- Email: [email protected]
An immunohistochemical analysis of human aortic fatty streaks
An Immunohistochemical Analysis of Human Aortic Fatty Streaks J. MICHAEL MUNRO, MB, BS, MRCP, JON D. VAN DER WALT, MB, BCH, MRCPATH,* COLIN S. MUNRO, MB, BCH, MRCP,t JOHN A C. CHALMERS, MB, CHB, FRCS,* AND ELAINE L. COX, FIMLS Recent studies have shown both macrophages and lymphocytes in very early intimal lesions of experimental aortic atherosclerosis. The authors obtained fresh samples of human aortic wall, which had been removed in the course of aortocoronary bypass graft surgery. Intimal fatty streaks were identified macroscopi. cally and six were studied immunohistochemically. The fatty streaks contained foam cells that were virtually all labeled by antibodies directed against members of the mononuclear phagocyte series (RFD-2 and RFD-7). Macrophages demonstrated a c i d phosphatase activity and marked expression of HLA-DR, suggesting activation. Other monoclonal antibodies (UCHT-I, OKT-4, and RFT-8) identified T lymphocytes, of both helper and suppressor phenotypes, within the fatty streaks. T lymphocytes of suppressor phenotype appeared to predominate over helper cells. B lymphocytes were not detected. The presence of activated macrophages and T lymphocytes in the fatty streaks indicates that components of a cell-mediated immune response are present. Such an immune process may be important in the pathogenesis of human atherosclerosis. HUM PATHOL 18:375--380, 1987.
MATERIALS AND METHODS
Specimens of proximal aortic wall were obtained from patients undergoing aortocoronary bypass graft surgery for ischemic heart disease. During this procedure a piece of aortic wall is removed in order to create an anastomosis with the vein graft. T h e s e pieces are typically 3 • 4 mm in size. Within 90 minutes o f excision, specimens containing macroscopically identifiable intilnal fatty streaks (focal, sometimes raised, elongated yellow areas) were bisected transversely; one half was formalin fixed, routinely processed, and paraffin embedded. T h e other half was e m b e d d e d in O C T compound (RA Lamb) and d r o p p e d into a bath of isopentane, precooled in liquid nitrogen. Five-micron cryostat sections were cut, air dried, fixed in 1:1 chloroform/acetone, and stored at - 7 0 ~ The presence of fatty streaks was c o n f i r m e d by h e m a t o x y l i n - e o s i n and oil red O stains, and frozen sections of these specimens were examined with a range of murine monoclonal antibodies (table 1) and immunohistologic techniques. Sections were incubated with appropriate dilutions of each antibody for 90 minutes, washed twice for 5 minutes in phosphate-buffered saline (PBS), and then incubated with a second layer reagent for a further 60 minutes. For immunoperoxidase studies, peroxidase-conjugated rabbit antimouse immuno-
Fatty streaks are considered to be potential precursors o f atherosclerotic plaques in humans although p r o o f is still lacking, t The foam cells in fatty streaks have been t h o u g h t to originate predominantly from s m o o t h muscle cells o f the arterial media. 2 However, recent studies in both animals 3-5 and humans 6 have indicated that most o f these cells are members of the mononuclear phagocyte series. Joris and colleagues 7 have shown that macrophage foam cells of very early atherosclerotic lesions in rats derive from blood monocytes that migrate through the endothelial layer. In addition, they noted that lymphocytes also migrated into the intima. In this study, immunohistochemical methods have been used to assess human aortic fatty streaks with regard to evidence of immunocompetent cells, particularly lymphocytes and their subsets.
TABLE 1.
Received from the Departments of Morbid Anatomy and ~:Cardiothoracic Surgery, The London Hospital, and the tDepartment of Immunology, the Royal Free Hospital, London, England. Accepted for publication August 4, 1986. Presented in part at the 152nd meeting of the Pathological Society of Great Britain and Ireland, January 8 - I 0 , 1986, London, England. *Supported by a fellowship from the Arthritis and Rheumatism Council. Address correspondence and reprint requests to Dr. van der Walt: Department of Morbid Anatomy, The London Hospital, Whitechapel, London, E1 1BB, England.
Reagent
Class
RFD2
IgG
RFD7
IgG
RFDRI* UCHT1 OKT4b
IgM IgG IgM
RFT8a RF-I8b
IgM IgG
Dakopan-B
IgG
Monoclonal Antibodies Used in Study Specificity Monocytes and macrophages ~ Tissue macrophages (not monocytes) HLA-DR T lymphocytes T helper cellsSuppressor/ cytotoxic cells B lymphocytes
Source
Reference
RFHSM
8
RFHSM
8
RFHSM P. Beverley Ortho
9 10 11
RFHSM
12
Dako
13
ABBREVIATION:RFHSM, Royal Free Hospital School of Medicine. * Conjugated to glucose oxidase.
