Cherie M. Southwood

CNS Myelin and Sertoli Cell Tight Junction Strands Are Absent in Osp/Claudin-11 Null Mice

Oligodendrocyte-specific protein (OSP)/claudin-11 is a recently identified transmembrane protein found in CNS myelin and testis with unknown function. Herein we demonstrate that Osp null mice exhibit both neurological and reproductive deficits: CNS nerve conduction is slowed, hindlimb weakness is conspicuous, and males are sterile. Freeze fracture reveals that tight junction intramembranous strands are absent in CNS myelin and between Sertoli cells of mutant mice. Our results demonstrate that OSP is the mediator of parallel-array tight junction strands and distinguishes this protein from other intrinsic membrane proteins in tight junctions. These novel results provide direct evidence of the pivotal role of the claudin family in generating the paracellular physical barrier of tight junctions necessary for spermatogenesis and normal CNS function.

The Unfolded Protein Response Modulates Disease Severity in Pelizaeus-Merzbacher Disease

The unfolded protein response (UPR) is a eukaryotic signaling pathway linking protein flux through the endoplasmic reticulum to transcription and translational repression. Herein, we demonstrate UPR activation in the leukodystrophy Pelizaeus-Merzbacher disease (PMD) as well as in three mouse models of this disease and transfected fibroblasts expressing mutant protein. The CHOP protein, widely known as a proapoptotic transcription factor, modulates pathogenesis in the mouse models of PMD; however, this protein exhibits antiapoptotic activity. Together, these data show that the UPR has the potential to modulate disease severity in many cells expressing mutant secretory pathway proteins. Thus, PMD represents the first member of a novel class of disparate degenerative diseases for which UPR activation and signaling is the common pathogenic mechanism.

Deafness in Claudin 11-null mice reveals the critical contribution of basal cell tight junctions to stria vascularis function.

Generation of a strong electrical potential in the cochlea is uniquely mammalian and may reflect recent evolutionary advances in cellular voltage-dependent amplifiers. This endocochlear potential is hypothesized to dramatically improve hearing sensitivity, a concept that is difficult to explore experimentally, because manipulating cochlear function frequently causes rapid degenerative changes early in development. Here, we examine the deafness phenotype in adult Claudin 11-null mice, which lack the basal cell tight junctions that give rise to the intrastrial compartment and find little evidence of cochlear pathology. Potassium ion recycling is normal in these mutants, but endocochlear potentials were below 30 mV and hearing thresholds were elevated 50 dB sound pressure level across the frequency spectrum. Together, these data demonstrate the central importance of basal cell tight junctions in the stria vascularis and directly verify the two-cell hypothesis for generation of endocochlear potential. Furthermore, these data indicate that endocochlear potential is an essential component of the power source for the mammalian cochlear amplifier.

The erythroid Krüppel-like factor transactivation domain is a critical component for cell-specific inducibility of a beta-globin promoter.

Erythroid Krüppel-like factor (EKLF) is an erythroid cell-specific DNA-binding protein that activates transcription from the beta-globin CACCC element, a functionally important and evolutionarily conserved component of globin as well as other erythroid cell-specific promoters and enhancers. We have attempted to elucidate the molecular role of EKLF in erythrocyte-specific transcriptional activation. First, in vivo and in vitro analyses have been used to demonstrate that the level of activation by EKLF is dependent on the orientation and number of CACCC elements, that EKLF contains separable activation and DNA-binding domains, and that the EKLF proline-rich region is a potent activator in CV-1 cells when fused to a nonrelated DNA-binding module. Second, we have established a transient assay in murine erythroleukemia cells in which reproducible levels of a reporter can be induced when linked to a locus control region enhancer-beta-globin promoter and in which induction is abolished when the promoter CAC site is mutated to a GAL site. Third, we demonstrate that the EKLF transactivation region, when fused to the GAL DNA-binding domain, can restore inducibility to this mutated construct and that this inducibility exhibits activator-, promoter-, and cell-type specificity. These results demonstrate that EKLF provides a crucial transactivation function for globin expression and further reinforce the idea that EKLF is an important regulator of CACCC element-directed transcription in erythroid cells.

