Thoracic duct lymphatic fluid harbors phenotypically naive T cells for use in adoptive T-cell therapy.

BACKGROUND AIMS: Manufacturing of potent chimeric antigen receptor (CAR) T cells requires phenotypically naive and early memory T cells. We hypothesized lymphatic fluid collected from the thoracic duct of children would serve as a unique reservoir for early T cells, which could then be used for CAR T-cell therapy. METHODS: We evaluated lymphatic fluid collected from 25 pediatric patients undergoing thoracic duct cannulation for other clinical indications. RESULTS: Lymphatic fluid in the thoracic duct was rich in T cells, with higher percentage of naive and stem central memory T-cell subsets compared with paired blood samples. T cells from lymphatic fluid showed decreased negative checkpoint regulators on the surface and increased rapid expansion with bead activation. Creation of CD19-directed CAR T cells from blood and lymphatic T cells showed similar lentiviral transduction properties, but CAR T cells generated from lymphatic fluid produced superior cytotoxicity in a murine leukemia model because they were able to achieve equivalent tumor eradication at lower doses. CONCLUSIONS: These results are the first characterization of T cells from the thoracic duct of pediatric patients and suggest an alternative approach for manufacturing of cellular therapy that will improve both expansion and cytotoxic effect.

T follicular helper cells in human efferent lymph retain lymphoid characteristics.

T follicular helper cells (Tfh), a subset of CD4+ T cells, provide requisite help to B cells in the germinal centers (GC) of lymphoid tissue. GC Tfh are identified by high expression of the chemokine receptor CXCR5 and the inhibitory molecule PD-1. Although more accessible, blood contains lower frequencies of CXCR5+ and PD-1+ cells that have been termed circulating Tfh (cTfh). However, it remains unclear whether GC Tfh exit lymphoid tissues and populate this cTfh pool. To examine exiting cells, we assessed the phenotype of Tfh present within the major conduit of efferent lymph from lymphoid tissues into blood, the human thoracic duct. Unlike what was found in blood, we consistently identified a CXCR5-bright PD-1-bright (CXCR5BrPD-1Br) Tfh population in thoracic duct lymph (TDL). These CXCR5BrPD-1Br TDL Tfh shared phenotypic and transcriptional similarities with GC Tfh. Moreover, components of the epigenetic profile of GC Tfh could be detected in CXCR5BrPD-1Br TDL Tfh and the transcriptional imprint of this epigenetic signature was enriched in an activated cTfh subset known to contain vaccine-responding cells. Together with data showing shared TCR sequences between the CXCR5BrPD-1Br TDL Tfh and cTfh, these studies identify a population in TDL as a circulatory intermediate connecting the biology of Tfh in blood to Tfh in lymphoid tissue.

Quantification of the passive and active biaxial mechanical behaviour and microstructural organization of rat thoracic ducts.

Mechanical loading conditions are likely to play a key role in passive and active (contractile) behaviour of lymphatic vessels. The development of a microstructurally motivated model of lymphatic tissue is necessary for quantification of mechanically mediated maladaptive remodelling in the lymphatic vasculature. Towards this end, we performed cylindrical biaxial testing of Sprague-Dawley rat thoracic ducts (n = 6) and constitutive modelling to characterize their mechanical behaviour. Spontaneous contraction was quantified at transmural pressures of 3, 6 and 9 cmH2O. Cyclic inflation in calcium-free saline was performed at fixed axial stretches between 1.30 and 1.60, while recording pressure, outer diameter and axial force. A microstructurally motivated four-fibre family constitutive model originally proposed by Holzapfel et al. (Holzapfel et al. 2000 J. Elast. 61, 1-48. (doi:10.1023/A:1010835316564)) was used to quantify the passive mechanical response, and the model of Rachev and Hayashi was used to quantify the active (contractile) mechanical response. The average error between data and theory was 8.9 ± 0.8% for passive data and 6.6 ± 2.6% and 6.8 ± 3.4% for the systolic and basal conditions, respectively, for active data. Multi-photon microscopy was performed to quantify vessel wall thickness (32.2 ± 1.60 µm) and elastin and collagen organization for three loading conditions. Elastin exhibited structural 'fibre families' oriented nearly circumferentially and axially. Sample-to-sample variation was observed in collagen fibre distributions, which were often non-axisymmetric, suggesting material asymmetry. In closure, this paper presents a microstructurally motivated model that accurately captures the biaxial active and passive mechanical behaviour in lymphatics and offers potential for future research to identify parameters contributing to mechanically mediated disease development.

