Selective activation by thymus-dependent antigens of distinct B cell subpopulations expressing a major cross-reactive idiotype

We determined the B cell subpopulations that produce the major cross-reactive idiotype (CRIA) associated with the anti-phenylarsonate (ARS) antibody response of A/J mice. Specifically, we examined the B2 subpopulation found in normal mice which, in H-2b mice, bears the I-Ab-encoded determinant Ia.W39; the B1 subpopulation found in mice expressing the CBA/N X-linked immunodeficiency trait (xid); and the B1 subpopulation found in normal mice after the cytotoxic elimination of B2 cells with anti-Ia. W39 and complement. CRIA is expressed in each of these B cell subpopulations. Antigen plays a selective role in the stimulation of distinct B cell sets. ARS conjugates of keyhole limpet hemocyanin (KLH) can activate both the B1 and B2 subpopulations. In contrast, ARS conjugates of synthetic polypeptides under Ir gene control selectively activate the B2 subpopulation in strains that are genetic responders to the carrier. This leads to the establishment of CRIA dominance where CRIA+ anti-ARS antibody is 70 to 95% of the total anti-arsonate antibody response. This class of antigens fails to activate the B1 cells in either normal or xid mice. We compared the CRIA+ antibody produced by selectively activated B2 cells to that produced by the B1 subpopulation in xid mice. For these comparisons, we used competitive radioimmunoassays that employed polyspecific anti-CRIA antiserum or monoclonal anti-CRIA antibodies specific for distinct idiotopes on the heavy chain of CRIA+ antibody. B2 cells produce a CRIA+ anti-ARS antibody that is idiotopically uniform among individual mice, and that closely approximates the hybridoma protein 36-65 (the heavy chain of 36-65 represents the germ line-encoded sequence of the unique CRIA structural gene (25]. In contrast, the CRIA+ antibody produced by the B1 cell subset of xid mice is idiotopically diverse among individual mice, and differs markedly from the 36-65 hybridoma protein. The extent of diversification found in CRIA+ antibody depends on the B cell subpopulation that produces it.     

Mobilization of cloned luciferase genes into Vibrio harveyi luminescence mutants

A recombinant plasmid which carried a 5 kb fragment of Vibrio harveyi DNA containing the luxA and luxB genes was mobilized from Escherichia coli into luminescence-deficient mutants of V. harveyi. The cloned genes complemented a temperature sensitive luciferase mutation, but failed to complement lesions in two different aldehyde deficient mutants. Expression of the cloned genes was not subject to autoinduction in either E. coli or in V. harveyi.     

Histone gene number and organisation in Xenopus: Xenopus borealis has a homogeneous major cluster

Using a Xenopus laevis H4 cDNA clone as a probe we have determined that the numbers of H4 histone genes in Xenopus laevis and Xenopus borealis are approximately the same. These numbers are dependent on the hybridization stringency and we measure about 90 H4 genes per haploid genome after a 60 degrees C wash in 3 X SSC. Using histone probes from both Xenopus and sea urchin we have studied the genomic organization of histone genes in these two species. In all of the X.borealis individuals analyzed about 70% of the histone genes were present in a very homogeneous major cluster. These genes are present in the order H1, H2B, H2A, H4 and H3, and the minimum length of the repeated unit is 16kb. In contrast, the histone gene clusters in X.laevis showed considerable sequence variation. However two major cluster types with different gene orders seem to be present in most individuals. The differences in histone gene organization seen in species of Xenopus suggest that even in closely related vertebrates the major histone gene clusters are quite fluid structures in evolutionary terms.     

A Persistent Daily Rhythm in Photosynthesis

The luminescent marine dinoflagellate, Gonyaulax polyedra, exhibits a diurnal rhythm in the rate of photosynthesis and photosynthetic capacity measured by incorporation of C¹⁴O₂, at different times of day. With cultures grown on alternating light and dark periods of 12 hours each, the maximum rate is at the 8th hour of the light period. Cultures transferred from day-night conditions to continuous dim light continue to show the rhythm of photosynthetic capacity (activity measured in bright light) but not of photosynthesis (activity measured in existing dim light). Cultures transferred to continuous bright light, however, do not show any rhythm. Several other properties of the photosynthetic rhythm are similar to those of previously reported rhythms of luminescence and cell division. This similarity suggests that a single mechanism regulates the various rhythms.     

Purification of component A of the soluble methane monooxygenase of Methylococcus capsulatus (Bath) by high-pressure gel permeation chromatography

A major improvement in the purification of the oxygenase protein (component A) of the methane monooxygenase has been effected. By employing high-pressure gel permeation chromatography several purification steps may be omitted from the previously published scheme. Furthermore the yield of the protein is enhanced and more importantly the recovered protein displays an increased specific activity, unlike that purified by other techniques.     

The stability and translation of sea urchin histone messenger RNA molecules injected into Xenopus laevis eggs and developing embryos

Embryonic sea urchin histone mRNA was injected into eggs and developing zygotes of Xenopus. The functional stability of the mRNA was monitored by separating newly synthesized sea urchin histones from those of Xenopus. Just as when injected into Xenopus oocytes, sea urchin H1, H2A, and H2B mRNA molecules have a functional half-life of about 3 hr in the developing embryo. This suggests that the endogenous Xenopus histone mRNA is also unstable and has a number of implications for the amount of histone mRNA that is stored in the oocyte and the time at which histone genes should become active in development. The injected mRNA is translated with little, if any, greater efficiency in the egg than in the oocyte. However, Xenopus histone synthesis increases about 20- to 50-fold during the transition from oocyte to egg. The injection experiments therefore suggest that this increase is brought about primarily by the mobilization of stored mRNA, rather than an increase in the efficiency of histone synthesis.     

Assimilation of Diazotrophic Nitrogen into Pelagic Food Webs

The fate of diazotrophic nitrogen (N_D) fixed by planktonic cyanobacteria in pelagic food webs remains unresolved, particularly for toxic cyanophytes that are selectively avoided by most herbivorous zooplankton. Current theory suggests that N_D fixed during cyanobacterial blooms can enter planktonic food webs contemporaneously with peak bloom biomass via direct grazing of zooplankton on cyanobacteria or via the uptake of bioavailable N_D (exuded from viable cyanobacterial cells) by palatable phytoplankton or microbial consortia. Alternatively, N_D can enter planktonic food webs post-bloom following the remineralization of bloom detritus. Although the relative contribution of these processes to planktonic nutrient cycles is unknown, we hypothesized that assimilation of bioavailable N_D (e.g., nitrate, ammonium) by palatable phytoplankton and subsequent grazing by zooplankton (either during or after the cyanobacterial bloom) would be the primary pathway by which N_D was incorporated into the planktonic food web. Instead, in situ stable isotope measurements and grazing experiments clearly documented that the assimilation of N_D by zooplankton outpaced assimilation by palatable phytoplankton during a bloom of toxic Nodularia spumigena Mertens. We identified two distinct temporal phases in the trophic transfer of N_D from N. spumigena to the plankton community. The first phase was a highly dynamic transfer of N_D to zooplankton with rates that covaried with bloom biomass while bypassing other phytoplankton taxa; a trophic transfer that we infer was routed through bloom-associated bacteria. The second phase was a slowly accelerating assimilation of the dissolved-N_D pool by phytoplankton that was decoupled from contemporaneous variability in N. spumigena concentrations. These findings provide empirical evidence that N_D can be assimilated and transferred rapidly throughout natural plankton communities and yield insights into the specific processes underlying the propagation of N_D through pelagic food webs.