Phenotypic variant of CLN3 mutation.

Purpose: To report a case of bilateral chorioretinal scarring due to CLN3 heterozygous deletion in an asymptomatic patient. Observations: A 63 year-old patient with a history of well-controlled diabetes presented as a referral for diabetic retinopathy. He was asymptomatic with 20/20 visual acuity in both eyes. Exam revealed bilateral multifocal chorioretinal scarring left worse than right, sparing the fovea. He was unable to provide a family history due to adoption, and his remaining medical history and review of systems were noncontributory. Inflammatory and infectious workup was negative; however, genetic testing revealed heterozygous deletion of CLN3 exons 8 and 9. His disease has been nonprogressive at all follow-up appointments. Conclusions and importance: Mutations of CLN3 can present with retina-specific findings including bull's-eye maculopathy and electroretinogram (ERG) deficits; to our knowledge this patient's presentation is unique among those with CLN3 mutations.

Emerging Insights and Interventions for Diabetic Retinopathy.

PURPOSE OF REVIEW: To introduce recent advances in the understanding of diabetic retinopathy and to summarize current and emerging strategies to treat this common and complex cause of vision loss. RECENT FINDINGS: Advances in retinal imaging and functional analysis indicate that retinal vascular and neural pathologies exist long before the development of clinically visible retinopathy. Such diagnostics could facilitate risk stratification and selective early intervention in high-risk patients. Antagonists of the vascular endothelial growth factor pathway effectively reduce vision loss in diabetes and promote regression of disease severity. Promising new strategies to treat diabetic retinopathy involve novel systemic diabetes therapy and ocular therapies that antagonize angiogenic growth factor signaling, improve blood-retina barrier function and neurovascular coupling, modulate neuroretinal metabolism, or provide neuroprotection. Long considered a pure microvasculopathy, diabetic retinopathy in fact affects the neural and vascular retina as well as neurovascular communication. Emerging therapies include those that target neuroretinal dysfunction in addition to those modulating vascular biology.

A proinvasive role for the Ca(2+) -activated K(+) channel KCa3.1 in malignant glioma.

Glioblastoma multiforme are highly motile primary brain tumors. Diffuse tissue invasion hampers surgical resection leading to poor patient prognosis. Recent studies suggest that intracellular Ca(2+) acts as a master regulator for cell motility and engages a number of downstream signals including Ca(2+) -activated ion channels. Querying the REepository of Molecular BRAin Neoplasia DaTa (REMBRANDT), an annotated patient gene database maintained by the National Cancer Institute, we identified the intermediate conductance Ca(2+) -activated K(+) channels, KCa3.1, being overexpressed in 32% of glioma patients where protein expression significantly correlated with poor patient survival. To mechanistically link KCa3.1 expression to glioma invasion, we selected patient gliomas that, when propagated as xenolines in vivo, present with either high or low KCa3.1 expression. In addition, we generated U251 glioma cells that stably express an inducible knockdown shRNA to experimentally eliminate KCa3.1 expression. Subjecting these cells to a combination of in vitro and in situ invasion assays, we demonstrate that KCa3.1 expression significantly enhances glioma invasion and that either specific pharmacological inhibition with TRAM-34 or elimination of the channel impairs invasion. Importantly, after intracranial implantation into SCID mice, ablation of KCa3.1 with inducible shRNA resulted in a significant reduction in tumor invasion into surrounding brain in vivo. These results show that KCa3.1 confers an invasive phenotype that significantly worsens a patient's outlook, and suggests that KCa3.1 represents a viable therapeutic target to reduce glioma invasion.

Autocrine regulation of glioma cell proliferation via pHe-sensitive K(+) channels.

