Structure and proteolysis of the growth hormone receptor on rat hepatocytes

125I-Labeled human growth hormone is isolated in high molecular weight (Mr) (300,000, 220,000, and 130,000) and low molecular weight complexes on rat hepatocytes after affinity labeling. The time-dependent formation of low molecular weight complexes occurred at the expense of the higher molecular weight species and was inhibited by low temperature or inhibitors of serine proteinases. Exposure to reducing conditions induced loss of Mr 300,000 and 220,000 species and augmented the amount of Mr 130,000 complexes. The molecular weight of growth hormone (22,000) suggests that binding had occurred with species of Mr 280,000, 200,000, and 100,000. Two-dimensional gel electrophoresis demonstrated that the 100,000-dalton receptor subunit is contained in both the 280,000- and 200,000-dalton species. Reduction of interchain disulfide bonds in the growth hormone receptor did not alter its elution from gel filtration columns, but intact, high molecular weight receptor constituents were separated from lower molecular weight degradation products. Digestion of affinity-labeled growth hormone-receptor complexes with neuraminidase increased the mobility of receptor constituents on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. These observations show that the growth hormone receptor is degraded by hepatic serine proteinases to low molecular weight degradation products which can be separated from intact receptor by gel filtration. Intact hormone-receptor complexes are aggregates of 100,000-dalton sialoglycoprotein subunits held together by interchain disulfide bonds and by noncovalent forces.     

Characterization of the Antigenic Subunits of the Envelope Protein of Yersinia pestis

Chemical, physical, and immunological properties of the envelope antigen of Yersinia pestis strains have been investigated. The antigen consists of two components with isoelectric points (pI) of 4.6 and 4.8. One component (pI 4.6) is a protein bound to a small carbohydrate moiety identified as an oligomeric galactan; the other component (pI 4.8) is a simple protein. These two components are antigenically identical. In buffered solution, the antigen exists as aggregates of molecular weights larger than 300,000. The aggregates dissociate into a variety of smaller molecular weight forms depending on the nature of the treatment for dissociation. Each aggregate can be further dissociated into a single antigenic subunit fraction containing protein and glycoprotein species with molecular weights in the range from 15,000 to 17,000. The subunits can be obtained by a dissociation treatment with 0.1% mercaptoethanol in 0.25% sodium dodecyl sulfate at 95 C for 5 min. The subunits will readily reaggregate into a variety of larger molecular weight forms on the removal of dodecyl sulfate.     

Chemical cross-linking of heteromeric glucocorticoid receptors

Glucocorticoid receptors of wild-type and nti ("increased nuclear transfer") mutant S49.1 mouse lymphoma cells exist in extracts under low-salt conditions predominantly as high molecular weight species (Mr greater than or equal to 300,000). These receptor-hormone complexes are unable to bind to DNA. High salt (300 mM KCl) produces dissociated receptors of Mr 116,000 and 60-A Stokes radius (wild type) and Mr 60,000 and 38-A Stokes radius (nti mutant), both of which bind to DNA. We used reaction with bifunctional N-hydroxysuccinimide esters as well as oxidation with Cu2+/o-phenanthroline to stabilize the high molecular weight structures. These cross-linked complexes do not interact with DNA, but reductive cleavage again produces the dissociable receptor forms and restores their ability to bind to DNA. The protein modifying reagents iodoacetamide and diethyl pyrocarbonate also produce stabilized high molecular weight receptor complexes. Cross-linking of the high molecular weight receptor forms can also be achieved in intact cells. Immunochemical techniques were used to prove that the complexes cross-linked either in vivo or in cell extracts do contain the heat shock protein of Mr 90,000 as a common constituent. The data show that the high molecular weight receptor complexes are preexisting in intact cells and that dissociation generates DNA binding ability.     

Control of the formation of extracellular ribonuclease in Neurospora crassa.

