RNA-protein interactions in the ribosome. II. Binding of ribosomal proteins to isolated fragments of the 16 S RNA

Specific fragments of the 16 S ribosomal RNA of Escherichia coli have been isolated and tested for their ability to interact with proteins of the 30 S ribosomal subunit. The 12 S RNA, a 900-nucleotide fragment derived from the 5′-terminal portion of the 16 S RNA, was shown to form specific complexes with proteins S4, S8, S15, and S20. The stoichiometry of binding at saturation was determined in each case. Interaction between the 12 S RNA and protein fraction $\text{S}\text{16}\text{S}\text{17}$ was detected in the presence of S4, S8, S15 and S20; only these proteins were able to bind to this fragment, even when all 21 proteins of the 30 S subunit were added to the reaction mixture. Protein S4 also interacted specifically with the 9 S RNA, a fragment of 500 nucleotides that corresponds to the 5′-terminal third of the 16 S RNA, and protein S15 bound independently to the 4 S RNA, a fragment containing 140 nucleotides situated toward the middle of the RNA molecule. None of the proteins interacted with the 600-nucleotide 8 S fragment that arose from the 3′-end of the 16 S RNA.When the 16 S RNA was incubated with an unfractionated mixture of 30 S subunit proteins at 0 °C, 10 to 12 of the proteins interacted with the ribosomal RNA to form the reconstitution intermediate (RI) particle. Limited hydrolysis of this particle with T₁ ribonuclease yielded 14 S and 8 S subparticles whose RNA components were indistinguishable from the 12 S and 8 S RNAs isolated from digests of free 16 S RNA. The 14 S subparticle contained proteins S6 and S18 in addition to the RNA-binding proteins S4, S8, S15, S20 and $\text{S}\text{16}\text{S}\text{17}$. The 8 S subparticle contained proteins S7, S9, S13 and S19. These findings serve to localize the sites at which proteins incapable of independent interaction with 16 S RNA are fixed during the early stages of 30 S subunit assembly.     

Identification of components of the streptomycin-binding center ofE. coli MRE 600 ribosomes by photo-affinity labelling

Summary The [H³]-labelled photo-activated analog of streptomycin (photo-Sm) is obtained as a result of the streptomycin reaction with 2-nitro, 4-azidobenzoylhydrazide and subsequent reduction with NaBH₄ ³. The analog retains the functional activity of the initial antibiotic as judged by two criteria: (1) it binds only to the 30S subparticle of ribosomes and (2) it inhibits the factor-free (“non-enzymatic”) PCMB-stimulated polyU-dependent system of translation (Gavrilova and Spirin, 1971). After irradiation of the reaction mixture containing photo-Sm and either the 30S or 50S subparticles of ribosomes under similar conditions, the analog covalently binds chiefly to the 30S subparticle. Irradiation of the photo-Sm mixture with whole 70S ribosomes leads to a uniform distribution of a covalently bound label among the subparticles. A comparison of the effects obtained allows the conclusion that the analog is located on the interface of the ribosomal subparticles. In the 30S subparticle the photo-Sm attacks mainly the protein component (more than 95% of all the covalently bound label). The proteins labelled by photo-reaction are identified as S7 (main), S14 (additional) and S16/S17 (minor).     

RNA-protein interactions in the ribosome: VIII. Co-operative interactions in the 50 S subunit of Escherichia coli

Six 50 S ribosomal subunit proteins, each unable to interact independently with the 23 S RNA, were shown to associate specifically with ribonucleoprotein complexes consisting of intact 23 S RNA, or fragments derived from it, and one or more RNA-binding proteins. In particular, L21 and L22 depend for attachment upon L20 and L24, respectively; L5, L10 and L11 interact individually with complexes containing L2 and L16; and one or both proteins of the $\text{L}\text{17}\text{L}\text{27}$ mixture are stimulated to bind in the presence of L1, L3, L6, L13 and L23. Moreover, L14 alone was found to interact with a fragment from the 3′ end of the 23 S RNA, even though it cannot bind to 23 S RNA. By correlating the data reported here with the findings of others, it has been possible to formulate a partial in vitro assembly map of the Escherichia coli 50 S subunit encompassing both the 5 S and 23 S RNAs as well as 21 of the 34 subunit proteins.     

