Proteinuria and lipoprotein lipase activity in Miniature Schnauzer dogs with and without hypertriglyceridemia.

Spontaneous hyperlipidemia in rats causes glomerular disease. Idiopathic hypertriglyceridemia (HTG) is prevalent in Miniature Schnauzers, but its relationship with proteinuria is unknown. Decreased activity of major lipid metabolism enzymes, lipoprotein lipase (LPL) and hepatic lipase (HL), may play a role in the cyclic relationship between hyperlipidemia and proteinuria. These enzymes have also not been previously investigated in Miniature Schnauzers. The aims of this study were to determine the relationship between HTG and proteinuria in Miniature Schnauzers and to measure LPL and HL activities in a subset of dogs. Fifty-seven Miniature Schnauzers were recruited (34 with and 23 without HTG). Fasting serum triglyceride concentrations and urine protein-to-creatinine ratios (UPC) were measured in all dogs, and LPL and HL activities were determined in 17 dogs (8 with and 9 without HTG). There was a strong positive correlation between triglyceride concentration and UPC (r = 0.77-0.83, P < 0.001). Proteinuria (UPC ≥ 0.5) was present in 60% of dogs with HTG and absent from all dogs without HTG (P < 0.001). Proteinuric dogs were not azotemic or hypoalbuminemic. Dogs with HTG had a 65% reduction in LPL activity relative to dogs without HTG (P < 0.001); HL activity did not differ. Proteinuria occurs with HTG in Miniature Schnauzers and could be due to lipid-induced glomerular injury. Reduced LPL activity may contribute to the severity of HTG, but further assay validation is required.

Contribution of hepatic lipase, lipoprotein lipase, and cholesteryl ester transfer protein to LDL and HDL heterogeneity in healthy women.

Hepatic lipase (HL) and cholesteryl ester transfer protein (CETP) have been independently associated with low density lipoprotein (LDL) and high density lipoprotein (HDL) size in different cohorts. These studies have been conducted mainly in men and in subjects with dyslipidemia. Ours is a comprehensive study of the proposed biochemical determinants (lipoprotein lipase, HL, CETP, and triglycerides) and genetic determinants (HL gene [LIPC] and Taq1B) of small dense LDL (sdLDL) and HDL subspecies in a large cohort of 120 normolipidemic, nondiabetic, premenopausal women. HL (P<0.001) and lipoprotein lipase activities (P=0.006) were independently associated with LDL buoyancy, whereas CETP (P=0.76) and triglycerides (P=0.06) were not. The women with more sdLDL had higher HL activity (P=0.007), lower HDL2 cholesterol (P<0.001), and lower frequency of the HL (LIPC) T allele (P=0.034) than did the women with buoyant LDL. The LIPC variant was associated with HL activity (P<0.001), HDL2 cholesterol (P=0.034), and LDL buoyancy (P=0.03), whereas the Taq1B polymorphism in the CETP gene was associated with CETP mass (P=0.002) and HDL3 cholesterol (P=0.039). These results suggest that HL activity and HL gene promoter polymorphism play a significant role in determining LDL and HDL heterogeneity in healthy women without hypertriglyceridemia. Thus, HL is an important determinant of sdLDL and HDL2 cholesterol in normal physiological states as well as in the pathogenesis of various disease processes.

PLTP activity in premenopausal women. Relationship with lipoprotein lipase, HDL, LDL, body fat, and insulin resistance.

Plasma phospholipid transfer protein (PLTP) is thought to play a major role in the facilitated transfer of phospholipids between lipoproteins and in the modulation of high density lipoprotein (HDL) particle size and composition. However, little has been reported concerning the relationships of PLTP with plasma lipoprotein parameters, lipolytic enzymes, body fat distribution, insulin, and glucose in normolipidemic individuals, particularly females. In the present study, 50 normolipidemic healthy premenopausal females were investigated. The relationships between the plasma PLTP activity and selected variables were assessed. PLTP activity was significantly and positively correlated with low density lipoprotein (LDL) cholesterol (r(s) = 0.53), apoB (r(s) = 0.44), glucose (r(s) = 0.40), HDL cholesterol (r(s) = 0.38), HDL(3) cholesterol (r(s) = 0.37), lipoprotein lipase activity (r(s) = 0.36), insulin (r(s) = 0.33), subcutaneous abdominal fat (r(s) = 0.36), intra-abdominal fat (r(s) = 0.29), and body mass index (r(s) = 0.29). HDL(2) cholesterol, triglyceride, and hepatic lipase were not significantly related to PLTP activity. As HDL(2) can be decreased by hepatic lipase and hepatic lipase is increased in obesity with increasing intra-abdominal fat, the participants were divided into sub-groups of non-obese (n = 35) and obese (n = 15) individuals and the correlation of PLTP with HDL(2) cholesterol was re-examined. In the non-obese subjects, HDL(2) cholesterol was found to be significantly and positively related to PLTP activity (r(s) = 0.44). Adjustment of the HDL(2) values for the effect of hepatic lipase activity resulted in a significant positive correlation between PLTP and HDL(2) (r(s) = 0.41), indicating that the strength of the relationship between PLTP activity and HDL(2) can be reduced by the opposing effect of hepatic lipase on HDL(2) concentrations. We conclude that PLTP-facilitated lipid transfer activity is related to HDL and LDL metabolism, as well as lipoprotein lipase activity, adiposity, and insulin resistance.

