A comparative study of cytoplasmic granules imaged by the real-time microscope, Nile Red and Filipin in fibroblasts from patients with lipid storage diseases.

Cytoplasmic granules in fibroblasts, visualized without stains, or labelled with Nile red, Filipin, or anti-LAMP-1 (lysosome-associated membrane protein 1), were imaged using the real-time microscope (RTM). New advances in light microscope technology were applied to detect cytoplasmic granules (RTM-visible granules) and characterize them by imaging contrast, size, shape, cellular distribution, composition, motion dynamics and quantity. Appearing as solid spheroids or ring structures, the majority of the RTM-visible granules contained Nile-red labelled neutral lipids. A smaller subpopulation, appearing dimmer, with less imaging contrast, contained Filipin-labelled free cholesterol. Most lipid storage granules have a diameter ranging from 0.3 mum to 0.6 mum, with a small population measuring up to 1 mum. They typically clustered in the perinuclear region and displayed relatively small oscillatory motion. Immunofluorescence based on LAMP-1 labelling highlighted granular structures that were distinct and separate from RTM-visible granules and other structures in the light modality of the microscope. RTM-visible granules were associated with disease phenotypes that have increased cellular neutral lipid stores corresponding to the Nile red-labelled droplets (e.g. triacylglycerides, cholesterol esters). As predicted, the fibroblast strains with a defect resulting in Wolman disease, when compared to control samples, consistently had RTM-visible granules, higher in imaging contrast and with larger diameters, that were labelled with Nile red, and also an increased frequency of Filipin-cholesterol complexes. By comparison, in fibroblasts where the lipid storage is less evident (Gaucher and Farber diseases) or from GM(1) gangliosidosis, where the primary storage substances are oligosaccharides, fewer and smaller RTM-visible granules were observed. In some cases, changes in contrast and morphology in the unstained cytoplasmic compartments were more evident than in the labelled structures. In summary, applying the RTM imaging system to fibroblasts enables differences between the various disease types to be seen and, in specific examples, a unique phenotype can be readily discerned.

An approach to the unification of suppressor T cell circuits: a simplified assay for the induction of suppression by T cell-derived, antigen-binding molecules (T-ABM).

A system is presented in which the in vitro response to sheep red blood cells (SRBC) can be regulated using antigenic determinants coupled to SRBC and T cell-derived antigen-binding molecules (T-ABM) directed against the coupled determinants. T suppressor-inducer factors (TsiF's) are composed of two molecules, one of which is a T-ABM and one which bears I-J determinants (I-J+ molecule). Using two purified T-ABM which have not previously been shown to have in vitro activity, we produced antigen-specific TsiF's which were capable of inducing the suppression of the anti-SRBC response. Suppression was found to require both the T-ABM and the I-J+ molecule, SRBC conjugated with the antigen for which the T-ABM was specific, and a population of Ly-2+ T cells in the culture. Two monoclonal TsiF (or TsF1) were demonstrated to induce suppression of the anti-SRBC response in this system, provided the relevant antigen was coupled to the SRBC in culture. The results are discussed in terms of the general functions of T-ABM in the immune system. This model will be useful in direct, experimental comparisons of the function of T-ABM and suppressor T cell factors under study in different systems and laboratories.

Phototherapy units: comparison of fluorescent ultraviolet B and ultraviolet A units with a high-pressure mercury system.

Comparison in ultraviolet (UV) dosimetry is reported for three different phototherapy machines. Two of the machines used UV-emitting fluorescent tubes in a standard upright cabinet formation. One of these machines was equipped with predominantly UVB-emitting fluorescent tubes and the other with predominantly UVA-emitting tubes. The third machine consisted of a series of vertically mounted high-pressure mercury halide lamps equipped with two different filters for selection of wavelengths between 295 and 400 nm or 320 and 400 nm. The horizontal UV output of the mercury halide and UVB fluorescent units was reduced between the UV-emitting areas, and it is advised that patients rotate when using these units. It was determined that the vertical uniformity and intensity of UV emission was superior in the mercury halide unit compared with the fluorescent tubed units.

A helper T cell clone produces an antigen-specific molecule (T-ABM) which functions in the induction of suppression.

