On the origin of species specificity of fibronectin. Immunological identification of a species-specific domain of human fibronectin

We have investigated whether species-specific epitopes of human fibronectin are localized at a specific domain of fibronectin using rabbit polyclonal antibodies. Tryptic fragments of human fibronectin were tested for reactivity with anti-human fibronectin antibody, which had been previously absorbed with other animal fibronectin to establish species specificity. Human-specific epitopes were found to be present on 75,000, 65,000, and 42,000 dalton fragments. The 42,000-dalton fragment shares almost all the epitopes with the 75,000 and 65,000 dalton fragments. It does not promote BHK cell spreading, whereas the 75,000 and 65,000 dalton fragments do. The amino acid sequence from the amino terminus of the 42,000-dalton fragment is Asp/Gly-Gln/Val-?-Ile-Val-, which is almost identical to the sequence Asp-Gln-Cys-Ile-Val- located in the carboxyl terminal 1/3 of the collagen-binding domain of human fibronectin (Kornblihtt et al. (1985) EMBO J. 4, 1755-1759). These results suggest that human fibronectin bears human-specific epitopes mainly on the amino-terminal half of domain 4 (Hayashi & Yamada (1983) J. Biol. Chem. 258, 3332-3340) located between the collagen and cell binding domains almost at the center of the fibronectin polypeptide. The domain specific for human fibronectin may be a general species-specific domain of animal fibronectins.     

Mapping the collagen-binding site of human fibronectin by expression in Escherichia coli.

The collagen-binding domain of human fibronectin has been expressed as a cro/beta-galactosidase fusion protein in Escherichia coli. The hybrid polypeptide was recognized by an anti-(human plasma fibronectin) serum and bound specifically to gelatin-Sepharose. The collagen-binding region was subdivided by constructing a series of overlapping bacterial expression plasmids. The fusion proteins produced by these constructs were analysed for gelatin-binding activity. The results indicate that the binding site lies within an approximately 12.5 kd fragment of fibronectin, and show that the following 14 amino acid sequence is critical for gelatin-binding activity: Ala-Ala-His-Glu-Glu-Ile-Cys-Thr-Thr-Asn-Glu-Gly-Val-Met. This sequence links the second type II homology unit with the adjacent type I repeat in the amino-terminal third of the fibronectin molecule.     

Isolation and biological characterization of active fragments of the adhesive glycoprotein fibronectin

Cellular fibronectin is a major cell surface glycoprotein that can mediate the adhesion of cells to collagen in vitro. To analyze its mechanism of action, we have undertaken experiments to isolate fragments of fibroblast fibronectin that retain different active sites. In this paper, we describe the purification of three chymotryptic fragments with apparent molecular weights of 40,000, 160,000 and 205,000 from chicken cellular fibronectin. These fragments were electrophoretically pure and retained different biologically active sites, as determined by a series of bioassays and competitive inhibition experiments. The 40K fragment was identified as the collagen-binding fragment. The 160K fragment was found to contain the cell surface-binding site(s) of cellular fibronectin. The 205K fragment contained both collagen-binding and cell surface-binding sites, and apparently represents the sum of the 40K and 160K fragments. When native fibronectin is cleaved to the 205K fragment, a polypeptide region containing all interchain disulfide bonds is lost. This alteration was accompanied by decreased hemagglutinating activity and loss of the capacity to restore a normal morphology to transformed cells, whereas cell attachment to collagen and cell spreading activities remained. Our results directly support the idea that the fibronectin molecule consists of separate structural domains containing different biological characteristics.     

Independent locations of kinase and 3'-phosphatase activities on T4 polynucleotide kinase

We have used two chemical modification reagents and three proteases to study the relationship between the two activities of T4 polynucleotide kinase. In each case, conditions were found where one of the two activities of the enzyme could be eliminated without greatly reducing the other. Taken together, these data indicate that the two activities are catalyzed by amino acid residues located in separate active sites on the polypeptide chain. Specific exopeptidase digestion indicates that the kinase activity lies in the NH2-terminal and the phosphatase in the COOH-terminal portion of the polypeptide chain. Partial trypsin digestion produces a 29,000-dalton fragment with no kinase activity and nearly normal 3'-phosphatase activity.     