Human lymphatic vessel contractile activity is inhibited in vitro but not in vivo by the calcium channel blocker nifedipine.

Calcium channel blockers (CCB) are widely prescribed anti-hypertensive agents. The commonest side-effect, peripheral oedema, is attributed to a larger arterial than venous dilatation causing increased fluid filtration. Whether CCB treatment is detrimental to human lymphatic vessel function and thereby exacerbates oedema formation is unknown. We observed that spontaneous lymphatic contractions in isolated human vessels (thoracic duct and mesenteric lymphatics) maintained under isometric conditions were inhibited by therapeutic concentrations (nanomolar) of the CCB nifedipine while higher than therapeutic concentrations of verapamil (micromolar) were necessary to inhibit activity. Nifedipine also inhibited spontaneous action potentials measured by sharp microelectrodes. Furthermore, noradrenaline did not elicit normal increases in lymphatic vessel tone when maximal constriction was reduced to 29.4 ± 4.9% of control in the presence of 20 nmol l(-1) nifedipine. Transcripts for the L-type calcium channel gene CACNA1C were consistently detected from human thoracic duct samples examined and the CaV1.2 protein was localized by immunoreactivity to lymphatic smooth muscle cells. While human lymphatics ex vivo were highly sensitive to nifedipine, this was not apparent in vivo when nifedipine was compared to placebo in a randomized, double-blinded clinical trial: conversely, lymphatic vessel contraction frequency was increased and refill time was faster despite all subjects achieving target nifedipine plasma concentrations. We conclude that human lymphatic vessels are highly sensitive to nifedipine in vitro but that care must be taken when extrapolating in vitro observations of lymphatic vessel function to the clinical situation, as similar changes in lymphatic function were not evident in our clinical trial comparing nifedipine treatment to placebo.

Origin, trafficking, and intraepithelial fate of gut-tropic T cells.

The small intestine epithelium (SI-Ep) harbors millions of unconventional (γδ and CD4(-) CD8(-) NK1.1(-) TCRαß) and conventional (CD8αß and CD4) T cells, designated intraepithelial lymphocytes (IELs). Here, we identified the circulating pool of SI-Ep-tropic T cells and studied their capacity to colonize the SI-Ep under steady-state conditions in SPF mice. Developmentally regulated levels of α4ß7 endowed recent thymic emigrants (RTEs) of unconventional types with higher SI-Ep tropism than their conventional homologues. SI-Ep-tropic RTEs, which in all lineages emerged naive, homed to the SI-Ep, but this environment was inadequate to stimulate them to cycle. In contrast, conventional and, unexpectedly, unconventional T cells, particularly Vγ7(+) (hallmark of γδ IELs), previously stimulated to cycle in the gut-associated lymphoid tissue (GALT), proliferated in the SI-Ep. Cycling unconventional SI-Ep immigrants divided far more efficiently than their conventional homologues, thereby becoming predominant. This difference impacted on acquisition of high Granzyme B content, which required extensive proliferation. In conclusion, SI-Ep-tropic T cells follow a thymus-SI-Ep or a GALT-SI-Ep pathway, the latter generating highly competitive immigrants that are the sole precursors of cytotoxic IELs. These events occur continuously as part of the normal IEL dynamics.

Nature's necrosis factor when associated with erythrocytes may not only explain the surprises in lung cancer metastases but also suggest target therapy.

Lung cancer is so strategically situated as regards the heart and aorta that it ought to scatter its metastasizing cells far and wide. However, at careful autopsy, instead of giant opportunities, only dwarf deposition may be detected. Indeed, up to seven patterns of its metastases demonstrate surprises. What explains these surprises? Consider the thoracic duct. When this 45 cm long duct was obtained in its entirety, coiled in the Swiss-roll manner, processed in the usual way, and examined on a single microscope slide, necrosis of some transported lung cancer cells was found to be very intimately associated with the erythrocytes. Therefore, let this underlying natural mechanism be named as the "erythrocyte associated necrosis factor", i.e., EANF. It is argued that this Factor operates differently from the suspected roles of both anoikis and stem cells. Accordingly, it is hypothesized that, if intravital video microscopy is used to obtain subsets of both necrotic and lively cancer cells from the thoracic duct of consenting lung cancer patients, the underlying EANF will definitely materialize. It is predicted that the manipulative replication of this Factor in leading centers will ensure progress. In sum, EANF would not only aid in our understanding of the outlined highly inefficient metastatic processes but also effect a breakthrough in the realms of target therapy.