375
HUMAN PATHOLOGY
Volume l& No. 4 (April 1987]
FIGURE 1 Cleft). Part of an aortic fatty streak showing lipid-containing foam cells. [Hematoxylin-eosin stain, x 300.] FIGURE 2 [right). Edge of an aortic fatty streak. Foam cells are present in the fatly streak to the left and diminish in number near the adjacent extralesional lntima. COil red O, hematoxylin counterstain. x 80.)
of frozen sections showing a preserved lesion was obtained in six specimens. Tile patients from whom these were obtained were all men whose ages ranged from 49 to 67. The cryostat sections were adequate for morphologic purposes. Four of tile six streaks were raised. T h e entire width was available for study in four cases, but two of the lesions extended to one resection margin. The lesions ranged from 0.50 to 1.95 mm in available width, and showed intimal aggregates of large lipid containing foam cells (fig. 1), which stained positively with oil red O (fig. 2). Areas o f necrosis, fibrous caps, and other features of more advanced atheromatous lesions were not seen. T h e foam cells were generally present close to the endothelium and were oval. In addition, elongated and spindle-shaped foam cells were present deeper in the lesions. Lymphocytes were identifiable in varying n u m b e r s in all lesions with h e m a t o x y l i n - e o s i n stained, paraffin-embedded sections. The intima adj~acent to the lesions showed diffuse thickening, and m four cases contained scattered foam cells. Approximately 90 per cent of the lesional foam cells reacted with RFD-2 (antipan monocyte/macrophage antibody (fig. 3). The occasional nonreactive lesional foam cells were situated deeply, between the main s u b e n d o t h e l i a l aggregate o f cells and the media. Scattered foam cells in the adjacent extralesional intima also reacted with RFD-2. RFD-7 (antitissue macrophage antibody) reacted with 25 to 85
globulin (Dako) was applied as second layer, and nonspecific binding was eliminated by including 1/100 normal human AB serum. Following a second wash, the sections were developed with diaminobenzidine/hydrogen peroxide and counterstained with hematoxylin. The prevalence of labeled cells was estimated visually. Glucose oxidase-conjugated antibody to HLA-DR was also used in a single layer technique, w i t h n i t r o b l u e tetrazolium as a substrate. This method facilitates assessment of the relative intensity of HLA-DR expression./4 In double immunofluorescence studies, IgG and IgM first layer reagents were labeled with rhodamine- and fluorescein-conjugated goat antibodies to the respective Ig classes (Southern Biotechnology Associates). The sections were mounted in PBS-glycerol and viewed under a Zeiss epifluorescence microscope with appropriate filters. Simultaneous azo-coupling to hexazotinized pararosaniline 15 was used for demonstrating acid phosphatase activity. In all studies, positive controls were provided by sections of human tonsil, and negative controls for antibody studies by incubation o f the sections with antibodies of irrelevant specificity. RESULTS
Fatty streaks were identified macroscopically in 11 o f 159 specimens examined. A sufficient number 376
ANALYSISOF HUMANAORTIC FAI"iYSTREAKS[Munro et al.)
t
.,,~ , ~ -
9 t_,b,~.
t
b
~ ~
J
,, "r
,,~w
~J
Q
P
9
FIGURE 3 [top/eft). Part of fatty sITeakassessed using antibody RFD2 [antimonocyte/macrophage]. Virtually all foam cells are positive. (Peroxidase technique, hematoxylin counterstain, x 200.] FIGURE 4 [top right]. Foam cells of fatty streak stained for HI_A-DR. CNitroblue tetrazoIium stain produced by glucose oxidase conjugated to RFDR-I. x 200.] FIGURE 5 [bottom right]. Foam cells of fatty streak showing acid phosphatase activity. [Acid phosphatase technique, hematoxylin counterstain, x 300.]
9
D
~"
t"
, .It A~
~4
377
HUMAN PATHOLOGY
Volume 18, No. 4 [April 1987]
FIGURE 6 (left). Fatty streak demonstrating presence of T lymphocytes. Laminae of autofluorescent elastin are visible at the bottom of the figure. (Fluorescein anti-lgG and UCHTI. • 150.) FIGURE 7 (right). The same section as in figure 6 demonstrating presence of T8-positive lymphocytes. Many cells visualized in figure 6 are not identifiable here. (Rhodamine anti-lgM and RFTSa. x t50.]