A unique proteolytic fragment of human fibrinogen containing the A alpha COOH-terminal domain of the native molecule

The COOH-terminal portion of the A alpha chain of human fibrinogen is highly susceptible to proteolytic degradation. This property has prevented isolation of the COOH-terminal domain of fibrinogen for the direct investigation of its functional characteristics. Human fibrinogen was degraded with hementin, a fibrinogen-olytic protease from the posterior salivary glands of the leech, Haementeria ghilianii. Two initial fragments, Yhem1 and Dhem1, produced by cleavage through the three polypeptide chains in the connector region, were characterized and shown to retain the entire A alpha COOH-terminal domain. Late cleavages by hementin occurred in the A alpha chain COOH-terminal region to produce fragments Yhem and Dhem with shorter A alpha chain remnants. Fragments Dhem were isolated from an intermediate hementin digest of fibrinogen using anion-exchange chromatography. Fragment Dhem1 was separated further from Dhem fragments with shorter alpha chain remnants by affinity chromatography on immobilized plasma fibronectin. Fragment Dhem1 represents a unique proteolytic fragment of fibrinogen containing an intact A alpha chain COOH-terminal region. NH2-terminal sequence analysis of isolated chains from fragment Dhem1 located hementin cleavage sites in the connector region to A alpha Asn102-Asn103, B beta Lys130-Gln131, and gamma Pro76-Asn77. The specific interaction of fragment Dhem1 with immobilized fibronectin indicated that the binding site probably was located within the COOH-terminal 111 amino acids of the A alpha chain. The overall pattern of fibrinogen cleavage by hementin is similar to that of plasmin, yet hementin cleaves preferably in the coiled-coil connector, sparing the A alpha COOH-terminal domain.     

Characterization of porcine plasma fibronectin and its fragmentation by porcine liver cathepsin B

Fibronectin was isolated from porcine plasma by affinity chromatography with gelatin-linked Sepharose 4B. Porcine fibronectin had a chemical composition similar to those of human and other fibronectins and reacted with antiserum raised against human fibronectin. It showed hemagglutination activity with trypsin-treated rabbit erythrocytes, though the activity was far less than that of human fibronectin. Porcine plasma fibronectin consisted of two subunit chains of about 230,000-daltons linked by disulfide bonds(s). Limited proteolysis of this protein with porcine liver cathepsin B yielded five major fragments which were investigated by affinity chromatography with gelatin- and heparin-linked Sepharose 4B. One fragment (Mr = 50,000) was bound to gelatin but not to heparin, while the remaining four were bound to heparin but not to gelatin, suggesting that plasma fibronectin takes a discrete domain structure with respect to interaction with these two macromolecules. The three larger heparin-binding fragments, Mr = 175,000, 150,000, and 130,000 were eluted with different concentrations of a mixture of NaCl and urea from the heparin-column, suggesting that they have different interactions with heparin, the 130,000-dalton fragment being the one with the strongest interaction. After reduction with 2-mercaptoethanol, the 175,000-dalton fragment was converted to the 150,000-dalton region fragment, which, together with the unchanged 150,000-dalton fragment, appeared to be equivalent in amount to the 130,000-dalton fragment. This finding suggests that the 150,000- and 130,000-dalton fragments may have originated from different subunit chains. Since the 175,000-dalton fragment was not produced by cathepsin B digestion of fibronectin which had been treated with plasmin, it was concluded that the 175,000-dalton fragment contained interchain disulfide bond(s) which had linked the native subunit chains. These results suggest that porcine plasma fibronectin has non-identical subunit chains composed of domains which differ in interaction with heparin and in susceptibility to cathepsin B.     

Domain structure of fibronectin and its relation to function. Disulfides and sulfhydryl groups.

Hamster cell fibronectin is a glycoprotein consisting of two 230,000-dalton subunits in a disulfide-bonded dimer. The molecule is composed of domains which can be separated by partial proteolytic cleavage. The carbohydrates, disulfide bonds, and a single free sulfhydryl group per chain are distributed nonuniformly among these regions. All the interchain disulfides are within 10,000 daltons of the end of the molecule and are removed by mild proteolysis which also generates 200,000- and 25,000-dalton fragments which do not contain interchain disulfides. The 200,000-dalton fragment contains all or most of the carbohydrate side chains, and the free sulfhydryl group, but is relatively poor in cystine. The 25,000-dalton fragment is carbohydrate-free and cystine-rich but has no free sulfhydryl groups. There is heterogeneity in carbohydrate content among the monomeric chains of intact fibronectin and the 200,000-dalton fragments. The gelatin binding site of fibronectin is in the 200,000 fragment. Intact disulfide bonds are required for binding of fibronectin to cells and to gelatin and blockage of the free sulfhydryl groups prevents binding of fibronectin to cells, suggesting that intermolecular disulfide bonding may be important.     

