Analysis of T-T lymphocytes and T-accessory cell interactions using cloned T cells: MHC I restricted cloned T cells activate MHC II restricted T helper cells

We evaluated the role of molecules of the major histocompatibility complex (MHC) involved in the cellular interactions of two T-cell clones by testing the effect of monoclonal antibodies on the responses of the clones in vitro. The two T-cell clones used in the study are specific for minor histocompatibility antigens and restricted to the H-2K^k. In the absence of exogenous IL-2 the clones require the presence of Ia⁺, Thy-1⁻ accessory cells and of Thy-1⁺, Lyt-1⁺2⁻ cells in the irradiated spleen cell suspension used as stimulator. It is also necessary that both the accessory cells and the T cells in the stimulator cell populations are recognized specifically by the clones. Monoclonal antibodies specific for the H-2K product inhibited the lytic effector function of the cytolytic clone. These antibodies when added to cultures of stimulator cells and clones inhibited also the proliferation of this clone and of a nonlytic clone. When antigen recognition was measured by the increase in sensitivity of the clones to IL-2 while confronted with uv-irradiated stimulator cells, both clones were blocked efficiently by anti-H-2K antibodies. Thus, these results suggest that the interaction of monoclonal antibodies with the restricting H-2K molecule is sufficient to block the recognition signal, a prerequisite for proliferation. In contrast, monoclonal antibodies specific for A_αA_β and/or E_αE_β had no effect on cytolysis or on restricted recognition. However, they inhibited the proliferative responses as efficiently as the H-2K specific antibodies. Inhibition by class II-specific antibodies was not abolished when stimulator cell populations were depleted of Lyt-2⁺ cells. The blocking effect, however, was reversed by the addition of IL-2. No inhibition was obtained with antibody specific for E_αE_β when B10.A(4R) spleen cells, which do not express E_αE_β, or when B10.A(4R) accessory cells, which were reconstituted with (BALB/c X B10.A(4R)) F1 T cells, were used as stimulators. Stimulator cells heterozygous for H-2 could be inhibited by antibodies to the parental haplotype not encoded in the clones (H-2K^d). These and previous results suggest that H-2K-restricted minor histocompatibility antigen-specific recognition transmits an activating signal to the clones and to the stimulator cells. The clones probably are induced to express more IL-2 receptors. The stimulator T cells seem to interact through A_αA_β and E_αE_β molecules with syngeneic accessory cells. This interaction results in IL-2 production by the stimulator T cells and thus in the proliferation of the clones.     

Mixed-Haplotype and Mixed-Isotype Major Histocompatibility Complex Class II Molecules Detected by Murine T-Cell Clones and Their Possible Involvement in Autoimmunity

The recognition of antigen by T lymphocytes (T cells) is restricted by Class I or Class II major histocompatibility complex (MHC) gene products, the phenomenon called “MHC restriction.” MHC restriction is speculated to be one of the major elements for the association of disease susceptibility to MHC haplotypes. Clones of T cells have been shown to be powerful tools for the analysis of such restriction specificity. In this report, I describe unique mixed-isotype Aβ^d/Eα^drestriction molecules detected by T-cell clones in (B6Eα^d× BALB/c)F1 transgenic mice. The restriction specificity of these clones was confirmed by anti-Class II mAb blocking experiments. The ability of spleen cells from Aβ^dand Eα^ddouble transgenic B6 (B6Aβ^dEα^d) mice that express Aβ^d/Eα^dmolecules to present KLH to these clones supported the existence of such unique specificity. I also describe autoreactive as well as KLH-reactive T-cell clones restricted by mixed-haplotype Aβz/Aα^dClass II molecules derived from (NZB × NZW)F1 (B/WF1) mice. The restriction specificity was demonstrated by mAb blocking experiments and by experiments using Class II gene-transfected antigen-presenting cells. It is possible that such unique mixed-isotype and mixed-haplotype Class II molecules are critically involved in autoimmunity. In addition, the detailed methodology for establishing T-cell clones currently employed in my laboratory is described.     

