Domains of colicin M involved in uptake and activity

Colicin M inhibits murein biosynthesis by interfering with bactoprenyl phosphate carrier regeneration. It belongs to the group B colicins the uptake of which through the outer membrane depends on the TonB, ExbB and ExbD proteins. These colicins contain a sequence, called the TonB box, which has been implicated in transport via TonB. Point mutations were introduced by PCR into the TonB box of the structural gene for colicin M, cma, resulting in derivatives that no longer killed cells. Mutations in the tonB gene suppressed, in an allele-specific manner, some of the cma mutations, suggesting that interaction of colicin M with TonB may be required for colicin M uptake. Among the hydroxylamine-generated colicin M-inactive cma mutants was one which carried cysteine in place of arginine at position 115. This colicin derivative still bound to the FhuA receptor and killed cells when translocated across the outer membrane by osmotic shock treatment. It apparently represents a new type of transport-deficient colicin M. Additional hydroxylamine-generated inactive derivatives of colicin M carried mutations centered on residues 193-197 and 223-252. Since these did not kill osmotically shocked cells the mutations must be located in a region which is important for colicin M activity. It is concluded that the TonB box at the N-terminal end of colicin M must be involved in colicin uptake via TonB across the outer membrane and that the C-terminal portion of the molecule is likely to contain the activity domain.

A carboxy-terminal fragment of colicin Ia forms ion channels

A carboxy-terminal, 18 kD fragment of colicin Ia, a bacterial toxin, forms ion channels in artificial phospholipid bilayers. This fragment, which comprises a quarter of the intact 70 kD molecule, is resistant to extensive protease digestion and probably constitutes a structural domain of the protein. The ion channels formed by the 18 kD fragment are functionally heterogeneous, having conductances that range from 15 to 30 pS at positive voltages and from 70 to 250 pS at negative voltages, and open lifetimes that range from at least 25 msec to 5 sec. In contrast, ion channels formed by whole colicin Ia open only at negative voltages, at which their conductances range from 6 to 30 pS, and their open lifetimes range from 1 sec to 3 min. Additionally, the open state of the 18 kD fragment channel is characterized by noisy fluctuations in current, while the open state of the whole molecule ion channel is often marked by numerous, stable subconductance states. Since the properties of the fragment channel differ substantially from those of the whole molecule channel, we suggest that portions of the molecule outside of the 18 kD fragment are involved in forming the whole molecule ion channel.

Intramembrane helix-helix interactions as the basis of inhibition of the colicin E1 ion channel by its immunity protein

It had previously been hypothesized that the ability of a small number of immunity protein molecules in the cytoplasmic membrane to confer protection against the lethal effects of a channel-forming colicin involves a complex stabilized by electrostatic or polar interactions between immunity protein, the colicin channel, and specific sites on the cytoplasmic membrane surface defined by the presence of the tol gene translocation proteins. The hypothesis was tested (a) by constructing a hybrid colicin molecule, IaE1, containing the E1 channel domain, and the translocation and receptor domains of Ia, and (b) by altering charged residues in all peripheral regions of the immunity protein to neutral residues. It was concluded that the specificity of immunity protein requires neither specific translocation proteins, nor a specific arrangement of charged residues in the immunity protein. (c) In addition, by making 65 site-directed mutations, "immunity by-pass" mutants were found at five different loci, Ala474, Ser477, His440, Phe443, and Gly444, on two proposed membrane-spanning helices of the open colicin channel, one hydrophobic (A471-A488) and one amphiphilic (V441-W460). The mutants in the hydrophobic helix showed a larger bypass effect. The "bypass" phenotype could be assayed by (i) cytotoxicity and (ii) K+ efflux in imm+ cells caused by a bypass mutant but not wild-type colicin. It is concluded that the immunity protein exerts its specific effect through rapid lateral diffusion in the cytoplasmic membrane and helix-helix recognition and interaction with at least one hydrophobic and one amphiphilic trans-membrane helix of the colicin channel. Interaction with the amphiphilic helix implies that the immunity protein can react with the channel in the open state.

