Disruption of Microtubules Post-Virus Entry Enhances Adeno-Associated Virus Vector Transduction.

Perinuclear retention of viral particles is a poorly understood phenomenon observed during many virus infections. In this study, we investigated whether perinuclear accumulation acts as a barrier to limit recombinant adeno-associated virus (rAAV) transduction. After nocodazole treatment to disrupt microtubules at microtubule-organization center (MT-MTOC) after virus entry, we observed higher rAAV transduction. To elucidate the role of MT-MTOC in rAAV infection and study its underlying mechanisms, we demonstrated that rAAV's perinuclear localization was retained by MT-MTOC with fluorescent analysis, and enhanced rAAV transduction from MT-MTOC disruption was dependent on the rAAV capsid's nuclear import signals. Interestingly, after knocking down RhoA or inhibiting its downstream effectors (ROCK and Actin), MT-MTOC disruption failed to increase rAAV transduction or nuclear entry. These data suggest that enhancement of rAAV transduction is the result of increased trafficking to the nucleus via the RhoA-ROCK-Actin pathway. Ten-fold higher rAAV transduction was also observed by disrupting MT-MTOC in brain, liver, and tumor in vivo. In summary, this study indicates that virus perinuclear accumulation at MT-MTOC is a barrier-limiting parameter for effective rAAV transduction and defines a novel defense mechanism by which host cells restrain viral invasion.

Recombinant adeno-associated virus: clinical application and development as a gene-therapy vector.

Gene therapy is gaining momentum as a method of treating human disease. Initially conceived as a strategy to complement defective genes in monogenic disorders, the scope of gene therapy has expanded to encompass a variety of applications. Likewise, the molecular tools for gene delivery have evolved and diversified to meet these various therapeutic needs. Recombinant adeno-associated virus (rAAV) has made significant strides toward clinical application with an excellent safety profile and successes in several clinical trials. This review covers the basic biology of rAAV as a gene therapy vector as well as its advantages compared with other methods of gene delivery. The status of clinical trials utilizing rAAV is also discussed in detail. In conclusion, methods of engineering the vector to overcome challenges identified from these trials are covered, with emphasis on modification of the viral capsid to increase the tissue/cell-specific targeting and transduction efficiency.

Cytoplasmic trafficking, endosomal escape, and perinuclear accumulation of adeno-associated virus type 2 particles are facilitated by microtubule network.

Understanding adeno-associated virus (AAV) trafficking is critical to advance our knowledge of AAV biology and exploit novel aspects of vector development. Similar to the case for most DNA viruses, after receptor binding and entry, AAV traverses the cytoplasm and deposits the viral genome in the cell nucleus. In this study, we examined the role of the microtubule (MT) network in productive AAV infection. Using pharmacological reagents (e.g., nocodazole), live-cell imaging, and flow cytometry analysis, we demonstrated that AAV type 2 (AAV2) transduction was reduced by at least 2-fold in the absence of the MT network. Cell surface attachment and viral internalization were not dependent on an intact MT network. In treated cells at 2 h postinfection, quantitative three-dimensional (3D) microscopy determined a reproducible difference in number of intracellular particles associated with the nuclear membrane or the nucleus compared to that for controls (6 to 7% versus 26 to 30%, respectively). Confocal microscopy analysis demonstrated a direct association of virions with MTs, further supporting a critical role in AAV infection. To investigate the underling mechanisms, we employed single-particle tracking (SPT) to monitor the viral movement in real time. Surprisingly, unlike other DNA viruses (e.g., adenovirus [Ad] and herpes simplex virus [HSV]) that display bidirectional motion on MTs, AAV2 displays only unidirectional movement on MTs toward the nuclei, with peak instantaneous velocities at 1.5 to 3.5 µm/s. This rapid and unidirectional motion on MTs lasts for about 5 to 10 s and results in AAV particles migrating more than 10 µm in the cytoplasm reaching the nucleus very efficiently. Furthermore, electron microscopy analysis determined that, unlike Ad and HSV, AAV2 particles were transported on MTs within membranous compartments, and surprisingly, the acidification of AAV2-containing endosomes was delayed by the disruption of MTs. These findings together suggest an as-yet-undescribed model in which after internalization, AAV2 exploits MTs for rapid cytoplasmic trafficking in endosomal compartments unidirectionally toward the perinuclear region, where most acidification events for viral escape take place.

Quantitative 3D tracing of gene-delivery viral vectors in human cells and animal tissues.

Trafficking through a variety of cellular structures and organelles is essential for the interaction between gene-delivery vectors (i.e., adeno-associated virus (AAV) and liposomes) and host cells/tissues. Here, we present a method of computer-assisted quantitative 3D biodistribution microscopy that samples the whole population of fluorescently-labeled vectors and document their trafficking routes. Using AAV as a working model, we first experimentally defined numerical parameters for the singularity of Cy5-labeled particles by combining confocal microscopy and atomic force microscopy (AFM). We then developed a robust approach that integrates single-particle fluorescence imaging with 3D deconvolution and isosurface rendering to quantitate viral distribution and trafficking in human cells as well as animal tissues at the single-particle level. Using this quantitative method, we uncovered an as yet uncharacterized rate-limiting step during viral cell entry, while delineating nuclear accumulation of virions during the first 8 hours postinfection. Further, our studies revealed for the first time that following intramuscular injection, AAV spread progressively across muscle tissues through endomysium between myofibers instead of traversing through target cells. Such 3D resolution and quantitative dissection of vector-host interactions at the subcellular level should significantly improve our ability to resolve trafficking mechanisms of gene-delivery particles and facilitate the development of enhanced viral vectors.

