CD5 Is Dissociated from the B-Cell Receptor in B Cells from Bovine Leukemia Virus-Infected, Persistently Lymphocytotic Cattle: Consequences to B-Cell Receptor-Mediated Apoptosis

doi:10.1128/JVI.75.4.1689-1696.2001

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Journal of Virology, February 2001, p. 1689-1696, Vol. 75, No. 4
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.4.1689-1696.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

CD5 Is Dissociated from the B-Cell Receptor in B Cells from Bovine Leukemia Virus-Infected, Persistently Lymphocytotic Cattle: Consequences to B-Cell Receptor-Mediated Apoptosis

Glenn H. Cantor,¹^,^* Suzanne M. Pritchard,¹ Franck Dequiedt,²^, Luc Willems,² Richard Kettmann,² and William C. Davis¹

Department of Veterinary Microbiology and Pathology, Washington State University, Pullman, Washington 99164-7040,¹ and Department of Applied Biochemistry and Biology, Molecular Biology and Animal Physiology Unit, Faculty of Agronomy, B-5030 Gembloux, Belgium²

Received 11 July 2000/Accepted 21 November 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Bovine leukemia virus (BLV), a retrovirus related to human T-cell leukemia virus types 1 and 2, can induce persistent nonneoplasticexpansion of the CD5⁺ B-cell population, termed persistent lymphocytosis (PL). As inhuman CD5⁺ B cells, we report here that CD5 was physically associated withthe B-cell receptor (BCR) in normal bovine CD5⁺ B cells. In contrast, in CD5⁺ B cells from BLV-infected PL cattle, CD5 was dissociated fromthe BCR. In B cells from PL cattle, apoptosis decreased when cellswere stimulated with antibody to surface immunoglobulin M (sIgM),while in B cells from uninfected cattle, apoptosis increased aftersIgM stimulation. The functional significance of the CD5-BCR associationwas suggested by experimental dissociation of the CD5-BCR interactionby cross-linking of CD5. This caused CD5⁺ B cells from uninfected animals to decrease apoptosis when stimulatedwith anti-sIgM. In contrast, in CD5⁺ B cells from PL animals, in which CD5 was already dissociatedfrom the BCR, there was no statistically significant change inapoptosis when CD5 was cross-linked and the cells were stimulatedwith anti-sIgM. Disruption of CD5-BCR interactions and subsequentdecreased apoptosis and increased survival in antigenically stimulatedB cells may be a mechanism of BLV-inducedPL.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Bovine leukemia virus (BLV), a member of the human T-cell leukemia virus (HTLV)-BLV group of retroviruses, causes persistentlymphocytosis (PL), a polyclonal increase in peripheral bloodB-lymphocyte numbers, in approximately 30% of infected cattle(14, 20). PL is a strong risk factor for development of lymphomaand/or leukemia, and 1 to 5% of PL animals eventually developneoplasia (14). Theoretically, either increased cell proliferationor decreased cell death can cause PL. B cells from BLV-infectedsheep and cattle may have a higher proliferation rate (18, 25,38). A decreased rate of apoptosis and therefore increased celllongevity may also contribute to PL (11, 12, 32, 33).There is an overall increase in apoptosis in ex vivo-culturedperipheral blood mononuclear cells (PBMCs) from PL cows, but infectedcells that express viral proteins are less prone to undergo spontaneousapoptosis than are cells from the same animals that do not expressviral proteins (11). Additionally, supernatants from culturesof PL PBMCs have antiapoptotic properties and delay apoptosiswhen added to uninfected cell cultures (11). These results suggestthat increased cell longevity due to delayed apoptosis may bemechanism of PL, particularly in more densely packed environmentssuch as lymph nodes, even if delayed apoptosis is not seen inex vivo cells from peripheralblood.

Several concurrent mechanisms may result in BLV-induced cell proliferation or delayed apoptosis. The Tax protein is one criticalfactor in BLV-induced cell proliferation and neoplasia (42,43). BLV and HTLV Tax activate the viral long terminal repeatpromoter, and HTLV-1 Tax is also known to activate many cellularpromoters, including those for interleukin-2 (IL-2), IL-2 receptoralpha, granulocyte-macrophage colony-stimulating factor, c-Fos,and vimentin (16). Several mechanisms have been investigated.Tax facilitates dimerization of CREB transcription factors andbinding to Tax-responsive elements in promoters (1, 44) andactivates NF- $kappa$ B (4). Polymorphisms in major histocompatibilitycomplex (MHC) class II alleles also play a major role in progressionto PL (45).

An additional, potentially concurrent mechanism for BLV-induced B-cell expansion may be direct interactions of viral proteinswith cellular signaling pathways originating at the cell membrane.Interaction with the phosphatase SHP-1 may be one such mechanism.In normal human and mouse B cells, SHP-1 associates with CD22(13) and CD32b (Fc $gamma$ RIIB) (8) and acts as a critical negativeregulator of the B-cell receptor (BCR) (8, 13). We previouslyshowed that in bovine B cells, SHP-1 physically associates withthe BLV transmembrane protein gp30 and suggested that this interactionmay sequester SHP-1 and make the BCR hyperresponsive to antigenicsignaling (6).

CD5 is one notable cell membrane protein in PL B cells. As in humans and mice, bovine CD5 is present in most T cells but onlya small number of normal, uninfected B cells. In BLV-infectedPL cattle, however, nearly all of the B cells are CD5⁺ (10). In human and mouse T cells, CD5 physically associateswith CD2 (27, 34) and T-cell receptor components, includingCD3 zeta chain (5, 26), and transduces signals to Lck (31),SHP-1 (7), and phosphatidylcholine-specific phospholipase C(35) that can modify T-cell receptor signaling. In human B cells,CD5 associates with the BCR (22). In mouse B cells, the interactionof CD5 with mouse BCR downregulates BCR-mediated signaling toundergo proliferation and to increase cell survival by delayedapoptosis (3).

Here, we show that the association of CD5 with the BCR differs in CD5⁺ B cells from normal, uninfected cattle and those from BLV-infectedPL cattle. CD5 and BCR were associated in cells from normal animalsand not associated in PL animals. BCR stimulation of B cells fromPL animals resulted in decreased apoptosis, while stimulationof B cells from uninfected animals increased apoptosis. When CD5and BCR from uninfected bovine CD5⁺ B cells were experimentally dissociated to simulate conditionsin PL cells, the uninfected cells showed decreased apoptosis afterBCR stimulation. This suggests that the dissociation of CD5 andBCR in the PL B cells is functionally significant and is a mechanismthat contributes to increased longevity and PL in B cells fromBLV-infectedanimals.

	MATERIALS AND METHODS

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Animals and cells. Naturally infected adult Holstein-Friesian cows were BLV seropositive by enzyme-linked immunosorbent assay and persistentlylymphocytotic based on three consecutive monthly lymphocyte countsabove 8,800 lymphocytes/µl (40). The animals were negative forbovine immunodeficiency virus, based on PCR and serology. Negativecontrol cows from the same herd were BLV seronegative. To determinehow closely the animals were related, the sire, dam, and grandparentsof each animal were determined. For two animals, ancestry couldnot be determined. Uninfected animals 1937 and 1830 are half-sisters.None of the other animals had common parents orgrandparents.