A finding was made that a species of ribonuclease is released into mycelial culture media when a wild-type strain of Neurospora crassa was grown on limiting amounts of phosphate. The ribonuclease activity in the fully derepressed state extends to about 60 to 100 fold of that in the repressed state. The synthesis of the ribonuclease was inhibited by the addition of rifampicin, cycloheximide or orthophosphate. Three molecular species of the ribonuclease were found. Two enzyme fractions showing larger molecular weights were suspected to be aggregates containing the enzyme showing the smallest molecular weight (molecular weight of 10 300). All three fractions showed pH optima of around 7, preferential hydrolysis of polyguanylic acid and poor hydrolysis of guanosine 2',3',-cyclic monophosphate. These characteristics were the same as those of ribonuclease N1, and it was suggested that ribonuclease N1 is a repressible extracellular enzyme. Mutations in the genes nuc-1 and nuc-2 caused loss of ability to derepress this enzyme, but heterokaryon between them partially restored the ability. The nuc-1 mutation was epistatic to the nuc-2 alleles which are partly constitutive in the ribonuclease production.     

Isolation and translation of mRNA coding for the variant surface antigens of Paramecium.

In the poly(A)+RNA isolated from the ciliate Paramecium primaurelia is found a discrete and abundant mRNA species of high molecular weight (corresponding to about 9,000 nucleotides). This mRNA species has size and abundance characteristics that identify it tentatively as the message coding for the variant cell-surface antigens. After microinjection of the high molecular weight mRNA into amphibian oocytes, polypeptides are synthesized that are immunoprecipitated specifically with antibodies directed against the homologous Paramecium antigen. On collecting the culture medium of oocytes microinjected with Paramecium mRNA, newly-synthesized complete antigen molecules (Mr approximately 300,000) can be recovered by immunoprecipitation.     

Virion RNA species of the arenaviruses Pichinde, Tacaribe, and Tamiami.

The principal RNA species isolated from labeled preparations of the arenavirus Pichinde usually include a large viral RNA species L (apparent molecular weight = 3.2 X 10(6)), and a smaller viral RNA species S (apparent molecular weight = 1.6 X 10(6)). In addition, either little or considerable quantities of 28S rRNA as well as 18S rRNA can also be obtained in virus extracts, depending on the virus stock and growth conditions used to generate virus preparations. Similar RNA species have been identified in RNA extracted from Tacaribe and Tamiami arenavirus preparations. Oligonucleotide fingerprint analyses have confirmed the host ribosomal origin of the 28S and 18S species. Such analyses have also indicated that the Pichinde viral L and S RNA species each contain unique nucleotide sequences. Viral RNA preparations isolated by conventional phenol-sodium dodecyl sulfate extraction often have much of their L and S RNA species in the form of aggregates as visualized by either electron microscopy or oligonucleotide fingerprinting of material recovered from the top of gels (run by using undenatured RNA preparations). Circular and linear RNA forms have also been seen in electron micrographs of undenatured RNA preparations, although denatured viral RNA preparations have yielded mostly linear RNA species with few RNA aggregates or circular forms.     

Molecular structure of elongated forms of electric eel acetylcholinesterase.

Molecular forms of acetylcholinesterase extracted from fresh electric organ tissue of the electric eel are elongated structures in which a multi-subunit head is connected to a fibrous tail. The principal form, 18 S acetylcholinesterase, is of molecular weight approximately 1,050,000, contains about 12 catalytic subunits in its head, has a tail approximately 500 Å long, and aggregates reversibly at low ionic strength. Trypsin converts it to an 11 S globular tetramer devoid of the tail and lacking the capacity to aggregate in low-salt solutions.Amino acid analysis shows that elongated forms of acetylcholinesterase contain significant amounts of hydroxyproline and hydroxylysine, characteristic components of collagen, which are absent from 11 S acetylcholinesterase.Collagenase converts 18 S acetylcholinesterase to a 20 S form which no longer aggregates in low salt. Purified 20 S acetylcholinesterase has about half the hydroxyproline and hydroxylysine contents of the 18 S enzyme, and physicochemical measurements indicate the formation of a more symmetrical molecular structure without marked reduction in molecular weight.Sodium dodecyl sulfate/polyacrylamide gel electrophoresis without reducing agent shows that in 18 S acetylcholinesterase half the catalytic subunits are present as dimers linked by disulfide bonds. The remaining subunits migrate as larger molecular species which contain significant amounts of hydroxylysine, are specifically modified by collagenase and are converted to dimers and monomers by trypsin.Sodium dodecyl sulfate/acrylamide gel electrophoresis with reducing agent reveals, in 18 S acetylcholinesterase, two polypeptides of molecular weights 45,000 and 47,000 which are absent in the 11 S tetramer. They are readily digested by collagenase under conditions which do not affect the catalytic subunits, with concomitant formation of a new 30,000 polypeptide.The above data can be rationalized by a model in which 18 S acetylcholinestorase contains three subunit tetramers, each linked by disulfides to one strand of a collagen triple helix. Sodium dodecyl sulfate detaches those subunit dimers which are not covalently linked to the tail; trypsin attacks the distal portion of the collagen triple helix releasing discrete tetramers, and collagenase specifically attacks the triple helix near its midpoint, producing a shortened structure in which the residual tail still holds the tetramers together, but destroying the capacity for self-association at low ionic strength. This latter property may be related to the postulated role of the tail in anchoring acetylcholinesterase to the fibrillar matrix of the basement membrane.     

