Immunotherapy of human colon cancer by antibody-targeted superantigens

T lymphocytes generally fail to recognize human colon carcinomas, suggesting that the tumour is beyond reach of immunotherapy. Bacterial superantigens are the most potent known activators of human T lymphocytes and induce T cell cytotoxicity and cytokine production. In order to develop a T-cell-based therapy for colon cancer, the superantigen staphylococcal enterotoxin A (SEA) was given tumour reactivity by genetic fusion with a Fab fragment of the monoclonal antibody C242 reacting with human colon carcinomas. The C242Fab-SEA fusion protein targeted SEA-reactive T cells against MHC-class-II-negative human colon carcinoma cells in vitro at nanomolar concentrations. Treatment of disseminated human colon carcinomas growing in humanized SCID mice resulted in marked inhibition of tumour growth and the apparent cure of the animals. Therapeutic efficiency was dependent on the tumour specificity of the fusion protein and human T cells. Immunohistochemistry demonstrated massive infiltration of human T cells in C242Fab-SEA-treated tumours. The results merit further evaluation of C242Fab-SEA fusion proteins as immunotherapy in patients suffering from colon carcinoma.     

Sulphydryl groups of (Na+ + K+)-ATPase from rectal glands of Squalus acanthias: Detection of ligand-induced conformational changes

1. Modification of the Class II sulphydryl groups on the (Na⁺ + K⁺)-ATPase from rectal glands of Squalus acanthias with N-ethylmaleimide has been used to detect conformational changes in the protein. The rates of inactivation of the enzyme and the incorporation of N-ethylmaleimide depend on the ligands present in the incubation medium. With 150 mM K⁺ the rate of inactivation is largest (k₁ = 1.73 mM^?1 · min^?1) and four SH groups per α-subunit are modified. The rate of inactivation in the presence of 150 mM Na⁺ is smaller (k₁ = 1.08 mM^?1 · min^-1) but the incorporation of N-ethylmaleimide is the same as with K⁺. 2. ATP in micromolar concentrations protects the Class II groups in the presence of Na⁺ (k₁ = 0.08 mM^?1 · min^?1 at saturating ATP) and the incorporation id drastically reduced. ATP in millimolar concentrations protects the Class II groups partially in the presence of K⁺ (k₁ = 1.08 mM^?1 · min^?1) and three SH groups are labelled per α subunit. 3. The K⁺ -dependent phosphatase is inhibited in parallel to the (Na⁺ + K⁺)-ATPase under all conditions, and the ligand-dependent incorporation of N-ethylmaleimide was on the α-subunit only. 4. It is shown that the difference between the Na⁺ and K⁺ conformations sensed with N-ethylmaleimide depends on the pH of the incubation medium. At pH 6 there is a very small difference between the rates of inactivation in the presence of Na⁺ and K⁺, but at higher pH the difference increases. It is also shown that the rate of inactivation has a minimum at pH 6.9, which suggests that the conformation of the enzyme changes with pH. 5. Modification of the Class III groups with N-ethylmaleimide-whereby the enzyme activity is reduced from about 16% to zero-shows that these groups are also sensitive to conformational changes. As with the Class II groups, ATP in micromolar concentrations protects in the presence of Na⁺ relative to Na⁺ or K⁺ alone. ATP in millimolar concentrations with K⁺ present increases the rate of inactivation relative to K⁺ alone, in contrast to the effect on the Class II groups. 6. Modification of the Class II groups with a maleimide spin label shows a difference between Class II groups labelled in the presence of Na⁺ (or K⁺) and Class II groups labelled in the presence of K + ATP, in agreement with the difference in incorporation of N-ethylmaleimide. The spectra suggest that the SH group protected by ATP in the presence of K⁺ is buried in the protein. 7. The results suggest that at least four different conformations of the (Na⁺ + K⁺)-ATPase can be sensed with N-ethylmaleimide: (i) a Na⁺ form of the enzyme with ATP bound to a high-affinity site (E₁-Na-ATP); (ii) a Na⁺ form without ATP bound (E₁-Na); (iii) a K⁺ form without ATP bound (E₂-K); and (iv) an enzyme form with ATP bound to a low-affinity site in the presence of K⁺, probably and E₁-K-ATP form.     