Fragmentation of the human transplantation antigen heavy chain by limited proteolysis, acid cleavage, and cyanogen bromide treatment.

Highly purified, papain-solubilized HLA-A, -B, and -C antigens comprising a mixture of a great number of allelic forms from at least three loci have been fragmented by limited proteolysis, acid cleavage, and cyanogen bromide treatment. Limited proteolysis of 125I-labeled HLA-A, -B, and -C antigens with trypsin, chymotrypsin, thermolysin, and pepsin resulted in the production of two large fragments. One fragment was associated with beta 2-microglobulin and contained all of the carbohydrate. The other fragment, which had a molecular weight of about 13,000, is most probably derived from the COOH-terminal part of the heavy chain. Acid cleavage of the HLA antigen heavy chain gave rise to two main fragments with molecular weights of 22,000 and 11,000. Both fragments contained disulfide bonds. Two minor components, representing further cleavage products of the 22,000-dalton fragment, were also observed. Cleavage of the HLA antigen heavy chain at methionyl residues gave rise to one carbohydrate-containing, cysteine-free 14,000-dalton fragment and one 20,000-dalton fragment that contained all cysteines but no carbohydrate. NH2-terminal amino acid sequence analyses demonstrated that the 22,000-dalton acid cleavage fragment and the 14,000-dalton cyanogen bromide fragment were derived from the NH2-terminal part of the HLA antigen heavy chain.     

Phosphorylation and transformation sensitivity of a major collagen-binding protein of fibroblasts

Using affinity chromatography with immobilized gelatin and native type I collagen, we have identified the major collagen-binding proteins in Nonidet P-40 extracts of chick embryo fibroblasts labeled with [35S] methionine. After washing the gelatin- or collagen-Sepharose beads with high ionic strength buffer, a 47,000-dalton protein was the only major protein besides fibronectin found to bind to these affinity beads. The isoelectric point of this protein was approximately 9.0, with a closely spaced minor spot. The total amount and the synthesis of this collagen-binding protein were both decreased in Rous sarcoma virus-transformed cells. This collagen-binding protein was found to be phosphorylated by incubating intact cells with [32P]orthophosphate. Phosphoamino acid analysis revealed that serine and threonine residues were phosphorylated, but tyrosine was not. Although quantities of the 47,000-dalton protein labeled with [35S]methionine were decreased by a factor 2.5 after transformation, the incorporation of [32P]orthophosphate/unit of protein was 5-7-fold higher in transformed cells. In temperature-sensitive mutant virus-infected cells, the amount of the 47,000-dalton protein was also decreased at the temperature permissive for transformation, and the incorporation of [32P]orthophosphate/protein was also increased. These studies establish that a major membrane-associated collagen-binding protein of fibroblasts is phosphorylated and that it is altered in both total quantity and degree of phosphorylation after malignant transformation.     

Hydrophobic properties of porcine fibronectin and its functional domains

The relations between surface hydrophobicities and binding properties of the functional domains of porcine plasma fibronectin were investigated. Porcine plasma fibronectin as well as human plasma fibronectin was adsorbed on a hydrophobic column with butyl or phenyl ligands in the presence of 0.5 M ammonium sulfate, and recovered in a single peak by decreasing the concentration of ammonium sulfate to 0 M, indicating that both fibronectins have very high surface hydrophobicities. On digestion with thermolysin, porcine plasma fibronectin yielded five fragments (140-150, 43, 25, 17, and 14 kDa) similar to those reported for human fibronectin, although porcine fibronectin was more resistant to the digestion than human fibronectin. The three heparin-binding fragments were found to have a wide range of surface hydrophobicities, the 140-150 kDa fragment having the lowest, the 25 kDa fragment a higher, and the 14 kDa fragment the highest among all the fragments. The 43 kDa collagen-binding and 17 kDa fragments had surface hydrophobicities as high as that of fibronectin. It is noteworthy that the 43 kDa collagen-binding fragment contributes to the high surface hydrophobicity of intact fibronectin in spite of the high content of carbohydrates.     