Subunit interactions provide a significant contribution to the stability of the dimeric four-alpha-helical-bundle protein ROP

Detailed thermodynamic and spectroscopic studies were carried out on the ColE1-ROP protein in order to establish a quantitative basis for the contribution of noncovalent interactions to the stability of four-helix-bundle proteins. The energetics of both heat- and GdnHCl-induced denaturation were measured by differential scanning microcalorimetry (DSC) and/or by following the change in circular dichroism in the far-UV range. Sedimentation equilibrium analyses were performed to characterize the state of aggregation of the protein. No intermediate species could be detected during thermal unfolding of the dimer in the absence of GdnHCl. Under these conditions ROP unfolding exhibits a strict two-state behavior. The thermodynamic parameters for the reaction N2<->2D are delta HD = 580 +/- 20 kJ.(mol of dimer)-1, delta Cp = 10.3 +/- 1.3 kJ.(mol of dimer)-1.K-1, and Tm = 71.0 +/- 0.5 degrees C. The corresponding Gibbs energy change of unfolding is delta GD degree = 71.7 kJ.(mol of dimer)-1 at 25 degrees C and pH 6. In the presence of 2.5 M GdnHCl, however, ROP dissociates into monomers at elevated temperatures, as the loss of the concentration dependence of Tm and the decreased molecular weight demonstrate. The corresponding transition parameters are delta HD (2.5 M GdnHCl) = 130 +/- 10 kJ.(mol of monomer)-1 and Tm = 51.6 +/- 0.3 degrees C. Isothermal unfolding studies at 19 degrees C using GdnHCl as denaturant yielded a Gibbs energy change of unfolding of 22.4 kJ.(mol of monomer)-1. This extrapolated value is 38% lower than the corresponding delta GD degree value of 35.85 kJ.(mol of monomer)-1 calculated from thermal unfolding for the monomer in the absence of GdnHCl, where the protein is known to be a dimer. These results suggest that subunit interactions are an important source of stabilization of the native four-helix-bundle structure of ROP.

Fluorescence energy transfer distance measurements. The hydrophobic helical hairpin of colicin A in the membrane bound state

The ion-channel-forming C-terminal fragment of colicin A binds to negatively charged lipid vesicles and provides an example of the insertion of a soluble protein into a lipid bilayer. The soluble structure is known and consists of a ten-helix bundle containing a hydrophobic helical hairpin. In this study fluorescence resonance energy transfer spectroscopy was used to determine the position of this helical hairpin in the membrane bound state. An extrinsic probe, N'-(iodoacetyl)-N'-(5-sulpho-1-naphthyl)ethylenediamine (I-AEDANS) was attached to mutant proteins each of which bears a unique cysteine residue. Five mutants I26C (helix 1), F105C (between helices 4 and 5), G166CJ (helix 8), A169C (helix 8-9), G176C (helix 9) were used. All mutants show wild-type binding activity to phosphatidylglycerol vesicles as judged by fluorescence polarization anisotropy, emission wavelength changes and brominated lipid quenching. The three tryptophan residues were used as a compound donor to AEDANS in resonance energy transfer distance determinations. The distances obtained for the soluble form were equal to those found in the crystal structure. On adding vesicles under conditions where intermolecular transfer was avoided the indicated distances increased; I26(10.9 A) F105(3.4 A), G166(3.3 A), A169(1.9 A) and G176(2.9 A). This confirms that, in the absence of a membrane potential, helices 1 and 2 open out onto the membrane surface whilst the helical hairpin remains closely packed against the rest of the structure. The insertion of this hairpin is thus not the driving force behind colicin membrane binding.

Colicin Ia inserts into negatively charged membranes at low pH with a tertiary but little secondary structural change

Colicin Ia, a member of the channel-forming family of colicins, inserts into model membranes in a pH- and lipid-dependent fashion. This insertion occurs with single-hit kinetics, requires negatively charged lipids in the target membrane, and increases in rate as the pH is reduced below 5.2. The low-pH requirement does not act by inducing a secondary structural change in colicin Ia, which remains 66% +/- 4% alpha-helical between pHs 7.3 and 3.1 as determined by circular dichroism. The secondary structure also remains unchanged between pHs 7.3 and 4.2 in the hydrophobic environment provided by the detergent octyl beta-D-glucopyranoside (beta-OG). However, at pH 3.1 in the presence of beta-OG, an 11% +/- 3% decrease in the alpha-helical content is observed. Further, beta-OG induces a change in tryptophan fluorescence and an altered pattern of proteolytic digestion, indicative of a tertiary structural changes. This suggests that colicin Ia undergoes a tertiary but little or no secondary structural change in its transition from a soluble to a transmembrane protein.

