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Molecular and Cellular Biology, July 2002, p. 5173-5181, Vol. 22, No. 14
0270-7306/02/$04.00+0     DOI: 10.1128/MCB.22.14.5173-5181.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

Generation of Mice Deficient for Macrophage Galactose- and N-Acetylgalactosamine-Specific Lectin: Limited Role in Lymphoid and Erythroid Homeostasis and Evidence for Multiple Lectins

Molecular Biology Section, Division of Biology,¹ Cancer Center,² Howard Hughes Medical Institute,³ Department of Cellular and Molecular Medicine,⁴ Department of Medicine,⁶ Glycobiology Research and Training Center, University of California, San Diego, La Jolla, California 92093,⁷ Laboratory of Cancer Biology, University of Tokyo, Tokyo 113-8657, Japan⁵

Received 21 March 2002/ Accepted 2 April 2002

	ABSTRACT

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Macrophage receptors function in pattern recognition for the induction of innate immunity, in cellular communication to mediate the regulation of adaptive immune responses, and in the clearance of some glycosylated cells or glycoproteins from the circulation. They also function in homeostasis by initiating the engulfment of apoptotic cells. Evidence has suggested that macrophage receptors function to recognize cells that are destined for programmed cell death but not yet overtly apoptotic. We have examined the function of a macrophage receptor specific for unsialylated glycoproteins, known as the mouse macrophage galactose- and N-acetylgalactosamine-specific lectin (mMGL) (Ii et al., J. Biol. Chem. 265:11295-11298, 1990; Sato et al., J. Biochem. [Tokyo] 111:331-336, 1992; Yamamoto et al., Biochemistry 33:8159-8166, 1994). With targeted disruption, we tested whether mMGL is necessary for macrophage function, controlled thymic development, the loss of activated CD8 T cells, and the turnover of red blood cells. Evidence indicates that mMGL may play a nonessential role in several of these macrophage functions. Experiments are presented that indicate the existence of another galactose- and N-acetylgalactosamine-recognizing lectin distinct from mMGL. This may explain the absence of a strong phenotype in mMGL-deficient mice.

	INTRODUCTION

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Differential sialylation is a general property of hematopoietic cell development, including lymphocytes and erythrocytes. For example, at a distinct stage in thymic development, several abundant cell surface glycoproteins, such as CD8, CD43, and CD45, are undersialylated, thus exposing terminal O-linked Galß1-3GalNAc, a ligand for the lectin peanut agglutinin (PNA). T-cell precursors migrate to the thymus as PNA^lo CD4^- CD8^- (double negative [DN]) cells (24, 38) and make the transition to PNA^hi cortical CD4⁺ CD8⁺ (double positive [DP]) cells (5, 18, 19, 25-27). Upon differentiation, the DP thymocytes progress to CD4 or CD8 lineage cells, migrate to the medulla, and once again become PNA^lo.

The extent of terminal Galß1-3GalNAc exposure inversely correlates with the expression of ST3Gal-I, a Galß1-3GalNAc-specific 2,3 sialyltransferase that is expressed primarily in medullary but not cortical thymocytes (3, 10). Upon expression of ST3Gal-I, Galß1-3GalNAc becomes sialylated, preventing PNA binding on these cells (23). Additionally, T cells become increasingly sialylated on N-linked Galß1-4GlcNAc as they transit from DP to single-positive (SP) cells (36). This latter sialylation is thought to involve multiple sialyltransferases (7, 35).

Naive PNA^lo T cells once again become PNA^hi upon mitogen- or antigen-mediated activation (8, 30). Effector T cells reveal terminal Galß1-3GalNAc, possibly through the action of endogenous sialidases (8). The deletion of ST3Gal-I causes all T cells to remain PNA positive and thus undersialylated on several O-linked glycoproteins. The phenotypic effect of an ST3Gal-I deficiency was a loss of CD8 T cells in the peripheral lymphoid organs via apoptosis (23). The conclusion from these studies was that regulated sialylation plays a role in the homeostatic maintenance of CD8 T cells.

Mouse macrophage galactose- and N-acetylgalactosamine-specific C-type lectin (mMGL) is a macrophage-specific, calcium-dependent C-type lectin whose carbohydrate recognition domain has been shown to have high affinity for glycoproteins bearing terminal galactose (Gal) and N-acetylgalactosamine (GalNAc) sugars (39). This lectin is also known as the macrophage asialoglycoprotein-binding protein by the group that cloned the gene from the rat (12). mMGL binding is inhibited by sialylation (39). It is expressed on a subpopulation of macrophages present in most tissues (20), and it has been implicated in macrophage tumoricidal ability, phagocytosis, and endocytosis (11, 15). mMGL expression is also upregulated during cardiac allograft rejection (28). Currently, the physiological role of mMGL remains uncertain.