were scattered among tile foam ceils and showed the same general distribution within the lesion. OKT-4 positive and RFT-8 positive populations were both represented, and the latter predominated in most cases with a typical ratio of 1:2. T4 directed antibodies may identify cells of tile mononuclear phagocyte series, 16 but UCHT-1/RFT-8 double fluorescence staining confirmed that the RFT-8 positive cells were not the sole T cell population (fig. 7). B lymphocytes were not identified in any of the lesions, and no lymphocytes of any type were identified in tile adjacent intima.
per cent of the foam cells in the fatty streaks. RFD7 negative foam cells were seen deep in tile lesions and in small groups in the subendothelial zone. Scattered foam cells in the adjacent thickened intima were labeled by RFD-7. Virtually all foam cells showed marked expression of HLA-DR (fig. 4), which was not identified on other types of cell present. A few foam cells located deep in the lesion were HLA-DR negative. A very few intimal foam cells outside the fatty streaks expressed HLA-DR, and the reaction appeared less intense than the reaction of foam cells within the lesion. Except for a few in the deep zone, all the foam cells in the streaks demonstrated acid phosphatase activity (fig. 5), which was comparable to that seen in germinal center macrophages in the control tonsil sections. Scattered foam cells in the extralesional intima also showed activity. More extralesional cells showed acid phosphatase activity than expressed HLA-DR. T lymphocytes were identified in all fatty streaks (fig. 6). The total number in single sections of lesions ranged from 3 to 37, their n u m b e r being broadly proportional to the size of the fatty streak. T cells
DISCUSSION
In this series of six cases, the authors have demonstrated that immunocompetent cells, in the form o f macrophages and T lymphocytes, are a major component of h u m a n fatty streaks, the type of lesion that may be the f o r e r u n n e r of the atherosclerotic plaque. 1 T h e foam cells in the streaks e x a m i n e d reacted with antibodies directed against members of the mononuclear phagocyte series. Ahhough RFD-2 labels all cells of this series, the antigen labeled by 378
ANALYSISOF HUMANAORTIC FA1]YSTREAKS(Munro el el.)
would be o f interest to characterize the l y m p h o c y t e s p r e s e n t in the fatty streaks o f y o u n g e r people. Atherosclerosis m i g h t involve an i m m u n e process d i r e c t e d against a lipid d e r i v e d f r o m the vessel l u m e n , as has b e e n suggested in a u t o i m m u n e h y p e r lipidemia, 26 or against an antigen native to the arterial wall. 27,28 I f the latter is the case, the i n f l a m m a tory process could cause local d a m a g e , leading to increased p e r m e a b i l i t y to lipids. A viral a n t i g e n 2~176or i m m u n e c o m p l e x deposition 31 m i g h t t r i g g e r the initial r e s p o n s e . It is clear that t h e r e is a n e e d f o r furt h e r w o r k o n the relevance o f i m m u n o l o g i c factors to the origins a n d p r o g r e s s i o n by atherosclerosis.
RFD-7 is e x p r e s s e d by tissue m a c r o p h a g e s but not e a r l i e r f o r m s i n c l u d i n g m o n o c y t e s . T h e fact t h a t m o r e f o a m cells reacted with RFD-2 than RFD-7 suggests that not all the cells h a d u n d e r g o n e differentiau o n into m a t u r e tissue m a c r o p h a g e s . T h e s e putative earlier cells o f the series were often seen in g r o u p s i m m e d i a t e l y b e n e a t h the e n d o t h e l i u m , which is consistent with p r e v i o u s m i g r a t i o n o f m o n o c y t e s f r o m the lumen, a phenomenon a p p a r e n t in a n i m a l models.3-5, 7 A l t h o u g h not specific, increased activity o f acid p h o s p h a t a s e is a f e a t u r e o f m a c r o p h a g e activation, 17 a n d activity o f this e n z y m e was readily d e m o n s t r a b l e in f o a m cells. H L A - D R expression by f o a m cells was seen, which c o n f i r m s p r e v i o u s o b s e r v a t i o n s , Is a n d the d e g r e e o f e x p r e s s i o n was m a r k e d . T h e p h e n o type o f the lesional f o a m cells indicated that all or virtually all cells e x p r e s s i n g surface H L A - D R were o f the m o n o n u c l e a r p h a g o c y t e series. S p i n d l e - s h a p e d cells d e e p e r in fatty streaks have b e e n f o u n d to react with a n a n t i b o d y d i r e c t e d against s m o o t h m u s c l e cells. 