Identification of interstitial Cajal-like cells in the human thoracic duct.

Interstitial Cajal-like cells (ICLCs) are speculated to be pacemakers in smooth muscle tissues. While the human thoracic duct (TD) is spontaneously active, the origin of this activity is unknown. We hypothesized that ICLCs could be present in the TD and using histological techniques, immunohistochemistry and immunofluorescence we have investigated the presence of ICLCs, protein markers for ICLCs and the cellular morphology of the human TD. Transmission electron microscopy was employed to investigate ultrastructure. Methylene blue staining, calcium-dependent fluorophores and confocal microscopy were used to identify ICLCs in live tissue. Methylene blue stained cells with morphology suggestive of ICLCs in the TD. Immunoreactivity localized the ICLC protein markers c-kit, CD34 and vimentin to many cells and processes associated with smooth muscle cells (SMCs): coexpression of c-kit with vimentin or CD34 was observed in some cells. Electron microscopy analysis confirmed ICLCs as a major cell type of the human TD. Lymphatic ICLCs possess caveolae, dense bands, a patchy basal lamina, intermediate filaments and specific junctions to SMCs. ICLCs were ultrastructurally differentiable from other interstitial cells observed: fibroblasts, mast cells, macrophages and pericytes. Lymphatic ICLCs were localized to the subendothelial region of the wall as well as in intimate association with smooth muscle bundles throughout the media. ICLCs were morphologically distinct with multiple processes and also spindle shapes. Confocal imaging with calcium-dependent fluorophores corroborated cell morphology and localization observed in fixed tissues. Lymphatic ICLCs thus constitute a significant cell type of the human TD and physically interact with lymphatic SMCs.

Lymphatic pump treatment augments lymphatic flux of lymphocytes in rats.

BACKGROUND: Lymphatic pump techniques (LPT) are used by osteopathic practitioners for the treatment of edema and infection; however, the mechanisms by which LPT enhances the lymphatic and immune systems are poorly understood. METHODS AND RESULTS: To measure the effect of LPT on the rat, the cisterna chyli (CC) of 10 rats were cannulated and lymph was collected during 4 min of 1) pre-LPT baseline, 2) 4 min LPT, and 3) 10 min post-LPT recovery. LPT increased significantly (p < 0.05) lymph flow from a baseline of 24 ± 5 µl/min to 89 ± 30 µl/min. The baseline CC lymphocyte flux was 0.65 ± 0.21 × 106 lymphocytes/min, and LPT increased CC lymphocyte flux to 6.10 ± 0.99 × 106 lymphocytes/min (p < 0.01). LPT had no preferential effect on any lymphocyte population, since total lymphocytes, CD4+ T cells, CD8+ T cells, and B cell numbers were similarly increased. To determine if LPT mobilized gut-associated lymphocytes into the CC lymph, gut-associated lymphocytes in the CC lymph were identified by staining CC lymphocytes for the gut homing receptor integrin α4ß7. LPT significantly increased (p < 0.01) the flux of α4ß7 positive CC lymphocytes from a baseline of 0.70 ± 0.03 × 105 lymphocytes/min to 6.50 ± 0.10 × 105 lymphocytes/min during LPT. Finally, lymphocyte flux during recovery was similar to baseline, indicating the effects of LPT are transient. CONCLUSIONS: Collectively, these results suggest that LPT may enhance immune surveillance by increasing the numbers of lymphocytes released in to lymphatic circulation, especially from the gut associated lymphoid tissue. The rat provides a useful model to further investigate the effect of LPT on the lymphatic and immune systems.

Syk and Zap-70 function redundantly to promote angioblast migration.

Spleen tyrosine kinase (Syk) plays critical roles in B-cell and T-cell development, the maintenance of vascular integrity, and proper partitioning of the blood vascular and lymphatic vascular system. Here, we utilize the zebrafish as an in vivo system to demonstrate novel roles for Syk and the related kinase Zeta associated protein (Zap-70) in promoting angioblast migration. Partial knockdown of either gene results in early angiogenic delay of the intersegmental vessels, dorsal intersegmental vessel patterning defects, and partial loss of the thoracic duct. Higher dose knockdown of both genes results in little to no angiogenic sprouting of the intersegmental vessels, a phenotype which resembles knockdown of vegfa. Di-phosphorylated ERK, an effector of the vegfa pathway, is also downregulated in the aorta of syk:zap double morphants. Over-expression of syk under the control of a blood-specific or vascular-specific promoter rescues sprouting defects after loss of vegfa. Together these results suggest that syk and zap-70 function redundantly in an early progenitor to promote the migration of intersegmental vessel angioblasts and lymphangioblasts that contribute to the thoracic duct, either downstream of, or in parallel to vegfa.