PBMCs from peripheral blood were purified by gradient centrifugation through Lymphoprep cell separation medium (specific gravity,1.077 g/ml) (Nycomed, Inc.) (37). B cells were enriched by depletionof T cells. PBMCs (1.5 × 10⁸ in RPMI 1640 with 10% fetal bovine serum [FBS], 100 µM streptomycin,and 100 µU penicillin) were incubated with mouse monoclonal antibodies(MAbs) to bovine CD3 (MM1A; immunoglobulin G1 [IgG1]; 160 µg),CD4 (ILA11A; IgG2a; 160 µg), and CD8 (CACT80C; IgG1; 40 µg) andan MAb to the $delta$ chain of bovine $gamma$ $delta$ T cells (GB21A; IgG2b; 40 µg).After rotating incubation for 30 min at 4°C, cells were washedtwice and incubated with 2 ml of anti-mouse IgG Magna Beads (Pierce,Rockford, Ill.) for 30 min at 4°C. T cells were removed by threerounds of magnetic depletion, 5 min per application, at 4°C. Insome experiments, MAbs to CD2 (B26A; IgM), CD8 (BAQ111A; IgM),CD4 (GC50A; IgM), and the $delta$ chain of $gamma$ $delta$ T cells (CACT148A; IgM)were used. In these experiments, T cells were depleted by complementlysis, as previously described (39). T-cell depletion was verifiedby flow cytometric (FC) analysis. In the coimmunoprecipitationexperiments, T cells from uninfected animals were reduced to 10%or less of the cell population, and T cells from PL animals werereduced to 1% or less. In the experiments using BCR stimulationto reduce apoptosis, T cells from uninfected animals constituted2% or less and T cells from PL animals constituted 0.2% or lessof the cellpopulation.

Antibodies. Mouse MAbs were anti-bovine CD5, CACT105A (IgG1), MUC1A (IgG1), and B29A (IgG2a); anti-bovine IgM, 1H4 (IgG1) (23) and PIG45A2(IgG2b); anti-CD79a (synonyms, Ig- $alpha$ and mb-1), HM57 (IgG1) (Dako)(24); anti-SHP-1 (IgG1) (Transduction Laboratories, Lexington,Ky.); anti-Escherichia coli (negative control MAbs) ColiS69A (IgG1)and ColiS169A (IgG2a); anti-chicken MHC class-II-like (negativecontrol MAb) AV64A (IgG1); and the T-cell depletion MAbs as above.With the exception of 1H4, HM57, and anti-SHP-1, antibodies werefrom the Washington State University Monoclonal AntibodyCenter.

Coimmunoprecipitations. Surface labeling of cells with biotin and coimmunoprecipitations were performed as previously described (6). In some experiments,1% digitonin was substituted for 1% Brij 96 in the lysisbuffer.

FC. FC analyses were performed on a Becton Dickinson FACScan flow cytometer. Data were analyzed with Cellquest software (BectonDickinson Immunocytometry, San Jose, Calif.) (11). Debris wasexcluded from analyses by scatter gating. In some analyses, CD5⁺ cells or surface IgM⁺ (sIgM⁺) cells were gated, and apoptotic analyses were restricted tothe gatedpopulation.

Apoptosis assays. Cells were cultured for 16 h in RPMI 1640 medium with 10% FBS, 100 µM streptomycin, and 100 µU penicillin. Cells were labeledusing MAbs to surface proteins at 15 µg/ml for 30 min at 4°C andwith fluorescein isothiocyanate or phycoerythrin-conjugated isotype-specificsecondary antibodies, followed by apoptosis assays. Apoptoticcells were identified using the terminal deoxynucleotidyltransferase-mediateddUTP-biotin nick end labeling (TUNEL) method, as described previously(11), or propidium iodide staining. Propidium iodide stainingwas performed after surface labeling for FC. Cells were suspendedin 70% ethyl alcohol overnight at $-$ 20°C, washed, permeabilizedin 0.1% Triton X-100-0.1% mM EDTA-50 µg of RNase A per ml in phosphate-bufferedsaline (PBS) for 30 min at 37°C and stained with propidium iodide(20 µg/ml), followed immediately by FC analysis. Cells with lessthan the 2N amount of DNA were classified as apoptotic, whilecells with more than 2N were classified as proliferative. In theinitial assays, results were verified by DNA ladder assay (11).

CD5 cross-linking. CD5 molecules were cross-linked to dissociate from the BCR as described by Bikah et al., using biotinylated MAb to CD5 (CACT105A)and avidin (group I) (3). Controls were incubated with biotinylatedMAb to CD5 without avidin (group II) or with biotinylated isotypecontrol MAb ColiS69 and avidin (group III). MAbs were dialyzedovernight in 50 mM sodium bicarbonate buffer (pH 8.5) at 4°C,incubated for 2 h on ice with Sulfo-NHS-LC-Biotin (Pierce) at0.045 µg of biotin per µg of MAb, and dialyzed again to removeunbound biotin. Biotinylation was quantitated by the 4-hydroxyazobenzene-2-carboxylicacid (Sigma, St. Louis, Mo.)-avidin reaction (15), and reactivitywith CD5⁺ cells was confirmed by FC analysis. Cells (6 × 10⁶ per group) were centrifuged and resuspended in 400 µl of RPMIwith 10% FBS at 4°C as above. Biotinylated MAb to CD5 or biotinylatedisotype control MAb was added (50 µg/ml) and incubated for 30min at 4°C while rotating. Cells were washed twice in RPMI-10%FBS. The biotinylated MAb-bound CD5 molecules were cross-linkedwith NutrAvidin, a deglycosylated form of avidin (Pierce), 100µg per group, for 20 min at 4°C while rotating and washed twice.Following CD5 cross-linking, cells were incubated at 37°C for30 min and then stimulated using anti-IgM MAb 1H4 at 6 µg/ml and37°C in 5% CO₂ for 16 h. One control group (IV) was incubatedwith biotinylated MAb to CD5 and avidin but cultured for 16 hwithout anti-IgM MAb. To gate on the CD5⁺ cells, cells were labeled with anti-CD5 MAb B29A (IgG2a) or withisotype control MAb ColiS169A, followed by phycoerythrin-conjugatedanti-mouse IgG2a, 1:150.

Statistical analyses. We used 95% confidence intervals to determine if means were significantly different from zero. To assess change in apoptosisafter BCR stimulation, the percent change in cells from PL versusuninfected animals was compared using Student's t test if datawere normally distributed and the Mann-Whitney rank sum test ifdata were not normally distributed. In the CD5 cross-linking experiments,data were compared by analysis of variance (ANOVA) and Fisher'sleast significant difference (LSD) method. Significance was determinedat P < 0.05.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

CD5 is physically associated with the BCR in B cells from normal cattle but not in B cells from BLV-infected PL animals. CD5 was shown previously to coimmunoprecipitate with BCR from normal human CD5⁺ B cells (22). Consistent with these results, we found thatCD5 coimmunoprecipitated with CD79a (the Ig-alpha component ofthe BCR complex) of B cells from uninfected cattle (Fig. 1A).First, T-cell-depleted, biotin-labeled B cells in 1% digitoninlysis buffer (6) were immunoprecipitated using MAb to CD79a,a tightly linked BCR component, or isotype control MAb. To identifyCD5 that was physically associated with CD79a, the precipitateswere resolubilized in higher stringency 1% NP-40 lysis bufferand immunoprecipitated a second time (6) with either the CD5MAb MUC1A or isotype control MAb. As a control, single immunoprecipitationwas performed with MAb to CD5.

