Characterization of MOPC 315 IgA oligosaccharide processing intermediates

The structures of alpha 1,2-mannose containing partially processed asparagine-linked oligosaccharides on the alpha-chain of MOPC 315 IgA were characterized using specific glycosidases and acetolysis. Man6GlcNAc2, a substrate for a Golgi alpha 1,2-mannosidase, was found to be a single isomeric structure. Likewise, Man7-9GlcNAc2 were single isomers indicating an ordered sequence of removal of alpha 1,2-linked mannose residues on this murine immunoglobulin heavy chain.     

Effect of tunicamycin on IgM, IgA, and IgG secretion by mouse plasmacytoma cells

Tunicamycin, an antibiotic that prevents glycosylation of glycoproteins by blocking the formation of N-acetylglucosamine-lipid intermediates, was used to study the importance of glycosylation for the secretion of immunoglobulins by mouse plasmacytoma lines that produce immunoglobulins of different classes. Biosynthetically labeled secreted and intracellular immunoglobulins were measured by immunoprecipitation assays. Tunicamycin, at a concentration of 0.5 mug/ml produced an 81% inhibition of IgM secretion by MOPC 104E plasma cells without significantly affecting the initial rate of synthesis of intracellular IgM. No increase in the intracellular degradation of nonglycosylated IgM could be demonstrated. Tunicamycin also produced a 64% average inhibition of IgA secretion by several mouse IgA-secreting plasmacytoma lines. In contrast, despite inhibiting the incorporation of D-[14C] glucosamine into newly synthesized IgG, tunicamycin only produced a 28% average inhibition of IgG secretion, which was only slightly more than the nonspecific inhibition of secretion of the normally nonglycosylated lambda2 light chains by variant MOPC 315 plasmacytomas. These data indicate that the extent of inhibition of immunoglobulin secretion produced by tunicamycin depends on the immunoglobulin class produced by the plasma cell.     

Electrophysiological and immunocytochemical characterization of DRG neurons on an organosilane surface in serum-free medium

We are attempting to recreate a stretch reflex circuit on a patterned Bio-MEMS (bio-microelectromechanical systems) chip with deflecting micro-cantilevers. The first steps to recreate this system is to be able to grow individual components of the circuit (sensory neuron, motoneuron, skeletal muscle, and muscle spindle) on a patternable, synthetic substrate coating the MEMS device. Sensory neurons represent the afferent portion of the stretch reflex arc and also play a significant role in transmitting the signal from the muscle spindle to the spinal cord motoneurons. We have utilized a synthetic silane substrate N-1[3-(trimethoxysilyl) propyl) diethylenetriamine (DETA) on which to grow and pattern the cells. DETA forms a self-assembled monolayer on a variety of silicon substrates, including glass, and can be patterned using photolithography. In this paper, we have evaluated the growth of sensory neurons on this synthetic silane substrate. We have investigated the immunocytochemical and electrophysiological properties of the sensory neurons on DETA and compared the resultant properties with a biological control substrate (ornithine/laminin). Immunocytochemical studies revealed the survival and growth of all three subtypes of sensory neurons: trkA, trkB, and trkC on both surfaces. Furthermore, whole-cell patch clamp recordings were used to study the electrophysiological properties of the sensory neurons on the two surfaces. There were no significant differences in the electrical properties of the neurons grown on either surface. This is the first study analyzing the immunocytochemical and electrophysiological properties of sensory neurons grown long-term in a completely defined environment and on a nonbiological substrate.     

Increasing picocyanobacteria success in shelf waters contributes to long‐term food web degradation

Continental margins are disproportionally important for global primary production, fisheries and CO₂ uptake. However, across the Northeast Atlantic shelves, there has been an ongoing summertime decline of key biota—large diatoms, dinoflagellates and copepods—that traditionally fuel higher tropic levels such as fish, sea birds and marine mammals. Here, we combine multiple time series with in situ process studies to link these declines to summer nutrient stress and increasing proportions of picophytoplankton that can comprise up to 90% of the combined pico‐ and nanophytoplankton biomass in coastal areas. Among the pico‐fraction, it is the cyanobacterium Synechococcus that flourishes when iron and nitrogen resupply to surface waters are diminished. Our field data show how traits beyond small size give Synechococcus a competitive edge over pico‐ and nanoeukaryotes. Key is their ability to grow at low irradiances near the nutricline, which is aided by their superior light‐harvesting system and high affinity to iron. However, minute size and lack of essential biomolecules (e.g. omega‐3 polyunsaturated fatty acids and sterols) render Synechococcus poor primary producers to sustain shelf sea food webs efficiently. The combination of earlier spring blooms and lower summer food quantity and quality creates an increasing period of suboptimal feeding conditions for zooplankton at a time of year when their metabolic demand is highest. We suggest that this nutrition‐related mismatch has contributed to the widespread, ~50% decline in summer copepod abundance we observe over the last 60 years. With Synechococcus clades being prominent from the tropics to the Arctic and their abundances increasing worldwide, our study informs projections of future food web dynamics in coastal and shelf areas where droughts and stratification lead to increasing nutrient starvation of surface waters.