Methods for lymphatic vessel culture and gene transfection.

OBJECTIVE: To develop the techniques needed for the specific gene/protein targeting transfection experiments in isolated lymphatic vessels, we completed two major tasks: 1) optimize the experimental conditions to maintain the viability of isolated rat lymphatic vessels in culture for sufficiently long periods of time to permit knockdown or overexpression of selected proteins/genes and 2) develop effective transfection protocols for lymphatic muscle and endothelial cells in intact lymphatic vessels without nonspecific impairment of lymphatic contractile function due to the transfection protocol itself. METHODS: Experimental protocols were developed for the maintenance of isolated lymphatic vessels under nonpressurized and pressurized conditions for 3-12 days in culture and for adenoviral gene transfection of the lymphatic muscle and endothelial cells. RESULTS: The data demonstrate the effectiveness of the newly developed experimental protocols for the maintenance of isolated rat mesenteric lymphatic vessels and thoracic duct in culture up to 3-12 days without significant impairment of the parameters of their pumping and effective adenoviral/GFP transfection of lymphatic endothelial and muscle cells in isolated rat mesenteric lymphatic vessels. CONCLUSIONS: These experimental techniques will extend the set of the modern experimental tools available to researchers investigating the physiology of lymphatic function.

Different effects of angiogenesis inhibitors IFN-alpha and TIMP-1 on lymphangiogenesis.

This study was designed to examine the effects of angiogenesis inhibitors IFN-alpha and TIMP-1 on lymphangiogenesis. We cultured lymphatic endothelial (LE) cells from pig thoracic ducts and performed morphological observations using light microscopy, TEM, and confocal microscopy to confirm their lymphatic origin. We tested these cells for growth inhibition by angiogenesis inhibitors IFN-alpha and TIMP-1 using both the scraping line and MTT methods. In addition, we analyzed apoptosis using the Hoechst and Caspase staining methods. Finally, we tested IFN-alpha and TIMP-1 using in vivo inhibitory assays. By morphological observations, all LE cells in vivo and in vitro were found to be of very similar morphology. Both in vitro inhibitory assays of scraping line and MTT showed significant differences for the IFN-alpha treatment (p < 0.01) and no significant difference for TIMP-1. Hoechst and Caspase apoptosis assays demonstrated that IFN-alpha could induce apoptosis of LE cells, and TIMP-1 had little effect. IFN-alpha and TIMP-1 inhibitory in vivo assays showed a lack of healing following IFN-alpha treatment compared to control and TIMP-1 treatment. In summary, these different angiogenesis inhibitors have different effects on lymphangiogenesis. IFN-alpha inhibits proliferation and migration of LE cells in a dose-dependent fashion and induces apoptosis of LE cells while TIMP-1 has no significant inhibitory effects on proliferation, migration, or inducing apoptosis.

Crotoxin alters lymphocyte distribution in rats: Involvement of adhesion molecules and lipoxygenase-derived mediators.

Crotoxin is the main neurotoxic component of Crotalus durissus terrificus snake venom and modulates immune and inflammatory responses, interfering with the activity of leukocytes. In the present work, the effects of crotoxin on the number of blood and lymphatic leukocytes and on lymph nodes and spleen lymphocytes population were investigated. The toxin s.c. administered to male Wistar rats, decreases the number of lymphocytes in blood and lymph circulation and increases the content of B and T-lymphocytes in lymph nodes. These effects were detected 1-2h after treatment. The crotoxin molecule is composed of two subunits, an acidic non-toxic polypeptide, named crotapotin and a toxic basic phospholipase A(2) (PLA(2)). PLA(2), but not crotapotin, decreased the number of circulating blood and lymph lymphocytes. Crotoxin promotes leukocyte adherence to endothelial cells of blood microcirculation and to lymph node high endothelial venules, which might contribute to the drop in the number of circulating lymphocytes. Crotoxin increases expression of the adhesion molecule LFA-1 in lymphocytes. The changes in the expression of the adhesion molecule might contribute, at least in part, for the increased leukocyte adhesion to endothelium. Zileuton, a 5-lipoxygenase inhibitor, blocked the decrease in the number of circulating leukocytes induced by crotoxin and also abolished the changes observed in leukocyte-endothelial interactions, suggesting the involvement of lipoxygenase-derived mediators in the effects of the toxin.