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FIG. 1. (A) CD5 coimmunoprecipitates with the BCR in uninfected animals. B cells were enriched from PBMCs by T-cell depletion. Lanes 1 to 3, biotin-labeled cells in 1% digitonin lysis buffer were immunoprecipitated (IP) with either MAb to CD79a (the Ig-alpha component of the BCR) or isotype control MAb AV64A. Precipitates were resuspended in 1% NP-40 lysis buffer, and a second immunoprecipitation was performed using MAb to CD5 (MUCIA) or isotype control MAb. As a control, CD5 was immunoprecipitated directly from the PBMC NP-40 lysate using MAb to CD5 (lane 4). (B) CD5 does not coimmunoprecipitate with BCR from BLV-infected PL animals. Methods and design were as in panel A. Despite the presence of a higher proportion of B cells in the PBMCs from the PL animal, CD5 did not coimmunoprecipitate with the BCR (lane 5), although it was seen in coimmunoprecipitations from an uninfected animal (lane 1). A light background band which migrates faster than CD5 is present in lanes 5 to 7. The position of CD5 in the single immunoprecipitation (lane 8) and the predicted position of CD5 in the double immunoprecipitation (lane 5) from PL cells are indicated with asterisks.

In contrast, in B cells from BLV-infected PL animals, CD5 did not coimmunoprecipitate with CD79a (Fig. 1B). In PL cell immunoprecipitations,a faster-migrating background band (60 kDa) was seen in all lanes(lanes 5 to 7) regardless of the primary antibody, but the slightlylarger CD5 protein (63 kDa), shown in the single immunoprecipitationcontrol lanes 4 and 8 and in the uninfected-cell coimmunoprecipitation(lane 1), is not seen in association with CD79a from PL cells(lane 5). Even overexposure of the film failed to show a distinctCD5 band in lane 5 compared with control lanes 6 and 7 (data notshown). The identity of the slower-migrating background band (70kDa) seen in all lanes, including those from cells of uninfectedand PL animals, is not known, but it may be Ig heavy chain thatattached to the protien G beads in the immunoprecipitations. Theexperiment was repeated with two other PL and normal animals,and results were similar (data notshown).

BCR stimulation delays apoptosis in PL B cells but increases apoptosis in uninfected B cells. To determine the effect of antigenic stimulation of the BCR on apoptosis of B cells from PL and uninfected animals, ex vivoPBMCs and B-cell-enriched cell cultures were cultured for 16 hwith or without MAb to IgM (1H4; IgG1) to stimulate the BCR. Apoptoticcells were identified using two different methods, TUNEL (Fig.2A and B) and propidium iodide (Fig. 2B), and B cells were identifiedand gated using anti-IgM MAb PIG45A2 (IgG2b).

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FIG. 2. Apoptosis decreases in BCR-stimulated PL B cells but not in B cells from uninfected animals. The percentage of B cells undergoing apoptosis, as determined by TUNEL analysis, is shown, together with the percent change in apoptosis. Ex vivo PBMCs or B-cell-enriched cell cultures were incubated for 16 h with or without MAb to IgM (1H4; IgG1). Apoptosis was detected using TUNEL (A and B) or propidium iodide staining (B). During FC analyses, B cells were gated for analysis using MAb PIG45A2 (IgG2b) to IgM at 4°C. FC analyses from representative experiments are shown, and the experiments are summarized. In TUNEL analyses, the number of apoptotic cells is defined as the sum of cells in the upper right and left quadrants (A). Significant differences (Student's t test or Mann-Whitney test) are indicated by superscript letters. Means that are significantly different are indicated by different letters, while means that are not statistically different are indicated by the same letter. In panel B, results with TUNEL are compared with those using propidium iodide. The 95% CI are shown. Results with cells from PL animals are significantly different than those with cells from uninfected animals, but are not significantly different based on the technique used to detect apoptosis.

When apoptosis in PBMC cultures from the PL animals was analyzed by TUNEL, BCR stimulation reduced apoptotic cells from 55.0%of the B-cell population to 41.3%, which represents a 26.0% decrease(mean for four animals). Results were similar in TUNEL-stainedB-cell-enriched cell cultures (27.1% decrease) (Fig. 2A). In Fig.2A, FC analysis from one experiment with one PL and one uninfectedanimal is illustrated as a dot plot, and data for each of theanimals aresummarized.

In contrast, in B cells from the uninfected animals, BCR stimulation increased apoptosis. B-cell apoptosis increased 23.5%in PBMCs (mean for three animals) and 8.9% in B cell-enrichedcultures (mean for six animals), as determined by TUNEL (Fig.2A).

Regardless of whether apoptosis was detected by TUNEL or propidium iodide, similar changes were seen (Fig. 2B). When the changein apoptosis of PL cells was compared to that of uninfected cells,the difference was statistically significant in both PBMCs andB-cell enriched cultures and in both TUNEL and propidium iodideexperiments (P < 0.05).

To determine if BCR stimulation also altered B-cell proliferation, the percentage of proliferating cells with more than 2NDNA content was also determined in the propidium iodide-stainedcells. No significant differences were detected between the PLand uninfected cells or between unstimulated and BCR-stimulatedcells (data notshown).

BCR stimulation delays apoptosis in uninfected B cells when CD5 is cross-linked. Observations that CD5 was dissociated from the BCR in PL cattle, BCR-mediated signaling in cells from PL cattle resulted indecreased apoptosis, and data from mice suggesting that CD5 downregulatesBCR signaling (3, 34) made us ask if the dissociation ofCD5 from the BCR in the PL cells might account for their decreasedapoptosis and increased survival in response to BCR stimulation(Fig. 3A).

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FIG. 3. (A) Proposed model and predictions. In B cells from uninfected animals, CD5 is associated with the BCR and downregulates BCR signaling when the BCR is triggered by antigen (indicated by a solid circle). In PL animals, CD5 is dissociated from the BCR and does not downregulate the BCR. The model predicts that in PL animals, in the absence of downregulation by CD5, antigen-triggered BCR signaling will result in decreased apoptosis and increased B-cell longevity. In B cells from uninfected animals, CD5 downregulates antigen-triggered BCR signaling, and apoptosis increases. The model predicts that in B cells from uninfected animals, experimental separation of CD5 from BCR will decrease apoptosis mediated by antigen binding in the same way that apoptosis is decreased in the antigen-triggered PL B cells in which CD5 is already dissociated from the BCR. (B) Cross-linking of CD5 followed by BCR stimulation inhibits apoptosis in CD5⁺ B cells of uninfected animals. (C) No statistically significant inhibition of apoptosis is seen in CD5⁺ B cells from PL animals when CD5 is cross-linked followed by BCR stimulation. The percentage of apoptotic cells in each group was compared with group III (non-cross-linked cells stimulated with MAb to BCR) to determine the percent change. Means and 95% CI are shown; significant differences are indicated by superscript letters. In each figure, means that are significantly different are indicated by different letters, while means that are not statistically different are indicated by the same letter.