Dephosphorylated NSSR1 is induced by androgen in mouse epididymis and phosphorylated NSSR1 is increased during sperm maturation.

NSSR1 (Neural salient serine/arginine rich protein 1, alternatively SRp38) is a newly identified RNA splicing factor and predominantly expressed in neural tissues. Here, by Western blot analysis and immunofluorescent staining, we showed that the expression of dephosphorylated NSSR1 increased significantly during development of the caput epididymis. In adult mice, phosphorylated NSSR1 was mainly expressed in the apical side of epithelial cells, and dephosphorylated NSSR1 in caput epididymis was upregulated in a testosterone dependent manner. In addition, subcellular immunoreactive distribution of NSSR1 varied in different regions of the epididymis. With respect to the sperm, phosphorylated NSSR1 was detected in the mid-piece of the tail as well as the acrosome. Furthermore, NSSR1 was released from the sperm head during the capacitation and acrosome reaction. These findings for the first time provide the evidence for the potential roles of NSSR1 in sperm maturation and fertilization.

NSSR1 is regulated by testosterone in the mouse uterus and extensively expressed in endometrial carcinoma.

Neural salient serine/arginine-rich protein 1 (NSSR1) has been found to play important roles in inhibiting alternative splicing during heat shock and mitosis and is predominantly expressed in neural tissues such as cerebral neurons, cerebellar Purkinje cells and bipolar cells of the retina. Recently, NSSR1 has also been shown to be highly expressed in the testes, suggesting its potential roles in reproductive system. In this report, the expression of NSSR1 in the columnar epithelium of the endometrium and gland epithelium during the development of the mouse uterus, the regulation of NSSR1 level by testosterone in the adult mouse uterus, and expression level of NSSR1 in both human endometrial carcinomas and ovarian cancers were analyzed by quantitative real-time polymerase chain reaction (qRT-PCR), Western blot, and immunohistochemistry. We demonstrated that the expression of NSSR1 was developmentally regulated in the columnar epithelium of the endometrium and gland epithelium in the mouse uterus. Additionally, the NSSR1 level in the mouse uterus was maintained and regulated by testosterone. Interestingly, an enhanced level of NSSR1 was observed in both human endometrial carcinomas and ovarian cancers. Our results suggest that expression and distribution of NSSR1 is developmentally and hormonally regulated and up-regulated in endometrial carcinomas as well as ovarian cancers, indicating its potential involvement in uterine development and tumorgenesis.

Expression pattern and splicing function of mouse ZNF265.

ZNF265 is a newly identified arginine/serine-rich (SR) protein and has two transcript isoforms (ZNF265-1 and ZNF265-2) that autoregulate between each other. Previous studies have shown that ZNF265 regulates the Tra2 beta isoform splicing. Here, we demonstrate that two ZNF-265 transcript isoforms are expressed in various mouse tissues and that ZNF265-1 is a major isoform. The ZNF265-1 protein level in the cerebral cortex is significantly lower in relative to other tissues. The recombinant proteins of both isoforms are nuclear, in consistent with its functions as pre-mRNA splicing regulators. Splicing analysis with GluR-B and SMN2 minigenes demonstrates that ZNF265-1 inhibits the Flop exon and exon 7 usages in the splicing of two minigenes, respectively. The regulation of GluR-B and SMN2 pre-mRNA splicing by ZNF265 implies this newly identified SR protein may play important roles in maintaining normal neuronal function and SMA pathogenesis.

NSSR1 is regulated in testes development and cryptorchidism and promotes the exon 5-included splicing of CREB transcripts.

Neural salient serine/arginine rich protein 1 (NSSR1, alternatively SRp38) is a newly identified splicing factor that is highly expressed in neural and reproductive tissues. We showed that the expression of testicular NSSR1 increased significantly during mouse testes development. NSSR1 was mainly expressed in germ cells, but barely detected in Sertoli cells. Testicular NSSR1 was mostly phosphorylated and cytosolic in germ cells. In comparison, pituitary NSSR1 was mostly dephosphorylated and nuclear. In the cryptorchid testes, the dephosphorylated NSSR1 was significantly increased. RT-PCR analysis demonstrated that the alternative splicing of CREB and CREM genes was altered in the cryptorchid testes. In addition, CREB transcripts were associated with NSSR1 either in testes tissues or cultured GC-1 cells. Moreover, the studies with NSSR1 over-expression or silence demonstrated that NSSR1 promoted the exon 5 inclusion of CREB, indicating that NSSR1 is a new factor that regulates the alternative exon 5 inclusion of CREB transcripts. The findings for the first time provide the evidence indicating the potential importance of NSSR1 in testes development, spermatogenesis and cryptorchidism.