecule lies in the preparation of series of derivatives of protein molecules. In order t o simplify interpretation of the results i t is desirable that such derivatives should be as homogeneous as the starting material. In practice this means that reagents must be chosen each of which is specific for one or more of the various reactive groups of the protein, and conditions must be found where the reaction can proceed quantitatively and without the introduction of non-specific structural changes or denaturation. The following studies on the reaction of 0methyl isourea with human serum albumin were undertaken to determine to what extent this reaction might fulfill the above requirements. Previous investigations by Greenstein and others2,3,4on the reaction of 0-methyl isourea with lysine and lysylglutamic acid indicated that this reagent reacted readily with the e-amino group of peptides. Preliminary studies on the effect of this reagent on horse and bovine serum albumins indicated that a marked decrease in solubility accompanied the conversion of the amino groups to guanidino groups."." (1) (a) ThispaperisNuniber78in theseries"Studies on the Plasma Proteins" from the Harvard Medical School, Boston, Massachusetts, on products developed by the Department of Physical Chemistry from blood collected by the American Red Cross. This work was originally supported by grants from the Rockefeller Foundation and from funds of Harvard University. It was aided early in 1941 by grants from the Committee on Medicine of the National Research Council, which included a grant from the American College of Physicians. From august, 1941, to July, 1946, it was carried out under contract, recommended by the Committee on Medical Research, between the Office of Scientific Research and Developlnent and Harvard Uqiversity. Since then it has been aided by a grant recommended by the Panel on Hematology of the National Institute of Health. (b) Presented, in part, bcfore the Division of Biological Chemistry of the American Chemical Society a t New York City in September, 1947. (1) (c) Present address: Xaval Medical Research Institute, S a tional Kava1 Medical Center, Betbesda 14, Maryland. (1) (d) Present address: Cancer Research and Cancer Control Unit, Department of Surgery, Tufts College Medical School, Boston, Massachusetts. (2) J. P. Greenstein, J . B i d . C h e m . , 109, 529, 541 (1935). (3) J. P. Greenstein, J . Org. Chcm., 2, 480 (1938). (4) See also J . Kapfhammer and H . Muller, Z. physiul. Chertl., aas, 1 (1934). ( 5 ) E. J. Cohn, Chem. Reus., 28, 395. footnote 10 (1941). ( 6 ) Schiitte has similarly used S-methyl isothiourea: 2. phrsiol. Chcm.. 279, 5 2 , 59 (1943).

.ZND

-1.L.

CARNEYld

Materials and Methods Human serum albumins used in these studies were crystallized by the metho scribed7and contained less than 0. by itnmunological test. Three preparations were used. Two of them (1T!?-4X and li9-5X) were derived from the same preparation of normal human serum albumin after i t had been crystallized four and five times, respectively, with the aid of chloroform. Another preparation of normal human serum albumin (Dec. 10) had been crystallized three times with the aid of n-decanol. 0-Methy isourea hydrochloride,s recrystallized from hot ethanol and thoroughly dried, was used in most of the studies here reported. 0-Methyl isourea acid sulfate replaced the hydrochloride in our most recent studies, since i t proved more stable, more readily purified, and more suitable for the preparation of the free base. The preparation and properties of this compound appear not to have been reported previously and are therefore described here : To an aqueous solution of crude methyl isourea hydrochloride was added an excess of sodium picrate solution. After standing overnight a t 0" the methyl.isourea picrate was filtered, washed with cold water and recrystallized from solution in the minimum quantity of boiling water b,y cooling to 0". The crystals, washed and dried at 110 , h a d a m . p. of 189' (dec.); recorded, 181" (dec.).Q For preparation of the acid sulfate, the methyl isourea picrate was dissolved in the minimum quantity of boiling acetone; the solution was then chilled and concentrated sulfuric acid, slightly in excess of theoretical (0.25 cc./g. of picrate), added with stirring. The crystalline acid sulfate was filtered, washed with acetone and then with ether. I t was recrystallized by dissolving in 5 parts of absolute methyl alcohol and precipitating with a mixture of 10 parts of acetone and 10 parts of ether. The crystals, washed with ether and dtied at 50-60' for twenty minutes, had a m. p. of 119-120 . The neutralization equivalent (methyl red as indicator) was 174 (calcd. for C?HsOjX2S = 172) ; nitrogen determination by Kjeldahl, 15.9 (calcd. 16.3). for C~HIOJY~S,

Preparation of Guanidinated Serum Albumin. -In general the chemical modification of a protein can be carried out most safely a t the lowest possible temperature, since the temperature coefficient of denaturation is much larger than that of most chemical reactions. In these experiments guanidination was carried out a t 0'. For economy, concentrated solutions were employed. -1s discussed below, the rate of the reaction depended largely on the pH. In fact, it (7) E. J. Cohn. W. I,. Hughes, Jr., and J . H . LVeare,

T H I S JOUR-

69, 1753 (1947). (8) \Ve are indebted to Dr. R. Bowling Barnes of the American

NAL,

Cyanamid Co. for this preparation. (9) E. A. Werner, J . Chem. Soc., 101, 928 (1914).