Ribosomal proteins: XLIII. In vivo assembly of Escherichia coli ribosomal proteins

Isolation of ribosomal precursors from Escherichia coli K12 is described. The RNA and protein content of the precursor particles was determined.One physiologically stable precursor was found for the 30 S subunit. The assembly scheme is as follows: p16 S RNA + 9 proteins → p30 S (“21 S” precursor) p30 S + 12 proteins → 30 S subunit where p is precursor.Each of the two precursors for the 50 S subunit, P₁50 S and p₂50 S (“32 S” and “43 S” precursors, respectively), contains p5 S + p23 S RNA's in a 1:1 molar ratio. The assembly scheme is as follows: p23 S RNA + p5 S RNA + 16 or 17 proteins → p₁50 S

In contrast to the p₂50 S precursor the p₁50 S precursor is not similar to any core particles, which were obtained by treating 50 S subunits with different concentrations of LiCl or CsCl.The precursors p30 S and p₂50 S can be converted into active 30 S and 50 S sub-units, respectively, by incubation at 42 °C in the presence of ribosomal proteins and under RNA methylating conditions.     

Isolation of all proteins from the 50S subparticles of ribosomes of Escherichia coli

The paper proposes a method of preparative isolation of all proteins from the 50S subparticle of E. coli ribosomes. The method is based on (1) preliminary fractionation into protein groups and ribonucleoprotein particles by a consecutive treatment of the 50S particles with increasing LiCl concentrations, and (2) chromatographic separation of protein groups on DE- and CM-cellulose and gel-filtration of separate fractions. The method allows to obtain any protein required for studies in preparative amounts avoiding many chromatographic stages. A detailed scheme of isolation of all proteins is given together with quantitative data of yields of individual proteins calculated per 6 g of the 50S subparticles.     

Possibility of internal organization of RNA and proteins in ribosomal subparticles. A structural model of Escherichia coli 30S ribosomal subparticle]

The hypothetic model of reciprocal spatial arrangement of 18 from 21 proteins in the E. coli 30S ribosomal subparticle is suggested. The model is based on conception of the 16S R-A molecule macrostrand which is the right superhelix in the subparticle composition. Macrohelix's biopolarity against single-stranded sites of RNA and its small width result in that proteins binding with single-stranded RNA organized in chain, one-number sequence. The double helixes uniting the corresponding one single-stranded sites of RNA play the role of rigid transmission between them. So, in the course of subparticles reconstruction from RNA and proteins the spatially uncoupled proteins can interact without its direct contact. The model takes into consideration the vast amount of information.     

Specific ribonucleoprotein fragments from 40-S ribosomal subunits.

Well-defined ribonucleoprotein fragments, resulting from the action of endogenous nuclease on 40-S subunits, were able to be separated when using high concentrations of LiCl. The ribonucleoproteins obtained sedimented at 12, 17 S, 23 S and 30 S and contained 8 S, 12 S and 17 S RNA, respectively, associated with a few proteins. The proteins extracted from the fragments were [3H] labeled by reductive methylation and their molar proportion was determined. The smallest fragment (12, 17 S) contained only three proteins, S8, S9 and S24. The 23-S and 30-S materials contained some proteins in common, S15, S19, S22, S25; S16 was found mainly in 30 S. Two proteins, S26 and "protein y" were found mainly in 23 S material. Thus, these results can give information on the relative location of certain proteins in the 40-S subunits.     