To experimentally test this possibility, CD5 was dissociated from the BCR by cross-linking (3). After T-cell depletion,cells were incubated with biotinylated MAb to CD5 (CACT105A) orwith biotinylated isotype control MAb, followed by incubationwith avidin to cross-link the CD5. The BCR was stimulated withMAb to IgM (1H4), as above (Fig. 3A). Analysis was restrictedto CD5⁺ cells by gating on cells that reacted with CD5 MAb B29A (IgG2a),and apoptosis was evaluated by TUNEL. The percentage of cellsin apoptosis is shown in Fig. 3B and C. To facilitate comparisonsamong experiments performed at different times, data were alsonormalized to control group III (biotinylated isotype controlMAb, avidin, and MAb to IgM). The percentage of change relativeto group III is shown in Fig. 3B andC.

If the observed dissociation of CD5 from the BCR in PL cells causes the BCR-induced decreased apoptosis, we predicted thatexperimental dissociation of CD5 from the BCR in cells from uninfectedanimals should likewise decrease BCR-induced apoptosis (Fig. 3A).In B cells from uninfected animals, which previously showed anincrease in apoptosis when the BCR was stimulated (Fig. 2A andB), there was a decrease in apoptosis when the CD5-cross-linkedcells were BCR stimulated (Fig. 3B). The mean decrease in apoptosiswas 21.47% (95% confidence interval [CI], ±5.64%) (group I) comparedwith the cells incubated with biotinylated isotype control antibody(group III). To evaluate the possibility that the effect couldbe due to antibody stimulation of CD5, control group II consistedof cells treated with biotinylated antibody to CD5 but no cross-linkingavidin, followed by BCR stimulation. In control group II, in whichcells were treated with anti-CD5 without cross-linking, therewas only a 3.63% inhibition of apoptosis (95% CI, ±3.60%). Asa control for the effects of CD5 cross-linking alone without BCRstimulation (group IV), there was an 11.09% increase in apoptosis,not significantly different from zero (95% CI, ±16.06%). Whengroups were compared by ANOVA followed by Pearson's LSD method,group I was significantly different from control groups II andIV.

If experimentally induced CD5-BCR dissociation results in decreased apoptosis in uninfected, BCR-stimulated B cells, and ifCD5 and BCR are already dissociated in B cells from PL animals,then we predicted that CD5 cross-linking should have little orno effect on the B cells from PL animals. CD5 cross-linking followedby stimulation with MAb to the BCR resulted in only a 9.47% meandecrease in apoptosis (group I) compared with the cells incubatedwith biotinylated negative control antibody (group III) (Fig.3C). This decrease was not significantly different from zero (95%CI, ±9.93%). In control group II, there was a 0.48% increase inapoptosis (95% CI, ±4.71%), not significantly different from zero.Consistent with the results in Fig. 2A and B, apoptosis was increasedin control group IV, in which cells from PL animals were not treatedwith antibody to the BCR. When the groups were compared by ANOVAfollowed by Pearson's LSD method, groups I and II were not significantlydifferent and group IV was different from groupIII.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

This study is consistent with and extends observations that CD5 normally functions as a downregulatory modulator of the BCR(3, 9). Here, we identify a naturally occurring diseasein which CD5 is dissociated from the BCR and experimentally testthe functional importance of this dissociation in delaying apoptosis.CD5⁺ B cells from uninfected animals were experimentally induced tobehave like the CD5⁺ B cells from PL animals by dissociation of CD5 and BCR. Indeed,the functional significance of this effect is suggested by thesimilarity between the magnitude of the effect on uninfected cellsof CD5 cross-linking followed by BCR stimulation (mean 21.5% decreasein apoptosis) and the magnitude of the decreased apoptosis inPL cells when they are BCR stimulated (mean 26.9% decrease inapoptosis). Although the magnitude of these apoptotic changesis relatively small in vitro, the biological significance couldbe much greater. The experiments were performed using culturedcells during a short time, but since PL takes months to yearsto develop after initial infection, small differences in apoptoticrates can be considerably amplified in vivo (2).

It is important to differentiate the effects of CD5 cross-linking followed by BCR stimulation from potential effects of antibody-mediatedCD5 stimulation alone. In some studies, stimulation of CD5 byantibodies led to increased signaling and cellular responses (17,19, 21). It was recently shown that ligation of both CD5 andIgM resulted in increased apoptosis in human tonsillar B cells(28). Here, the possible effect of antibody-mediated CD5 stimulationwas controlled by incubating group II with MAb to CD5 but no avidinand then stimulating with MAb to the BCR. A small effect was seen(3.63% decrease in apoptosis; 95% CI, 3.60%) in cells from uninfectedanimals, but this effect was much less than the effect of CD5cross-linking (21.47% decrease in apoptosis; 95% CI, 5.64%). Itmay also be asked if cross-linking of CD5 alone (i.e., aggregationof the CD5 molecules) without BCR-CD5 dissociation could be responsiblefor the delayed apoptosis seen here. This is unlikely, becausecross-linking of CD5 without BCR stimulation of uninfected cellsinstead leads to an increase in apoptosis (group IV; Fig. 3B andC). The mechanisms of the CD5-BCR dissociation in cells from PLanimals remain unknown. Physical associations, either direct orindirect, between viral proteins and either CD5 or BCR may disruptCD5-BCR interactions. One such interaction may involve the BLVtransmembrane (TM) protein gp30, CD5, and SHP-1. CD5 physicallyassociates with SHP-1 in human T cells (27) and mouse B-1 Bcells (34), and we found similar results in bovine CD5⁺ B cells (unpublished data). We previously showed that BLV TMis physically associated with SHP-1 (6), and a competitionbetween BLV TM, SHP-1, and CD5 may be envisioned that resultsin dissociation of CD5 and BCR. However, interactions with viralproteins cannot fully explain the dissociation of CD5 and BCR,since not all infected cells express viral proteins. We previouslyshowed that only 15 to 20% of PBMCs from PL cattle express viralp24 even after 24 h of culture (11). This experiment was donewith PBMCs rather than B cells and with expression of p24 ratherthan TM. However, if viral proteins are only expressed in a smallpercentage of infected cells, then physical associations betweenviral proteins and CD5, BCR, or associated proteins such as SHP-1do not fully explain the CD5-BCR dissociation in ex vivo PL Bcells. Correlation of viral load and the percentage of infectedcells with apoptotic rates in future experiments may be of assistancein resolving thisissue.

Alternatively, the CD5-BCR dissociation may be due to altered cytokines or cellular environment or other changes in cellularsignaling components. PL B cells produce increased amounts ofIL-2 and IL-10 mRNA, increased IL-2 activity, and decreased amountsof IL-12 mRNA (29, 30, 41), and it is possible that thisaltered cytokine environment may trigger changes in CD5 or BCRinteractions. Changes in levels of other B-cell surface receptors,including IL-2 receptor alpha and class II MHC, may also be involved(36).

A third alternative is that the CD5⁺ B cells of PL cattle may represent a different lineage or different developmental stagethan CD5⁺ B cells of uninfected cattle. A diversity of CD5⁺ B cells are recognized in other species, including cells in whichCD5 expression is either constitutive or induced (46). AlthoughCD5⁺ B cells from the uninfected and PL cattle both express CD5, theremay be enough other phenotypic differences that only the celltype from the uninfected animals has an association between CD5and theBCR.

