Roberto L. Ceriani

Characterization of cell surface antigens of human mammary epithelial cells with monoclonal antibodies prepared against human milk fat globule

Hybridomas have been prepared that secrete monoclonal antibodies against three different surface antigens of normal human mammary epithelial cells by fusion of mouse myeloma cells with spleen cells from mice and rats immunized with delipidated human milk fat globules. Using a novel method for molecular weight determination, the three different monoclonal antibodies, BLMRL-HMFG-Mc3, BLMRL-HMFG-McR2, and BLMRLHMFG-Mc5, were found to identify molecules with apparent molecular weights of 46,000, 70,000, and 400,000 daltons, respectively. The latter is a mucin-like glycoprotein with a high sugar content and has not previously been described as a component of the human milk fat globule or of human mammary epithelial cell membranes. Single-cell quantitation of binding of monoclonal BLMRL-HMFG-Mc5 to three breast tumor cell lines using a Microscope Spectrum Analyzer and indirect immunofluorescence revealed a heterogeneous expression. Further, using a competitive radioimmunoassay, it was found that breast tumor cell lines differed by at least 10-fold in the 400,000-molecular-weight antigen content. None of the three antigens are detectable on several nonbreast cell lines, including normal breast fibroblasts.

Milk fat globule glycoproteins in human milk and in gastric aspirates of mother's milk-fed preterm infants.

Human milk fat globule (HMFG) glycoproteins can prevent infections by microorganisms in breast-fed infants; the MUC-1 mucin inhibits binding of S-fimbriated Escherchia coli to buccal mucosa, and lactadherin may prevent symptomatic rotavirus infections. In this study, the survival of these HMFG glycoproteins in the stomach of human milk-fed preterm infants (gestational age = 27.5 ± 0.4 wk) was assessed, and levels in their mothers milk determined, using specific RIAs. Butyrophilin, a major component of HMFG membrane that has no demonstrated antimicrobial activity, was studied for comparison. The levels of mucin, lactadherin, and butyrophilin in 41 milk samples of 20 mothers were 729 ± 75, 93 ± 10, and 41 ± 3 µg/mL, respectively. Mucin and lactadherin were significantly higher in early milk samples (<15 d postpartum) than in later milk samples (15-90 d postpartum), whereas butyrophilin showed no such difference. Significant amounts of mucin and lactadherin were found in almost all gastric aspirates of human milk-fed infants, even 4 h after feeding (mucin, 270 ± 30 µg/mL; lactadherin, 23.2 ± 4.4 µg/mL), whereas butyrophilin was rapidly degraded in the majority of aspirates. Western blot analysis demonstrated that the immunoreactive mucin, lactadherin, and butyrophilin in the milk-fed gastric aspirates had the expected native molecular weights. Mucin and lactadherin survived at all gastric pH values, whereas butyrophilin was found only at pH > 4. Neither lactadherin nor butyrophilin were detected in gastric aspirates of formula-fed infants (gestational age = 27.8 ± 0.5 wk), whereas the very low level of mucin (9.1 ± 1.1 µg/mL) in this group is presumably cross-reacting gastric mucin. These results demonstrate that two HMFG glycoproteins implicated in prevention of infection, MUC-1 mucin and lactadherin, survive and maintain their integrity in the stomachs of human milk-fed preterm infants.

Structural and Functional Aspects of Three Major Glycoproteins of the Human Milk Fat Globule Membrane

The MUC1 mucin, lactadherin, and butyrophilin are 3 major components of the human milk fat globule membrane. The mucin inhibits binding of S-fimbriated Escherichia coli to buccal epithelial cells, and lactadherin prevents symptomatic rotavirus infection in breast-fed infants. Butyrophilin has been suggested to be a structural component of the human milk fat globule (HMFG) membrane and to have receptor functions, but has no known anti-infective activity. These HMFG glycoproteins also are present in skimmed milk, possibly associated with phospholipid micelles, while mucin is also in a soluble form. Mucin and lactadherin resist digestion in the stomach of milk-fed infants, while butyrophilin is rapidly degraded. The MUC1 mucin is an extended rod-like structure forming part of the glycocalyx on the surface of many epithelial cells and membranes of milk, and may act as a decoy for binding of infective agents. The extracellular segment of butyrophilin has homology to Ig superfamily receptors and an intracellular domain with homology to developmentally regulated proteins. Lactadherin is a laterally mobile cell adhesion molecule that interacts with integrins and has a novel means of membrane-association involving specific binding to phosphatidylserine. The structural and functional aspects of these glycoproteins are discussed with regard to their role in human milk for breast-fed infants.