Systemic transmigration of allosensitizing donor dendritic cells to host secondary lymphoid organs after rat liver transplantation.

UNLABELLED: Donor dendritic cell (DC) migration and allosensitization in host secondary lymphoid organs after liver transplantation are ill defined. We used rat models to investigate graft-derived cells and intrahost allosensitization. Liver transplantation induced diffuse blood-borne migration of donor major histocompatibility class II antigen-positive (MHCII(+)) cells and MHCI(+) cells from the graft to host secondary lymphoid organs, not only the spleen, but also lymph nodes and Peyer's patches. The migrated MHCII(+) cells included DCs and some T cells and B cells. The DCs formed clusters with host BrdU(+) cells where they up-regulated CD86(+), and a CD8(+) T cell proliferative response originated within 24 hours after liver transplantation, demonstrating that these DCs can quickly mature and trigger direct allosensitization in host lymphoid organs. Transfer of allogeneic bone marrow cells also induced DC transmigration and a similar host response. In contrast, allogeneic thoracic duct lymph cells contained many fewer transmigrating DCs, and their transfer induced a comparable T cell response but significantly weaker CD8(+) T cell proliferation. Thus, there is a different outcome via the indirect pathway by host DCs that have captured donor alloantigens. CONCLUSION: The rat liver as well as bone marrow contains an immature DC population that can systemically transmigrate through blood vessel walls of the host secondary lymphoid organs, quickly mature, and induce diffuse intrahost CD8(+) T cell responses, which may promote graft rejection.

Mechanotransduction in lymphatic endothelial cells.

Initial lymphatic vessel endothelial cells are connected to the surrounding elastic fibers by fibrillin anchoring filaments that have been hypothesized to favor interstitial fluid drainage in edema pulling apart interendothelial junctions. We hypothesized a biochemical mechanism involving mechanotransduction. This study was designed to verify whether a relation exists between focal adhesion molecules and anchoring filaments and whether they may transduce extracellular forces to the nucleus. We first performed an immunohistochemical study on human skin cryostat sections to evaluate whether fibrillin and alphav-beta3 integrins, FAK and fibrillin, or alphav-beta3 integrins and FAK co-localize in lymphatic endothelium. We observed that integrins and FAK co-localize and that fibrillin filament attachment sites to endothelial cells merge with these molecules. These data may suggest that fibrillin anchoring filaments are connected to endothelial cells through focal adhesions. Mechanotransduction was investigated applying static stretching to bovine thoracic duct segments and lymphatic endothelial cells cultured on elastic membranes and immunohistochemically evaluating the expression of ERK1/2. Under stretching conditions, ERK1/2 labels the nucleus. Western blotting on cultured cells confirmed the presence of ERK1/2 in stretched cells. Based on our data we speculate that anchoring filaments may trigger a focal adhesion-mediated cascade of mechanotransduction toward the nucleus for genetic modulation and thus contribute to endothelial adaptation to interstitial requirements.

Establishment and characterization of conditionally immortalized endothelial cell lines from the thoracic duct and inferior vena cava of tsA58/EGFP double-transgenic rats.

The basic biology of blood vascular endothelial cells has been well documented. However, little is known about that of lymphatic endothelial cells, despite their importance under normal and pathological conditions. The lack of a lymphatic endothelial cell line has hampered progress in this field. The objective of this study has been to establish and characterize lymphatic and venous endothelial cell lines derived from newly developed tsA58/EGFP transgenic rats harboring the temperature-sensitive simian virus 40 (SV40) large T-antigen and enhanced green fluorescent protein (EGFP). Endothelial cells were isolated from the transgenic rats by intraluminal enzymatic digestion. The cloned cell lines were named TR-LE (temperature-sensitive rat lymphatic endothelial cells from thoracic duct) and TR-BE (temperature-sensitive rat blood-vessel endothelial cells from inferior vena cava), respectively, and cultured on fibronectin-coated dishes in HuMedia-EG2 supplemented with 20% fetal bovine serum and Endothelial Mitogen at a permissive temperature, 33 degrees C. A temperature shift to 37 degrees C resulted in a decrease in proliferation with degradation of the large T-antigen and cleavage of poly (ADP-ribose) polymerase. TR-LE cells expressed lymphatic endothelial markers VEGFR-3 (vascular endothelial growth factor receptor), LYVE-1 (a lymphatic endothelial receptor), Prox-1 (a homeobox gene product), and podoplanin (a glomerular podocyte membrane mucoprotein), together with endothelial markers CD31, Tie-2, and VEGFR-2, whereas TR-BE cells expressed CD31, Tie-2, and VEGFR-2, but no lymphatic endothelial markers. Thus, these conditionally immortalized and EGFP-expressing lymphatic and vascular endothelial cell lines might represent an important tool for the study of endothelial cell functions in vitro.