6 In the p r e s e n t study, the failure o f cells in the d e e p e r parts o f the fatty streak to react with RFD-2 a n d RFDR-1 is c o m p a t i b l e with s m o o t h muscle derivation. H o w e v e r , a recent study has d e m o n s t r a t e d that in atherosclerotic plaques a large p r o p o r t i o n o f the cells e x p r e s s i n g H L A - D R a n t i g e n s a r e in fact s m o o t h muscle d e r i v e d , 19 a n d in the f u t u r e it would be o f interest to assess w h e t h e r any s m o o t h muscle cells express H L A - D R e v e n in early stages o f a t h e r o sclerosis. T h e p r e s e n c e o f lymphocytes, including T lymphocytes, is r e c o g n i z e d witlfin a d v a n c e d atherosclerotic lesions. ~9 H o w e v e r , in h u m a n fatty streaks cells of lymphocyte morphology have previously been n o t e d only in passing, z~ a n d o t h e r extensive descriptions o f fatty streaks do not include m e n t i o n o f lymphocytes. 21,2z L y m p h o c y t e nuclei visible o n r o u t i n e staining m a y h a v e been t a k e n to be f o a m cell nuclei because the two cell types are a d m i x e d . T h i s study demonstrates that both T-helper and -suppressor p h e n o t y p e s are p r e s e n t in intimal fatty streaks. In the circulation T - h e l p e r cells p r e d o m i n a t e , 23 but in f a t t y s t r e a k s T - s u p p r e s s o r cells a p p e a r e d to b e p r e s e n t in g r e a t e r n u m b e r s . H o w e v e r , in view o f the small n u m b e r s o f l y m p h o c y t e s p r e s e n t in these lesions, f u r t h e r studies will be r e q u i r e d to c o n f i r m this observation. Class I I a n t i g e n s ( H L A - D R a n d r e l a t e d m o l e cules in h u m a n s ) a r e k n o w n to be involved in the p r e sentation o f a n t i g e n to lymphocytes. 24 T h e p r e s e n c e o f m a c r o p h a g e s e x p r e s s i n g a b u n d a n t H L A - D R , tog e t h e r with T l y m p h o c y t e s in both fatty streaks a n d p l a q u e s 19 indicates t h a t c e l l - m e d i a t e d i m m u n e responses m a y be involved in atherosclerosis. T h i s is in k e e p i n g with the o b s e r v a t i o n that certain H L A types a r e a s s o c i a t e d with a t h e r o s c l e r o t i c disease. 25 T h e fatty streaks w e r e o b t a i n e d f r o m subjects with c o m plicated atherosclerosis at o t h e r sites, a n d it is possible that the p r o m i n e n c e o f T - s u p p r e s s o r / c y t o t o x i c cells indicates a s e c o n d a r y r e g u l a t o r y process. T h u s it
Acknowledgments. The authors thank Dr. Leonard W. Poulter for kindly donating reagents used in the study and Professor David J. Evans for helpful criticism of the manuscript. REFERENCES 1. McGill HC Jr: Persistent problems in the pathogenesis of atherosclerosis. Arteriosclerosis 4:443, 1984 2. Ross R, Glomset JA: Atherosclerosis and the arterial smooth muscle cell. Science 180:1332, 1973 3. Gerrity RG: The role of the monocyte in atherogenesis: I. Transition of blood-borne monocytes into foam cells in fatty lesions. AmJ Pathol 103:181, 1981 4. Schwartz CJ, Sprague EA, Kelley JL. et al: Aortic intimal monocyte recruitment in the normo and hypercholesterolemic baboon (Papio cynocephalus): an uhrastructural study: implications in atherogenesis. Virchows Arch [A] 405:175, 1985 5. Watanabe T, Hirata M, Yoshikawa Y, et al: Role of macrophages in atherosclerosis: sequential observations of cholesterol-induced rabbit aortic lesions by the immunoperoxidase technique using monoclonal antimacrophage antibody. Lab Invest 53:80, 1985 6. Aqel NM, Ball RY, Waldmann H, et al: Identification of macrophages and smooth muscle cells in human atherosclerosis using monoclonal antibodies. J Pathol 146:197, 1985 7. joris I, Zand T, NunnariJJ, etal: Studies on the pathogenesis of atherosclerosis. I. Adhesion and emigration of mononuclear cells in the aorta of hypercholesterolemic rats. Am J Pathol 113:341, 1983 8. Mtmro CS, Mitchell DN, Poulter LW, etal: Early cellular responses to intradermal injection of Kveim suspension in normal subjects and those with sarcoidosis. J Clin Pathol 39:176, 1986 9. Janossy G, Bofill M, Poulter LW: Two-color immunofluorescence: analysis of the immune system with monoclonal antibodies. In PolakJ, van Noorden S (eds): Immunocytoclaemistry: Practical Applications in Pathology and Biology, ed 2. Bristol, Wright. In press 10. Beverley PCL, Callard RE: Distinctive f_unctional characteristics of human 'T' lymphocytes defined by E-rosetting or a monoclonal anti-T-cell antibody. Eur ~J Immunol 11:329, 1981 11. Bach M-A, l'han-Dinh-Tuy F, Bacb J-F, et al: Unusual phenotypes of human inducer T cells as measured by OKT4 and related monoclonal antibodies. J Immunol 127:980, 1981 12. Janossy G, Prentice IIG: T cell subpopulations, monoclonal antibodies, and their therapeutic application. Clin Hematol 11:631, 1982 13. Stein H, GerdesJ, Mason DY: The normal and malignant germinal center. Clin Hematol 11:531, 1982 14. Collings LA, Tidman N, Pouher LW: Quantitation of HLADR expression by cells involved in the skin lesions of tuberculoid and lepromatous leprosy. Clin Exp Immunol 61:58, 1985