CLONING AND SEQUENCE ANALYSIS OF HUMAN BUTYROPHILIN REVEALS A POTENTIAL RECEPTOR FUNCTION

Human butyrophilin was cloned and sequenced from a human breast cDNA library. The derived amino acid sequence shows 84% sequence identity and identical domain arrangements with the previously reported bovine sequence. Sequence analysis reveals an immunoglobulin constant (IgC) domain that was not previously identified in the bovine sequence. The extracellular domain composition of butyrophilin suggests a cell surface receptor function.

Conjugation of interferon alpha to a humanized monoclonal antibody (HuBrE-3vl) enhances the selective localization and antitumor effects of interferon in breast cancer xenografts

Human mammary carcinoma xenografts (MCF-7) growing in nude mice were treated with natural interferon α (n-IFN-α) alone or conjugated to a humanized monoclonal antibody (MoAb) anti-breast mucin (HuBrE-3vl) or to irrelevant human IgG1κ. The IFN and the conjugates were administered as 20 intra-lesional (i.l.) injections to 1 of 2 xenografts in each mouse, or i.p. The growth inhibitory effects of HuBrE-3vl/nIFN-α were significantly greater than those of nIFN-α used as a single agent or conjugated to HuIgG1κ. These effects occurred locally in the tumors receiving i.l. injections and systemically, although to a slightly lesser extent, in the noninjected tumors of mice treated i.l. and in the xenografts of mice treated i.p. Biodistribution studies showed that the uptake of 125I-HuBrE-3vl/nIFN-α by the tumors 24 hours after i.l. or s.c. injection was greater than that of 125I-HuIgG1κ/nIFN-α,125 I-nIFN-α alone, or by normal tissues, documenting a tumor targeting effect and favorable tumor:normal tissues (T:NT) ratios. The targeting effects and the resulting tumor growth inhibition were favored by the IFN-mediated up-regulation of the HuBrE-3vl reactive antigen, which was more prominent after 3 weeks of treatment with HuBrE-3vl/nIFN-α. These results were superior to those we obtained previously with nIFN-α conjugated to another MoAb of the same group (Mc5). These studies point out the potential usefulness of HuBrE-3vl/nIFN-α for the local and systemic treatment of breast cancer lesions by providing a means of delivering high doses of IFN to the tumors while minimizing the amount of IFN binding to normal tissues.

CHARACTERIZATION OF CELLS CULTURED FROM EARLY LACTATION MILKS

SummaryTwo major types of cells can be cultured from early lactation human milks: a colony-forming epithelial cell and an adherent nondividing cell referred to as a foam cell The epithelial cells show a positive reaction with a specific antiserum reactive against membrane components of the milk fat globule, whereas the foam cells do not. The nondividing foam cells are phagocytic and can be killed by silica particles; they produce lysozyme, are resistant to trypsinization, and have Fc receptors. These properties, together with the lack of reaction with antiserum to the milk fat globule membrane, suggest that the foam cells are not terminally differential epithelial cells, but tissue macrophages.

Quantitation of human mammary epithelial antigens in cells cultured from normal and cancerous breast tissues

SummaryA sensitive radioimmunoassay technique was developed to quantitatite the level of human breast celltype specific antigens on cells from normal breast and from various established cell lines of breast and nonbreast origins. Polyacrylamide gel electrophoresis revealed four major proteinaceous components (150,000; 75,000; 60,000; and 48,000) in human milk fat globule membranes that were used to immunize rabbits in order to elicit antimammary epithelial cell antibody. Antisera obtained were rendered specific by abosorptions and were able to recognize three specific mammary epithelial components of the breast epithelial cell. Human mammary epithelial (HME) antigen expression was highest (1290 ng/106 cells) in normal breast epithelial cells from primary cultures of normal breasts. Lower levels (range: 955 to 330 ng/106 cells) were found in breast epithelial cells from cell lines established from cancerous breast tissue. Cells of nonbreast origins as well as fibroblasts from breast gave much lower values (less than 30 ng/106 cells). On treatment, with trypsin, of two breast epithelial cell lines (MDA-MB-157 and MCF-7) 80 to 85% of their HME antigen expression was lost, suggesting that a majority of these breast antigens reside on the cell surface.