The interaction of fibronectin fragments with fibroblastic cells

We have examined the interaction of the purified cell-binding domain of fibronectin with fibroblastic baby hamster kidney cells. When the cell-binding region of fibronectin is part of a large 75,000-dalton fragment, the direct binding of the tritium-labeled fragment to cells in suspension can be observed. There is a single class of 10(5) sites/cell with an apparent dissociation constant of 4 X 10(-7) M. When the cell-binding region is part of a smaller 11,500-dalton fragment, an interaction with cells can only be observed indirectly via inhibition assays. The apparent affinity of this fragment for the cell surface fibronectin receptor is low. This 11,500-dalton fragment competitively inhibits both the direct binding of soluble [3H]fibronectin to cells in suspension and the spreading of cells on fibronectin-coated substrates, suggesting that the fragment binds to the same receptor site as intact fibronectin. Possible models describing the mechanism of the interaction of fibronectin with its receptor are proposed.     

Immunological cross-reactivity between human tripeptidyl peptidase II and fibronectin.

Tripeptidyl peptidase II (TPP II) is a large intracellular exopeptidase with an active site of the subtilisin type. Affinity-purified hen antibodies against human erythrocyte TPP II cross-reacted with fibronectin in an immunoblot analysis. Furthermore, antibodies against human fibronectin cross-reacted with TPP II. Antibodies against a 65 kDa cell-binding fragment of fibronectin specifically reacted with TPP II, whereas antibodies against the collagen-binding domain, the main heparin-binding domain or the N-terminal fibrin-binding domain did not react. Moreover, the affinity-purified antibodies against TPP II reacted with a 105 kDa cell-binding fragment of fibronectin but not with the fibrin-binding domain or the collagen-binding domain. When native TPP II was dissociated into smaller units through dialysis against a dilute Tris buffer, it could be digested by chymotrypsin into three stable fragments of 70 kDa, 42 kDa and 20 kDa. It could be demonstrated that the 42 kDa fragment was specifically recognized by antibodies against the 65 kDa cell-binding fragment of fibronectin. Furthermore, labelling with di-[3H]isopropyl phosphorofluoridate and N-terminal sequence determination showed that the 70 kDa fragment contained the active-site serine residue. In conclusion, our findings suggest that one domain of the TPP II molecule bears structural resemblance to a cell-binding fragment of fibronectin.     

Latent fibronectin-degrading serine proteinase activity in N-terminal heparin-binding domain of human plasma fibronectin

The N-terminal 70-kDa fragment of human plasma fibronectin, purified from a cathepsin D digest, is characterized by lack of stability. It is processed proteolytically during incubation in the presence of Ca2+ into 27-kDa N-terminal heparin-binding and 45-kDa collagen-binding domains. The N-terminal residue in the 27-kDa fragment was blocked as in native fibronectin. The 45-kDa fragments began with the sequences AAVYQP, AVYQP and VYQP (residues 260, 261, 262-265 of fibronectin) that correspond to the beginning of the collagen-binding domain. In the presence of Ca2+ the purified 27-kDa fragment underwent further processing finally leading to the cleavage of the bond K85-D86 and to the simultaneous appearance of a specific proteolytic activity. Inhibition studies suggests that the newly generated enzyme is a Ca(2+)-dependent serine proteinase. Among all assayed matrix proteins, the newly generated enzyme cleaves native fibronectin and its fragments. It is proposed that this fibronectinase may originate from the N-terminal domain of fibronectin.     

Fibronectin receptors of mononuclear phagocytes: Binding characteristics and biochemical isolation

Fibronectin receptors on mononuclear phagocytes are involved in the localization of monocytes at inflammatory sites and in the subsequent expression of macrophage-like phenotypes. In this study, we have investigated the hypothesis that proteolytically derived fragments of fibronectin may interfere with binding of fibronectin to monocytes in the extracellular matrix. We report on the reactivity of U937 cells with an 80-kDa tryptic fragment of fibronectin which contains the cell-binding domain but lacks the gelatin/collagen-binding domain. U937 cells attached to surfaces coated with the 80-kDa fragment as well as with intact fibronectin. Preincubation of the cells with the 80-kDa fragment inhibited attachment to both surfaces while intact fibronectin had little or no inhibitory effect. The Ki for inhibition of attachment (0.5 microM) was consistent with the Kd for binding of the 3H-labeled 80-kDa fragment (0.34 microM) to U937 cells in suspension. There were 4-5 x 10(5) 80-kDa binding sites per cell. The relatively high affinity of the 80-kDa fragment for the monocyte surface permitted the isolation and characterization of fibronectin-binding proteins from U937 cells and peripheral blood monocytes by affinity chromatography. When octylglucoside lysates of lactoperoxidase iodinated cells were applied to 80-kDa-Sepharose columns, a polypeptide complex of 152/125 kDa was eluted with the synthetic peptide GRGDSPC, but not with GRGESP. This complex resolved into a single diffuse band of 144 kDa upon reduction. Binding of the protein complex to the affinity column required divalent cations. The complex bound to wheat germ agglutinin and could be specifically eluted by N-acetylglucosamine. Similar cell-surface proteins were isolated from peripheral blood monocytes.     