MHC recognition by clones of Mls specific T-lymphocytes

To test whether M1s determinants, like other non-MHC or nominal antigens, are recognized by T-cells in association with H-2 determinants, the in vitro proliferative responses of T-cell lines and clones were studied. Lines and clones were prepared by soft agar cloning (B10.BR x BALB/c)F₁ (H-2^k/H-2^d, M1s^b/M1s^b) T-cells responding in a primary MLR to AKD2F1 (H-2^k/H-2^d, M1s^a/M1s^a) stimulator cells. All the T-cell clones obtained could respond equally well in a proliferative assay to the Mls^a determinant in association with the H-2 haplotype of either parent, i. e., DBA/2 (H-2^d, M1s^a), and AKR (H-2^k, M1s^a) both stimulated equally well. When the T-cell lines and clones were screened against stimulators from recombinant inbred (RI) strains, it became apparent that strains exhibiting the H-2^b, M1s^a genotype stimulated poorly or not at all. This shows that the T-cell response to M1s^a involves MHC recognition, and raises the possibility that the response to M1s^a can involve recognition of H-2 specificities shared between the H-2 ^k and H-2 ^d haplotypes.Abbreviations used in this paper MHC major histocompatibility complex - MLC mixed lymphocyte culture - IL-2 interleukin 2 - Con A concanavalin A - RI recombinant inbred Howard Hughes Medical Institute     

Hybrid Ia antigens: Genetic,serologic, and biochemical analyses

Ia specificities 22 and 23 were found to be determinants on hybrid Ia molecules, formed by the noncovalent binding of a 26,000–28,000 dalton beta polypeptide chain (A_e) coded by the I-A subregion and a 32,000–35,000 dalton alpha chain (E_α) coded by the I-E subregion. For expression of Ia. 23 the A_e chain, coded by the I-A subregion, must be derived from the H-2^d haplotype, while A^b, A^s, or A^k can provide the complementing beta chain for the expression of Ia. 22. For expression of Ia. 22 and Ia. 23, most Ia. 7 positive strains can provide the complementing alpha chain (E_α), with the one exception of B 10. PL (E^u), which is Ia. 7 positive but will not complement with A^d to express Ia. 23. Antisera were also produced against hybrid Ia antigens by immunizing with F₁ cells expressing Ia. 22 or Ia. 23 generated by transcomplementation. These antisera detect the same specificities as conventional anti-Ia. 22 and anti-Ia. 23 sera produced against cis-complementing Ia antigens. It is postulated that hybrid Ia determinants are involved in recognition and generation of immune response to antigens under dual Ir gene control. It is also suggested that there are 2 types of Ia specificities: (1) allotypic Ia specificities expressed on the alpha or beta chains (for example, Ia. 7 on the E_α chain) and (2) hybrid Ia specificities, which are unique interaction determinants formed by the association of alpha and beta chains (for example, Ia. 22 and Ia. 23). These interaction gene products may be involved in antigen recognition and presentation.     

Variable spread of X inactivation affecting the expression of different epitopes of the Hya gene product in mouse B-cell clones

Cloned B-cell lines from a female T16H/XSxr mouse in which Tdy expression was suppressed due to X inactivation and from a male X/XSxr mouse, both of the (kxb)F₁ haplotype, were examined for H-Y expression. This was determined both by their ability to act as targets for H-2^k and H-2^b-restricted H-Y-specific cytotoxic T cells and by their ability to stimulate the proliferation of H-2K^k, H-2D^b (class I) and A^b (class II)-restricted T-cell clones. In B-cell clones from the T16H/XSxr mouse, expression of H-Y/D^b exhibited partial X inactivation and only a proportion ( 30%) of the cells were targets for or stimulated H-2D^b-restricted H-Y-specific T cells. In contrast, H-Y eiptopes restricted by H-2^k (H-Y/K^k, H-Y/D^k) and A^b (H-Y/A^b) exhibited no X inactivation. Furthermore, no inactivation of H-Y/D^b, H-Y/A^b, or H-Y^k was observed in the male X/XSxr mouse. These results indicate that the T16H/XSxr female is a mosaic, as a result of the variable spread of X inactivation into the Sxr region. They further suggest that the H-Y antigen recognized in association with H-2^k and H-2D^b class I molecules and A^b class II molecules may be the product of more than one gene.     