Evidence of extensive phospholipid fatty acid methylation during the assumed selective methylation of plasma free fatty acids by diazomethane

We compared a conventional method (Method I) for measuring plasma free fatty acid (FFA) concentrations with two more rapid procedures (Method II and Method III). Method I required total lipid extraction, separation of FFA by thin-layer chromatography, methylation, and gas-liquid chromatographic analysis of the fatty acid (FA) methyl esters. Method II was a colorimetric procedure. Method III relied upon diazomethanes presumed ability to selectively methylate FFA even in the presence of FA esters. The three methods were compared using plasma from fasted and from fed nude mice, tumor-bearing mice (MX-1 and ZR-75-1 human mammary carcinomas), and controls. Method II, was less reliable than Method I, but both gave similar mean values for plasma FFA levels in fasted mice. Both Methods I and II also showed similar lowering of plasma FFA levels after feeding previously fasted mice. Method III consistently gave values that were far greater than those obtained using Methods I and II. Moreover, highly significant differences between fasted and fed mice were obscured by direct methylation of plasma FFA with diazomethane (Method III). The excess FA methyl esters formed in Method III were derived from plasma phospholipids, but not from plasma triacylglycerols. After feeding fasted mice, plasma free palmitic acid and oleic acid levels fell (Method I); by contrast, the excess “FFA” formed by methylation of plasma phospholipid FA increased two-fold and fourteen-fold, respectively. Caution is therefore advised in the use of direct methylating agents when measuring total and individual plasma FFA levels.

Analysis of Expression of Human Mammary Epithelial Antigens in Normal and Malignant Breast Cells at the Single Cell Level by Flow Cytofluorimetry

The expression of cell-type specific antigens on the surface of human mammary epithelial cells (HME antigens) is analyzed at the single cell level by flow cytofluorimetry. Methods are described to deal with two technical difficulties that have hampered the quantitation of surface antigens on cells from primary cultures by flow cytofluorimetry, namely, cell clumping and the presence of several cell types. By staining the cells simultaneously with two different fluorescent markers: the cell surface HME antigens with fluorescein-tagged antibodies (green fluorescence) and the cell DNA with propidium iodide (red fluorescence), it was possible to determine the expression of HME antigens per unit DNA, analyze their expression on breast cells in mixed populations, and analyze their expression in different phases of the cell cycle. The HME antigens were diminished in malignant breast epithelial cells as compared to their normal counterpart.

Epitope expression on the breast epithelial mucin.

SummaryMultiple epitope expression on the breast epithelial mucin was explored using a panel of monoclonal antibodies (MoAbs) created against milk and breast tissue preparations, against blood group determinants, and against other non-breast epithelial mucins. Since the breast epithelial mucin is now used in both diagnostic and therapeutic modalities for breast cancer, and also because altered or incomplete glycosylation in varying degrees is expected in breast carcinoma tissue, the antigenic target used here was the native mucin and sequential stages of deglycosylation introduced to it by HF treatment. Partial deglycosylation increased exposure of core peptide amino acid sequences increasing MoAb binding generally, while it either decreased or occasionally increased binding of blood group oligosaccharides. Cross reactivity of MoAbs to other mucins was low with the breast epithelial mucin (BEM). The study of the affinity binding constants of some of the anti-BEM peptide MoAbs predicted carbohydrate participation in their epitope structure. The identification of different epitopes on the BEM, investigations on their possible epitopic structure, and the study of MoAb binding during different stages of glycosylation of the molecule leads to knowledge on the contribution of carbohydrates to their epitopes and strengthens the ability to understand their performance in their diverse possible applications in breast cancer diagnosis, prognosis, and therapy.