43 research outputs found
Endothelial progenitor cells and integrins: adhesive needs
In the last decade there have been multiple studies concerning the contribution of endothelial progenitor cells (EPCs) to new vessel formation in different physiological and pathological settings. The process by which EPCs contribute to new vessel formation in adults is termed postnatal vasculogenesis and occurs via four inter-related steps. They must respond to chemoattractant signals and mobilize from the bone marrow to the peripheral blood; home in on sites of new vessel formation; invade and migrate at the same sites; and differentiate into mature endothelial cells (ECs) and/or regulate pre-existing ECs via paracrine or juxtacrine signals. During these four steps, EPCs interact with different physiological compartments, namely bone marrow, peripheral blood, blood vessels and homing tissues. The success of each step depends on the ability of EPCs to interact, adapt and respond to multiple molecular cues. The present review summarizes the interactions between integrins expressed by EPCs and their ligands: extracellular matrix components and cell surface proteins present at sites of postnatal vasculogenesis. The data summarized here indicate that integrins represent a major molecular determinant of EPC function, with different integrin subunits regulating different steps of EPC biology. Specifically, integrin α4β1 is a key regulator of EPC retention and/or mobilization from the bone marrow, while integrins α5β1, α6β1, αvβ3 and αvβ5 are major determinants of EPC homing, invasion, differentiation and paracrine factor production. β2 integrins are the major regulators of EPC transendothelial migration. The relevance of integrins in EPC biology is also demonstrated by many studies that use extracellular matrix-based scaffolds as a clinical tool to improve the vasculogenic functions of EPCs. We propose that targeted and tissue-specific manipulation of EPC integrin-mediated interactions may be crucial to further improve the usage of this cell population as a relevant clinical agent
Inhibition of DNA polymerase reactions by pyrimidine nucleotide analogues lacking the 2-keto group.
To investigate the influence of the pyrimidine 2-keto group on selection of nucleotides for incorporation into DNA by polymerases, we have prepared two C nucleoside triphosphates that are analogues of dCTP and dTTP, namely 2-amino-5-(2'-deoxy-beta-d-ribofuranosyl)pyridine-5'-triphosphate (d*CTP) and 5-(2'-deoxy- beta-d-ribofuranosyl)-3-methyl-2-pyridone-5'-triphosphate (d*TTP) respectively. Both proved strongly inhibitory to PCR catalysed by Taq polymerase; d*TTP rather more so than d*CTP. In primer extension experiments conducted with either Taq polymerase or the Klenow fragment of Escherichia coli DNA polymerase I, both nucleotides failed to substitute for their natural pyrimidine counterparts. Neither derivative was incorporated as a chain terminator. Their capacity to inhibit DNA polymerase activity may well result from incompatibility with the correctly folded form of the polymerase enzyme needed to stabilize the transition state and catalyse phosphodiester bond formation
Effects of CO2, light and temperature on rubisco activase protein in wheat leaf segments
Rubisco activase catalyzes the ATP-dependent activation of rubisco. At moderately
elevated temperature (for wheat above 30°C), rubisco activase becomes reversibly
inactivated in leaf segments (2). A further increase of the temperature (for wheat above
40°C) causes partial insolubilization and the formation of aggregates in less than 30
minutes.
Senescence in wheat leaf segments depends on the availability of CO2, the illumination
and the incubation temperature. In general, net protein degradation is delayed under
CO2 depletion. At higher light (PAR: 150 μmol m-2 s- 1), several stromal proteins are less
rapidly degraded than at low light (PAR: 50 μmol m-2 s- 1). In absence of CO2 and at the
higher PAR, chloroplast enzymes are maintained in wheat leaf segments over days even
at 35°C indicating that senescence and net degradation of chloroplast proteins are not
necessarily accelerated by such unfavorable conditions for photosynthesis. The fate of
rubisco activase protein under such conditions is of special interest, since its activity is
temperature-sensitive and this enzyme plays an important role in the regulation of
rubisco activity and as a consequence of the Calvin-cycle