Role of N-acetyl-D-galactosamine residue on B151K12-derived T cell-replacing factor (B151-TRF) molecule in B cell-receptor binding and -stimulating activity

The role of sugar moiety on T cell-replacing factor molecule derived from a monoclonal T cell hybridoma B151K12 (B151-TRF) was analyzed with respect to the interaction with receptor on B cells. The induction of B cell differentiation into Ig-secreting cells by B151-TRF was specifically inhibited by addition of N-acetyl-D-galactosamine (GalNAc) to culture. Such inhibition appeared to be attributed to the interference of GalNAc in the interaction of TRF with its receptor, because absorption of TRF activity with B cells was notably inhibited by the presence of GalNAc. To substantiate this point further, we established binding assay of B151-TRF molecule to the receptor on B cells by using 125I-labeled TRF fraction enriched by reversed-phase high-performance liquid chromatography and gel filtration. The results revealed that the binding of 125I-TRF molecule to the B cells was almost completely blocked by GalNAc. Moreover, the existence of GalNAc residue(s) on B151-TRF molecule was evidenced by the facts that 1) the TRF activity was eluted from lectin gels with specificity for GalNAc as revealed by the functional assay, and 2) the 125I-TRF molecule specifically bound to such lectin gels. Thus, the GalNAc residue(s) on B151-TRF molecule plays an important role in binding of TRF molecule to the receptor and in the stimulation of B cells. The molecular properties of B cell-stimulatory B151-TRF and its mode of interaction with corresponding receptor on B cells were discussed in the context of B151-TRF as a glycosylated lymphokine molecule and B151-TRF receptor as a carbohydrate-binding protein (animal lectin).     

BCGFII activity on activated B cells of a purified murine T cell-replacing factor (TRF) from a T cell hybridoma (B151K12)

Experiments were performed to examine a growth-promoting activity on B cells or B leukemic cells of T cell-replacing factor (TRF) produced by a murine T cell hybridoma (B151K12) which constitutively produces TRF. The cellfree supernatant (CFS) from B151K12 cells (B151-CFS) could induce terminal differentiation of pre-activated B cells or in vivo passaged chronic B leukemia cells, BCL1, into immunoglobulin-secreting cells, while it did not exert a nominal lymphokine activity such as BCGFI (now known as BSFpl), IL 2, or gamma-interferon. However, it promoted [3H]thymidine uptake of dextran sulfate (DXS)-stimulated normal B cells and in vivo passaged BCL1 cells, suggesting that it also has BCGFII activity. We tried extensively to purify and to separate the TRF active molecule from the BCGFII active molecule by using many types of purification procedures. The purification scheme consisted of ammonium sulfate precipitation, DEAE-cellulose chromatography, Blue-Sepharose chromatography, hydroxylapatite chromatography, and gel permeation with fast protein liquid chromatography (FPLC). It was revealed that the BCGFII active molecule was hardly separable from the TRF during the entire purification procedure. The TRF as well as BCGFII active materials were glycoprotein with an apparent m.w. of 50 to 60 Kd on gel permeation chromatography and 18 Kd on SDS-PAGE under reducing conditions. The BCGFII active materials were hardly separable from the TRF active one, even after a reverse-phase FPLC, in which both BCGFII and TRF activities were recovered in the fractions eluted at 44 to 48% acetonitrile in 0.1% trifluoroacetic acid (TFA). Furthermore, the absorption of TRF and BCGFII active materials by using BCL1 cells removed not only TRF but also BCGFII activity. Moreover, B cell-specific monoclonal antibody (9T1), which can preferentially block TRF-dependent plaque-forming cell responses, also inhibited the expression of BCGFII activity to BCL1 cells. Taking all of the results together, we conclude that the TRF from B151K12 cells promotes growth of appropriately activated, such as DXS-stimulated normal cells and BCL1 tumor cells. These results suggest that B151-TRF may act on B cells as B cell growth and differentiation factors.     