Among Ly-1+,2-T cells there appears to be two independent modes of antigen recognition. Helper and cytotoxic Ly-1 T cells recognize antigen only in the context of I region products whereas regulatory T cells, such as T suppressor inducer cells, produce antigen-specific, antigen-binding molecules (T-ABM). These T-ABM often have been found to form a part of biologically active, antigen-specific regulatory factors. A number of environmental conditions effect whether a foreign antigen will produce a positive response leading to immunity or a negative one leading to tolerance. Many of the conditions which favor the induction of suppressor T cells simultaneously preclude the proper interaction of antigen presenting cells with helper T cells. This parallel led us to ask whether helper T cells perform at least two, apparently opposite functions: a) under conditions favoring immunity helper T cells produce lymphokines to activate immune effector cells, and b) under conditions favoring suppression they produce molecules which function in suppressor cell induction. Therefore, this question relates to the mechanisms by which an immune response is switched into either a positive (help) or negative (suppressive) track. In addition, it begins to address the relationship between the different modes of antigen recognition exhibited by helper T cells vs. T suppressor inducer cells (see above). To explore this problem we employed an antigen-specific, I-Ak restricted helper T cell clone as the purest available source of helper T cells. We presented antigen to the cloned T cells under conditions which favor suppression rather than help (for example, by ultraviolet irradiation of the antigen-presenting cells) and collected supernatants 48 hrs later. The supernatants were then examined for activity in a functional assay for antigen-specific suppressor factors. Our results indicate that under conditions favoring suppression, a T-ABM was produced which functioned in the antigen-specific induction of suppression in vitro. The T-ABM had the same antigen specificity as that exhibited by the helper T cell and was therefore probably derived from the clone. This observation introduces the possibility that the interaction between antigen-presenting cells and helper T cells is a crucial decision point in the immune response which can lead to either immunity or suppression. The latter would be achieved through the production, by helper T cells, of an antigen-specific component of T suppressor inducer factor (i.e., the T-ABM). The possible relationship between T-ABMs and the T cell receptor is discussed.

Serologic heterogeneity in I-J determinants associated with functionally distinct T cell regulatory factors.

Information transfer among regulatory T cell subsets is mediated by biologically active T cell factors. Many of these factors are comprised of two molecules: one that binds antigen, and another that is I-J+ and determines the self recognition capability of the factor (I-J molecule). In the in vitro response to sheep red blood cells, we used three functionally distinct I-J+ factors to study the relationship between polymorphic I-J determinants and the biological activity of these factors. Our study shows that several monoclonal I-J antibodies react with I-J molecules associated with T suppressor-inducer factor (TsiF) and T suppressor-effector factor (TseF), but not with T contrasuppressor inducer factor (TcsiF). In contrast, a different set of monoclonal I-J reagents reacts with TcsiF but not TsiF or TseF. Finally, some monoclonal I-J antibodies distinguish between I-J molecules associated with TsiF and TseF. Thus anti-I-J reagents differentially react with I-J determinants on regulatory factors, and this differential pattern of reactivity correlates with the functional activity of the factors. The possible relationship between I-J heterogeneity and the biological function of I-J molecules in regulation is discussed.

Information transfer between T cell subsets is directed by I-J+ antigen nonspecific molecules.

T cell antigen-specific suppressor factors (TsF) consist of two distinct polypeptide chains: one that binds antigen (ABM) and one that bears I-J region markers (I-J+ chain). We studied the functional role of these two molecules in delivering the biologic message of suppression to its appropriate target cell. Two different biologically active TsF were used in these studies: TsiF, a T suppressor-inducer factor consisting of an ABM secreted by Ly-1 T cells (Ti-ABM) and an I-J+ subfactor secreted by Ly-1 T cells (I-Ji), which initiates the suppressor circuit by inducing an Ly-1,2 T cell; and TseF, a T suppressor-effector factor consisting of an ABM secreted by Ly-2 T cells (Te-ABM) and an I-J+ subfactor secreted by Ly-1 T cells (I-Je), which delivers the biologic message of suppression to the T helper (TH) cell. In both TsF, the ABM and I-J+ chain are noncovalently associated and can be easily separated. Both molecules must be present, however, for biologic activity of the TsF to be manifest. We studied the role of each chain in delivering these biologically active messages by constructing "hybrid" factors made from mixing the ABM from TsiF with I-J+ chains from either TsiF or TseF and determined which of these chains could reconstitute functional TsiF activity. Likewise, we mixed the AMB from TseF with I-J+ chains of TsiF or TseF to determine which I-J+ chain could reconstitute TseF activity. We found that I-J+ chain from TsiF (I-Ji) can reconstitute ABM from TsiF to form a functional TsiF capable of inducing suppression but cannot reconstitute ABM from TseF to form a functional TsiF capable of suppressing the activity of TH cells. Likewise, the addition of I-J+ chain from TseF to ABM from TseF can reconstitute its ability to suppress TH responses, but I-J+ chain from TsiF plus ABM from TseF has no effect on these TH cell responses. We did find, however, that this hybrid TsF composed of the ABM from TseF and the I-J+ chain from TsiF is capable of suppressing the Ly-1,2 Ttrans cell, the cell normally induced by the ABM + I-J+ suppressor inducer complex from T suppressor-inducer cells (TsiF).(ABSTRACT TRUNCATED AT 400 WORDS)