A puzzling conundrum of both HTLV and BLV infection is that only a subset of infected animals develop lymphocyte proliferation.The data here suggest a model to explain this. Delayed apoptosismay be a property of those PL cells that are antigenically stimulatedvia the BCR. Since PL is a polyclonal condition, virus-expressingcells are a broad array of B cells that are specific for manydifferent antigens. A variety of antigens, then, may trigger delayedapoptosis in those B cells in which the downregulatory CD5 isdissociated from BCR. There may be some threshold of appropriateantigenic triggering of the BCR that results in decreased apoptosisand development of PL in some but not all animals at various timesafter BLVinfection.

The advantage of BLV as an animal model for the closely related HTLV viruses and also for the nonviral human neoplastic diseasechronic lymphocytic leukemia is that results from ex vivo or invitro studies can be experimentally tested in vivo by infectionof animals with altered infectious molecular clones of BLV. Determinationof mechanisms of the disruption of CD5-BCR interactions and mappingof amino acids responsible for this disruption will allow testingof the significance of these observations in sheep orcattle.

	ACKNOWLEDGMENTS

We thank D. Hoover, V. Hamilton, I. Eriks, K. Mealey, G. Palmer, D. Stone, T. Besser, and A. Burny for valuable discussions;J. Evermann for serologic analyses; E. Wagner (University of Idaho)for excellent animal care; and Hao Zhang for statisticalconsultation.

Grant support is from NIH K08 AI01198, USDA 94-37204-1253, American Cancer Society IRG 1190, ACS B-72451, FB Assurances (Fortis),Services de Programmation pour la politique scientifique (SSTC-P4/30),International Union Against Cancer Postdoctoral Fellowship, andthe Belgian National Fund for Scientific Research. R.K. and L.W.are Research Directors and F.D. is a Senior Research Assistantof the Belgian National Fund for ScientificResearch.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Veterinary Microbiology and Pathology, Washington State University, Pullman,WA 99164-7040. Phone: (509) 335-6042. Fax: (509) 335-8529. E-mail:gcantor{at}vetmed.wsu.edu.

Present address: J. David Gladstone Institute of Virology and Immunology, University of California-San Francisco, San Francisco,CA94141.

REFERENCES

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Adam, E., P. Kerkhofs, M. Mammerickx, R. Kettmann, A. Burny, L. Droogmans, and L. Willems. 1994. Involvement of the cyclic AMP-responsive element binding protein in bovine leukemia virus expression in vivo. J. Virol. 68:5845-5853[Abstract/Free Full Text].

2. Berman, J. J., and G. W. Moore. 1992. The role of cell death in the growth of preneoplastic lesions: a Monte Carlo simulation model. Cell Prolif. 25:549-557[Medline].

3. Bikah, G., J. Carey, J. R. Ciallella, A. Tarakhovsky, and S. Bondada. 1996. CD5-mediated negative regulation of antigen receptor-induced growth signals in B-1 B cells. Science 274:1906-1909[Abstract/Free Full Text].

4. Brooks, P. A., G. L. Cockerell, and J. K. Nyborg. 1998. Activation of BLV transcription by NF- $kappa$ B and Tax. Virology 243:94-98[CrossRef][Medline].

5. Burgess, K. E., M. Yamamoto, K. V. S. Prasad, and C. E. Rudd. 1992. CD5 acts as a tyrosine kinase substrate within a receptor complex comprising T-cell receptor zeta chain/CD3 and protein-tyrosine kinases p56^lck and p59^fyn. Proc. Natl. Acad. Sci. USA 89:9311-9315[Abstract/Free Full Text].

6. Cantor, G. H., S. M. Pritchard, O. Orlik, G. A. Splitter, W. C. Davis, and R. Reeves. 1999. Bovine leukemia virus transmembrane protein gp30 physically associates with the down-regulatory phosphatase SHP-1. Cell. Immunol. 193:117-124[CrossRef][Medline].

7. Carmo, A. M., D. W. Mason, and A. D. Beyers. 1993. Physical association of the cytoplasmic domain of CD2 with the tyrosine kinases p56^lck and p59^fyn. Eur. J. Immunol. 23:2196-2201[Medline].

8. D'Ambrosio, D., K. L. Hippen, S. A. Minskoff, I. Mellman, G. Pani, K. A. Siminovitch, and J. C. Cambier. 1995. Recruitment and activation of PTP1C in negative regulation of antigen receptor signaling by Fc $gamma$ RIIB1. Science 268:293-297[Abstract/Free Full Text].

9. Dennehy, K. M., R. Broszeit, W. F. Ferris, and A. D. Beyers. 1998. Thymocyte activation induces the association of the proto-oncoprotein c-Cbl and Ras GTPase-activating protein with CD5. Eur. J. Immunol. 28:1617-1625[CrossRef][Medline].

10. Depelchin, A., J. J. Letesson, N. Lostrie-Trussart, M. Mammerickx, D. Portetelle, and A. Burny. 1989. Bovine leukemia virus (BLV)-infected B-cells express a marker similar to the CD5 T cell marker. Immunol. Lett. 20:69-76[CrossRef][Medline].

11. Dequiedt, F., G. H. Cantor, V. T. Hamilton, S. M. Pritchard, W. C. Davis, P. Kerkhofs, A. Burny, R. Kettmann, and L. Willems. 1999. Bovine leukemia virus-induced persistent lymphocytosis in cattle does not correlate with increased ex vivo survival of B lymphocytes. J. Virol. 73:1127-1137[Abstract/Free Full Text].

12. Dequiedt, F., E. Hanon, P. Kerkhofs, P.-P. Pastoret, D. Portetelle, A. Burny, R. Kettmann, and L. Willems. 1997. Both wild-type and strongly attenuated bovine leukemia viruses protect peripheral blood mononuclear cells from apoptosis. J. Virol. 71:630-639[Abstract].

13. Doody, G. M., L. B. Justement, C. C. Delibrias, R. J. Matthews, J. Lin, M. L. Thomas, and D. T. Fearon. 1995. A role in B cell activation for CD22 and the protein tyrosine phosphatase SHP. Science 269:242-244[Abstract/Free Full Text].

14. Ferrer, J. F., R. R. Marshak, D. A. Abt, and S. J. Kenyon. 1979. Relationship between lymphosarcoma and persistent lymphocytosis in cattle: a review. J. Am. Vet. Med. Assoc. 175:705-708[Medline].

15. Green, N. M. 1970. Spectrophotometric determination of avidin and biotin. Methods Enzymol. 18A:418-424.

16. Green, P. L., and I. S. Y. Chen. 1994. Molecular features of the human T-cell leukemia virus: mechanisms of transformation and leukemogenicity, p. 277-311. In J. A. Levy (ed.), The Retroviridae, vol. 3. Plenum, New York, N.Y.

17. Gringhuis, S. I., L. F. M. H. de Leij, P. J. Coffer, and E. Vellenga. 1998. Signaling through CD5 activates a pathway involving phosphatidylinositol 3-kinase, Vav, and Rac1 in human mature T lymphocytes. Mol. Cell. Biol. 18:1725-1735[Abstract/Free Full Text].

