The presidential agenda: sources of executive influence in Congress

(print) x, 205 p. : ill. ; 24 cmList of Illustrations vii -- Part I The Theoretical Problem of Presidential Agenda Setting in Congress -- 1. An Informational Theory of Presidential Agenda Setting p. 3 -- 2. Game Theory and Presidential Agenda Setting p. 21 -- 3. Public Addresses and the Legislative Programming Process p. 32 -- 4. Draft Bills and the Legislative Clearance Process p. 47 -- Part II An Empirical Study of Presidential Agenda Setting in Congress -- 5. Redefining Congressional Agenda Setting p. 63 -- 6. Presidential Agenda Setting in the House p. 87 -- 7. Presidential Agenda Setting in the Senate p. 117 -- 8. Information and Presidential Agenda Setting p. 142 -- Appendixes -- A. Proof of Legislative Programming Equilibrium p. 149 -- B. Proof of Legislative Clearance Equilibrium p. 160 -- C. Tables of Comparative Characteristics of House and Senate Committees p. 165 -- D. The Linear Probability Model with Dichotomous Independent Variables p. 168 -- E. Indirect and Total Effects in Path Analysis p. 172 -- F. Tables of Regression Coefficients for Direct Effects on House Agenda p. 174 -- G. Tables of Regression Coefficients for Direct Effects on Senate Agenda p. 179 -- Notes p. 183 -- Bibliography p. 189Item embargoed for five year

CXCR4 Cardiac Specific Knockout Mice Develop a Progressive Cardiomyopathy

Activation of multiple pathways is associated with cardiac hypertrophy and heart failure. We previously published that CXCR4 negatively regulates β-adrenergic receptor (β-AR) signaling and ultimately limits β-adrenergic diastolic (Ca2+) accumulation in cardiac myocytes. In isolated adult rat cardiac myocytes; CXCL12 treatment prevented isoproterenol-induced hypertrophy and interrupted the calcineurin/NFAT pathway. Moreover; cardiac specific CXCR4 knockout mice show significant hypertrophy and develop cardiac dysfunction in response to chronic catecholamine exposure in an isoproterenol-induced (ISO) heart failure model. We set this study to determine the structural and functional consequences of CXCR4 myocardial knockout in the absence of exogenous stress. Cardiac phenotype and function were examined using (1) gated cardiac magnetic resonance imaging (MRI); (2) terminal cardiac catheterization with in vivo hemodynamics; (3) histological analysis of left ventricular (LV) cardiomyocyte dimension; fibrosis; and; (4) transition electron microscopy at 2-; 6- and 12-months of age to determine the regulatory role of CXCR4 in cardiomyopathy. Cardiomyocyte specific-CXCR4 knockout (CXCR4 cKO) mice demonstrate a progressive cardiac dysfunction leading to cardiac failure by 12-months of age. Histological assessments of CXCR4 cKO at 6-months of age revealed significant tissue fibrosis in knockout mice versus wild-type. The expression of atrial naturietic factor (ANF); a marker of cardiac hypertrophy; was also increased with a subsequent increase in gross heart weights. Furthermore, there were derangements in both the number and the size of the mitochondria within CXCR4 cKO hearts. Moreover, CXCR4 cKO mice were more sensitive to catocholamines, their response to β-AR agonist challenge via acute isoproterenol (ISO) infusion demonstrated a greater increase in ejection fraction, dp/dtmax, and contractility index. Interestingly, prior to ISO infusion, there were significant differences in baseline hemodynamics between the CXCR4 cKO compared to littermate controls. However, upon administering ISO, the CXCR4 cKO responded in a robust manner overcoming the baseline hemodynamic deficits reaching WT values supporting our previous data that CXCR4 negatively regulates β-AR signaling. This further supports that, in the absence of the physiologic negative modulation, there is an overactivation of down-stream pathways, which contribute to the development and progression of contractile dysfunction. Our results demonstrated that CXCR4 plays a non-developmental role in regulating cardiac function and that CXCR4 cKO mice develop a progressive cardiomyopathy leading to clinical heart failure

Immunogenicity and efficacy of Zika virus Envelope Domain III in DNA, protein and ChAdOx1 adenoviral-vectored vaccines

The flavivirus envelope protein domain III (EDIII) was an effective immunogen against dengue virus (DENV) and other related flaviviruses. Whether this can be applied to the Zika virus (ZIKV) vaccinology remains an open question. Here, we tested the efficacy of ZIKV-EDIII against ZIKV infection, using several vaccine platforms that present the antigen in various ways. We provide data demonstrating that mice vaccinated with a ZIKV-EDIII as DNA or protein-based vaccines failed to raise fully neutralizing antibodies and did not control viremia, following a ZIKV challenge, despite eliciting robust antibody responses. Furthermore, we showed that ZIKV-EDIII encoded in replication-deficient Chimpanzee adenovirus (ChAdOx1-EDIII) elicited anti-ZIKV envelope antibodies in vaccinated mice but also provided limited protection against ZIKV in two physiologically different mouse challenge models. Taken together, our data indicate that contrary to what was shown for other flaviviruses like the dengue virus, which has close similarities with ZIKV-EDIII, this antigen might not be a suitable vaccine candidate for the correct induction of protective immune responses against ZIKV