Colicin E1 binding to membranes: time-resolved studies of spin-labeled mutants

To investigate the mechanism of interaction of the toxin colicin E1 with membranes, three cysteine substitution mutants and the wild type of the channel-forming fragment were spin labeled at the unique thiol. Time-resolved interaction of these labeled proteins with phospholipid vesicles was investigated with stopped-flow electron paramagnetic resonance spectroscopy. The fragment interacts with neutral bilayers at low pH, indicating that the interaction is hydrophobic rather than electrostatic. The interaction occurs in at least two distinct steps: (i) rapid adsorption to the surface; and (ii) slow, rate-limiting insertion of the hydrophobic central helices into the membrane interior.

pH-dependent stability and membrane interaction of the pore-forming domain of colicin A

Thermal stability of the pore-forming domain of colicin A was studied by high sensitivity differential scanning calorimetry and circular dichroism spectroscopy. In the pH range between 8 and 5, the thermal denaturation of the protein in solution occurs at 66-69 degrees C and is characterized by the calorimetric enthalpy of approximately 90 kcal/M. At pH below 5, there is a rapid pH-dependent destabilization of the pore-forming domain resulting in the lowering of the midpoint denaturation temperature and a decrease in the calorimetric enthalpy of denaturation. Circular dichroism spectra in the near and far ultraviolet show that the thermotropic transition is associated with collapse of the native tertiary structure of the pore-forming domain, although a large proportion of the helical secondary structure remains preserved. The present data indicate some similarity also between acid-induced and temperature-induced denaturation of the pore-forming domain of colicin A. Association of the pore-forming domain with phospholipid vesicles of dioleoylphosphatidylglycerol results in total disappearance of the calorimetric transition, even at pH values as high as 7. Since lipid binding also induces collapse of the near ultraviolet circular dichroism spectrum, these data indicate that interaction with the membrane facilitates a conformational change within the pore-forming domain to a looser (denaturated-like) state. These findings are discussed in relation to the recent model (van der Goot, F. G., Gonzalez-Manas, J. M., Lakey, J. H., Pattus, F. (1991) Nature 354, 408-410) which postulates that a flexible "molten globule" state is an intermediate on the pathway to membrane insertion of colicin A.

Structural alignment of globins, phycocyanins and colicin A

A database search employing a novel algorithm for protein structure comparison by alignment of distance matrices has revealed a striking resemblance between the tertiary structures of the bacterial toxin colicin A and globins. The globin-like domain in colicin A contains all elements essential for the toxin's lethal ionophoric activity. The structural similarity between colicin A and globins is comparable to that between globins and phycocyanins. This suggests that these three protein families, which have unrelated sequences and different functional contexts, are an example of physical convergence to a stable folding motif, the three-on-three helical sandwich.

Constraints imposed by protease accessibility on the trans-membrane and surface topography of the colicin E1 ion channel

The surface topography of a 190-residue COOH-terminal colicin E1 channel peptide (NH2-Met 333-Ile 522-COOH) bound to uniformly sized 0.2-micron liposomes was probed by accessibility of the peptide to proteases in order (1) to determine whether the channel structure contains trans-membrane segments in addition to the four alpha-helices previously identified and (2) to discriminate between different topographical possibilities for the surface-bound state. An unfolded surface-bound state is indicated by increased trypsin susceptibility of the bound peptide relative to that of the peptide in aqueous solution. The peptide is bound tightly to the membrane surface with Kd < 10(-7) M. The NH2-terminal 50 residues of the membrane-bound peptide are unbound or loosely bound as indicated by their accessibility to proteases, in contrast with the COOH-terminal 140 residues, which are almost protease inaccessible. The general protease accessibility of the NH2-terminal segment Ala 336-Lys 382 excludes any model for the closed channel state that would include trans-membrane helices on the NH2-terminal side of Lys 382. Lys 381-Lys 382 is a major site for protease cleavage of the surface-bound channel peptide. A site for proteinase K cleavage just upstream of the amphiphilic gating hairpin (K420-K461) implies the presence of a surface-exposed segment in this region. These protease accessibility data indicate that it is unlikely that there are any alpha-helices on the NH2-terminal side of the gating hairpin K420-K461 that are inserted into the membrane in the absence of a membrane potential. A model for the topography of an unfolded monomeric surface-bound intermediate of the colicin channel domain, including a trans-membrane hydrophobic helical hairpin and two or three long surface-bound helices, is proposed.

