Epidermal powder immunization induces both cytotoxic T-lymphocyte and antibody responses to protein antigens of influenza and hepatitis B viruses.

Cytotoxic T lymphocytes (CTL) play a vital role in host defense against viral and intracellular bacterial infections. However, nonreplicating vaccines administered by intramuscular injection using a syringe and needle elicit predominantly humoral responses and not CTL responses. Here we report that epidermal powder immunization (EPI), a technology that delivers antigens on 1.5- to 2.5-microm gold particles to the epidermis using a needle-free powder delivery system, elicits CTL responses to nonreplicating antigens. Following EPI, a majority of the antigen-coated gold particles were found in the viable epidermis in the histological sections of the target skin. Further studies using transmission electron microscopy revealed the intracellular localization of the gold particles. Many Langerhans cells (LCs) at the vaccination site contained antigen-coated particles, as revealed by two-color immunofluorescence microscopy, and these cells were found in the draining lymph nodes 20 h later. Immune responses to several viral protein antigens after EPI were studied in mice. EPI with hepatitis B surface antigen (HBsAg) and a synthetic peptide of influenza virus nucleoprotein (NP peptide) elicited antigen-specific CTL responses as well as antibody responses. In an in vitro cell depletion experiment, we demonstrated that the CTL activity against HBsAg elicited by EPI was attributed to CD8(+), not CD4(+), T cells. As controls, needle injections of HBsAg or the NP peptide into deeper tissues elicited solely antibody, not CTL, responses. We further demonstrated that EPI with inactivated A/Aichi/68 (H3N2) or A/Sydney/97 (H3N2) influenza virus elicited complete protection against a mouse-adapted A/Aichi/68 virus. In summary, EPI directly delivers protein antigens to the cytosol of the LCs in the skin and elicits both cellular and antibody responses.

Spectral observation of an acyl-enzyme intermediate of lipoprotein lipase.

There have been several studies indicating that hydrolysis reactions of fatty acid esters catalyzed by lipases proceed through an acyl-enzyme intermediate typical of serine proteases. In particular, one careful kinetic study with the physiologically important enzyme lipoprotein lipase (LPL) is consistent with rate-limiting deacylation of such an intermediate. To observe the spectrum of acyl-enzyme and study the mechanism of LPL-catalyzed hydrolysis of substrate, we have used a variety of furylacryloyl substrates including 1,2-dipalmitoyl-3-[(beta-2-furylacryloyl)triacyl]glyceride (DPFATG) to study the intermediates formed during the hydrolysis reaction catalyzed by the enzyme. After isolation and characterization of the molecular weight of adipose LPL, we determined its extinction coefficient at 280 nm to quantitate the formation of any acyl-enzyme intermediate formed during substrate hydrolysis. We observed an intermediate at low pH during the enzyme-catalyzed hydrolysis of (furylacryloyl)imidazole. This intermediate builds early in the reaction when a substantial amount of substrate has hydrolyzed but no product, furylacrylate, has been formed. The acyl-enzyme has a lambda max = 305 nm and a molar extinction coefficient of 22,600 M-1 cm-1; these parameters are similar to those for furylacryloyl esters including the serine ester. These data provide the first spectral evidence for a serine acyl-enzyme in lipase-catalyzed reactions. The LPL hydrolysis reaction is base catalyzed, exhibiting two pKa values; the more acidic of these is 6.5, consistent with base catalysis by histidine. The biphasic rates for substrate disappearance or product appearance and the absence of leaving group effect indicate that deacylation of intermediate is rate limiting.

Electrostatic effect upon association of reduced nicotinamide adenine dinucleotide and equine liver alcohol dehydrogenase.

The rate of association of equine liver alcohol dehydrogenase and its coenzymes exhibits a large pH dependence with slower rates at basic pH and an observed kinetic pKa value of approximately 9-9.5. This pH dependence has been explained by invoking local active site electrostatic effects which result in repulsion of the negatively charged coenzyme and the ionized hydroxyl anion form of the zinc-bound water molecule. We have examined a simpler hypothesis, namely, that the pH dependence results from the electrostatic interaction of the coenzyme and the enzyme which changes from an attractive interaction of the negatively charged coenzyme and the positively charged enzyme to a repulsive interaction between the two negatively charged species at the isoelectric point for the enzyme (pH 8.7). We have tested this proposal by examining the ionic strength dependence of the association rate constant at various pH values. These data have been interpreted by using the Wherland-Gray equation, which we have shown can be applied to the kinetics of enzyme-coenzyme association. Our results indicate that the shielding of the buffer electrolyte changes from a negative to a positive value as the charge on the protein changes at the isoelectric point. This result is exactly that which is predicted for electrostatic effects that depend on the charge of the protein molecule and is not consistent with predictions based upon the local active site effects. At low ionic strength values of 10 mM or less, approximately 75% of the observed pH dependence results from the enzyme electrostatic effects; the remaining pH dependence may result from active site effects.(ABSTRACT TRUNCATED AT 250 WORDS)

The EH2 reduced intermediate of glutathione reductase contains oxidised flavin-while EH4 does not.

Glutathione reductase is a flavoprotein whose x-ray structure has been established. Functional data and the x-ray structure are consistent with a mechanism of reaction in which NADPH reacts with the enzyme to produce a two electron, EH2, and four electron, EH4, intermediate. The former is competent for the transfer of electrons to the substrate glutathione. Several structures are possible for the two NADPH intermediates; in order to aid in the determination of the structure of these intermediates, we have determined their resonance Raman spectra at two excitation frequencies. These studies establish that the EH2 intermediate is an oxidized flavin species while the EH4 species is not. Furthermore, the most likely structure for EH2 involves a charge transfer donation of electrons from the anion of cys-63 to the N5 position of flavin.