Properties and Ultrastructure of Phycoerythrin From Porphyridium cruentum

Phycoerythrin, a photosynthetic accessory pigment, was isolated from Porphyridium cruentum and examined by electron microscopy and disc gel electrophoresis. The absorption monomer, with maxima at 563, 545, and a shoulder at 500 nm, has a molecular weight of about 300,000. With phosphotungstic acid staining it appears as a tightly structured disc-shaped particle possessing a mean diameter of 101 ± 0.4Ä and height of 54 ± 0.7Å. The absorption maxima remained the same in glutaraldehyde fixed material, and in dimer and trimer aggregates. Treatment with sodium dodecyl sulfate caused a breakdown into smaller units accompanied by a loss of the 563 nm peak. It is suggested that this absorption monomer is the in vivo functional species and comparable to the phycocyanin hexamer, but structurally distinguishable at the ultrastructural level. It has been calculated that about 35 phycobiliprotein molecules can be contained within each phycobilisome. There are 1.4 × 10³ chlorophyll molecules per phycobilisome, but not contained within it.     

Heterogeneity of ovine prolactin after labeling with iodine 125: value of labeling with lactoperoxidase]

The authors have shown an heterogeneity of the ovine prolactine molecule after labelling with iodine 125. As well with chloramine T as with lactoperoxydase, it appears three molecular species which react with the immune serum antiprolactine (I.S.). The first species is of high molecular weight and is probably constituted of aggregates. Their combination with the I.S. is non specific and give blanks of high value. The second species is a dimere and the third one is the monomere. The two last species react with the I.S. and can give competition curves when they are choosen as tracer. However, if one uses as tracer a product obtained by labelling with chloramine T, the competition appears for high concentrations of native hormone. As if the I.S. recognizes much more the labelled protein than the native one. But if one uses the same species but labelled with lactoperoxydase, the competition appears for concentrations lower than five nanogrammes. In the same time one can see that the specificity toward different I.S. is modified. The authors think that the labelling with lactoperoxydase better preserves the tertiary structure of the native protein than do the labelling with chloramine T.     

Micelles of cerebroside sulphate

The critical micelle concentration of cerebroside sulphate in water is 0-01 mM: it increases with increasing concentrations of buffer to 0-07 mM in 0-1 M sodium acetate and formate buffers, pH 5-6 and 4-5 respectively. The partial specific volume of the micelles is about 0-94. The behaviour of the micelles in the ultracentrifuge and on Sephadex G-200 shows them to be grossly heterogeneous with respect to size. In 0-1 M buffer s20,w is about 26 S; in water or 0-01 M buffer smaller micelles with an s20,w of about 6 S are also present. In 0-01 M formate, pH 4-5, the smallest species detectable by equilibrium ultracentrifugation had a micellar weight of about 180,000 corresponding to an aggregation number of about 180. Much larger aggregates were also present. It is suggested that the smallest micelles are the substrate for sulphatase A when this is acting as a cerebroside sulphatase in buffers of low ionic strength.     

Purification and characterization of the amylase of B. subtilis NRRL B3411

The amylase of Bacillus subtilis NRRL B3411 has been purified and partially characterized. The specific activity can be increased from 300,000 units/g to 6,000,000 units/g with a 60% recovery of total units. The purified material consists of one major and one trace anodic component as determined by disc gel electrophoresis. The molecular weight was 48,000 as determined by bio-gel filtration; the molecular weight was 44,900 ± 2400 as determined by sedimentation equilibrium methods. This purified enzyme is stable at, 70°C in the presence of 0.01 M Ca⁺⁺ and 0.1 M NaCl over a broad pH range from 5.5–9.5. The pH activity profile indicates optimum activity at pH 6.0. This amylase exhibits maximum activity at 60°C. The enzyme is a liquefying α-amylase as determined by analysis of hydrolysis products and immunological studies.     

