Glycolipids of cell surfaces: Isolation of specific sugar sequences using carbohydrate-binding proteins

Proteins that bind carbohydrates can be used to isolate specific sugar sequences from complex mixtures. Free sialyloligosaccharides or sialyloligosaccharides released from gangliosides by ozonolysis and alkaline fragmentation are labeled at their reducing ends by reduction with NaB[³H]₄. After partial separation by column chromatography, oligosaccharide fractions are tested for binding to anti-sialyloligosaccharide antibodies [Smith, D. F., and Ginsburg, V. (1980) J. Biol. Chem.255, 55–59] and cholera toxin by a nitrocellulose filter assay. Oligosaccharides bound by the proteins can be eluted from the filters and further characterized. The method can be used to isolate and identify carbohydrate ligands of cell surfaces.     

Chromosomal localization of zein genes by in situ hybridization in Zea mays

Summary In order to localize the genes coding for zein, the major storage protein of maize endosperm, zein ¹²⁵I-mRNA and ³H-cDNA labelled at high specific activity were used for in situ hybridization on heterozygous interchanges and paracentric inversions of the KYS strain of Zea mays. The analysis of the diplotene-metaphase I microsporocytes indicated the presence of zein structural genes on the long arm of chromosomes 4 and 5, the short arm of chromosome 7 and the distal segment of the long arm of chromosome 10. The two hybridization sites on chromosomes 7 and 10 are found near opaque-2 and opaque-7 loci which are known to regulate zein synthesis. The present data are discussed in relation to results obtained by other authors using genetical mapping of zein genes.     

The human Ia system: Definition and characterization by xenogeneic antisera

The production of xenogeneic anti-Ia serum against Ia antigens in serum has been previously described in the mouse and we now describe the production of xenogeneic anti-human Ia antisera using similar methods. With an indirect resetting technique, Ia-like antibodies were shown to react with the majority of B cells (95%), a subpopulation of T cells, with carbonyl iron adherent cells, and with some E^–Ig^– null cells, but there was no reaction with red cells and platelets. These reactions were the same as those obtained with DRW antisera using cytotoxicity testing. In addition, antigens detected with xenogeneic antisera were also found in serum, where they were found to exist in a low molecular weight, dialyzable form. By the selective removal of different cell surface markers by cocapping, no association could be found with the specifities detected with the xenogeneic anti-Ia antisera and with surface Ig, ₂-microglobulin, or HLA-A and B specificities. Alloantibodies to DRW specificities (but not HLA-A, B specificities) were able to specifically block the binding of the rabbit anti-Ia antibodies to B cells, and reciprocal blocking of rabbit antisera by DRW antibodies was also observed. Several xenogenic antisera were produced by immunizing rabbits with the serum of different individuals. Each antiserum was shown to contain a number of different specificities, as they gave different reaction patterns with different individuals when testing was done both directly and by absorption. These xenogeneic anti-la sera also segregated in a family with HLA-A and B specificities. The detection of a polymorphic antigenic system segregating with the HLA complex, distinct from HLA-A and B specificities, and whose antigens occur predominantly on B cells is therefore described. Because of the similarity of the reactions of the xenogeneic antisera in man to those found in the mouse, and because of the close relationship to the DRW specificities, the system has been provisionally called the H.Ia system.Abbreviations used in this paper AET 2-aminoethyl isothiouronium bromide - ₂-M -2 microglobulin - BSA Bovine serum albumin - H.Ia Human Ia - HuRBC Human red blood cells - Ig Immunoglobulin - Ir Immune response - MHC Major histocompatibility complex - MLR Mixed lymphocyte reaction - NHS Normal human serum - NMS Normal mouse serum - PBL Peripheral blood lymphocytes - PBS Phosphate-buffered saline - RAHIg Rabbit anti-human immunoglobulin - RASIg Rabbit anti-sheep immunoglobulin - RFC Rosette-forming cells - SAHIg Sheep anti-human immunoglobulin - SARIy Sheep anti-rabbit immunoglobulin - SRBC Sheep red blood cells     