July, 1049

(;UANIDINATED

DERIVATIVES OF HUMAN SBRUht

ALHUMIN

24fi

appeared possible to control the degree uf p a n i ilination through the PH (see Fig. :3), using the reagent itself as a buffer. The methyl isnurva reagent was prepared by the additinn of alkali to its salt at 0' iminediately before use. At the end of the reaction. the protein was separated from excess reagent and from its cleconipiisititin products by dialysis or by isoelectric precipitation, and dried frtm the frnzen state. Unrracted reagent could he recovered :is its picrate. Details for the preparation of a crystalline derivative (see Fig. I ) of human Serum albumin follow. Preparation of Crystallized Gvanidinated Serum Albumin.-To l i . 2 g. (11.111 molr) of mrtliyl isouwii ;arid nilfutr dissolvrd in SI cc. of w:itcr at 11' is : ~ l d e dO,l!l equivxlent of hot ronrentratcrl hwium hyclroxidr, I O cc. a t i t time with C W l i l l K tx,tween successive sdditionr. ( 5 .V barium

Fig. I.-Cryst;dr of hurnaii wrtm itll,umin (with 54 iiiniiio groups g u i n i d i m t t c ~ ~ fmm ~ 11.114 v!?, ptl 6.11. ilrrtiltC

l,,,lTcr.

Unreacted methyl isourea w a s tlvtCrmincd i ~ thr v picrtatc by prccipitiatiou from I I C U ~ T :solution ~ by the :dditim nf ;In equal volumu of 11.2 JI lithium picrxtv. After t ~ n t y four hours rlancling :it In cumplclc rryst;illinttion, the prwipitiite wits filtered, w;trhr~lwith i t sm;,ll volume of wtler, dricd at I111' :and w i g h d . Thr xpplication nf this mrthorl to :L series of ~tiindiirdmrthyl isourca solutions varying in conrentratim from 0 . 1 to 11.112.5 .I1 gxve rvcowries of 8x to $13' ;.. pH measurements wcrr made it1 room tmqrr:,turc with dcrtrmlr ICatnbridgr rcnearrh motlrl). Protein samples were trau;illy dilutecl to 1'; with w.ttw. Electrophoretic, ultracentrifugal and viscosimetric analyses, to drtrnnine whrthrr thr nmdifirtl protrin had IWPII rrnrlerrd IICICTO~C.~L.OUS with resprct to size, sh;tpe or IICI rhxge, wcmc rarrird out by mcthmls already described.'"."~~ Solubility measurements were carried out by adding neutral concentrated solution of the protein to it volumc of calculated 10 give the &sired ionic strength n in the system. After standing twenty-four temperature, the precipitate was S P I X N B ~ C ~ hy centrifugation nnd the pH and protcin conmrmatioii of t h e solntion determined. the latter hy the biuret reitction."

Results and Discussion l i n s t reactions for the preparation of prnteiii derivatives involve a radical change in the nature of a chrmical group-dten accnmpanied by t h e loss of a charged or ionized group. 0-llcthyl iwiurea, however. reacts to replace the basic amino group by the more basic guanidino gniup. Reing more rextive than S-methyl isothinurea aitd cyanamide,'6 it would uppear prefrrable tc, these despite the iiistahility of the reagent i n aqueous systems. This instability results i n the (111 (sal S. H. hmnrtrurw. Jr.. A I . I. E. Iltalku a ~ i t lK. C. .Murrisan. 41R (19171: (1,) J . I,.Ondcy, G. Sralrh.mrd and A. Hrown. J. I'hyi. nml Cdl. C h m . . 81. IR4 (IB471: (rl Thew "ndyrcs wcrc carried out under the direction 01 J . I,. Onclry by hl. J . E. Hiidke. C. (:ordon and I4 I?llcnboycn IIJIJ . l\'. hlphl. J . Hinl.