Effect of lipid transfer proteins on lipoprotein lipase induced transformation of VLDL and HDL.

Lipoprotein lipase-induced lipolysis of human plasma VLDL usually does not yield a complete conversion of VLDL to LDL due to insufficient loss of surface and core lipids and apolipoprotein E. In order to assess the role of lipid transfer proteins in this process human VLDL and apo E free HDL, in approximately physiologic proportions, and with sufficient albumin to bind all released fatty acids, were subjected to 90% lipolysis of triglycerides in 2 h by lipoprotein lipase in the presence or absence of partially purified human cholesteryl ester and phospholipid transfer proteins. Lipoprotein lipase caused a partial transfer of VLDL unesterified cholesterol (16%) and phospholipid (11%), apo E (19%) and almost complete transfer of apo CII and CIII to HDL. VLDL remnants possessed excess apo E and surface and core lipids when compared to plasma LDL, and densities ranging from that of VLDL/IDL to LDL. With addition of the lipid transfer proteins to the lipolysis incubation there was an increased transfer of phospholipid and unesterified cholesterol (2-fold) and apo E (1.6-fold) to HDL over that for lipoprotein lipase incubations. The source of transferred material was primarily from remnants which isolated in the LDL density range in lipoprotein lipase incubations. This transfer resulted in LDL-like particles which had a smaller particle size but lighter density compared to those in lipoprotein lipase incubation. Transfer of cholesteryl esters to VLDL from HDL in exchange for triglyceride was absent or substantially reduced in incubations containing lipoprotein lipase and lipid transfer proteins compared to incubations with only lipid transfer proteins. It is concluded that during rapid lipolysis lipid transfer proteins promote the loss of phospholipid, unesterified cholesterol and apo E from VLDL remnants but do not promote the transfer of cholesteryl ester from HDL to VLDL.

Influence of lipoprotein lipase and hepatic lipase on the transformation of VLDL and HDL during lipolysis of VLDL.

In order to study the relative effects of lipolytic enzymes on the removal of lipids and apolipoproteins, in particular apolipoprotein (apo) E and cholesteryl ester, from human very low density lipoprotein (VLDL) during its conversion to product lipoproteins, the action of lipoprotein lipase (LPL) and the combined action of lipoprotein lipase and hepatic lipase (HL) were studied in the presence of physiological proportions of high density lipoprotein (HDL) (10 mg protein), VLDL (2 mg protein) and albumin in an amount sufficient for the binding of all released fatty acids. The HDL used in the incubation was free of apo E in order to facilitate assessment of apo E transfer from VLDL to HDL. The redistribution of lipid and apolipoprotein mass and the movement of labeled cholesteryl ester from VLDL to other lipoprotein fractions was assessed by density gradient ultracentrifugation. Following 90%-95% lipolysis of VLDL triglycerides by rat heart LPL in 2 h, there was an almost complete transfer of apo C-II and apo C-III to HDL but only 20% of VLDL apo E was transferred to HDL. There was significant augmentation of HDL unesterified cholesterol and phospholipid mass during LPL action despite a substantial overall phospholipid hydrolysis (30%). The transfer of cholesteryl ester mass to HDL was variable (0%-13%) with a mean transfer of 7% of VLDL cholesteryl ester. Transfer of labeled VLDL cholesteryl ester to HDL was 3%-6%. A considerable amount of the VLDL lipid mass appeared in the light fraction of the low density lipoprotein (LDL) region, but a substantial amount remained in the VLDL/intermediate density lipoprotein (IDL) region. The post-lipolysis particles that were isolated in the VLDL-LDL density range were larger than LDL and contained a high ratio of surface lipids relative to core lipids as compared to plasma LDL. The inclusion of human HL with LPL did not alter the redistribution of apolipoproteins proteins or lipids from VLDL to LDL or to HDL. The major effect of HL, relative to that observed with LPL alone, was a marked hydrolysis of HDL triglycerides (68%). Despite the combined action of LPL and HL on VLDL in the presence of HDL and over 90% lipolysis of triglycerides, a major portion of residual VLDL mass remained in fractions lighter than normal LDL density and retained apo E. It is concluded that lipoprotein lipase of LPL in combination with HL are ineffective in bringing about the complete conversion of plasma VLDL to LDL. Lipoprotein lipase was effective in substantially augmenting the HDL mass including cholesteryl while the major effect of HL was the selective hydrolysis of HDL triglycerides.