379
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V o l u m e 18, No. 4 (April 1987]
15. Lojda Z, Grossau R, Schleiber T I t : Enzyme Histocllemistry. Berlin, Springer-Verlag, 1979 16. Wood GS, Warner NL, Warnke RA: Anti-Leu-3/T4 antibodies react with cells of monocyte/nmcrophage and Langerlmns lineage. J Immonol 131:212, 1983 17. Adams DO, ttamilton TA: The cell biology of macrophage activation. Annu Rev Immunol 2:283, 1984 18. Vedeler CA, Nyland H, Matre R: In situ characterisation of the foam cells in earl)' human atherosclerotic lesions. Acta Path Microbiol Immunol Scand [C] 92:133, 1984 19~ Jonasson L, Holm J, Skalli O, et al: Expression of class II transplantation antigen on vascular smooth muscle cells in human atherosclerosis. J Clin Invest 76:125, 1985 20. Still WJS, Marriott PR: Comparative morpholog)' of the earl)' atherosclerotic lesion in man and cholesterol-atherosclerosis in rabbit: an electromicroscopic study. J Atheroscler Res 4:373, 1964 21. Geer JC, McGill HC, StrongJP: The fine structure of human atherosclerotic lesions. Am J Pathol 38:263, 1961 22. Balis JU, Haust MD, More RH: Electron-microscopic studies in human atherosclerosis: Cellular elements in aortic fatty streaks. Exp Mol Pathol 3:511, 1964 23. Rogers MF, Morens DM, Stewart JA, et al: The task force on acquired immune deficiency syndrome: national case-control study of Kaposi's sarcoma and pneumocystis carinii
380
24. 25. 26.
27. 28. 29. 30. 31.
pneumonia in homosexual men: part 2, laboratory resuhs. Ann Intern Med 99:151, 1983 Unanue ER: Antigen presenting function of the nmcrophage. Annu Rev Immunol 2:395, 1984 MathewsJD: Ischenfic heart disease: possible genetic markers. Lancet 2:681, 1975 Beaumont JL, Bandet MF, Dachet C, et al: Antoimmune hyperlipidemia and atttoimmune xanthomatosis, hz Gotto AM Jr, Smith LC, Allen B (eds): Atherosclerosis V - - P r o ceedings of the fifth international symposiunl. New York, Springer-Verlag, 1980 Loft B, Olsen F: Delayed hypersensitivity and arteriosclerosis in man. Acta Path Microbiol Scand [B] 81:779, 1973 Cerilli J, Brasile L, Karmody A: Role of the vascular endothelial cell antigen system in the etiology of atherosclerosis. Ann Surg 202:329, 1985 Benditt EP, Barrett T, McDougall JK: Viruses in the etiology of atherosclerosis. Proc Natl Acad Sci USA 80:6386, 1983 Melnick JL, Petrie BL, Dreesman GR, et al: Cytomegalovirus antigen within human arterial smooth muscle cells. Lancet 2:644, 1983 Fust G, Szondy E, SzekelyJ, et al: Studies on the occurrence of circulating immune complexes in vascular diseases. Atherosclerosis 29:181, 1978
MATERIALS AND METHODS
Specimens of proximal aortic wall were obtained from patients undergoing aortocoronary bypass graft surgery for ischemic heart disease. During this procedure a piece of aortic wall is removed in order to create an anastomosis with the vein graft. T h e s e pieces are typically 3 • 4 mm in size. Within 90 minutes o f excision, specimens containing macroscopically identifiable intilnal fatty streaks (focal, sometimes raised, elongated yellow areas) were bisected transversely; one half was formalin fixed, routinely processed, and paraffin embedded. T h e other half was e m b e d d e d in O C T compound (RA Lamb) and d r o p p e d into a bath of isopentane, precooled in liquid nitrogen. Five-micron cryostat sections were cut, air dried, fixed in 1:1 chloroform/acetone, and stored at - 7 0 ~ The presence of fatty streaks was c o n f i r m e d by h e m a t o x y l i n - e o s i n and oil red O stains, and frozen sections of these specimens were examined with a range of murine monoclonal antibodies (table 1) and immunohistologic techniques. Sections were incubated with appropriate dilutions of each antibody for 90 minutes, washed twice for 5 minutes in phosphate-buffered saline (PBS), and then incubated with a second layer reagent for a further 60 minutes. For immunoperoxidase studies, peroxidase-conjugated rabbit antimouse immuno-
Fatty streaks are considered to be potential precursors o f atherosclerotic plaques in humans although p r o o f is still lacking, t The foam cells in fatty streaks have been t h o u g h t to originate predominantly from s m o o t h muscle cells o f the arterial media. 2 However, recent studies in both animals 3-5 and humans 6 have indicated that most o f these cells are members of the mononuclear phagocyte series. Joris and colleagues 7 have shown that macrophage foam cells of very early atherosclerotic lesions in rats derive from blood monocytes that migrate through the endothelial layer. In addition, they noted that lymphocytes also migrated into the intima. In this study, immunohistochemical methods have been used to assess human aortic fatty streaks with regard to evidence of immunocompetent cells, particularly lymphocytes and their subsets.