A method of preparing Escherichia coli 16 S RNA possessing previously unobserved 30 S ribosomal protein binding sites

A method of preparing 16 S RNA has been developed which yields RNA capable of binding specifically at least 12, and possibly 13, 30 S ribosomal proteins. This RNA, prepared by precipitation from 30 S subunits using a mixture of acetic acid and urea, is able to form stable complexes with proteins S3, S5, S9, S12, S13, S18 and possibly S11. In addition, this RNA has not been impaired in its capacity to interact with proteins S4, S7, S8, S15, S17 and S20, which are proteins that most other workers have shown to bind RNA prepared by the traditional phenol extraction procedure (Held et al., 1974; Garrett et al., 1971; Schaup et al., 1970,1971).We have applied several criteria of specificity to the binding of proteins to 16 S RNA prepared by the acetic acid-urea method. First, the new set of proteins interacts only with acetic acid-urea 16 S RNA and not with 16 S RNA prepared by the phenol method or with 23 S RNA prepared by the acetic acid-urea procedure. Second, 50 S ribosomal proteins do not interact with acetic acidurea 16 S RNA but do bind to 23 S RNA. Third, in the case of protein S9, we have shown that the bound protein co-sediments with acetic acid-urea 16 S RNA in a sucrose gradient. Additionally, a saturation binding experiment showed that approximately one mole of protein S9 binds acetic acid-urea 16 S RNA at saturation. Thus, we conclude that the method employed for the preparation of 16 S RNA greatly influences the ability of the RNA to form specific protein complexes. The significance of these results is discussed with regard to the in vitro assembly sequence.     

Study of the internal structure of Escherichia coli ribosomes by neutron and x-ray scattering.

Neutron scattering curves of the small and large subparticles of Escherichia coli ribosomes are presented over a wide range of scattering angles and for several contrasts. It was verified that the native ribosome structure was not affected by ²H₂O in the buffer. The reliability of the neutron scattering curves, obtained in H₂O buffer, was established by X-ray scattering experiments on the same material.The non-homogeneous distribution of RNA and protein in the subparticles of E. coli ribosomes is confirmed, with RNA predominantly within the particle and protein predominantly on its periphery. The distances between the centres of gravity of the RNA and protein components do not exceed 25 Å and 30 Å, in the large and small subparticles, respectively.The volume occupied by the RNA within the large and small subparticles is determined. The ratio of the “dry” volume of the RNA to the occupied volume is found to be 0.56; it is the same in both subparticles. Such packing of RNA is characteristic of single helices of ribosomal RNA at their crystallization and of the helices in transfer RNA crystals. A conclusion is drawn that RNA in ribosomes is in a similar state.Experimental scattering curves for the small subparticle depend significantly on the contrast in the angular region in which the scattering is mainly determined by the particle shape. The scattering curve, as infinite contrast is approached, is similar to that calculated for the particle as observed by electron microscopy. Thus, the long-existing contradiction between electron microscopy data (an elonggated particle with an axial ratio 2:1) and X-ray data (an oblate particle with an axial ratio 1:3.5), concerning the overall shape of the 30 S subparticle, is settled in favour of electron microscopy. The experimental neutron scattering curve of RNA within the small subparticle is well-described by the V-like RNA model proposed recently by Vasiliev et al. (1978).Experimental data are given to support the hypothesis that the maxima in the X-ray scattering curves, in the region of scattering angles corresponding to Bragg distances of 90 to 20 Å, arise from the ribosomal RNA component alone. It is shown that the prominence of the peaks in this region of the scattering curve depends only on the scattering fraction of the RNA component. The scattering fraction can be changed both by using the “native contrast” (ribosomal particles containing different amounts of protein) and by varying the solvent composition. The maxima are most pronounced where the RNA scattering fraction is highest or in solvents where the protein density is matched by the solvent. The scattering vectors of the maxima in the X-ray and neutron scattering curves, however, remain unchanged. This allows us to propose the tight packing of RNA as a common principle for the structural arrangement of RNA in ribosomes.     

Structure of protein-deficient 50 S ribosomal subunits. Nine core proteins induce the compact conformation of 23 S ribosomal RNA

The complex of 23 S ribosomal RNA with the nine core proteins L2, L3, L4, L13, L17, L20, L21, L22 and L23 obtained either by the disassembly procedure or by reconstitution has been studied by electron microscopy. This complex is found to be very similar to the intact 50 S subunit both in size and in shape.     