18. Hailata, N., R. Johnson, F. Al-Bagdadi, and S. Hanash. 1995. Proliferating cell nuclear antigen expression in sheep infected with bovine leukemia virus. Vet. Immunol. Immunopathol. 44:211-222[CrossRef][Medline].

19. Imboden, J. B., C. H. June, M. A. McCutcheon, and J. A. Ledbetter. 1990. Stimulation of CD5 enhances signal transduction by the T cell antigen receptor. J. Clin. Investig. 85:130-134.

20. International Committee on Bovine Leukosis. 1968. Criteria for the determination of the normal and leukotic state in cattle. JNCI 41:243-263.

21. Jamin, C., R. Le Corre, P. M. Lydyard, and P. Youinou. 1996. Anti-CD5 extends the proliferative response of human CD5+ B cells activated with anti-IgM and interleukin-2. Eur. J. Immunol. 26:57[Medline].

22. Lankester, A. C., G. M. W. van Schijndel, J. L. Cordell, C. J. M. van Noesel, and R. A. W. van Lier. 1994. CD5 is associated with the human B cell antigen receptor complex. Eur. J. Immunol. 24:812-816[Medline].

23. Letesson, J. J., N. Lostrie-Trussart, and A. Depelchin. 1985. Production d'anticorps monoclonaux spécifiques d'isotypes d'immunoglobulines bovines. Ann. Med. Vet. 129:131-141.

24. Mason, D. Y., J. L. Cordell, A. G. D. Tse, J. J. M. Van Dongen, C. J. M. van Noesel, K. Micklem, K. A. F. Pulford, F. Valensi, W. M. Comans-Bitter, J. Borst, and K. C. Gatter. 1991. The IgM-associated protein mb-1 as a marker of normal and neoplastic B cells. J. Immunol. 147:2474-2482.

25. Matheise, J. P., M. Delcommenne, A. Mager, C. H. Didembourg, and J. J. Letesson. 1992. CD5⁺ B cells from bovine leukemia virus infected cows are activated cycling cells responsive to interleukin 2. Leukemia 6:304-309[Medline].

26. Osman, N., A. I. Lazarovits, and M. J. Crumpton. 1993. Physical association of CD5 and the T cell receptor/CD3 antigen complex on the surface of human T lymphocytes. Eur. J. Immunol. 23:1173-1176[Medline].

27. Perez-Villar, J. J., G. S. Whitney, M. A. Bowen, D. H. Hewgill, A. A. Aruffo, and S. B. Kanner. 1999. CD5 negatively regulates the T-cell antigen receptor signal transduction pathway: involvement of SH2-containing phosphotyrosine phosphatase SHP-1. Mol. Cell. Biol. 19:2903-2912[Abstract/Free Full Text].

28. Pers, J. O., C. Jamin, R. Le Corre, P. M. Lydyard, and P. Youinou. 1998. Ligation of CD5 on resting B cells, but not on resting T cells, results in apoptosis. Eur. J. Immunol. 28:4170-4176[CrossRef][Medline].

29. Pyeon, D., K. L. O'Reilly, and G. A. Splitter. 1996. Increased interleukin-10 mRNA expression in tumor-bearing or persistently lymphocytotic animals infected with bovine leukemia virus. J. Virol. 70:5706-5710[Abstract/Free Full Text].

30. Pyeon, D., and G. A. Splitter. 1998. Interleukin-12 p40 mRNA expression in bovine leukemia virus-infected animals: increase in alymphocytosis but decrease in persistent lymphocytosis. J. Virol. 72:6917-6921[Abstract/Free Full Text].

31. Raab, M., M. Yamamoto, and C. E. Rudd. 1994. The T-cell antigen CD5 acts as a receptor and substrate for the protein-tyrosine kinase p56^lck. Mol. Cell. Biol. 14:2862-2870[Abstract/Free Full Text].

32. Reyes, R. A., and G. L. Cockerell. 1998. Increased ratio of bcl-2/bax expression is associated with bovine leukemia virus-induced leukemogenesis in cattle. Virology 242:184-192[CrossRef][Medline].

33. Schwartz-Cornil, I., N. Chevallier, C. Belloc, D. Le Rhun, V. Lainé, M. Berthelemy, A. Mateo, and D. Levy. 1997. Bovine leukaemia virus-induced lymphocytosis in sheep is associated with reduction of spontaneous B cell apoptosis. J. Gen. Virol. 78:153-162[Abstract].

34. Sen, G., G. Bikah, C. Venkataraman, and S. Bondada. 1999. Negative regulation of antigen receptor-mediated signaling by constitutive asociation of CD5 with the SHP-1 protein tyrosine phosphatase in B-1 B cells. Eur. J. Immunol. 29:3319-3328[CrossRef][Medline].

35. Simarro, M., J. Calvo, J. M. Vila, L. Places, O. Padilla, J. Alberola-Ila, J. Vives, and F. Lozano. 1999. Signaling through CD5 involves acidic sphingomyelinase, protein kinase C-zeta, mitogen-activated protein kinase kinase, and c-Jun NH₂-terminal kinase. J. Immunol. 162:5149-5155[Abstract/Free Full Text].

36. Stone, D. M., A. J. Hof, and W. C. Davis. 1995. Up-regulation of IL-2 receptor $alpha$ and MHC class II expression on lymphocyte subpopulations from bovine leukemia virus infected lymphocytotic cows. Vet. Immunol. Immunopathol. 48:65-76[CrossRef][Medline].

37. Stone, D. M., T. F. McElwain, and W. C. Davis. 1994. Enhanced B-lymphocyte expression of IL-2R $alpha$ associated with T lymphocytosis in BLV-infected persistently lymphocytotic cows. Leukemia 8:1057-1061[Medline].

38. Stone, D. M., L. K. Norton, and W. C. Davis. 1997. Modulation of bovine leukemia virus-associated spontaneous lymphocyte proliferation by monoclonal antibodies to lymphocyte surface molecules. Clin. Immunol. Immunopathol. 83:156-164[CrossRef][Medline].

39. Stone, D. M., L. K. Norton, N. S. Magnuson, and W. C. Davis. 1996. Elevated pim-1 and c-myc proto-oncogene induction in B lymphocytes from BLV-infected cows with persistent B lymphocytosis. Leukemia 10:1629-1638[Medline].

40. Thurmond, M. C., R. L. Carter, J. P. Picanso, and K. Stralka. 1990. Upper-normal prediction limits of lymphocyte counts for cattle not infected with bovine leukemia virus. Am. J. Vet. Res. 51:466-470[Medline].

41. Trueblood, E. S., W. C. Brown, G. H. Palmer, W. C. Davis, D. M. Stone, and T. F. McElwain. 1998. B-lymphocyte proliferation during bovine leukemia virus-induced persistent lymphocytosis is enhanced by T-lymphocyte-derived interleukin-2. J. Virol. 72:3169-3177[Abstract/Free Full Text].

42. Willems, L., C. Grimonpont, H. Heremans, N. Rebeyrotte, G. Chen, D. Portetelle, A. Burny, and R. Kettmann. 1992. Mutations in the bovine leukemia virus Tax protein can abrogate the long terminal repeat-directed transactivating activity without concomitant loss of transforming potential. Proc. Natl. Acad. Sci. USA 89:3957-3961[Abstract/Free Full Text].

