Stimulation in vitro of lymphocytes for induction of uveoretinitis without any significant proliferation.

Experimental autoimmune uveoretinitis can be adoptively transferred into naive recipients by lymphocytes from rats immunized with uveitogenic Ag, provided these cells are activated in vitro before being injected. The activation of sensitized lymphocytes, by the immunizing Ag, or by cross-reacting Ag, is usually accompanied by vigorous proliferation. We report, however, on a complete dissociation between the capacity of a peptide to generate uveitogenicity and to stimulate proliferation in cultured lymphocytes. This peptide, which occupies sequence 579-591 of the bovine interphotoreceptor retinoid-binding protein (IRBP), is one of the three "repeats" that exhibit partial sequence homologies with the immunodominant and highly immunogenic peptide, 1179-1191. Peptide 579-591 is nonimmunogenic and nonuveitogenic in Lewis rats and does not stimulate any significant proliferation in lymphocytes sensitized against whole IRBP, peptide 1179-1191, or another "repeat" peptide, 271-283, which is immunogenic and uveitogenic. In contrast, peptide 579-591 effectively generates uveitogenicity in the lymphocytes sensitized against these three Ag. Unlike 579-591, peptides 271-283 and 1179-1191 stimulated both proliferation and uveitogenicity in these sensitized lymphocytes. A different pattern of activities was observed with the other "repeat" peptide, 880-892. This peptide did not have any effect on the lymphocytes sensitized against IRBP, 271-283 or 1179-1191, but did stimulate both proliferation and uveitogenicity in lymphocytes sensitized against itself. The data suggest that 579-591 selectively stimulates a lymphocyte subset that is uveitogenic, but is incapable of mounting proliferative responses.     

Analysis of the pivotal residues of the immunodominant and highly uveitogenic determinant of interphotoreceptor retinoid-binding protein.

Interphotoreceptor retinoid-binding protein (IRBP), a retinal-specific Ag, induces experimental autoimmune uveitis in a variety of animals. We have previously shown that sequence 1169-1191 of bovine IRBP is the immunodominant epitope of this protein in Lewis rats and is highly immunogenic and uveitogenic in these rats. The active site of peptide 1169-1191 was determined by testing its truncated forms. The shortest peptide to be immunologically active was found to be 1182-1190 (WEGVGVVPD). To determine the role of individual residues of this sequence, we have tested the immunologic activities of nine analogs of peptide 1181-1191, in which each of residues 1182-1190 was substituted with alanine (A). The tested activities included the capacity to induce experimental autoimmune uveitis and cellular responses in immunized rats, as well as the capability to stimulate lymphocytes sensitized against IRBP or the parent peptide 1181-1191. Analogs that did not stimulate these lymphocytes were also tested for their capacity to competitively inhibit the proliferative response to 1181-1191. Analogs A(1184), A(1186), and A(1187) resembled 1181-1191 in their activities, whereas the other analogs exhibited remarkably reduced activities, with several patterns being noticed. Analog A(1182) was inactive in all tests. Analog A(1190) was very weakly uveitogenic and non-immunogenic, but it stimulated lymphocytes sensitized against IRBP or 1181-1191 when added at exceedingly high concentrations. Analogs A(1183) and A(1185) resembled A(1190) in being weakly uveitogenic and A(1185) was also found to be poorly immunogenic. In addition, relatively high concentrations of A(1183) and A(1185) were needed to stimulate lymphocytes sensitized against IRBP or 1181-1191. However, a different pattern of activities was exhibited by analogs A(1188) and A(1189). These peptides were uveitogenic and immunogenic, but failed to stimulate lymphocytes sensitized to IRBP or 1181-1191. Furthermore, A(1188) and A(1189), but not A(1182), also inhibited the response to 1181-1191 of a cell line specific toward this parent peptide. The data are interpreted to show that residues 1188 and 1189 are involved in the interaction of the peptide with the TCR, whereas residues 1182 and 1190 and, perhaps, 1183 and 1185, are pivotal for the binding of peptide 1181-1190 to the MHC molecules on APC.     

Recognition of peptides that are immunopathogenic but cryptic. Mechanisms that allow lymphocytes sensitized against cryptic peptides to initiate pathogenic autoimmune processes.