Co-operative response of oligomeric protein receptors coupled to non-co-operative ligand binding.

The biogenesis of 30 S and 50 S ribosomal subunits in exponentially growing Escherichia coli has been studied by following the rate of appearance of pulse-labelled ribosomal proteins on mature subunits. Cells were pulse-labelled for two minutes and for three and a half minutes with radioactive leucine. Ribosomal proteins were extracted and purified by chromatography on carboxymethyl cellulose and analysed by bidimensional gel electrophoresis. All 30 S proteins and most of the 50 S proteins were thus prepared and their radioactivity counted: unequal labelling was obtained. 30 S and 50 S proteins were ordered according to increasing specific radioactivity at both time pulses. The incorporation was greater at three and a half minutes than at two minutes. No major difference in the order at the two labelling times was observed.Only two classes of proteins can be defined in the 30 S and the 50 S subunits, namely early and late proteins. In each class a gradual increase in the radioactivity is apparent from the poorly labelled to the highly labelled proteins. This suggests a definite order of addition.Early 30 S proteins: S17, S16, S15, S19, S18, S8, S4, S20, S10, S6, S9, S12, S7.Late 30 S proteins: S5, S3, S2, S14, S11, S13, S1, S21.Early 50 S proteins: L22, L20, L21, L4, L13, L16, L3, L23, L18, L24, L28, L17, L19, L29, L32, L5, L15, L2, L30, L27.Late 50 S proteins: L25, L11, L7, L12, L1, L9, L8, L10, L33, L14, L6.This order is discussed taking into account the pool size of the proteins measured in the same conditions of cell culture.     

Assembly in vitro of the 50 S subunit from Escherichia coli ribosomes: proteins essential for the first heat-dependent conformational change.

An early intermediate during the assembly in vitro of the ribosomal 50 S subunit is the RI₅₀(1) particle, which undergoes a drastic change in s value to form the RI₅₀¹(1) particle. The formation of this RI₅₀¹(1) particle, which is essential for the assembly of a highly active 50 S particle, was analyzed. Total reconstitution experiments with purified proteins revealed that six ribosomal components (23 S RNA and the proteins L4, L13, L20, L22 and L24) are essential for the RI₅₀¹(1) formation. Protein L3 had a stimulatory effect, but was not essential. With these seven components, a particle with the RI₅₀¹ conformation could be formed.A comparison with assembly in vivo demonstrated that the pathways of protein assembly in vitro and in vivo are very similar at the beginning, but diverge towards the end of the process. Furthermore, the sequence in which the proteins can be split off the 50 S subunit by increasing concentrations of LiCl corresponds, to a first approximation, to the reverse of the order of assembly in vitro.     

Protection of specific sites in 23 S and 5 S RNA from chemical modification by association of 30 S and 50 S ribosomes.

The effect of 30S subunit attachment on the accessibility of specific sites in 5 S and 23 S RNA in 50 S ribosomal subunits was studied by means of the guanine-specific reagent kethoxal. Oligonucleotides surrounding the sites of kethoxal substitution were resolved and quantitated by diagonal electrophoresis. In contrast to the extensive protection of sites in 16 S RNA in 70 S ribosomes (Chapman &; Noller, 1977), only two strongly (approx. 90%) protected sites were detected in 23 S RNA. The nucleotide sequences at these sites are

in which the indicated kethoxal-reactive guanines (with K above them) are strongly protected by association of 30 S and 50 S subunits. The latter sequence has the potential to base-pair with nucleotides 816 to 821 of the 16 S RNA, a site which has been shown to be protected from kethoxal by 50 S subunits and essential for subunit association. Six additional sites in 23 S RNA are partially (30 to 50%) protected by 30 S subunits. One of these sequences,

is complementary to nucleotides 787 to 792 of 16 S RNA. a site which is also 50 S-protected and essential for association. Of the two kethoxal-reactive 5 S RNA sites in 50 S subunits, G₁₃ is partially protected in 70 S ribosomes. while G₄₁ remains unaffected by subunit association.The relatively small number of kethoxal-reactive sites in 23 S RNA that is strongly protected in 70 S ribosomes suggests that subunit association may involve contacts between single-stranded sites in 16 S RNA and 50 S subunit proteins or non-Watson-Crick interactions with 23 S RNA. in addition to the two suggested base-paired contacts.     