Identification of two distinct factors, B151-TRF1 and B151-TRF2, inducing differentiation of activated B cells and small resting B cells into antibody-producing cells

We demonstrated previously that cellfree supernatant of the B151K12 T cell hybridoma (B151-CFS) contained T cell-replacing factor (here in after referred to as B151-TRF1) capable of inducing growth and differentiation of antigen-activated B cells into antigen-specific plaque-forming cells (PFC). In the present study, we have identified in B151-CFS another unique lymphokine activity (referred to as B151-TRF2), which induces polyclonal differentiation of unstimulated B cells into IgM-secreting cells without concomitant stimulation of antigen, mitogen, or anti-Ig antibody. The B151-TRF2 activity induced polyclonal IgM PFC responses via the action on surface Ig-positive small resting B cells from normal unprimed mice. This activation was effective across an H-2 barrier, and apparently independent of the presence of T cells and accessory cells. Interestingly, the B151-TRF2 activity notably stimulated B cells of neonatal and mutant DBA/2Ha mice, which are nonresponders to B151-TRF1, whereas it failed to activate the xid B cells from CBA/N mice. To substantiate that B151-TRF1 and B151-TRF2 activities are mediated by mutually distinguishable molecules, an absorption experiment of B151-CFS was performed by utilizing DBA/2Ha B cells which are lacking in B151-TRF1 receptor. It was found that DBA/2Ha B cells could absorb B151-TRF2 activity but not B151-TRF1 activity. In contrast, murine chronic B cell leukemia BCL1 cells, which were shown to differentiate into IgM-secreting cells by stimulation with B151-CFS, selectively removed B151-TRF1 activity but not B151-TRF2 activity. Furthermore, biochemical analysis revealed that the B151-TRF2 was a heat (56 degrees C for 30 min)-sensitive protein with an apparent m.w. of 30,000 by gel filtration, whereas B151-TRF1 was a heat-resistant glycoprotein with m.w. of 50,000. In addition, it was shown that prostaglandin E2 selectively inhibited B151-TRF2-mediated B cell responses. These results demonstrate clearly that B151-TRF1 and B151-TRF2 are distinct B cell differentiation factors involved in the different activation pathways of distinct B cell subpopulations. The immunologic implication of B151-TRF2 activity in B cell differentiation is discussed in comparison with other lymphokines so far reported to activate small resting B cells.     

Evidence for existence of two distinct TNP-Ficoll-responsive B cell subpopulations preferentially reactive either to a T cell-replacing factor (B151-TRF) or to a signal from accessory cells

The ability of B cells to respond to TNP-Ficoll has been shown to correlate with their ability to respond to T cell-replacing factor (TRF). The present study analyzed the relationship of TNP-Ficoll-responsive B cells to a TRF-responsive B cell subpopulation. The B cells from normal, unprimed mice responded to TNP-Ficoll in the presence of accessory cells. Such responses were notably augmented by the addition of TRF derived from a monoclonal T cell hybridoma, B151K12(B151-TRF). Interestingly, B cells of mutant X-linked immunodeficient DBA/2Ha which failed to respond to B151-TRF gave anti-TNP PFC responses to TNP-Ficoll comparable to those of normal mice, depending on the presence of accessory cells. However, under this condition, the addition of B151-TRF did not augment the TNP-Ficoll responses. One explanation of the augmentation of TNP-Ficoll response by TRF for the B cells from nondefective mice was that two distinct B cell subpopulations exist which differ in their respective activation requirement for TRF and accessory cells. To examine this possibility, syngeneic accessory cells were pulsed with TNP-Ficoll and were assayed for their ability to activate normal B cells in the presence or absence of B151-TRF. The results revealed that TNP-Ficoll-pulsed accessory cells were able to induce primary anti-TNP PFC responses in normal B cells to the same magnitude as soluble TNP-Ficoll. However, these B cell responses induced by the TNP-Ficoll-pulsed accessory cells were not augmented by the addition of B151-TRF to the culture. These results support the notion that two distinct TNP-Ficoll-responsive B cell subpopulations exist; one requires accessory cell-B cell interaction to be activated by TNP-Ficoll but fails to respond to TRF, and the other can be activated by TRF in a totally accessory cell-independent manner.     