Based on the expression of mMGL in the thymus and peripheral lymphoid organs and the existence of cells bearing potential ligands for this terminal Gal/GalNAc-specific lectin, we examined the role of mMGL-bearing cells in the regulation and turnover of lymphocytes during development and activation. In this report we describe the generation of mice that are deficient for mMGL. An analysis of these mice revealed that the loss of mMGL did not affect lymphoid differentiation or immune function. Further, red blood cell turnover and life span are minimally affected. We also show that mMGL is not the only Gal/GalNAc-specific lectin expressed by mouse macrophages, and its inhibition does not substantially complement the ST3Gal-I deficiency. We conclude from these studies that mMGL plays a role in T-cell and erythrocyte homeostasis but that there are other macrophage lectins with redundant or overlapping functions.

	MATERIALS AND METHODS

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Flow cytometry. Cells were labeled with the following monoclonal antibodies and reagents: anti-CD4-phycoerythrin (PE), anti-CD8-TC (CalTag), anti-CD5-fluorescein isothiocyanate (FITC), anti-CD3-FITC, anti-heat-stable antigen-biotin, anti-CD44-PE, anti-CD25-biotin or -FITC, anti-CD62L-PE (all from Pharmingen), PNA-FITC, and Erythrina cristigalli agglutinin-biotin (Sigma Chemical Co., St. Louis, Mo.). Apoptotic cells were detected with annexin V-FITC (CalTag), or terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick-end labeling (Boehringer Mannheim). Samples were analyzed with a FACSCAN or FACSCalibur (Becton Dickinson) and CellQuest software.

Genomic mapping and knockout construct. Exons 2 and 3 encoding the translational start site, cytoplasmic domain, and the transmembrane domain of mMGL were mapped from genomic clones isolated from a strain 129SvJ library (Stratagene, La Jolla, Calif.). The probe used was a mouse full-length mMGL cDNA isolated from a subtractive hybridization experiment and identified by sequence as previously published (3). These exons were replaced with the pPGKneobpA cassette (32), resulting in a targeting construct consisting of a 1.5-kb and a 4-kb arm to mediate homologous recombination. The construct was transfected into R1 embryonic stem (ES) cells (129 strain), and 700 G418-resistant colonies were screened for homologous recombinants. One clone, H1, was identified and injected into C57BL/6 blastocysts. Male mice obviously chimeric by coat color were crossed to C57BL/6J females to obtain F₁ heterozygotes, which were then incrossed to obtain F₂ mice homozygous for the deficient mMGL allele.

Immunohistochemistry. Tissues were collected from mice, frozen in OCT (VWR Scientific), and kept at -70°C until sectioned on a cryostat. Sections were acetone fixed, washed in Tris-buffered saline, and blocked with 2% bovine serum albumin. Biotinylated and unbiotinylated polyacrylamide arrays carrying multiple copies of Galß1-3GalNAc and Gal1-3GalNAc were purchased from Glycotech (Rockville, Md.). Antifreeze glycoprotein (AFGP; Sigma Chemical Company) was biotinylated with a biotinylation kit (Sigma Chemical Company). Rat anti-mouse mMGL monoclonal antibody LOM-14 (13) was prepared as previously described. Biotinylated anti-Mac-1 and FITC-conjugated anti-Mac-1 were purchased from BD Pharmingen.

Sections were incubated with primary reagents at room temperature for at least 1 h, washed, and incubated for 30 min with secondary goat anti-rat alkaline phosphatase (Jackson Immunochemicals). Sections were then developed with alkaline phosphatase substrate and Vector Blue, and nuclei were counterstained with Nuclear Fast Red (Vector Labs, Burlingame, Calif.). Alternatively, primary biotinylated reagents were developed with fluorescently tagged streptavidin or streptavidin-alkaline phosphatase.

Fibroblasts expressing mMGL. Full-length mMGL cDNA was subcloned into pcDNA3 (Invitrogen, Carlsbad, Calif.) and transfected into 3T6 fibroblasts with Polybrene as described before (21). G418-resistant clones were tested for mMGL expression with flow cytometry and Northern analysis. Positive clones were subcloned by limiting dilution. Transfected fibroblasts were seeded into 24-well plates at 10⁵ cells/well overnight.