Regulation of uridine kinase quaternary structure. Dissociation by the inhibitor CTP

Uridine kinase from mouse Ehrlich ascites cells can exist in a variety of different aggregation states, from monomer up to aggregates that may contain 32 or more subunits. With very crude enzyme preparations, uridine kinase activity is always associated with several different coexisting molecular weight species. Changes in the aggregation state are produced in the presence of normal effectors (orthophosphate, ATP and CTP) at physiological concentrations. With uridine kinase that has been purified 9,000-fold, enzyme activity is associated with only a single molecular weight species, but is still responsive to the same physiological effectors. In the presence of orthophosphate, uridine kinase has a molecular weight of 380,000 (appropriate for a dodecamer). In the presence of CTP, the enzyme dissociates with concomitant loss of activity. The dissociated enzyme can be reassociated to the native size. These results imply that alteration of the enzyme's quaternary structure by normal effectors constitutes a mechanism for regulating uridine kinase activity in vivo.     

Characterization of cytoplasmic alpha-synuclein aggregates. Fibril formation is tightly linked to the inclusion-forming process in cells

The alpha-synuclein fibrillation process has been associated with the pathogenesis of several neurodegenerative diseases. Here, we have characterized the cytoplasmic alpha-synuclein aggregates using a fractionation procedure with which different aggregate species can be separated. Overexpression of alpha-synuclein in cells produce two distinct types of aggregates: large juxtanuclear inclusion bodies and small punctate aggregates scattered throughout the cytoplasm. Biochemical fractionation results in an inclusion-enriched fraction and two small aggregate fractions. Electron microscopy and thioflavin S reactivity of the fractions show that the juxtanuclear inclusion bodies are filled with amyloid-like alpha-synuclein fibrils, whereas both the small aggregate fractions contain non-fibrillar spherical aggregates with distinct size distributions. These aggregates appear sequentially, with the smallest population appearing the earliest and the fibrillar inclusions the latest. Based on the structural and kinetic properties, we suggest that the small spherical aggregates are the cellular equivalents of the protofibrils. The proteins that co-exist in the Lewy bodies, such as proteasome subunit, ubiquitin, and hsp70 chaperone, are present in the fibrillar inclusions but absent in the protofibrils, suggesting that these proteins may not be directly involved in the early aggregation stage. As predicted in the aggresome model, disruption of microtubules with nocodazole reduced the number of inclusions and increased the size of the protofibrils. Despite the increased size, the protofibrils remained non-fibrillar, suggesting that the deposition of the protofibrils in the juxtanuclear region is important in fibril formation. This study provides evidence that the cellular fibrillation also involves non-fibrillar intermediate species, and the microtubule-dependent inclusion-forming process is required for the protofibril-to-fibril conversion in cells.     

Purification of the 300K intermediate filament-associated protein and its in vitro recombination with intermediate filaments

IFAP-300K is a 300,000-mol-wt intermediate filament-associated protein previously identified in the baby hamster kidney fibroblastic cell line (BHK-21) by a monoclonal antibody (Yang H.-Y., N. Lieska, A. E. Goldman, and R. D. Goldman, 1985, J. Cell Biol., 100: 620-631). In the present study, this molecule was purified from the high salt/detergent-insoluble cytoskeletal preparation of these cells. Gel filtration on Sephacryl S-400 in the presence of 7.2 M urea allowed separation of the high molecular weight fraction from the structural intermediate filament (IF) subunits desmin and vimentin, designated 54K and 55K, respectively, and other low molecular weight polypeptides. DE-52 cellulose chromatography of the high molecular weight fraction using a linear NaCl gradient in 8 M urea yielded a pure 300,000-mol-wt species which was confirmed to be IFAP-300K by immunological and peptide mapping criteria. Two-dimensional PAGE of native BHK IF preparations followed by immunoblot analysis demonstrated the inability of the IFAP-300K-immunoreactive material to enter the first dimensional gel except as a 200,000-mol-wt doublet which presumably represented a major proteolytic derivative of IFAP-300K. The molecule's pl of 5.35, as determined by chromatofocusing, and its amino acid composition were extremely similar to those of BHK cell vimentin/desmin despite their non-identity. Ultrastructurally, IFAP-300K preparations in low salt buffers existed as particles composed of one or two elliptical units measuring 16 X 20 nm. In physiological salt buffers, the predominant entities were large, elongated aggregates of the elliptical units, which were able to be decorated by using the immunogold technique with monoclonal anti-IFAP-300K. Compared with the morphology of homopolymer vimentin IF, in vitro recombination studies using column-purified vimentin and IFAP-300K demonstrated the additional presence of aggregates similar in appearance to IFAP-300K at points of contact between IFs. Antibody decoration and immunogold labeling of these recombined preparations using rabbit antidesmin/vimentin and monoclonal anti-IFAP-300K confirmed the identity of the inter-filament, amorphous material as IFAP-300K. The presence of IFAP-300K at many points of intersection and lateral contact between IFs, as well as at apparent inter-filament "bridges," in these recombined specimens was identical to that seen both in situ and in native IF preparations. No such co-sedimentation was found in vitro between actin and IFAP-300K. No effects of IFAP-300K upon the kinetics of IF polymerization were detected by turbidimetric measurements.     