Genetic Control of Immune Responses to a Synthetic Fimbrial Antigen of Actinobacillus actinomycetemcomitans

The incidence of infection by Actinobacillus actinomycetemcomitans, one of the important pathogens in human periodontal diseases, has been reported to be associated with racial background and genetic factors. We attempted to determine the genetic regulation of immune responses to A. actinomycetemcomitans fimbriae, an attachment factor, using various inbred strains of mice. For this purpose, we synthesized an oligopeptide antigen using the amino acid sequence of the fimbriae and conjugated this antigen to branched lysine polymer resin beads. After immunization with the synthetic A. actinomycetemcomitans fimbrial antigen, serum antibody levels and the delayed-type hypersensitivity (DTH) reaction to the antigen were measured by enzyme-linked immunosorbent assay (ELISA) and footpad swelling responses, respectively. The strains of mice found to be high-IgG responders to the antigen were B10.HTT, B10.RIII, B10A (5R) and B10.S (9R). These results indicate that mice with E_β^s: E_α^k, E_β^r: E_α^r and E_β^b: E_α^k respond strongly to the synthetic peptide. All of the high-IgG responders showed a high DTH response. A cell transfer experiment confirmed that CD4 T cells mediated with a DTH response to the synthetic peptide. Thus, the results of this study demonstrate that the immune responses to A. actinomycetemcomitans fimbriae are genetically controlled.     

IN SEARCH OF A PHYSIOLOGICAL BASIS FOR COVARIATIONS IN LIGHT‐LIMITED AND LIGHT‐SATURATED PHOTOSYNTHESIS1

The photosynthesis‐irradiance (PE) relationship links indices of phytoplankton biomass (e.g. chl) to rates of primary production. The PE curve can be characterized by two variables: the light‐limited slope (α^b) and the light‐saturated rate (P^b_max) of photosynthesis. Variability in PE curves can be separated into two categories: that associated with changes in the light saturation index, E_k (=P^b_max/α^b) and that associated with parallel changes in α^band P^b_max (i.e. no change in E_k). The former group we refer to as “E_k‐dependent” variability, and it results predominantly from photoacclimation (i.e. physiological adjustments in response to changing light). The latter group we refer to as “E_k‐independent” variability, and its physiological basis is unknown. Here, we provide the first review of the sporadic field and laboratory reports of E_k‐independent variability, and then from a stepwise analysis of potential mechanisms we propose that this important yet largely neglected phenomenon results from growth rate–dependent variability in the metabolic processing of photosynthetically generated reductants (and generally not from changes in the oxygen‐evolving PSII complexes). Specifically, we suggest that as growth rates decrease (e.g. due to nutrient stress), reductants are increasingly used for simple ATP generation through a fast (<1s) respiratory pathway that skips the carbon reduction cycle altogether and is undetected by standard PE methodologies. The proposed mechanism is consistent with the field and laboratory data and involves a simple new “twist” on established metabolic pathways. Our conclusions emphasize that simple reductants, not reduced carbon compounds, are the central currency of photoautotrophs.     

Interactions between MHC-encoded products and cloned T-cells. I. Fine specificity of induction of proliferation and lysis

To study the interactions between T cells and class I MHC products, we developed in vitro a T-cell line reactive to H-2K^b stimulating cells and derived T-cell clones from it. Although the T-cell line could proliferate in the absence of exogeneous T-cell growth factors when stimulated with H-2K^b spleen cells, each of the derived T-cell clones required both H-2K^b stimulating cells and an external source of T-cell growth factor for its propagation. Each of the T-cell clones was also cytolysic for H-2K^b target cells. Such T-cell clones allowed the comparison of the antigenic requirements for proliferation and cytolysis. By using H-2K ^b mutant mice, we found that while the original anti-H-2K^b T-cell line reacted with each of the six mutants tested, the individual T-cell clones could be distinguished in terms of their reactivity pattern. Similar fine specificity patterns were found when H-2K ^b mutant cells were used as stimulating or target cells for any given T-cell clone. Each of the three monoclonal H-2K^b-specific antibodies reacting with different epitopes of the H-2K^b molecule totally inhibited H-2K^b-induced proliferation and lysis by the T-cell clones. Further blocking studies involved use of Fab antibody fragments and definition of their reactivity on cells from the H-2K ^b mutants. We concluded that: (1) blocking with a monoclonal antibody does not prove identity of alloantigens recognized by the T-cells and the antibody; (2) a monoclonal antibody could either block or not block H-2K^b-CTL interactions depending on structural variations of the H-2K^b molecule not affecting the CTL-H-2K^b functional interaction; (3) blocking one type of H-2K^b-T-cell interaction (induction of proliferation) always affects the other type (cytolysis).Abbreviations used in this paper MHC major histocompatibility complex - CTL cytotoxic - T lymphocytes - Th T helper cells - PMA 4-phorbol 12-myristate 13-acetate - Con A Concanavalin A - LPS E. coli lipopolysaccharide - SCA Con A stimulated rat spleen-cells supernatant - SBD B6 anti-DBA/2 mixed lymphocyte culture supernatant - TCGF T-cell growth factors - IL-2 interleukin 2 - mAb monoclonal antibody - FCS fetal calf serum - PBS phosphate buffered saline - C complement     