43. Willems, L., H. Heremans, G. Chen, D. Portetelle, A. Billiau, A. Burny, and R. Kettmann. 1990. Cooperation between bovine leukaemia virus transactivator protein and Ha-ras oncogene product in cellular transformation. EMBO J. 9:1577-1581[Medline].

44. Willems, L., R. Kettmann, G. Chen, D. Portetelle, A. Burny, and D. Derse. 1992. A cyclic AMP-responsive DNA-binding protein (CREB2) is a cellular transactivator of the bovine leukemia virus long terminal repeat. J. Virol. 66:766-772[Abstract/Free Full Text].

45. Xu, A., M. J. T. Van Eijk, C. Park, and H. A. Lewin. 1993. Polymorphism in BoLA-DRB3 exon 2 correlates with resistance to persistent lymphocytosis caused by bovine leukemia virus. J. Immunol. 151:6977-6985[Abstract].

46. Youinou, P., C. Jamin, and P. M. Lydyard. 1999. CD5 expression in human B-cell populations. Immunol. Today 20:312-316[CrossRef][Medline].

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1.	Adam, E., P. Kerkhofs, M. Mammerickx, R. Kettmann, A. Burny, L. Droogmans, and L. Willems. 1994. Involvement of the cyclic AMP-responsive element binding protein in bovine leukemia virus expression in vivo. J. Virol. 68:5845-5853[Abstract/Free Full Text].
2.	Berman, J. J., and G. W. Moore. 1992. The role of cell death in the growth of preneoplastic lesions: a Monte Carlo simulation model. Cell Prolif. 25:549-557[Medline].
3.	Bikah, G., J. Carey, J. R. Ciallella, A. Tarakhovsky, and S. Bondada. 1996. CD5-mediated negative regulation of antigen receptor-induced growth signals in B-1 B cells. Science 274:1906-1909[Abstract/Free Full Text].
4.	Brooks, P. A., G. L. Cockerell, and J. K. Nyborg. 1998. Activation of BLV transcription by NF- $kappa$ B and Tax. Virology 243:94-98[CrossRef][Medline].
5.	Burgess, K. E., M. Yamamoto, K. V. S. Prasad, and C. E. Rudd. 1992. CD5 acts as a tyrosine kinase substrate within a receptor complex comprising T-cell receptor zeta chain/CD3 and protein-tyrosine kinases p56^lck and p59^fyn. Proc. Natl. Acad. Sci. USA 89:9311-9315[Abstract/Free Full Text].
6.	Cantor, G. H., S. M. Pritchard, O. Orlik, G. A. Splitter, W. C. Davis, and R. Reeves. 1999. Bovine leukemia virus transmembrane protein gp30 physically associates with the down-regulatory phosphatase SHP-1. Cell. Immunol. 193:117-124[CrossRef][Medline].
7.	Carmo, A. M., D. W. Mason, and A. D. Beyers. 1993. Physical association of the cytoplasmic domain of CD2 with the tyrosine kinases p56^lck and p59^fyn. Eur. J. Immunol. 23:2196-2201[Medline].
8.	D'Ambrosio, D., K. L. Hippen, S. A. Minskoff, I. Mellman, G. Pani, K. A. Siminovitch, and J. C. Cambier. 1995. Recruitment and activation of PTP1C in negative regulation of antigen receptor signaling by Fc $gamma$ RIIB1. Science 268:293-297[Abstract/Free Full Text].
9.	Dennehy, K. M., R. Broszeit, W. F. Ferris, and A. D. Beyers. 1998. Thymocyte activation induces the association of the proto-oncoprotein c-Cbl and Ras GTPase-activating protein with CD5. Eur. J. Immunol. 28:1617-1625[CrossRef][Medline].
10.	Depelchin, A., J. J. Letesson, N. Lostrie-Trussart, M. Mammerickx, D. Portetelle, and A. Burny. 1989. Bovine leukemia virus (BLV)-infected B-cells express a marker similar to the CD5 T cell marker. Immunol. Lett. 20:69-76[CrossRef][Medline].
11.	Dequiedt, F., G. H. Cantor, V. T. Hamilton, S. M. Pritchard, W. C. Davis, P. Kerkhofs, A. Burny, R. Kettmann, and L. Willems. 1999. Bovine leukemia virus-induced persistent lymphocytosis in cattle does not correlate with increased ex vivo survival of B lymphocytes. J. Virol. 73:1127-1137[Abstract/Free Full Text].
12.	Dequiedt, F., E. Hanon, P. Kerkhofs, P.-P. Pastoret, D. Portetelle, A. Burny, R. Kettmann, and L. Willems. 1997. Both wild-type and strongly attenuated bovine leukemia viruses protect peripheral blood mononuclear cells from apoptosis. J. Virol. 71:630-639[Abstract].
13.	Doody, G. M., L. B. Justement, C. C. Delibrias, R. J. Matthews, J. Lin, M. L. Thomas, and D. T. Fearon. 1995. A role in B cell activation for CD22 and the protein tyrosine phosphatase SHP. Science 269:242-244[Abstract/Free Full Text].
14.	Ferrer, J. F., R. R. Marshak, D. A. Abt, and S. J. Kenyon. 1979. Relationship between lymphosarcoma and persistent lymphocytosis in cattle: a review. J. Am. Vet. Med. Assoc. 175:705-708[Medline].
15.	Green, N. M. 1970. Spectrophotometric determination of avidin and biotin. Methods Enzymol. 18A:418-424.
16.	Green, P. L., and I. S. Y. Chen. 1994. Molecular features of the human T-cell leukemia virus: mechanisms of transformation and leukemogenicity, p. 277-311. In J. A. Levy (ed.), The Retroviridae, vol. 3. Plenum, New York, N.Y.
17.	Gringhuis, S. I., L. F. M. H. de Leij, P. J. Coffer, and E. Vellenga. 1998. Signaling through CD5 activates a pathway involving phosphatidylinositol 3-kinase, Vav, and Rac1 in human mature T lymphocytes. Mol. Cell. Biol. 18:1725-1735[Abstract/Free Full Text].
18.	Hailata, N., R. Johnson, F. Al-Bagdadi, and S. Hanash. 1995. Proliferating cell nuclear antigen expression in sheep infected with bovine leukemia virus. Vet. Immunol. Immunopathol. 44:211-222[CrossRef][Medline].
19.	Imboden, J. B., C. H. June, M. A. McCutcheon, and J. A. Ledbetter. 1990. Stimulation of CD5 enhances signal transduction by the T cell antigen receptor. J. Clin. Investig. 85:130-134.
20.	International Committee on Bovine Leukosis. 1968. Criteria for the determination of the normal and leukotic state in cattle. JNCI 41:243-263.
21.	Jamin, C., R. Le Corre, P. M. Lydyard, and P. Youinou. 1996. Anti-CD5 extends the proliferative response of human CD5+ B cells activated with anti-IgM and interleukin-2. Eur. J. Immunol. 26:57[Medline].
22.	Lankester, A. C., G. M. W. van Schijndel, J. L. Cordell, C. J. M. van Noesel, and R. A. W. van Lier. 1994. CD5 is associated with the human B cell antigen receptor complex. Eur. J. Immunol. 24:812-816[Medline].