Establishment of an assay system for the detection of translated materials of T-cell-replacing factor mRNA in Xenopus oocytes

We established an assay system for detecting T cell-replacing factor (TRF) activity of translated materials in Xenopus oocytes of poly (A)-positive mRNA extracted from a T cell hybrid cell line, B151K12 (B151) which constitutively produces TRF. Since it was difficult to detect TRF activity of the translated products of B151-mRNA, partly because of low TRF activities, we developed the following two systems. First, RNA was prepared from B151 cells stimulated with phorbol myristate acetate and calcium ionophore A23187 because such stimulations augmented TRF production by approximately three to five-fold. Second, interleukin 2 (IL-2, 125 U/ml) was added to the culture of BCL1 cells to detect a small amount of TRF-active materials since IL-2 synergizes with a suboptimal dose of TRF to induce IgM secretion in TRF-responding BCL1 cells (chronic B cell leukemic cells). Here we describe TRF activity of translation products of B151-mRNA in Xenopus oocytes. B151-TRF mRNA was detected in the fractions sedimented between 15 and 18S by analysis using sucrose density gradient centrifugation.     

Immunoregulation in the rat: cellular and molecular requirements for B cell responses to types 1, 2, and T-dependent antigens

The requirements for primary in vitro plaque-forming cell (PFC) development in cultures of purified rat splenic B cells have been examined. Rat B cells were directly responsive to the type 1 antigen trinitrophenyl-Brucella abortus (TNP-BA), but both T cells and adherent accessory cells were required for B cell responses to the type 2 antigen TNP-Ficoll and the T cell-dependent (TD) antigen sheep erythrocytes (SRBC). However, the cellfree supernatants from concanavalin A-induced spleen cells of rat or mouse origin replaced the requirement for T cells and macrophages, and resulted in PFC development in response to TNP-Ficoll and SRBC and augmented PFC numbers in response to TNP-BA. Culture supernatants from induced murine T cell and macrophage cell lines were used to partially deduce the molecular requirements for the support of PFC development by rat B cells to these three antigens. Supernatants from the EL-4 (EL-4 sup) and B151 K12 (B15 sup) T cell lines augmented TNP-BA responses, suggesting that B cell growth factor II (BCGF-II) mediated this effect. An admixture of purified interleukin 2 (IL 2) and B15 sup supported PFC development to SRBC; indicating that IL 2, BCGF-II, and the T cell-replacing factor in B15 sup (B15-TRF) were sufficient to support this response. In addition, the IL 2 plus B15 sup-supported anti-SRBC PFC response was increased by the addition of an interleukin 1-containing fraction from the supernatant of the macrophage line P388D1. PFC development in response to TNP-Ficoll had the most stringent requirements and only occurred in the presence of EL-4 sup and B15 sup (IL 2, BCGF-I, BCGF-II, EL-TRF, B15-TRF). These data indicate that different cellular and molecular requirements exist for PFC development in response to types 1, 2, and TD antigens by rat B cells.     

Polyclonal B cell activation by a B cell differentiation factor, B151-TRF2. II. Evidence for interaction of B151-TRF2 with glycoprotein on B cell membrane via recognition of terminal N-acetyl-D-glucosamine residue(s)

We investigated the role of carbohydrates in the interaction of a B cell differentiation factor designated as B151-TRF2 derived from B151K12 T cell hybridoma with the corresponding receptor on B cells. Induction of polyclonal differentiation of unprimed B cells into IgM-secreting cells by B151-TRF2 was specifically inhibited by addition of N-acetyl-D-glucosamine (GlcNAc) but not by structurally unrelated monosaccharides such as D-galactose, D-glucose, and N-acetyl-D-galactosamine (GalNAc). Absorption of B151-TRF2 activity with spleen cells was specifically inhibited by the presence of GlcNAc. These results indicate that GlcNAc residues are involved in the interaction of B151-TRF2 with the receptor on B cells. To gain insight into mechanism by which GlcNAc inhibits B151-TRF2-mediated B cell responses, the existence of GlcNAc residues was examined on the B151-TRF2 molecule and the corresponding receptor on the B cell surface. The results revealed that B151-TRF2 molecule was not bound to various lectin-coupled agarose beads so far tested, suggesting absence of carbohydrate moieties on the B151-TRF2 molecule. By contrast, pretreatment of spleen cells with trypsin or glycosidase mixture abolished their ability to absorb B151-TRF2 activity. Moreover, B151-TRF2-absorbing ability of spleen cells disappeared by the pretreatment with beta-N-acetylglucosaminidase, which cleaves terminal GlcNAc. The fact that pnitrophenyl (PNP)-GlcNAc specifically inhibited such enzyme activity on target cells indicates that terminal GlcNAc on the B cell surface plays a crucial role in the interaction with B151-TRF2 molecule. Interestingly, it was also found that B151-TRF2 activity was trapped and eluted from GlcNAc-coupled agarose beads. Taken collectively, these results strongly suggest that B cell membrane receptors for B151-TRF2 comprise glycoproteins with a terminal GlcNAc residue(s), and that binding of B151-TRF2 with terminal GlcNAc on the receptor is important for the subsequent activation of B cells.     