Dictyostelium myosin: characterization of chymotryptic fragments and localization of the heavy-chain phosphorylation site

Chymotrypsin cleaves Dictyostelium myosin in half, splitting the heavy chain (210,000 daltons) into two fragments of 105,000 daltons each. One of the two major fragments is soluble at low ionic strength and has a native molecular weight of 130,000. As judged by SDS polyacrylamide gel electrophoresis, this soluble fragment consists of the two intact myosin light chains of 18,000 and 16,000 daltons and a 105,000-dalton polypeptide derived from the myosin heavy chain. The soluble fragment retains actin-activated ATPase activity and the ability to bind to actin in an ATP-dissociable fashion. The maximal velocity of the actin- activated ATPase activity of the soluble fragment is 80% of that of uncleaved myosin, although its apparent Km for actin is 12-fold greater than that of myosin. In addition to the major soluble 105,000-dalton fragment discussed above, chymotryptic cleavage of the Dictyostelium myosin also generates fragments that are insoluble at low ionic strength. The major insoluble fragment is 105,000 daltons on an SDS polyacrylamide gel and forms thick filaments that are devoid of myosin heads. A less prevalent insoluble fragment has a molecular weight of 83,000 and is probably a subfragment of the insoluble 105,000-dalton fragment. The heavy chain of myosin is phosphorylated in vivo and the phosphorylation site has been localized to the insoluble fragments, which derive from the tail portion of the myosin molecule.     

The collagen-binding site of type-II units of bovine seminal fluid protein PDC-109 and fibronectin

A single type-II domain has been isolated by limited proteolysis of the collagen-binding bovine seminal fluid protein, PDC-109. The 45-residue fragment corresponding to the second type-II domain of the parent molecule was found to have retained affinity for immobilized collagen, indicating that this minidomain carries critical regions of the collagen-binding site. Studies on various fragments of fibronectin have also implicated the two type-II units of this molecule in collagen-binding. In the present work we have found that type-II domains of human fibronectin, expressed in Escherichia coli as beta-galactosidase fusion proteins, bind specifically to immobilized collagen.     

Limited trypsin proteolysis of photoreceptor GTP-binding protein. Light- and GTP-induced conformational changes

The amphibian photoreceptor rod outer segment contains a guanine nucleotide-binding complex which consists of a 39,000-dalton polypeptide that binds guanine nucleotides (G protein), a 36,000-dalton polypeptide (H protein), and an approximately 6,500-dalton polypeptide. Sensitivity to trypsin proteolysis was utilized as a probe of structure-function relationships for these polypeptides. Digestion of the H protein generated fragments of 26,000 and 15,000 daltons whose proteolytic susceptibility was not altered by guanosine triphosphates, light, or membranes. The approximately 6,500-dalton polypeptide was not trypsin sensitive. When the G protein was eluted from illuminated membranes by GTP, trypsin proteolysis cleaved a terminal 1,000-dalton fragment (G1) to yield a 38,000-dalton fragment (G38). With increased digestion time, a 6,000-dalton fragment (G6) was removed from G38 to yield a 32,000-dalton fragment (G32). G32 was subsequently digested to fragments of 23,000 and 12,000 daltons. However, when the G protein was eluted from illuminated membranes by hydrolysis-resistant analogues of GTP, G32 was protected from further digestion. This is consistent with a GTP-induced conformational change in the G protein which is altered by GTP hydrolysis. Proteolysis of the G protein after covalent labeling with a photoaffinity analogue of GTP demonstrated that the analogue is bound to first G38 and then G32, indicating the GTP-binding site is associated with G32. Fragment G6 was cleaved when the G protein was soluble or bound to unilluminated membranes. However, when bound to illuminated membranes, fragments were generated reflecting the loss of 7,500, 9,000, or 11,000 daltons from the G protein. This light-induced alteration in proteolytic susceptibility indicates there is a light-induced conformational change in the G protein. Fragment G1 was not removed from the G protein when it was membrane bound, suggesting G1 is involved in binding to a membrane structure. These data suggest that the light-induced binding of the G protein to illuminated membranes and the reversal of this binding by GTP are mediated through conformational changes in the G protein and that three conformations exist: 1) a basal, inactive conformation; 2) a primed conformation induced by binding to photolyzed rhodopsin, with a high affinity for GTP; and 3) an active conformation, induced by binding of GTP, which activates the catalytic complex of light-activated phosphodiesterase.     