Development of a density gradient ultracentrifugation technique for the resolution of plasma lipoproteins which avoids apo E dissociation.

A density gradient ultracentrifugation technique for analyzing and isolating plasma lipoproteins was developed that was simple to set up, allowed for the isolation of the plasma lipoproteins in one centrifugal spin, and avoided the dissociation of apolipoprotein E from high-density lipoprotein (HDL) which can occur when plasma is subjected to ultracentrifugation at high concentrations of salt. The density gradient emphasized the resolution of the HDL density region while still enabling the separation of low-density and very low-density lipoprotein.

CD66 identifies the biliary glycoprotein (BGP) adhesion molecule: cloning, expression, and adhesion functions of the BGPc splice variant.

Within the hematopoietic lineage, the monoclonal antibody (MoAb) CD66 reacts with cells of the granulocyte lineage, but not with the majority of progenitor cells from human bone marrow. Our previous studies have shown that CD66 binds specifically to at least three carcinoembryonic antigen (CEA) superfamily members, ie, CEA itself, nonspecific cross-reacting antigen (NCA), and CGM1, but not to CGM6 (NCA-95). In this report, we show that CD66 will also identify the biliary glycoproteins (BGP). A full-length cDNA for the BGPc molecule (a cytoplasmic splice variant of BGPa) was isolated by expression cloning using the CD66 MoAbs. This protein has an identical extracellular and transmembrane sequence to BGPa with one N-terminal IgV like domain, three IgC-like extracellular domains (A1, B1, and A2), plus a transmembrane domain, but the cytoplasmic domain is spliced by 53 nucleotides. Reverse transcriptase-polymerase chain reaction experiments show that this splice variant can be detected in colonic carcinoma cell lines, in primary colonic adenocarcinomas, and in myeloid and B-cell lines to varying degrees. Quantitative analyses of BGPc RNA expression by RNase protection indicate that abundant levels occur only in the colonic, but not in the hematopoietic, cell lines tested. Studies presented here show that BGPc mediates homotypic adhesion and suggest that the cytoplasmic splicing does not alter the initial homotypic adhesion properties of BGPa.

Adhesion receptors are differentially expressed on developing thymocytes and epithelium in human thymus.

The thymic microenvironment consists of a network of interrelated cells of epithelial, fibroblastic, endothelial, and hemopoietic origin. Within this environment, the development of specific T-lymphocyte subpopulations partially depends on the selective interaction of T-cell precursors with such cells. Human thymic epithelial cell strains, generated with a defective retroviral vector containing simian virus 40 (SV40) large T antigen and the neomycin resistance gene or by transfection with an SV40 plasmid defective in the origin of replication, provide useful tools for understanding the mechanisms contributing to the control of T-cell maturation. Because interepithelial, epithelial-macrophage, and lymphocyte-epithelial cell interactions are important for thymocyte differentiation, the distribution of integrin and nonintegrin adhesion receptors on these cells and on developing thymocytes in vivo and in vitro has been examined in detail. Our results indicate that the transformed human thymic epithelial cell strains express the common very late antigen (VLA)-beta 1 receptor and unique alpha chains VLA-2, VLA-3, and VLA-6. The cells are also positive for LFA-3 and ICAM-1 and weakly express beta 3, beta 4, and VNR alpha. They do not express the Leu-cellular adhesion molecules (CAM). This phenotypic profile on cultured thymic epithelium generally corresponds to the distribution of integrin and other receptor molecules on thymic epithelial cells in tissue sections. The majority of thymocytes also express the integrin VLA-beta 1 and -beta 2 chains as well as VLA-4, VLA-6, and LFA-1 alpha(L). Three-color flow cytometric analyses show differential levels of expression of these adhesion receptors on human thymocyte subsets. Taken together with the immunohistochemical localization of extracellular matrix molecules, these studies suggest that both the distribution of receptor-ligand pairs and the level of expression of adhesion molecules may influence T-cell development within the thymus.