Task partitioning in swarms of robots: an adaptive method for strategy selection

Task partitioning is the decomposition of a task into two or more sub-tasks that can be tackled separately. Task partitioning can be observed in many species of social insects, as it is often an advantageous way of organizing the work of a group of individuals. Potential advantages of task partitioning are, among others: reduction of interference between workers, exploitation of individuals?? skills and specializations, energy efficiency, and higher parallelism. Even though swarms of robots can benefit from task partitioning in the same way as social insects do, only few works in swarm robotics are dedicated to this subject. In this paper, we study the case in which a swarm of robots has to tackle a task that can be partitioned into a sequence of two sub-tasks. We propose a method that allows the individual robots in the swarm to decide whether to partition the given task or not. The method is self-organized, relies on the experience of each individual, and does not require explicit communication between robots. We evaluate the method in simulation experiments, using foraging as testbed. We study cases in which task partitioning is preferable and cases in which it is not. We show that the proposed method leads to good performance of the swarm in both cases, by employing task partitioning only when it is advantageous. We also show that the swarm is able to react to changes in the environmental conditions by adapting the behavior on-line. Scalability experiments show that the proposed method performs well across all the tested group sizes.     

In vitro targeting of erythrocytes to cytotoxic T-cells by coupling of Thy-1.2 monoclonal antibody.

A method was explored to develop a general means to target erythrocytes to T-cells in vitro. Mouse erythrocytes were coupled with an anti-Thy-1.2 monoclonal antibody by two methods. Chromic chloride coupling of antibody was preferred to biotinylation. The morphology, osmotic fragility, and the hematological values of treated cells were normal compared with those of control erythrocytes. Antibody-coupled erythrocytes were incubated with cytotoxic T-lymphocytes (CTLL) in vitro at a 20:1 ratio. Approximately 60-70% of the CTLL formed rosettes. The cell mixture was subjected to gradient centrifugation and separated into four fractions. THe rosettes were clearly identified only in the treated group containing anti-Thy-1.2-coupled erythrocytes. No rosettes were found when aspecific monoclonal antibody was coupled to erythrocytes. Examination by scanning and transmission electron microscopy revealed CTLL with 4-5 erythrocytes attached to them but did not show any evidence of membrane fusion. Rosettes of CTLL incubated in vitro proliferated as well as CTLL alone and maintained their dependency on interleukin-2. Targeting of erythrocyte carriers to lymphocytes offers the potential for delivery of molecules directly to the target cell.     

Neuroendocrinology and neurobiology of sebaceous glands

The nervous system communicates with peripheral tissues through nerve fibres and the systemic release of hypothalamic and pituitary neurohormones. Communication between the nervous system and the largest human organ, skin, has traditionally received little attention. In particular, the neuro‐regulation of sebaceous glands (SGs), a major skin appendage, is rarely considered. Yet, it is clear that the SG is under stringent pituitary control, and forms a fascinating, clinically relevant peripheral target organ in which to study the neuroendocrine and neural regulation of epithelia. Sebum, the major secretory product of the SG, is composed of a complex mixture of lipids resulting from the holocrine secretion of specialised epithelial cells (sebocytes). It is indicative of a role of the neuroendocrine system in SG function that excess circulating levels of growth hormone, thyroxine or prolactin result in increased sebum production (seborrhoea). Conversely, growth hormone deficiency, hypothyroidism, and adrenal insufficiency result in reduced sebum production and dry skin. Furthermore, the androgen sensitivity of SGs appears to be under neuroendocrine control, as hypophysectomy (removal of the pituitary) renders SGs largely insensitive to stimulation by testosterone, which is crucial for maintaining SG homeostasis. However, several neurohormones, such as adrenocorticotropic hormone and α‐melanocyte‐stimulating hormone, can stimulate sebum production independently of either the testes or the adrenal glands, further underscoring the importance of neuroendocrine control in SG biology. Moreover, sebocytes synthesise several neurohormones and express their receptors, suggestive of the presence of neuro‐autocrine mechanisms of sebocyte modulation. Aside from the neuroendocrine system, it is conceivable that secretion of neuropeptides and neurotransmitters from cutaneous nerve endings may also act on sebocytes or their progenitors, given that the skin is richly innervated. However, to date, the neural controls of SG development and function remain poorly investigated and incompletely understood. Botulinum toxin‐mediated or facial paresis‐associated reduction of human sebum secretion suggests that cutaneous nerve‐derived substances modulate lipid and inflammatory cytokine synthesis by sebocytes, possibly implicating the nervous system in acne pathogenesis. Additionally, evidence suggests that cutaneous denervation in mice alters the expression of key regulators of SG homeostasis. In this review, we examine the current evidence regarding neuroendocrine and neurobiological regulation of human SG function in physiology and pathology. We further call attention to this line of research as an instructive model for probing and therapeutically manipulating the mechanistic links between the nervous system and mammalian skin.