Quaternary structure changes and kinetics of urease inactivation by L-usnic acid in relation to the regulation of nutrient transfer between lichen symbionts

Abstract L-usnic acid inactivates urease by the formation of high molecular weight aggregates which can reach a maximum of 700,000 under experimentation conditions previously described. The substrate, urea, itself provokes temporary aggregation states which may be either active or inactive; the latter being reversible. However, these inactive aggregates, of 820,000 molecular weight, are irreversibly stabilized by L-usnic acid. The active aggregates with molecular weights oscillating from 605,000 to 650,000, depending on whether they are formed in the presence or absence of inactivator, may combine with the substrate to form an apparently normal ES complex.     

The size and genetic composition of virus-specific RNAs in the cytoplasm of cells producing avian sarcoma-leukosis viruses.

The genome of avian sarcoma virus (ASV) contains four known genes: gag, encoding structural proteins of the viral core; pol, encoding the viral RNA-directed DNA polymerase; env, encoding the glycoprotein(s) of the viral envelope; and src, which is responsible for neoplastic transformation of the host cell. We have located these genes on virus-specific RNAs in cells productively infected with both nondefective and defective strains of ASV by using molecular hybridization with DNAs complementary to specific portions of the ASV genome.The cytoplasm of cells producing nondefective ASV contains three species of polyadenylated virus-specific RNA, each of which has chemical polarity identical to that of the viral genome. The largest species has a molecular weight of 3.3 × 10⁶ daltons and a sedimentation coefficient of 38S, encodes all four viral genes, and is probably identical to the viral genome. A second species has a molecular weight of 1.8 × 10⁶ daltons and a sedimentation coefficient of 28S, and encodes the 3′ half of the viral genome, including env, src and a genetically silent region known as “c.” The smallest species has a molecular weight of 1.2 × 10⁶ daltons and a sedimentation coefficient of 21S, and encodes only src and “c.” All three species of virus-specific RNA contain nucleotide sequences at least partially homologous to a sequence of 101 nucleotides found at the extreme 5′ end of the ASV genome. This sequence may not be present in the portions of the ASV genome which encode the 28S and 21S virus-specific RNAs, and hence may be joined to these RNAs during their maturation from precursor molecules.The size and genetic composition of virus-specific RNAs in cells producing defective deletion mutants reflect the nature of the deletion. Deletions of either src or env eliminate the 28S virus-specific RNA, leaving a 21S RNA (which contains either env and “c” in the case of src deletions or src and “c” in the case of env deletions) and a 35S RNA which is probably identical to the viral genome.Based on these and related results, we propose a model for viral gene expression which conforms to previous suggestions that eucaryotic cells initiate translations only at the 5′ termini of messenger RNAs.     

Quantitative analysis of the protein composition of yeast ribosomes

The molecular weights of the individual yeast ribosomal proteins were determined. The ribosomal proteins from the 40-S subunit have molecular weights ranging from 11 800 to 31 000 (average molecular weight = 21 300). The molecular weights of the 60-S subunit proteins range from 10 000 to 48 400 (average molecular weight = 21 800). Stoichiometric measurements, performed by densitometric scanning on ribosomal proteins extracted from high-salt dissociated subunits revealed that isolated ribosomal subunits contain, besides some protein species occurring in submolar amounts, a number of protein species which are present in multiple copies: S13, S27, L22, L31, L33, L34 and L39. The mass fractions of the ribosomal proteins which were found to be present on isolated ribosomes in non-unimolar amounts, were re-examined by using an isotope dilution technique. Applying this method to proteins extracted from mildely isolated 80-S ribosomes, we found that some protein species such as S32, S34 and L43 still are present in submolar amounts. On the other hand, however, we conclude that some other ribosomal proteins, in particular the strongly acidic proteins L44 and L45 get partially lost during ribosome dissociation. Proteins L44/L45 appears to be present on 80-S ribosomes in three copies.     