Specific binding of ribosome recycling factor (RRF) with the Escherichia coli ribosomes by BIACORE

The direct assays on Biacore with immobilised RRF and purified L11 from E. coli in the flow trough have shown unspecific binding between the both proteins. The interaction of RRF with GTPase domain of E. coli ribosomes, a functionally active complex of L11 with 23S r RNA and L10.(L7/L12)₄ was studied by Biacore. In the experiments of binding of RRF with 30S, 50S and 70S ribosomes from E. coli were used the antibiotics thiostrepton, tetracycline and neomycin and factors, influencing the 70S dissociation Mg²⁺, NH₄Cl, EDTA. The binding is strongly dependent from the concentrations of RRF, Mg²⁺, NH₄Cl, EDTA and is inhibited by thiostrepton. The effect is most specific for 50S subunits and indicates that the GTPase centre can be considered as a possible site of interaction of RRF with the ribosome. We can consider an electrostatic character of the interactions with most probable candidate 16S and 23S r RNA at the interface of 30S and 50S ribosomal subunits.     

Proteins occurring at, or near, the subunit interface of E. coli ribosomes

Summary The identification of ribosomal proteins that occur at, or near, the subunit interface of the 30S and 50S subunits in the E. coli 70S ribosome was attempted by studying the effect of antibodies on the Mg⁺⁺ dependent dissociation-association equilibrium of 70S ribosomes. Dissociated ribosomes were mixed with monovalent fragments of IgG antibodies (Fab's) specific for each ribosomal protein and then reassociated into intact 70S particles. Various degrees of inhibition of this reassociation were observed for proteins S9, S11, S12, S14, S20, L1, L6, L14, L15, L19, L20, L23, L26 and L27. A small amount of aggregation of 50S subunits was caused by IgG's specific for the proteins S9, S11, S12, S14 and S20 and purified 50S subunits. It was inferred that the presence of small amounts of these proteins on 50S subunits was compatible with their presence at the subunit interface. Finally, the capacity of proteins S11 and S12 to bind to 23S RNA was demonstrated.Paper No. 84 on Ribosomal Proteins. Preceding paper is by Rahmsdorf et al., Molec. gen. Genet. 127, 259–271 (1973).     

Cooperative binding of 3'-fragments of transfer ribonucleic acid to the peptidyltransferase center of Escherichia coli ribosomes.

The binding of substrates to the A-site half (A′) and the P-site half (P′) of the peptidyltransferase center was measured by means of equilibrium dialysis. The tRNA fragments C-A-C-C-A-Leu and C-A-C-C-A-(N-acetyl)Leu were used as A′-site and P′-site substrates, respectively. The A′- and P′-substrates bound well to 50 S in contrast to 30 S subunits; significant binding to 23 S and 16 S RNA was also found. The binding of the P′-site substrate to 23 S RNA and 50 S subunits was very similar at various Mg²⁺ and K⁺ concentrations, indicating that the 23 S RNA is probably directly involved in the binding of the 3′-end of the peptidyl-tRNA. Cooperative effects at the peptidyltransferase center were found using chloramphenicol and deacylated tRNA as competitors, which completely inhibited the substrate binding to one site whilst drastically stimulating binding to the other. Chloramphenicol inhibited the binding of the A′-site substrate C-A-C-C-A-Leu, whereas the binding of the corresponding P′-site substrate was stimulated. In contrast, deacylated tRNA blocked the binding of the P′-site substrate, but stimulated the corresponding A′-site binding. Similarly, the trinucleotide C_p,C_pA inhibited binding of the P′-site substrate (showing complete inhibition at 70 μm) whereas binding of the A′-site substrate was slightly stimulated at concentrations below 70 μm.     