TABLE 1.
Received from the Departments of Morbid Anatomy and ~:Cardiothoracic Surgery, The London Hospital, and the tDepartment of Immunology, the Royal Free Hospital, London, England. Accepted for publication August 4, 1986. Presented in part at the 152nd meeting of the Pathological Society of Great Britain and Ireland, January 8 - I 0 , 1986, London, England. *Supported by a fellowship from the Arthritis and Rheumatism Council. Address correspondence and reprint requests to Dr. van der Walt: Department of Morbid Anatomy, The London Hospital, Whitechapel, London, E1 1BB, England.
Reagent
Class
RFD2
IgG
RFD7
IgG
RFDRI* UCHT1 OKT4b
IgM IgG IgM
RFT8a RF-I8b
IgM IgG
Dakopan-B
IgG
Monoclonal Antibodies Used in Study Specificity Monocytes and macrophages ~ Tissue macrophages (not monocytes) HLA-DR T lymphocytes T helper cellsSuppressor/ cytotoxic cells B lymphocytes
Source
Reference
RFHSM
8
RFHSM
8
RFHSM P. Beverley Ortho
9 10 11
RFHSM
12
Dako
13
ABBREVIATION:RFHSM, Royal Free Hospital School of Medicine. * Conjugated to glucose oxidase.
375
HUMAN PATHOLOGY
Volume l& No. 4 (April 1987]
FIGURE 1 Cleft). Part of an aortic fatty streak showing lipid-containing foam cells. [Hematoxylin-eosin stain, x 300.] FIGURE 2 [right). Edge of an aortic fatty streak. Foam cells are present in the fatly streak to the left and diminish in number near the adjacent extralesional lntima. COil red O, hematoxylin counterstain. x 80.)
of frozen sections showing a preserved lesion was obtained in six specimens. Tile patients from whom these were obtained were all men whose ages ranged from 49 to 67. The cryostat sections were adequate for morphologic purposes. Four of tile six streaks were raised. T h e entire width was available for study in four cases, but two of the lesions extended to one resection margin. The lesions ranged from 0.50 to 1.95 mm in available width, and showed intimal aggregates of large lipid containing foam cells (fig. 1), which stained positively with oil red O (fig. 2). Areas o f necrosis, fibrous caps, and other features of more advanced atheromatous lesions were not seen. T h e foam cells were generally present close to the endothelium and were oval. In addition, elongated and spindle-shaped foam cells were present deeper in the lesions. Lymphocytes were identifiable in varying n u m b e r s in all lesions with h e m a t o x y l i n - e o s i n stained, paraffin-embedded sections. The intima adj~acent to the lesions showed diffuse thickening, and m four cases contained scattered foam cells. Approximately 90 per cent of the lesional foam cells reacted with RFD-2 (antipan monocyte/macrophage antibody (fig. 3). The occasional nonreactive lesional foam cells were situated deeply, between the main s u b e n d o t h e l i a l aggregate o f cells and the media. Scattered foam cells in the adjacent extralesional intima also reacted with RFD-2. RFD-7 (antitissue macrophage antibody) reacted with 25 to 85
globulin (Dako) was applied as second layer, and nonspecific binding was eliminated by including 1/100 normal human AB serum. Following a second wash, the sections were developed with diaminobenzidine/hydrogen peroxide and counterstained with hematoxylin. The prevalence of labeled cells was estimated visually. Glucose oxidase-conjugated antibody to HLA-DR was also used in a single layer technique, w i t h n i t r o b l u e tetrazolium as a substrate. This method facilitates assessment of the relative intensity of HLA-DR expression./4 In double immunofluorescence studies, IgG and IgM first layer reagents were labeled with rhodamine- and fluorescein-conjugated goat antibodies to the respective Ig classes (Southern Biotechnology Associates). The sections were mounted in PBS-glycerol and viewed under a Zeiss epifluorescence microscope with appropriate filters. Simultaneous azo-coupling to hexazotinized pararosaniline 15 was used for demonstrating acid phosphatase activity. In all studies, positive controls were provided by sections of human tonsil, and negative controls for antibody studies by incubation o f the sections with antibodies of irrelevant specificity. RESULTS
Fatty streaks were identified macroscopically in 11 o f 159 specimens examined. A sufficient number 376
ANALYSISOF HUMANAORTIC FAI"iYSTREAKS[Munro et al.)