B cell maturation factor (BMF): a lymphokine or family of lymphokines promoting the maturation of B lymphocytes

Two in vitro B cell tumor lines have been used to characterize and partially purify a lymphokine, or family of lymphokines, from monoclonal helper T cell immune response supernatants. These lymphokines induce the pre-B-like 70Z/3 tumor cell to synthesize Ig L chains and express complete Ig molecules on its cell surface, and cause the mature B cell-like WEHI-279 tumor cell to increase its ratio of secretory to membrane mu production, begin high rate Ig secretion, and then die. Most of the activity responsible for these changes co-purifies during five different separation procedures, implying the existence of a discrete molecule or closely related class of molecules able to mediate all of these effects. The molecules active in these systems appear distinct from the other lymphokines IL 1, IL 2, G/M-CSA, TRF, IFN, BCGF, and the activity variously termed IL 3/BPA/PSF/HCGF/MCGF, etc. We call these B cell-differentiating molecules BMF, or B cell maturation factor(s). The BMF molecules are mildly acidic (pI 5 to 6 in various conditions), extremely hydrophobic, probably heterogeneously glycosylated glycoproteins, with an apparent m.w. of 50,000 to 55,000 by gel permeation chromatography and 16,000 by SDS-PAGE. BMF has been purified approximately 3000-fold by three sequential chromatographic steps, with the use of the B tumor line assay systems. BMF molecules thus purified also cause normal resting splenic B cells to mature to the state of active Ig secretion.     

TRF requirements for in vitro PFC responses to SRBC and R36a. I. TRF is distinct from IL 2 but indistinguishable from polyclonal BCSF

In vitro PFC responses to the thymus-independent (TI) antigen Streptococcus pneumoniae R36a require T cell replacing factor(s) (TRF). This requirement for TRF is as significant as for the thymus-dependent (TD) antigen SRBC. TRF is shown to be distinct from IL 2 by the following observations: 1) culture supernatants from the cloned T cell line L2, collected over an 8-day period after allogeneic stimulation, transiently contain IL 2 activity but maintain high levels of TRF activity throughout 192 hr; 2) L2V, a variant subclone of L2, produces much higher levels of TRF activity than the parental line but no detectable IL 2 activity; 3) the addition of IL2+, TRF- supernatants from the T cell hybridoma FS6-14.13 does not affect the L2V SF-driven PFC responses to R36a or SRBC; and 4) the addition of contaminating T cells to cultures containing T cell-depleted spleen cells, L2V SF, and antigen does not affect the PFC response. TRF does appear to be indistinguishable from polyclonal B cell stimulating factor (BCSF), which stimulates polyclonal PFC responses in the absence of antigen, mitogen, or anti-Ig. The TRF and BCSF activities of L2V SF could not be separated by ion-exchange, hydrophobic-interaction, and gel-filtration chromatography. TRF and BCSF have an apparent m.w. of approximately 40,000.     

