Antiviral Protection and Germinal Center Formation, But Impaired B Cell Memory in the Absence of CD19

Coligation of CD19, a molecule expressed during all stages of B cell development except plasmacytes, lowers the threshold for B cell activation with anti-IgM by a factor of 100. The cytoplasmic tail of CD19 contains nine tyrosine residues as possible phosphorylation sites and is postulated to function as the signal transducing element for complement receptor (CR)2. Generation and analysis of CD19 gene–targeted mice revealed that T cell–dependent (TD) antibody responses to proteinaceous antigens were impaired, whereas those to T cell–independent (TI) type 2 antigens were normal or even augmented. These results are compatible with earlier complement depletion studies and the postulated function of CD19. To analyze the role of CD19 in antiviral antibody responses, we immunized CD19^−/− mice with viral antigens of TI-1, TI-2, and TD type. The effect of CD19 on TI responses was more dependent on antigen dose and replicative capacity than on antigen type. CR blocking experiments confirmed the role of CD19 as B cell signal transducer for complement. In contrast to immunization with protein antigens, infection of CD19^−/− mice with replicating virus led to generation of specific germinal centers, which persisted for >100 d, whereas maintenance of memory antibody titers as well as circulating memory B cells was fully dependent on CD19. Thus, our study confirms a costimulatory role of CD19 on B cells under limiting antigen conditions and indicates an important role for B cell memory.     

Regulation of late B cell differentiation by intrinsic IKKalpha-dependent signals

NF-kappaB-inducing kinase (NIK)-mediated IKKalpha phosphorylation activates the alternative NF-kappaB pathway, which is characterized by nuclear translocation of p52:RelB heterodimers. This alternative pathway is initiated by a select few receptors, including LT-betaR, BAFF-R, and CD40. Although NIK, IKKalpha, and p52 are all critical regulators of LT-betaR signaling in stromal cells during humoral immune responses, lymphocytes require NIK, but not p52, for optimal Ig production. This disparity suggests that NIK possesses critical cell-type-specific functions that do not depend on NF-kappaB. Here we use mice bearing targeted mutations of the IKKalpha activation loop Ser(176/180) (IKKalpha(AA)) to address the B cell-intrinsic functions of NIK-IKKalpha signaling in vivo. We find that IKKalpha(AA) B cells mount normal primary antibody responses but do not enter germinal centers. This defect likely derives from ineffective early T-B cell collaboration and leads to impaired generation of humoral memory and relatively short-lived, low-affinity antibody production. Our findings contrast with those obtained by using p52(-/-) B cells, which mount normal Ig responses, and alymphoplasia (NIK mutant) B cells, which produce very little primary Ig. Thus, the NIK-IKKalpha-p52 axis is not as linear and exclusive as previous studies suggest, and IKKalpha possesses critical NF-kappaB-independent functions in B cells.     

Cerebral response to norepinephrine compared with fluid resuscitation in ovine traumatic brain injury and systemic inflammation

OBJECTIVE: Traumatic brain injury is frequently accompanied by a systemic inflammatory response. Systemic inflammation was associated with cerebral hyperperfusion uncoupled to global oxygen metabolism in ovine head trauma. The present study investigated the cerebral effects of cerebral perfusion pressure (CPP) management performed by either fluid resuscitation or vasopressor treatment of low CPP induced by systemic inflammation. DESIGN: Nonrandomized experimental study. SETTING: University hospital laboratory. SUBJECTS: A total of 12 adult sheep. INTERVENTIONS, MEASUREMENTS, AND MAIN RESULTS: Sheep were anesthetized and ventilated throughout the experimental period (13 hrs). After baseline measurements (hour 0), blunt head trauma was induced by a nonpenetrating stunner. After postinjury measurements (hour 2), all animals received continuous endotoxin infusion. At hour 10, one group (n = 6) was infused with hydroxyethyl starch until CPP reached 60-70 mm Hg. A second group (n = 6) received norepinephrine for CPP elevation. In the norepinephrine group, blood was isovolemically exchanged by hydroxyethyl starch to achieve comparable hematocrit levels. Head trauma increased intracranial pressure and decreased brain tissue oxygen tension. Endotoxemia induced a hyperdynamic cardiovascular response with increased internal carotid blood flow in the presence of systemic hypotension and decreased CPP. Hydroxyethyl starch infusion further increased internal carotid blood flow from (mean +/- sd) 247 +/- 26 (hour 10) to 342 +/- 42 mL/min (hour 13) and intracranial pressure from 20 +/- 4 (hour 10) to a maximum of 25 +/- 3 mm Hg (hour 12) but did not significantly affect brain tissue oxygen tension, sinus venous oxygen saturation and oxygen extraction fraction. Norepinephrine increased internal carotid blood flow from 268 +/- 19 to 342 +/- 58 mL/min and intracranial pressure from 22 +/- 11 to 24 +/- 11 mm Hg (hour 10 vs. hour 13) but significantly increased sinus venous oxygen saturation from 49 +/- 4 (hour 10) to a maximum of 59 +/- 6 mm Hg (hour 12) and decreased oxygen extraction fraction. The increase in brain tissue oxygen tension during norepinephrine treatment was not significant. CONCLUSION: We conclude that despite identical carotid blood flows, only CPP management with norepinephrine reduced the cerebral oxygen deficit in this model.     

Conformational implications of asparagine-linked glycosylation.

The effects of cotranslational protein modification on the process of protein folding are poorly understood. Time-resolved fluorescence energy transfer has been used to assess the impact of glycosylation on the conformational dynamics of flexible oligopeptides. The peptide sequences examined are selected from glycoproteins of known three-dimensional structure. The energy transfer modulation associated with N-linked glycosylation is consistent with the glycopeptides sampling different conformational profiles in water. Results show that glycosylation causes the modified peptides to adopt a different ensemble of conformations, and for some peptides this change may lead to conformations that are more compact and better approximate the conformation of these peptides in the final folded protein. This result further implies that cotranslational glycosylation can trigger the timely formation of structural nucleation elements and thus assist in the complex process of protein folding.