[Functional anatomy of lymphangion].

This paper reviews the results of the studies performed mainly by the Russian anatomists on the functional anatomy of lymphangion as a structural and functional unit of lymphatic vessel. One of the peculiar features of functional anatomy of lymphangion is the heterogeneity of its structures (myocytes, endothelium, blood supply and innervation). The functional heterogeneity of different lymphangions, which depends on the local differences in the combination of lymph flow factors, was demonstrated. The role of lymphatic vessels is discussed on the basis of significance of lymphangion in active lymph transport. This is demonstrated by the multiple correlations between lymphangion structure, rate and type of its contractions, length of thoracic duct lymphangions and contraction type (peristaltic, rhythmic), number of lymphangions of thoracic duct and its type (presence of collaterals), form of individual variability of thoracic duct and its myoarchitecture, body mass and lymphangion volume in various animals and at different stages of ontogenesis.

Establishment of rat lymphatic endothelial cell line.

OBJECTIVE: The objective of the present study was to establish a rat lymphatic endothelial cell line and then to investigate the morphological and immunohistochemical properties of the cells. METHODS: The lymphatic endothelial cells of rat thoracic ducts were isolated enzymatically by trypsin digestion and were cultured in endothelium growth medium (EGM)-2 in an atmosphere of low oxygen (5% O(2), 5% CO(2), and 90% N(2)) or high oxygen (21% O(2), 5% CO(2), and 74% N(2)). RESULTS: The number of the cells cultured in the low-oxygen atmosphere was significantly larger than that obtained in the high-oxygen atmosphere. The cultured cells in the low-oxygen atmosphere showed a monolayer with uniform cobblestone appearance, suggesting the morphological properties of endothelial cells. Factor VIII-related antigen and cell surface carbohydrates (i.e., D-galactose alpha and D-N-acetylgalactosamine alpha) were found on the lymphatic cultured cells. The phagocytosis of 1,1-diocadecyl1-3,3,3',3'-tetramethylindo-carbocyanine perchlorate-labeled acetylated low-density lipoprotein also was observed in the cultured cells. The cytoskeleton protein F-actin was located on the plasma membrane of the cultured cells as circumferential thin bundles and in the cytoplasma as filamentous bundles. CONCLUSIONS: The present study indicates that the choice of EGM-2 as a culture medium and the hypoxic atmosphere ( approximately 5%) enabled us to establish rat lymphatic endothelial cell line.

Focal adhesion molecules expression and fibrillin deposition by lymphatic and blood vessel endothelial cells in culture.

The microfibrils of anchoring filaments, a typical ultrastructural feature of initial lymphatic vessels, consist mainly of fibrillin and are similar to the microfibrils of elastic fibers. As we previously demonstrated, they radiate from focal adhesions of lymphatic endothelium to the perivascular elastic network. Although present in large blood vessels, fibrillin microfibrils have never been detected in blood capillaries. Here we report immunohistochemical evidence that cultured bovine aortic and lymphatic endothelial cells express fibrillin microfibrils. These microfibrils form an irregular web in lymphatic endothelial cells, whereas in blood vessel endothelial cells they are arranged in a honeycomb pattern. Cultured lymphatic and blood vessel endothelial cells also produce focal adhesion molecules: focal adhesion kinase, vinculin, talin, and cytoskeletal beta-actin. Our data suggest that anchoring filaments of initial lymphatic vessels in vivo may be produced by endothelium. Through their connection with focal adhesions, they may form a mechanical anchorage for the thin wall of initial lymphatic vessels and a transduction device for mechanical signals from the extracellular matrix into biochemical signals in endothelial cells. The complex anchoring filaments-focal adhesions may control the permeability of lymphatic endothelium and finely adjust lymph formation to the physiological conditions of the extracellular matrix. The different deposition of fibrillin microfibrils in blood vessel endothelial cells may be related to the necessity of withstanding shear forces. Thus, in our opinion, differences in fibrillin deposition imply a different role of fibrillin in blood vessel and lymphatic endothelium.