Interphotoreceptor retinoid binding protein (IRBP) is a glycoprotein that localizes in the retina and induces inflammatory changes in this tissue in immunized animals. Certain IRBP-derived peptide determinants are also immunopathogenic, and we have previously shown that these determinants could be either immunodominant or cryptic. Lymphocytes sensitized against the cryptic peptides do not recognize whole IRBP in vitro, and yet these lymphocytes must recognize the protein in vivo to initiate the autoimmune pathogenic process. We have examined here two hypothetical explanations for this dissociation: 1) It is possible that when IRBP is processed in vitro, immunodominant peptide determinants compete with the cryptic ones and inhibit their interaction with the MHC molecules on the APC. This explanation was ruled out here by the finding that the immunodominant peptide 1179-1191 ("W10") did not inhibit the response to a cryptic one, 1158-1180 ("R4"), when added at equivalent and even moderately higher concentrations. 2) The second hypothesis proposes that the cryptic antigenic sites are not generated from IRBP by the APC in vitro, whereas enzymes in the retina digest the protein to yield fragments that generate these antigenic sites upon processing by the APC. In line with this hypothesis, we have found that cleavage of IRBP by certain endoproteinases (Asp-N, Glu-C, or V-8) produced molecules that were recognized in culture by lymphocytes sensitized to the immunopathogenic but cryptic peptide R4. This study, therefore, describes a putative Ag processing mechanism that results in IRBP recognition and, consequently, the initiation of an autoimmune process by lymphocytes sensitized against a cryptic peptide. Furthermore, experiments with R4 and other cryptic peptides have shown that cleavage fragments of up to 38 residues in length can be presented by APC, to stimulate lymphocytes sensitized against these peptides. No responses were stimulated, however, by fragments of 75 or more residues. The data thus provide new insights into the processing and presentation of cryptic peptide determinants by APC.     

The existence of two completely distinct antigenic sites within a decapeptide.

A decapeptide (1182-1191) derived from the bovine interphotoreceptor retinoid-binding protein (IRBP) was found to contain two completely distinct antigenic sites when tested in Lewis rats. One site, localized in sequence 1182-1191, is the core of the immunodominant and highly uveitogenic determinant of IRBP. The second site localizes within sequence 1183-1191 and becomes detectable only when tryptophan at position 1182 is deleted. Lymphocytes sensitized against the first, larger site recognized all longer peptides within sequence 1169-1191, as well as whole IRBP. In contrast, lymphocytes sensitized against the second, short epitope recognized only two peptides, 1184-1191 and (to a lesser degree) 1183-1191. The responses to both sites were restricted by the same major histocompatibility complex (MHC) product (I-A), as shown by monoclonal antibody blocking and by the finding that the lymphocyte response to 1184-1191 was competitively inhibited by peptide 1181-1191. The unique finding of two completely distinct antigenic sites within a decapeptide could be explained by the hypothesis that peptides of the two sites combine with the MHC molecule on antigen-presenting cells by different configurations, thus forming two distinct antigenicities.     

Rat T-cell lines specific to a nonimmunodominant determinant of a retinal protein (IRBP) produce uveoretinitis and pinealitis

Rat lymphocyte lines were established, with specificity toward two synthetic peptides derived from the interphotoreceptor retinoid-binding protein (IRBP), which specifically localizes in the retina and pineal gland. One of the peptides, R4, is immunopathogenic, producing experimental autoimmune uveoretinitis (EAU) and pinealitis (EAP) in immunized rats, while the other peptide, R3, exhibits no detectable immunopathogenicity in rats. The cell lines carry surface markers specific for the helper/inducer subset of T-lymphocytes. When tested by the proliferation assay, the line cells demonstrated major histocompatibility-restricted vigorous responses against the immunizing (homologous) peptide, but failed to recognize the intact IRBP molecule. This finding is in line with other data indicating that peptides R3 and R4 are nonimmunodominant determinants of IRBP for the Lewis rat. Yet, the cell lines specific for R4 were highly immunopathogenic, producing EAU and EAP in naive rats at numbers as low as 0.25 x 10(6), with histopathological changes similar to those induced by active immunization with this peptide. The immunological capacity of the cell lines was further demonstrated by the finding that spleen cells from recipient rats of these lines responded well against the homologous peptides. The uniqueness of this system, in which lymphocytes specific toward a nondominant determinant are immunopathogenic, is underscored and the possible mechanisms of disease induction are discussed.     