Acidic interaction of the colicin A pore-forming domain with model membranes of Escherichia coli lipids results in a large perturbation of acyl chain order and stabilization of the bilayer

2H and 31P NMR techniques were used to study the effects on acyl chain order and lipid organization of the well-characterized pore-forming domain of colicin A (20-kDa thermolytic fragment of colicin A) upon insertion in model membrane systems derived from the Escherichia coli fatty acid auxotrophic strain K 1059, which was grown in the presence of [11,11-2H2]-labeled oleic acid. Addition of the protein to dispersions of the E. coli total lipid extract, in a 1/70 molar ratio of peptide to lipids, resulted in a large pH-dependent decrease in quadrupolar splitting of the 2H NMR spectra. The decrease of the quadrupolar splitting obtained at the various pH values was correlated with the pH dependence of the insertion of the protein in monolayer films using the same E. coli lipid extracts. The pK governing the perturbing effects on the order of the fatty acyl chains was around 5, in agreement with the values of the pH-dependent conformational changes of the pore-forming domain of colicin A required for membrane insertion as reported by van der Goot et al. [(1991) Nature 354, 408-410]. 31P NMR measurements show that the bilayer organization remains intact upon addition of the protein to dispersions of lipid extract. Surprisingly, 31P NMR measurements as a function of temperature indicate that the pore-forming domain of colicin A even stabilizes bilayer lipid structure at pH 4. Both the large effect of the protein on acyl chain order and its bilayer-stabilizing activity are indicative of a surface localization of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)

An alpha-helical hydrophobic hairpin as a specific determinant in protein-protein interaction occurring in Escherichia coli colicin A and B immunity systems

A collection of chimeric pore-forming domains between colicins A and B was constructed to investigate the specific determinants responsible for recognition by the corresponding immunity proteins. The fusion sites in the hybrid proteins were positioned according to the three-dimensional structure of the soluble form of the colicin A pore-forming domain. The hydrophobic hairpin of colicin pore-forming domains, buried in the core of the soluble structure, was the main determinant recognized by the integral immunity proteins. The immunity protein function may require helix-helix recognition within the lipid bilayer.

Dynamic properties of the colicin E1 ion channel

The mechanism of channel formation and action of channel-forming colicins is a paradigm for the study of dynamic aspects of membrane-protein interactions. The following experimental results concerning interaction of the colicin E1 channel domain with target membranes, in vitro and in vivo, are discussed: (1) the nature of the translocation-competent state of the channel-forming domain; (2) unfolding of the colicin channel peptide during in vitro binding and anchoring of the channel to liposome membranes at acidic pH; (3) reversal of channel peptide binding to liposomes by an alkaline-directed pH shift; (4) voltage-driven translocation and gating of the ion channel, discussed in the context of a four-helix model for a monomeric channel; (5) rescue of colicin-treated cells by high levels of external K+; (6) trypsin rescue of cells depolarized by the colicin ion channel; and (7) interaction of the channel domain with its immunity protein.

Brominated phospholipids as a tool for monitoring the membrane insertion of colicin A

The intrinsic fluorescence of the colicin A thermolytic fragment does not change after insertion into normal phospholipid vesicles and is thus an unsuitable probe for monitoring the membrane insertion process. In this paper, we report the results of studies on the quenching of this fluorescence by brominated dioleoylphosphatidylglycerol (Br-DOPG) vesicles. Bromine atoms located at the midpoint of the phospholipid acyl chain quench the tryptophan fluorescence, indicating contact between fluorophores of the protein and the bilayer's hydrophobic core. Addition of Br-DOPG vesicles to a protein solution quenches the tryptophan fluorescence in a time-dependent manner. This quenching can be fitted to a single-exponential function, and thus interpreted as a one-step process. This allows calculation of an apparent rate constant of protein insertion into the membrane. Parameters known to affect the insertion of the thermolytic fragment into phospholipid monolayers or vesicles (pH and negative charge density) also affect the rate constant in comparable ways. In addition to the information gained concerning membrane exposure in the steady state, this approach provides the first real-time method for measuring the insertion of colicin into membranes. It is highly quantitative and can be used on all versions of the protein, e.g., full size, proteolytic fragments, and mutants. Brominated lipids provide experimental conditions identical to normal lipids and allow for great flexibility in protein/lipid ratios and concentrations. The kinetic analysis shows clearly the existence of a two-step process involving a rapid adsorption of the protein to the lipid surface followed by a slow insertion.

The membrane insertion of colicins

Pore-forming toxins, such as colicin A, are water-soluble proteins that insert into lipid bilayers. The water-soluble structure of Colicin A is known at a high resolution and this review describes the kinetic and structural steps involved in its soluble-to-membrane bound transformation.