Microtubule Deacetylases, SirT2 and HDAC6, in the Nervous System

Examination of the cytoskeleton has demonstrated the pivotal role of regulatory proteins governing cytoskeletal dynamics. Most work has focused on cell cycle and cell migration regarding cancer. However, these studies have yielded tremendous insight for development, particularly in the nervous system where all major cell types remodel their shape, generate unsurpassed quantities of membranes and extend cellular processes to communicate, and regulate the activities of other cells. Herein, we analyze two microtubule regulatory alpha-tubulin deacetylases, histone deacetylase-6 (HDAC6) and SirT2. HDAC6 is expressed by most neurons but is abundant in cerebellar Purkinje cells. In contrast, SirT2 is targeted to myelin sheaths. Expression of these proteins by post-mitotic cells indicates novel functions, such as process outgrowth and membrane remodeling. In oligodendrocytes, targeting of SirT2 to paranodes coincides with the presence of the microtubule-destabilizing protein stathmin-1 during early myelinogenesis and suggests the existence of a microtubule regulatory network that modulates cytoskeletal dynamics.

Erythroid Krüppel‐like factor exhibits an early and sequentially localized pattern of expression during mammalian erythroid ontogeny

Erythroid Krüppel‐like factor (EKLF) is an erythroid cell‐specific transcription factor that mediates activation via binding to a 9 base pair sequence that encompasses the CACCC element, one of a trio of evolutionarily conserved sequence motifs that are functionally important for transcription of red cell‐specific genes. Molecular analyses have delineated the specificity of its interaction and activation through the CAC site at the adult β‐globin promoter. However, its expression and distribution during murine ontogeny have not been established. To address these issues, we have focused on biological aspects of EKLF expression by examining the onset and localization of its mRNA during murine development by using reverse transcription/polymerase chain reaction (RT/PCR) analysis of differentiating embryonic stem cells and in situ analyses of normal developing embryos. In addition, we have monitored the presence of EKLF protein by blot analysis of whole‐cell extracts derived from circulating cells and embryonic tissue.

CNS Myelin Paranodes Require Nkx6-2 Homeoprotein Transcriptional Activity for Normal Structure

Homeodomain proteins play critical roles during development in cell fate determination and proliferation, but few studies have defined gene regulatory networks for this class of transcription factors in differentiated cells. Using a lacZ-knock-in strategy to ablate Nkx6-2, we find that the Nkx6-2 promoter is active embryonically in neuroblasts and postnatally in oligodendrocytes. In addition to neurological deficits, we find widespread ultrastructural abnormalities in CNS white matter and aberrant expression of three genes encoding a paranodal microtubule destabilizing protein, stathmin 1, and the paranodal cell adhesion molecules neurofascin and contactin. The involvement of these downstream proteins in cytoskeletal function and cell adhesion reveals mechanisms whereby Nkx6-2 directly or indirectly regulates axon- glial interactions at myelin paranodes. Nkx6-2 does not appear to be the central regulator of axoglial junction assembly; nonetheless, our data constitute the first evidence of such a regulatory network and provide novel insights into the mechanism and effector molecules that are involved.

Alternative promoters and polyadenylation regulate tissue-specific expression of Hemogen isoforms during hematopoiesis and spermatogenesis