Characterization of ribosomes of a strain ofStreptomyces aureofaciens producing chlortetracycline

These studies were designated to investigate the effect of chlortetracycline on sedimentation properties of polysomes and ribosomes present in the chlortetracycline producing strain ofStreptomyces aureofaciens. In presence of chlortetracycline polysomes and ribosomes are more stable than the bacterial ones. At lower chlortetracycline concentrations (1–5 μg/ml) dissociation of polysomes into 70 S monomers was not observed. Ribosomes in higher concentration of chlortetracycline (400 μg/ml) form aggregates. A decrease of Mg²⁺ to 0.1mm caused dissociation of ribosomes to two subunits and in this state none of indicated concentrations of chlortetracycline caused aggregation. The exact sedimentation values of ribosomes and ribosomal subunits were calculated from extrapolation to infinite dilution. S_20,w for monomer form was 68.8, and for ribosomal subunits 49.8 and 31.2 respectively. Ribosomal RNA sedimentates as two Schlieren peaks of 16 S and 22 S. It was found that 30 S subunits contain 15 structural proteins, while 21 proteins were resolved from 50 S subunits.     

Dissociation of proteins from the human 40S ribosomal subunit in a lithium chloride gradient

Human 40S ribosomal subunits were subjected to centrifugation through a 0.3–1.5 M LiCl gradient in 0.5 M KCl, 4 mM MgCl₂. Most of the proteins started to dissociate at the initial concentration of monovalent cations (0.8 M); the last to dissociate at 1.55 M salt were the core proteins S3, S5, S7, S10, S15, S16, S17, S19, S20, and S28; among these, S7, S10, S16, and S19 were the most tightly bound to 18S rRNA.     

Protein involved in the binding of dihydrostreptomycin to ribosomes of Escherichia coli

At increasing ammonium chloride concentrations, 30 S subunits on one hand, and 50 S subunits, 16 S BNA and 23 S RNA on the other hand, show a different behaviour with respect to dihydrostreptomycin binding. Within a wide range (10 to 250 mm) binding to 30 S subunits is not affected by NH₄Cl, whereas binding to 50 S and the RNAs decreases by increasing NH₄Cl concentrations. 30 S subunits lose more than 90% of their binding capacity by washing with 1.15 m-LiCl (SP_1.5³).The split proteins SP_1.15 were analysed by DEAE-cellulose chromatography and Sephadex G100 gel filtration. After reconstitution with the non-binding 2.0 core the proteins S3 and S5 can bind dihydrostreptomycin independently of each other; the S5-dependent binding is stimulated by S9 and S14 (S10). The Scatchard plot revealed 0.8 binding sites per 30 S subunit. We conclude that S3 and S5 are part of one binding site of dihydrostreptomycin.     

Effects of Major Capsid Proteins,Capsid Assembly,and DNA Cleavage/Packaging on the pUL17/pUL25 Complex of Herpes Simplex Virus 1