A fusion plasmid for the synthesis of lipopeptide-antigen chimeras in Escherichia coli

Lipopeptides are potential vaccine candidates with a built-in adjuvant property. To circumvent the present chemical route of synthesis for lipopeptide-antigen conjugates, the lipoprotein property of the pColE2-P9-encoded lysis protein, CelB, was used to create the bacterial fusion plasmid, pKLY3, to produce lipopeptide-antigen chimeras in Escherichia coli. Plasmid pKLY3 is a derivative of pKK233-2 with the origin of replication of the single-stranded DNA phage, fl. Under control of the promoter, ptrc, is the 5' end of the celB gene coding for a lipoprotein signal peptide and the first five amino acids (aa) (CQANY) of the mature lysis protein. As model systems for the synthesis of small and large lipopeptide-antigens, DNA sequences coding for the P2 peptide and E. coli alkaline phosphatase (PhoA) were fused in frame to the region of celB coding for a lipoprotein signal peptide and CQANY. P2 is a 12-aa peptide including a tyrosine phosphorylation site of the epidermal growth factor receptor (EGF-R). Inducible expression of stable lipohexapeptide CQANYV, lipo-CQANY-P2, and lipo-CQANYA-PhoA, was demonstrated. Similar expression was obtained for lipo-CIEGR-P2 and lipo-CIEGRA-PhoA in which IEGR is a cleavage recognition site for the blood coagulation factor, Xa. Like QANY, IEGR is predicted to form a beta-turn structure. The presence of a lipid moiety on the products was confirmed by demonstrating the incorporation of radioactive palmitic acid and inhibition of processing by globomycin. The lipid-modified peptides were also identified by incorporation of radioactive tyrosine, and the nature of the P2 peptide was verified immunologically.(ABSTRACT TRUNCATED AT 250 WORDS)

The secondary structure of the colicin E3 immunity protein as studied by 1H-1H and 1H-15N two-dimensional NMR spectroscopy

By performing 1H-1H and 1H-15N two-dimensional (2D) nuclear magnetic resonance (NMR) experiments, the complete sequence-specific resonance assignment was determined for the colicin E3 immunity protein (84 residues; ImmE3), which binds to colicin E3 and inhibits its RNase activity. First, the fingerprint region of the spectrum was analyzed by homonuclear 1H-1H HOHAHA and NOESY methods. For the identification of overlapping resonances, heteronuclear 1H-15N (HMQC-HOHAHA, HMQC-NOESY) experiments were performed, so that the complete 1H and 15N resonance assignments were provided. Then the secondary structure of ImmE3 was determined by examination of characteristic patterns of sequential backbone proton NOEs in combination with measurement of exchange rates of amide protons and 3JHN alpha coupling constants. From these results, it was concluded that ImmE3 contains a four-stranded antiparallel beta-sheet (residues 2-10, 19-22, 47-49, and 71-79) and a short alpha-helix (residues 31-36).

Refined structure of the pore-forming domain of colicin A at 2.4 A resolution

The E1 subgroup (E1, A, B, IA, IB, K and N) of anti-bacterial toxins called colicins is known to form voltage-dependent channels in lipid bilayers. The crystal structure of the pore-forming domain of colicin A from Escherichia coli has been refined to the diffraction limit of the crystals at 2.4 A resolution by means of molecular dynamics and restrained least-squares methods to a conventional R-factor of 0.18 for all data between 6.0 and 2.4 A resolution. The polypeptide chain of 204 amino acid residues consists of ten alpha-helices organized in a three-layer structure. The helices range in length from 9 to 23 residues with an average length of 125 residues. The packing arrangement of the helices has been analysed; the packing is different from that observed in four-helix bundle proteins. The sites of 83 water molecules have been located and refined. Analysis of the structure provides insights into the mechanism of formation of a voltage-gated channel by the protein. Although it is proposed that substantial tertiary structural changes occur during membrane insertion, the secondary structural elements remain conserved. This idea has been proposed recently for a number of other protein-membrane events and thus may have more general applicability.

Colicin A unfolds during its translocation in Escherichia coli cells and spans the whole cell envelope when its pore has formed

The addition of the pore forming colicin A to Escherichia coli cells results in an efflux of cytoplasmic potassium. This efflux is preceded by a lag time which is related to the time needed for the translocation of the toxin through the envelope. Denaturing the colicin A with urea, before adding it to the cells, did not affect the properties of the pore but decreased the lag time. After renaturation, the lag time was similar to that of the native colicin. This suggests that the unfolding of colicin A accelerates its translocation. The addition of trypsin, which has access neither to the periplasmic space nor to the cytoplasmic membrane, resulted in an immediate arrest of the potassium efflux induced by colicins A and B. The possibility that trypsin may act on a bacterial component required for colicin reception and/or translocation was ruled out. It is thus likely that the arrest of the efflux corresponds to a closing of the pores. This long distance effect of trypsin suggests that part of the polypeptide chain of the colicins may still be in contact with the external medium even when the pore has formed in the inner membrane.