23.	Letesson, J. J., N. Lostrie-Trussart, and A. Depelchin. 1985. Production d'anticorps monoclonaux spécifiques d'isotypes d'immunoglobulines bovines. Ann. Med. Vet. 129:131-141.
24.	Mason, D. Y., J. L. Cordell, A. G. D. Tse, J. J. M. Van Dongen, C. J. M. van Noesel, K. Micklem, K. A. F. Pulford, F. Valensi, W. M. Comans-Bitter, J. Borst, and K. C. Gatter. 1991. The IgM-associated protein mb-1 as a marker of normal and neoplastic B cells. J. Immunol. 147:2474-2482.
25.	Matheise, J. P., M. Delcommenne, A. Mager, C. H. Didembourg, and J. J. Letesson. 1992. CD5⁺ B cells from bovine leukemia virus infected cows are activated cycling cells responsive to interleukin 2. Leukemia 6:304-309[Medline].
26.	Osman, N., A. I. Lazarovits, and M. J. Crumpton. 1993. Physical association of CD5 and the T cell receptor/CD3 antigen complex on the surface of human T lymphocytes. Eur. J. Immunol. 23:1173-1176[Medline].
27.	Perez-Villar, J. J., G. S. Whitney, M. A. Bowen, D. H. Hewgill, A. A. Aruffo, and S. B. Kanner. 1999. CD5 negatively regulates the T-cell antigen receptor signal transduction pathway: involvement of SH2-containing phosphotyrosine phosphatase SHP-1. Mol. Cell. Biol. 19:2903-2912[Abstract/Free Full Text].
28.	Pers, J. O., C. Jamin, R. Le Corre, P. M. Lydyard, and P. Youinou. 1998. Ligation of CD5 on resting B cells, but not on resting T cells, results in apoptosis. Eur. J. Immunol. 28:4170-4176[CrossRef][Medline].
29.	Pyeon, D., K. L. O'Reilly, and G. A. Splitter. 1996. Increased interleukin-10 mRNA expression in tumor-bearing or persistently lymphocytotic animals infected with bovine leukemia virus. J. Virol. 70:5706-5710[Abstract/Free Full Text].
30.	Pyeon, D., and G. A. Splitter. 1998. Interleukin-12 p40 mRNA expression in bovine leukemia virus-infected animals: increase in alymphocytosis but decrease in persistent lymphocytosis. J. Virol. 72:6917-6921[Abstract/Free Full Text].
31.	Raab, M., M. Yamamoto, and C. E. Rudd. 1994. The T-cell antigen CD5 acts as a receptor and substrate for the protein-tyrosine kinase p56^lck. Mol. Cell. Biol. 14:2862-2870[Abstract/Free Full Text].
32.	Reyes, R. A., and G. L. Cockerell. 1998. Increased ratio of bcl-2/bax expression is associated with bovine leukemia virus-induced leukemogenesis in cattle. Virology 242:184-192[CrossRef][Medline].
33.	Schwartz-Cornil, I., N. Chevallier, C. Belloc, D. Le Rhun, V. Lainé, M. Berthelemy, A. Mateo, and D. Levy. 1997. Bovine leukaemia virus-induced lymphocytosis in sheep is associated with reduction of spontaneous B cell apoptosis. J. Gen. Virol. 78:153-162[Abstract].
34.	Sen, G., G. Bikah, C. Venkataraman, and S. Bondada. 1999. Negative regulation of antigen receptor-mediated signaling by constitutive asociation of CD5 with the SHP-1 protein tyrosine phosphatase in B-1 B cells. Eur. J. Immunol. 29:3319-3328[CrossRef][Medline].
35.	Simarro, M., J. Calvo, J. M. Vila, L. Places, O. Padilla, J. Alberola-Ila, J. Vives, and F. Lozano. 1999. Signaling through CD5 involves acidic sphingomyelinase, protein kinase C-zeta, mitogen-activated protein kinase kinase, and c-Jun NH₂-terminal kinase. J. Immunol. 162:5149-5155[Abstract/Free Full Text].
36.	Stone, D. M., A. J. Hof, and W. C. Davis. 1995. Up-regulation of IL-2 receptor $alpha$ and MHC class II expression on lymphocyte subpopulations from bovine leukemia virus infected lymphocytotic cows. Vet. Immunol. Immunopathol. 48:65-76[CrossRef][Medline].
37.	Stone, D. M., T. F. McElwain, and W. C. Davis. 1994. Enhanced B-lymphocyte expression of IL-2R $alpha$ associated with T lymphocytosis in BLV-infected persistently lymphocytotic cows. Leukemia 8:1057-1061[Medline].
38.	Stone, D. M., L. K. Norton, and W. C. Davis. 1997. Modulation of bovine leukemia virus-associated spontaneous lymphocyte proliferation by monoclonal antibodies to lymphocyte surface molecules. Clin. Immunol. Immunopathol. 83:156-164[CrossRef][Medline].
39.	Stone, D. M., L. K. Norton, N. S. Magnuson, and W. C. Davis. 1996. Elevated pim-1 and c-myc proto-oncogene induction in B lymphocytes from BLV-infected cows with persistent B lymphocytosis. Leukemia 10:1629-1638[Medline].
40.	Thurmond, M. C., R. L. Carter, J. P. Picanso, and K. Stralka. 1990. Upper-normal prediction limits of lymphocyte counts for cattle not infected with bovine leukemia virus. Am. J. Vet. Res. 51:466-470[Medline].
41.	Trueblood, E. S., W. C. Brown, G. H. Palmer, W. C. Davis, D. M. Stone, and T. F. McElwain. 1998. B-lymphocyte proliferation during bovine leukemia virus-induced persistent lymphocytosis is enhanced by T-lymphocyte-derived interleukin-2. J. Virol. 72:3169-3177[Abstract/Free Full Text].
42.	Willems, L., C. Grimonpont, H. Heremans, N. Rebeyrotte, G. Chen, D. Portetelle, A. Burny, and R. Kettmann. 1992. Mutations in the bovine leukemia virus Tax protein can abrogate the long terminal repeat-directed transactivating activity without concomitant loss of transforming potential. Proc. Natl. Acad. Sci. USA 89:3957-3961[Abstract/Free Full Text].
43.	Willems, L., H. Heremans, G. Chen, D. Portetelle, A. Billiau, A. Burny, and R. Kettmann. 1990. Cooperation between bovine leukaemia virus transactivator protein and Ha-ras oncogene product in cellular transformation. EMBO J. 9:1577-1581[Medline].
44.	Willems, L., R. Kettmann, G. Chen, D. Portetelle, A. Burny, and D. Derse. 1992. A cyclic AMP-responsive DNA-binding protein (CREB2) is a cellular transactivator of the bovine leukemia virus long terminal repeat. J. Virol. 66:766-772[Abstract/Free Full Text].
45.	Xu, A., M. J. T. Van Eijk, C. Park, and H. A. Lewin. 1993. Polymorphism in BoLA-DRB3 exon 2 correlates with resistance to persistent lymphocytosis caused by bovine leukemia virus. J. Immunol. 151:6977-6985[Abstract].
46.	Youinou, P., C. Jamin, and P. M. Lydyard. 1999. CD5 expression in human B-cell populations. Immunol. Today 20:312-316[CrossRef][Medline].