Peritoneal macrophages. Littermates aged 4 to 8 months were challenged with 1 ml of 3% thioglycollate intraperitoneally, and 4 days later peritoneal cells were isolated by lavage with 10 ml of cold Hanks' balanced salt solution. Cells were washed, counted, and stained for Mac-1. Cells were resuspended in RPMI medium, seeded with 10⁶ Mac-1⁺ cells to form monolayers, and allowed to adhere to wells for 2 to 4 h. Nonadherent cells were vigorously washed with medium.

In vitro coculture. Thymocytes were explanted from C57BL/6 mice and cultured as described above. Thymocytes (4 x 10⁶ to 5 x 10⁶) were added to triplicate wells containing monolayers of macrophages or fibroblasts in 1 ml of medium for 16 to 18 h. After vigorous washing, 0.2 ml from each well was stained, counted, and analyzed by flow cytometry to determine live cell recovery. Recovery was calculated by multiplying the fraction of nonapoptotic cells (annexin V^-) of a specific subset by the total number of cells recovered.

CTL assay. Cytotoxic T lymphocyte (CTL) assays were performed as previously described (23). Briefly, mice were injected with 2 x 10⁶ P815 tumor cells intraperitoneally. On day 10, spleens and mesenteric lymph nodes were isolated from mice, and lymphocytes were counted. Lymphocytes were added to 96-well V-bottomed plates containing ⁵¹Cr-labeled specific target cells (P815) or nonspecific targets (EL-4) at various effector-to-target cell ratios. Cells were incubated for 4 h with targets, and ⁵¹Cr release was measured.

Determination of erythrocyte life span. To determine the life span of erythrocytes, mMGL-deficient mice and control littermates were biotinylated in vivo with N-hydroxysuccinimido-biotin (NHS-biotin) (Sigma, St. Louis, Mo.) as described previously (1). Briefly, NHS-biotin was dissolved in dimethyl sulfoxide (Aldrich, Milwaukee, Wis.) and diluted 1:10 with phosphate-buffered saline (PBS) (Sigma) to a final concentration of 4 mg/ml, and 150 µl of the final solution was injected into the tail vein. The injection was repeated 1 h later. Blood from biotinylated mice was taken at 1-week intervals, and 50 µl of blood was washed with 2 ml of PBS supplemented with 2% fetal calf serum and 1 mM EDTA to remove biotinylated plasma proteins. Triplicate samples containing 15 µl of blood cells were stained with 0.5 µg of streptavidin-PerCP (Pharmingen, San Diego, Calif.) at room temperature for 30 min. The percentage of labeled erythrocytes was determined by flow cytometry, and the disappearance of the cells over time was used to determine the erythrocyte life span for each mouse.

	RESULTS

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Generation of mMGL^-/- mice. To understand the physiological role of mMGL in vivo, we targeted mMGL for germ line deletion in mice. Since mMGL is a type II transmembrane protein, we mapped the N-terminal transmembrane domain and targeted exons 2 and 3 for replacement with a neomycin resistance cassette with the vector pPGKneo (Fig. 1A). Homologous recombinants in ES cells could be identified by a 12-kb HindIII recombinant fragment, compared to a 10.5-kb endogenous fragment when probed with an upstream genomic probe. Of 700 G418-resistant ES clones examined by Southern blot analysis, one clone revealed the expected recombinant allele, and this clone was injected into blastocysts. The resulting chimeric mice passed the deficient allele to the first-generation progeny (Fig. 1B). Homozygous deficient mice were deficient for mMGL by Northern (Fig. 1C) as well as by reverse transcription-PCR analysis (data not shown).

View larger version (25K): [in this window] [in a new window]   FIG. 1. Targeted deletion of mMGL exons 2 and 3 results in mice deficient for mMGL. (A) Genomic mapping of the mMGL amino-terminal cytoplasmic and transmembrane domains revealed a 1.0-kb HindIII fragment encoding exons 2 and 3 which was targeted for deletion with replacement vector pPGKneo (23). (B) Tail DNA from F2 mice digested with HindIII and probed with an upstream genomic probe revealed an endogenous 10.5-kb fragment and the recombinant 12-kb fragment. (C) Northern analysis of mMGL mRNA in mMGL+/- and mMGL-/- mice. GAPDH, glyceraldehyde-3-phosphate dehydrogenase. H, HindIII; S, SacI; R, EcoRI; Bx, BstXI; B, BamHI; N, NotI.