Secondary structure of the membrane-bound form of the pore-forming domain of colicin A. An attenuated total-reflection polarized Fourier-transform infrared spectroscopy study

The structure of the pore-forming domain of the bacterial toxin colicin A was studied by attenuated total-reflection polarized Fourier-transform infrared spectroscopy. This channel-forming fragment interacts with dimyristoylglycerophosphoglycerol (Myr2GroPGro) vesicles and forms disk-like complexes. Analysis of the shape of the amide I' band indicates that its secondary structure is not affected by the pH 5.0-7.2. However, 5-10% of the peptide amino acids adopt an alpha-helical structure upon complex formation with Myr2GroPGro, while the random-coil and beta-sheet structure contents decrease. Interestingly, the increase in alpha-helical content is essentially due to an increase in the high-frequency component of the alpha-helical domain of amide I'. The fact that only this component was 90 degrees polarized (i.e. the helix is parallel to the acyl chain) suggests that only this particular type of helix is associated with the Myr2GroPGro bilayer.

A 'molten-globule' membrane-insertion intermediate of the pore-forming domain of colicin A

The 'molten' globular conformation of a protein is compact with a native secondary structure but a poorly defined tertiary structure. Molten globular states are intermediates in protein folding and unfolding and they may be involved in the translocation or insertion of proteins into membranes. Here we investigate the membrane insertion of the pore-forming domain of colicin A, a bacteriocin that depolarizes the cytoplasmic membrane of sensitive cells. We find that this pore-forming domain, the insertion of which depends on pH, undergoes a native to molten globule transition at acidic pH. The variation of the kinetic constant of membrane insertion of the protein into negatively charged lipid vesicles as a function of the interfacial pH correlates with the appearance of the acidic molten globular state, indicating that this state could be an intermediate formed during the insertion of colicin A into membranes.

Molecular and genetic analysis of a region of plasmid pCF10 containing positive control genes and structural genes encoding surface proteins involved in pheromone-inducible conjugation in Enterococcus faecalis

Exposure of Enterococcus faecalis cells carrying the tetracycline resistance plasmid pCF10 to the heptapeptide pheromone cCF10 results in an increase in conjugal transfer frequency by as much as 10(6)-fold. Pheromone-induced donor cells also express at least two plasmid-encoded surface proteins, the 130-kDa Sec 10 protein, which is involved in surface exclusion, and the 150-kDa Asc10 protein, which has been associated with the formation of mating aggregates. Previous subcloning and transposon mutagenesis studies indicated that the adjacent EcoRI c (7.5 kb) and e (4.5 kb) fragments of pCF10 encode the structural genes for these proteins and that the EcoRI c fragment also encodes at least two regulatory genes involved in activation of the expression of the genes encoding Asc10 and Sec10. In this paper, the results of physical and genetic analysis of this region of pCF10, along with the complete DNA sequences of the EcoRI c and e fragments, are reported. The results of the genetic studies indicate the location of the structural genes for the surface proteins and reveal important features of their transcription. In addition, we provide evidence here and in the accompanying paper (S. B. Olmsted, S.-M. Kao, L. J. van Putte, J. C. Gallo, and G. M. Dunny, J. Bacteriol. 173:7665-7672, 1991) for a role of Asc10 in mating aggregate formation. The data also reveal a complex positive control system that acts at distances of at least 3 to 6 kb to activate expression of Asc10. DNA sequence analysis presented here reveals the positions of a number of specific genes, termed prg (pheromone-responsive genes) in this region of pCF10. The genes mapped include prgA (encoding Sec10) and prgB (encoding Asc10), as well as four putative regulatory genes, prgX, -R, -S, and -T. Although the predicted amino acid sequences of Sec10 and Asc10 have some structural features in common with a number of surface proteins of gram-positive cocci, and the Asc10 sequence is highly similar to that of a similar protein encoded by the pheromone-inducible plasmid pAD1 (D. Galli, F. Lottspeich, and R. Wirth, Mol. Microbiol. 4:895-904, 1990), the regulatory genes show relatively little resemblance to any previously sequenced genes from either procaryotes or eucaryotes.