Dissociation between lymphocyte activation for proliferation and for the capacity to adoptively transfer uveoretinitis

We have shown previously that immunization with bovine interphotoreceptor retinoid-binding protein (IRBP) induces in rats severe eye disease, experimental autoimmune uveoretinitis (EAU). This study examined the uveitogenic capacity of IRBP of another species, the monkey, and tested the cross-antigenicity between these two proteins by a battery of immunological assays. Monkey IRBP was found to be approximately 20 times less uveitogenic in Lewis rats than bovine IRBP. High levels of cross-reactivity between bovine and monkey IRBP were demonstrated by antibodies as measured by the enzyme-linked immunosorbent assay, and by the radiometric ear test of delayed-type hypersensitivity, by using rats immunized with either one of the IRBP. On the other hand, lymphocytes from these rats failed to detect the cross-reactivity between the two IRBP by the proliferation response in culture. Yet, such lymphocytes did recognize the nonimmunizing IRBP when activated in culture for acquiring the capacity to adoptively transfer EAU into naive recipients. The data are discussed with regard to the limited usefulness of the lymphocyte proliferation assay for detection of immunopathogenic processes and the role of cross-reacting antigens in initiation of autoimmune responses.     

A quantitative analysis of the variables affecting the repertoire of T cell specificities recognized after vaccinia virus infection

Many components contribute to immunodominance in the response to a complex virus, but their relative importance is unclear. This was addressed using vaccinia virus and HLA-A*0201 as the model system. A comprehensive analysis of 18 viral proteins recognized by CD8(+) T cell responses demonstrated that approximately one-fortieth of all possible 9- to 10-mer peptides were high-affinity HLA-A*0201 binders. Peptide immunization and T cell recognition data generated from 90 peptides indicated that about one-half of the binders were capable of eliciting T cell responses, and that one-seventh of immunogenic peptides are generated by natural processing. Based on these results, we estimate that vaccinia virus encodes approximately 150 dominant and subdominant epitopes restricted in by HLA-A*0201. However, of all these potential epitopes, only 15 are immunodominant and actually recognized in vivo during vaccinia virus infection of HLA-A*0201 transgenic mice. Neither peptide-binding affinity, nor complex stability, nor TCR avidity, nor amount of processed epitope appeared to strictly correlate with immunodominance status. Additional experiments suggested that vaccinia infection impairs the development of responses directed against subdominant epitopes. This suggested that additional factors, including immunoregulatory mechanisms, restrict the repertoire of T cell specificities after vaccinia infection by a factor of at least 10.     

Interphotoreceptor retinoid-binding protein. Gene characterization, protein repeat structure, and its evolution

The gene for bovine interphotoreceptor retinoid-binding protein (IRBP) has been cloned, and its nucleotide sequence has been determined. The IRBP gene is about 11.6 kilobase pairs (kb) and contains four exons and three introns. It transcribed into a large mRNA of approximately 6.4 kb and translated into a large protein of 145,000 daltons. To prove the identity of the genomic clone, we determined the protein sequence of several tryptic and cyanogen bromide fragments of purified bovine IRBP protein and localized them in the protein predicted from its nucleotide sequence. There is a 4-fold repeat structure in the protein sequence with 30-40% sequence identity and many conservative substitutions between any two of the four protein repeats. The third and fourth repeats are the most similar pair. All three of the introns in the IRBP gene fall in the fourth protein repeat. Two of the exons, the first and the fourth, are large, 3173 and 2447 bases, respectively. The introns are each about 1.5-2.2 kb long. The human IRBP gene has a sequence that is similar to one of the introns from the bovine gene. The unexpected gene structure and protein repeat structure in the bovine gene lead us to propose a model for the evolution of the IRBP gene.     

Photoaffinity labeling of human IRBP with all-trans-retinoic acid

Interphotoreceptor retinoid-binding protein (IRBP), found only in photosensitive tissues, is a large approximately 135-kDa glycoprotein that contains a fourfold repeat structure. IRBP may function as a buffer and prevent retinoid toxicity and retinoid degeneration. Here we asked (i) whether each repeat of IRBP possesses the capability of photo-crosslinking all-trans-retinoic acid (RA), (ii) within Repeat 1 whether a single retinoic acid-binding domain exists, and (iii) whether protease and CNBr digestion of Repeat 1 bound RA indicate the exact location of the binding site. 3H-RA cross-linked to all four repeats, consistent with the current model of multiple binding sites in IRBP. Acetone precipitation was effective in removing unbound 3H-RA. LysC and tryptic digestion of the RA-Repeat 1 detected 18- and 5-kDa bands, respectively. CNBr digestion showed two bands about 9 and 11 kDa in size. Our data suggests a single binding site near positions 151-160 in the center of Repeat 1.     