Polyclonal B cell activation by B cell differentiation factor B151-TRF2. I. Involvement of self-Ia recognition process mediated by B cells

The present study examined the functional role of Ia antigens on B cells in polyclonal B cell activation induced by a B cell differentiation factor, B151-TRF2. The polyclonal IgM PFC responses by B151-TRF2 were inhibited by monoclonal antibodies specific for class II MHC antigens (Ia antigens) but not class I MHC antigens. Such inhibition by anti-Ia antibodies was haplotype-specific and was observed in the absence of both T cells and accessory cells. Moreover, the anti-Ia antibody-induced inhibition of the B151-TRF2 responses was not due to the blocking of binding of B151-TRF2 to the corresponding B cell receptor. A series of kinetic studies revealed that some Ia-mediated cellular activation process occurs before the resting B cells become responsive to B151-TRF2. Thus, the B151-TRF2-mediated B cell responses consist of at least two distinct phases. The early phase is an Ia-dependent but B151-TRF2-independent process, whereas the late phase is an Ia-independent but B151-TRF2-dependent process. To further characterize the functional role of Ia antigens on B cells, an additional experiment was carried out by using F1 B cells which co-dominantly express both parental Ia antigens on the surface. Interestingly, it was observed that the degree of inhibition of the B151-TRF2-mediated responses of F1 B cells by anti-parental Ia antibody was, at best, one-half that of the parental B cells, suggesting that F1 B cells may be separated into two subpopulations with the restriction specificity for the respective parental Ia antigens. To examine this possibility, (B10 X B10.BR)F1 B cells were separated into adherent and nonadherent cell populations by their ability to bind to either one of the parental B cell monolayers, and the specificity of inhibition of their responses to B151-TRF2 by anti-Ia antibodies was assessed. It was found that the responses of (B10 X B10.BR)F1 B cells adherent to the B10 B cell monolayer or the B10.BR B cell monolayer were almost completely inhibited by anti-I-Ab and anti-I-Ak antibodies, whereas those of nonadherent cells were now selectively inhibited by anti-I-Ak and anti-I-Ab antibodies, respectively. These findings are interpreted as indicating that the B151-TRF2-responsive F1 B cells consist of at least two subpopulations with the restriction specificity for either one of the parental Ia antigens.(ABSTRACT TRUNCATED AT 400 WORDS)     

Demonstration of up-regulated IL 2 receptor expression on an in vitro cloned BCL1 subline

We have established BCL1 CL-3 cells capable of responding to B15-TRF and interleukin 2 (IL 2). This clone has both high affinity and low affinity receptors for IL 2 (IL 2R), but IL 2 by itself did not stimulate either proliferation or immunoglobulin (Ig) secretion. B15-TRF, which possesses both growth and differentiation activity, causes an increase in size of CL-3 cells and renders CL-3 cells responsive to IL 2, including an increased expression of IL 2R (eight-fold to 10-fold) and the differentiation of CL-3 cells into Ig secretion (60 to 80% of cultured cells). CL-3 cells pretreated with B15-TRF for 12 hr become competent to respond to IL 2 by up-regulation of IL 2R within 12 hr. In contrast CL-3 cells pretreated with IL 2 for 12 hr required 24 hr B15-TRF stimulation to result in IL 2R up-regulation. Thus the ordered action of B15-TRF and IL 2 is the most effective operational pathway for the up-regulation of IL 2R. This IL 2-mediated IL 2R up-regulation and induction of Ig synthesis depends upon the concentration of IL 2 in the culture. Both responses seem to be caused by IL 2 molecules bound to high affinity IL 2R. However, the possibility of involvement of low affinity IL 2R can not be vigorously excluded. In fact the level of IL 2 required for a response is far higher than that needed for activated T cell proliferation. This cloned BCL1 subline promises to be a useful tool for studying the regulation and mechanisms of B cell responses.     

Ia-restricted B-B cell interaction. I. The MHC haplotype of bone marrow cells present during B cell ontogeny dictates the self-recognition specificity of B cells in the polyclonal B cell activation by a B cell differentiation factor, B151-TRF2