The subunit structure of thymus leukemia antigens.

EDTA-containing buffer solubilizes thymus leukemia antigens (TLa) from crude thymocyte membrane fractions. The TL antigens consist mainly of molecules of a size similar to immunoglobulin G when gel chromatography analyses were performed under physiological conditions. A single component of TLa was apparent on sucrose density gradient ultracentrifugation of solubilized thymocyte membrane macromolecules as monitored by indirect immunoprecipitation. The sedimentation constant for the TL antigens (5.8 S) was considerably less than that for immunoglobulin G. The gel chromatography and ultracentrifugation data suggest an apparent molecular weight for TLa of about 120000. TLa isolated by indirect immunoprecipitation is composed of two types of polypeptide chains. The smaller subunit was identified as beta2-microglobulin. The larger polypeptide chain carried the alloantigenic determinants and displayed a molecular weight of about 50000 after reduction and alkylation. TLa subjected to molecular weight determination under denaturing conditions was composed of two components. The smaller component was beta2-microglobulin which evidently is linked to the larger polypeptide chain by noncovalent interactions only. The larger component had a size greater than reduced and alkylated immunoglobulin G heavy chains. Upon reduction and alkylation of the latter component its size was reduced and it appeared to have a molecular weight of about 50000. Consequently, TLa is composed of two disulfide linked heavy polypeptide chains and two beta2-microglobulin molecules. TLa solubilized by papain digestion comprises two polypeptide chains, one of which is beta2-microglobulin. The larger 37000-dalton subunit is a fragment of the heavy polypeptide chain. This was demonstrated by digesting solubilized 120000-dalton TLa with papain. The proteolytic fragments obtained were indistinguishable from those directly released from the cell surface by proteolysis. The papain-derived TLa fragment exhibited most if not all the alloantigenic determinants.     

Isolation and characterization of rat plasma fibronectin.

Rat plasma fibronectin has been isolated and characterized and monospecific antibodies were prepared to it. Two components of fresh rat plasma (in the presence of proteinase inhibitors) bound to a gelatin-Sepharose affinity column. One protein was eluted with 4.0 M-urea and was identified as fibronectin. Another protein was eluted from the gelatin-Sepharose column with 8.0 M-urea and was identified as a 70 000-Mr collagen-binding molecule. This 70 000-Mr fragment was found to be a normal constituent of blood plasma, and its presence did not represent a proteolytic degradation product formed during isolation. The antibodies prepared against rat fibronectin only weakly cross-reacted with plasma fibronectins of chicken, horse and human. These studies shed light on the metabolic interrelationships between fibronectin and other collagen-binding molecules.     

Interchain disulfide bonding in the regulatory subunit of cAMP-dependent protein kinase I

The two protomers of the purified regulatory subunit from porcine cAMP-dependent protein kinase I have been shown to be covalently cross-linked by interchain disulfide bonding. Limited proteolysis which cleaves the polypeptide chain into two fragments demonstrated that the disulfide bonding was associated exclusively with the fragment that corresponded to the NH2-terminal region of the polypeptide chain. This NH2-terminal fragment accounted for approximately 15 to 20% of the molecule. The disulfide bonding was further characterized by alkylating the cysteines in the native regulatory subunit. Following oxidation with performic acid, each regulatory subunit contained 7 cysteic acid residues; however, under denaturing conditions, but without prior reduction, only 5 cysteine residues could be alkylated with iodoacetic acid. Following limited proteolysis, all five of these cysteines were associated with the larger COOH-terminal, cAMP binding domain. In contrast, if the denatured subunit was first reduced prior to alkylation, all 7 cysteine residues were alkylated. The 2 cysteines that were only accessible to alkylation after prior reduction were both associated with the NH2-terminal end of the polypeptide chain ultimately with a 5,400 peptide. Alkylation of the isolated, denatured NH2-terminal domain with iodoacetic acid resulted in no covalent modification unless the fragment was first reduced with dithiothreitol. The NH2-terminal and COOH-terminal domains were shown to be linked by a region of the polypeptide chain that is rich in both proline and arginine. It is the arginine-rich site that is readily prone to proteolytic cleavage.