Coreceptor function of CD4 in response to the MHC class I molecule

The specificity of the T-cell receptor (TCR) and its interaction with coreceptors play a crucial role in T-cell passing through developmental checkpoints and, eventually, determine the efficiency of adaptive immunity. The genes for the α and β chains of TCR were cloned from T-cell hybridoma 1D1, which was obtained by fusion of BWZ.36CD8α cells with CD8⁺ memory cells specific for the H-2K^b MHC class I molecule. Retroviral transduction of the 1D1 TCR genes and the CD4 and CD8 coreceptor genes was used to obtain 4G4 thymoma variants that exposed the CD3/TCR complex together with CD4, CD8, or both of the coreceptors on their surface. Although the main function of CD4 is to stabilize the interaction of TCR with MHC class II molecules, CD4 was found to mediate the activation of transfected cells via TCR specific for the H-2K^b MHC class I molecule. Moreover, CD4 proved to dominate over CD8, since the response of CD4⁺CD8⁺ transfectants was suppressed by antibodies against CD4 and the A^b MHC class II molecule but not to CD8. The response of CD4⁺ transfectants was not due to a cross-reaction of 1D1 TCR with MHC class II molecules, because the transfectants did not respond to splenocytes of H-2^b knockout mice, which were defective in the assembly of the MHC class I molecule/β2 microglobulin/peptide complex and did not expose the complex on cell surface. The domination was not due to sequestration of p56^lck kinase, since CD4 devoid of the kinase-binding site was functional in 4G4 thymoma cells. The results were used to explain some features of intrathymic cell selection and assumed to provide an experimental basis for developing new methods of anticancer gene therapy.     

Signaling to a B-cell clone by Ek,but not Ak,does not reflect alteration of A k genes

The mouse B-cell clone, CH12.LX (Ia^k, Ly-1⁺, ⁺, ⁺), can be induced to differentiate and secrete antibody in an antigen-specific, H-2-restricted manner. Induction requires two signals. One must be provided by the binding of specific antigen to the membrane IgM; the other is delivered by the binding of E^k-specific T-cell hybridomas to the E^k molecules of CH12.LX (Bishop and Haughton 1986). Previous studies demonstrated that E^k-specific monoclonal antibodies (mAbs) could substitute for T cells in delivering the second differentiative signal (Bishop and Haughton 1986). Although CH12.LX cells present A^k to A^k-restricted or alloreactive T-helper cells, neither T cells nor mAbs specific for A^k induce differentiation (Bishop and Haughton 1986). However, since the A^kspecifc mAbs tested previously were -chain-specific and the Ia epitope specificity of the T cells used was unknown, it is possible that the differentiative signal delivered to the CH12.LX class 11 molecule is chain-specific. Here we report the effects of ten additional Ia^k-specific mAbs upon the differentiation of CH12.LX. In addition, a cl)NA library was prepared from CHI 2.LX cells, clones corresponding to the and chains of the A^k molecule were isolated, and their nucleotide sequences were determined. Finally, the A^k and E^k molecules of CH12.LX and H-2^k spleen cells were compared by two-dimensional gel electrophoresis to examine possible post-translational differences in the Ia^k molecules of CH12.LX.     