We have demonstrated that B cell recognition of Ia molecules is involved in polyclonal B cell differentiation by B151-TRF2. The present study was undertaken to examine the Ia recognition specificity of B151-TRF2-responsive B cells in fully major histocompatibility complex (MHC)-allogeneic P1----P2, semiallogeneic P1----(P1 x P2)F1, and double donor (P1 + P2)----(P1 x P2)F1 and (P1 + P2)----P1 radiation bone marrow chimeras. The B cells from both P1----P2 and P1----(P1 x P2)F1 chimeras could give rise to in vitro immunoglobulin M-producing cells upon stimulation with B151-TRF2 comparable in magnitude to that of normal P1 B cells, and their responses were inhibited by anti-I-AP1 but not by anti-I-AP2 monoclonal antibody even in the presence of mitomycin C-treated T cell-depleted P2 spleen cells as auxiliary cells. In contrast, the B151-TRF2 responses of P1 B cells isolated from both (P1 + P2)----(P1 x P2)F1 and (P1 + P2)----P1 double bone marrow chimeras became sensitive to the inhibition of not only anti-I-AP1 but also anti-I-AP2 monoclonal antibody only when the culture was conducted in the presence of P2 auxiliary cells, demonstrating that they adaptively differentiate to recognize as self-structures allogeneic as well as syngeneic Ia molecules. Moreover, the experiments utilizing B cells from H-2-congenic mice and B cell hybridoma clones as auxiliary cells revealed that B151-TRF2-responsive B cells recognize Ia molecules expressed on B cells. Taken together, these results demonstrate that B151-TRF2-responsive B cells recognize Ia molecules expressed by B cells as self-structures and that their self-recognition specificity is dictated by the MHC haplotype of bone marrow cells present during the B cell ontogeny but not by the MHC haplotype of a radiation-resistant host environment.     

人端粒结合蛋白TRF1的克隆、表达和抗体制备

利用RT-PCR技术,从HeLa细胞的cDNA文库中扩增到人端粒结合蛋白1(hTRF1)基因编码区序列,克隆至pUCm-T载体,测序正确后,构建带His₆-tag原核表达载体pET-28c-TRF1,经IPTG诱导表达的His₆-TRF1融合蛋白分子量约为65kD,Western-blot证实表达产物可特异地与TRF1抗体sc-6165结合。用Ni^2＋NTA胶亲和层析纯化可得到电泳均一的融合蛋白,免疫新西兰纯种大白兔,获得特异性好的多克隆抗体,该抗体可用于免疫荧光染色和Western-blot方法检测哺乳动物细胞内源性的TRF1分子。     

Role of T cell-replacing factor (TRF) in the murine B cell differentiation: induction of increased levels of expression of secreted type IgM mRNA

T cell-replacing factor (TRF) is known to play a critical role in the regulation of B cell growth and differentiation. In this study, the role of TRF in the expression of mRNA for both IgM and IgG1 class was investigated. The TRF was purified from cellfree supernatants from a T cell hybridoma, B151K12. RNA was isolated from chronic B cell leukemia (BCL1) cells, DNP-KLH-primed B cells, or normal B cells cultured with or without LPS, and LPS plus TRF or LPS plus BSF-1. The steady state level of isotype-specific mRNA was assessed by Northern blot analysis with a mu-specific or a gamma 1-specific probe. It was demonstrated that BCL1 and purified B cells cocultured with TRF expresses increased levels (twofold and fourfold, respectively) of secreted forms of mu mRNA. Purified B cells from DNP-KLH-primed mice also expressed increased levels (twofold to fourfold) of mu as well as gamma 1 mRNA for secreted form by stimulation with TRF. Total expression of mu mRNA, however, was approximately threefold higher than that of gamma 1 mRNA. The stimulation of normal B cells with LPS plus TRF induced an increase in the levels of mu mRNA and gamma 1 mRNA expression, fourfold and threefold, respectively. However, the levels of gamma 1 mRNA expression was one-third of that induced in B cells stimulated with LPS plus BSF-1. These results indicate that TRF preferentially induces increased levels of secreted type of mu mRNA and induces less gamma 1 mRNA than BSF-1. The differential role of TRF from BSF-1 in the expression of Ig mRNA will be discussed.     

Human insulin receptor beta-subunit transmembrane/cytoplasmic domain expressed in a baculovirus expression system: purification, characterization, and polylysine effects on the protein tyrosine kinase activity.