View larger version (153K): [in this window] [in a new window]   FIG. 2. Localized expression of mMGL in mouse tissues. Tissue sections from mMGL+/+ and mMGL-/- mice were stained with rat immunoglobulin (Ig) control or monoclonal anti-mMGL antibodies and compared to Mac-1 staining in each tissue. (A) Cytospin of peritoneal exudate cells. (B) Thymus. Note that cells staining for mMGL in wild-type (WT) mice were seen predominantly in the corticomedullary junction and medulla. (C) Spleen, showing sparse staining of mMGL staining compared to that in skin (D) , lymph node (E) , and lung (F) .

Normal lymphoid development and homeostasis in mMGL^-/- mice. We examined mMGL-deficient mice for lymphoid development. Our initial hypothesis was that medullary mMGL-expressing macrophages might regulate the developmental transition that occurs from the cortical, undersialylated immature thymocytes to medullary, fully sialylated mature T cells. This process can be monitored by analyzing thymocytes stained with PNA to detect O-linked terminal Gal-GalNAc and staining for CD4 and CD8 to detect the major thymic subpopulations (Fig. 3A). Thymocytes were separately stained with E. cristigalli agglutinin, which detects the terminal galactose present on N-linked branched glycoproteins (Fig. 3A). With either of these lectins, we found that undersialylated thymocytes in wild-type mice were mainly CD4⁺ CD8⁺, the population found in the cortex, whereas the sialylated thymocytes were either CD4⁺ CD8^- (CD4SP) or CD4^- CD8⁺ (CD8SP), the mature populations found in the medulla.

View larger version (70K): [in this window] [in a new window]   FIG. 3. mMGL null mice show normal T-cell development and homeostasis. (A) Thymocytes were harvested from C57BL/6 mice and stained with anti-CD4-PE, anti-CD8-TC, and either PNA directly conjugated to FITC (top) or biotinylated E. cristigalli agglutinin (ECA) and streptavidin-FITC (bottom). Cells were gated on PNAhi (left) or PNAlo (right) to indicate populations with terminal O-linked Galß1-3GalNAc or ECAhi (left) or ECAlo (right) to indicate terminal N-linked Galß1-4GlcNAc. (B) Thymocytes from mMGL+/- and mMGL-/- littermates were stained with anti-CD4 and anti-CD8 and analyzed by flow cytometry. (C) CD4SP (top) and CD8SP (bottom) populations were analyzed for PNA binding between mMGL+/+ and mMGL-/- mice. (D) Thymocytes were cocultured for 16 h with mMGL- or mock-transfected 3T6 fibroblasts, and the live cell recovery of different subsets was determined by multiplying cell count by percentage of annexin V staining on gated populations. (E) Thymocytes from C57BL/6 mice were harvested and cocultured with thioglycollate-elicited macrophages from mMGL+/+ and mMGL-/- mice in vitro.

The thymus size of mMGL-deficient mice compared to heterozygous littermates seemed slightly increased in mice aged 8 to 16 weeks (9.8 [±4.5] x 10⁷ cells, n = 27 [-/-] versus 8.4 [±3.6] x 10⁷ cells, n = 33 [+/+]), but due to the variability within each group, this difference was not statistically significant (P > 0.05, Student's t test, unpaired). B-cell expression of B220 was similar among wild-type and mMGL null mice, and B-cell proliferation to anti-immunoglobulin M and lipopolysaccharide in vitro was normal (data not shown). We conclude from these data that T-cell development is grossly unaltered and that expression of mMGL is not required for normal T- or B-cell development.

We also studied the function of mMGL with respect to the induction of apoptosis in Gal/GalNAc-exposed CD4⁺ CD8⁺ thymocytes. In the first set of experiments, we showed that fibroblasts transfected with mMGL would result in cell loss of CD4⁺ CD8⁺ (cortical) but not CD4SP or CD8SP (medullary) thymocytes (Fig. 3D).We then sought to determine whether elicited peritoneal macrophages would mediate the loss of thymocytes in an mMGL-dependent manner. Measuring cell recovery, viability, and apoptotic indices, we found that macrophages do have a substantial effect on the recovery of thymocytes, but after extensive investigation, including numerous separate trials, we did not find a significant difference between macrophages from wild-type and mMGL-deficient mice (data not shown). Thus, despite the ability of mMGL transfectants to mediate thymocyte cell death in vitro and the demonstrated large amounts of mMGL on peritoneal macrophages (Fig. 2A), there was no indication that mMGL expression was required for thymocyte cell death.