Since the seminal studies of Otto Warburg in the 1920s, it has been widely recognized that cancers grow glycolytically, even in the presence of oxygen. This generates an abundance of protons in a gradient across most solid tumors with an acidic core and an alkaline rim. Whether and how this proton gradient may also serve in an autocrine fashion in these tumors is unclear. We demonstrate that human glioma cells form spheroids that act as a viable three-dimensional tumor model, forming physiologically relevant extracellular pH (pHe) and cell proliferation gradients. Using fluorescent cell cycle trackers, we determined that the rate of cell proliferation is directly dependent on pHe and that cells adjust their growth rate according to their position within the pH gradient. We further show that glioma cells sense pH via H(+)-sensitive K(+) channels, which translate changes in pH into changes in membrane voltage. These channels are tonically active and blocked by acidic pHe, quinine, and ruthenium red. Blockade of this K(+) conductance by acidic pHe or drug inhibition depolarized glioma cells and tumor spheroids and prevented their passage through the hyperpolarization-dependent G1-to-S phase cell cycle checkpoint, thereby inhibiting cell division. In this way, pHe directly determines the proliferative state of glioma cells.

Involvement of tumor acidification in brain cancer pathophysiology.

Gliomas, primary brain cancers, are characterized by remarkable invasiveness and fast growth. While they share many qualities with other solid tumors, gliomas have developed special mechanisms to convert the cramped brain space and other limitations afforded by the privileged central nervous system into pathophysiological advantages. In this review we discuss gliomas and other primary brain cancers in the context of acid-base regulation and interstitial acidification; namely, how the altered proton (H(+)) content surrounding these brain tumors influences tumor development in both autocrine and paracrine manners. As proton movement is directly coupled to movement of other ions, pH serves as both a regulator of cell activity as well as an indirect readout of other cellular functions. In the case of brain tumors, these processes result in pathophysiology unique to the central nervous system. We will highlight what is known about pH-sensitive processes in brain tumors in addition to gleaning insight from other solid tumors.

Egr3 dependent sympathetic target tissue innervation in the absence of neuron death.

Nerve Growth Factor (NGF) is a target tissue derived neurotrophin required for normal sympathetic neuron survival and target tissue innervation. NGF signaling regulates gene expression in sympathetic neurons, which in turn mediates critical aspects of neuron survival, axon extension and terminal axon branching during sympathetic nervous system (SNS) development. Egr3 is a transcription factor regulated by NGF signaling in sympathetic neurons that is essential for normal SNS development. Germline Egr3-deficient mice have physiologic dysautonomia characterized by apoptotic sympathetic neuron death and abnormal innervation to many target tissues. The extent to which sympathetic innervation abnormalities in the absence of Egr3 is caused by altered innervation or by neuron death during development is unknown. Using Bax-deficient mice to abrogate apoptotic sympathetic neuron death in vivo, we show that Egr3 has an essential role in target tissue innervation in the absence of neuron death. Sympathetic target tissue innervation is abnormal in many target tissues in the absence of neuron death, and like NGF, Egr3 also appears to effect target tissue innervation heterogeneously. In some tissues, such as heart, spleen, bowel, kidney, pineal gland and the eye, Egr3 is essential for normal innervation, whereas in other tissues such as lung, stomach, pancreas and liver, Egr3 appears to have little role in innervation. Moreover, in salivary glands and heart, two tissues where Egr3 has an essential role in sympathetic innervation, NGF and NT-3 are expressed normally in the absence of Egr3 indicating that abnormal target tissue innervation is not due to deregulation of these neurotrophins in target tissues. Taken together, these results clearly demonstrate a role for Egr3 in mediating sympathetic target tissue innervation that is independent of neuron survival or neurotrophin deregulation.

Cortical DNA methylation maintains remote memory.

A behavioral memory's lifetime represents multiple molecular lifetimes, suggesting the necessity for a self-perpetuating signal. One candidate is DNA methylation, a transcriptional repression mechanism that maintains cellular memory throughout development. We found that persistent, gene-specific cortical hypermethylation was induced in rats by a single, hippocampus-dependent associative learning experience and pharmacologic inhibition of methylation 1 month after learning disrupted remote memory. We propose that the adult brain utilizes DNA methylation to preserve long-lasting memories.