We have expressed, purified, and characterized the insulin receptor protein tyrosine kinase (PTK) retaining the transmembrane and downstream domains. The proteins expressed in insect cells using a baculovirus expression system were identified as membrane-bound by immunofluorescence staining and biochemical characterization. One-step purification by immunoaffinity chromatography from Triton X-100 cell extracts resulted in a approximately 360-fold increase in the specific kinase activity with a yield of approximately 50%. An appMr = approximately 60,000 protein was the major component identified by both silver staining of the purified enzyme and immunostaining of the crude extracts after separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Using nondenaturing conditions, the molecular weight was estimated to be approximately 250,000 and approximately 500,000 by glycerol gradient centrifugation and gel permeation chromatography, respectively, suggesting that oligomers of the beta-subunit domains such as tetramers and octamers are formed. The basal PTK activity of this enzyme was much higher than those of previously reported soluble-form insulin receptor PTKs expressed in insect cells or the native receptor. Km and Vmax for two substrates, src-related peptide and poly(Glu, Tyr) (4:1), were 2.4 mM and 2.5 mumol min-1 mg-1 and 0.26 mM and 1.2 mumol min-1 mg-1, respectively. Specific activities measured under two previously reported conditions using histone H2B as a substrate were 100 or 135 nmol min-1 mg-1, in contrast to those of soluble PTKs which were reported to be 20 or 70 nmol min-1 mg-1, respectively. The purified enzyme was autophosphorylated at Tyr residues. Autophosphorylation activated the enzyme approximately 3-fold.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional analysis of mononuclear cells infiltrating into tumors. IV. Purification and functional characterization of cytotoxic cell-generating factor

Rat cytotoxic cell-generating factor (CGF) was purified from cell-free supernatants of a T cell hybridoma (6B2-B8) that constitutively produces CGF. CGF activity was assessed by its ability to generate cytotoxic cells against 51Cr-labeled T-9 cells from spleen cells of T-9-immunized rats. The purification scheme consisted of ammonium sulfate precipitation, AcA 54 gel permeation, Mono Q anion exchange chromatography, Superose 12HR 10/30 gel permeation, SDS-PAGE with subsequent electroelution, and ProRPC HR5/10 reverse phase column chromatography. Overall, CGF was purified approximately 13,000-fold, with a maximum 2.5% recovery of activity, and the sp. act. of the purified CGF was approximately 19,000 U/mg. The purified CGF is distinct from the other lymphokines such as IL-1, IL-2, IL-3, IL-4, T cell-replacing factor/IL-5, IL-6, and IFN-gamma. It is capable of promoting the generation of cytotoxic T cells from R1-10B5 (+) spleen cells of T-9-immunized rats and also stimulates a W3/25 (+) T cell hybridoma to express the IL-2R. The CGF has an apparent m.w. of 28,000 under non-reducing and 14,000 and 16,000 under reducing conditions. 125I-labeled CGF binds to normal thymocytes as well as splenic T cells. The highest level of binding of CGF was detected on splenic T cells derived from T-9-immunized rats that were previously shown to contain CTL precursors. The binding analysis with 125I-labeled CGF demonstrated that CGF binds to a specific cell surface molecule with an approximate m.w. of 60,000 to 70,000.     

Telomerase inhibitor PinX1 provides a link between TRF1 and telomerase to prevent telomere elongation

Telomere maintenance is essential for protecting chromosome ends. Aberrations in telomere length have been implicated in cancer and aging. Telomere elongation by human telomerase is inhibited in cis by the telomeric protein TRF1 and its associated proteins. However, the link between TRF1 and inhibition of telomerase elongation of telomeres remains elusive because TRF1 has no direct effect on telomerase activity. We have previously identified one Pin2/TRF1-interacting protein, PinX1, that has the unique property of directly binding and inhibiting telomerase catalytic activity (Zhou, X. Z., and Lu, K. P. (2001) Cell 107, 347-359). However, nothing is known about the role of the PinX1-TRF1 interaction in the regulation of telomere maintenance. By identifying functional domains and key amino acid residues in PinX1 and TRF1 responsible for the PinX1-TRF1 interaction, we show that the TRF homology domain of TRF1 interacts with a minimal 20-amino acid sequence of PinX1 via hydrophilic and hydrophobic interactions. Significantly, either disrupting this interaction by mutating the critical Leu-291 residue in PinX1 or knocking down endogenous TRF1 by RNAi abolishes the ability of PinX1 to localize to telomeres and to inhibit telomere elongation in cells even though neither has any effect on telomerase activity per se. Thus, the telomerase inhibitor PinX1 is recruited to telomeres by TRF1 and provides a critical link between TRF1 and telomerase inhibition to prevent telomere elongation and help maintain telomere homeostasis.     