Hemogen is a nuclear protein encoded by HEMGN (also known as hemogen in mouse, EDAG in human and RP59 in rat). It is considered to be a hematopoiesis‐specific gene that is expressed during the ontogeny of hematopoiesis. Herein, we characterize two distinct splicing variants of HEMGN mRNA with restricted expression to hematopoietic cells and to round spermatids in the testis, respectively. Expression of the testis‐specific HEMGN mRNA (HEMGN‐t) is developmentally regulated and is concurrent with the first wave of meiosis in prepuberal mice. Sequence analysis reveals that HEMGN‐t and the hematopoietic HEMGN mRNA (HEMGN‐h) share a common coding sequence with distinct 5′ and 3′ untranslated regions and that these two isoforms are transcribed from the same gene locus, HEMGN, through the use of alternative promoters and polyadenylation sites. Thus, HEMGN expression exemplifies a developmental regulatory mechanism by which the diversification of gene expression is achieved through using distinct regulatory sequences in different cell types. Moreover, the existence of a testis‐specific isoform of HEMGN suggests a role in spermatogenesis. Finally, fluorescence in situ hybridization demonstrates that HEMGN is localized to chromosome 4 A5‐B2 in mouse and to chromosome 9q22 in human, which is a region known to harbor a cluster of leukemia breakpoints. Developmental Dynamics 228:606–616, 2003.

Potential For Cell-mediated Immune Responses In Mouse Models Of Pelizaeus-Merzbacher Disease

Although activation of the innate and adaptive arms of the immune system are undoubtedly involved in the pathophysiology of neurodegenerative diseases, it is unclear whether immune system activation is a primary or secondary event. Increasingly, published studies link primary metabolic stress to secondary inflammatory responses inside and outside of the nervous system. In this study, we show that the metabolic stress pathway known as the unfolded protein response (UPR) leads to secondary activation of the immune system. First, we observe innate immune system activation in autopsy specimens from Pelizaeus-Merzbacher disease (PMD) patients and mouse models stemming from PLP1 gene mutations. Second, missense mutations in mildly- and severely-affected Plp1-mutant mice exhibit immune-associated expression profiles with greater disease severity causing an increasingly proinflammatory environment. Third, and unexpectedly, we find little evidence for dysregulated expression of major antioxidant pathways, suggesting that the unfolded protein and oxidative stress responses are separable. Together, these data show that UPR activation can precede innate and/or adaptive immune system activation and that neuroinflammation can be titrated by metabolic stress in oligodendrocytes. Whether or not such activation leads to autoimmune disease in humans is unclear, but the case report of steroid-mitigated symptoms in a PMD patient initially diagnosed with multiple sclerosis lends support.

Overexpression of CHOP in Myelinating Cells Does Not Confer a Significant Phenotype under Normal or Metabolic Stress Conditions.

The PKR-like endoplasmic reticulum kinase (PERK) pathway of the unfolded protein response (UPR) is protective against toxic accumulations of misfolded proteins in the endoplasmic reticulum, but is thought to drive cell death via the transcription factor, CHOP. However, in many cell types, CHOP is an obligate step in the PERK pathway, which frames the conundrum of a prosurvival pathway that kills cells. Our laboratory and others have previously demonstrated the prosurvival activity of the PERK pathway in oligodendrocytes. In the current study, we constitutively overexpress CHOP in myelinating cells during development and into adulthood under normal or UPR conditions. We show that this transcription factor does not drive apoptosis. Indeed, we observe no detriment in mice at multiple levels from single cells to mouse behavior and life span. In light of these data and other studies, we reinterpret PERK pathway function in the context of a stochastic vulnerability model, which governs the likelihood that cells undergo cell death upon cessation of UPR protection and while attempting to restore homeostasis. SIGNIFICANCE STATEMENT Herein, we tackle the biggest controversy in the UPR literature: the function of the transcription factor CHOP as a protective or a prodeath factor. This manuscript is timely in light of the 2014 Lasker award for the UPR. Our in vivo data show that CHOP is not a prodeath protein, and we demonstrate that myelinating glial cells function normally in the presence of high CHOP expression from development to adulthood. Further, we propose a simplified view of UPR-mediated cell death after CHOP induction. We anticipate our work may turn the tide of the dogmatic view of CHOP and cause a reinvestigation of its function in different cell types. Accordingly, we believe our work will be a watershed for the UPR field.