mMGL-deficient mice were also tested for T-cell responses by measuring the cytotoxic T-cell response to major histocompatibility-disparate tumor cells. P815 tumor cells were injected intraperitoneally into mMGL^+/+ and mMGL^-/- mice. On day 10 of the response, CTL specific lysis was measured ex vivo along with the expansion of CD8 T cells. The cytotoxic T-cell responses of mMGL^+/+ and mMGL^-/- mice were similar (Fig. 4A). Similar expansion of CD8 T cells was also observed (Fig. 4B). Both mMGL^+/+ and mMGL^-/- T cells exhibited the expression of activation markers, becoming CD44^hi, CD62L^lo, and PNA^hi (data not shown). In addition, we measured the proportion of apoptotic T cells as measured by annexin V during the time course of a T-cell response in vivo and again found no significant differences in mice lacking mMGL on day 10 (Fig. 4C), day 12, or day 17 (data not shown). These results indicate that CD8 T-cell responses do not rely on mMGL for activation, effector function, or turnover of activated T cells.

View larger version (25K): [in this window] [in a new window]   FIG. 4. Allogeneic cytotoxic T-cell response in mMGL+/+ and mMGL-/- mice. (A) P815 targets were cultured with lymphocytes from the spleen, and CTL lysis was determined. mMGL-deficient mice showed cytolytic activity similar to that in the wild type. (B) Expansion of CD8 T cells after the in vivo response was similar between mMGL+/+ and mMGL-/- mice. (C) Percentage of annexin V+ CD8 T cells was similar between mMGL+/+ and mMGL-/- mice.

View larger version (19K): [in this window] [in a new window]   FIG. 5. Erythrocyte (RBC) turnover in mMGL+/+ and mMGL-/- mice. Mean life span of red blood cells was determined in (A) mMGL+/+ and (B) mMGL-/- mice after biotinylation in vivo. The mean erythrocyte life span was 36.67 days in mMGL+/+ mice, versus 37.27 days in mMGL-/- mice.

Mice were crossed to produce ST3Gal-I^+/- controls and either ST3Gal-I^-/- mMGL^+/- or ST3Gal-I^-/- mMGL^-/- littermates (Fig. 6). The number of CD8 T cells was enumerated in the peripheral blood at 3 to 6 weeks of age. In addition, the data were segregated for males and females. As shown in Fig. 6, there were approximately 11% CD8 T cells at all ages in ST3Gal-I^+/- mice, whereas the percentage of CD8 T cells in ST3Gal-I^-/- mice varied between 1 and 5%. The absence of mMGL did not complement the level of CD8 T cells to wild-type levels, but there was a trend toward increased T-cell numbers at all ages in double null mice. The difference between ST3Gal-I^-/- mMGL^+/- and ST3Gal-I^-/- mMGL^-/- in females reached statistical significance at weeks 3 and 5 (P < 0.05 and P < 0.01, respectively). However, we conclude that mMGL minimally mediates the loss of CD8 T cells in ST3Gal-I^-/- mice. Either the loss of CD8 T cells in ST3Gal-I^-/- mice occurs by a different mechanism entirely, or there is another endogenous galactose-specific lectin that is functionally redundant with mMGL in this regard.

View larger version (31K): [in this window] [in a new window]   FIG. 6. Effect of mMGL deficiency in ST3Gal-I-deficient mice. ST3Gal-I mice were crossed to mMGL-deficient mice to examine the role of mMGL in the CD8 T-cell loss in ST3Gal-I-deficient mice. Solid squares represent ST3Gal-I+/- mice, which show normal CD8 T-cell numbers in the peripheral blood lymphocytes (PBL). Solid circles represent ST3Gal-I-/- mMGL+/- mice, which show decreased numbers of CD8 T cells. Open circles show doubly deficient mice. (Top) Female doubly deficient mice show a trend of increased CD8 T-cell numbers compared to ST3Gal-I-deficient mice, reaching statistical significance in female mice aged 3 and 5 weeks. (Bottom) Male mice showed no statistically significant changes.

View larger version (79K): [in this window] [in a new window]   FIG. 7. Identification of Gal/GalNAc-specific lectin(s) distinct from mMGL. (A) Sialic acid (SA) binding alone. (B) Galß1-3GalNAc-PAA. (C to E) Serial sections were probed with (C) Galß1-3GalNAc-PAA, (D) Galß1-3GalNAc-PAA plus Galß1-3GalNAc, and (E) Gal1-3GalNAc plus Gal1-3GalNAc.