Igh variable region-restricted T cell interactions. Genetic restriction of an antigen-specific suppressor inducer factor is imparted by an I-J+ antigen-nonspecific molecule.

Immunized Ly-1 T cells secrete an antigen-specific molecule that will induce Ly-2+ T cells to express suppressive activity. In two separate systems, factors that suppress the primary anti-sheep erythrocyte (SE) plaque-forming cell response of spleen cells in vitro (Ly-1 TsiF) or the contact sensitivity of azobenzenearsonate (ABA)-TsF1 consist of two macromolecules, one which binds antigen and is IJ-, the other which is I-J+ and does not bind antigen. Both of these chains are required for the factor's biological activity. These factors show a genetic restriction in their ability to induce suppression that is linked to the variable region of the Ig heavy chain gene complex (Igh-V). The I-J+ chain from the ABA-specific TsF1 could replace the I-J+ chain needed by the SE-specific Ly-1 TsiF for biological activity. Mixtures of ABA-binding chain with I-J+ material obtained from the SE-specific Ly-1 TsiF had no effect on the primary anti-SE response in vitro. In mixtures of SE antigen-binding chain from Ly-1 TsiF and I-J+ material from the ABA-specific TsF1, it is the I-J+ molecule that determined the factor's Igh-V restriction. Thus, the antigen-combining site of the factor determined the antigen specificity of this factor but is irrelevant to its Igh-V-linked genetic restrictions. The implications of these results for the idiotype network hypothesis are discussed.

Discrimination of 2 types of suppressor T cells by cell surface phenotype and by function: the ability to regulate the contrasuppressor circuit.

Contrasuppression is an immunoregulatory T cell activity that augments immune responses by interfering with suppressor T cell function. Since contrasuppression appears to play a role in autoimmunity, hyperimmunity, and recovery from induced general unresponsiveness (such as appears following burn trauma), an understanding of how contrasuppression is controlled may have profound implications for understanding immune regulation as well as for manipulating immune responses. Further, since inhibition of contrasuppressor function would appear as suppression, identifying cells able to perform this function would describe at least two modes of suppression in immune regulation, and allow a synthesis of regulatory T cell circuits not previously possible. In the studies described, we have sought to identify distinct lymphocyte subpopulation(s) having the specialized activity of regulating the cells of the contrasuppressor circuit. Two experimental systems have been previously examined. In the first, cells regulating the appearance of contrasuppressor effector T cells generated in cultures of neonatal spleen cells have been characterized. In the second, cells producing a contrasuppressor inducer factor derived from antigen-stimulated Ly-2 T cells have been studied, as well as their cellular targets. Regulation of contrasuppressor T cell activation in both systems by various cell populations was characterized by means of antisera against cell surface differentiation antigens. Our studies demonstrate that an I-J+, Ly-1,2 cell whose activity is not apparent before 1-2 weeks postbirth appears in adult T cell populations and regulates the generation of contrasuppressor cells in neonatal cell cultures. This adult cell can be removed with a low concentration of a monoclonal anti-T cell reagent. Removal of these T cells from adult populations allows the generation of an adult contrasuppressor effector cell indistinguishable from the one found in neonatal spleen by means of the spleen cell culture system. Adult antigen-primed Ly-2 T cells, used for the production of suppressor factor, contain a cell sensitive to the monoclonal antibody that normally prevents the dominance of contrasuppression over suppression. We refer to this cell as a "level 2" suppressor because after its removal contrasuppression is found, and after this contrasuppression is eliminated by selective antiserum treatment suppression is observed. This indicates that a "level 1" suppressor exists, but effector factors mediating this suppression are significantly more susceptible to contrasuppression than are those of "level 2" suppressor cells. Our findings demonstrate two types of suppressor cell circuits