Purification and some Properties of β-Xylosidase from Trichoderma viride

β-Xylosidase was purified 25 fold from a culture filtrate by ammonium sulfate fractionation, DEAE-Sephadex chromatography, column electrophoresis, gel filtration on Biogel P-100, and isoelectric focusing. The purified β-xylosidase was found to be homogeneous on SDS (sodium dodecyl sulfate) polyacrylamide gel electrophoresis and on disc electrophoresis. A molecular weight of 101,000 was estimated by chromatography on Sephadex G-200, and 102,000 was obtained by SDS polyacrylamide gel electrophoresis. The purified p-xylosidase had an isoelectric point at pH 4.45, and contained 4.5% carbohydrate residue. The optimum activity for the enzyme was found to be at pH 4.5 and 55°C. The enzyme activity was inhibited by Hg^{2 +}, and N-bromosuccinimide at a concentration of 1 x 10^?3 m. The purified enzyme hydrolyzed phenyl β-d-xyloside (k_o—13.0 sec”¹), p-nitrophenyl β-d-xyloside (k_o=2l.3 sec^?1), o-nitrophenyl β-d-xyloside (k_o = 22.2 sec^?1), o-chlorophenyl β-d-xyloside (k_o = 20.0 sec^?1), p-methylphenyl β-d-xyloside (k_o~9.0 sec^?1), o-methylphenyl β-d-xyloside (k_o= 10.7 sec^?1), p-methoxyphenyl β-d-xyloside (k_o=10.3 sec^?1), o-methoxyphenyl β-d-xyloside (&;_o=10.9 sec^?1), xylobiose (k_o = 36A sec^?1), xylotriose (k_o = 34.5 sec^?1), xylotetraose (k_o~HA sec^?1), and xylopentaose (k_o= 13.0 sec^?1). On enzymic hydrolysis of phenyl β-d-xyloside, the reaction product was found to be β-d-xylose with retention of configuration. The purified p-xylosidase was practically free of α-xylosidase and β-glucosidase activities.     

Expression of the I-E target antigen for T-cell killing requires two genes

TheH?2I ^k region encodes at least two different target antigens for unrestricted T-cell mediated killing. The first is controlled by theI?A region alone and the second depends on a pair of alleles, one located to the left ofI?B (presumably inI?A) and the other to the right ofI?J (presumably inI?E). Hence, effector cells nominally specific for a product of theI?E region do not kill target cells with the sameI?E region as the stimulator unless theI?A region is also shared. Some effectors specific forH?2I ^k , such as A.TH anti-A.TL and B10.A(4R) anti-B10.A(2R), cross-react with B10.A(3R) and B10.A(5R) target cells. A product of theH?2 ^b haplotype was shown to complement products of theH?2 ^d orH?2 ^k haplotypes in forming this cross-reactive determinant. The results are consistent with recent biochemical data on the component chains of Ia antigens.     

The minimal polymorphism of class II Eα chains is not due to the functional neutrality of mutations

Given the extensive allelic amino acid sequence polymorphism present in the first domain of A, A, and E chains and its profound effects on class II function, the minimal polymorphism in the mouse E chain (and in its human homologue DR) is paradox. Two possible explanations for the lack of polymorphism in E are: (1) the E chain plays such a uniquely critical structural/functional role in antigen presentation, T-cell activation, repertoire selection, and/or pairing with E or other proteins for expression that it cannot vary, and mutations are selected against; (2) the E chain plays a less significant role than the outer domains of other major histocompatibility complex (MHC) proteins in determining the interactions with processed peptides or with T-cell receptor (TCR), so there is no selective pressure to maintain new mutations. To explore this question we compared the ability of transfectants expressing wild type (wt) EE ^d and mutant E wt E ^d proteins to present peptides and bacterial superantigens to T-cell hybridomas. Mutations at the E amino acid positions 31, 52, and 65&66, to residues that represent allelic alternatives in A chains, significantly reduced activation of peptide-specific T hybridomas, and mutations at 71 sometimes enhanced T-cell stimulation. None of the E mutations reduced, and some enhanced, superantigen stimulation of T-cell hybridomas. These results argue against the hypothesis that E chains are minimally polymorphic because mutations in E are functionally neutral.     

Alteration of the T-cell receptor repertoire in A. CA mice expressing anEa d transgene

In an effort to generate an A.CA mouse expressing E^d, the Ea^d gene has been introduced into A. CA mice which lack the major histocompatibility complex (MHC) class II E molecule. Flow cytometric analysis shows cell surface expression of the E chain on lymphocytes and macrophages in the transgenic mice. Analysis of T-cell receptor (Tcr) genes deleted in some E-expressing mouse strains demonstrates that T cells expressingTcrb-VS are partially deleted in these transgenic mice while those expressingTcrb-V8 andTcrb-11 are not. In addition, the expressed E^d chain can promote Mycoplasma arthriditis mitogen (MAM)-induced T-cell proliferation. The expression of the Ea chain, presumably as an Aß ^fE^d heterodimer, can alter the peripheral T-cell repertoire and T-cell reactivity to a microbial superantigen.     