Human thymic epithelial cells are frequently transformed by retroviral vectors encoding simian virus 40.

The thymic microenvironment contains a mixture of phenotypically distinct epithelial cells of varied functions, some of which are unknown. In an attempt to understand their relevance to T cell differentiation in the thymus, human thymic epithelial cell clones from both fetal (SM3-SM5) and postnatal (SM6) thymus were produced by using a defective recombinant retroviral vector encoding the simian virus 40 large T antigen and the neomycin resistance gene. The presence of keratins 8 and 18, desmosomes, and tonofilaments confirmed the epithelial origin of the cell strains. The cells expressed Thy-1 and HLA-Class I at high levels, showed weak-expression antigens defined by TE3B and A2B5, and low to negligible levels of the MR19-defined molecule. When compared with the phenotype of thymic epithelial cells in situ, the cell strains appear to be derived from neuroendocrine components in the outer cortical region of the human thymus. The use of retroviral vectors to transform human thymic epithelium was considerably more efficient than transfection with a plasmid carrying the origin of replication-defective SV40 large T gene. In the latter case, only two cell strains with subcapsular epithelial phenotypes were derived from fetal thymus. With the retroviral vectors, epithelial cell strains could, for the first time, be generated from human postnatal thymus as well as from fetal thymus.

Detection of additional JH/BCL2 translocations in follicular lymphoma.

In vitro enzymatic amplification and direct sequencing were used to detect and characterize t(14;18) recombination junctions in peripheral blood and bone marrow mononuclear cell preparations from patients with follicular lymphoma in remission. Samples from 24/44 patients were found to be positive for translocations involving the major breakpoint region of the BCL2 gene. In samples from seven patients two distinct t(14;18) translocations were shown to be present simultaneously; in one case the second translocation involved the minor cluster region of the BCL2 gene. Biopsy tissue obtained earlier in the course of the disease was available from five of these patients and was shown to contain one of the translocations in each case, but both translocations in only one. Further remission blood and bone marrow samples from the group were also examined. This led to the detection of both translocations in separate samples obtained at different times in a total of four out of the seven cases. In two of the remaining three patients the second translocation could not be amplified from further samples, but in both cases the search led to the identification of a third translocation, again only detectable in a single sample. These findings demonstrate that JH/BCL2 translocations can occur more than once during the course of follicular lymphoma. They suggest that biclonal follicular lymphoma may be more common than has previously been recognized but also raise the possibility that the translocation arises sporadically in the normal lymphoid cells of this group of patients.

CD66 identifies a neutrophil-specific epitope within the hematopoietic system that is expressed by members of the carcinoembryonic antigen family of adhesion molecules.

Preliminary results from the IVth Leucocyte Culture Conference have classified the monoclonal antibody (MoAb), YTH 71.3.2, as CD66. Two other MoAbs, YPC 2/12.1 and CE6/2D3.1, share a common cellular specificity, reacting with cells of the neutrophil series and colonic epithelium. The YTH 71.3.2 and CE6/2D3.1 MoAbs both recognize a similar CD66 defined epitope that is distinct from that identified by YPC 2/12.1. By Western blotting, these antibodies react with different molecular species from cells of different lineages. The antibodies identify 50- to 55-Kd, 80- to 100-Kd, and 130- to 200-Kd components present in a semi-purified carcinoembryonic antigen (CEA) preparation from colonic adenocarcinomas and a 90- to 130-Kd molecule from HL-60 cells. With the colonic cell line, LS174T, YPC2/12.1 stains diffuse bands of 160 to 200 Kd and 90 to 130 Kd with equal intensity, whereas the binding of CE6/2D3.1 and YTH 71.3.2 is biased toward the lower molecular weight set of molecules. Remarkably, all three antibodies recognize CEA-related molecules. Defined analyses using HeLa cells transfected with CEA, NCA(NCA-50/90), and CGM6(NCA-95) cDNAs show that the three MoAbs identify CEA to varying degrees. While YTH 71.3.2 and CE6/2D3.1 also bind to NCA-50/90, YPC 2/12.1 recognizes an epitope expressed by both the NCA-50/90 and NCA-95 molecular species.