Changing ABRA protein peptide to fit into the HLA-DRbeta1*0301 molecule renders it protection-inducing

The Plasmodium falciparum acidic-basic repeat antigen represents a potential malarial vaccine candidate. One of this protein's high activity binding peptides, named 2150 ((161)KMNMLKENVDYIQKNQNLFK(180)), is conserved, non-immunogenic, and non-protection-inducing. Analogue peptides whose critical binding residues (in bold) were replaced by amino-acids having similar mass but different charge were synthesized and tested to try to modify such immunological properties. These analogues' HLA-DRbeta1* molecule binding ability were also studied in an attempt to explain their biological mechanisms and correlate binding capacity and immunological function with their three-dimensional structure determined by (1)H NMR. A 3(10) distorted helical structure was identified in protective and immunogenic peptide 24922 whilst alpha-helical structure was found for non-immunogenic, non-protective peptides having differences in alpha-helical position. The changes performed on immunogenic, protection-inducing peptide 24922 allowed it to bind specifically to the HLA-DRbeta1*0301 molecule, suggesting that these changes may lead to better interaction with the MHC Class II-peptide-TCR complex rendering it immunogenic and protective, thus suggesting a new way of developing multi-component, sub-unit-based anti-malarial vaccines.     

Plasmodium falciparum SERA protein peptide analogues having short helical regions induce protection against malaria

Three Plasmodium falciparum serine repeat antigen (SERA) protein peptides were studied by NMR and structure calculations being done in 70:30 water:trifluoroethanol solution. Peptide 22834 was shown to be immunogenic and protective against malaria in Aotus monkeys, whilst native peptide 6737 and its analogue 14096 did not present protection against the disease in these monkeys. Results showed a relationship between these peptides' secondary structure and their function as immunogen against malaria.     

Sequence-variant repeats of MUC1 show higher conformational flexibility, are less densely O-glycosylated and induce differential B lymphocyte responses

The human epithelial cancer mucin MUC1 is able to break tolerance and to induce humoral immune responses in healthy subjects and in cancer patients. We recently showed that clusters of sequence-variant repeats are interspersed in the repeat domain of MUC1 at high frequency, which should contribute to the structural and immunological features of the mucin. Here we elucidated the potential effects exerted by sequence-variant repeats on their O-glycosylation. Evidence from in vitro glycosylation with polypeptide N-acetylgalactosaminyltransferases GalNAc-T1 and GalNAc-T2 in concert with mass spectrometric analyses of in vivo glycosylated MUC1 probes from transiently transfected HEK293 cells indicated reduced glycosylation densities of repeats with three concerted replacements: AHGVTSAPESRPAPGSTAPA. The Pro to Ala replacement in STAPA exerts not only proximal effects on the ppGalNAc-T2 preferred site at -3 and -4, but also more distant effects on the ppGalNAc-T1 preferred site at -15 (TSAPESRPAPGSTAPA). We also examined the conformational changes of MUC1 glycopeptides induced by the concerted DT to ES replacements and revealed a higher conformational flexibility of ES/P peptides compared to DT/P peptides. Differences in conformational flexibilities and in O-glycosylation densities could underlie the observed differential humoral responses in humans. We were able to show that the natural immunoglobulin G (IgG) responses to the repeat domain of MUC1 in sera from nonmalignant control subjects are preferentially directed to variant repeat clusters. In contrast, the IgG response in patients with adenocarcinoma shifted to higher frequencies of preferential DTR peptide binding.     

The use of filamentous bacteriophage fd to deliver MAGE-A10 or MAGE-A3 HLA-A2-restricted peptides and to induce strong antitumor CTL responses

Delivery of tumor-associated Ag-derived peptides in a high immunogenic form represents one of the key issues for effective peptide-based cancer vaccine development. We report herein the ability of nonpathogenic filamentous bacteriophage fd virions to deliver HLA-A2-restricted MAGE-A10(254-262)- or MAGE-A3(271-279)-derived peptides and to elicit potent specific CTL responses in vitro and in vivo. Interestingly, human anti-MAGE-A3(271-279)-specific CTLs were able to kill human MAGE-A3(+) tumor cells, even if these cells naturally express a low amount of MAGE-A3(271-279) peptide-HLA epitope surface complexes and are usually not recognized by CTLs generated by conventional stimulation procedures. MAGE-A3(271-279)-specific/CD8(+) CTL clones were isolated from in vitro cultures, and their high avidity for Ag recognition was assessed. Moreover, in vivo tumor protection assay showed that vaccination of humanized HHD (HLA-A2.1(+)/H2-D(b+)) transgenic mice with phage particles expressing MAGE-A3(271-279)-derived peptides hampered tumor growth. Overall, these data indicate that engineered filamentous bacteriophage virions increase substantially the immunogenicity of delivered tumor-associated Ag-derived peptides, thus representing a novel powerful system for the development of effective peptide-based cancer vaccines.     