Fine specificity and T-cell receptor β-chain gene rearrangements of five H-2Db-specific cytotoxic T-cell clones

A panel of cytotoxic T lymphocyte clones that recognize H-2^b target cells has been established. Six different clones were distinguished according to the following criteria. First, the fine specificity of the clones was determined by testing proliferation and cytotoxicity on target cells of recombinant mice. Clone 221 recognized H-2K^b, and five other clones recognized H-2D^b. Clone 433 distinguished itself from the other five D^b-specific clones by cross-reacting with an antigen on H-2^k cells. Second, the presence of an idiotypic determinant as defined by the 3179 clone-specific monoclonal antibodies was investigated in cytotoxicity inhibition experiments. One of the D^b-specific clones, 653, was inhibited by these antibodies and was therefore clearly different from the other D^b-specific clones. The third criterion involved the rearrangement pattern of the DNA coding for the chain of the T-cell receptor. Southern blot analysis showed that each clone had a unique pattern. Interestingly, clone 653 , which expresses the same idiotypic determinant as clone 3F9, had deleted the C 1 gene cluster, whereas this gene is functionally expressed in clone 3179.Abbreviations used in this paper C constant gene segment - Con A concanavalin A - CTLs cytotoxic T lymphocytes - D diversity gene segment - ³H-dThd tritiated thymidine - J joining gene segment - kb kilobase pairs - LPS lipopolysaccharide - MHC major histocompatibility complex - MLC mixed lymphocyte culture - SDS sodium dodecyl sulfate - V ariable gene segment     

Gibberellins in Immature Seeds of Pharbitis nil

A new gibberellin, gibberellin A₂₀ (GA₂₀), was isolated from immature seeds of morning-glory (Pharbitis nil). Its structure was established as 4aα, 7α-dihydroxy-1β-methyl-8-methylenegibbane-1α, 10β-dicarboxylic acid-1→4a lactone (I) on the basis of its physicochemical analysis as well as chemical evidences. GA₂₀ shows marked growth promoting activities on dwarf maize d₂ and d₅ but weak activities on d₁, rice seedling and dwarf pea.     

Hybrid (combinatorial) Ia specificities: Gene complementations to generate Ia.22

Ia specificity 22 is expressed on a hybrid I-E molecule formed by the association of a beta chain (Ae) coded for by the I-A subregion and an alpha chain (E) encoded by the I-E subregion. Ia.22 can be generated by the complementation of A ^b , A ^k A ^s , A ^r with E ^d , E ^k , E ^vp , E ^r , E ^w3 , E ^u , E ^v but not E ^b , E ^f , E ^q , and E ^s . With the exception of H-2 ^p which does not complement with A ^s to generate Ia.22, all Ia.7-positive (I-E) haplotypes can provide the permissive E allele. It is postulated that Ia.22 is a combinatorial Ia determinant generated by the association of the alpha and beta chains. These determinants are probably involved in the immune recognition of antigens under dual Ir-gene control.     

Functional similarities of AeEα Ia molecules as determined by analysis with T-cell clones

Recognition of A_eE Ia antigens at the functional level was investigated using T-cell clones. The reactivities of an alloreactive and an antigen-reactive clone, both of which recognized A_eE Ia molecules, were compared on a panel of stimulator/antigen-presenting cells of various genotypes. The two clones recognized all tested A _e ^b E ^x Ia molecules, where x is a haplotype capable of expressing an Ia.7-bearing E polypeptide. Ia antigen recognition by either clone could be inhibited by the monoclonal antibody Y-17, which recognizes a combinatorial serologic determinant on certain A_eE molecules. There were no differences in the recognition of Ia by the alloreactive versus the antigen-reactive clone, suggesting that Ia antigens are recognized by the two clones in a fundamentally similar way. The recognition of these various Ia molecules by the two cloned T-cell lines provides evidence that the E polypeptides from H-2 haplotypes k, d, r, and u are functionally indistinguishable.Abreviations MHC major histocompatibility complex - Mb myoglobin - MLR mixed leukocyte reaction - PBS phosphate buffered saline - APC antigen presenting cell - KLH keyhole limpet hemocyanin - GAT poly (glut⁶⁰ alai³⁰ tyr¹⁰)n - (TG)-A—L poly (L-tyr, L-glu)-poly (D, L-ala)—poly L-lys - GLPhe poly (glu⁵⁵ lys³⁶ phe⁹)n     

