The effects of historical fragmentation on major histocompatibility complex class II β and microsatellite variation in the Aegean island reptile,Podarcis erhardii

The major histocompatibility complex (MHC) plays a key role in disease resistance and is the most polymorphic gene region in vertebrates. Although habitat fragmentation is predicted to lead to a loss in MHC variation through drift, the impact of other evolutionary forces may counter this effect. Here we assess the impact of selection, drift, migration, and recombination on MHC class II and microsatellite variability in 14 island populations of the Aegean wall lizard Podarcis erhardii. Lizards were sampled from islands within the Cyclades (Greece) formed by rising sea levels as the last glacial maximum approximately 20,000 before present. Bathymetric data were used to determine the area and age of each island, allowing us to infer the corresponding magnitude and timing of genetic bottlenecks associated with island formation. Both MHC and microsatellite variation were positively associated with island area, supporting the hypothesis that drift governs neutral and adaptive variation in this system. However, MHC but not microsatellite variability declined significantly with island age. This discrepancy is likely due to the fact that microsatellites attain mutation‐drift equilibrium more rapidly than MHC. Although we detected signals of balancing selection, recombination and migration, the effects of these evolutionary processes appeared negligible relative to drift. This study demonstrates how land bridge islands can provide novel insights into the impact of historical fragmentation on genetic diversity as well as help disentangle the effects of different evolutionary forces on neutral and adaptive diversity.     

Biochemical properties of conjugates of urokinase-type plasminogen activator with a monoclonal antibody specific for cross-linked fibrin

Equimolar mixtures of recombinant single chain urokinase-type plasminogen activator (rscu-PA) and a murine monoclonal antibody (MA-15C5) directed against fragment-D dimer of human cross-linked fibrin were conjugated, using the cross-linking agent N-succinimidyl 3-(2-pyridyldithio)propionate (PySSProSu). The conjugate (rscu-PA/MA-15C5), purified by immunoadsorption on a urokinase antibody and affinity chromatography on fibrin fragment-D dimer with a yield of 42 +/- 15% (mean +/- SD, n = 3), contained an average of 1.2 +/- 0.3 IgG molecules/rscu-PA molecule. On non-reduced SDS/PAGE it migrated as a main band with apparent Mr of 200,000. Specific amidolytic activities expressed/mass of u-PA were less than 250 IU/mg for rscu-PA/MA-15C5 and rscu-PA, 140,000 +/- 13,000 IU/mg and 100,000 +/- 17,000 IU/mg for their plasmin-generated two chain derivatives rtcu-PA/MA-15C5 and rtcu-PA respectively. Specific activities on fibrin plates were 100,000 +/- 24,000 IU/mg and 130,000 +/- 49,000 IU/mg for rscu-PA/MA-15C5 and rtcu-PA/MA-15C5 respectively, as compared to 180,000 +/- 15,000 IU/mg for both rscu-PA and rtcu-PA. Activation of plasminogen with rscu-PA/MA-15C5 (Km = 0.37 +/- 0.16 microM, k2 = 0.0063 +/- 0.0030 s-1 or rtcu-PA/MA-15C5 (Km = 19 +/- 3.0 microM, k2 = 2.0 +/- 0.10 s-1) in purified systems followed Michaelis-Menten kinetics with Km and k2 values comparable to those of rscu-PA and rtcu-PA. In an in vitro system composed of a 125I-fibrin-labeled whole human plasma clot immersed in citrated human plasma, dose- and time-dependent lysis was obtained; 50% lysis in 2 h required 1.4 microgram/ml of rscu-PA or 0.33 microgram/ml of rtcu-PA, but only 0.22 microgram u-PA/ml of rscu-PA/MA-15C5 or 0.15 microgram u-PA/ml of rtcu-PA/MA-15C5. Addition of purified fragment-D dimer reversed the increased fibrinolytic potency of rscu-PA/MA-15C5 in a concentration-dependent way (50% inhibition at 7.2 micrograms fragment-D dimer/ml). Thus, conjugation of u-PA moieties with the fibrin-specific antibody MA-15C5 targets the plasminogen activator to the clot, resulting in a significant increase of their fibrinolytic potencies as compared to their unconjugated counterparts: 6.4-fold for rscu-PA and 2.2-fold for rtcu-PA.     

Alkaline phosphatase activity in human polymorphonuclear leukocytes

Synopsis Alkaline phosphatase has been localized ultracytochemically in PMN of man with normal and elevated levels of this enzyme. Contrary to guinea-pig PMN, no activity appears to be present in the specific granules. Instead, the plasma membrane and the membrane of the endocytic vacuoles show a strong staining. However, the demonstration of this activity depends on the preparatory procedure employed for PMN isolation. the use of dextran and Ficoll-Hypaque in the isolation procedure induces a marked increase in alkaline phosphatase staining of the PMN plasma membrane. Strongly increased activity at this site has been found in PMN from cancer patients. In most of them, additional staining has been observed in atypical vesicles and sometimes in the Golgi apparatus. These findings are discussed in the light of some previously reported controversial biochemical and cytochemical data on the distribution of alkaline phosphatase in human PMN.     

Identification of phospholipids as new components that assist in the in vitro trimerization of a bacterial pore protein.

The in vitro trimerization of folded monomers of the bacterial pore protein PhoE, into its native-like, heat- and SDS-stable form requires incubations with isolated cell envelopes and Triton X-100. The possibility that membranes could be isolated that are enriched in assembly factors required for assembly of the pore protein was now investigated. Fractionation of total cell envelopes of Escherichia coli via various techniques indeed revealed the existence of membrane fractions with different capacities to support assembly in vitro. Fractions containing mainly inner membrane vesicles supported the formation of trimers that were associated with these membrane vesicles. However, only a proportion of these trimers were heat- and SDS-stable and these were formed with slow kinetics. In contrast, fractions containing mainly outer membrane vesicles supported formation of high amounts of heat-stable trimers with fast kinetics. We identified phospholipids as active assembly components in these membranes that support trimerization of folded monomers in a process with similar characteristics as observed with inner membrane vesicles. Furthermore, phospholipids strongly stimulate the kinetics of trimerization and increase the final yield of heat-stable trimers in the context of outer membranes. We propose that lipopolysaccharides stabilize the assembly competent state of folded monomers as a lipochaperone. Phospholipids are involved in converting the folded monomer into new assembly competent intermediate with a short half-life that will form heat-stable trimers most efficiently in the context of outer membrane vesicles. These results provide biochemical evidence for the involvement of different lipidic components at distinct stages of the porin assembly process.