A shared epitope of the interphotoreceptor retinoid-binding protein recognized by the CD4+ and CD8+ autoreactive T cells

We previously demonstrated that cultures of rat uveitogenic T cells rapidly become dominated by CD4+ cells, but activation of CD8+ autoreactive T cells also occurred during the in vitro culture of in vivo-primed T cells. In the present study, we show that the commonly used uveitogenic peptide, interphotoreceptor retinoid-binding protein (IRBP) 1-20, generated both CD4+ and CD8+ autoreactive T cells in the C57BL/6 (B6) mouse and that this 20-mer contains at least two distinct antigenic epitopes. To determine whether the CD8 response was Ag-specific and whether CD4+ and CD8+ IRBP1-20-specific T cells recognize distinct antigenic epitopes, we prepared highly purified CD4+ and CD8+ T cells from IRBP1-20-primed mice and tested their proliferative response to a large panel of truncated peptides derived from IRBP1-20. The results showed that both CD4+ and CD8+ T cells recognized the same spectrum of peptides. In addition, peptides P10-18 were found to bind effectively to CD8+ IRBP1-20-specific T cells when complexed with recombinant H-2K(b) and also stimulate the proliferation and cytokine production of CD4+ IRBP1-20-specific T cells. Our results document for the first time that CD8+ and CD4+ autoreactive T cells display characteristic epitope recognition and they both recognize the same core epitope.     

Epitope mapping of a single repetitive unit of the B13 Trypanosoma cruzi antigen as fusions to Escherichia coli LamB protein

B13, one of the immunodominant antigens of Trypanosoma cruzi, is composed of repeats of a 12-amino-acid motif. Using synthetic peptides, the sequence FGQAAAGDK was previously shown to contain the B13 immunodominant epitope recognized by chagasic patients sera. To investigate the effects of neighboring sequences in the immunodominance, we tested serum recognition of two B13 sequences fused to LamB. GDKPSPFGQAAA-LamB and FGQAAAGDKPSP-LamB were recognized, respectively, by 15% and 80% of 80 sera reactive to B13 antigen. Recognition of FGQAAAGDKPSP-LamB was inhibited by AAAGDK-containing synthetic peptides. FGQAAAGDKPSP-LamB competed with a B13 recombinant protein containing 16.6 repeats for binding to chagasic antibodies. These results strengthen previous conclusions on the immunodominant epitope of B13 and provide a comparison of two methods for epitope mapping.     

Interspecies conservation of structure of interphotoreceptor retinoid-binding protein. Similarities and differences as adjudged by peptide mapping and N-terminal sequencing.

Structural properties of the retinal extracellular-matrix glycolipoprotein interphotoreceptor retinoid-binding protein (IRBP) from human, monkey and bovine retinas have been compared. SDS/polyacrylamide-gel-electrophoretic analysis of limited tryptic and Staphylococcus aureus-V8-proteinase digests show virtually identical patterns for the monkey and human proteins, whereas both sets differ considerably from the bovine protein pattern. Time-course digestion shows monkey IRBP to be more readily cleaved than bovine IRBP and also cleaved to smaller fragments. Also, reversed-phase h.p.l.c. of complete tryptic digests of the IRBPs indicate that, although they have in common a similar preponderance of hydrophobic peptides, all three proteins differ extensively in their fine structure. The N-terminal sequences of monkey and bovine IRBPs have been extended beyond those presented in our previous report [Redmond, Wiggert, Robey, Nguyen, Lewis, Lee & Chader (1985) Biochemistry 24, 787-793] to over 30 residues each. The sequences yet show extensive homology, differing at only two positions, although the major monkey sequence has an additional five amino acid residues at its N-terminus ('n + 5' sequence) not observed with bovine IRBP ('n' sequence). The newly determined N-terminal sequence of human IRBP demonstrates the presence of equal amounts of the 'n' and 'n+5' sequences that are qualitatively identical with those of the monkey. The presence of the five-amino-acid-residue extension in primate, but not bovine, IRBP may indicate variation in post-translational processing.     