t
.,,~ , ~ -
9 t_,b,~.
t
b
~ ~
J
,, "r
,,~w
~J
Q
P
9
FIGURE 3 [top/eft). Part of fatty sITeakassessed using antibody RFD2 [antimonocyte/macrophage]. Virtually all foam cells are positive. (Peroxidase technique, hematoxylin counterstain, x 200.] FIGURE 4 [top right]. Foam cells of fatty streak stained for HI_A-DR. CNitroblue tetrazoIium stain produced by glucose oxidase conjugated to RFDR-I. x 200.] FIGURE 5 [bottom right]. Foam cells of fatty streak showing acid phosphatase activity. [Acid phosphatase technique, hematoxylin counterstain, x 300.]
9
D
~"
t"
, .It A~
~4
377
HUMAN PATHOLOGY
Volume 18, No. 4 [April 1987]
FIGURE 6 (left). Fatty streak demonstrating presence of T lymphocytes. Laminae of autofluorescent elastin are visible at the bottom of the figure. (Fluorescein anti-lgG and UCHTI. • 150.) FIGURE 7 (right). The same section as in figure 6 demonstrating presence of T8-positive lymphocytes. Many cells visualized in figure 6 are not identifiable here. (Rhodamine anti-lgM and RFTSa. x t50.]
were scattered among tile foam ceils and showed the same general distribution within the lesion. OKT-4 positive and RFT-8 positive populations were both represented, and the latter predominated in most cases with a typical ratio of 1:2. T4 directed antibodies may identify cells of tile mononuclear phagocyte series, 16 but UCHT-1/RFT-8 double fluorescence staining confirmed that the RFT-8 positive cells were not the sole T cell population (fig. 7). B lymphocytes were not identified in any of the lesions, and no lymphocytes of any type were identified in tile adjacent intima.
per cent of the foam cells in the fatty streaks. RFD7 negative foam cells were seen deep in tile lesions and in small groups in the subendothelial zone. Scattered foam cells in the adjacent thickened intima were labeled by RFD-7. Virtually all foam cells showed marked expression of HLA-DR (fig. 4), which was not identified on other types of cell present. A few foam cells located deep in the lesion were HLA-DR negative. A very few intimal foam cells outside the fatty streaks expressed HLA-DR, and the reaction appeared less intense than the reaction of foam cells within the lesion. Except for a few in the deep zone, all the foam cells in the streaks demonstrated acid phosphatase activity (fig. 5), which was comparable to that seen in germinal center macrophages in the control tonsil sections. Scattered foam cells in the extralesional intima also showed activity. More extralesional cells showed acid phosphatase activity than expressed HLA-DR. T lymphocytes were identified in all fatty streaks (fig. 6). The total number in single sections of lesions ranged from 3 to 37, their n u m b e r being broadly proportional to the size of the fatty streak. T cells
DISCUSSION
In this series of six cases, the authors have demonstrated that immunocompetent cells, in the form o f macrophages and T lymphocytes, are a major component of h u m a n fatty streaks, the type of lesion that may be the f o r e r u n n e r of the atherosclerotic plaque. 1 T h e foam cells in the streaks e x a m i n e d reacted with antibodies directed against members of the mononuclear phagocyte series. Ahhough RFD-2 labels all cells of this series, the antigen labeled by 378
ANALYSISOF HUMANAORTIC FA1]YSTREAKS(Munro el el.)
would be o f interest to characterize the l y m p h o c y t e s p r e s e n t in the fatty streaks o f y o u n g e r people. Atherosclerosis m i g h t involve an i m m u n e process d i r e c t e d against a lipid d e r i v e d f r o m the vessel l u m e n , as has b e e n suggested in a u t o i m m u n e h y p e r lipidemia, 26 or against an antigen native to the arterial wall. 27,28 I f the latter is the case, the i n f l a m m a tory process could cause local d a m a g e , leading to increased p e r m e a b i l i t y to lipids. A viral a n t i g e n 2~176or i m m u n e c o m p l e x deposition 31 m i g h t t r i g g e r the initial r e s p o n s e . It is clear that t h e r e is a n e e d f o r furt h e r w o r k o n the relevance o f i m m u n o l o g i c factors to the origins a n d p r o g r e s s i o n by atherosclerosis.