Variations in the activity of microsomal palmitoyl-CoA hydrolase in mixed micelle solutions of palmitoyl-CoA and non-ionic detergents of the triton X series

The kinetics of palmitoyl-CoA hydrolase were influenced by both the availability of the substrate and formation of micelles. At palmitoyl-CoA concentrations below the critical micelle concentration, addition of non-ionic detergent increased the activity until the critical micelle concentration of the mixed micelles was reached. At palmitoyl-CoA concentrations above the critical micelle concentration, inhibitor of the activity was observed, but addition of detergents of the Triton X series reversed the inhibition. Maximum palmitoyl-CoA hydrolase activity was found when the ratios (w/v) of palmitoyl-CoA: Triton X-100 and palmitoyl-CoA: Triton X-405 were approximately 0.35 and 0.05, respectively. At these above the mixed critical micelle concentration. The results indicate that monomer palmitoyl-CoA is the substrate and that monomer forms of the non-ionic detergents of the Triton X series activate the enzyme. Isolated microsomal lipids activated the microsomal palmitoyl-CoA hydrolase, suggesting that a hydrophobic environment is advantageous for interaction between enzyme and substrate in vivo. The maximum activity in the presence of mixed micelles is discussed in relation to a model where mixed micelles are regarded as artificial membranes to which the enzyme may adhere in an equilibrium with the monomer substrate and detergent in the monomer form. It is suggested that intracellular membranes may resemble mixed micelles in equilibrium with detergent-active substrates such as palmitoyl-CoA.     

Intracellular localization of long-chain acyl-coenzyme A hydrolase and acyl-L-carnitine hydrolase in brown adipose tissue from guinea pigs.

The activities of long-chain acyl-CoA hydrolase (palmitoyl-CoA hydrolase, EC 3.1.2.2) and long-chain acyl-L-carnitine hydrolase, EC 3.1.1.28) in brown adipose tissue from cold-exposed and control guinea pigs were studied. Mitochondria from cold-exposed animals hydrolysed 21 nmol of palmitoyl-CoA/min per mg of protein and 1.3 nmol of palmitoyl-L-carnitine/min per mg of protein, and the specific activities were respectively 2 and 5 times as high in cold-exposed as in control animals. The subcellular-localization studies showed that both the long-chain acyl-CoA hydrolase and long-chain acyl-L-carnitine hydrolase were localized in the mitochondria. A location also in the soluble fraction cannot be excluded. The long-chain acyl-CoA hydrolase activity was doubled when the mitochondria were disrupted; this indicates that the enzyme is localized in the matrix compartment.     

Structural determinants of multimerization and dissociation in 2-Cys peroxiredoxin chaperone function

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Spatial resolution and location impact group structure in a marine food web

Ecological processes in food webs depend on species interactions. By identifying broad‐scaled interaction patterns, important information on species' ecological roles may be revealed. Here, we use the group model to examine how spatial resolution and proximity influence group structure. We examine a data set from the Barents Sea, with food webs described for both the whole region and 25 subregions. We test how the group structure in the networks differ comparing (1) the regional metaweb to subregions and (2) subregion to subregion. We find that more than half the species in the metaweb change groups when compared to subregions. Between subregions, networks with similar group structure are spatially related. Interestingly, although species overlap is important for similarity in group structure, there are notable exceptions. Our results highlight that species ecological roles vary depending on fine‐scaled differences in the patterns of interactions, and that local network characteristics are important to consider.     

The role of the active site Zn in the catalytic mechanism of the GH38 Golgi α-mannosidase II: Implications from noeuromycin inhibition

Golgi α-mannosidase II (GMII) is a Family 38 glycosyl hydrolase involved in the eukaryotic N-glycosylation pathway in protein synthesis. Understanding of its catalytic mechanism has been of interest for the development of specific inhibitors that could lead to novel anti-metastatic or anti-inflammatory compounds. The active site of GMII has been characterized by structural studies of the Drosophila homologue (dGMII) and unusually contains a Zn atom which forms contacts with substrate analogues, stabilized catalytic intermediates, and other inhibitors observed in the active site. In this contribution, we analyze the structure of the sugar mimetic compound noeuromycin complexed with dGMII. Distortions of the conformation of this inhibitor, together with similar observations from other complexes, have permitted us to propose specific roles for the Zn atom in the chemical mechanism of catalysis of Family 38 glycosidase. Such insights have relevance to efforts to formulate novel, specific inhibitors of GMII.     

Neurotransmitter-Triggered Transfer of Exosomes Mediates Oligodendrocyte–Neuron Communication

Reciprocal interactions between neurons and oligodendrocytes are not only crucial for myelination, but also for long-term survival of axons. Degeneration of axons occurs in several human myelin diseases, however the molecular mechanisms of axon-glia communication maintaining axon integrity are poorly understood. Here, we describe the signal-mediated transfer of exosomes from oligodendrocytes to neurons. These endosome-derived vesicles are secreted by oligodendrocytes and carry specific protein and RNA cargo. We show that activity-dependent release of the neurotransmitter glutamate triggers oligodendroglial exosome secretion mediated by Ca²⁺ entry through oligodendroglial NMDA and AMPA receptors. In turn, neurons internalize the released exosomes by endocytosis. Injection of oligodendroglia-derived exosomes into the mouse brain results in functional retrieval of exosome cargo in neurons. Supply of cultured neurons with oligodendroglial exosomes improves neuronal viability under conditions of cell stress. These findings indicate that oligodendroglial exosomes participate in a novel mode of bidirectional neuron-glia communication contributing to neuronal integrity.