CTB-MPR(649-684), a translational fusion protein consisting of cholera toxin B subunit (CTB) and residues 649 684 of gp41 membrane proximal region (MPR), is a candidate vaccine aimed at blocking early steps of HIV-1 mucosal transmission. Bacterially produced CTB MPR(649-684) was purified to homogeneity by two affinity chromatography steps. Similar to gp41 and derivatives thereof, the MPR domain can specifically and reversibly self-associate. The affinities of the broadly-neutralizing monoclonal Abs 4E10 and 2F5 to CTB MPR(649-684) were equivalent to their nanomolar affinities toward an MPR peptide. The fusion protein's affinity to GM1 ganglioside was comparable to that of native CTB. Rabbits immunized with CTB-MPR(649-684) raised only a modest level of anti-MPR(649-684) Abs. However, a prime-boost immunization with CTB-MPR(649-684) and a second MPR(649-684)-based immunogen elicited a more productive anti-MPR(649-684) antibody response. These Abs strongly blocked the epithelial transcytosis of a primary subtype B HIV-1 isolate in a human tight epithelial model, expanding our previously reported results using a clade D virus. The Abs recognized epitopes at the N-terminal portion of the MPR peptide, away from the 2F5 and 4E10 epitopes and were not effective in neutralizing infection of CD4+ cells. These results indicate distinct vulnerabilities of two separate interactions of HIV-1 with human cells - Abs against the C-terminal portion of the MPR can neutralize CD4+-dependent infection, while Abs targeting the MPR's N-terminal portion can effectively block galactosyl ceramide dependent transcytosis. We propose that Abs induced by MPR(649-684)-based immunogens may provide broad protective value independent of infection neutralization.
SummaryNeural stem cell (NSC) transplantation is a promising strategy for delivering therapeutic proteins in the brain. We evaluated a complete process of ex vivo gene therapy using human induced pluripotent stem cell (iPSC)-derived NSC transplants in a well-characterized mouse model of a human lysosomal storage disease, Sly disease. Human Sly disease fibroblasts were reprogrammed into iPSCs, differentiated into a stable and expandable population of NSCs, genetically corrected with a transposon vector, and assessed for engraftment in NOD/SCID mice. Following neonatal intraventricular transplantation, the NSCs engraft along the rostrocaudal axis of the CNS primarily within white matter tracts and survive for at least 4 months. Genetically corrected iPSC-NSCs transplanted post-symptomatically into the striatum of adult Sly disease mice reversed neuropathology in a zone surrounding the grafts, while control mock-corrected grafts did not. The results demonstrate the potential for ex vivo gene therapy in the brain using human NSCs from autologous, non-neural tissues.
Wood SK, McFadden K, Griffin T, Wolfe JH, Zderic S, Valentino RJ. A corticotropin-releasing factor receptor antagonist improves urodynamic dysfunction produced by social stress or partial bladder outlet obstruction in male rats. Am J Physiol Regul Integr Comp Physiol 304: R940 -R950, 2013. First published April 3, 2013 doi:10.1152/ajpregu.00257.2012.-Barrington's nucleus, in the pons, regulates micturition through spinal projections to preganglionic parasympathetic neurons. The stress neuropeptide CRF is prominent in these projections and has an inhibitory influence. Social stress in rats causes urinary retention and abnormal urodynamics resembling those produced by partial bladder outlet obstruction (pBOO), and this is associated with CRF upregulation in Barrington's nucleus. Here, we examined the role of CRF in social stress-and pBOO-induced urodynamic dysfunction by assessing the ability of a CRF 1 receptor antagonist to alter these effects. Male rats exposed to repeated resident-intruder stress were administered vehicle or a CRF1 antagonist (NBI-30775) daily prior to the stress. Urodynamic function was recorded in the unanesthetized state 72 h after the final stress. NBI-30775 prevented the increased intermicturition interval, micturition volume, and bladder capacity produced by social stress, but not the increase in CRF expression in Barrington's nucleus neurons. The urinary dysfunction was also partly prevented by shRNA targeting of CRF in Barrington's nucleus, suggesting that stress-induced urinary dysfunction results, in part, from CRF upregulation in Barrington's nucleus and enhanced postsynaptic effects in the spinal cord. Finally, NBI-30775 improved urodynamic function of rats that had pBOO of 2-wk duration when administered daily during the second week but did not block the increase in CRF expression in Barrington's nucleus neurons. These findings implicate a role for Barrington's nucleus CRF in stress-and pBOO-induced urodynamic changes and suggest that CRF1 antagonists may be useful therapeutic agents for the treatment of urinary dysfunction. cystometry; resident-intruder; Barrington's nucleus; urinary BARRINGTON'S NUCLEUS IN THE pons regulates the descending limb of the micturition reflex through its axonal projections to preganglionic neurons of the lumbosacral spinal cord that provide the parasympathetic input to the detrusor muscle (21). Electrical and chemical stimulation of Barrington's nucleus elicits detrusor contraction, and conversely, lesions disrupt the micturition reflex (1,27,29). More recent anatomical and physiological evidence suggests that Barrington's nucleus plays a key role in coordinating central and visceral responses during micturition (39) (for review, see Ref. 41). In addition to its connections to the bladder, Barrington's nucleus neurons are transsynaptically linked to the distal colon and other pelvic viscera, suggesting a broader role for this nucleus in the regulation of pelvic visceral functions (23,24,33,40,44). Elucidating the function of neuromodulators expresse...
The stress-related neuropeptide, corticotropin-releasing factor (CRF), is prominent in neurons of the pontine micturition center, Barrington’s nucleus. These neurons co-innervate spinal preganglionic neurons that control the bladder and locus coeruleus (LC) neurons that provide norepinephrine innervation throughout the brain. Adeno-associated viral (AAV) vector-mediated transfer of CRF cDNA was used to increase CRF expression in Barrington’s nucleus neurons and investigate the impact of a gain of function in Barrington’s nucleus spinal and LC projections. AAV transfer of the reverse CRF cDNA sequence served as the control. Bladder urodynamics and behavior were assessed four weeks after vector injection into Barrington’s nucleus. Rats with bilateral injections of AAV-CRF cDNA into Barrington’s nucleus had immunohistochemical evidence of CRF overexpression in neurons and transport to the spinal cord and LC. The bladder: body weight ratio was greater and micturition pressure was less in these rats compared to controls, consistent with an inhibitory influence on bladder function. Other indices of urodynamic function were not altered. CRF innervation of the LC was increased in rats with bilateral Barrington’s nucleus injections of AAV-CRF cDNA and this was associated with increased burying behavior, an endpoint of LC activation by CRF. The results provide immunohistochemical evidence for viral vector-induced CRF overexpression in Barrington’s nucleus neurons and underscore the ability of AAV vector-mediated transfer to increase CRF function in selective circuits. The findings support an inhibitory influence of CRF in Barrington’s nucleus regulation of the bladder and an excitatory influence on the brain norepinephrine system that translates to behavioral activation.
6 and 12 months after transplant and was maintained thereafter. Vector marking in peripheral blood cells remained consistently detectable (> 0.1 copy/PBMC and ≥ 0.003 copy/granulocyte) at 2 years and later after transplant in subjects who discontinued ERT. These subjects also had PBMC ADA enzymatic activity in the normal range and red blood cell deoxynucleotide levels below 10%. Three subjects have discontinued intravenous immunoglobulin; five subjects have discontinued prophylactic antibiotics. All subjects have polyclonal gene marking with no sign of lymphoproliferative disease. The subjects remain in good health without infections or other complications.
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