The U_L17 and U_L25 proteins (pU_L17 and pU_L25, respectively) of herpes simplex virus 1 are located at the external surface of capsids and are essential for DNA packaging and DNA retention in the capsid, respectively. The current studies were undertaken to determine whether DNA packaging or capsid assembly affected the pU_L17/pU_L25 interaction. We found that pU_L17 and pU_L25 coimmunoprecipitated from cells infected with wild-type virus, whereas the major capsid protein VP5 (encoded by the U_L19 gene) did not coimmunoprecipitate with these proteins under stringent conditions. In addition, pU_L17 (i) coimmunoprecipitated with pU_L25 in the absence of other viral proteins, (ii) coimmunoprecipitated with pU_L25 from lysates of infected cells in the presence or absence of VP5, (iii) did not coimmunoprecipitate efficiently with pU_L25 in the absence of the triplex protein VP23 (encoded by the U_L18 gene), (iv) required pU_L25 for proper solubilization and localization within the viral replication compartment, (v) was essential for the sole nuclear localization of pU_L25, and (vi) required capsid proteins VP5 and VP23 for nuclear localization and normal levels of immunoreactivity in an indirect immunofluorescence assay. Proper localization of pU_L25 in infected cell nuclei required pU_L17, pU_L32, and the major capsid proteins VP5 and VP23, but not the DNA packaging protein pU_L15. The data suggest that VP23 or triplexes augment the pU_L17/pU_L25 interaction and that VP23 and VP5 induce conformational changes in pU_L17 and pU_L25, exposing epitopes that are otherwise partially masked in infected cells. These conformational changes can occur in the absence of DNA packaging. The data indicate that the pU_L17/pU_L25 complex requires multiple viral proteins and functions for proper localization and biochemical behavior in the infected cell.Immature herpes simplex virus (HSV) capsids, like those of all herpesviruses, consist of two protein shells. The outer shell comprises 150 hexons, each composed of six copies of VP5, and 11 pentons, each containing five copies of VP5 (23, 29, 47). One vertex of fivefold symmetry is composed of 12 copies of the protein encoded by the U_L6 gene and serves as the portal through which DNA is inserted (22, 39). The pentons and hexons are linked together by 320 triplexes composed of two copies of the U_L18 gene product, VP23, and one copy of the U_L38 gene product, VP19C (23). Each triplex arrangement has two arms contacting neighboring VP5 subunits (47). The internal shell of the capsid consists primarily of more than 1,200 copies of the scaffold protein ICP35 (VP22a) and a smaller number of protease molecules encoded by the U_L26 open reading frame, which self-cleaves to form VP24 and VP21 derived from the amino and carboxyl termini, respectively (11, 12, 19, 25; reviewed in reference 31). The outer shell is virtually identical in the three capsid types found in HSV-infected cells, termed types A, B, and C (5, 6, 7, 29, 43, 48). It is believed that all three are derived from the immature procapsid (21, 38). Type C capsids contain DNA in place of the internal shell, type B capsids contain both shells, and type A capsids consist only of the outer shell (15, 16). Cleavage of viral DNA to produce type C capsids requires not only the portal protein, but all of the major capsid proteins and the products of the U_L15, U_L17, U_L28, U_L32, and U_L33 genes (2, 4, 10, 18, 26, 28, 35, 46). Only C capsids go on to become infectious virions (27).The outer capsid shell contains minor capsid proteins encoded by the U_L25 and U_L17 open reading frames (1, 17, 20). These proteins are located on the external surface of the viral capsid (24, 36, 44) and are believed to form a heterodimer arranged as a linear structure, termed the C capsid-specific complex (CCSC), located between pentons and hexons (41). This is consistent with the observation that levels of pU_L25 are increased in C capsids as opposed to in B capsids (30). On the other hand, other studies have indicated that at least some U_L17 and U_L25 proteins (pU_L17 and pU_L25, respectively) associate with all capsid types, and pU_L17 can associate with enveloped light particles, which lack capsid and capsid proteins but contain a number of viral tegument proteins (28, 36, 37). How the U_L17 and U_L25 proteins attach to capsids is not currently known, although the structure of the CCSC suggests extensive contact with triplexes (41). It is also unclear when pU_L17 and pU_L25 become incorporated into the capsid during the assembly pathway. Less pU_L25 associates with pU_L17(−) capsids, suggesting that the two proteins bind capsids either cooperatively or sequentially, although this could also be consequential to the fact that less pU_L25 associates with capsids lacking DNA (30, 36).Both pU_L25 and pU_L17 are necessary for proper nucleocapsid assembly, but their respective deletion generates different phenotypes. Deletion of pU_L17 precludes DNA packaging and induces capsid aggregation in the nuclei of infected cells, suggesting a critical early function (28, 34), whereas deletion of pU_L25 precludes correct cleavage or retention of full-length cleaved DNA within the capsid (8, 20, 32), thus suggesting a critical function later in the assembly pathway.The current studies were undertaken to determine how pU_L17 and pU_L25 associate with capsids by studying their interaction and localization in the presence and absence of other capsid proteins.