Synthesis,conformation and T-helper cell stimulation of an O-linked glycopeptide epitope containing extended carbohydrate side-chains

To answer the question whether or not T cells to immunodominant protein fragments recognize glycosylated antigens, we synthesized a series of glycopeptides corresponding to peptide 31D, a major T-helper cell epitope of the rabies virus nucleoprotein. Thr4 of the epitope is known to allow mono- or disaccharide side-chain substitutions in either - or β-anomeric configuration without interfering with MHC-binding. To model naturally occurring glycoprotein fragments that carry extended sugar chains, we prepared Fmoc-Ser/Thr-OPfp building blocks containing - and β-linked linear tri- and heptasaccharides. Peptide 31D was synthesized with the complex carbohydrates attached to Thr4, and the T-helper cell activity of the glycopeptides was determined. Addition of -linked carbohydrates, that mimic most of the natural O-linked glycoproteins, resulted in a major drop in the T-cell stimulatory ability in a sugar length-dependent manner. In contrast, the cytosolic glycoprotein mimicking β-linked glycopeptides retained their T-cell stimulatory activity, with the trisaccharide-containing analogue being almost as potent as the unglycosylated peptide. When the peptides were preincubated with diluted human serum, all peptides lost their ability to stimulate the 9C5.D8-H hybridoma. These findings indicated that (i) in contrast to cytosolic glycosylation, incorporation of long O-linked carbohydrates into T-helper cell epitopes abrogates the antigenicity of these protein fragments, and (ii) glycosylation is not a viable alternative to improve the immunogenic properties of subunit peptide vaccines. Glycosylation with all four carbohydrate moieties similarly destroyed the inducible -helical structure of peptide 31D as detected by CD, indicating that the differences in the T-cell activity were not due to different peptide conformations.     

Orientating peptide residues and increasing the distance between pockets to enable fitting into MHC-TCR complex determine protection against malaria

The erythrocyte binding antigen EBA-175 is a 175-kDa Plasmodium falciparum protein, which has been shown to be involved in the process of invasion of erythrocytes. It has been found that conserved peptide 1818 belonging to this protein has high red blood cell binding capacity and plays an important role in the invasion process. This peptide is neither immunogenic nor protective. Peptide 1818 analogues had some of their previously recognized critical red blood cell binding residues substituted for amino acids having similar volume or mass but different polarity to make them fit into HLA-DRbeta(1)*1101 molecules; these 1818 peptide analogues were then synthesized and inoculated into Aotus nancymaae monkeys, generating different immunogenic and/or protective immune responses. Short structures such as 3(10)-helix, classical, or distorted type-III beta-turns were found in the immunogenic and protective peptides once the secondary structure had been analyzed by NMR and its structure correlated with its immunological properties. These data suggest that peptide flexibility may lead to better fitting into immune system molecules, therefore making them excellent candidates for consideration as components of a subunit-based, multicomponent synthetic antimalarial vaccine.     

Investigation of self-assembling proline- and glycine-rich recombinant proteins and peptides inspired by proteins from a symbiotic fungus using atomic force microscopy and circular dichroism spectroscopy

Fiber-forming proteins and peptides are being scrutinized as a promising source of building blocks for new nanomaterials. Arabinogalactan-like (AGL) proteins expressed at the symbiotic interface between plant roots and arbuscular mycorrhizal fungi have novel sequences, hypothesized to form polyproline II (PPII) helix structures. The functional nature of these proteins is unknown but they may form structures for the establishment and maintenance of fungal hyphae. Here we show that recombinant AGL1 (rAGL1) and recombinant AGL3 (rAGL3) are extended proteins based upon secondary structural characteristics determined by electronic circular dichroism (CD) spectroscopy and can self-assemble into fibers and microtubes as observed by atomic force microscopy (AFM) and scanning electron microscopy (SEM). CD spectroscopy results of synthetic peptides based on repeat regions in AGL1, AGL2 and AGL3 suggest that the synthetic peptides contain significant amounts of extended PPII helices and that these structures are influenced by ionic strength and, at least in one case, by concentration. Point mutations of a single residue of the repeat region of AGL3 resulted in altered secondary structures. Self-assembly of these repeats was observed by means of AFM and optical microscopy. Peptide (APADGK)(6) forms structures with similar morphology to rAGL1 suggesting that these repeats are crucial for the morphology of rAGL1 fibers. These novel self-assembling sequences may find applications as precursors for bioinspired nanomaterials.