A human helper T cell clone secreting both killer helper factor(s) and T cell-replacing factor(s)

A human helper T cell clone (d4), which showed its helper effect on the differentiation of both T and B cells, was established by MLC reaction of normal T cells against a B lymphoblastoid cell line (CESS) followed by cloning in the presence of IL2 and x-irradiated CESS and autologous non-T cells. d4 cells helped the induction of cytotoxic T cells against UV-treated CESS cells. Antigen-stimulated d4 cells secreted helper factor(s) involved in the induction of cytotoxic T cells (killer helper factor(s), KHF), and KHF activity could be separated into two fractions, one with the m.w. of 15,000 to 20,000 and the other with the m.w. of 45,000 to 50,000. The factor with 15,000 to 20,000 m.w. showed IL 2 activity; the other factor showed gamma-interferon activity without IL 2 activity, suggesting that both IL 2 and gamma-interferon exerted KHF activity. d4 cells or their culture supernatant showed helper activity in the induction of IgG in a B cell line (CESS). The helper activity of the supernatant (TRF) was absorbed with CESS cells but not with IL 2-dependent CTLL, whereas KHF activity was absorbed with IL 2-dependent CTLL but not with CESS cells. The results showed that TRF and KHF were distinct molecules and a single helper T cell clone could secrete helper factors for both B and T cells.     

Induction of proliferation and Ig production in human B leukemic cells by anti-immunoglobulins and T cell factors

The proliferation and differentiation of human leukemic B cells (B-CLL cells) with anti-Ig and T cell-derived helper factors are described. Stimulation of B-CLL cells with anti-Ig and T helper factors could induce proliferation as well as differentiation into IgM- and IgG-producing cells. Neither anti-Ig nor T helper factors alone could induce any proliferation and/or differentiation of B-CLL cells. Not only whole molecules of anti-Ig but also F(ab')2 fragments could induce proliferation and differentiation of B-CLL cells in the presence of T helper factors, but monovalent Fab' fragments were not effective. Induction of both IgM and IgG with the same idiotype was confirmed by immunofluorescent and SDS-PAGE analysis. By employing an IL 2-dependent cytotoxic T cell line and a TRF-responsive B cell line, T cell factors were separated into a fraction with IL2 activity but no TRF activity and a fraction with TRF activity but no IL 2 activity by chromatofocusing. Anti-Ig and IL 2 fraction could induce proliferation of B-CLL cells, but TRF fraction was not effective for the induction of proliferation in anti-IG-stimulated cells. For IgM and IgG production, anti-Ig and both IL 2 and TRF fractions were required. Depletion of IL 2 fraction in the first 2 days' culture inhibited Ig production, whereas the absence of TRF fraction in the first 2 days did not show any inhibitory effect on Ig production.     

An examination of the TRF assay reveals a heterogeneity of TRF-like activities

Supernatant from the cloned Mlsa,d-reactive helper T cell line L2V is a potent source of T cell replacing factor (TRF) activity. To determine whether L2V SF was representative of TRF-active supernatants, it was compared with supernatant from Con A-stimulated spleen cells (CASF) by using TRF assays. This analysis, facilitated by the use of four different antigens (R36a, TNP-R36a, SRBC, and HRBC), produced the following results. 1) L2V SF and CASF allowed responses of similar magnitude against either R36a or TNP-R36a; however, CASF always allowed responses of fivefold to 30-fold greater magnitude against SRBC than L2V SF. 2) B cells from xid and "normal" mice will give equally large responses to TNP-R36a when CASF is used as the source of TRF; however, L2V SF will only effect the responses by "normal" B cells. 3) L2V SF-driven responses to R36a and SRBC, and CASF-driven responses to R36a, follow single-hit kinetics and are IL 2 independent, whereas CASF-driven responses to SRBC follow multi-hit kinetics and are IL 2 dependent. These results indicate that the TRF assay measures a heterogeneity of TRF-like activities that can be distinguished according to the supernatant, antigen, and/or B cell responders used. The determination of whether this heterogeneity is due to the number of molecular components of a single "type" of TRF required for each antigen-induced PFC response or to the existence of distinct "types" of TRF is examined.