Alloreactive T-cell clones. Ly phenotypes predict both function and specificity for major histocompatibility complex products

We have studied the association of Ly phenotype with function and specificity for major histocompatibility complex (MHC) products by examining the properties of 21 T-cell clones derived from B10 anti-B 10.D2 and B10.A anti-B10.D2 mixed lymphocyte cultures (MLC). T cells were selected after MLC solely on the basis of Ly phenotype, cloned by limiting dilution, and tested for stability of Ly phenotype, function and specificity for class I or class II MHC products. Sixteen Ly-1⁺2^– and five Ly-1^–2⁺ T-cell clones were tested. The clones selected for the Ly-1 ⁺2^– phenotype maintained this phenotype, expressed helper but not lytic function, and recognized class II MHC products (I-A^d or I-Ed). All Ly-1^–2^– clones maintained this phenotype, possessed cytolytic but not helper activity, and recognized class I MHC products (D^d and L^d). Our data therefore confirm at the clonal level the original observations of a remarkably consistent correlation between Ly markers, MHC specificity, and. function. They suggest that the expression of Ly antigens on T-cell clones forms part of a genetic program for each of these specialized cells that also determines their function and MHC specificity.Abbreviations used in this paper MHC major histocompatibility complex - MLC mixed lymphocyte culture - TCGF T cell growth factor (Interleukin-2) - Con A Concanavalin A - DME Dulbecco's modified Eagle's medium - PHA phytohaemagglutinin - LPS lipopolysaccharide - TRF-C T cell replacing factor required for induction of cytolytic cells from thymocytes - PBS phosphate-buffered saline (pH 7.4)     

Purification and Some Properties of β-Xylosidase from Emericella nidulans

β-Xylosidase was purified 662 fold from a culture filtrate by ammonium sulfate fractionation, gel filtration on Biogel P-100, DEAE-Sephadex chromatography, and gel filtration on Sephadex G-200. With isoelectric focusing, the purified β-xylosidase found to be homogeneous on SDS (sodium dodecyl sulfate) polyacrylamide gel electrophoresis. The molecular weight was estimated by gel filtration to be 240,000, and 116,000 by SDS polyacrylamide gel electrophoresis. The purified β-xylosidase had an isoelectric point at pH 3.25, and contained 4% carbohydrate residue. The optimum pH was found to be in the range of 4.5 ~ 5, and the optimum temperature was 55°C. The enzyme activity was inhibited by Hg^{2 +}, SDS, and N-bromosuccinimide at a concentration of 1 × 10^?3 m, and also p-chloromercuribenzoate at a concentration of 1 × 10^?4m. The purified enzyme hydrolyzed phenyl β-d-xyloside (k_o = 302.6 sec^?1),β-nitrophenyl β-d-xyloside (k_o = 438.9 sec^?1), o-nitrophenyl β-d-xyloside (k_o = 431.0 sec^?1), p-chlorophenyl β-d-xyloside (k_o = 207.9 sec^?1), o-chlorophenyl β-d-xyloside (k_o = 211.8 sec^?1), β-methylphenyl β-d-xyloside k_o = 96.5 sec^?1), o-methylphenyl β-d-xyloside (k_o = 83.1 sec^?1), p-methoxyphenyl β-d-xyloside (k_o = 99.3 sec^?1), o-methoxyphenyl β-d-xyloside (k_o= 100.0 sec^?1), xylobiose (k_o = 992A sec^?1), xylotriose (k_o = 1321.9 sec^?1), xylotetraose (k_o = 7S9.1 sec^?1) and xylopentaose (k_o = 508.0 sec^?1). On enzymic hydrolysis of phenyl β-d-xyloside, the reaction product was found to be β-d-xylose with retention of the configuration. The purified β-xylosidase was practically free of a-xylosidase and β-glucosidase activities.