Characterization of methylprednisolone esters of hyaluronan in aqueous solution: conformation and aggregation behavior

Methylprednisolone steroid esters of hyaluronan differing in degree of functionalization and molecular weight were investigated in aqueous solution. Conformation and aggregation phenomena were elucidated by means of circular dichroism, viscometry, rheology, and nuclear magnetic resonance, mainly by (1)H pulsed field gradient (PFG) NMR, which allows the determination of the diffusion coefficient of the species under investigation. The functionalization of hyaluronan with the steroid induces a reduction of the molecular volume, as a consequence of intramolecular hydrophobic interactions. For concentrated samples we have observed the coexistence of unimolecular collapsed chains and of aggregates, the latter disappearing upon dilution. The methylprednisolone ester of lower molecular weight hyaluronan has a larger molecular volume than its higher molecular weight analogue, even though still smaller than the underivatized polymer. This effect can be explained with the reduced flexibility of the polymer backbone probably impairing intramolecular interactions.     

Length heterogeneity of amplified circular rDNA molecules in oocytes of the house cricket Acheta domesticus (Orthoptera: Gryllidae)

Amplification of the genes coding for rRNA occurs in the oocytes of a wide variety of organisms. The amplification process appears to be mediated through a rolling-circle mechanism. The approximate molecular weight of the smallest rDNA circles is equivalent to the estimated combined molecular weight of DNA which codes for a single ribosomal RNA precursor molecule and an associated non-transcribed spacer DNA sequence. RNA-DNA hybridization studies carried out on oocytes of the house cricket, Acheta domesticus, suggest that DNA coding for rRNA accounts for only a small fraction of the rDNA satellite, all of which is amplified in the oocyte. In order to test the possibility that the remainder of the amplified rDNA represents spacer and to determine whether a rolling-circle mechanism might also be involved in amplification in A. domesticus oocytes, rDNA was isolated from ovaries of A. domesticus and spread for electron microscopy. A large proportion of the rDNA isolated from ovaries is circular, while main-band DNA and rDNA prepared from other tissues demonstrates few if any circles. The mean size of the smallest rDNA circles is approximately 8 times longer than the length estimated for DNA which codes for 18 S and 28 S rRNA. Denaturation mapping shows the rDNA circles to contain two major readily denaturing regions located about equidistant from one another on the circle. Each readily denaturing region accounts for 4–6% of the total DNA in the circle. The fact that only 12% of the average molecule is required to code for A. domesticus 18 S and 28 S rRNA is consistent with the hybridization data. Considerable size heterogeneity exists in the length of the smallest class of rDNA molecules. In the rDNA of other species such heterogeneity has been shown to reside in the non-transcribed spacer.     

Plasmid profile types of virulent and avirulent strains of phase-I Shigella sonnei and their rough phase-II and R-form variants

The study of S. sonnei in phase I, irrespective of their virulence, has revealed the existence of at least 3 types of profiles of large plasmids: (I)A having a single plasmid with a molecular weight of about 120 MD; (I)B having, alongside plasmid pSS120, a plasmid with a molecular weight of about 60 MD; (I)C, represented only by vaccine strain 6S, having three plasmids with molecular weights of about 80, 60 and 37 MD. The plasmid profiles of rough S. sonnei in phase II are characterized by the absence of large plasmids with a molecular weight of 120-80 MD, typical of bacteria in phase I, and can be in their turn subdivided, in accordance with the type of the initial culture, into three subvariants (II)A, (II)B and (II)C. The plasmid profiles of rough S. sonnei (R-forms and phase II) completely coincide. The biosynthesis of the specific antigen of S. sonnei in phase I can be determined by smaller derivatives obtained from large plasmid pSS120 by deletion (e.g., by a plasmid with a molecular weight of about 80 MD, such as plasmid pSS80).