RFD-7 is e x p r e s s e d by tissue m a c r o p h a g e s but not e a r l i e r f o r m s i n c l u d i n g m o n o c y t e s . T h e fact t h a t m o r e f o a m cells reacted with RFD-2 than RFD-7 suggests that not all the cells h a d u n d e r g o n e differentiau o n into m a t u r e tissue m a c r o p h a g e s . T h e s e putative earlier cells o f the series were often seen in g r o u p s i m m e d i a t e l y b e n e a t h the e n d o t h e l i u m , which is consistent with p r e v i o u s m i g r a t i o n o f m o n o c y t e s f r o m the lumen, a phenomenon a p p a r e n t in a n i m a l models.3-5, 7 A l t h o u g h not specific, increased activity o f acid p h o s p h a t a s e is a f e a t u r e o f m a c r o p h a g e activation, 17 a n d activity o f this e n z y m e was readily d e m o n s t r a b l e in f o a m cells. H L A - D R expression by f o a m cells was seen, which c o n f i r m s p r e v i o u s o b s e r v a t i o n s , Is a n d the d e g r e e o f e x p r e s s i o n was m a r k e d . T h e p h e n o type o f the lesional f o a m cells indicated that all or virtually all cells e x p r e s s i n g surface H L A - D R were o f the m o n o n u c l e a r p h a g o c y t e series. S p i n d l e - s h a p e d cells d e e p e r in fatty streaks have b e e n f o u n d to react with a n a n t i b o d y d i r e c t e d against s m o o t h m u s c l e cells. 6 In the p r e s e n t study, the failure o f cells in the d e e p e r parts o f the fatty streak to react with RFD-2 a n d RFDR-1 is c o m p a t i b l e with s m o o t h muscle derivation. H o w e v e r , a recent study has d e m o n s t r a t e d that in atherosclerotic plaques a large p r o p o r t i o n o f the cells e x p r e s s i n g H L A - D R a n t i g e n s a r e in fact s m o o t h muscle d e r i v e d , 19 a n d in the f u t u r e it would be o f interest to assess w h e t h e r any s m o o t h muscle cells express H L A - D R e v e n in early stages o f a t h e r o sclerosis. T h e p r e s e n c e o f lymphocytes, including T lymphocytes, is r e c o g n i z e d witlfin a d v a n c e d atherosclerotic lesions. ~9 H o w e v e r , in h u m a n fatty streaks cells of lymphocyte morphology have previously been n o t e d only in passing, z~ a n d o t h e r extensive descriptions o f fatty streaks do not include m e n t i o n o f lymphocytes. 21,2z L y m p h o c y t e nuclei visible o n r o u t i n e staining m a y h a v e been t a k e n to be f o a m cell nuclei because the two cell types are a d m i x e d . T h i s study demonstrates that both T-helper and -suppressor p h e n o t y p e s are p r e s e n t in intimal fatty streaks. In the circulation T - h e l p e r cells p r e d o m i n a t e , 23 but in f a t t y s t r e a k s T - s u p p r e s s o r cells a p p e a r e d to b e p r e s e n t in g r e a t e r n u m b e r s . H o w e v e r , in view o f the small n u m b e r s o f l y m p h o c y t e s p r e s e n t in these lesions, f u r t h e r studies will be r e q u i r e d to c o n f i r m this observation. Class I I a n t i g e n s ( H L A - D R a n d r e l a t e d m o l e cules in h u m a n s ) a r e k n o w n to be involved in the p r e sentation o f a n t i g e n to lymphocytes. 24 T h e p r e s e n c e o f m a c r o p h a g e s e x p r e s s i n g a b u n d a n t H L A - D R , tog e t h e r with T l y m p h o c y t e s in both fatty streaks a n d p l a q u e s 19 indicates t h a t c e l l - m e d i a t e d i m m u n e responses m a y be involved in atherosclerosis. T h i s is in k e e p i n g with the o b s e r v a t i o n that certain H L A types a r e a s s o c i a t e d with a t h e r o s c l e r o t i c disease. 25 T h e fatty streaks w e r e o b t a i n e d f r o m subjects with c o m plicated atherosclerosis at o t h e r sites, a n d it is possible that the p r o m i n e n c e o f T - s u p p r e s s o r / c y t o t o x i c cells indicates a s e c o n d a r y r e g u l a t o r y process. T h u s it
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