View larger version (61K): [in this window] [in a new window]   FIG. 8. Gal/GalNAc-specific lectin(s) is macrophage restricted. (A) Splenic sections from mMGL-/- mice were probed with biotinylated Galß1-3GalNAc-PAA or anti-Mac-1 antibodies. Localized binding of the Galß1-3GalNAc-PAA probe was observed in the splenic red pulp, and this correlated with Mac-1 staining. (B) Double staining of splenic sections from mMGL-deficient mice with Galß1-3GalNAc-PAA and Mac-1 revealed colocalization of the lectin to a Mac-1+ cell. Galß1-3GalNAc-PAA binding was always seen on Mac-1 binding cells but not the converse, suggesting that the lectin(s) is expressed on a subpopulation of macrophages or mature dendritic cells.

	DISCUSSION

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The development and selection of thymocytes are accompanied by a high rate of cell death, so that an estimated 98% of the thymocytes produced in the thymus die prior to emigration (31). The physiological mechanisms responsible for thymocyte cell death are almost entirely uncharacterized (37). Several receptor-ligand interactions have been proposed to participate in thymocyte death (6, 16, 17, 22), but there are few examples of targeted deletions that result in thymus hyperplasia (33). Despite the many studies on the topic, there is yet no real conceptual understanding of the signaling mechanisms that distinguish positive and negative selection of developing thymocytes. As such, we wanted to study the possibility that differential sialylation during thymus development could be recognized by an endogenous lectin as a way of regulating the emergence of mature T cells. From this and previous studies, we conclude that neither the deletion of ST3Gal-I nor the deletion of mMGL appears to have a substantial effect on T-cell development (23).

The observation that activated T cells lose sialylation and following expansion show significant apoptosis prompted us to consider the possibility that an endogenous lectin could induce death based on cross-linking of undersialylated molecules. This mechanism would be consistent with the loss of CD8 T cells in ST3Gal-I-deficient mice and the delay in death of antigen-specific effector CD8 T cells in CD43^-/- mice (Onami et al., unpublished data). We saw no differences in CD8 T cell numbers for mMGL^+/+ versus mMGL^-/- mice following activation in vivo and similar numbers of apoptotic CD8 T cells in these mice as well. To determine whether an mMGL gene inhibition could complement the targeted ST3Gal-I deficiency in the loss of CD8 T cells, we produced mice deficient in both genes. As shown, although there appeared to be a tendency toward higher numbers of CD8 T cells in the mice lacking mMGL, mMGL^-/- ST3Gal-I^-/- mice still showed a profound CD8 T-cell deficiency. Therefore, we conclude that mMGL cross-linking of undersialylated cell surface molecules is not the predominant mechanism of cell loss in ST3Gal-I^-/- mice.

In addition to lymphocytes, erythrocytes undergo differential sialylation. Experiments show that sialic acids are lost as erythrocytes undergo senescence (2, 4, 14). The role of sialic acids in erythrocyte senescence is not understood, but one possibility is that it constitutes one of the signals that target aged erythrocytes for destruction (9). We considered the possibility that mMGL-bearing macrophages could recognize the undersialylated erythrocytes and execute their engulfment. There does appear to be a difference in erythrocyte numbers in mMGL mice (Table 1), but the biological significance is difficult to discern. We did not find a statistically significant difference in turnover rates, leading us to believe that the increases seen in erythrocytes in mMGL^-/- mice may be explained by other indirect effects. Moreover, mMGL expression is not abundant in the spleen and liver, where erythrocyte turnover takes place after desialylation.

With AFGP as a probe, we identified an additional macrophage lectin(s) or lectin-like activity that is specific for Galß1-3GalNAc but independent of mMGL. Binding of this lectin to its ligand is not affected by EDTA, suggesting that binding is not calcium dependent, and thus it is not a C-type lectin. In future studies, this lectin can be characterized further by purifying galactose-specific binding proteins with cell lysates derived from mMGL null mice. We propose that this lectin may play a functionally redundant role to mMGL and conclude from our studies that mMGL expression is not required for normal lymphoid homeostasis.

	ACKNOWLEDGMENTS

 
This work was supported by Public Health Service grants RO1AI37988 (S.M.H.) and PO1HL57345 (A.V.) from the National Institutes of Health and the Howard Hughes Medical Institute (J.D.M.).

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Biology, University of California, San Diego, La Jolla, CA 92093-0687. Phone: (858) 534-6269. Fax: (858) 534-5611. E-mail: shedrick{at}ucsd.edu.

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